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Bibliographic record
Abstract
Identification of the biosynthetic enzymes involved in cell wall biosynthesis remains one of the major unsolved problems of plant biology. Of the major polysaccharides of the plant cell wall, pectins and hemicelluloses are synthesized in the Golgi, and callose and cellulose are synthesized at the plasma membrane. The evidence is now quite extensive that the catalytic subunits of cellulose synthase are encoded by members of the largeCESA gene family (Arioli et al., 1998; Fagard et al., 2000;Holland et al., 2000; Taylor et al., 2000). With a few exceptions, however, the genes for the enzymes of pectin and hemicellulose biosynthesis have not been identified (Edwards et al., 1999; Perrin et al., 1999). Nothing is currently known about the genes encoding the enzymes that catalyze the synthesis of the hemicellulose backbones. The primary cell walls of all higher plants contain large amounts of cellulose in their walls, and, consistent with this, CESAgenes are found throughout the plant kingdom (Richmond, 2000; Richmond and Somerville, 2000). In contrast, the hemicelluloses of dicotyledons and graminaceous monocotyledons (cereals) are distinct. Whereas dicots contain large amounts of pectin and xyloglucan, cereals contain low amounts of pectin and xyloglucan, large amounts of glucuronoarabinoxylan, and, at least in some tissues, the cereal-specific polymer (1–3),(1–4)-β-d-glucan (also known as mixed-linked glucan) (Carpita and Gibeaut, 1993; Carpita, 1996). On the basis of these structural differences, it would be expected that dicots and cereals would have a distinct panoply of hemicellulose biosynthetic enzymes. Plants contain a superfamily of genes, called CSL (cellulose synthase-like), whose amino acid sequences are related to theCESA genes. The Csl proteins are predicted to be integral membrane proteins and contain a sequence, the “D,D,D,QXXRW” motif, that seems to be characteristic of processive glycosyl transferases (Saxena and Brown, 1995). On these grounds, it has been proposed that the CSL genes encode the catalytic subunits of the enzymes that synthesize the hemicellulose backbones (Richmond and Somerville, 2000, 2001). Although no biochemical function has yet been elucidated for anyCSL gene, three studies implicate them in wall biosynthesis. Root hairs of Arabidopsis plants that are mutated in AtCSLD3are defective, apparently because of abnormal cell walls (Favery et al., 2001; Wang et al., 2001). A gene (NaCSLD1) that is highly expressed in Nicotiana alata pollen tubes, whose walls are composed almost entirely of callose and cellulose, has been proposed to encode a pollen-specific cellulose synthase (Doblin et al., 2001). Arabidopsis mutants in AtCSLA9 have increased resistance to Agrobacterium tumefaciens, which binds to plant cell walls at an early stage of infection (Nam et al., 1999). With the completion of the Arabidopsis genome, every CSLgene in this plant has been identified (Richmond and Somerville, 2001). The rice (Oryza sativa) genome is expected to be complete by the end of 2002, and currently, approximately 50% of the rice genome is available either publicly in GenBank or through Monsanto's password-protected web site (http://www.rice-research.org). Approximately 80,000 rice expressed sequence tags (ESTs) and the actual corresponding cDNAs are also in the public domain. We present here an analysis of the CSL genes present in the available rice sequence databases. We have identified 37 CSLgenes and have deduced full-length protein coding sequences for 23 of them (Table I). The genes were identified by BLAST searches of GenBank (nonredundant and dbEST) and the Monsanto database using the Arabidopsis CesA and Csl proteins as queries. Richmond's web page (http://cellwall.stanford.edu) served as a very useful starting point for the analysis. cDNAs corresponding to all OsCSL ESTs were obtained from the appropriate sources and sequenced completely. Most of the cDNAs came from the Rice Genome Research Program (http://rgp.dna.affrc.go.jp). The Rice Genome Research Program cDNA clones were of high quality; all but one were viable and accurately annotated. The one exception,D22177, was chimeric, containing OsCSLA2 at one end and a predicted DNA-binding protein at the other. For all sequences, the corresponding proteins were deduced using gene prediction software from GeneMark (Atlanta;http://opal.biology.gatech.edu/GeneMark) and Softberry, Inc. (White Plains, NY; http://www.softberry.com), and by manual alignment with the Arabidopsis Csl proteins and with each other. The sequences were aligned with Clustal X and presented with TreeView (Glasgow, UK) and CorelDraw (Ottawa, ON, Canada) (Thompson et al., 1994; Page, 1996; Jeanmougin et al., 1998). The CSL superfamily of rice Sequences are available at www.prl.msu.edu/walton. To the extent possible, the gene nomenclature has been made consistent with that of Richmond (http://cellwall.stanford.edu). OSM indicates a Monsanto database accession number; all other accession numbers refer to GenBank. Multiple OSM contigs for a single gene indicate that the contigs overlap; OSM151756, OSM14798, and OSM14796overlap to form one contig containing two CSLF genes, which are also present on AP004261 along with OsCSLF1 andOsCSLF2. Indicates whether a full-length protein can be deduced with reasonable confidence. Accession numbers starting with AF are standard GenBank entries. Numbers starting with BK are in the GenBank Third Party Annotation database. There appear to be three frameshifts within an ∼80-bp region of CSLA4. Two apparently independent genomic sequences containing this gene, one from Monsanto (OSM11235) and the other from The Institute for Genomic Research (TIGR) (GenBank AC073556), are identical. The sequence covering this region in AC073556 is of “very high quality” (Robin Buell, TIGR, personal communication). Therefore, CSLA4 is probably a pseudogene. NS, not sequenced. The sequence of AU166554 did not correspond to the published EST sequence; the source of this discrepancy has not been determined. the “equals” sign indicates that the two accession numbers represent two EST sequences from the same cDNA clone, confirmed by complete sequencing of the cDNA. These DNA sequences were concluded to contain the following errors: three frame shifts in OsCSLA8; one frame shift in OsCSLA9; one frame shift and one in-frame stop codon in OsCSLA10 (in addition, OSM124376 is probably chimeric); two nucleotide omissions in the genomic sequence ofOsCSLH1 (OSM16234), which were identified by comparison to the cDNA sequence of AU085988; an intron start of GC instead of GT inOsCSLD3; one frame shift in OsCSLE4; five frame shifts and an in-frame stop codon in OsCSLE5; a frame shift and two in-frame stop codons in OsCSLF5. If any of these assumed errors are real, then the corresponding genes might be pseudogenes. The sequence of OSM133403 is interrupted by a string of undefined nucleotides (NNNN...). It has therefore been submitted to GenBank as two sequences. The undefined sequences occur within an intron, which has been established using the sequence of an overlapping cDNA, and therefore do not affect the deduced protein sequence. The CSL superfamily of rice Sequences are available at www.prl.msu.edu/walton. To the extent possible, the gene nomenclature has been made consistent with that of Richmond (http://cellwall.stanford.edu). OSM indicates a Monsanto database accession number; all other accession numbers refer to GenBank. Multiple OSM contigs for a single gene indicate that the contigs overlap; OSM151756, OSM14798, and OSM14796overlap to form one contig containing two CSLF genes, which are also present on AP004261 along with OsCSLF1 andOsCSLF2. Indicates whether a full-length protein can be deduced with reasonable confidence. Accession numbers starting with AF are standard GenBank entries. Numbers starting with BK are in the GenBank Third Party Annotation database. There appear to be three frameshifts within an ∼80-bp region of CSLA4. Two apparently independent genomic sequences containing this gene, one from Monsanto (OSM11235) and the other from The Institute for Genomic Research (TIGR) (GenBank AC073556), are identical. The sequence covering this region in AC073556 is of “very high quality” (Robin Buell, TIGR, personal communication). Therefore, CSLA4 is probably a pseudogene. NS, not sequenced. The sequence of AU166554 did not correspond to the published EST sequence; the source of this discrepancy has not been determined. the “equals” sign indicates that the two accession numbers represent two EST sequences from the same cDNA clone, confirmed by complete sequencing of the cDNA. These DNA sequences were concluded to contain the following errors: three frame shifts in OsCSLA8; one frame shift in OsCSLA9; one frame shift and one in-frame stop codon in OsCSLA10 (in addition, OSM124376 is probably chimeric); two nucleotide omissions in the genomic sequence ofOsCSLH1 (OSM16234), which were identified by comparison to the cDNA sequence of AU085988; an intron start of GC instead of GT inOsCSLD3; one frame shift in OsCSLE4; five frame shifts and an in-frame stop codon in OsCSLE5; a frame shift and two in-frame stop codons in OsCSLF5. If any of these assumed errors are real, then the corresponding genes might be pseudogenes. The sequence of OSM133403 is interrupted by a string of undefined nucleotides (NNNN...). It has therefore been submitted to GenBank as two sequences. The undefined sequences occur within an intron, which has been established using the sequence of an overlapping cDNA, and therefore do not affect the deduced protein sequence. Like the Arabidopsis Csl proteins, all of the rice Csl proteins are predicted to be integral membrane proteins. All except two have the QXXRW motif (Saxena and Brown, 1995). The exceptions are OsCslA10, which has RXXRW, and OsCslE2, which has LXXRW, at the equivalent positions. All of the OsCsl proteins have a DXD motif approximately 120 to 250 amino acids upstream of QXXRW. Unrooted phylogenetic tree of Csl proteins from rice and Arabidopsis. Only the deduced full-length rice Csl (OsCsl) proteins are included. The Arabidopsis Csl coding sequences were deduced by the same criteria used for the rice proteins and the sizes of many of the AtCsl proteins differ slightly from those given by Richmond (http://cellwall.stanford.edu). All of the Arabidopsis CslB, CslD, CslE, and CslG proteins are included, but for clarity only three of nine AtCslA, three of five AtCslC, and a sampling of maize (Zea mays), rice, and Arabidopsis CesA proteins are shown; inclusion of the others did not significantly change any of the relationships. The lengths of each deduced protein in number of amino acids are indicated after the protein names. First, rice has a group of CSL genes, the products of which are related to CesA and CslD but nonetheless form a distinct group separate from either of these families (Fig. 1). These proteins are also significantly shorter than the CesA or CslD proteins because of truncation at their N termini (Fig. 1). On these grounds, we propose that these genes constitute a new cereal-specific family, for which we propose the name CSLF. (As with earlier classifications of the CSL genes [Richmond and Somerville, 2001], the family designations are solely for nomenclatural convenience and do not necessarily reflect any underlying functional relationships). The products of OsCSLF1 and OsCSLF2 have >98% amino acid identity but are clearly two different genes based on a number of nucleotide differences in their 5′- and 3′-untranslated regions. OsCSLF1, OsCSLF2, OsCSLF3, and OsCSLF4 are physically linked within an approximately 49-kb region on PAC AP004261. Consistent with this, OsCSLF3and OsCSLF4 are on the same overlapping Monsanto contigs (Table I). It is not yet known if any of the other OsCSLgenes are clustered, although some are on the same chromosomes (TableI). Intron/exon structures of the full-length riceCSL genes. Exons are indicated by solid boxes and introns by white boxes. Vertical black lines indicate the position of the QxxRW motif. The number of introns for each gene is indicated in parentheses after the gene name. The genes are drawn to scale; the bar in the lower left indicates 1 kb. Full-length coding sequences for OsCSLF5 andOsCSLF6 are not available, and the two deduced partial proteins do not overlap. Therefore, it is possible that these two proteins are from the same gene. A second major difference between Arabidopsis and rice is the deep branching between their respective members in the CslB family. All six Arabidopsis CslB proteins form one cluster, whereas the two rice CslB-like proteins form a related but distinct branch. No rice proteins cluster tightly with the AtCslB sequences. In contrast to the OsCslF proteins, the deduced CslB-like proteins of the two species are similar in size (Fig. 1). We attempted to analyze other CslB and CslB-like proteins, based on EST sequences, from other dicots and cereals to see if the dichotomy shown in Figure 1 would hold up. Two partial Sorghum bicolor CslB-like proteins could be reliably assembled from public ESTs, and both of these (SbCslB2 accession nos. A286049 and BE594529; SbCslB3 nos. BE597410 andBG463462; see http://cellwall.stanford.edu) aligned more closely with the rice CslB-like proteins than with the AtCslB family (data not shown). This supports the hypothesis that the cereal CslB-like proteins constitute a distinct family, and we therefore propose the nameCSLH for the rice CSLB-like genes. A third salient feature of the tree (Fig. 1) is that rice apparently lacks any CSLG family, members of which are widespread in dicots and have not been found so far in any monocot. This observation was made earlier by Richmond and Somerville (2001). Arabidopsis is predicted to have 30 CSL genes (Richmond and Somerville, 2001), whereas rice has at least 37 (Table I). A number of the rice genome survey sequences predict the existence of additionalOsCSL genes (see http://cellwall.stanford.edu), but because of their short lengths, unavailability for further sequencing, and lack of utility for predicting intron/exon structure, they have not been included in the current analysis. Rice and Arabidopsis differ in the number of predicted genes in each of the “common” families. Arabidopsis and rice have nine and 10 CSLA genes, five and nine CSLC genes, six and four CSLD genes, and one and fiveCSLE genes, respectively. Intron/exon structures were deduced for all of the full-lengthOsCSL genes (Fig. 2). The OsCESA,OsCSLA, OsCSLH, and OsCSLEfamilies tend to have more introns compared with OsCSLD,OsCSLC, and OsCSLF. In Arabidopsis, theAtCSLD family has the fewest introns (Richmond and Somerville, 2000). Intron number also tends to be conserved within a family (Fig. 2). Genes in the CSL superfamily are currently the most promising candidates for encoding the glycosyl synthases that make the hemicellulose backbones of plant cell walls (Richmond and Somerville, 2001). Although all plant cell walls have similarities in their polysaccharide composition, the hemicelluloses of dicots and cereals show marked differences (Carpita, 1996). This dimorphism is expected to be reflected in distinct patterns of wall biosythetic enzymes and hence encoding genes. Consistent with both the similarities and differences between the walls of dicots and cereals, the CSL gene superfamily shows both degrees of conservation and degrees of differences between Arabidopsis and rice. We thank Robin Hawley (Michigan State University-Department of Energy [MSU-DOE]) for technical assistance and Todd Richmond (NimbleGen Systems, Inc., Madison, WI) for useful discussions. We thank Weiqing Zeng (MSU-DOE) for sharing his analyses of the Arabidopsis CSL genes. For cDNA clones, we thank the Rice Genome Research Program of the National Institute of Agrobiological Resources (Tsukuba, Japan); the Department of Cytogenetics (National Institute of Agricultural Sciences and Technology, Suwon City, Korea); the Department of Plant Breeding (Cornell University, Ithaca, NY); and Christine Michalowski (University of Arizona, Tucson). All cDNA clones mentioned in this paper are available to nonprofit researchers directly from the original source or, with their written permission, from the corresponding author.
Fetched live from OpenAlex and de-inverted. Abstracts are not stored in this database: the inverted indexes are 8.6 GB of the frame’s 9.3 GB of text, and the host has 13 GB free.
Full frame distilled prediction
Teacher imitationNot calibrated prevalence, not ground truth. Human validation pending. Learned from the 10,348 direct Codex labels and 10,348 direct Gemma labels. Candidate is the union of thresholded teacher heads; consensus is their intersection. These outputs are machine_predicted_unvalidated and are not human labels or direct frontier model labels.
Codex and Gemma teacher scores by category
| Category | Codex | Gemma |
|---|---|---|
| Metaresearch | 0.000 | 0.000 |
| Meta-epidemiology (narrow) | 0.000 | 0.000 |
| Meta-epidemiology (broad) | 0.000 | 0.000 |
| Bibliometrics | 0.000 | 0.000 |
| Science and technology studies | 0.000 | 0.000 |
| Scholarly communication | 0.000 | 0.000 |
| Open science | 0.000 | 0.000 |
| Research integrity | 0.000 | 0.000 |
| Insufficient payload (model declined to judge) | 0.002 | 0.000 |
Machine scores (provisional)
The two teacher heads of the student model, read on this work. A score orders the frame for review; it never asserts a category, and the validation status ships verbatim with every row.
Baseline scores from an immature model (maturity gate not passed, 7 training rounds). Scores rank; they never assert a category.
score_only:v0-immature-baseline · verbatim from the scoring run: score_only means the number may rank works, and no category label ships from it