OsBC1L4 encodes a COBRA-like protein that affects cellulose synthesis in rice

Plant morphogenesis is highly dependent on the regulation of cell division and expansion. The organization of the cellulose microfibrils in the cell wall is a key determinant of cell expansion. Previously, a dwarf mutant with fewer tillers, Osbc1l4 (Oryza sativa brittle culm 1 like 4), was identified by screening a rice T-DNA insertion mutant library. It is reported here that OsBC1L4 encodes a COBRA-like protein that exhibits typical structural features of a glycosylphosphatidylinositol-anchor protein. The T-DNA insertion in OsBC1L4 results in abnormal cell expansion. A decrease in cellulose content but the increase in pectin and starch contents was identified in Osbc1l4 mutants by measuring the content of wall components. OsBC1L4 was expressed in all tissues/organs examined, with a low level in leaves. OsBC1L4 protein is mainly located in the cell wall and plasma membrane. Correlation analysis indicated that the expression of OsBC1L4 was highly correlated to that of several primary wall-forming cellulose synthase genes (CESAs). Moreover, the expression level of several cellulose-related genes is increased in Osbc1l4 mutants, which suggests that a feedback mechanism may exist during cellulose synthesis.     

Detection of novel blast resistance genes, Pi58(t) and Pi59(t), in a Myanmar rice landrace based on a standard differential system

The use of broad-spectrum R genes is an effective way to achieve durable resistance against rice blast (Magnaporthe oryzae Couch, anamorph: Pyricularia oryzae Cavara) in rice (Oryza sativa L.). We previously surveyed the diversity of blast resistance in 948 rice varieties and found a Myanmar rice landrace, Haoru (International Rice Research Institute genebank acc. no. IRGC33090), with broad-spectrum resistance against the standard differential blast isolates. Here, we examined the genetic basis of Haoru’s broad-spectrum resistance by using the standard blast differential system consisting of the standard isolates and differential varieties. For genetic analysis, we used a BC1F1 population and BC1F2 lines derived from crosses of Haoru with a susceptible variety, US-2. Co-segregation analysis of the reaction pattern in the BC1F1 population against the 20 standard isolates suggested that Haoru harbors three R genes. By using bulk-segregant and linkage analysis, we mapped two of the three R genes on chromosomes 12 and 6, and designated them as Pi58(t) and Pi59(t), respectively. Pi58(t) and Pi59(t) were differentiated from other reported R genes using the standard differential system. The estimated resistance spectrum of Pi58(t) corresponded with that of Haoru, suggesting that Pi58(t) is primarily responsible for Haoru’s broad-spectrum resistance. In addition, Pi59(t) and the third gene were also proven to be new and useful genetic resources for studying and improving blast resistance in rice.     

The Rice B-Box Zinc Finger Gene Family: Genomic Identification,Characterization, Expression Profiling and Diurnal Analysis

Background

The B-box (BBX) -containing proteins are a class of zinc finger proteins that contain one or two B-box domains and play important roles in plant growth and development. The Arabidopsis BBX gene family has recently been re-identified and renamed. However, there has not been a genome-wide survey of the rice BBX (OsBBX) gene family until now.

Methodology/Principal Findings

In this study, we identified 30 rice BBX genes through a comprehensive bioinformatics analysis. Each gene was assigned a uniform nomenclature. We described the chromosome localizations, gene structures, protein domains, phylogenetic relationship, whole life-cycle expression profile and diurnal expression patterns of the OsBBX family members. Based on the phylogeny and domain constitution, the OsBBX gene family was classified into five subfamilies. The gene duplication analysis revealed that only chromosomal segmental duplication contributed to the expansion of the OsBBX gene family. The expression profile of the OsBBX genes was analyzed by Affymetrix GeneChip microarrays throughout the entire life-cycle of rice cultivar Zhenshan 97 (ZS97). In addition, microarray analysis was performed to obtain the expression patterns of these genes under light/dark conditions and after three phytohormone treatments. This analysis revealed that the expression patterns of the OsBBX genes could be classified into eight groups. Eight genes were regulated under the light/dark treatments, and eleven genes showed differential expression under at least one phytohormone treatment. Moreover, we verified the diurnal expression of the OsBBX genes using the data obtained from the Diurnal Project and qPCR analysis, and the results indicated that many of these genes had a diurnal expression pattern.

Conclusions/Significance

The combination of the genome-wide identification and the expression and diurnal analysis of the OsBBX gene family should facilitate additional functional studies of the OsBBX genes.     

SUI-family genes encode phosphatidylserine synthases and regulate stem development in rice

In vascular plants, the regulation of stem cell niche determines development of aerial shoot which consists of stems and lateral organs. Intercalary meristem (IM) controls internode elongation in rice and other grasses, however little attention has been paid to the underlying mechanism of stem cell maintenance. Here, we investigated the stem development in rice and showed that the Shortened Uppermost Internode 1 (SUI1) family of genes are pivotal for development of rice stems. We demonstrated that SUI-family genes regulate the development of IM for internode elongation and also the cell expansion of the panicle stem rachis in rice. The SUI-family genes encoded base-exchange types of phosphatidylserine synthases (PSSs), which possessed enzymatic activity in a yeast complementary assay. Overexpression of SUI1 and SUI2 caused outgrowths of internodes during vegetative development, and we showed that expression patterns of Oryza Sativa Homeobox 15 (OSH15) and Histone4 were impaired. Furthermore, genome-wide gene expression analysis revealed that overexpression and RNA knockdown of SUI-family genes affected downstream gene expression related to phospholipid metabolic pathways. Moreover, using Ultra-performance liquid chromatography–quadrupole time of flight-mass spectrometry, we analyzed PS contents in different genetic backgrounds of rice and showed that the quantity of very long chain fatty acids PS is affected by transgene of SUI-family genes. Our study reveals a new mechanism conveyed by the SUI1 pathway and provides evidence to link lipid metabolism with plant stem cell maintenance.     

The IQD Gene Family in Soybean: Structure,Phylogeny, Evolution and Expression

Members of the plant-specific IQ67-domain (IQD) protein family are involved in plant development and the basal defense response. Although systematic characterization of this family has been carried out in Arabidopsis, tomato (Solanum lycopersicum), Brachypodium distachyon and rice (Oryza sativa), systematic analysis and expression profiling of this gene family in soybean (Glycine max) have not previously been reported. In this study, we identified and structurally characterized IQD genes in the soybean genome. A complete set of 67 soybean IQD genes (GmIQD1–67) was identified using Blast search tools, and the genes were clustered into four subfamilies (IQD I–IV) based on phylogeny. These soybean IQD genes are distributed unevenly across all 20 chromosomes, with 30 segmental duplication events, suggesting that segmental duplication has played a major role in the expansion of the soybean IQD gene family. Analysis of the Ka/Ks ratios showed that the duplicated genes of the GmIQD family primarily underwent purifying selection. Microsynteny was detected in most pairs: genes in clade 1–3 might be present in genome regions that were inverted, expanded or contracted after the divergence; most gene pairs in clade 4 showed high conservation with little rearrangement among these gene-residing regions. Of the soybean IQD genes examined, six were most highly expressed in young leaves, six in flowers, one in roots and two in nodules. Our qRT-PCR analysis of 24 soybean IQD III genes confirmed that these genes are regulated by MeJA stress. Our findings present a comprehensive overview of the soybean IQD gene family and provide insights into the evolution of this family. In addition, this work lays a solid foundation for further experiments aimed at determining the biological functions of soybean IQD genes in growth and development.     

Genome-Wide Identification,Biochemical Characterization,and Expression Analyses of the YTH Domain-Containing RNA-Binding Protein Family in Arabidopsis and Rice

RNA-binding proteins are critical to RNA metabolism in cells and, thus, play important roles in diverse biological processes. In the present study, we identified the YTH domain-containing RNA-binding protein (RBP) family in Arabidopsis thaliana and rice at the molecular and biochemical levels. A total of 13 and 12 genes were found to encode YTH domain-containing RBPs in Arabidopsis and rice and named as AtYTH01–13 and OsYTH01–12, respectively. The phylogeny, chromosomal location, and structures of genes and proteins were analyzed. Electrophoretic mobility shift assays demonstrated that recombinant AtYTH05 protein could bind to single-stranded RNA in vitro, demonstrating that the YTH proteins have RNA-binding activity. Analyses of publicly available microarray data, gene expression by qRT-PCR, and AtYTH05 promoter activity indicate that the Arabidopsis AtYTHs and rice OsYTHs genes have distinct and diverse expression patterns in different tissues and developmental stages, showing tissue- and developmental-specific expression patterns. Furthermore, analyses of publicly available microarray data also indicate that many of the Arabidopsis AtYTHs and rice OsYTHs genes might be involved in responses to various abiotic and biotic stresses as well as in response to hormones. Our data demonstrate that the YTH family proteins are a novel group of RBPs and provide useful clues to define their biological functions of this RBP family in plants.     

Gtsf1l and Gtsf2 Are Specifically Expressed in Gonocytes and Spermatids but Are Not Essential for Spermatogenesis

The unknown protein family 0224 (UPF0224) includes three members that are expressed in germ-line cells in mice: Gtsf1, Gtsf1l, and {"type":"entrez-nucleotide","attrs":{"text":"BC048502","term_id":"28913420"}}BC048502 (Gtsf2). These genes produce proteins with two repeats of the CHHC Zn-finger domain, a predicted RNA-binding motif, in the N terminus. We previously reported that Gtsf1 is essential for spermatogenesis and retrotransposon suppression. In this study, we investigated the expression patterns and functions of Gtsf1l and Gtsf2. Interestingly, Gtsf1l and Gtsf2 were found to be sequentially but not simultaneously expressed in gonocytes and spermatids. Pull-down experiments showed that both GTSF1L and GTSF2 can interact with PIWI-protein complexes. Nevertheless, knocking out Gtsf1, Gtsf2, or both did not cause defects in spermatogenesis or retrotransposon suppression in mice.     

Genome-Wide Identification and Analysis of the TIFY Gene Family in Grape

Background

The TIFY gene family constitutes a plant-specific group of genes with a broad range of functions. This family encodes four subfamilies of proteins, including ZML, TIFY, PPD and JASMONATE ZIM-Domain (JAZ) proteins. JAZ proteins are targets of the SCF^COI1 complex, and function as negative regulators in the JA signaling pathway. Recently, it has been reported in both Arabidopsis and rice that TIFY genes, and especially JAZ genes, may be involved in plant defense against insect feeding, wounding, pathogens and abiotic stresses. Nonetheless, knowledge concerning the specific expression patterns and evolutionary history of plant TIFY family members is limited, especially in a woody species such as grape.

Methodology/Principal Findings

A total of two TIFY, four ZML, two PPD and 11 JAZ genes were identified in the Vitis vinifera genome. Phylogenetic analysis of TIFY protein sequences from grape, Arabidopsis and rice indicated that the grape TIFY proteins are more closely related to those of Arabidopsis than those of rice. Both segmental and tandem duplication events have been major contributors to the expansion of the grape TIFY family. In addition, synteny analysis between grape and Arabidopsis demonstrated that homologues of several grape TIFY genes were found in the corresponding syntenic blocks of Arabidopsis, suggesting that these genes arose before the divergence of lineages that led to grape and Arabidopsis. Analyses of microarray and quantitative real-time RT-PCR expression data revealed that grape TIFY genes are not a major player in the defense against biotrophic pathogens or viruses. However, many of these genes were responsive to JA and ABA, but not SA or ET.

Conclusion

The genome-wide identification, evolutionary and expression analyses of grape TIFY genes should facilitate further research of this gene family and provide new insights regarding their evolutionary history and regulatory control.     

Analysis of rice glycosyl hydrolase family 1 and expression of Os4bglu12 β-glucosidase

Background

Glycosyl hydrolase family 1 (GH1) β-glucosidases have been implicated in physiologically important processes in plants, such as response to biotic and abiotic stresses, defense against herbivores, activation of phytohormones, lignification, and cell wall remodeling. Plant GH1 β-glucosidases are encoded by a multigene family, so we predicted the structures of the genes and the properties of their protein products, and characterized their phylogenetic relationship to other plant GH1 members, their expression and the activity of one of them, to begin to decipher their roles in rice.

Results

Forty GH1 genes could be identified in rice databases, including 2 possible endophyte genes, 2 likely pseudogenes, 2 gene fragments, and 34 apparently competent rice glycosidase genes. Phylogenetic analysis revealed that GH1 members with closely related sequences have similar gene structures and are often clustered together on the same chromosome. Most of the genes appear to have been derived from duplications that occurred after the divergence of rice and Arabidopsis thaliana lineages from their common ancestor, and the two plants share only 8 common gene lineages. At least 31 GH1 genes are expressed in a range of organs and stages of rice, based on the cDNA and EST sequences in public databases. The cDNA of the Os4bglu12 gene, which encodes a protein identical at 40 of 44 amino acid residues with the N-terminal sequence of a cell wall-bound enzyme previously purified from germinating rice, was isolated by RT-PCR from rice seedlings. A thioredoxin-Os4bglu12 fusion protein expressed in Escherichia coli efficiently hydrolyzed β-(1,4)-linked oligosaccharides of 3–6 glucose residues and laminaribiose.

Conclusion

Careful analysis of the database sequences produced more reliable rice GH1 gene structure and protein product predictions. Since most of these genes diverged after the divergence of the ancestors of rice and Arabidopsis thaliana, only a few of their functions could be implied from those of GH1 enzymes from Arabidopsis and other dicots. This implies that analysis of GH1 enzymes in monocots is necessary to understand their function in the major grain crops. To begin this analysis, Os4bglu12 β-glucosidase was characterized and found to have high exoglucanase activity, consistent with a role in cell wall metabolism.     

Genomic analysis and expression pattern of <Emphasis Type="Italic">OsZIP1, OsZIP3</Emphasis>, and <Emphasis Type="Italic">OsZIP4</Emphasis> in two rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) genotypes with different zinc efficiency

The ZRT-and IRT-like proteins (ZIP) comprise a large family of transition metal transporters in plants that have diverse functions to transport zinc, iron, copper, etc. Here, we provided a complete overview of this gene family in rice (Oryza sativa L.). Based on the hidden Markov model and BLAST analysis, a total of 17 ZIP-coding genes were identified and further studied by semi-quantitative RT-PCR analysis. Sequence analysis revealed 17 putative genes distributed randomly on eight chromosomes. Although most of the predicted proteins had typical characteristics of the ZIP protein family, the extent of their sequence similarity varied considerably. The expression patterns of OsZIP1, OsZIP3, and OsZIP4, which encode Zn²⁺ transporters in rice, were studied in the Zn-efficient and Zn-inefficient rice genotypes (IR8192 and Erjiufeng) by semi-quantitative RT-PCR analysis of roots, shoots, and panicle from the plants grown under Zn deficiency and normal conditions. OsZIP1 was expressed only in the roots and very weakly if at all in the panicles, while the other two genes were expressed in all parts of plants under study. The Zn-deficient conditions up-regulated the expression of OsZIP1, OsZIP3, and OsZIP4 in the roots and that of OsZIP4 in the shoots of both genotypes, indicating that all these genes may participate in rice zinc nutrition. Furthermore, the expression of OsZIP3 and OsZIP4 was found to be much stronger in the roots of IR8192 than those of Erjiufeng, which suggests that these genes may contribute to high Zn efficiency in rice. The expression patterns and the roles of other OsZIPs are also discussed on the basis of the phylogenetic tree of ZIP proteins and RT-PCR analysis of the two rice genotypes with different zinc efficiency.     

Molecular characterization and functional analysis of “fruit-weight2.2-like” gene family in rice

Tomato fruit-weight 2.2 (FW2.2) was reported to control up to 30 % fruit weight. Recent studies demonstrated that FW2.2-like (FWL) genes also play important roles in plant growth and development. For instance, a maize homolog of FW2.2, named cell number regulator 1 (CNR1), negatively regulates plant and organ size. However, FWL genes in rice have not been characterized yet. In this study, eight FWL genes were identified in rice genome and designated as OsFWL1-8. The chromosome location, gene structure, protein motif, and phylogenetic relationship of OsFWL genes were analyzed. RT-PCR result and microarray data revealed that OsFWL genes exhibited diverse expression patterns and the detailed expression patterns of OsFWL5, 6, and 7 negatively correlated with leaf growth activity. Rice protoplast transient transformation experiment showed that most OsFWL proteins locate at cell membrane but OsFWL8 is present in the nucleus. In addition, the functions of OsFWL genes were investigated by analyzing two T-DNA insertion lines for OsFWL3 and 5. Compared with wild type, the grain weight of osfwl3 mutant and the plant height of osfwl5 mutant were increased by 5.3 and 12.5 %, respectively. We also found that the increase in grain length of osfwl3 mutant was due chiefly to incremental cell number, not cell size and the expression of OsFWL3 negatively correlated with glume growth activity. These results provide a comprehensive foundation for further study of OsFWL functions in rice.     

Genome-wide identification and expression profiling of ankyrin-repeat gene family in maize

Members of the ankyrin repeats (ANK) gene family encode ANK domain that are common in diverse organisms and play important roles in cell growth and development, such as cell-cell signal transduction and cell cycle regulation. Recently, genome-wide identification and evolutionary analyses of the ANK gene family have been carried out in Arabidopsis and rice. However, little is known regarding the ANK genes in the entire maize genome. In this study, we described the identification and structural characterization of 71 ANK genes in maize (ZmANK). Then, comprehensive bioinformatics analyses of ZmANK genes family were performed including phylogenetic, domain and motif analysis, chromosomal localization, intron/exon structural patterns, gene duplications and expression profiling. Domain composition analyses showed that ZmANK genes formed ten subfamilies. Five tandem duplications and 14 segmental duplications were identified in ZmANK genes. Furthermore, we took comparative analysis of the total ANK gene family in Arabidopsis, rice and maize, ZmANKs were more closely paired with OsANKs than with AtANKs. At last, expression profile analyses were performed. Forty-one members of ZmANK genes held EST sequences records. Semi-quantitative expression and microarray data analysis of these 41 ZmANK genes demonstrated that ZmANK genes exhibit a various expression pattern, suggesting that functional diversification of ZmANK genes family. The results will present significant insights to explore ANK genes expression and function in future studies in maize.     

Functional conservation of the glycosyltransferase gene GT47A in the monocot rice

Glucuronoarabinoxylan is the major hemicellulose in grass cell walls, yet the mechanism of xylan synthesis in monocot plants is still unclear. Unraveling the genes involved in the biosynthesis of xylan in rice will be very important for the utilization of rice straw as a source of bioenergy in the future. In this report, we investigated the functional role of a rice gene homologous to Arabidopsis IRREGULAR XYLEM10 (IRX10), belonging to the glycosyl transferase (GT) gene family 47 (GT47), in the biosynthesis of xylan. The protein sequence of OsGT47A from rice exhibits a 93.49 % similarity to IRX10, which is involved in the biosynthesis of glucuronoxylan in Arabidopsis. Phylogenetic analysis of the GT47 glycosyl transferase family in the rice genome revealed that OsGT47A is a closely related homolog of IRX10 and IRX10L. Expression pattern analysis showed that the OsGT47A gene is highly expressed in the rice stem. Overexpression of OsGT47A in the irx10 irx10L double mutant rescued the plant growth phenotype and restored secondary wall thickness. Analysis of monosaccharides indicated that the rescued plants had levels of xylose identical to those of the wild type plants, and the fluorescence signals were restored in the complementation plants by xylan immunolocalization. The OsGT47A complementation under the native promoter of Arabidopsis IRX10L (ProIRX10L) partially rescued the double mutant, indicating that OsGT47A is functionally equivalent to IRX10L. Together, these results suggest that the IRX10 homolog OsGT47A exhibits functional conservation and is most likely involved in xylan synthesis in rice.     

Brittle Culm1, a COBRA-Like Protein,Functions in Cellulose Assembly through Binding Cellulose Microfibrils

Cellulose represents the most abundant biopolymer in nature and has great economic importance. Cellulose chains pack laterally into crystalline forms, stacking into a complicated crystallographic structure. However, the mechanism of cellulose crystallization is poorly understood. Here, via functional characterization, we report that Brittle Culm1 (BC1), a COBRA-like protein in rice, modifies cellulose crystallinity. BC1 was demonstrated to be a glycosylphosphatidylinositol (GPI) anchored protein and can be released into cell walls by removal of the GPI anchor. BC1 possesses a carbohydrate-binding module (CBM) at its N-terminus. In vitro binding assays showed that this CBM interacts specifically with crystalline cellulose, and several aromatic residues in this domain are essential for binding. It was further demonstrated that cell wall-localized BC1 via the CBM and GPI anchor is one functional form of BC1. X-ray diffraction (XRD) assays revealed that mutations in BC1 and knockdown of BC1 expression decrease the crystallite width of cellulose; overexpression of BC1 and the CBM-mutated BC1s caused varied crystallinity with results that were consistent with the in vitro binding assay. Moreover, interaction between the CBM and cellulose microfibrils was largely repressed when the cell wall residues were pre-stained with two cellulose dyes. Treating wild-type and bc1 seedlings with the dyes resulted in insensitive root growth responses in bc1 plants. Combined with the evidence that BC1 and three secondary wall cellulose synthases (CESAs) function in different steps of cellulose production as revealed by genetic analysis, we conclude that BC1 modulates cellulose assembly by interacting with cellulose and affecting microfibril crystallinity.     

The carbohydrate-binding module (CBM)-like sequence is crucial for rice CWA1/BC1 function in proper assembly of secondary cell wall materials

We recently reported that the cwa1 mutation disturbed the deposition and assembly of secondary cell wall materials in the cortical fiber of rice internodes. Genetic analysis revealed that cwa1 is allelic to bc1, which encodes glycosylphosphatidylinositol (GPI)-anchored COBRA-like protein with the highest homology to Arabidopsis COBRA-like 4 (COBL4) and maize Brittle Stalk 2 (Bk2). Our results suggested that CWA1/BC1 plays a role in assembling secondary cell wall materials at appropriate sites, enabling synthesis of highly ordered secondary cell wall structure with solid and flexible internodes in rice. The N-terminal amino acid sequence of CWA1/BC1, as well as its orthologs (COBL4, Bk2) and other BC1-like proteins in rice, shows weak similarity to a family II carbohydrate-binding module (CBM2) of several bacterial cellulases. To investigate the importance of the CBM-like sequence of CWA1/BC1 in the assembly of secondary cell wall materials, Trp residues in the CBM-like sequence, which is important for carbohydrate binding, were substituted for Val residues and introduced into the cwa1 mutant. CWA1/BC1 with the mutated sequence did not complement the abnormal secondary cell walls seen in the cwa1 mutant, indicating that the CBM-like sequence is essential for the proper function of CWA1/BC1, including assembly of secondary cell wall materials.Key words: carbohydrate-binding module, COBRA-LIKE, CWA1/BC1, glycosylphosphatidylinositol-anchored protein, secondary cell wall formationThe main function of carbohydrate-binding modules (CBMs) of microbes and plants is to attach the enzyme to a variety of cell surface glycans and thereby increase the local concentration of substrate, leading to more efficient catalysis.^1–4 Almost all CBMs studied to date contain surface-exposed aromatic rings, which have been shown to be the main sites of interaction with polysaccharides. These residues form face-to-face hydrophobic stacking interactions in which a Trp residue or ring of a Tyr residue interacts with the non-polar face of a sugar ring.^5–9 CBMs have been classified into families based on amino acid sequence similarity. Currently, there are 59 defined families of CBMs and these CBMs display substantial variation in ligand specificity (http://www.cazy.org/Carbohydrate-Binding-Modules.html). Among these CBM families, the large family of CBM2 has been further classified into two subgroups, CBM2a and 2b, which have shown to bind cellulose and xylan, respectively.^10–12 CBM2a characteristically possess three exposed Trp residues,¹³ whereas CBM2b have two Trp residues,¹⁴ which are conserved among the CBM2 members (Fig. 1A).Open in a separate windowFigure 1Sequence alignment of the CBM-like sequence of CWA1/BC1, the BC1L proteins and bacterial CBM2 members. (A) Sequence alignment between bacterial CBM2a, 2b and CWA1/BC1. The three surface-exposed Trp residues of CBM2a members are indicated by asterisks and W. The CBM sequences of CBM2a are: CfiCenA, Cellulomonas fimi endo-1,4-glucanase; CfiCex, C. fimi exo-beta-1,4-glucanase. Those of CBM2b are: CfiXylD1, C. fimi endo-1,4-beta-xylanase D; CfiXylD2, C. fimi endo-1,4-beta-xylanase. CWA1/BC1 shows weak similarity to CBM2, and some Trp residues are conserved with bacterial CBM2 members. (B) Sequence alignment of CWA1/BC1, the BC1L proteins and CWA1/BC1 orthologs, Zea maiz Brittle Stalk 2 (ZmBk2) and Arabidopsis thaliana COBRA-LIKE 4 (AtCOBL4). The CBM-like sequence of CWA1/BC1, especially the Trp residues, is highly conserved among the analyzed sequences. Substituted Trp (W) residues to Val (V) in CWA1/BC1 are indicated by closed triangles. Numbers at the left are the positions of the amino acids in each protein, with gaps (dashes) included to maximize alignments. Identical and similar amino acids are shaded and gray, respectively.Our recent study showed that the defect of the rice CWA1/BC1 (CELL WALL ARCHITECTURE 1/BRITTLE CULM 1) gene induced abnormal secondary cell wall formation with amorphous and bulky structures at the cytoplasm side and CWA1/BC1 encodes one of COBRA-like glycosylphosphatidylinositol (GPI)-anchored proteins, which are specifically found in plants, suggesting that CWA1/BC1 regulates assembly of secondary cell wall materials in rice sclerenchyma. Furthermore, several reports have shown that the N-terminus of rice CWA1/BC1 and other COBRA-like GPI-anchored proteins in Arabidopsis (12 members) and maize Brittle Stalk 2 (Bk2) share weak similarity to a CBM2 in several bacterial cellulases.^15,16 However, the importance of CBM-like sequence in COBRA family members has not been clarified. To investigate the nature of CWA1/BC1, we compared the CBM-like sequence in rice CWA1/BC1 with bacterial CBM2, 10 members of the BC1-like (BC1L) protein in rice and CWA1/BC1 orthologs, Arabidopsis COBL4 and maize Bk2. Furthermore, we constructed three-point mutated CWA1/BC1, in which three conserved Trp residues in CBM-like sequence were substituted for Val residues (CWA1/BC1^W→V), and introduced it into the cwa1 mutant to evaluate the necessity of the CBM-like sequence for proper function of CWA1/BC1. We discuss a putative explanation, based on our results, of the properties and possible functions of CWA1/BC1.     

Inefficient Tat-Dependent Export of Periplasmic Amidases in an Escherichia coli Strain with Mutations in Two DedA Family Genes

The DedA family genes are found in most bacterial genomes. Two of these proteins are Escherichia coli YqjA and YghB, predicted inner membrane proteins of unknown function sharing 61% amino acid identity. The E. coli single deletion mutants are largely without phenotype, but the double mutant (BC202; ΔyqjA::Tet^r ΔyghB::Kan^r) is characterized by incomplete cell division, temperature sensitivity, and altered phospholipid levels (K. Thompkins et al., J. Bacteriol. 190:4489-4500, 2008). In this report, we have better characterized the cell division chaining defect of BC202. Fluorescence recovery after photobleaching indicates that 58% of the cells in chains are compartmentalized by at least a cytoplasmic membrane. Green fluorescent protein fusions to the cell division proteins FtsZ, ZipA, FtsI, FtsL, and FtsQ are correctly localized to new septation sites in BC202. Periplasmic amidases AmiC and AmiA, secreted by the twin arginine transport (Tat) pathway, are localized to the cytoplasm in BC202. Overexpression of AmiA, AmiC, or AmiB, a periplasmic amidase secreted via the general secretory pathway, restores normal cell division but does not suppress the temperature sensitivity of BC202, indicating that YghB and YqjA may play additional roles in cellular physiology. Strikingly, overexpression of the Tat export machinery (TatABC) results in normal cell division and growth at elevated temperatures. These data collectively suggest that the twin arginine pathway functions inefficiently in BC202, likely due to the altered levels of membrane phospholipids in this mutant. These results underscore the importance of membrane composition in the proper function of the Tat protein export pathway.Roughly 25 to 30% of the genes in sequenced genomes are predicted to encode integral membrane proteins (12). The functions of many of these genes, even in a well-studied organism such as Escherichia coli, remain unknown. We have reported on the functional redundancy of two highly conserved and related E. coli inner membrane proteins, YqjA and YghB (40). These proteins belong to a large family (commonly called the DedA family) found widespread in most sequenced genomes. yghB and yqjA encode predicted inner membrane proteins with multiple membrane-spanning domains and 61% amino acid identity. In addition, E. coli contains three other genes predicted to encode proteins with significant similarity to YqjA and YghB (YabI, YohD, and DedA; amino acid BLAST E value of <1 × 10⁻⁶) and two other proteins with lower degrees of similarity (YdjX and YdjZ). Currently, there are >1,000 genes in the NCBI protein database annotated as either belonging to this family or possessing significant amino acid identity to E. coli DedA/YghB/YqjA (protein BLAST E values of <0.02). No member of this family has a known function, nor is it known whether they possess common functions across phylogenetic groups.Individually, yghB and yqjA are nonessential genes, as each single deletion mutant grows normally (2). However, BC202, an E. coli strain with targeted deletions of both yqjA and yghB, does not grow above 42°C and displays a dramatic cell division phenotype by forming chains of cells when grown at the permissive temperature of 30°C. Phase-contrast and scanning electron microscopy analysis of BC202 suggests that mutants can begin septation but are blocked at a later step in constriction (40). The cause of this phenotype is unclear.BC202 also has alterations in membrane phospholipid composition (40). While BC202 is capable of synthesizing all classes of phospholipids at all growth temperatures, it is depleted of phosphatidylethanolamine (PE), with elevated levels of the acidic phospholipids phosphatidylglycerol (PG) and cardiolipin (CL). In some respects, BC202 resembles phosphatidylserine synthase deletion mutants, such as AD90 (pss93::Kan^r), which produces no membrane PE (14). Mutants deficient in PE are viable, but they require divalent cations for growth (14) and display cell division abnormalities (28, 33). Likewise, normal growth and cell division are restored to BC202 when LB growth medium is supplemented with millimolar concentrations of divalent cations (40). Unlike many mutants defective in cell wall synthesis, BC202 is not hypersensitive to detergents or antibiotics, indicating the presence of an intact outer membrane when grown at the permissive temperature.BC202, therefore, displays several phenotypes: a block at an apparent late stage of cell division, temperature sensitivity, and an imbalance in membrane phospholipid composition. To better understand the functions of YghB and YqjA, we have hypothesized two roles for these genes that are not mutually exclusive to explain the phenotypes of BC202. First, YqjA/YghB may play direct roles in cell division. The phospholipid phenotype may be a consequence secondary to the primary cell division defect in this scenario. Second, YqjA/YghB may play a direct role in efficient PE synthesis or controlling membrane phospholipid composition. The cell division phenotype may be a secondary consequence of the lipid imbalance. Here, we have better characterized the cell division phenotype of BC202 by using green fluorescent protein (GFP) fusions of cell division proteins and fluorescence recovery after photobleaching (FRAP) analysis. We find that while most of the cell division proteins are correctly localized to new septal rings, the periplasmic amidase AmiC is not localized to the septal ring as was reported previously (5), and this may be responsible for the observed cell division phenotype of BC202. AmiC is found mostly in the cytoplasmic compartment in BC202, as is AmiA, both of which are exported to the periplasm by the twin arginine pathway (5). The cell division defect of BC202 can be corrected by overexpression of periplasmic amidases or the TatABC operon, collectively suggesting that the Tat pathway functions inefficiently in BC202.