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November 27, 2002 Phosphonate TubulesB. Thomas1, R.C. Corcoran2, C. Cotant2, J.E. Kirsch2, C.M. Lindemann3, and P.J. Persichini4 Tubules are stable, hollow, cylindrical crystalline tube-like structures a few micrometers (millionths of a meter) in size, with potential applications in nanofabrication and medical encapsulation. Stringent control of the kinetics of the process by which these tubules self-assemble is necessary to control the dimensions and qualities of the tubules. An alternative control mechanism involves subtle chemical modifications made to the self-assembling molecules. By using x-rays produced at the National Synchrotron Light Source, scientists have studied both control pathways to understand better how subtle changes made to lecithin, a molecule found in egg yolks and the plasma membrane of plant and animal cells, causes rigid, hollow tubules, to form.
Perhaps the most familiar example of self-assembly is the formation of vesicles from phospholipids (lipids typically found in cellular plasma membrane) placed in water. The vesicles form under the action of divergent forces on the phospholipid's long, water-insoluble (hydrophobic) hydrocarbon tails, and its compact, water-soluble (hydrophilic) “headgroup.” These divergent forces drive self-assembly. For example, the hydrophilic headgroups lie exposed upon the inner and outer surfaces of spontaneously formed spherical vesicles, while their hydrophobic tails lie sheltered in between the two hydrated surfaces.
Close examination of these cylinders, called tubules, reveals two unusual features: the tubules are coaxially nested sets of cylinders, also called lamellae, and the tubules possess a helical, hence chiral, substructure. Tubules form through the helical winding of a uniform-width phopholipid bilayer ribbon, which creates a cylinder that serves as a “nucleus” for subsequent coaxial windings. Interestingly, the tubule's helical sense of handedness depends upon the chirality of the tubule-forming molecule: molecules of one chirality produce tubules possessing a right-handed helical structure, while molecules of the opposing chirality always produce left-handed helices.
Tubule gross morphology can be quickly measured by microscopy, but such measurements are both static and insensitive to the tubule’s interior structure. The high intensity of the x-rays produced at beam line X10A of the National Synchrotron Light Source has allowed us to perform kinetic small-angle x-ray scattering (SAXS) studies of the transition between spheres and tubules. These studies revealed that: (1) the transition is of the first order (spheres and tubules are in equilibrium during the transition) and is reversible; (2) tubular interlamellar spacing is tightly conserved when tubule diameter is doubled; and (3) the number of lamellae is halved when the tubule diameter doubles. These surprising results about tubule interior structure give important clues about intrinsic membrane curvatures and bending moduli, which are unobtainable by any other means. Tubule dimensions and morphology suggest a host of potential technological applications, ranging from nanofabrication and purification to medical encapsulation. Our work is one step into realizing this technological potential, which will ultimately require optimizing the tubule’s morphology for a given application, and understanding not only its “gross” structure but its interior structure as well. BEAMLINE FUNDING PUBLICATION FOR MORE INFORMATION |
The National Synchrotron Light Source at Brookhaven National Laboratory in New York, is a national user research
facility funded by the U.S. Department of Energy's Office of Basic Energy Science. The NSLS operates two electron
storage rings: an X-Ray ring and a Vacuum UltraViolet (VUV) ring which provide intense light spanning the electromagnetic
spectrum from the infrared through x-rays. Each year over 2300 scientists from universities, industries and government
labs perform research at the NSLS.
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Scientists are currently studying how to build novel materials
the size of a few nanometers (a few billionths of a meter, or the
size of a few atoms), and the conditions under which these tiny
materials could self-assemble spontaneously into specific
configurations. Understanding the self-assembly process is one of
the most important objectives of nanotechnology, because this
process could lead to materials with completely novel properties.
We are now learning that factors far more subtle than the simple
“hydrophobic” and “hydrophilic” forces can have profound
consequences upon the morphology of a self-assembled material. For
example, small, inflexible sections can be inserted in the
phospholipid’s otherwise flexible hydrocarbon tails by creating
triple bonds in the tails. When this change to the tail’s shape is
made, then cooling the resulting spherical vesicles leads to the
creation of rigid, hollow 30-by-0.5 micrometer (millionth of a
meter) vesicles of an astonishing cylindrical symmetry (figure 1).
To understand better tubule formation, we have made synthetic
perturbations to tubule-forming molecules and characterized the new
products. While it is clear that the tails' diynes are required for
tubule formation, the remarkable helical handedness-molecular
chirality correspondence suggests that by altering the molecule near
its chiral center, significant changes to tubule morphology could
result. Indeed, we have found that removing the phosphoryl oxygen
that links the headgroup to the tails of the tubule-forming molecule
called 1,2-bis(10,12-tricosadiynoyl)-sn-glycero-3-phosphocholine, we
have doubled the tubule diameter (figure 2). This change in tubule
diameter is significant, since previous studies have succeeded in
changing tubule length, but not its diameter.