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Plant Cell. 2003 May; 15(5): 1170–1185.
doi: 10.1105/tpc.010926.
PMCID: PMC153724
Cloning and Characterization of the WAX2 Gene of Arabidopsis Involved in Cuticle Membrane and Wax Production
Xinbo Chen, S. Mark Goodwin, Virginia L. Boroff, Xionglun Liu, and Matthew A. Jenks1
Department of Horticulture and Landscape Architecture, Purdue University, West Lafayette, Indiana 47907
1To whom correspondence should be addressed. E-mail jenks/at/hort.purdue.edu; fax 765-494-0391
Received January 31, 2003; Accepted March 7, 2003.
Abstract
Insertional mutagenesis of Arabidopsis ecotype C24 was used to identify a novel mutant, designated wax2, that had alterations in both cuticle membrane and cuticular waxes. Arabidopsis mutants with altered cuticle membrane have not been reported previously. Compared with the wild type, the cuticle membrane of wax2 stems weighed 20.2% less, and when viewed using electron microscopy, it was 36.4% thicker, less opaque, and structurally disorganized. The total wax amount on wax2 leaves and stems was reduced by >78% and showed proportional deficiencies in the aldehydes, alkanes, secondary alcohols, and ketones, with increased acids, primary alcohols, and esters. Besides altered cuticle membranes, wax2 displayed postgenital fusion between aerial organs (especially in flower buds), reduced fertility under low humidity, increased epidermal permeability, and a reduction in stomatal index on adaxial and abaxial leaf surfaces. Thus, wax2 reveals a potential role for the cuticle as a suppressor of postgenital fusion and epidermal diffusion and as a mediator of both fertility and the development of epidermal architecture (via effects on stomatal index). The cloned WAX2 gene (verified by three independent allelic insertion mutants with identical phenotypes) codes for a predicted 632–amino acid integral membrane protein with a molecular mass of 72.3 kD and a theoretical pI of 8.78. WAX2 has six transmembrane domains, a His-rich diiron binding region at the N-terminal region, and a large soluble C-terminal domain. The N-terminal portion of WAX2 is homologous with members of the sterol desaturase family, whereas the C terminus of WAX2 is most similar to members of the short-chain dehydrogenase/reductase family. WAX2 has 32% identity to CER1, a protein required for wax production but not for cuticle membrane production. Based on these analyses, we predict that WAX2 has a metabolic function associated with both cuticle membrane and wax synthesis. These studies provide new insight into the genetics and biochemistry of plant cuticle production and elucidate new associations between the cuticle and diverse aspects of plant development.
INTRODUCTION

The plant cuticle forms the outermost coating over essentially all aerial plant surfaces and provides a protective barrier to many forms of environmental stress, including those caused by drought, phytophagous insects, and pathogens (Eigenbrode and Espelie, 1995; Jenks and Ashworth, 1999; Jenks, 2002). One of the cuticle's most important functions is limiting transpiration to conserve water, a mechanism especially important for plant survival in water-limited environments such as those found in desert, alpine, and coastal ecosystems (Schreiber and Riederer, 1996; Riederer and Schreiber, 2001; Jenks, 2002). As described by Jeffree (1996), the plant cuticle is a complex structure composed of two basic layers: an outermost epicuticular wax layer that overlies a cuticle membrane layer. Epicuticular waxes often are visible to the naked eye as a bluish-white coating called glaucousness or bloom. By scanning electron microscopy, these glaucous waxes are visible as a field of densely distributed wax crystals, with diverse shapes specific to species and organs. Nonglaucous and glossy leaf surfaces have a smooth coating of wax or may possess very sparsely distributed wax crystals. Using transmission electron microscopy, the cuticle membrane in most plants is seen to possess two basic layers: an outer translucent cuticle proper and an inner opaque cuticular layer defined by the presence of osmiophilic cellulose microfibrils (Jeffree, 1996). Compositionally, the epicuticular waxes are primarily long-chain aliphatic molecules that are soluble in organic solvents, whereas the cuticle membrane is composed primarily of insoluble cutin polyester with lesser amounts of intracuticular waxes.

To date, nine genes associated with plant cuticular wax production have been cloned, including five from Arabidopsis. Four of these—CER2, CER3, GL2, and GL15—appear to encode regulatory loci (Tacke et al., 1995; Hannoufa et al., 1996; Moose and Sisco, 1996; Negruk et al., 1996; Xia et al., 1996), three—CER6, KCS1, and GL8—may encode metabolic enzymes (Xu et al., 1997; Millar et al., 1999; Todd et al., 1999; Fiebig et al., 2000), and two—CER1 and GL1—may be involved in either the transport or the metabolism of wax compounds (Aarts et al., 1995; Hansen et al., 1997). None of these genes has been associated with cuticle membrane synthesis.

Only two cuticle membrane mutants, sorghum bm2 and maize cr4, have been reported in plants. The bm2 mutant has >60% reduction in cuticle membrane weight and thickness (Jenks et al., 1994) and a significant alteration in its waxes (Jenks et al., 2000). The BM2 gene has not been cloned. The cr4 mutant displays an irregularly thickened cuticle membrane and postgenital fusion, a condition in which organs, after being formed, fuse together upon physical contact (Jin et al., 2000; Becraft et al., 2001). Whether cr4 affects waxes was not reported. The CR4 gene was cloned and shown to encode a receptor-like kinase involved in the regulation of global aspects of leaf development rather than strictly cuticle membrane metabolism. Other genes were cloned whose predicted protein sequences suggest functions in the synthesis of cutin (the primary component of cuticle membrane); these genes include CYP86A1, CYP94A1, CYP94A2, and LCR (Benveniste et al., 1998; Tijet et al., 1998; LeBouquin et al., 1999; Wellesen et al., 2001). However, these genes have yet to be linked with cutin synthesis in planta.

We recently used insertion mutagenesis to isolate a cuticle membrane mutant in Arabidopsis designated wax2. Compared with that of the wild type, the cuticle membrane of wax2 weighed less, was thicker, was much less reticulated, and was structurally disorganized. Besides altered cuticle membrane, wax2 had a glossy stem, similar to that of the Arabidopsis epicuticular wax mutants designated eceriferum (cer). wax2 also displayed postgenital fusion. Comparable Arabidopsis stem wax mutants displaying postgenital fusion were reported previously, including wax1 (Jenks et al., 1996), ded1 (Lolle et al., 1998), and cer10 and cer13 (Jenks et al., 2002). Whether these mutants, like wax2, have altered cuticle membranes is unknown. wax2 also had reduced fertility, a condition reported for many cer mutants (Koornneef et al., 1989), increased epidermal permeability similar to that of the sorghum cuticle membrane mutant bm2 (Jenks et al., 1994), and a lower stomatal index. By comparison, the cer1 and cer6 wax mutants had higher stomatal indices (Gray et al., 2000). Thus, the wax2 mutation reveals a unique cuticle gene involved in diverse aspects of plant development. We describe here the cloning and characterization of WAX2, a cuticle membrane gene from Arabidopsis.

RESULTS

Isolation and Genetic Analysis of the wax2 Mutant
Approximately 35,000 families from a T-DNA–mutagenized population of Arabidopsis ecotype C24 (created as described by Weigel et al., 2000) were screened to identify mutants with reduced visible glaucousness of the inflorescence stem. These stem wax mutants then were screened for changes in the rate of water loss from excised stems (Jenks et al., 1994). One mutant (later designated wax2) had a higher water-loss rate than the wild type and all other mutants. Gravimetric and transmission electron microscopy studies showed that the wax2 mutant had dramatic alterations in the cuticle membrane (see below).

The activation T-DNA vector pSKI015 insert used for mutagenesis contains the BAR gene for bialophos resistance. Bialophos-resistant plants segregated in an approximate 3:1 (resistant:susceptible) ratio (χ2 test on 259 plants, P > 0.05) in a backcross F2 population, indicating the presence of a single bialophos-active T-DNA insert. Cosegregation of bialophos resistance, the glossy stem, and small, nearly seedless siliques was consistent with the genetic linkage of these phenotypes and the monogenic recessive inheritance of the responsible wax2 allele. Postgenital fusion of wax2 segregants in the F2 population showed variable penetrance in the low-humidity environment in which the plants were grown. No glaucous wild-type segregants showed fusion or low fertility. Fifteen randomly selected glossy, reduced fertility segregants had higher excised stem water loss rates than 15 wild-type segregants, indicating cosegregation of high transpiration and the visible mutant phenotypes. Gel blot analysis of DNA from wax2 digested with the restriction enzymes BamHI, EcoRI, and HindIII using the BAR gene probe revealed the presence of only one hybridizing band (data not shown), providing further evidence that a single insertion in the WAX2 gene was responsible for the described phenotypes.

Cuticle Membrane Alteration
Wild-type stem cuticles have a typical type-3 cuticle structure (Jeffree, 1996), with an amorphous cuticle proper and a reticulate cuticular layer (visualized by transmission electron microscopy). The cuticle ultrastructure of wax2 stems was altered dramatically compared with that of wild-type stems (Figure 1). The cuticle membrane thickness of wax2 stems was increased by 36.4% relative to that of the wild-type (cuticle proper plus cuticular layer). wax2 cuticle membranes were 151.7 nm thick, whereas wild-type membranes were 111.2 nm thick. The osmiophilic reticulum typical of the cuticular layer of wild-type membranes, and the normally visible line of demarcation between the cuticle proper and the cuticular layer, were nearly absent in wax2 membranes. The connective region between the cuticle membrane and the cell wall was irregular and disorganized in wax2, showing distinct, unorganized bulges of less reticulate or nonreticulate cuticle extending into outer cell wall regions. The outer epidermal cell wall of wax2 was more darkly stained (osmiophilic) than that of the wild type (Figure 1). Interestingly, ZnCl2-extracted cuticle membranes of wax2 stems had 20.2% less total weight than those of wild-type stems, even though wax2 cuticles were thicker. Stem cuticle membrane weight was reduced from 11.9 mg/dm2 in the wild type to 9.5 mg/dm2 in wax2. The stem cuticle membrane weight and ultrastructure of five cer mutants, including cer1, were not significantly different from those of the wild type (data not shown). Likewise, wax2 leaf cuticle membranes were thicker than those in the wild type (data not shown).
Figure 1.Figure 1.
Arabidopsis Ecotype C24 and wax2 Mutant Stem Pavement Cell Cuticle Membranes Visualized Using Transmission Electron Microscopy.

Cuticular Wax Alteration
Scanning electron microscopy was used to show that the density of wax crystals on the wax2 stem was reduced severely (to nearly no wax crystals in places) relative to the wild type (Figure 2). Where present in wax2, there was a higher proportion of horizontal plate–like wax crystals and corresponding reductions in vertical plate–like and upright tubular wax crystals. Leaf surfaces of C24 and wax2 lack visible wax crystals (data not shown). Relative to the wild type, total stem and leaf wax on wax2 were reduced by 78.3 and 80.3%, respectively (Table 1). The wax composition on wax2 stems was characterized as having large proportional reductions in aldehydes, alkanes, secondary alcohols, and ketones, with corresponding increases in acids, primary alcohols, and esters (Table 1). The wax2 mutation produced a slightly different effect on leaf than stem waxes in that only the alkane proportions were reduced on leaves of wax2 (Table 1). Total proportions of acids, primary alcohols, and esters were increased greatly on wax2 leaves relative to wild-type leaves, with wax2 leaf aldehyde proportions increased just slightly (Table 1). Secondary alcohols and ketones are trace constituents on leaves of both the wild type and wax2 and are not discussed further. For individual wax constituents, the absolute amount of C30 primary alcohols on wax2 stems was ~180% greater than on wild-type stems, whereas the amounts of all other wax2 stem constituents were reduced relative to those of the wild type (Figure 3). The increased C30 alcohols on wax2 stems are consistent with shunting of the C30 acyl-CoA precursors (normally converted primarily to C29 alkanes) toward the primary alcohol branch of the wax pathway. The leaves of wax2 did not exhibit a similar skewing in the chain length distribution of wax homologs, except that certain shorter chain length wax constituents in all classes were reduced less (or increased slightly) than longer chain waxes compared with the wild type (Figure 3). This differential effect on short-chain versus long-chain leaf waxes was small.
Figure 2.Figure 2.
Epicuticular Wax Crystallization Patterns on Stem Surfaces of Arabidopsis Ecotype C24 and the wax2 Mutant Visualized Using Scanning Electron Microscopy.
Table 1.Table 1.
Stem and Leaf Cuticular Waxes on Wild-Type Arabidopsis Ecotype C24 and the Isogenic wax2 Mutant
Figure 3.Figure 3.
Stem Cuticular Wax Constituents on Arabidopsis Ecotype C24 and the wax2 Mutant.

Molecular Cloning of the WAX2 Gene
Plant DNA fragments of 1.4 and 1.1 kb flanking the T-DNA insert were rescued from the wax2 right border by EcoRI and HindIII, respectively. Sequencing results indicated that they represented the same insert site. A PCR assay showed that 25 randomly selected mutants in a backcross F2 population were homozygous for the T-DNA insert, indicating tight linkage between the insert and the visible wax2 mutant phenotypes. The insert occurred in the third intron of a putative Arabidopsis GLOSSY1 homolog, At5g57800. The gene At5g57800 was predicted to generate an mRNA transcript of 1917 bp, which encoded a 566–amino acid protein with similarity to the predicted GL1, CER1, and CER1-like proteins but ~70 amino acids shorter at the N terminus.

To be certain that we had obtained the full-length WAX2 mRNA sequence, we performed 5′ and 3′ rapid amplification of cDNA ends (RACE) using gene-specific primers designed from EST sequences available at the Arabidopsis EST stock center. A 1759-bp 5′ RACE fragment and a 1259-bp 3′ RACE fragment were obtained with 498 bp overlap of 100% sequence match. Both sequences aligned to the genomic DNA and ESTs. Compared with the At5g57800 sequence, our 5′ RACE fragment of WAX2 contained an additional exon (17,352 to 17,402 bp of MTI20) upstream of the original first exon. As such, the T-DNA insert occurs in the fourth intron of WAX2. The full WAX2 nucleotide sequence and associated annotation are available in GenBank. The full-length WAX2 spans 3813 bp of genomic DNA and has 11 exons and 10 introns. Exons range from 51 to 257 bp, and introns range from 75 to 313 bp. The full-length cDNA is 2500 bp and has a coding region of 1899 bp, a 376-bp 5′ untranslated region, and a 193-bp 3′ untranslated region. The 5′ untranslated region contains five contiguous stop codons immediately before the start codon, and there are no other alternative start codons within it. A TATA box (TAT-ATAAG) at position −35 bp and two CAAT boxes at −7 and −289 bp relative to the 5′ end of the transcription start site are present. The 3′ untranslated region possesses a putative polyadenylation signal (AAAAA).

After cloning and characterization of the WAX2 sequence, a second wax2 allelic mutant in the Columbia ecotype with a T-DNA insert in the third exon (SAIL 832 E06), designated wax2-2, was obtained from Syngenta (Basel, Switzerland). A third wax2 allelic mutant in the Columbia ecotype with a T-DNA insert in the fifth exon, obtained from the Salk Institute through the ABRC Stock Center (SALK 034318) and designated wax2-3, was identified in the Salk T-DNA–tagged lines. The SALK 034318 insertion mutant information was obtained from the SIGnAL World Wide Web site (http://signal.salk.edu). Both wax2-2 and wax2-3 displayed the same visible glossy stem, reduced fertility, and postgenital fusions as the original wax2-1 mutant. PCR genotyping of wax2-2 and wax2-3 in a backcross F2 population indicated that all mutants were homozygous for the insert wax2 sequence. In addition, wax2-2 and wax2-3 phenotypic segregation ratios in F2 populations showed monogenic recessive inheritance, as did wax2-1. These data confirm that the independent insertions in the WAX2 sequence are responsible for the altered visible phenotypes of these mutants. The wax2 mutant complemented wax1 in a test of allelism, and WAX2 was not closer than an estimated 20 centimorgan to any of the existing cer loci on chromosome 5 (A.M. Rashotte, M.A. Jenks, and K.A. Feldmann, unpublished data).

Characterization of the Predicted WAX2 Protein
The WAX2 transcript encodes a polypeptide of 632 amino acids with an estimated molecular mass of 72.3 kD and a theoretical pI of 8.78. No alternative open reading frames were identified. WAX2 protein had highest sequence similarities to a partial Senecio odora cDNA clone named epi23 (Hansen et al., 1997) and a partial rice sequence annotated as a GLOSSY1 homolog (Hansen et al., 1997), with 65 and 63% amino acid identity, respectively (Figure 4). WAX2 has 35% amino acid identity to GLOSSY1 in maize (Hansen et al., 1997) and 34% amino acid identity to CER1 in Arabidopsis (Aarts et al., 1995). WAX2 amino acid identity to three other CER1-like paralogs in Arabidopsis varied between 31 and 34%. The C-terminal sequences of the WAX2 polypeptide (366 to 553 amino acids) and its rice and Senecio homologs were highly similar (83 and 80% identity, respectively, to WAX2), suggesting that this region may have similar functions in all three species. Similar to the CER1 and CER1-like proteins, WAX2 appears to be an integral membrane protein possessing highly conserved transmembrane-spanning domains at its N terminus. Specifically, WAX2 is predicted to have six transmembrane-spanning domains between residues 42 and 64, 95 and 117, 127 and 146, 186 and 208, 301 and 323, and 330 and 349 of the deduced WAX2 protein (TMHMM Program; data not shown). The N-terminal end of WAX2 (including the transmembrane domain) was 95.4% aligned to the signature sequence (coding domain [CD] length of 216 residues) of the sterol desaturase family.
Figure 4.Figure 4.
Alignment of Arabidopsis WAX2 with Five Related Proteins.

The WAX2 protein also was found to possess the three His-rich motifs (HX3H, HX2HH, and HX2HH, where X stands for any amino acid) of the SUR2-type hydroxylase/desaturase catalytic domains (Figure 4). Based on TMHMM Program analysis, the C terminus (residues 350 to 632) is located outside of a membrane. A span of 66 amino acids (residues 456 to 521) near the C-terminal end shares 33% identity and 49% similarity to a domain found in retinol dehydrogenase. Residues 456 to 497 were 16.7% aligned to a signature (CD length of 252 residues) found in the short-chain dehydrogenase/reductase family (SDR). Computer-based homology searches using various BLAST (Basic Local Alignment Search Tool) and FASTA algorithms with phylogenetic analysis revealed that the Senecio EPI23 and Rice GL1 sequences are more appropriately termed WAX2 homologs (Figure 5). The WAX2 homologs and GL1 form a distinct group separate from CER1, CER1L19 (Figure 5), and two other CER1-like proteins (data not shown) in Arabidopsis.

Figure 5.Figure 5.
Phylogenetic Analysis of WAX2.

Analysis of WAX2 Transcript Expression
The 5′ RACE WAX2 cDNA fragment was used as a probe in RNA gel blot experiments. After plants bolted, total RNA was isolated from different organs of wild-type and wax2 mutant plants. These studies revealed a 2.5-kb mRNA band in stems, rosette leaves, siliques, and whole flowers of the wild type (Figure 6). The amount of WAX2 transcripts was highest in siliques and lower in leaves than in stems and flowers. The WAX2 transcript was not detected in root RNA of the wild type. These results are similar to those reported for CER1 RNA expression (Aarts et al., 1995), except that the highest expression of WAX2 occurred in siliques, whereas the highest expression of CER1 occurred in flowers. The RNA isolated from wax2-1, wax2-2, and wax2-3 lacked the WAX2 transcript in all organs examined (data not shown). The lack of transcript and the location of the insert suggest that all three wax2 insertional alleles are functional knockouts.
Figure 6.Figure 6.
Expression of WAX2 in Wild-Type Arabidopsis Ecotype C24.

Pleiotropic Effects of wax2
Postgenital fusions between aerial organs in the wax2 mutant were common (Figure 7), although the penetrance and expressivity of this trait in wax2 populations was variable, occurring with greater frequency in the greenhouse than in growth rooms. Fusions were seen to occur between many aerial organs, especially between leaves, sepals (i.e., flower buds), sepals and leaves, leaves and stems, and sepals and stems. Gently clamping together fully expanded wax2 leaves did not produce fusions, suggesting that the competence for fusion occurs in primordial or young expanding organs but not in older organs. Fusion between two or more wax2 plants growing in close contact was not observed. In addition, the penetrance of the fusion phenotype was never 100%.
Figure 7.Figure 7.
Terminal Inflorescences of Arabidopsis Ecotype C24 and the wax2 Mutant.

wax2 showed a significant reduction in fertility in a low-humidity atmosphere under open pollination, as revealed by very small siliques (Figure 7) with very few (if any) seeds produced relative to the wild type. Plants open pollinated in high-humidity conditions showed restored fertility. To determine whether wax2 sterility was male or female specific, reciprocal crosses were made by hand between wax2 and the isogenic wild type. Under low-humidity conditions (~30% RH, and without bagging after crossing), 78.1% of siliques (25 of 32) produced seeds in crosses made using wax2 as the female and the wild type as the male pollen donor (wax2/WAX2) and 76.2% of siliques (16 of 21) produced seeds in the WAX2/WAX2 cross. In the WAX2/wax2 and wax2/wax2 crosses, 0 of 29 and 0 of 21 siliques produced seeds, respectively. Under high-humidity conditions (bagging after crossing), 78.3% of siliques (18 of 23) produced seeds in the wax2/WAX2 cross, 70.8% (17 of 24) produced seeds in the WAX2/wax2 cross, 80.9% (17 of 21) produced seeds in the WAX2/WAX2 cross, and 66.7% (14 of 21) produced seeds in the wax2/wax2 cross. As with cer1 (Aarts et al., 1995) and cer6-2 (Preuss et al., 1993), sterility appeared limited to the male reproductive system and was dependent on humidity.

Adaxial and abaxial leaves of wax2 had a 16.0 and 17.4% lower stomatal index than wild-type leaves (Table 2). Whereas wild-type C24 leaves had an adaxial stomatal index of 29.4 ± 0.74 and an abaxial stomatal index of 29.3 ± 0.3, wax2 leaves had an adaxial stomatal index of 24.7 ± 0.5 and an abaxial stomatal index of 24.2 ± 0.9. The size and general morphology of wax2 stomata appeared normal, although electron microscopy studies are needed to verify this finding. The stomatal and pavement cell density was higher in wax2 than in the wild type (Table 2). wax2 leaves were slightly smaller than wild-type leaves, indicating that there was probably less expansion of epidermal cells in wax2 than in the wild type during leaf development.

Table 2.Table 2.
Arabidopsis Ecotype C24 and Mutant wax2 Stomatal and Pavement Cell Densities and Stomatal Index of Adult-Phase Leaf Blades

Chlorophyll efflux studies showed that rates of chlorophyll extraction by 80% ethanol during a 24-h period were greater in both leaves and stems of wax2 than in the wild type (Figure 8). In addition, preflowering wax2 rosettes sustained greater foliar injury than wild-type rosettes when sprayed with either acifluorfen or paraquat. Visual scoring using a modified Horsfall-Barret scale revealed 81% discoloration and 80% wilting of wax2 leaves compared with 21% discoloration and 27% wilting of wild-type leaves at 24 h after paraquat application. Results using acifluorfen were similar (data not shown). In addition, epidermal permeability to water vapor was higher in wax2 than in the wild type and all other mutants examined (Figure 9). wax2 plants had higher transpiration rates than wild-type plants in both light and dark environments but had normal stomatal closure response time after transfer from light to darkness and normal stomatal opening response time after transfer from dark to light (Figure 9). Similar results were seen for whole preflowering plants (data not shown).

Figure 8.Figure 8.
Permeability to Chlorophyll by Arabidopsis Ecotype C24 and the wax2 Mutant.
Figure 9.Figure 9.
Transpiration Rates (±sd) of Arabidopsis Ecotype C24 and the wax2 Mutant.

DISCUSSION

The WAX2 Protein Functions in Cuticle Membrane and Wax Production
The wax2 mutant's reduction in cuticle membrane reticulation and the presence of regular bulges of cuticular material in outer cell walls indicate that the wax2 cuticle membrane undergoes very irregular development. Increased thickness and increased translucence, along with the loss of general organization of the wax2 cuticle membrane, suggest a potential disruption in the linkages that normally hold the cuticle membrane lipids together. Whether these changes are caused by alterations in the synthesis of certain cutin monomers (the major cuticle membrane subunit) or by covalent bonds between cutin monomers that form the cutin polyester framework of the membrane remains unclear.

Previous studies suggest that wax compositional changes such as those that occur in wax2 could not have caused these ultrastructural changes in wax2 cuticle membrane. First, exhaustive extraction of waxes from cuticles does not alter cuticle membrane ultrastructure, except for a slight reduction in the visibility of cuticle proper lamellae (Viougeas et al., 1995). Second, the cuticle membranes of seven wax mutants in sorghum and five wax mutants in Arabidopsis, including cer1, were ultrastructurally normal (Jenks et al., 1994; M.A. Jenks, unpublished data). By comparison, it seems unlikely that alteration in the cuticle membrane ultrastructure of wax2 could have caused such a large reduction in wax amount on wax2. Cuticle membrane alteration also would not be expected to suppress just one branch of the wax synthetic pathway, as occurs on wax2 (i.e., wax2 primarily inhibits the conversion of acyl-CoAs to aldehydes, as discussed below). Also, wax2's outer epidermal cell walls were much more darkly stained with osmium (as reported for sorghum bm2), suggesting the accumulation of new materials. Whether these new cell wall deposits represent the accumulation of cuticle precursors or secreted proteins required for cuticle synthesis is uncertain. Potentially, WAX2 plays a role in the conversion or secretion of cuticle lipid precursors common to both cutin and wax pathways.

The predicted WAX2 protein has 32 and 35% sequence identity to the predicted Arabidopsis CER1 and maize GL1 proteins, respectively, and mutations in both CER1 and GL1 cause dramatic alterations in the amount, composition, and crystallization patterns of their cuticular waxes (Lorenzoni and Salamini, 1975; Bianchi et al., 1985; Jenks et al., 1995). Aarts et al. (1995) predicted that CER1 could code for a putative plant decarbonylase, because cer1 is proportionally deficient only in alkanes (and alkane-derived metabolites) and had increased aldehydes, and that the CER1 protein had metal binding motifs found in other lipid-synthesizing proteins (Cheesbrough and Kolattukudy, 1984; Dennis and Kolattukudy, 1992). In contrast to cer1, the stems of wax2 are deficient in both aldehydes and alkanes (and its metabolites), suggesting that wax2's primary blockage (Figure 10) occurs in the metabolic step preceding that blocked by cer1. Conversely, Hansen et al. (1997) suggested that the homologous GL1 could not code for a decarbonylase because the gl1 mutant actually had higher proportions of alkanes than the wild-type parent and the GL1 protein lacked the third His-rich motif required for iron binding. Instead, based on the predicted secondary structure of GL1 and CER1, Hansen et al. (1997) suggested that these proteins might belong to a superfamily of integral membrane receptors that are composed of a hydrophobic N-terminal domain with seven transmembrane-spanning regions and a globular water-soluble C-terminal domain (Probst et al., 1992). Although WAX2, CER1, and GL1 have comparable transmembrane structures, our analysis using Sequence BLAST and multiple alignments using CLUSTAL W 1.82 did not show high similarity to membrane receptors.

Figure 10.Figure 10.
Model Pathway for Acyl-CoA Conversion in Cuticle Lipid Metabolism.

Our analysis (like that of Aarts et al., 1995) indicates that WAX2 is homologous with lipid metabolic proteins. The WAX2 amino acid sequence was 95.4% aligned with the signature sequence (CD length of 216 residues) of the sterol desaturase family at the N-terminal end and contained the three His-rich motifs conserved in this family. These His-rich motifs are associated with diiron-oxo binding and are required for catalytic activity in enzymes such as fatty acyl desaturase, alkane ω-hydroxylase, xylene monooxygenase, C-5 desaturase, and C-4 sterol methyl oxidase (Fox et al., 1994; Shanklin et al., 1994, 1997; Bard et al., 1996; Gachotte et al., 1996). The C-terminal end of WAX2 (residues 456 to 497) was 16.7% aligned with the signature sequence (CD length of 252 residues) of the SDR. The homology with SDR existed only in WAX2 (and Rice and Senecio WAX2 homologs) and not in GL1, CER1, and CER1-like proteins. The SDR family contains a wide variety of dehydrogenases, most of which are known to be NAD- or NADP-dependent oxidoreductases. Members of this SDR family include acetoacetyl-CoA dehydrogenase, 3-oxoacyl(acyl-carrier protein) reductase, NADH-dependent carbonyl reductase, alcohol de-hydrogenase, d-β-hydroxybutyrate dehydrogenase, and retinol dehydrogenase (from PROSITE, http://ca.expasy.org/cgi-bin/prosite-search-ac?PDOC00060).

Potentially, wax2's effect on both cuticle membrane and wax pathways might be explained if WAX2 is a fusion of two functional proteins containing both sterol desaturase and SDR domains that play separate roles in each part. These separate domains in WAX2 even appear to include the conserved residues essential for distinct catalytic function. Previously, a single gene from yeast was shown to encode a cytochrome b5 sequence fused to the C-terminal domain of a Δ9-18:0-CoA desaturase (Mitchell and Martin, 1995), and single genes from both yeast and plants have cytochrome b5 at the N terminus of a sphingolipid desaturase (Mitchell and Martin, 1997; Sperling et al., 1998). An alternative hypothesis is that WAX2 possesses a single catalytic site capable of more than one kind of reaction. Xylene monooxygenase (of the sterol desaturase family) from Escherichia coli catalyzes each step in the oxygenation of toluene and pseudocumene to the corresponding alcohols, aldehydes, and acids (Buhler et al., 2000), and oleate hydroxylase from Lesquerella fendleri has both hydroxylase and desaturase activities (Broun et al., 1998a, 1998b). Broun et al. (1998b) showed how only seven residues were strictly conserved in a comparison among six desaturases. Interestingly, as few as four amino acid substitutions converted a strict desaturase to an enzyme that retained some desaturase activity but also was an efficient hydroxylase, and as few as six amino acid substitutions increased desaturation activity in a hydroxylase.

The broad range of activities and catalytic plasticity associated with both the sterol desaturase and SDR families, and the cuticle properties of the wax2 mutant, lead us to speculate that WAX2 may participate in the modification of more than one cuticle lipid substrate. Specifically, WAX2 could be a multifunctional enzyme involved in both the reduction of acyl-CoAs to aldehydes (which is required for the synthesis of alkane and its metabolites) and the hydroxylation of acyl-CoAs to certain cutin monomers (Figure 10). However, additional studies are needed.

WAX2 Contributes to the Suppression of Postgenital Fusion
The wax2 mutant often displays postgenital fusion. Likewise, the glossy-stemmed Arabidopsis mutants wax1 (Jenks et al., 1996) and ded (Lolle et al., 1998) and the semiglaucous mutants cer10 and cer13 have organs that undergo postgenital fusion. Fusion in wax2, cer10, and cer13 is less severe than that in wax1 and ded. Other Arabidopsis mutants that show postgenital fusion are ahd, bud, cod, fdh, hth, phd, thd (Lolle et al., 1998), and lcr (Wellesen et al., 2001). However, none of these mutants has altered visible wax deposition. Interestingly, the FDH and LCR genes were cloned and found to encode putative cuticle lipid-synthesizing enzymes (Yephremov et al., 1999; Pruitt et al., 2000; Wellesen et al., 2001). Whether these fusion mutants with normal glaucousness have changes in their cuticle ultrastructures or compositions has not been reported. Ectopic expression of the cutinase gene from Fusarium solani f.sp. pisi in Arabidopsis led to altered cuticle membrane ultrastructure, increased cutin monomers, and postgenital fusion (Sieber et al., 2000), providing additional evidence for cutin involvement in fusion. In wax2, fully expanded leaves do not fuse upon physical contact, suggesting that fusion competence occurs in primordial or young organs. Potentially, postgenital fusion by wax2 could be caused by a delay or reduction in cuticle deposition early in organ formation. In the wild type, the cuticle itself could act as the suppressor of postgenital fusion by blocking the diffusion of morphogenic signal compounds that normally function in cell-to-cell fusion, as occurs between carpels (Verbeke and Walker, 1986). Alternatively, WAX2 itself could synthesize lipids involved in signaling epidermal development. Further studies of cuticle involvement in the regulation of plant development are needed.

WAX2 Plays a Conditional Role in Pollen Fertility
Like certain cuticular wax mutants in Arabidopsis (Koornneef et al., 1989), wax2 shows severe male sterility in low-humidity environments that can be overcome in high humidity. Similarly, reduced fertility in cer1 and cer6 also was male gamete specific and associated with the alteration of certain pollen coat lipids (Preuss et al., 1993; Aarts et al., 1995; Fiebig et al., 2000). Evidence that altered pollen lipids disrupt normal pollen-stigma communication includes the following: (1) cer1 and cer6 pollen induces noncompatibility reactions (callose synthesis) in normally compatible stigmas; (2) wild-type, cer1, and cer6 pollen germinate in an artificial medium equally well; and (3) wild-type, cer1, and cer6 pollen placed on the same stigma induce the secretion of stigma water, leading to pollen hydration and almost normal development of the wild-type and mutant pollen. It has been proposed that altered pollen lipid composition and ultrastructure may disrupt pollen-stigma communication, but a detailed study of most pollen lipid components (such as cutin, wax esters, shorter chain lipids, and others) has not been reported. Also, whether the deficiency in lipid globules of the cer6 exine (which is visible by transmission electron microscopy) is attributable to a reduction in waxes is doubtful, because long-chain waxes typically form crystalline structures. Recent reports that cis-unsaturated triacylglycerides may serve as stigma-pollen recognition signals (Wolters-Arts et al., 1998) raise intriguing questions about the role of these wax gene products in synthesizing fertility-regulating signaling compounds. Whether wax2 alters the synthesis of signaling compounds, or simply changes pollen or stigma permeability to the diffusion of other signaling molecules, is an important question for future studies.

WAX2 Affects Epidermal Permeability
The Arabidopsis wax2 mutant had increased transpiration rates relative to the wild type, both when stomata were assumed primarily open (in light) and when stomata were assumed closed (in dark), even though wax2 has fewer stomata. The response time for light-induced changes in transpiration were identical in the wild type and wax2, indicating that stomatal function in this respect is normal. Relative to the wild type, chlorophyll is extracted more rapidly from leaves and stems of wax2, and the wax2 mutant shows higher susceptibility to two foliarly applied herbicides, indicating that larger molecules than water also penetrate the cuticle more easily. Increased epidermal permeability to both water and larger compounds by wax2 was not unexpected, because Niederl et al. (1998) suggested that water and organic compounds such as the herbicide 2,4-D diffuse along identical amorphous pathways in the cuticle. Exactly how diffusion pathways have changed in wax2 remains unclear. wax2 has reduced visible density in the cuticle membrane, suggesting that the internal molecular packing of cuticle lipid molecules may be less dense. If this is so, the proportion of crystalline regions in the cuticle, which serve as exclusion zones for diffusion (Baur et al., 1999), may be reduced, leading to more direct pathways for water diffusion through wax2 cuticles. The effect of wax2 on cuticles that overlie the stomatal ridges, pores, or substomatal chambers (Osborn and Taylor, 1990; Zhao and Sack, 1999) or the inner epidermis adjacent to the mesophyll (Pesacreta and Hasenstein, 1999) is unknown. Studies to assess the relative impact of wax2 on the permeability of cuticle membranes associated with epidermal pavement cells (inner and outer surfaces) and the stomatal complexes are needed to provide a more complete understanding of wax2's effects on plant water relations and epidermal permeability.

WAX2 Affects Epidermal Architecture
Wax mutants often possess altered stomata. For example, leaf surfaces of Arabidopsis cer1 and cer6 mutants have higher stomatal indices than those of their isogenic wild-type parent (Gray et al., 2000), and 12 mutant alleles of the cer-g locus in barley have abnormal stomatal morphology (Zeiger and Stebbins, 1972). By contrast, wax2 has a lower stomatal index than the wild type. As opposed to stomatal density, which could be changed by differences in leaf and cell expansion, the stomatal index describes the number of stomata as a function of total cell number. Thus, fewer stomata (and more pavement cells) were initiated in the leaf primordium of wax2 than in the wild type. Whether wax2 cuticle alterations influence the synthesis or diffusion of chemical signals that direct stomatal initiation during epidermal development is the subject of ongoing studies. Interestingly, WAX2 plays a role in the formation of both the cuticle and the stomata, two epidermal traits critically involved in transpirational control and, ultimately, plant drought tolerance.

Conclusions
The wax2 mutation identified a novel gene that functions in both cuticle membrane and cuticle wax production. Our studies reveal a possible role for the cuticle as a suppressor of organ fusion early in organ formation and provide further evidence for a connection between the cuticle and both fertility and the development of epidermal architecture (via effects on the stomatal index). Whether these functions are associated with genetics, chemical signaling, physical effects, or other mechanisms remains unclear. The WAX2 gene is homologous with Arabidopsis CER1. However, mutation in CER1 alters wax but not the cuticle membrane. Comparisons of the predicted WAX2, CER1, and GL1 proteins, and the phenotypes of their respective mutants, lead us to predict that the WAX2 gene product has a metabolic function. Further studies of WAX2 are needed to provide a better understanding of gene involvement in plant cuticle production and to advance our understanding of the cuticle's role in plant development.

METHODS

Genetic Analysis of wax2
The activation T-DNA vector pSKI015 was used to generate an insertion mutant population (T1) in the genetic background of Arabidopsis thaliana ecotype C24 as described by Weigel et al. (2000). Bialophos resistance was used as the selectable marker. Plants were grouped into pools of 10 families, and T2 progeny of ~200 plants from these pools were screened for mutants with reduced visible glaucousness of the inflorescence stem surface. Mutagenized populations were grown in a greenhouse at Purdue University using overhead irrigation, natural light, and a temperature of ~22°C. The original mutants were given a secondary screen for water loss from excised stems and whole plant transpiration rates (see below). Mutants with high transpiration rates were examined subsequently for changes in cuticle membrane weight and ultrastructure (see below).

Analysis of the Cuticle Membrane
The cuticle and outer cell wall ultrastructures of inflorescence stems and abaxial and adaxial leaf epidermises of 6-week-old plants were viewed by transmission electron microscopy. Stem specimens were collected from the middle of the first (lowest) internode, whereas leaf samples were collected from the middle of the blade between the midvein and the margin of leaf 8. The samples were fixed for 1 h at room temperature in primary fixative containing 2.5% (v/v) glutaraldehyde and 2% (v/v) formaldehyde in 0.05 M phosphate buffer, pH 6.8 (PB) (Karnovsky, 1965). A microwave oven (model 3450; Ted Pella, Redding, CA) with vacuum was used to improve cuticle fixation. Various microwave treatments were tested and compared with standard fixation at room temperature; two 40-s microwave treatments using the low power setting, with a 3-min period between the two exposures, provided excellent preservation. After fixation, samples were washed with PB and postfixed for 1 h in 2% (v/v) osmium tetroxide in 0.05 M PB. One 40-s microwave treatment with vacuum as described above was applied during osmium fixation. After washing with PB, the tissues were dehydrated through a gradient series of ethanol, infiltrated with Spurr's embedding medium (Electron Microscopy Sciences, Fort Washington, PA), and polymerized for 48 h at 60°C. Ultrathin sections (80 to 100 nm) were prepared from Spurr's resin–embedded samples and mounted on carbon-coated Formvar 100-mesh copper grids (Electron Microscopy Sciences). Sections were air-dried, stained at room temperature with 2% (v/v) uranyl acetate for 5 min, and then stained with lead citrate for 3 min before viewing with a Philips EM 400 electron microscope (FEI Co., Hillsboro, OR).

Gravimetric measurements of cuticle membrane weight were determined for wild-type and wax2 inflorescence stem samples collected from the first internodes of 6-week-old plants. After removing soluble cuticular waxes by means of a 30-s dip in hexane, stem samples were soaked for 8 h in a 60% (w/v) solution of ZnCl in HCl to separate cuticle membranes from underlying stem tissues (Jenks et al., 1994). Bulk samples of 30 stem cuticle membranes (separated with a dissecting microscope) were placed on glass microscope cover slips, oven-dried at 50°C, and then placed in a desiccator containing dried silica gel for at least 12 h. Average cuticle membrane weights per surface area (stem segment circumference times height) for each line were determined from six replicate bulk samples using a microbalance. Leaf cuticles regularly broke up during ZnCl-HCl treatments, especially those of wax2. For that reason, leaf cuticle weights were not determined.

Analysis of Cuticular Waxes
Scanning electron microscopy was used to analyze epicuticular wax crystallization patterns. Leaf and stem (first internode above the rosette) samples were collected from Arabidopsis wild-type and wax2 plants after 6 weeks of growth. Four replicates of each sample were mounted on aluminum stubs and sputter-coated with gold palladium using six 30-s bursts from the sputter coater. Previous research showed that air-dried samples coated in this way were similar to specimens prepared using low-temperature scanning electron microscopy with little evidence of artifacts in wax crystallization patterns (Jenks et al., 1992). Coated surfaces were viewed using a JEOL JSM-840 scanning electron microscope at 5 kV.

For compositional analysis, cuticular wax samples were extracted from the leaves and stems of flowering Arabidopsis wild-type and wax2 plants after 6 weeks of growth. Leaf and stem (representing the first through fifth internodes) samples were inserted into a 20-mL standard glass scintillation vial, and ~15 mL of gas chromatography–grade hexane was added. The tissues were agitated for 30 s, and the solvent was decanted into new scintillation vials. Tissues and vials were given a 1-s rinse with approximately 2 mL of hexane, and then the solution was decanted into the sample vial. Thus, the leaf extracts contain waxes from both abaxial and adaxial leaf surfaces and, like stems, showed little or no coloration as a result of chlorophyll or other internal lipids. Wax compositional analysis was performed according to Jenks et al. (1995). The hexane-soluble cuticular wax extracts were evaporated to dryness under a nitrogen stream, and the dried residue was prepared for gas chromatography by derivatization using N,O-bis(trimethylsilyl)trifluoroacetamide. Derivatization was for 15 min at 100°C. After surplus N,O-bis(trimethylsilyl)trifluoroacetamide was evaporated under nitrogen, the sample was redissolved in hexane for analysis with a Hewlett-Packard 5890 series II gas chromatograph equipped with a flame ionization detector (Palo Alto, CA). The gas chromatograph was equipped with a 12-m, 0.2-mm HP-1 capillary column with helium as the carrier gas. The gas chromatograph was programmed with an initial temperature of 80°C and increased at 15°C/min to 260°C, at which point the temperature remained unchanged for 10 min. The temperature then was increased at 5°C/min to 320°C, at which point the temperature was held for 15 min.

Quantification was based on flame ionization detector peak areas and the internal standard hexadecane. Specific correction factors were developed from external standards and applied in a standard manner as described by Jenks et al. (1995)(1996). The total amount of cuticular wax was expressed per unit of stem or leaf surface area. Stem surface areas were calculated as the surface area of a right circular cylinder, and leaf areas were determined using computer digitization (NIH Image version 1.62). All values represent averages of four replicate plant samples ± sd. Selected subsamples were used for injection in a gas chromatograph–mass spectrometer (FinniganMAT/Thermospray Corp., San Jose, CA) to produce electron ionization mass spectra to verify the identities of all components.

Plasmid Rescue and Linkage Analysis
Plasmid rescue was performed according to Weigel et al. (2000). The restriction enzymes EcoRI and HindIII were used to rescue the right T-DNA border flanking sequences, and BamHI was used for left border rescue. The rescued sequences were sequenced directly from both ends using primers designed from inside the restriction site sequences and the T-DNA border sequences. The flanking gene-specific DNA sequence was searched against the Arabidopsis genome database (http://www.ncbi.nlm.nih.gov/PMGifs/Genomes/ara.html). A primer pair designed from the rescued T-DNA and flanking gene-specific sequence (SKIAV, 5′-TCACGGATCGACTGCTTCT-3′; and P2, 5′-CACTTCTGCTACACTCTA-CT-3′) and a primer pair across the insertion designed from At5g57800 (P1, 5′-TTCTTCACACATTACCACTCT-3′; and P2) were used for PCR analysis of the wax2-1 backcross F2 population for linkage between the tagged sequence and the mutant phenotype. The PCR primers used to check the linkage between wax2-2's visible mutant phenotypes and the flanking T-DNA were P3 (5′-AGATTGATCACGAATGGCACT-3′) and P4 (5′-TTTCCAATAACGTTGCGTTTC-3′) from the WAX2 gene and GarlicLB2 (5′-ATCTTCCCAAATTACCAATACA-3′) from the T-DNA left border.

5′ and 3′ Rapid Amplification of cDNA Ends
The full-length cDNA clone was obtained by 5′ and 3′ rapid amplification of cDNA ends (RACE) using the SMART RACE cDNA Amplification Kit (BD Biosciences Clontech, Palo Alto, CA) as described by the manufacturer. The gene-specific primers used for RACE were designed from the EST and the At5g57800 putative mRNA sequence. The primers for 5′ RACE were 5R1 (5′-TCCTGCTTGCATCTCCTTTCACCTG-3′) and 5R2 (5′-GGCTCCAGTCAAGAAAACCTC-3′). The primers for 3′ RACE were P1 and 3R2 (5′-GTGCCGGAGTTTGTGTTCTTA-3′). The PCR fragments were cloned into the pGEM-T Easy vector (Promega, Madison, WI).

DNA and RNA Gel Blot Analysis
Genomic DNA was isolated from rosette leaves according to Dellaporta et al. (1983) with minor modifications. DNA was digested using three restriction enzymes, HindIII, BamHI, and EcoRI, and fractionated using electrophoresis. A BAR gene fragment was used as a DNA probe. The probe was labeled with α-32P-dCTP (DuPont–New England Nuclear) using the random prime labeling kit (Decaprime II; Ambion, Austin, TX). Membranes were washed at 42°C in 2× SSC (1× SSC is 0.15 M NaCl and 0.015 M sodium citrate) and 0.1% SDS twice for 5 min followed by washing in 0.1× SSC and 0.1% SDS twice for 15 min.

Total RNA was isolated from various tissues using the RNeasy Plant Mini Kit (Qiagen, Valencia, CA) as described by the manufacturer. RNA gel blot analysis was performed according to standard methods. The 1.8-kb EcoRI-digested fragment from the 5′ RACE product was used as a probe, with probe labeling and hybridization the same as for the DNA blot.

Bioinformatics
Multiple sequence alignment was performed with CLUSTAL W (Thompson et al., 1994) using default parameters through BCM Search Launcher (http://searchlauncher.bcm.tmc.edu/multi-align/multi-align.html). The boxshade was created by BOXSHADE 3.21 (http://www.ch.embnet.org/software/BOX_form.html). The rooted phylogenetic tree was constructed using CLUSTAL W (Thompson et al., 1994). Transmembrane analysis was performed using TMHMM (http://www.cbs.dtu.dk/services/TMHMM/).

Quantifying Epidermal Traits of the Wild Type and wax2
To quantify excised stem water loss rates, stems of 6-week-old plants were excised and the cauline leaves were removed. The stems were placed immediately in water (in the dark) and soaked for 60 min. Stems removed from soaking were shaken gently and blotted to remove excess water, suspended in complete darkness, and weights were determined gravimetrically every 30 min using a microbalance. For whole plant transpiration measurements, flowering plants were grown in 3-inch pots enclosed in polyethylene bags and bound either over or under the rosette to prevent water loss except through the exposed plant surfaces. The contact point between the bag and the stem or crown was sealed with Parafilm to prevent water loss between the plant and the pot enclosure. Allowing 8 h for plant transpiration rates to stabilize, transpiration rates of three wild-type and three wax2 replicates were monitored instantaneously using six electronic balances and WinWedge data-acquisition software (TalTech, Philadephia, PA). To increase water loss amounts to improve measurement accuracy, three plants placed on one balance constituted one replicate. Measurements were performed in complete darkness (when stomata were assumed generally closed) and in the light (when stomata were assumed generally open). A 400-W metal halide lamp provided illumination (120 μmol·m−2·s−1). Temperature during the study ranged from 27 to 28°C, and RH was between 32 and 42%. Short-term responsiveness of transpiration to light-dark transitions was monitored as a means of describing stomatal responsiveness. Excised stem water loss also was examined in segregating populations, as described by Jenks et al. (1994), between the wild type and wax2 to verify that high water loss cosegregated with the visible phenotypes (see above).

Epidermal permeability also was measured using chlorophyll efflux and foliarly applied herbicide sensitivity studies. Twenty whole preflowering rosettes and stem first internodal segments were collected from 4- and 6-week-old plants, respectively, and immersed in an 80% ethanol solution in glass scintillation vials. Vials were covered with aluminum foil and agitated gently on a shaker platform. Aliquots of 100 μL were removed at 10 min, 30 min, 50 min, and 24 h after initial immersion. The amount of chlorophyll extracted into the solution was quantified using a UV-2102 PC spectrophotometer (UNICO, Dayton, NJ) and calculated from UV light absorption at 647 and 664 nm as described by Lolle et al. (1998). Total chlorophyl was expressed for each time point as a percentage of total chlorophyll extracted after 24 h. Herbicide sensitivity of the wild type and wax2 was determined for two herbicides, paraquat and acifluorfen, after initial dose-response curves were established for the wild type to approximate 50% lethal dose levels. Seven replicates of each line were treated with doses just above the 50% lethal dose. Injury was scored visually by three investigators over a 48-h time course according to a modified Horsfall-Barret scale (0 to 10, with 0 indicating no damage and 10 representing 100% of tissue showing any discoloration).

Stomatal density, epidermal pavement cell density, and stomatal index for both the adaxial and abaxial surfaces were determined using light microscopy modified according to Gray et al. (2000). Instead of dental rubber impressions, we created imprints using Duro Super Glue (Loctite, Avon, OH; cyanoacrylate) of 1.01-mm2 areas taken from the middle of the leaf blade between the midrib and the margin. Leaves were selected for uniform size, being numbered 20 to 23 from the first true leaves, and the plants were 39 days old. Values for stomatal index presented for each surface represent the average of at least 9 to 12 replicate imprints.

Upon request, all novel materials described in this article will be made available in a timely manner for noncommercial research purposes.

Accession Numbers
The GenBank accession number for the WAX2 nucleotide sequence is AY131334. Other accession numbers are as follows: At5g57800, NM125164; epi23, L33792; partial rice sequence annotated as a GLOSSY1 homolog, T04146; maize GLOSSY1, U37428; Arabidopsis CER1, U40489; Senecio odorus partial protein sequence, L33792; Arabidopsis CER1L19, X95965; and Schizosaccharomyces pombe C-4 methyl sterol oxidase of the desaturase family, T38986.

Acknowledgments

We thank Syngenta for providing the T-DNA mutant line SAIL 832 E06 and the Salk Institute Genomic Analysis Laboratory for providing the sequence-indexed Arabidopsis T-DNA insertion mutant (SALK 034318). We also thank Debra Sherman of the Purdue University Electron Microscopy Center. This article is publication 16904 of the Purdue University Office of Agricultural Research.

Notes
Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.010926.
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