THE STABILITY OF BROKEN ENDS OF
          CHROMOSOMES IN ZEA MAYS

                  BARBARA McCLINTOCK
           University of Missouri, Colwnbia, Missouri

              Received November 27, 1940

                      I. INTRODGCTION
I F CHROMOSOMES are broken by various means, the broken ends
appear to be adhesive and tend to fuse with one another z-by-z. This
has been abundantly illustrated in the studies of chromosomal aberrations
induced by X-ray treatment. It also occurs after mechanical rupture of
ring-shaped chromosomes during somatic mitoses in maize and is assumed
to occur during the normal process of crossing-over. In a previous publica-
tion (MCCLINTOCK ro38b) it was shown that following breakage of a single
chromatid in a meiotic anaphase of maize, fusion occurs at the position of
breakage between the two sister halves of this broken chromatid. Because
of this fusion, the two sister halves cannot separate freely from one another
in the following mitotic anaphase. As the two centromeres of the termi-
nally united chromsomes pass to opposite poles in this mitotic anaphase, a
chromatin bridge is produced. The tension on the bridge configuration,
following the poleward migration of the centromeres, results in rupture.
Once again, a chromatid with a broken end enters each sister telophase
nucleus. The questions then arise: Will fusions occur at the position of
breakage between the two sister halves of each of these broken chromo-
somes giving rise to an anaphase bridge configuration in the following
mitosis? If so, will this breakage-fusion-bridge cycle continue in each suc-
cessive nuclear division, or will the broken end, produced by the rupture of
an anaphase bridge configuration, eventually "heal," thus discontinuing
the breakage-fusion-bridge cycle? Answers to these questions were pre-
sented briefly in a preliminary publication (MCCLINTOCK 1939). The re-
sults presented in this latter publication and those presented in this paper
have led to the following conclusions. (I) If a chromosome, broken at the
previous meiotic anaphase, is delivered to the primary endosperm nucleus
through either the male or the female gametophyte, the breakage-fusion-
bridge cycle will continue in the successive nuclear divisions during the
development of the endosperm tissues. (2) A similarly broken chromosome
delivered to the zygote nucleus by either the sperm or the egg does not give
rise to bridge configurations in successive nuclear divisions in the sporo-
phytic tissues. The broken end heals. There is a complete cessation of the
breakage-fusion-bridge cycle. (3) The breakage-fusion-bridge cycle is con-
fined to the gametophytic and endosperm tissues of the generation im-
mediately following the initial break in the chromosome. (4) Healing of the


             SThBILITI' OF BROKEN CHROMOSOMES           235
broken end in the embryonic sporophyte is permanent. When a chromo-
some with a healed broken end is introduced into gametophytic or endo-
sperm tissues in succeeding generations, no fusions of broken ends result
either between sister halves of the broken chromosome or between two
such broken chromosomes when both are introduced into a single nucleus.
It is the purpose of this paper to present the evidence for these conclusions.

      II. THE TYPES OF GENETIC VARIEGATION PRODUCED BY THE

                BREAKAGE-FUSION-BRIDGE CYCLE
If a broken chromosome continued the breakage-fusion-bridge cycle in
successive nuclear divisions, its presence should be made evident by genetic
variegation in endosperm and plant tissues. This would follow when the

FIGURE I.-A representative illustration of the method by which variegation may be produced
in tissues carrying a chromosome with a broken end. The clear circle represents the centromere.
The dominant genes A B and C are carried by the arm with the broken end, A being near the
broken end and C near the centromere. The homologue of this chromosome (not diagrammed) is
considered to be normal and to carry the genes a b and c. Division of this broken chromosome re-
sults in fusion at the position of breakage between the two split halves (prophase, second diagram
from top). This is followed by a bridge configuration in the following anaphase (anaphase, third
diagram from top). The arrow points to the position of breakage, the two broken chromosomes
entering the sister telophase nuclei (telophase, right and left). This process is repeated in succes-
sive divisions. One such division is diagrammed below each of these two telophase chromatids.
The diagrams illustrate how dominant genes may be deleted or reduplicated followed the break-
age-fusion-bridge cycle.

broken chromosome carried dominant genes and its normal homologue
carried the recessive alleles. Figure I illustrates the method by which
variegation is produced in consequence of the breakage-fusion-bridge cycle.
The line at the top of the figure represents a chromosome with a broken
end. The dominant genes A B and C are carried by the arm with a broken
end, A being close to the broken end and C nearest to the centromere. The


236                  iLJ~Kl3.4K.i McCLISTOCI;
diagram immediately below represents this chromosome at the following
prophase, fusion having occurred between the two sister chromatids at the
position of previous breakage. Separation of the two sister centromeres at
anaphase results in a bridge configuration (third diagram, fig. I). If a
break occurred at the position of the arrow, a chromosome carrying the
genes A A B C and possessing a broken end would enter one telophase
nucleus (left in the diagram) and one chromosome carrying the genes B
and C would enter the sister telophase nucleus (right in diagram). All the
cells arising from this latter cell would lack the dominant gene A. Thus, the
recessive gene a would appear in all cells arising from this cell, and the
process which results in variegation would have commenced. Each of these
broken chromosomes could, in turn, repeat the process just outlined. In
the telophase chromosome to the right, the broken ends of the two sister
chromatids would again be fused at the succeeding prophase (see diagram),
and a bridge configuration would result at the following anaphase (see
diagram below). If a break occurred at the arrow, a broken chromosome
carrying B B C would enter one telophase nucleus and a broken chromo-
some carrying only C would enter the sister nucleus. All the cells arising
from this latter cell would have lost the dominant genes `4 and B, and the
tissues would show the character of the recessive alleles a and b. In the
first telophase to the left, a similar process has been diagrammed whereby
the dominant gene A is lost to one daughter nucleus and repeated duplica-
tions of -4 genes are introduced into the sister nucleus.
The diagram (fig. 11 is merely an example. The break in the first ana-
phase might have occurred between the two A genes. Several nuclear
cycles might take place before a break occurred to one side of these genes
resulting in the loss of the .4 gene to one of the daughter nuclei. On the
other hand, the first or successive breaks might have occurred close to one
of the centromeres resulting in the loss of all three dominant genes to one
nucleus and their duplication in the sister nucleus. Variegation patterns of
dominant and recessive tissue resulting from this type of behavior should
be very distinctive. Some tissues could be totally recessive-that is.
(I b c. In this case, all three genes would be lost from a nucleus in a single
anaphase break. Other tissues could be recessive for a but variegated for
b and c. In this case A would be lost from the cell following one anaphase
break, while B and C would be subsequently lost. In these tissues, patches
should be found which are (I) a b c where B and C have subsequently and
simultaneously been lost; (2) a b C from which B and not C has been lost.
In this latter patch, which is wholly Q b in genetic character, still smaller
patches should be found which are a b c. No tissues should be found which
show the genetic constitution a B c. In other words, when variegation
within variegation is present, the developmental pattern should show the


             ST;\BILITI' OF BROKEN CHROMOSOMES          237
loss of the terminal genes before loss of genes close to the centromere. Since
variegation of endosperm tissues was the means by which individuals pos-
sessing broken chromosomes were detected, a description of the types of
variegation observed will be given after the method has been described by
which broken chromosomes may be obtained.

In order to secure cytological evidence of the presence of a broken chro-
mosome in a plant and to study the genetic consequences of its behavior,
two methods were employed. Both methods involve the breakage of chro-
mosome 9 at a meiotic anaphase and its deliverance to the endosperm
and the zygote after successful passage through the developmental periods
of the male or the female gametophytes (the pollen grain and embryo sac,
respectively). This necessitates the production of a broken chromosome

E`IGVRE I-.-I'hotomicrograph of chromosome o at pachytene in a microsporocyte. The centro-
mere appears as a grey bulge (arrow). The short arm of one of the homologues terminates in a
small knob. Sate the deep-staining region adjacent to the centromere in the short arm and the
smaller, more widely spaced chromomeres in the distal part of the arm. The proximal deep-
staining segment appears relatively longer in this photograph than in the diagrams given in this
paper. This is due to an overlapping of the two homologous chron-osones immediately distal to
the junction of the deep-staining and lighterstaining regions.

which possesses at least a full set of genes if transmissions are to occur
through the male gametophyte, or broken chromatids with only relatively
short terminal deficiencies if transmissions are to occur through the female
gametophyte. No deficiencies within the short arm of chromosome 9 which
are transmitted through the pollen are known, but deficiencies of terminal
segments up to and including one third of the short arm may be trans-
mitted through the female gamete (MCCLINTOCK unpublished).

Both methods involve the use of abnormalities in the structural arrange-
ment of chromosome 9 of maize. A photograph of a normal chromosome
9 at the mid-prophase of meiosis is given in figure 2. The genes I'g?, C,
Sh, and Wx are located in the short arm of chromosome 9. E'g normal green
plant, yg yellow-green plant; C colored aleurone, c colorless aleurone; Sk
normal development of the endosperm? slz shrunken endosperm; Tl'x nor-
mal starch staining blue with iodine, wx waxy starch staining red with
iodine). The linear order of these genes is E'g-C-Sh-TIT.r. I'g is located very-


238                  B.%RB;\RX McCLINTOCK
near the end of the short arm. C is located approximately a quarter of the
distance in from the end of the short arm. Sh is located very close to it.
11'~ is located at approximately the middle of the short arm, although its
exact position has not been determined. It should be noted that the gene
Ug is a plant character, whereas the genes C, Sh, and Wx are endosperm
characters.

III. THE PRODUCTION OF A BROKEN CHROMOSOME BY MEANS
     OF 4 REARRANGEMENT IN CHROMOSOME 9
     (a) Description of the rearrangement

The first method will be described in considerable detail, since it affords
particularly favorable material for a cytological and genetical study of the
behavior of broken chromosomes. It involves the use of a chromosome 9

FICVRE 3.--A normal chromosome o terminating in a large knob (stippled). The clear oval
region represents the centromere. The individual parts of the chromosome have been numbered
from I to I 7, The broken line (segments I to 4) represents the widely spaced small chromomeres of
the distal two-thirds of the short arm. The wide line (segments 5 and 6) represents the proximal
deep-staining region of the short arm adjacent to the centromere. The long arm is represented by
a narrow line. The arrow point to the positions of breaks which resulted in the rearranged chromo-
some shown in b.

with a moderately complex rearrangement of parts which arose following
X-ray treatment. A normal chromosome 9 is diagrammed in a, figure 3.
In the strain of maize irradiated, the short arm terminated in a large knob
(stippled). (In certain strains of maize no knob is present at the end of the
short arm. In other strains small or intermediate size knobs are found.
The knob substance lengthens the chromosome but does not carry essential
genie material.) The proximal one-third of the short arm (fig. 2 and regions
- and 6 fig. 3) adjacent to the centromere (clear oval region in diagram) is
3
characterized by large, closely associated deeply-staining chromomeres,
suggesting heterochromatin in appearance. It will be referred to as the
pycnotic region. The distal two-thirds of the short arm (clash lines fig. 3)
is composed of small, widely spaced chromomeres. The arrows in a (fig 3)
indicate the positions of breaks which resulted in the rearrangement of
segments shown in b (fig. 3). The large terminal knob has been broken into
two unequal parts, the small part together with three quarters of the short
arm being inserted into the long arm in the normal order. The section which


            STABILITY OF BROKEN CHROMOSOMES           `39
includes 6 to IO became attached to the larger segment of the knob at
region IO, resulting in an inverted order for the genes in this segment.

  (b) Types of chromosomes produced as the result of crossing-otqer
Plants which contain one rearranged chromosome 9 and a normal homo-
logue give rise to several types of anaphase I and II configurations following
crossing over in the rearranged segments. A diagram of the meiotic pro-
phase synaptic configuration is given in figure 4. The regions where cross-
ing over results in aberrant configurations are labelled A, B, and C. Region
A includes the segment from I to 5, Region B includes segment 6. Region
C includes the segment 7 to IO.

Several types of altered chromosomes result from crossing over in these
regions. In figure 5, the types of dicentric chromatids produced by crossing

A

FIGURE A.-Synaptic configuration produced following homologous associations of a normal
chromosome 9 (without a knob) and the rearranged chromosome diagrammed in b of figure 3.
Region A includes segments I to 5. Region B includes segment 6 (between the small knob and the
centromere). Region C includes segments 7 to 10.

over are diagrammed. The type of crossing over which produces each type
of dicentric chromatid is given in the description beneath the figure. In
most cases, the dicentric chromatid produces a bridge configuration in ana-
phase I. The two types of crossovers which lead to bridge configurations
at anaphase II are indicated in the legend. In addition to the dicentric
chromatids, two new monocentric chromatids can be produced as the re-
sult of crossing over. These are diagrammed in figure 6. The various types
of acentric chromatids, which are the complements of the dicentric chro-
matids, are mainly lost to the successive nuclei following crossing over.
Thus, they have not been diagrammed.

As indicated in figure 5, most of the dicentric chromatids result in a
bridge configuration in anaphasc I. Only the three-strand double crossovers
involving regions ,4 and B result in bridge configurations in anaphase IT.


240                  13:1RH;\R.4 MrCI,INTOCK
Observations of the number of bridge configurations in the two meiotic
divisions indicate the frequency of the types of crossovers. Among 238
                                                            I

d

FIGURE S.--Types of dicentric chromatids produced as the consequence of crossovers in re-
gions A, B, and C of figure 4. a. Dicentric chromatid produced following a single crossover in region
A. A bridge configuration occurs at anaphase I. b. A dicentric chromatid resulting from a two-
strand double crossover involving regions A and B or i\ and C. A bridge configuration occurs at
anaphase I. c. Dicentric chromatid resulting from a three-strand double crossover involving one
chromatid of the rearranged chromosome and the two chromatids of the normal chromosome. One
crossover in region .A, the other in region C. will result in a bridge configuration in anaphase I.
If the second crossover is in region R, a bridge configuration will occur in anaphase II. d. Dicentric
chromatid resulting from a three-strand double crossover, as in c, but the chromatids involved are
the reverse-that is, one from the normal chromosome and two from the rearranged chromosome.

microsporocytes in anaphase I, 77 or 32 percent showed a chromatid
bridge. In two of these microsporocytes a double bridge with two acentric
fragments was observed-the result of a four-strand double crossover.

17            II   IO  9  0  7    6   I   2  3  4  5  II               17

a

10967 654   3 2 I
                . . . . . ---.-.I

b

FIGCRE 6.-Types of deri\.ed chromosomes \vith a single centromere resulting from a crossover
in regions B or C of tigure 4. The chromatid in a could be recovered, since it contains a complete set
of genes plus a duplication of segments I I to I 7. The chromatid in b could not be recovered, since
it is deficient for the segments I I to r 7.

In anaphase II, only those dyads were counted in which both sister cells
could be observed at mid-anaphase. Among 271 such dyads, only five or
1.8 percent showed a chromatin bridge configuration in one of the sister
cells.

The dicentric chromatid most frequently formed (a, fig. 5) is of particu-
lar signiticance for this study. The part of the Acentric chromatid extend-


            STABILITY OF BROKEN CHROMOSOMES           241
ing from the small internal knob to the right end of the chromosome is the
equivalent of a complete chromosome 9. Left of the small internal knob is
the short pycnotic region 6 followed by the second centromere and the seg-
ment 7 to IO which terminates in the large knob. At anaphase I, the two
centromeres moving in opposite directions cause the chromatid to break.
Analyses of anaphase I configurations and of the composition of this chro-
mosome in microspores indicate that the break may occur at any position
between the two centromeres. Breaks which occur immediately to the right
of the small internal knob or to the left of this position, will result in one
broken chromatid with at least a full set of genes of chromosome 9. This
chromatid could result in a viable spore since no essential genie material
has been lost from the chromosome at this initial break. Breaks which occur
to the right of the small inner knob within regions I to 6 would result in a
chromatid deficient for various numbers of genes of the short arm, de-
pending in each case upon where the break had occurred. Regardless of
where the break occurs, the resulting broken chromatid to the left would be
deficient for a large number of genes of chromosome 9. It would not be ex-
pected to produce a functional spore. Interest centers, therefore, on the
transmissions of the broken chromatid to the right.
The two dicentric chromatids shown in b and c (fig. 5) could give rise to
broken chromatids with a full complement of genes. Those in d would not
be expected to survive, because both of the broken chromatids would be
highly deficient. In b (fig. 5) the surviving chromatid following breakage
would have most of the genes in the short arm in the inverted order. In c
(fig. 5) the surviving broken chromatid could have its genes in the normal
order if the break occurred between the knob and the left centromere and
would be indistinguishable from the broken chromatid derived from a. If
the break occurred in segment 6 adjacent to the right centromere, the sur-
viving broken chromatid would have the order of the genes reversed, as in
b. Since none of the transmitted broken chromosomes so far obtained have
shown an inverted order of genes, attention will be concentrated on the sur-
viving broken chromatid arising from the dicentric chromatid of a.
       (c) Types of kernels resulting from the cross
C Sh WX rearranged chromosome 9 X c sh wx normal chromosome 9.
  G sh wx normal chromosome 9
The dicentric chromatid (a, fig. 5) arises from a crossover in region A of
figure 4. This region carries the loci of the genes Yg C Sh and IVn. Since
the chromosomes with a broken end arise from a dicentric chromatid which
suffered a break at anaphase I or II, all surviving chromosomes with a
broken end should be crossovers within this region A. If the breakage-fu-
sion-bridge cycle continues after the initial meiotic anaphase break, the


242                BARBAR. WCLINTOCK
endosperm tissue should be variegated when it has received from one par-
ent a broken chromosome 9 carrying any or all of the dominant endosperm
genes and from the other parent a normal chromosome 9 with the recessive
alleles, c sh and WX.

The following tests were made in order to show that the variegated ker-
nels arise following a crossover in region A of figure 4. Plants were obtained
which possessed a rearranged chromosome 9 carrying the genes Yg C Sh
Wx and a normal chromosome 9 with the genes yg c sh wx. These plants
were crossed to those carrying two normal chromosomes 9 each with the
genes yg c sh WX. The types of single crossovers within this region and the
resulting dicentric chromatids with their genie constitutions are shown in
figure 7. The rearranged chromosome 9 with the genes Yg C Sh WX and
the normal chromosome 9 with the genes yg c sh x's are diagrammed at the

FIGURE Y.--The genie constitution of dicentric chromatids resulting from crossing over in seg-
ments I to 5. At the top of the diagram, homologous associations of the rearranged chromosome
9 and a normal chromosome 9 are represented only betwen segments I to 5. The genie constitu-
tion of each chromosome is indicated. Between the two chromosomes the regions where crossovers
may be detected are numbered I, 2. 3, and 4. The dicentric chromatids with their genie constitu-
tions resulting from crossol-ers in each of these regions are given below.

top of figure 7. To simplify visualization of the crossovers, homologous as-
sociations of these two chromosomes are diagrammed only in the region
carrying these genes (region A of fig. 4). There are four marked regions of
crossing over, designated I, 2, 3, and 4 in the diagram. The amount of
crossing over which occurs between two normal chromosomes 9 in regions
I, 2, and 3 are 19 percent, 3 percent, and 21 percent, respectively (EMER-
SON, FRASER, and BEADLE 1935). The normal amount of crossing over in
region 4 (from TVx to the break) cannot be stated, since there were no pre-
vious tests for this region. A crossover in region I (from Yg to C) would
give rise to a dicentric chromatid carrying the genes Yg c sh x'x. Following


             STABILITY OF BROKEN CHROMOSOMES           243
the meiotic anaphase break, a surviving broken chromatid with the endo-
sperm genes c sh and wx could be delivered to the primary endosperm
nucleus. Since no variegation would result, this broken chromatid could
not be detected by the endosperm characters.
A crossover in region 2 would give rise to a dicentric chromatid carrying
I'g C slz VS. If the first break in the dicentric chromatid occurred to the left
of C, a broken chromosome carrying the genes C slz and ii1.r could be de-
livered to an endosperm, provided the successive breaks in the gameto-
phyte divisions did not eliminate C. The resulting endosperm should be
homozygous for sh and w but variegated for C and c.
A crossover in region 3 would give rise to a decentric chromatid carrying
I'g C Sh WX. Thus a broken chromosome with the genes c` S/I and wx could
be delivered to the primary endosperm nucleus. The endosperm tissue
which develops should be homozygous for :;`s but variegated for C-c and
Sil-sh.
A crossover in region 4 would give rise to a dicentric chromatid carrying
the genes E'g C Sh and 11's. If the original break and the successive breaks
in the gametophptc divisions occurred to the left of C, a broken chromo-
some with the genes C Slz and 11'~ would be delivered to the endosperm.
The endosperm then should be variegated for all three genes, the detectible
order of the loss of the dominant genes being C, followed by Sh, followed by
11"~. In this last case, a break occurring between C and Sh, either in the first
or in subsequent gametophyte divisions, could deliver a broken chromo-
some with the genes Sh and Tl'x to the endosperm tissues. The endosperm
would then be c but variegated for Sh-sh and l17x-~;j~. If the original or
subsequent break in the gametophyte occurred between Sla and Wx, the
endosperm tissues would be c and sh but variegated for WX-WX. Thus, sin-
gle crossovers in regions 2, 3, and 4 should be genetically detectible by the
type of endosperm variegation. Since C and S/t are close together and the
genes Sh and 1%`~ relatively distant, there should be many more C-c Sh-sh
XL kernels than C-c slz ux kernels. If the normal relative rates of crossing
over for these two regions is maintained in the plants heterozygous for the
altered chromosome 9, the two types of variegated kernels should occur in
the ratio of I to 7. That this ratio is maintained is seen from an examination
of table I, which gives the tvpes of kernels resulting from the cross C Sh WX
rearranged chromosome 9,:~ S/Z WC normal chromosome 9 Xc sh wx normal
chromosome 9. This table considers only the endosperm characters. In the
crosses contributing to table I, the plant character ~g need not be con-
sidered. However, in some crosses, both parents were homozygous Yg. In
other crosses, the heterozygous parent was either Yg Yg, or Yg yg as in
figure 7, while the recessive parent was homozygous for yg.
In this table it may be seen that 99 percent of the kernels have the genet-


244                 BARBARA McCLINTOCK
ic constitution of the two parental chromosomes of the heterozygous in-
dividual-that is C Sh Wx non-variegated or c sh WX. Only 0.8 percent of
the kernels in the first column and 0.51 percent of the kernels in the second
column are variegated, but the relative proportions, respectively, of the
variegated kernels representing crossovers in regions 2,3, and 4 are similar

TABLE I

Types of kernels arising from the cross.

C Sh Wx rearranged chromosome 9
c sk -8% normal chromosome 9   Xc sh wx normal chromosome 9

iXon-variegated, non-
crossover kernels

   C Sh W-s
   c sh wx

0 PABENTHETEROZYGOCi       3 PARENTHETEROZYGOCS




II ,716                6,789
11,679               5,812

Subtotal

Non-variegated,
crossover kernels
  C sh wx
  c Sh Wx
  C Sh MX
  c sh Wx
  c 2-h wr
  cShwx
       Subtotal

23 Y 393
98.9%

12,601
99.1%

2                       3
3                       1
I2                       11
8                       14
0                       0
I                       0
        26                      39
    0.19%              0 30%

Variegated kernels
c-c sh Ic'x
C-G Sit-sh Z'X
C-c Sh-sh Tt'r-tiz
c Sk-sh Wr--wx
c sh Trx-"W
        Subtotal

78                  48
21                       II
2                       0
I                       0

        109                      66
    0.80%              0.51%

Totals                 23,530               11,706

in both crosses. Among the variegated kernels 14 were homozygous for S/I
and ux but variegated for C-c. These represent crossovers in region 2. One
hundred twenty-six were homozygous for wx but variegated for both C-C
and Sh-sly. These represent crossovers in region 3. Thirty-two were varie-
gated for all three genes. These represent crossovers in region 4. The rela-
tive proportions of crossovers in regions 2 and 3 conform to expectancy on
the basis of both the cytological and genetic evidence for the distance be-
tween the genes C Sh and Wr. The relative proportion of crossing over


             STABILITY OF BROKEN CHROMOSOMES          245
from Wx to the break in the rearranged chromosome 9 could not be antici-
pated, since no previous genetic evidence was available for this region.

In both crosses there were a few kernels (0.19 percent in column r and
0.30 percent in column 2) carrying crossover chromatids which did not
show variegation. According to expectancy, these should represent double
crossover chromatids with normal, non-broken ends. The kernels should
possess either a normal chromosome 9 or a rearranged chromosome 9 but
not a broken chromosome 9. Whether, in any class, a normal or a rearranged
chromosome is present would depend upon the positions of the two cross-
overs with respect to both the genes and the chromatids involved (see table
6).

Cytological evidence for the conclusion that the variegated kernels carry
a chromosome 9 with a broken end and that the non-variegated kernels
possess a non-broken chromosome could be obtained readily by examina-
tion of the chromosome complement of the plants arising from each of
these types of kernels. However, before these results are described, it is de-
sirable to emphasize the genetic evidence which allows one to conclude
that the breakage-fusion-bridge cycle is responsible for the variegation in
the endosperm. These may be enumerated as follows. (I) The frequency of
the different types of kernel variegation indicates their relationship to
crossing over in region A, figure 4, which, in turn, results in a dicentric chro-
matid and finally a broken chromosome. (2) The very low percentage of
non-variegated kernels carrying crossover chromatids. This is expected
on the assumption of their origin from a double crossover. These should be
relatively infrequent. (3) The developmental order of loss of the genes in
the variegated kernels containing C Sh and FVx is the type expected on the
basis of the breakage-fusion-bridge cycle as outlined in figure I. The genes
nearer the broken end are lost before those nearest the centromere. (4)
A striking confirmation of the breakage-fusion-bridge cycle appears in the
various colored regions in the variegated kernels. In normal endosperm tis-
sues the C allele may be present in a single dose (Ccc), a double dose
(C C c), or a triple dose (C C C). Usually the depth of color of the aleurone
layer is related to the number of C alleles present, C c c being lighter than
C C c which in turn is lighter than C C C (JONES 1937). When a broken
chromosome 9 is introduced in the cross outlined, the depth of color in the
C regions in the variegated kernels varies from very light to exceptionally
dark. The regions are distributed in well defined patches for each intensity
of color. This type of variegation is exactly what should be produced fol-
lowing the breakage-fusion-bridge cycle. As illustrated in figure I, genes
may not only be lost but may be reduplicated as a consequence of this
cycle. Thus, various doses of the C allele in different regions of the aleurone
are to be expected.


246                 Ri\RBARA McCLI~TOCK
On the basis of the genetic evidence obtained from the variegated ker-
nels, it was expected that the plant tissues would likewise show variegation
for the Yg gene when the homozygous parent contained the gene yg, as
well as the genes G sh WX, in its two normal chromosomes 9 while the
heterozygous parent contained Yg in each of its two chromosomes 9. Some
of the crosses contributing to table I were of this type. The plants arising
from the variegated kernels would be expected to show variegation
(Yg-yg) or to be wholly yg if the Yg locus had been lost either in the original
or in an early subsequent break. The results were unexpected. The plants
were either Yg or yg. There were no variegated individuals. Forty-eight
plants were grown from the variegated kernels. Forty were Yg and eight
were yg. Cytological examination showed that al1 the plants arising from
these variegated kernels actually possessed a broken chromosome 9. The
Yg plants had at least a complete chromosome 9. All the yg plants had lost
a segment at the end of the short arm of chromosome 9 which included the
Yg locus. In all cases, however, the broken end of the chromosome 9 had
healed in the somatic diploid tissues, discontinuing the breakage-fusion-
bridge cycle and thus the possibility of producing variegation in the Yg in-
dividuals. If the non-variegated crossover kernels possessed a non-broken
end resulting from a double crossover, none of the plants arising from these
kernels should be yg. All should possess either the normal chromosome 9 or
the rearranged chromosome 9. Twenty-six plants were grown from the
crossover non-variegated kernels. All twenty-six were Yg; none was yg.
Cytological examination showed that a11 possessed an unbroken chromo-
some 9.
The cross outlined above allows one to distinguish between the crossover
types which give a broken chromosome 9 and those which give a non-
broken chromosome 9. As stated earlier, the single crossovers in region I of
figure 7 cannot be detected by variegation, because the broken chromosome
has the constitution c sh QX. Since this region between the knob and C in
normal material shows as much crossing over as that between C and WX,
a number of broken chromosomes must have remained undetected in the
above crosses. In order to detect the transmissible broken chromosomes
following a crossover in region I, as we11 as in the other three regions, indi-
viduals of the constitution C Sh W'x rearranged chromosome 9,/C sh *rcls
normal chromosome 9 were crossed with plants carrying two normal chro-
mosomes 9 each with c sh -X,X. In this cross, the single crossovers in region I
(fig. 7) would result in a dicentric chromatid with the constitution C sh zlx.
Following breakage of the dicentric chromatid, the surviving broken chro-
mosome should have the constitution C sh UT and would result in a kernel
variegated for C-c but homozygous for sh and UX. The single crossovers in
regions 2, 3, and 4 would produce the same types of variegated kernels as


             `STABILITY OF BROKEN CHROMOSOMES           247
described in figure 7. Since single crossovers in regions I and 2 result in sur-
viving broken chromosomes with similar constitutions, the class C-c sh ux
among the variegated kernels should be relatively increased in this cross.
This is shown in table 2, where the results of this cross are recorded. The
first column gives the results obtained when the female parent was hetero-
zygous. The second column gives the results obtained when the male

TABLE z

Types of keraels arisirtg front the cross.

C Sh 11*x rearranged chromosome 9
C sh WC normal chromosome 9   Xc sh i;`x normal chromosome 9

                 $? P.AREiVTHETEROZYGOLX       3 P,ARI'ST IIETEROZYGOT~S

Son-variegated kernels
      c                 4,532                 4.116
      c                      I                        8

Variegated kernels

c-c sh V'X                   16                  38
C-c Sh-sh iux                 `7                       22
C-c Sh-sh W'x-;ur               4                       6

Totals
Percentage variegated kernels

4,570                    4,190
0.8                      I.6
  ._

parent was heterozygous. This cross was designed to test the maximum
number of surviving broken chromosomes. Because some of the double
crossover chromatids in the C non-variegated class could not be detected,
classification of kernel types in the non-variegated classes have not been
included in the table. Kernels with the constitution c should arise only
following mutation of C to c, which is very rare, or following deletion of the
C gene from the broken chromosome before its deliverance to the endo-
sperm as a consequence of the breakage-fusion-bridge cycle. The one
c sh XIX kernel in the first column was diseased. It is possible that color did
not develop because of this disease. In the second column, six of the eight
c sh W'X kernels appeared on two of the I I ears examined. This strongly sug-
gests that they arose following contamination. Plants have not been
grown from these kernels to check the chromosome constitution.

The results of a similar cross which included yg are given in table 3. This
cross was designed to test for the presence of yg in the plants derived from
the various types of kernels. If the variegated kernels are the only ones
which have a broken chromosome, no yg should appear in plants arising
from the non-variegated kernels, either in the non-crossover classes or the
crossover classes. However, yg could appear in the plants derived from the


248                BARBARA McCLINTOCK
variegated kernels. NO yg plants appeared in more than 400 plants derived
from each of the two non-variegated, non-crossover classes. The three
plants derived from the non-variegated crossover kernels were likewise k'g.
Their chromosome 9 constitution showed that a double crossover chroma-
tid with a normal end had entered the endosperm and zygote nuclei. Sine

TABLEA

TYPES of kernels arising jrollt the CROSS.

E-g C 511 If-.x rearranged chromosome 9
IVg C sh w,x normal chromosome 9   0 Xyg c sh wx normal chromosome 93

--









__-

Son-variegated,
non-crossover kernels     Sumber of kernels
C Sh il'z              2,061
C sh ;elx              2,016

Son-variegated,
crossover kernels
c s/z X'X                    ?
C sh 1l.z                    I

Variegated kernels
c-c sh U'X                   3
C-c Sh-sh -xx                 8
c-c Sk-Sk H-x--xY               I

plants were obtained from the variegated kernels. Five of these were E'g
and four were yg. All nine plants carried a broken chromosome 9. The five
Yg plants possessed at least a complete chromosome 9. Each of the four
yg plants possessed a chromosome 9 deficient for a terminal segment of the
short arm which included the E'g locus.

   (d) The clzronzosonze 9 constitzrtion of plants arising from
            the ;laricgated kernels
In the prex-ious section, genetic evidence has been given which indicates
that variegation in the endosperm tissue is due to the presence in these
tissues of a chromosome 9 with a broken end. The variegation appears as
the consequence of the breakage-fusion-bridge cycle in successive nuclear
divisions. In contrast, the plants arisin, u from the variegated kernels, al-
though possessing a chromosome with a broken end, do not show variega-
tion. The broken end of the chromosome heals in the embryo nuclei and re-
mains permanently healed regardless of the tissue in which it may later be
present.

In this section it is desired to describe the types of broken chromosomes
which are present in the plants arising from the variegated kernels. In a
previous publication (MCCLINTOCK 1938b) it was shown that a chromo-


           STABILITY OF BROKEN CHROMOSOMES           249
some broken at a meiotic anaphase gave rise to a bridge configuration in
the following microgametophyte division as the result of the fusion at the
position of breakage of the two sister halves of the broken chromatid. If
this occurred in both the male and the female gametophytes, the broken
chromosomes delivered to the zygotes should include various types of de-
ficiencies and duplications (see fig. I), depending upon where the breaks
occurred in the anaphase bridge configurations in the successive gameto-
phyte divisions. If the broken end, produced as the result of a bridge con-
figuration in the last gametophyte division, healed in the zygote nucleus,
all the cells of the plant would show the same type of modified chromosome
9. The meiotic prophases in these plants would then reveal the constitution
of the broken chromosome 9 which each plant had received.
One hundred twentg-six plants arising from variegated kernels were ex-
amined at meiotic prophase for the constitution of the chromosome 9 de-
livered by the heterozygous parent. In I 20 of these plants, this chromosome
9 terminated in a broken end. In three plants the chromosome 9 delivered
by the heterozygous parent had undergone a secondary modification; two
involved a translocation between chromosome 9 and a second chromo-
some, and in the third plant the chromosome 9 was in the shape of a ring.
In the three remaining plants, heterofertilization had occurred. In each of
these three cases, sperms from two pollen grains had contributed to the de-
velopment of the kernel, a sperm from one pollen grain fusing with the po-
lar nuclei and a sperm from a second pollen grain fusing with the egg nu-
cleus. A normal, unbroken chromosome 9 carrying genes not corresponding
with those in the endosperm tissues was present in these plants. In maize,
hetero-fertilization may be expected in a low percentage of the cases
(SPRAGUE 1932). For comparison, 49 plants arising from the C Sk 1X non-
variegated kernels of table I were examined. All 49 plants had received the
rearranged chromosome 9 with an unbroken end (b, fig. 3) from the hetero-
zygous parent.
In 109 of the I 20 plants possessing a chromosome 9 with a broken end no
duplications were present of the type which could arise as a consequence of
the breakage-fusion-bridge cycle in the preceding gametophytic divisions.
AS illustrated in figure I, a chromosome with a broken end but possessing a
duplication or repeat duplications of terminal segments could be present in
these plants if the breaks in anaphase in the sucessive gametophytic divi-
sions (two in the male gametophyte, three in the female gametophyte) did
not occur at position of previous fusions-that is were non-median. To re-
cover such a duplication, it is likewise necessary that following such a non-
median break the longer segment be included in the telophase nucleus
which will give rise to a gamete (first telophase to left in fig. I instead of
first telophase to right). For descriptive purposes, therefore, the type of


2.50                 B.1RB.XR.A McCLINTOCK
recovered broken chromosome may be referred directly to the dicentric
chromatid (a, fig. 5) from which it originally arose. This chromatid is re-
produced in figure 8. In all cases except one (dash-line arrow, fig. 8) the re-
covered broken chromosome had the constitution to the right of the position

40        I

FIGURE X.-Types of broken chromosomes which were recovered in plants arising from varie-
gated kernels. In each plant, the type of recovered chromosome may be referred to the dicentric
chromatid illustrated here. The arrows and brackets give the positions of the broken ends. The re-
covered broken chromosome had the constitution to the right of the arrow (except for the dash-
line arrow) or to the right of any particular position within the bracket. In the case of the dash-
line arrow, the recovered broken chromosome had the constitution to the left of the arrow. The
numbers associated with the arrows or brackets indicate the number of plants which possessed
this particular broken chromosome constitution.

of breakage as indicated by the arrows or to the right of any particular posi-
tion within the brackets. The numbers placed above or below the arrows
and below the brackets give the number of individuals with the constitu-
tion indicated. In the one exceptional case, the recovered broken chromo-
some had the constitution to the left of the dash-arrow in figure 8. This
case is of particular interest and will be considered separately elsewhere in
this paper.

Thirty-two of these plants showed a broken chromosome 9 with a section
of the pycnotic region 6 extending beyond the small knob. In 40 plants, the
broken chromosome ended in a small knob, the last break having occurred
immediately to the left of the knob in most cases but through the knob in a
few cases. In I 7 plants, the chromosome was complete to the knob, but the
knob itself was missing. In 19 plants, the recovered broken chromosome
was deficient. The deficiencies ranged from loss of a single chromomere to
loss of the entire short arm. In the latter case, the broken end terminated in
the centromere.

Among the remaining II plants of the 120, the broken chromosome 9
possessed various types of duplicated segments arising in each case through
secondary fusions and breakages. The broken chromosome 9 in no two
plants was exactly alike, but for descriptive purposes the II plants may
be divided into five classes according to the composition of the broken
chromosome. In four of the five classes, the recovered broken chromo-
some showed evidence of only a single fusion and breakage following the
original break at a meiotic anaphase. In the fifth case, at least two fusions
and breaks followed the original meiotic break (type V, fig. 9). AS will be
shown later there appears to be a tendency for successive breaks to occur
at positions of previous fusions, indicating a weak fusion of sister chroma-


              STABILITY OF BROKEN CHROMOSOMES           2.51
tids following a break. A strong union is produced, however, following
many of the breaks. Therefore, although the breakage-fusion-bridge cycle
may have continued in all gametophyte divisions following the initial
break at meiotic anaphase, the recovery of many complicated duplications
                      II/

Type 1

cr-:---` =
   . . . . -.-..
      t TT

Type II   u-`----`--' x
         . . . . . . ___.
      T      T

Type III    :----------
         . . .._._.... I
          f T

Type IV    r--.-.-
        :. - . - . - .    d
         T

i  ~:::::-I::: 5
TYPO " +:::::::;:.      a

b

FIGURE o.-The types of recovered broken chromosomes in plants arising from variegated
kernels which demonstrate the breakage-fusion-bridge cycle. The dicentric chromatid from which
each recovered broken chromosome originated is given above. Although the position of the initial
break in this dicentric chromatid is not definitely known for each recovered broken chromosome,
for purposes of illustrating the chromatin constitution of the broken chromosome, the break which
preceded the final break in types I to IV and in a of type V may be referred to the dicentric chro-
matid (section of dicentric chromatid to right of arrows and bracket). This broken chromosome,
with its two halves fused at the position of previous breakage, is reproduced below for each type.
For types I to IV, the position of the final break is indicated by the arrows, one for each plant with-
in a type, the broken chromatid with the upper centromere being recovered in the zygote. In type
V, the recovered broken chromatid indicated that three successive breaks had occurred. The posi-
tion of the first break is indicated in the dicentric chromatid. The position of the second break is
indicated by the arrow in a, the chromatid with the upper centromere being in the line of descent.
The position of the third break is indicated by the arrow in b, the recovered chromosome having
the constitution of the broken chromatid with the upper centromere.

resulting from this process need not be anticipated. For illustrative pur-
poses, the origin of the various classes of broken chromosomes with du-
plicated segments may be referred to the original dicentric chromatid with
only one fusion and consequent break following the original meiotic break
in types I to IV, and two successive fusions and breaks in type V. In figure
9, the dicentric meiotic chromatid in which the first break occurred is dia-
grammed above, the region of the first break being indicated by the arrows
and the bracket for each of the five types. In all five types, the chromatid in
the line of descent is that to the right of the break. This chromatid with its


252                BARBAR. McCLIXTOCK
two split halves fused at the position of breakage is diagrammed below for
each type. The position of the second break is indicated by arrows, one for
each plant in a type class except for types I and II, where the second break
occurred close to the centromere in two cases in each of these two classes.
The chromatid with the upper centromere was recovered in each case and
represents the observed broken chromosome. Four plants were included in
type I, three in type II, and two in type III. There was only one plant in

TABLET

The broken chromosome 9 co~~stittrtion of plants derired from variegated kertrels. The symbol
( 0 ) or (8') placed beside the kernel type Adicates which parelzt xs heterozygous for tke rearranged
chromosome 9.

CHROMO- PYCNOTIC

KERNEL
CHARACTER

SOVE   EXTESSION  DUPLICA- SO KKOB, TERMISAL
              TION OF   SO DEFI-    DEFI-    OTHERS
ENDS    BEYOND  SHORT AR\1 CIENCY   CIENCY
IN KNOB    KNOB

Totals              40

33       IO

17       19     4*

* For description of these types. SW te\t

type IV. The recovered broken chromosome in this plant possessed a de-
ficiency of approximately one-fifth of the distal segment of the short arm
but possessccl a duplication of nearly all of the remaining proximal four-
fifths of the short arm. -As stated above, in type V the breakage-fusion-
bridge process is detected through one more cycle. The upper chromatid
was in the line of descent following each of the two successive breaks.

Although the breaks in the tlicentric chromatids may occur at any posi-
tion between the two centromcres the evidence from all IZO cases suggests
that there is a tendency for the breaks to occur at either side of the small
inner knob. In approximately half of the cases, the composition of the re-
covered broken chromosome indicated that a break had occurred to either
side of this knob (fig. 8). Similarly, in six of the II plants with duplicated
segments (fig. 9) one or more of the breaks must have occurred to one side
of the knob. In the chromosome represented in type V (fig. 9) both the sec-
ond and the third breaks must have occurred adjacent to the knob. The
results of these studies on the chromosome 9 constitution of plants arising
from variegated kernels are given in table 4 and are summarized in table 5.


          STABILITY OF BROKEN CHROMOSOMES          253
The tendency for successive breaks to occur at the positions of previous
fusions probably accounts for the relatively few cases of complicated dupli-
cations which otherwise would be expected to be present following repeated
fusions and breaks in the gametophyte divisions. Likewise, this tendency
should work toward increasing the correspondence in the genie constitution
of the broken chromosome in the endosperm and the plant tissues. The two
sperms (one for the endosperm tissues and one for the plant tissues) need

A summary of the various types of broken chromosomes 9 delivered to the zygote through the female
                and male gametophytes.

THROUGH                 THROUGH

                  FEMALE CAMETOPHYTE         MALE GlllETOPHYTE
TYPE OF BROKEN

CHROMOSOME

NUMBER OF
PLANTS

%

NCYBER OF    %
PLANTS

Chromosome ends in knob         24       30.7           16        35.5
Pycnotic extension beyond knob     24       30.7            9        20.0
Duplication of short arm           5       6.4           5        11.1
No knob, no deficiency            9        1I.j            8        17.7
Terminal deficiency             14       17.8           5        II .I
Others                      1        2.5            2         4.4

Totals                78                     45

not possess the same genie constitution with respect to the genes C Sh and
Wx. A decidedly non-median break in a bridge configuration at the division
of the generative nucleus could introduce a duplication of one or more genes
into one sperm nucleus and a deficiency of these genes in the sister sperm
nucleus. Following such a break, the genie constitution of the endosperm
and embryo tissues would not be the same. Similarly, this reasoning may
be applied to the embryo and endosperm tissues when the broken chromo-
some is introduced through the female gametophyte.

Among the examined plants the genie constitution of the broken chro-
mosome 9 in the plant tissues was determined in all cases and compared
with the genie constitution of the broken chromosome 9 delivered to the
endosperm of the kernel from which the plant arose. Excluding the three
cases of hetero-fertilization, as previously mentioned, correspondence was
obtained in all but two cases. In these two cases, the male was the hetero-
zygous parent; the endosperm and embryo nuclei differed in genie consti-
tution. In both cases, the chromosome 9 delivered to the endosperm pas-
sessed the genes C and Sh as shown by C-c and Sh-sh variegation. The
chromosome 9 in the plant tissues lacked both these genes because the


254                BARBARA McCLIh`TOCK
broken chromosome 9 was deficient for all of the short arm, in one case, and
nearly all of it in the second case.
It will be noted in the summary table (table 5) that the proportion of the
various types of recovered broken chromosomes are similar whether deliv-
ered through the sperm or the egg nucleus. It is known that deficiencies of
the extent observed in these studies are not transmitted through the pollen
when the tube nucleus possesses such a deficient chromosome. A deficient
broken chromosome was observed in five plants when the broken chromo-
some was delivered through the male parent. This deficiency must have
arisen through a non-median break in an anaphase bridge configuration
subsequent to the division which produced the tube nucleus.
A deficient broken chromosome was observed in 14 plants when the
broken chromosome was delivered through the female gametophyte. When
all the nuclei of a female gametophyte possess a short terminal deficiency of
chromosome 9, a functional embryo sac can develop. It is not certain,
therefore, whether the deficiency in the broken chromosome arose at meio-
sis or in a subsequent division. In two cases, the evidence suggests that the
deficiency may have arisen at the meiotic anaphase, for both the endo-
sperm and the plant nuclei were deficient for terminal segments of the short
arm of chromosome 9 which had deleted the same genes.
The long duplications observed in plants which have received their
broken chromosomes from the male parent have some theoretical interest.
All such duplications must arise in divisions subsequent to that which gave
rise to the initial break-that is, subsequent to the meiotic break. This sub-
sequent break must have occurred at a non-median position in an anaphase
bridge. If the long duplications originated in the first microspore division,
the generative nucleus would receive the duplication and the tube nucleus
would receive a highly deficient chromosome. Such a pollen grain would
not be expected to function unless the tube nucleus had received an acen-
tric fragment with a genie complement covering the deficiency. If the long
duplications originate in the division of the generative nucleus, the two
sperm nuclei would differ in constitution with regard to the genes C Sh and
WX. In the four cases of recovered long duplications, the detectible genie
constitution of the embryo and the endosperm were similar. This would
suggest that the duplication observed in these plants could have arisen dur-
ing the first division of the zygote as a consequence of an unequal break in
a bridge configuration. Since it is known that acentric fragments occasion-
ally are carried through several nuclear cycles before being lost to the tele-
phase nuclei, it is not possible to determine directly by this analysis
whether a bridge configuration actually occurred at the first zygotic ana-
phase. If a bridge configuration does occur at this division, healing of the
broken end must occur very shortly thereafter.


            ST.\BILITY OF BROKEN CHROMOSOMES          255
Mention should be made of the four plants arising from variegated ker-
nels whose chromosome 9 constitution was unexpected (see table 4). One of
these cases is of particular interest. As stated above, all but one of the re-
covered broken chromosomes arising from the original dicentric chroma-
tid, possessed the broken segment to the right of the arrow or bracket in
figure 9. However, one broken chromosome possessed the segment of the di-
centric chromatid to the left of the dash-line arrow in figure 8. This broken
chromosome, introduced by the male parent, is deficient for a large section
of chromosome 9. It is known that a pollen grain, all of whose nuclei carry
such a deficient chromosome, does not develop normally and does not pro-
duce a functional grain. It is highly probable that the acentric fragment,
produced during the formation of the dicentric chromatid, was included in
the microspore nucleus and again included in the tube nucleus following the
first microspore division (MCCLI~~TOCK r938b). This acentric fragment
could possess the genie material which is absent in the broken chromosome.
A pollen grain with such a tube nucleus, possessing at least a complete com-
plement of genes of chromosome 9, could develop normally and function in
the delivery of two deficient sperms to the endosperm and zygote nuclei,
respectively.
The genes C Sh and 1%`~ were carried by this broken chromosome 9 (fig.
IO). The normal chromosome 9 in this plant carried the recessive alleles,
c s/z and UX. (The observed order of loss of the dominant genes in the vari-


         0            C Sh WI
                       . . . . . ---.-I
            Q x
                `-.;.;h.' -;;.    J
                                  a

                        C Sh VI
                       mm. _ . . . . . . .
           `:.
                             b
FKCRE ho.-a. Homologous associations of segments I to 4 of a broken chromosome (left of
dash-line arrow, figure 8) and a normal chrorrosome. The genie constitution of each chromosome
in indicated. A crossover, as indicated, would give rise to the dicentric chromatid shown in b.
egated endosperm of the kernel from which this plant arose was WX, fol-
lowed by Sh, followed by C. This is expected on the assumption of the
breakage-fusion-bridge cycle, since the gene nearest the broken end (Wx)
would be lost before the gene nearest the centromere (C) .) Functional gam-
etes carrying the dominant genes can be produced by this plant only fol-
lowing crossing over. All single crossovers in regions indicated by homolo-
gous associations in a (fig. IO) will give rise to dicentric chromatids (b, fig.
10) similar in constitution to that of a in figure 5. This dicentric chromatid
is broken at anaphase I. Consequently, following such a crossover, all chro-
mosomes with dominant genes must possess a broken end. In the cross of
this plant with one homozygous for c sh and -UX, these broken chromosomes


256                 Br\RRr\R,I McCLINTOCK
should give rise to kernels with variegated endosperms. Unfortunately, at
the time this plant was ready for pollination, no plants homozygous for
c sh and wx were available. Consequently, it was selfed. Pollen from this
plant was also placed on silks of plants of the constitution C c. Among the
54 kernels obtained from the self, 12 showed the presence of the dominant
gene C. The endosperms of all 12 kernels were variegated for C and c.
(2 C-c sh wx: 8 C-c Sh-sh WX: 2 C-c Sh-sh W'x-wx). The remaining 44 ker-
nels were completely recessive for all three endosperm genes.
The cross onto the heterozygous plant (C c) gave 1070 C non-variegated
to 859 c to 133 C-c variegated kernels. The contribution from the female
parent would lead to a I : I ratio of C non-variegated to G. Any distortion of
this ratio would depend upon the C contribution of the male parent. Since
variegation for C-c produced by the presence of a broken chromosome 9
carrying C and introduced by the male parent, can express itself only fol-
lowing union with c carrying nuclei contributed by the female parent, this
class of 133 kernels may be added to the 859 c kernels to obtain the mini-
mum number of c carrying gametophytes produced by the female parent.
The resulting ratio of 1070 to 992 is close to the I C: I c ratio which the fe-
male parent alone should contribute. The distortion in favor of the C-non-
variegated class could be accounted for by the functioning of C-carrying
gametes whose chromosome 9 possessed a normal end following a double
crossover, In the material available, this class could not be detected. Nev-
ertheless, the results of these two crosses are of significance in confirming
the relationship between broken chromosomes and variegated endosperms.
The second plant of the four arising from the variegated kernels whose
chromosome 9 constitution was unpredicted possessed a segment of chro-
mosome 9 in the shape of a ring. This ring carried the genes C and Sh but
not WX. The variegation for C-c and Sh-sh in the kernel from which this
plant arose was probably related to the aberrant mitotic behavior of the
ring-shaped chromosome (MCCLINTOCK r938a). The origin of this ring
chromosome was not determined.
The third plant possessed a translocation between the short arm of chro-
mosome 9 and chromosome 8. The meiotic prophase figures were too poor
to allow an analysis of this translocation.
The fourth plant had a complete chromosome 9 with the addition of a
segment of chromatin of undetermined origin extending beyond the end of
the short arm. The extra segment did not represent a duplication of part of
the short arm of chromosome 9.
With the exception of the three cases of heterofertilization and the three
cases just mentioned, all the other plants examined (I 20) showed the pres-
ence of a broken chromosome 9 in the plants derived from kernels with
variegated endosperms. In 38 cases, the composition of the broken chromo-


             STrlBILITY OF BROKEN CHROMOSOMES          257
some clearly indicated that it had arisen from the dicentric chromatid
diagrammed in a, of figure j (arrows to the left of the small knob, fig. 8;
dashline arrow, fig. 8; types I and V, fig. 9). All other cases could readily be
derived from this dicentric chromatid as illustrated in figures 8 and 9.
That the variegation is the result of the breakage-fusion-bridge cycle is
strongly supported by the types of recovered chromosomes illustrated in
figure 9. It is not understood why this process is limited to the gametophyte
and endosperm and does not continue in the embyro tissues. In all cases,
the broken end of chromosome 9 healed in the embryo tissues. This is a per-
manent healing, for when this chromosome is again introduced into endo-
sperm tissues in successive generations, it causes no variegation. When two
such chromosomes are brought together in a single plant after each has
passed through a sporophytic generation, no fusions occur between the
broken ends. If the broken chromosome has a full set of genes or in addition
a pycnotic extension composed of region 6, its behavior and transmissions
through successive generations are comparable in every way to a normal,
unbroken chromosome 9 (see f of this section),

   (e) The chromosome 9 constitution of plants arising from the
          non-aariegated crosso'der kernels
Earlier in this paper the assumption was made that the non-variegated
kernels in a crossover class (tables I and 3) had received a non-broken
chromosome 9 from the heterozygous parent as the consequence of a double
crossover. Because no broken end was present, no variegation should be ex-
pected. In the classes C sh Wx, c Sh Wx, C Sh WX, and c sk Wx, the broken
chromosome 9 derived from a double crossover chromatid could be either
the normal chromosome 9 or the rearranged chromosome 9, depending up
on where the two crossovers had occurred. The chromosome 9 constitu-
tion of jo plants arising from the non-variegated crossover kernels are
summarized in table 6. In 44 individuals, the chromosome 9 constitution
was as expected-that is, the plant possessed either a normal chromosome
9 or a rearranged chromosome 9. Among the six individuals with excep-
tional constitutions, four arose following heterofertilization and conse-
quently must be eliminated from consideration. In one of the two remaining
exceptional individuals, a segment of the end of the long arm of chromo-
some 4 had been translocated to the end of the short arm of chromosome 9.
The origin of this modified chromosome is not understood. The other ex-
ceptional individual showed a chromosome 9 with the same constitution as
the dicentric chromatid in a, of figure 5, except that the left ccntromcre was
deleted. It is possible that this centromere was torn from the dicentric chro-
matid during anaphase I, the broken ends fusing on each side of the tear to
give rise to the observed chromosome.


258                 BARBARA McCLINTOCK
Genetic tests were conducted with some of these plants to verify the
cytological determination of the presence of a double crossover chromo-
some. Plants of the constitution Yg C Sh Wx rearranged chromosome
9/yg c sh wx normal chromosome 9 were crossed by plants of the constitu-
tion Yg c sh wx normal chromosome 9. Since the locus of yg is almost im-
mediately adjacent to the terminal knob in the normal chromosome 9

TABLE 6

Type of chromosome 9, deliaered by the helerozygozls parent, in plants arising from the non-Darie-
gated crossover kernels. The symbol ( 0 ) or (3) placed beside the kernel type indicates the heterozygous
parent.

                    NORMAL         REARRANGED
KERKEL CHARACTER     CHROMOSONE 9     CHROMOSOME $I

OTHERS

CShwx (0)
C Sh wz (3')
c sh W"z ( 0 )
c sh Wz (8')
Cshwx(O)
C sh wx (8')
cShWx(`?)
c Sh W'x (3)

Totals               25              19             6

5               6
8               4
6               2

3              5
1               0
I               0
0               1
I               0

21
1+
0
I*
0
I*
0
0

* Endosperm and embryo chromosome constitution not alike due to hetero-fertilization.
t See test for description of chromosome 9 in these two plants.

(CREIGHTON 1934, MCCLINTOCK unpublished), crossovers between yg and
the knob are infrequent. If the kernels in the non-variegated crossover
classes possessed a chromosome derived from a double crossover chro-
matid, all the plants arising from these kernels which have a n&ma1
chromosome 9 should be heterozygous for yellow-green (Yg yg). Those
possessing a rearranged chromosome 9 should be homozygous dominant
(Yg Yg). These tests were conducted with nine plants carrying a normal
chromosome 9 and four plants carrying a rearranged chromosome 9. The
results conformed with expectancy.

  (f) The genetical and cytological behavior of the broken chromo-
    somes in successive generations. Further proof that varie-
     gation follows the introduction of a recently broken
        chromosome into the endosperm tissues
To test whether the broken chromosomes, summarized in table 5, would
induce variegation in the endosperm tissues of the next succeeding genera-
tion, plants in all the categories of table j were either selfed or crossed by
those containing two normal chromosomes 9 carrying c. In all of these tests


           STABILITY OF BROKEN CHROMOSOMES          259
the broken chromosome carried C, its normal homologue, c. In the first cat-
egory of plants in table 5,--that is plants whose broken chromosome ended
in a knob,-the selfing of 28 plants gave rise to 6,142 C non-variegated ker-
nels, 2,048 G kernels, and 3 that were variegated for C and c. Two plants
were crossed by plants homozygous for c. There resulted 242 C non-varie-
gated kernels, 249 c kernels, and no variegated kernels. The variegation in
the three kernels appearing in the selfed progenies need not be related to
the behavior of the original broken end of chromosome 9. A small percent-
age of such kernels have been noted in many genetic crosses in maize
produced through causes the exact nature of which cannot be easily ascer-
tained. Thus, the behavior in successive generations of this broken chro-
mosome in column I of table 5 is comparable in every way to a normal
chromosome 9 with a normal end.
Eighteen plants in the second category of table 5 were selfed. These
plants possessed a duplication of the pycnotic region 6 of chromosome 9
extending beyond the small knob. The selfing of these eighteen plants
gave rise to 4,209 C non-variegated kernels, 1,566 c kernels, and no varie-
gated kernels. In no individual case was there a marked deviation from a
3 : I ratio, although in the total counts there is a slight deviation in favor of
the c class. This is probably due to a slight selection against the pollen
grains carrying the chromosome 9 with the pycnotic extension. The back-
cross ratios likewise suggest this. Pollen carrying c was placed on the silks
of seven of these plants. There resulted 1,532 C non-variegated kernels,
1,565 c kernels, and one C-c variegated kernel. When pollen of two of
these plants was placed on the silks of seven plants homozygous for c,
there resulted 1,087 C non-variegated kernels, 1,200 c kernels, and no varie-
gated kernels. A lack of variegated kernels in the progeny of this second
category of plants likewise shows the stability of the broken end following
its healing in the embryo of the parent plant. Similar tests were carried out
with plants in the fourth category, those whose broken chromosome had
no knob but likewise no observable deficiency. The selfing of eight plants
produced 1,818 C non-variegated kernels, 605 c kernels, and no variegated
kernels. Only one plant was crossed by c. This resulted in I I 2 C non-varie-
gated kernels, 139 c kernels, and no variegated kernels. Pollen of two plants
in this category was placed on silks of c-carrying plants. There resulted 904
C non-variegated kernels, 883 c kernels, and no variegated kernels. Com-
plete healing of the broken end likewise occurred in these plants. These
chromosomes, although deficient for the knob, behaved strictly as a normal
chromosome 9.
The broken end in plants of the fifth category likewise showed a perma-
nent healing. Since the transmissions of the deficient chromosomes is de-
pendent upon the extent of the deficiency, no ratios will be given here.


260                 BARBARA McCLINTOCK
The plants in the third category, those whose broken chromosome pos-
sessed a duplication of the short arm of chromosome 9, gave entirely dif-
ferent results. Many variegated kernels resulted from the selfing and back-
crossing of these plants. It will be shown that this is not due to the insta-
bility of the original broken end but to the production at meiosis in these
plants of chromosomes 9 with new broken ends. These new broken ends are
the cause of the variegation in the endosperms of the progeny. These new
broken chromosomes become stable in the embryos of these variegated
kernels and remain stable from then on. Although the number of variegated
kernels arising from a self or a backcross of a plant carrying a duplication
depends upon the particular duplication that is present, a summary of the
results from crosses involving all the duplications is illuminating. The prog-
eny from selfing eight plants carrying duplications gave I ,05 2 C non-varie-
gated kernels, 841 c kernels, and 152 C-c variegated kernels. When the fe-
male parent carried the duplication, the backcross gave 397 C non-
variegated kernels, 450 c kernels, and 29 C-c variegated kernels. When
these plants were used as pollen parents, the backcross gave 179 C non-
variegated kernels, 641 c kernels, and 49 C-c variegated kernels. Since pol-
len grains carrying the duplication do not function readily in competition
with those carrying a normal chromosome 9, a deficiency of the C class is to
be expected in the selfed and male backcross progenies. Among a total of
3,789 kernels resulting from these crosses, 230 were variegated for C-c. The
variegation was of the type which would be produced by a broken chromo-
some. This presents an extreme contrast to the results recorded from the
previous classes where four C-c variegated kernels appeared in a total of
24,305 kernels.
A chromosome 9 with a duplication of all or of only a part of the short
arm, such as that illustrated in figure 9, can give rise to new broken chro-
mosomes following crossing over. The method by which crossing over can
give rise to broken chromosomes is illustrated in figure II. In this illustra-
tion the plant is considered to be heterozygous for a duplication of the short
arm of chromosome 9. In the diagram, the end of the short arm of the nor-
mal chromosome 9 terminated in a large knob. No knob has been dia-
grammed in the duplication chromosome. This constitution has been
chosen, since it will apply to all the duplications which will be discussed in
sections 4 and 5 of this paper. At meiosis, association of the three homolo-
gous segments of the two chromosomes 9 is 2-by-z. Two of these associations
are diagrammed (a and b, fig. II). In a, the duplicated segment is asso-
ciated with the short arm of the normal chromosome 9. A crossover as in-
dicated would give rise to a dicentric chromatid (c, fig. I I). This dicentric
chromatid is the equivalent of two chromosomes 9 fused at the ends of their
short arms, In b (fig. II), the two homologous segments in the duplicated


             STABILITY OF BROKEN CHROMOSOMES           261
chromosome 9 are associated. A crossover as indicated would result in the
same dicentric chromatid (c, fig. II). Disjunction of homologous cen-
tromeres in anaphase I would result in a first division bridge configuration
following the crossover in a. Separation of sister centromeres in anaphase
II would give rise to a second division bridge configuration following the
crossover in b. In the late anaphase or early telophase of these cells, the di-
centric chromatid is broken at some position between the two centromeres.
If the break occurred at the position of the arrow (c, fig. I I), each of the
two broken chromatids would contain a complete set of genes of chromo-
some 9. If the break occurred at any other position, a deficient chromatid
would enter one nucleus and a chromatid with a duplication would enter
the sister nucleus. In this way, chromosomes 9 could be produced with var-
ious lengths of duplication and deficiencies of segments of the short arm.

        
c

FIGURE I I .-a. Diagram of a meiotic prophase association of a normal chromosome 9 with a
large terminal knob and a chromosome 9 with a duplication of the short arm but with no knob.
The duplicated segment is homologously associated with the short arm of the normal chromosome
9. A crossover as indicated produces a chromatid composed of two attached chromosomes 9, as
shown in c. This will produce a bridge configuration at anaphase I. b. Association of homologous re-
gions of the duplication chromosome 9. A crossover as indicated will gix-e rise to the dicentric
chromatid shown in c. A bridge configuration will result in anaphase II.

However, each would possess a newly broken end. Each, therefore, should
be capable of inducing variegation in the endosperm tissues to which it is
delivered, provided the appropriate genie markers are present to allow de-
tection of variegation. Plants arising from these variegated kernels should
show a new series of various types of broken chromosomes 9. All plants
with duplications of the type illustrated in figure 9 were heterozygous-
that is, contained a duplication chromosome 9 with dominant genes in the
duplicated segments and a normal chromosome 9 carrying the recessive
alleles. In deriving the constitution of the dicentric chromosome produced
following crossing over, it is necessary to insert the knobs and pycnotic re-
gions where they occur in each of the duplicated chromosomes.

Meiotic anaphases were observed in all plants heterozygous for duplica-
tions. All showed bridge configurations in some of the anaphase I and II
cells. The total percentages and proportions of bridges in the two divisions
were not the same and should not be the same for all duplications. A sum-
mary of meiotic behavior and the types of progeny will be confined to a


262                B.IRB.IRA McCLINTOCK
single case, that of duplication 1276-1 (arrow to right in type I, fig. 9). In
this plant, 189 microsporocytes in anaphase I were recorded. Nineteen, or
ten percent of these showed a bridge configuration. In the second division,
recordings were made only when the two sister cells were in mid-anaphase.
Among 144 such dyads, 38 or 26 percent showed a bridge configuration in
one of the cells of the dyad. This plant was selfed and produced I 26 C non-
variegated kernels, 97 c kernels, and 13 C-c variegated kernels. At the time

FIGURE rz.-Chromatin constitution of the dicentric chromatid produced by crossing over in
plant 1276-1. The constitution of the recovered broken chromosome in plants arising from the
variegated kernels may be referred to this dicentric chromatid. The recovered broken chromo-
somes have the constitutions to the right of the arrows and to the right of positions within the
bracket, The numbers given above or below indicate the number of plants in which the broken
chromosome had this particular constitution.

of pollination there were no homozygous c plants to which it could be
crossed. Consequently, it was crossed to a normal plant of the constitution
C c. This cross produced 187 C non-variegated kernels, 144 c kernels, and 18
C-c variegated kernels.

The chromosome 9 constitution was determined in 14 plants arising from
the C non-aariegated kernels of the self of 1276-1. Thirteen of these plants
possessed a normal chromosome 9 and a chromosome 9 with the duplica-
tion-that is, had the same constitution as the parent. One plant possessed
two normal chromosomes 9, the result of a crossover between the short arm
of the normal chromosome 9 and the proximal homologous segment of the
duplicated chromosome 9. Cytological determination of the chromosome 9
constitution of eight plants arising from variegated kernels of the self and
of nine plants arising from the variegated kernels of the outcross were il-
luminating. All 17 plants possessed a newly broken chromosome 9. In eight
of these plants, derivation from the dicentric chromatid produced by cross-
ing over of the type illustrated in figure I I was unmistakable. Tn the parent
plant, 1276-1, a short segment of pycnotic region 6 was inserted between
the two knobs and thus between the proximal and distal duplicated seg-
ments of the short arm (see arrow to right, type I, fig. 9). A crossover as
diagrammed in a or b of tigure II would give rise to a dicentric chromatid
with the constitution shown in figure 12. All the newly produced broken
chromosomes 9 showing a pycnotic segment extending beyond the knob
may be traced to this dicentric chromatid. For illustrative purposes, the
chromosome constitution of 16 of the 17 plants arising from variegated ker-
nels may be referred to this dicentric chromatid (fig. 12). The arrows indi-


           STABILITY OF BROKEN CHROMOSOMES        263
cate the positions of breakage; the numbers above or below the arrows
indicate the number of plants whose broken chromosome 9 constitution
corresponded to that part of the dicentric chromatid to the right of the
arrow. A new duplication, derived from secondary fusions and breaks, was
present in one plant. Its constitution is shown in c, figure 13. The method of
deriving the origin from the dicentric chromatid (a and b, fig. 13) is the
same as that used in figure 9.

8 . .._..__...
, . . . . . . . . .    -
   b t

FIGURE IS.-Illustration of the origin of a new duplication chromosome 9 from duplication
1276-1 as a consequence of the breakage-fusion-bridge cycle. a. Dicentric chromatid produced
following a crossover in plant 1276-1 (heterozygous for a duplication shown in type I, figure 9).
The arrow indicates the position of the first break, the broken chromatid to the right being in the
line of descent. b. The two split halves of the broken chromatid fused at the position of previ-
ous breakage. The arrow indicates the position of the second recognizable break which gave rise
to the recovered broken chromosome with a new duplication shown in c.

The stability of these newly broken chromosomes following their passage
through a sporophytic generation is indicated by kernel characters obtained
from selfing seven of the plants whose broken chromosome ended either in
a knob or in a short pycnotic segment extending beyond the knob. There
were 1,385 C non-variegated kernels, 456 c kernels, and no variegated ker-
nels. The ratio obtained from selfing the plant with the newly derived long
duplication, illustrated in figure 13, gave 104 C non-variegated kernels, 80
c kernels, and 26 C-c variegated kernels. These variegated kernels were ex-
pected, for the process of forming new broken chromosomes at meiosis is
the same in this plant as it was in the parent plant with the original dupli-
cation. The selfed ear from the plant with the short duplication (left-most
arrow in fig. 12) was badly diseased. However, pollen of this plant placed
upon silks of a Cc plant with two normal chromosomes 9 gave 98 C non-
variegated kernels, 68 c kernels, and three C-c variegated kernels. From
this plant, likewise, variegated kernels should appear and do appear in the
progeny.

Although the original duplicated chromosome in plant 1276-1 carried C
in each of the homologous segments, it is not certain that this genie consti-
tution will be preserved when this chromosome is passed on to the next
generation. Following crossing over at meiosis in plant 1276-1, the c gene
carried by the normal homologue, could have been inserted into one of the


264                  BARB.%R.% McCLINTOCK
duplicated segments. As stated above, 13 of the 14 examined plants derived
from the C non-variegated kernels of the self of 1276-1 possessed the origi-
nal duplicated chromosome 9 and a normal chromosome 9. Regardless of
crossing over, a C gene must be present in at least one of the homologous
segments of the duplication. Consequently, variegated kernels should ap-
pear in the progeny of these plants following appropriate crosses because
newly broken chromosomes should be produced during meiosis in these
plants in exactly the same manner as occurred in the parent plant. The re-
sults of crosses involving these plants are summarized in table 7. It is ob-
vious from this table that variegated kernels do appear. The plants arising
from these variegated kernels should show, in turn, newly derived broken
chromosomes.

TABLE 7

Churacter of kerrrels in the progeny ojcrosse~ iaoo&ns a duplicatim offhe short arm of
          ckron~osonte 9 deriuedfrom plant 1276-r.

                    c                 C-C
                                c
(`ROSS              NOS-VARIEGATED            VARIEGATED
                              KERSELS
                    KERNELS               KERP;EIS

Duplication chromosome 9 carrying Co xc~
Sormal chromosome 9 carrying c

                    16
192         242

   Reciprocal
Duplication chromosome 9 carrying C
Xormal chromosome           seifed
             9 carrying c

From the numerous examples so far presented in this paper, there can be
little doubt that lrariegation in the endosperm tissues is correlated with the
presence of a chromosome with a broken end. Furthermore, if the constitu-
tion of chromosome 9 in a plant is known, it is possible to predict whether
or not variegated kernels will appear in the progeny. ,411 predictions have
been completely verified.

IV. THE CORREL.kTION OF VARIEGATION AND BROKEN CHRO-

  MOSOMES Ih- THE PROGENY OF A XATURALLY ARISING

DC-PLICATION IN CHROMOSONE 9

Before the investigations described in section III of this paper had been
undertaken, studies were underway on a chromosome 9 possessing a dupli-
cation of the short arm. Cultures containing this chromosome gave rela-
tively high percentages of variegated kernels in their progeny. The origin
of this duplication was unknown. It was discovered in a genetic strain of
maize belonging to DR. L. J. STADLER. The author is indebted to DR.
STADLER for use of this duplication in the study now reported. The consti-


             STABILITY OF BROKEI\; CHROMOSOMES        26s
tution of the duplicated chromosome 9 is essentially similar to the dupli-
cated chromosome 9 illustrated in type III of figure 9. The duplication
included practically all of the short arm of chromosome 9. Ko knob was
present. This duplicated chromosome carried the genes I and Wr in the
two homologous segments. 1, an inhibitor of aleurone color development, is
placed at the same locus as the gene C (HUTCHISON 1922). The color pat-
tern of variegation induced by broken chromosomes derived from this du-
plicated chromosome is the reverse of that described in section III, for loss
of the I gene from cells of the aleurone allows color (j) to appear in these
cells.

Since the origin of the broken chromosome at meiosis in plants heterozy-
gous for this duplication is exactly the same as that described in the previ-

TABLE 8

I 11+x duplication chromosome 9
i x1.r normal chromosome 9   -Xi ~~I normal chromosome 0

P Parent heterozygous   438       0      23      445        Ii       cl
c7 Parent heterozygous     62       0      29     765        27       3

ous section, the evidence obtained from this duplicated chromosome will be
but briefly reviewed.

In plants heterozygous for the duplicated chromosome 9,-that is, pos-
sessing one duplicated chromosome 9 and a normal chromosome 9,-bridge
configurations are seen in both the first and second meiotic mitoses. Of the
193 anaphase I cells recorded, 26 or 13.4 percent showed a bridge configu-
ration. Among 74 dyads in anaphase II, IO or 13.5 percent showed a bridge
configuration in one of the cells of the dyad.

In these plants, the duplication chromosome 9 carried I and U'X in each
of the duplicated segments. No knobs were present in the duplication
chromosome 9. The normal homologue carried i and WY. Its short arm ter-
minated in a large knob. The chromosome 9 constitution of these plants
was similar to that shown in figure II. Following crossing over as dia-
grammed in figure I I, the order of the genes between the two centromeres of
the dicentric chromatid could be Wx I i WX, W'x: 1 I XIX, or WX I I WX.
Following breakage of the dicentric chromosome at a meiotic anaphase,
broken chromosomes with various genie compositions should arise. Those
possessing I IYx or 1 XX, either singly or in duplication, should produce
variegation for color if delivered to an endosperm following the cross of this
plant to one possessing two normal chromosomes 9 carrying i wx.


266                 BARB.4RA IvIcCLINTOCK
The results of such a cross are given in table 8. In the first line of the

table, the female was the heterozygous parent. In the second line, the male
was the heterozygous parent. The low frequency of the I Wx non-varie-
gated class in this latter cross is due to the low transmission through the
pollen of the chromosome carrying the duplication. Six plants derived from
the I JVX non-variegated kernels in this latter cross were examined cytolog-
ically. Five plants showed the presence of the duplication chromosome 9;
one plant possessed two normal chromosomes 9, the short arms of each
terminating in a large knob. Since the normal chromosome 9 in all the plant
of this study possessed a large terminal knob, the chromosome with I WX
in this latter plant obviously arose through a crossover between the normal
chromosome 9 and the proximal segment of the duplication chromosome 9.
The chromosome 9 constitutions were determined in 26 plants derived
from the 1 WX non-variegated class of the first line of table 8. All 26 pos-
sessed the duplicated chromosome 9 and a normal chromosome 9 terminat-
ing in a large knob.

The chromosome 9 constitution has been determined for 28 plants de-
rived from the variegated kernels of table 8. A broken chromosome 9 was
present in each plant. For illustrative purposes, the type of recovered

FICCRE x4.-Types of recovered broken chromosomes in plants arising from variegated ker-
nels. The parental chromosome constitution of the heterozygousparent was exactlyas diaprammed
in figure I I, The dicentric chromatid produced following crossing over is shown in a and b. The
constitution of the recovered broken chromosome is that to the right of the arrow in each case.
The numbers above or below the arrows indicate the number of plants with this particular broken
chromosome. In a, the female parent contributed the broken chromosome. In b, the male parent
contributed the broken chromosome.

broken chromosome may be referred to the original dicentric chromatid
from which it arose (fig. 14). The broken chromosome in seven of these
plants was introduced by the female parent (variegated kernels in line I
table 8). The broken chromosomes in the remaining 21 plants were intro-
duced by the male parent (variegated kernels in line 2, table 8). Since the
proportion of types of recovered broken chromosomes are not comparable
in the two crosses, the types received from the female parent are shown in
a (fig. 14), those received from the male parent in b (fig. 14). The composi-
tion of the broken chromosome is that to the right of the arrow in each case.
The numbers above or below each arrow indicate the number of plants


           STABILITY OF BROKEN CHROMOSOMES         267
with this particular broken chromosome. Totalling both crosses, 14 of the
plants possessed a duplicated segment. These varied in length from a single
chromomere in one plant to the full short arm in three plants. There was
only one plant with a deficiency (b, fig. 14), but this deficiency included
all of the short arm. The remaining 13 plants had a complete chromosome
9 with neither a duplication nor a deficiency. Twelve of these were intro-
duced by the male parent. In these plants, the broken chromosome 9 could
readily be distinguished from the normal chromosome 9, since the former
possessed no knob whereas the short arm of the latter terminated in a large
knob.

The duplications derived from the rearranged chromosome 9, described
in f of section III, could be explained only as the result of successive fu-
sions and breaks, as shown in figure 9. However, it could not be determined

A Sormal chromosome 9 carrying I
Sormal chromosome 9 carrying i Xnormal chromosome 9 carrying i

   TYPE OF CROSS


0 parent heterozygous
a* parent heterozygous

  NON-VARIEG.lTED       V,ARIEG.lTED
     KERNELS           KERSELS
I          i          I-i

3,974        3,153          I

2,213       2,129          I

B. Broken chromosome carrying 1, no duplication or deficiencv
Normal chromosome 9 carrying i         -2--Xnormalchromosome 9 carrying i

   TYPE OF CROSS


0 parent heterozygous
c? parent heterozygous

  SON-VARIEGATED        V.ARIEG.ATED
    KERNELS            KERNELS
I           i          I-i

I,46i        1,419          I
3,008        3,011          I

c, Sex duplication chromosomes gcarrying I
Normal chromosome 9 carrying i     Xnormal chromosome 9 carrying i

                      X0X-\-ARIEGATED        ,`.ARIEG.ITED
   TYPE OF CROSS             KERNELS            KERNELS
                    I          i          I-i

0 parent heterozygous     1,822        2,107         49
3 parent heterozygous        22        164         4

in some cases and was not determined in others whether the duplications
illustrated in figure 14 arose directly from the dicentric chromatid or fol-
lowing subsequent fusions and breaks. Distinctive morphological markers
such as knobs and pycnotic extensions, illustrated in figure 9, could not be
present in these duplications. The presence of small extra segments in-
serted between the two main duplicated segments could be identified only
with considerable difficulty and was not attempted. However, successive


265                  B.\RB.`.R.\ McCLINTOCK
fusions and breaks must have preceded the formation of the deficient chro-
mosome in b of figure 14 (for discussion, see section III d).

At this point, attention should be called to the contrast in the types of
broken chromosomes delivered by the sperm and the egg. Most of those de-
livered by the female gamete have duplications. The majority of those com-
ing from the male parent are without duplication or possess only a very
small duplication. A discussion of the possible significance of this will be
postponed until more cases have been considered.

Healing of the broken end in the embryo should result in stability of the
broken chromosome in successive generations. The broken chromosomes
with no duplication or deficiency should behave as a normal chromosome 9.
On the other hand, the broken chromosomes with newly derived duplica-
tions should give rise to variegated kernels following crossovers similar to
those diagrammed in figure I I. The kernel characters obtained from cross-
ing these various plants by those containing normal chromosomes 9 with i
in each homologue are given in table 9. A, table 9, represents a control cross
the heterozygous parent possessing two normal, unbroken chromosomes 9.
In B, table 9, the I carrying chromosome possessed a broken end, but no
duplication or deficiency was present. In C, table 9, the chromosomes carry-
ing Z possessed the newly derived duplications of figure 14. The results are
as expected and require no further explanation.

V. THE CORRELATION OF VARIEGATION AND BROKEN

CHROUOSOMES IN THE PROGENY OF A SHORT DUPLI-

CATION DERIVED FROM A LONG DUPLICATION

All the newly derived duplications illustrated in figure 14 gave rise to
variegated kernels in their progeny. Plants arising from these variegated
kernels should have a newly broken chromosome. This has proved to be
true. However, extensive tests were conducted with only one of these du-
plications, the short duplication composed of a fifth of the short arm (third
arrow from left, b, fig. 14). The plant possessing this short duplication car-
ried Z in the duplicated chromosome and i in the normal homologue. When
pollen carrying a normal chromosome 9 with i was placed upon silks of this
plant, there resulted 139 I non-variegated kernels, 188 i kernels, and two
Z-i variegated kernels. When pollen of this plant was placed on the silks of
a normal plant carrying i, there resulted seven Z non-variegated kernels, 92
i kern&, and three Z-i variegated kernels. Twenty-one plants derived from
the Z nou-xzriegakd kernels in the former cross were examined for the con-
stitution of the chromosome 9 delivered by the female parent. The short
duplication was present in 20 of these plants. In one plant, two normal
chromosomes 9, each terminating in a large knob, were present-obviously
the result of a crossover which inserted Z into the normal chromosome 9 of


            STABILITY OF BROKEN CHROMOSOMES        2%
the female parent. Plants derived from the seven 1 non-oariegaled kernels in
the latter cross were likewise examined. Five of these had received the short
duplication chromosome 9, and two had received a normal chromosome 9-
the consequence of a crossover in the parent plant.
The formation of dicentric chromatids at meiosis has been assumed
to be the means of producing the broken chromosomes which give rise to
variegation. The method of origin of the dicentric chromatids is the same as
that diagrammed in figure I I. To verify this, meiotic anaphases were ex-
amined in plants heterozygous for the short duplication. Among 231 ana-
phase I configurations recorded, 20 or 8.6 percent showed a bridge con-
figuration. At anaphase II, rjo dyads were recorded. Eleven or 7.3 per-
cent showed a bridge configuration in one of the cells of the dyad. Plants
derived from the I Wx non-variegated kernels in the crosses given above
which were heterozygous for the duplication (carrying I in the duplicated
chromosome and i in the normal chromosome) were crossed with plants
possessing two normal chromosomes 9 each carrying i. The results are
shown in table IO. These crosses produced a total of I j I variegated kernels.

                    TABLE IO

         Types of kernels res&ing from the cross.
Short duplication chromosome 9 carrying I
Normal chromosome Q carrying i     Xnormal chromosome 9 carrying i

  TYPE OF CROSS



0 parent heterozygous
3 parent heterozygous

  NON-VARIEGATED          VARIEGATED
     KERNELS              KERXELS
I            i           I-i


6,684       6,774          106
698       3,081           45

In contrast, the three examined F1 plants with two normal chromosomes 9,
which were derived from the 1 WJC non-variegated kernels, produce no
variegated kernels following similar crosses.

A cytological determination was made of the chromosome 9 constitution
of 15 plants derived from the variegated kernels of table IO to verify the
supposition of the presence in these plants of a newly derived broken chro-
mosome. This proved to be true. The constitutions of the newly derived
broken chromosomes are illustrated in figure 15. The method of illustration
is the same as that used in figure 14. The derived broken chromosome is re-
ferred to the dicentric chromatid from which it arose. The broken chromo-
somes have the constitutions to the right of the arrows. Below each arrow
is given the number of plants having this particular composition of its
broken chromosome; in a, the female parent contributed the broken chro-
mosome; in b, the male parent contributed the broken chromosome. Five


270                BARBARA McCLINTOCK
of the 15 plants had a newly derived broken chromosome with no duplica-
tion or deficiency. Nine plants possessed newly derived duplications of var-
ious lengths, and one plant possessed a broken chromosome deficient for a
terminal segment which included approximately one-fourth of the short
arm.

4 0                     . . .._._.._-__......._
                   tt

i ;

   bJ                     ______.___..____._._.-
               tttt ttt
                        II2 I   33 I
FIGURE IS.-The description for this figure is similar to that given with figure 14 except that
the duplication in the heterozygous parent was short, composed of a terminal segment only one-
fifth the length of the short arm. Nevertheless, following crossing over, the dicentric chromatid
has the same constitution as that in c of figure I I and in a and b of figure 14.

As in previous cases, these newly broken chromosomes were tested for
their stability in the succeeding generation. The results are given in table
I I. They are as expected. The five plants whose broken chromosome had
neither a duplication nor a deficiency produced no variegated kernels (A,
table I I). In contrast, tests of seven of the newly derived duplications (B,

                         TABLE II

Tests of the stability of broken chromosomes derived from the chromosome 9 with the short duplicalion.

A. BrokenchromosomegcarryingZ (noduplicationordeficiency)
Normal chromosome 9 carrying i             X normal chromosome 9 carrying i


                            NON-VARIEGATED        VARIEGATED
                               KERNELS            KERNELS
         TYPE OP CROSS         I           i          I-i
    9 parent heterozygous        662         661          0
    3 parent heterozygous      1,524        I,.P~          0

Newly derived duplication chromosomes 9 carrying I
B. -

Normal chromosome 9 carrying i

0 Xnormal chromosome 9 carrying i8'

                   NON-VARIEGATED          VARIEGATED
                      KERNELS              KERNELS
                 I           i           I-i
             956          1,119           20
table II) gave a total of 20 variegated kernels. Each ear possessed one or
more variegated kernels. There can be little doubt that the plants arising
from these variegated kernels would again show newly broken chromo-
somes. In view of the extensive analysis of the chromosome composition of
plants derived from variegated kernels in the progenies of (I) the rear-
ranged chromoxome 9 (section III, d), (2) the duplication chromosomes 9
derived from the rearranged chromosome 9 (section III, f), (3) the original
long duplication which arose in a genetic culture of maize (section IV), and


            STABILITY OF BROKEN CHROMOSOMES           27=
and (4) the short duplication derived from this latter duplication (section
V), it was not considered necessary to make these tests. The evidence is
conclusive from all of these cases that variegation in the endosperm tissues
is related to the presence of a chromosome with a broken end, the original
break having occurred in the previous meiotic divisions. The type of varie-
gation which appeared in these kernels supports the assumption of the
breakage-fusion-bridge cycle as the causal agent for this variegation, that
is, the deletions of genes from some nuclei and their duplication in other
nuclei.

                        VI. DISCUSSION
   (a) The positions of the breaks in anaphase bridge conjigura-
           tions in successioe nuclear dioisions
In the preceding sections of this paper the determination of the chromo-
some constitution of 186 plants, derived from variegated kernels, has been
given. In 180 of these plants, a chromosome with a broken end was found.
In each case, the chromosome with the broken end carried the genes asso-
ciated with the variegation, these genes being located in the arm of the
chromosome which possessed the broken end. Of the six exceptional cases,
three resulted from hetero-fertilization; consequently, the chromosome
constitution of the plant tissues could not be related to that in the endo-
sperm tissues. The remaining three exceptional cases showed an altered
chromosome, but the relation of the alteration to the variegation appear-
ing in the endosperm could be determined in only one case (see section
III d). There can be little doubt that the variegation in the endosperm tis-
sues, described in this paper, is related to the presence in this tissue of a
newly derived broken chromosome. It is necessary that the broken end be
newly derived for a broken end heals when introduced into a zygote and is
no longer capable of producing variegation either in the resulting sporophyt-
ic tissues or in the gametophytic and endosperm tissues of succeeding
generations. This has been clearly established.
In all cases mentioned in this paper, the broken chromosome had its
origin in a meiotic mitosis. The variegation was confined to the endosperm
tissues in the generation immediately following. It made no difference
whether the broken chromosome was introduced through the pollen grain
or through the embryo sac. In either case variegation resulted in the endo-
sperm tissues. The character of this variegation was clearly of the type
which should arise following the breakage-fusion-bridge cycle where suc-
cessive breaks do not always occur at positions of previous fusions (see fig.
I). Evidence for the initiation of this cycle has been given in a previous
publication (MCCLINTOCK ro38b). The observations were confined to the
first division of the microspore or male gametophyte. This is the first divi-


272                  BARBAR. McCLINTOCK
sion following the production of the broken end. The evidence for continu-
ation of this cycle in the following gametophyte divisions is obtained infer-
entially in the study reported here. In several cases the broken chromo-
some in the endosperm and in the embryo were not alike in chromosome
constitution. The difference could readily be accounted for if fusion had
occurred between the broken ends of sister chromatids in the generative
nucleus followed by an anaphase bridge configuration during the division
of this nucleus. If the break in this bridge configuration occurred closer to
one centromere than to the other, each sperm would receive a broken chro-
mosome, but the constitution of the broken chromosome in each sperm
would differ.
Evidence for the breakage-fusion-bridge cycle in the female gametophyte
is likewise inferential. The duplications 1276-1 and 1503-2 (type I, fig. 9)
and duplication 1269 (type V, fig. 9) were delivered to the zygote through
the female gametophyte. These duplication chromosomes have obviously
been derived from a dicentric chromatid in the preceding meiotic mitosis.
At least one fusion and break following the original break must have oc-
curred to give rise to duplications 1276-1 and 1503-2. At least two such fu-
sions and breaks must have occurred to have produced the duplication of
plant 1269.
On the assumption of the continuation of the breakage-fusion-bridge
cycle in the gametophytic tissues, the agreement in so many cases between
the genie constitution of the broken chromosome delivered to the endo-
sperm and that delivered to the zygote might appear surprising. Two ex-
planations are possible. First, the break in an anaphase bridge configura-
tion may tend to occur at a median position between the two centromeres.
Secondly, following an original meiotic break, the break in the successive
anaphase figures may tend to occur at positions of previous fusions. Either
or both possibilities must be considered only as trends; otherwise, no dupli-
cated chromosomes would have been produced following breakage of the
dicentric chromatid of figure 8 nor would extensive variegation be pro-
duced in kernels receiving broken chromosomes.
Evidence obtained from both meiotic anaphase configurations and from
examination of broken chromosomes in the prophase of the first microspore
division has indicated that the original break in a bridge configuration at a
meiotic anaphase may occur at any position between the two centromeres.
However, no data have been obtained which could be treated statistically.
It is certain, though, that breaks need not occur at median positions. This
is confirmed by the number of cases where the recovered broken chromo-
somes possessed long duplications or deficiencies.The evidence does sug-
gest, however, that following an original break, the breaks in the succeed-
ing anaphases may tend to occur at positions of previous fusions. This is


           ST.ABILITY OF BROKE?; CHROMOSOMES          273
based on three sets of evidence. The broken chromosomes arising from the
dicentric chromatid of figure 8 (see table 4) may be considered first. A
functional pollen grain could arise only when the original meiotic break oc-
curred either immediately to the right of the inner small knob or at a posi-
tion between this point and the left centromere. Thus, a broken chromo-
some can be transmitted through the pollen only after a decidedly non-
median break in the original dicentric chromatid. ,411 other breaks would
result in broken chromatids with deficiencies. A pollen grain whose tube
nucleus does not have a complete set of genes of chromosome 9 is not func-
tional. In the summary table 5 the percentage is given of the various types
of broken chromosomes received by the embryos. Eleven and one-tenth
percent possessed a deficient chromosome 9, and I I .I percent possessed a
duplication of chromosome 9. Each of these types of chromosomes could be
contributed by the pollen only following a secondary break which did not
occur at the position of previous fusion. Thus, it is established that in aT-
proximately one-fourth of these cases, a secondary break did not occur at
the position of previous fusion. The broken chromosomes transmitted by
the female gamete cannot be so analyzed, since deficiencies of approxi-
mately one-third of the distal part cf the short arm can produce functional
embryo sacs (MCCLINTOCK unpublished). The chromosomes with duplica-
tions are the only ones which must have originated following a successive
break which was not at the position of previous fusion. The high percent-
age of cases where the broken chromosome ended either in the knob or at
positions immediately adjacent to it strongly suggests that at anaphase
this substance is more readily broken than are other parts of the chromo-
some. This introduced an obstacle in the analysis of the randomness of the
breaks. However, most of the recorded broken chromosomes gave no evi-
dence of having undergone the breakage-fusion-bridge cycle, which sug-
gests that breakage in successive anaphases may tend to occur at positions
of previous fusions.
The evidence is likewise suggestive when the recovered broken chromo-
somes illustrated in figures 14 and I 5 are analyzed. A surprisingly high per-
centage (47 percent) of the broken chromosomes delivered to the zygote by
the pollen parent had neither a duplication nor a deficiency. Although the
number of chromosomes examined is small, the figure for this one class is
very high. The relative percentages of types of recovered broken chromo-
somes delivered by the male and female gametes, respectively, are as fof-
lows :

                          Nale gametes    Female gametes
So duplication or deficiency               47 percent      20 percent
Deficiency                        6.2 percent       0.0 percent
Duplication                       47 percent      80 percent


274                  B;\RB.\R.\ McCLISTOCK
Pollen grains whose tube nucleus possesses a deficiency do not function.
Therefore, chromosomes with deficiencies introduced by the male parent
must have resulted from a break which was not at the position of previous
fusion, Again, pollen grains whose tube nucleus contains a duplication do
not function as successfully as those containing a normal genie comple-
ment. Since some of these grains are known to function, it cannot be de-
termined whether the duplications delivered through the pollen arose at
the time of meiosis or at a later stage following a break which did not occur
at a position of previous fusion. More probably, both factors were involved
to give the 47 percent of such cases. When the tube nucleus contains
neither a duplication nor a deficiency, the pollen grain functions normally.
Pollen grains whose tube nucleus contains a broken chromosome with this
constitution would not meet competition. If breaks tend to occur at posi-
tions of previous fusions, the constitution of the sperm nuclei and that of
the tube nucleus would tend to be similar in many grains carrying broken
chromosomes. Among all the pollen grains containing broken chromosomes
produced by these plants, those whose tube nucleus contains neither a
duplication nor a deficiency would be selectively favored in effecting
fertilization. If there were a tendency for breaks to occur at positions of
previous fusions, a high percentage of the plants receiving broken chromo-
somes through the pollen would have neither a duplication nor a deficiency
in the broken chromosome. Although the numbers are small, the results
so far obtained are very suggestive of this interpretation. Since selection
against megaspores and embryo sacs with duplications and in some cases
small deficiencies does not occur, no such proportionality of recovered
broken chromosomes should appear. The numbers of examined cases are
too few to be decisive, but the percentages of types of broken chromosomes
recovered from the female gametophyte does not appear to be the same
as the percentages recovered from the male gametophyte.
The third line of evidence relates to the simplicity of the recovered
broken chromosomes with duplications. Two divisions in the male gameto-
phyte and possibly the first division in the zygote shou1.d follow the
breakage-fusion-bridge cycle. If the microspore nucleus possessed a broken
chromosome with at least a full set of genes, a decidedly non-median break
in the bridge contiguration at the first microspore division in most cases
would result in a tube nucleus with a deficiency or a duplication. Selection
against the functioning of such grains could result. However, no such effect
should follow the breaks in the next divisions in the male gametophyte (or
in the first division of the zygote if a bridge configuration occurs here).
Since some functional pollen grains should have had duplications in their
generative nuclei, repeat duplications could be produced following a non-
median break in the anaphase of the tlivision of the generative nucleus.


             STABILITY OF BROKEN CHROMOSOMES          27.5
However, such repeat duplications have not been observed. In the female
gametophyte, three divisions separate the megaspore from the egg nucleus.
Since there is no selection against megaspores or embryo sacs carrying
duplicated segments in chromosome 9, repeat duplications could be present
in the egg nucleus following non-median breaks in the bridge configurations
of the division leading to the formation of the egg nucleus. Nevertheless,
repeat duplications are rare; only one such case was recognized (type V,
fig. 9). Considering the facts given above, it seems reasonable to conclude
that there is a tendency for the breaks to occur in the anaphase bridges
at the positions of previous fusions, although it has been definitely proven
that this does not occur in all such bridge configurations. Since the
mechanism which results in fusions of broken ends of sister chromatids is
not known, it is not possible to ascribe this breakage at the position of
previous fusion to a weak or imperfect union caused by a partial healing
of the broken end. The broken end must remain capable of fusion; other-
wise variegation would not be produced in the endosperm tissues. This
variegation can result only when the breaks do not occur at positions of
previous fusions. Furthermore, once a complete fusion has occurred, it
must be as strong as that between any other regions in the chromosome;
otherwise the broken chromosomes derived from the dicentric chromatid
of figures 12 and 13 would tend to be alike. They are not alike, however.

04 The trP  f
     e o variegation in endosperms receiving one broken chromosome
     contrasted with those receiving two broken chromosomes
The presence of a single broken chromosome in the endosperm tissues
was considered in the interpretation of the cause of variegation, as illus-
trated in figure I. This chromosome carried the dominant genes. The endo-
sperm tissues are 3n; two sets of chromosomes are contributed by the fe-
male gametophyte, and one set is contributed by the male gametophyte.
Variegation in the endosperm results when the broken chromosomes are
contributed by either the female or the male gametophytes. In the latter
case, only one broken chromosome is present. In the former case, two
broken chromosomes are present. The interpretation of variegation on the
basis of fusion of broken ends of sister chromatids following breakage of
an anaphase bridge configuration in the previous division is the only logical
assumption when a single broken chromosome is present (contributed by
the male parent). However, when two broken chromosomes are present
(contributed by the female parent), two possibilities may occur, Either
fusion of broken ends could occur between the sister halves of each broken
chromosome, following breakage of the anaphase bridge configurations,
or the two broken ends of each chromosome could fuse with one another.
In the first assumption, each broken chromosome would produce a bridge


276                B.iRBAR.1 McCLINTOCK
configuration in successive mitoses. In the latter assumption, bridge con-
figurations would result when the two centromeres of the dicentric chroma-
tids passed to opposite poles. Interlocking of chromatids resulting in
breakage could likewise follow the passage to the same pole of the two
centromeres of a chromatid. However, either of the above interpretations
would lead to variegation in the endosperm tissues.

If fusions of sister chromatids occurred, the amount of recessive tissue
appearing in the variegated kernels should be considerably less when two
broken chromosomes are present than when one broken chromosome is
present. The dominant genes from two chromosomes would have to be
lost to a nucleus before the recessive character would show in the former
case, whereas loss of the dominant gene from only one chromosome is
necessary in the latter case. Comparative examinations of variegated
kernels have not shown this difference. Although the amount of recessive
tissue exhibited by individual kernels on the same ear is variable in either
case, taken as a whole, the endosperms which receive two broken chromo-
somes do not show considerably less recessive tissue than those receiving
but one broken chromosome. There is a decided difference, however, in
the range of color of the various C spots in the two cases. The endosperms
which receive two broken chromosomes carrying C have many more spots
of extreme deep color than those which receive but one broken chromosome
with C. This would occur if many C genes were included in some of the
nuclei following breakage and fusion of two broken chromosomes. The
more C genes present, the deeper the color produced. The type of variega-
tion and the more extreme range in color of the C spots may be explained
as the consequence of fusions between the broken ends of the two chromo-
somes followed by breaks in each of the dicentric chromatids at similar
positions in any one anaphase spindle. That fusions may occur in sporo-
phytic tissues between two broken ends of chromosomes rather than be-
tween the two sister halves at the position of previous breakage has been
demonstrated in maize where ring-shaped chromosomes were present
(MCCLINTOCK ro38a). It may likewise occur in the endosperm tissue. Thus,
the fusion of broken ends of sister chromatids occur in successive divisions
when a single broken chromosome has been introduced in the endosperm,
whereas the fusion of broken ends of two chromosomes may occur when two
such broken chromosomes are present in the nuclei of the endosperm cells.

     (c) The healing of broken ends of chromosomes
It has been repeatedly emphasized that the broken end of a chromosome
becomes healed in the sporophytic tissues. The breakage-fusion-bridge
cycle, which characterizes its behavior in the gametophytic and endosperm


            STABILITY OF BROKEN CHROMOSOMES           277
tissues, ceases. The healing is permanent. When this chromosome is re-
introduced into endosperm tissues in the following generations, no fusions
occur at the broken end between the two sister halves. Furthermore,
when two such broken chromosomes are brought together after each has
passed through a sporophytic generation, no fusions occur between the
two broken ends. No obvious explanation is available for the healing of the
broken ends in the sporophytic tissues as contrasted with the lack of
healing in the gametophytic and endosperm tissues. The question might
arise as to whether the broken end ever heals in the gametophyte or endo-
sperm tissues. Although this may occur in some cases, the evidence sug-
gests that it must be rare. It will be recalled that the majority of varie-
gated kernels arising from the rearranged chromosome 9 (see table I)
had the constitution C Sh ZYC. There were some non-variegated kernels
with this constitution. It was assumed that the variegated kernels had
broken chromosomes and the non-variegated kernels, non-broken chromo-
somes. If healing of broken ends occurs, the plants arising from some of
the non-variegated C Sh ZL~X kernels should have shown a broken chromo-
some. However, as table 6 shows, none of the plants arising from the
C Sh wx, non-variegated kernels possessed a broken chromosome. Under
certain physiological conditions it is possible that the broken end might
heal in the endosperm tissues, but at present these conditions are not
known.
Realization of the healing of the broken end in the sporophytic tissues
came as a surprise. Evidence from the behavior of ring-shaped chromo-
somes had indicated that fusions of broken ends of chromosomes occurred
in the sporophytic tissues when the break originated in this tissue. Although
extensively looked for, no evidence for healing of these broken ends was
obtained in the ring-chromosome material. Since it has been proven that
broken ends can heal, it could be expected that healing of the broken ends
arising from the breakage of a ring chromosome might occur under certain
physiological conditions.
The broken chromosomes described in this paper and the breaks in the
ring-shaped chromosomes all originated as the consequence of mechanical
rupture in an anaphase or telophase spindle figure. Breakage induced
by other means may not lead to similar consequences-that is, the
fusions of broken ends. MULLER (1940) recently reviewed the evidence of
the effect of X-rays on the production and behavior of broken kndsof
chromosomes and concluded that X-ray-induced breakage is followed by
z-by-2 fusions of broken ends, either between parts of the same chromo-
some, between two chromosomes, or between sister halves of a single
chromosome at the position of previous breakage. However, SAX (1940)


278                B.ARB.4R.A McCLINTOCK
and SWANSON (1940) in recent studies on the types of chromosomal ab-
normalities induced by X-radiation have reported observations which
suggest that not all the induced breaks are followed by fusions of broken
ends. Their observations were of the division immediately following the
treatment of the microspore nucleus and of the generative nucleus of the
pollen grain in Tradescantia. It was not shown whether or not these un-
fused broken ends healed permanently, since the behavior in successive
divisions was not followed. With regard to fusions of broken ends, the
breaks induced by X-rays and by mechanical rupture apparently are simi-
lar. However, the breaks induced in chromosomes by ultraviolet irradiation
do not appear to be similar to those produced by X-rays or mechanical
rupture. SWANSON (1940) has observed the direct effect of ultraviolet
radiation on the breakage of chromosomes. His observations suggest that
the breaks induced by the radiation are not followed by fusions of broken
ends of chromosomes. Previous to this work, the genetic and cytological
evidence of the effect of ultraviolet radiation of maize pollen (SINGLETON
1939, SINGLETOX and CLARK I~~O,STADLER and SPRAGUE 1936, STADLER
1939) had indicated that the breakage induced by ultraviolet radiation
differed from that induced by X-radiation. Most of the recovered chromo-
somal abnormalities appeared to be terminal deficiencies. The broken end
was completely healed. When two such broken chromosomes were present
in a single nucleus, no fusion had occurred between them.
Further evidence for the non-fusibility of broken ends produced as the
consequence of ultraviolet radiation is suggested by the character of the
endosperm tissues which receive a nucleus derived from irradiated pollen.
Studies of the sporophytic tissues mentioned above would suggest that
many of the endosperm nuclei were receiving chromosomes with broken
ends following ultraviolet treatment of pollen. If fusions occur between
sister halves of this chromosome at the position of breakage, variegation
kernels of the type described in this paper would be expected. These
were not present in numbers greater than might be expected from normal,
untreated material. If the endosperm possesses a broken chromosome,
fusions do not occur at the position of breakage. It becomes apparent that
the capacity of a broken end to fuse depends upon the method by which
the chromosome becomes broken and the conditions of the cell following
the breakage.
Since it has been demonstrated that broken ends of chromosomes under
certain conditions retain their capacity to fuse with one another but lose
this capacity permanently under other conditions, it will be necessary in
the future to determine the nature of these conditions by experimental
methods before an understanding can be attained of the factors responsible
for fusions or for healing of broken ends.


           ST.\BILITT OF BROKEN CHROMOSOMES           279
  (d) The behaoior of chromosomes initially broken in the endosperm
          and in the sporophytic tissues
In this paper, the variegation in the endosperm tissues has been brought
about by the introduction into this tissue of a chromosome which was
initially broken in the previous meiotic divisions. The recent evidence
reported by CLARK and COPELAND (1940) suggests that the breakage-
fusion-bridge cycle will follow if a chromosome receives its initial break
after its introduction into the endosperm. The authors examined cyto-
logically the mitotic divisions in the endosperm of strains of maize which
had consistently given high percentages of kernels with variegated sectors
in the endosperm tissues. The nature of the variegation has been inten-
sively studied by JONES (1937), who came to the conclusion that spontane-
ous translocations were occurring at a relatively high rate in this material.
Such translocations should produce dicentric chromosomes in some nuclei.
Breakage of a dicentric chromosome in a succeeding mitotic anaphase
would introduce a chromosome with a broken end into the telophase
nucleus. If fusions of sister chromatids at the positions of breakage resulted,
the breakage-fusion-bridge cycle would be initiated. Extensive cytological
examination of mitotic anaphases in this material should reveal bridge
configurations many of which should not show an accompanying fragment.
The authors have found this to be true and have concluded that the
breakage-fusion-bridge cycle will follow a break initiated in the endosperm
tissue itself. In view of the healing which results when a broken chromo-
some is introduced by a gamete into sporophytic tissue, a similar type of
investigation needs to be conducted with sporophytic tissues to establish
whether or not such healing of a single broken end will occur in this tissue
if the break in the chromosome originates in the sporophytic tissue itself.
SAX (1940) states that he has obtained evidence for the breakage-fusion-
bridge cycle following a breakage of a chromosome in the sporophytic
tissues, but a detailed description of the evidence has not been reported
as yet.
     (e) Selective orientation of broken chromatids in the
               second meiotic mitosis
The high percentage of bridge configurations (32 percent) observed at
the first meiotic anaphase in microsporocytes of plants heterozygous for the
rearranged chromosome would lead one to expect either a high percentage
of variegated kernels on the ears of such plants in the crosses outlined or,
if most of the broken chromosomes were highly deficient, a recognizable
amount of ovule sterility due to lack of development of ovules whose
functional megaspores carried such a deficient chromosome. Neither of
these conditions was observed. The percentage of variegated kernels was


280                BARB.~RA McCLINTOCK
low, and there was no marked increase in the sterility of the ovules. Ob-
servations of normal maize plants has shown that it is the lower magaspore
which develops into the embryo sac (WEATHERWAX 1919). Three explana-
tions may be suggested for this lack of ovule sterility. First, there may be
very much less crossing over in the megasporocytes. RHOADES (1940) has
reported a difference in crossing over in mega- and microsporocytes in
maize for genes of chromosome 5. Nevertheless, a decrease in crossing over
would not fully account for the lack of ovule sterility. One could suggest
as a second alternative a tendency for selection of megaspores carrying a
normal chromosome 9. A third possibility seems more likely. As shown
previously, most of the bridge configurations occur at anaphase I. The
anaphase bridge delays the migration of the chromatids toward the two
poles. Following breakage, each of the two broken chromatids may be held
closer to the cell plate than the two normal chromatids. If this orientation
is maintained through interkinesis, a broken chromatid would enter each
of the two middle megaspores. and a normal chromatid would enter the
two end megaspores. The innermost megaspore of the row of four, which
normally develops the embryo sac, would then contain a normal chromo-
some 9. Evidence given in a previous publication (MCCLINTOCK r938b)
would lead one to expect this orientation of broken chromosomes in some
but not all of the second division spindle figures. This interpretation is
similar to that presented by STURTEVANT and BEADLE (1936) as an ex-
planation of low egg sterility in Drosophila in individuals heterozygous
for an inversion in the X chromosome. This third alternative is favored as
the probable explanation of lack of ovule sterility and is supported by simi-
lar evidence obtained from plants heterozygous for an inversion (MCCLIN-
TOCK unpublished).

                           SUMYARY
By use of (I) a rearranged chromosome 9, (2) a duplication arising from
this rearrangement, (3) a deficiency derived from this rearrangement,
(4) a duplication occurring in a genetic strain of maize, and (5) new dupli-
cations derived from this latter duplication it was possible to obtain
functional gametes carrying a chromosome 9 whose short arm terminated
in a broken end.
In all cases, the broken end arose following crossing over at meiosis which
produced a dicentric chromatid. Rupture of the dicentric chromatid at a
meiotic anaphase produced the broken end.
During the following gametophytic division, fusions occurred at the
position of breakage between the two sister halves of the broken chromatid,
resulting in an anaphase bridge configuration. Rupture of this bridge at
late anaphase or early telophase again introduced a broken chromosome


             ST.%BILITT OF BROKEN CHROMOSOMES          281
into the sister telophase nuclei. This breakage-fusion-bridge cycle con-
tinued in the successive gametophytic divisions.
When such a chromosome, initially broken in the previous meiotic
mitosis, is introduced into the endosperm tissues of the following genera-
tion through either the male or the female gametophyte, the evidence
indicates that the breakage-fusion-bridge cycle continues in each successive
division. When this chromosome carries dominant genes in the arm with
the broken end and when the normal homologue carries the recessive
alleles, variegation for these genes appears in the endosperm tissues. This
is caused by non-median breaks in the bridge configurations in many ana-
phase figures which deletes dominant genes from one telophase nucleus
and duplicates them in the sister telophase nucleus.
When such a broken chromosome is introduced into the zygote, the
broken end heals, discontinuing the breakage-fusion-bridge cycle. This
healing is permanent. The broken end behaves in every respect like a
normal end. When a broken chromosome has passed through a sporophytic
generation, it no longer is capable of producing variegation in the endc-
sperm of the following generation. When two such chromosomes are
brought together after each has passed through a sporophytic generation,
no fusions occur between their broken ends.
Thus, the breakage-fusion-bridge cycle occurs only in the nuclear di-
visions of the gametophytic and endosperm tissues when the broken end
is newly derived and has not passed through a sporophytic generation.
Evidence is presented which suggests that following an initial meiotic
anaphase break, the breaks in the successive anaphase bridge configura-
tions in the following gametophytic divisions tend to occur at the position
of previous fusion, but many breaks occur at other positions.
Once a complete fusion has occurred at the position of breakage between
the sister halves of a broken chromosome, the fusion results in a union
which is as permanent and strong as that between other parts of the
chromosome.
The factors responsible for fusions of broken ends or for the healing of
a broken end are not understood but are probably related to the method
by which the chromosome becomes broken and to the physiological condi-
tions surrounding the broken end.


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282                  B.\RB.IR;\ McCLIKTOCK

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