The galactose residues of xyloglucan are essential to maintain mechanical strength of the primary cell walls in Arabidopsis during growth

In land plants, xyloglucans (XyGs) tether cellulose microfibrils into a strong but extensible cell wall. The MUR2 and MUR3 genes of Arabidopsis encode XyG-specific fucosyl and galactosyl transferases, respectively. Mutations of these genes give precisely altered XyG structures missing one or both of these subtending sugar residues. Tensile strength measurements of etiolated hypocotyls revealed that galactosylation rather than fucosylation of the side chains is essential for maintenance of wall strength. Symptomatic of this loss of tensile strength is an abnormal swelling of the cells at the base of fully grown hypocotyls as well as bulging and marked increase in the diameter of the epidermal and underlying cortical cells. The presence of subtending galactosyl residues markedly enhance the activities of XyG endotransglucosylases and the accessibility of XyG to their action, indicating a role for this enzyme activity in XyG cleavage and religation in the wall during growth for maintenance of tensile strength. Although a shortening of XyGs that normally accompanies cell elongation appears to be slightly reduced, galactosylation of the XyGs is not strictly required for cell elongation, for lengthening the polymers that occurs in the wall upon secretion, or for binding of the XyGs to cellulose.     

The GLABRA2 homeodomain protein directly regulates CESA5 and XTH17 gene expression in Arabidopsis roots

Arabidopsis root hair formation is determined by the patterning genes CAPRICE ( CPC ), GLABRA3 ( GL3 ), WEREWOLF ( WER ) and GLABRA2 ( GL2 ), but little is known about the later changes in cell wall material during root hair formation. A combined Fourier-transform infrared microspectroscopy–principal components analysis (FTIR-PCA) method was used to detect subtle differences in the cell wall material between wild-type and root hair mutants in Arabidopsis. Among several root hair mutants, only the gl2 mutation affected root cell wall polysaccharides. Five of the 10 genes encoding cellulose synthase ( CESA1 – 10 ) and 4 of 33 xyloglucan endotransglucosylase ( XTH1 – 33 ) genes in Arabidopsis are expressed in the root, but only CESA5 and XTH17 were affected by the gl2 mutation. The L1-box sequence located in the promoter region of these genes was recognized by the GL2 protein. These results indicate that GL2 directly regulates cell wall-related gene expression during root development.     

Arabidopsis cell wall proteome defined using multidimensional protein identification technology

With the completion of the sequencing of the Arabidopsis genome and the recent advances in proteomic technology, the identification of proteins from highly complex mixtures is now possible. Rather than using gel electrophoresis and peptide mass fingerprinting, we have used multidimensional protein identification technology (MudPIT) to analyse the "tightly-bound" proteome for purified cell walls from Arabidopsis cell suspension cultures. Using bioinformatics for the prediction of signal peptides for targeting to the secretory pathway and for the absence of ER retention signal, 89 proteins were selected as potential extracellular proteins. Only 33% of these were identified in previous proteomic analyses of Arabidopsis cell walls. A functional classification revealed that a large proportion of the proteins were enzymes, notably carbohydrate active enzymes, peroxidases and proteases. Comparison of all the published proteomic analyses for the Arabidopsis cell wall identified 268 non-redundant genes encoding wall proteins. Sixty of these (22%) were derived from our analysis of tightly-bound wall proteins.     

Cloning and characterization of cellulose synthase-like gene, PtrCSLD2 from developing xylem of aspen trees

Genetic improvement of cell wall polymer synthesis in forest trees is one of the major goals of forest biotechnology that could possibly impact their end product utilization. Identification of genes involved in cell wall polymer biogenesis is essential for achieving this goal. Among various candidate cell wall-related genes, cellulose synthase-like D (CSLD) genes are intriguing due to their hitherto unknown functions in cell wall polymer synthesis but strong structural similarity with cellulose synthases (CesAs) involved in cellulose deposition. Little is known about CSLD genes from trees. In the present article PtrCSLD2, a first CSLD gene from an economically important tree, aspen (Populus tremuloides) is reported. PtrCSLD2 cDNA was isolated from an aspen xylem cDNA library and encodes a protein that shares 90% similarity with Arabidopsis AtCSLD3 protein involved in root hair tip growth. It is possible that xylem fibers that also grow by intrusive tip growth may need expression of PtrCSLD2 for controlling the length of xylem fibers, a wood quality trait of great economical importance. PtrCSLD2 protein has a N-terminal cysteine-rich putative zinc-binding domain; eight transmembrane domains; alternating conserved and hypervariable domains; and a processive glycosyltransferases signature, D, D, D, QXXRW; all similar to aspen CesA proteins. However, PtrCSLD2 shares only 43-48% overall identity with the known aspen CesAs suggesting its distinct functional role in cell wall polymer synthesis perhaps other than cellulose biosynthesis. Based on Southern analysis, the aspen CSLD gene family consists of at least three genes and this gene copy estimate is supported by phylogenetic analysis of available CSLDs from plants. Moreover, gene expression studies using RT-PCR and in situ mRNA hybridization showed that PtrCSLD2 is expressed at a low level in all aspen tissues examined with a slightly higher expression level in secondary cell wall-enriched aspen xylem as compared to primary cell wall enriched tissues. Together, these observations suggest that PtrCSLD2 gene may be involved in the synthesis of matrix polysaccharides that are dominant in secondary cell walls of poplar xylem. Future molecular genetic analyses will clarify the functional significance of CSLD genes in the development of woody trees.     

AtCSLD3, a cellulose synthase-like gene important for root hair growth in arabidopsis

A member of the cellulose synthase-like (subfamily D) gene family of Arabidopsis, AtCSLD3, has been identified by T-DNA tagging. The analysis of the corresponding mutant, csld3-1, showed that the AtCSLD3 gene plays a role in root hair growth in plants. Root hairs grow in phases: First a bulge is formed and then the root hair elongates by polarized growth, the so-called "tip growth." In the mutant, root hairs were initiated at the correct position and grew into a bulge, but their elongation was severely reduced. The tips of the csld3-1 root hairs easily leaked cytoplasm, indicating that the tensile strength of the cell wall had changed at the site of the tip. Based on the mutant phenotype and the functional conservation between CSLD3 and the genuine cellulose synthase proteins, we hypothesized that the CSLD3 protein is essential for the synthesis of polymers for the fast-growing primary cell wall at the root hair tip. The distinct mutant phenotype and the ubiquitous expression pattern indicate that the CSLD3 gene product is only limiting at the zone of the root hair tip, suggesting particular physical properties of the cell wall at this specific site of the root hair cell.     

Real-Time Imaging of Cellulose Reorientation during Cell Wall Expansion in Arabidopsis Roots

Cellulose forms the major load-bearing network of the plant cell wall, which simultaneously protects the cell and directs its growth. Although the process of cellulose synthesis has been observed, little is known about the behavior of cellulose in the wall after synthesis. Using Pontamine Fast Scarlet 4B, a dye that fluoresces preferentially in the presence of cellulose and has excitation and emission wavelengths suitable for confocal microscopy, we imaged the architecture and dynamics of cellulose in the cell walls of expanding root cells. We found that cellulose exists in Arabidopsis (Arabidopsis thaliana) cell walls in large fibrillar bundles that vary in orientation. During anisotropic wall expansion in wild-type plants, we observed that these cellulose bundles rotate in a transverse to longitudinal direction. We also found that cellulose organization is significantly altered in mutants lacking either a cellulose synthase subunit or two xyloglucan xylosyltransferase isoforms. Our results support a model in which cellulose is deposited transversely to accommodate longitudinal cell expansion and reoriented during expansion to generate a cell wall that is fortified against strain from any direction.The walls of growing plant cells must fulfill two simultaneous and seemingly contradictory requirements. First, they must expand to accommodate cell growth, which is anisotropic in many tissues and determines organ morphology. Second, they must maintain their structural integrity, both to constrain the turgor pressure that drives cell growth and to provide structural rigidity to the plant. These requirements are met by constructing primary cell walls that can expand along with growing cells, whereas secondary cell walls are deposited after cell growth has ceased and serve the latter function.One of the major constituents of both types of cell walls is cellulose, which exists as microfibrils composed of parallel β-1,4-linked glucan chains that are held together laterally by hydrogen bonds (Somerville, 2006). Microfibrils are 2 to 5 nm in diameter, can extend to several micrometers in length, and exhibit high tensile strength that allows cell walls to withstand turgor pressures of up to 1 MPa (Franks, 2003). In vascular plants, cellulose is synthesized by a multimeric cellulose synthase (CESA) complex composed of at least three types of glycosyl transferases arranged into a hexameric rosette (Somerville, 2006). After delivery to the plasma membrane, CESA initially moves in alignment with cortical microtubules (Paredez et al., 2006), but its trajectory can be maintained independently of microtubule orientation. For example, in older epidermal cells of the root elongation zone in Arabidopsis (Arabidopsis thaliana), cellulose microfibrils at the inner wall face are oriented transversely despite the fact that microtubules reorient from transverse to longitudinal along the elongation zone (Sugimoto et al., 2000), suggesting that microtubule orientation and cellulose deposition are independent in at least some cases.Depending on species, cell type, and developmental stage, cellulose microfibrils may be surrounded by additional networks of polymers, including hemicelluloses, pectins, lignin, and arabinogalactan proteins (Somerville et al., 2004). Hemicelluloses are composed of β-1,4-linked carbohydrate backbones with side branches and include xyloglucans, mannans, and arabinoxylans. Xyloglucan is thought to interact with the surface of cellulose and form cross-links between adjacent microfibrils (Vissenberg et al., 2005). In some cell types, pectin or lignin may also participate in cross-linking or entrapment of other cell wall polymers. It is unclear how the associations between networks of different cell wall components are relaxed to allow for cell wall expansion during growth.Several models have been proposed for the behavior of cell wall components during wall expansion. The passive reorientation hypothesis (also called the multinet growth hypothesis; Preston, 1982) postulates that in longitudinally expanding cells, cellulose microfibrils are synthesized in a transverse pattern and are then reoriented toward the longitudinal axis due to the strain generated by turgor pressure (Green, 1960). This phenomenon has been observed in the multicellular alga Nitella (Taiz, 1984). In higher plants, there is less direct evidence for passive reorientation, and another hypothesis holds that wall expansion involves active, local, and controlled remodeling of cellulose microfibrils along a diversity of orientations (Baskin, 2005). Such remodeling could be achieved by proteins such as xyloglucan endotransglycosylases (XETs), which break and rejoin xyloglucan chains, and expansins, which loosen cell walls in vitro in a pH-dependent manner (Cosgrove, 2005). Marga et al. measured cellulose microfibril orientation at the innermost layer of the cell wall before and after in vitro extension and did not observe reorientation (Marga et al., 2005). This suggests that processes other than microfibril reorientation might be involved in wall expansion, at least under certain circumstances or in some wall layers. Thus, the degree to which cellulose microfibrils are reoriented after their synthesis during wall expansion has remained unclear.One difficulty in resolving this problem has been the inability to directly image cellulose microfibrils in the growing cell wall. Existing methods to assess cellulose structure and orientation in plant cell walls are limited by the low contrast of cellulose in transmission electron microscopy, the ability to image only the surface of the wall using field emission scanning electron microscopy, and the use of polarized light microscopy in combination with dyes such as Congo red to measure only the bulk orientation of cellulose microfibrils (Baskin et al., 1999; Sugimoto et al., 2000; Verbelen and Kerstens, 2000; MacKinnon et al., 2006). In addition, the sample manipulation required for the former two methods has the potential to introduce artifacts (Marga et al., 2005). Although cellulose microfibril orientation differs at the inner and outer surfaces of the cell wall (Sugimoto et al., 2000) and presumably changes over time, the dynamics of cellulose reorientation during cell wall expansion have not been observed to date.In this study, we tested fluorescent dyes for their potential to allow imaging of cellulose distribution in the walls of Arabidopsis seedlings by confocal microscopy. We used one of these dyes to characterize the distribution of cellulose in wild-type root cells and in mutants with reduced cellulose or xyloglucan. By directly observing the fine structure of cellulose over time in growing wild-type root cells, we concluded that cellulose microfibrils in these cells reorient in a transverse to longitudinal direction as predicted by the passive reorientation hypothesis.     

Subfunctionalization of cellulose synthases in seed coat epidermal cells mediates secondary radial wall synthesis and mucilage attachment

Arabidopsis (Arabidopsis thaliana) epidermal seed coat cells follow a complex developmental program where, following fertilization, cells of the ovule outer integument differentiate into a unique cell type. Two hallmarks of these cells are the production of a doughnut-shaped apoplastic pocket filled with pectinaceous mucilage and the columella, a thick secondary cell wall. Cellulose is thought to be a key component of both these secondary cell wall processes. Here, we investigated the role of cellulose synthase (CESA) subunits CESA2, CESA5, and CESA9 in the seed coat epidermis. We characterized the roles of these CESA proteins in the seed coat by analyzing cell wall composition and morphology in cesa mutant lines. Mutations in any one of these three genes resulted in lower cellulose content, a loss of cell shape uniformity, and reduced radial wall integrity. In addition, we found that attachment of the mucilage halo to the parent seed following extrusion is maintained by cellulose-based connections requiring CESA5. Hence, we show that cellulose fulfills an adhesion role between the extracellular mucilage matrix and the parent cell in seed coat epidermal cells. We propose that mucilage remains attached to the seed coat through interactions between components in the seed mucilage and cellulose. Our data suggest that CESA2 and CESA9 serve in radial wall reinforcement, as does CESA5, but CESA5 also functions in mucilage biosynthesis. These data suggest unique roles for different CESA subunits in one cell type and illustrate a complex role for cellulose biosynthesis in plant developmental biology.     

Size-exclusion chromatography of enzymatically treated cellulose and related polysaccharides: a review

Size-exclusion chromatography (SEC) of wood pulp polysaccharides (cellulose and hemicelluloses) has become widely used for the analysis of these polymers, including monitoring of transformations occurring under various chemical and biological processes. The present review provides information on the different procedures and methodologies developed for the characterization of molecular mass distribution (MMD) and chemical composition of cellulose and hemicelluloses by SEC. This paper also includes the significant results obtained in the characterization of enzymatically treated wood polysaccharides. Conventional SEC with double detection (refractometric and UV), "hyphenated" with a fractional dissolution, was demonstrated to be an efficient method for simultaneous determination of MMD and chemical heterogeneity.     

A revised architecture of primary cell walls based on biomechanical changes induced by substrate-specific endoglucanases

Xyloglucan is widely believed to function as a tether between cellulose microfibrils in the primary cell wall, limiting cell enlargement by restricting the ability of microfibrils to separate laterally. To test the biomechanical predictions of this "tethered network" model, we assessed the ability of cucumber (Cucumis sativus) hypocotyl walls to undergo creep (long-term, irreversible extension) in response to three family-12 endo-β-1,4-glucanases that can specifically hydrolyze xyloglucan, cellulose, or both. Xyloglucan-specific endoglucanase (XEG from Aspergillus aculeatus) failed to induce cell wall creep, whereas an endoglucanase that hydrolyzes both xyloglucan and cellulose (Cel12A from Hypocrea jecorina) induced a high creep rate. A cellulose-specific endoglucanase (CEG from Aspergillus niger) did not cause cell wall creep, either by itself or in combination with XEG. Tests with additional enzymes, including a family-5 endoglucanase, confirmed the conclusion that to cause creep, endoglucanases must cut both xyloglucan and cellulose. Similar results were obtained with measurements of elastic and plastic compliance. Both XEG and Cel12A hydrolyzed xyloglucan in intact walls, but Cel12A could hydrolyze a minor xyloglucan compartment recalcitrant to XEG digestion. Xyloglucan involvement in these enzyme responses was confirmed by experiments with Arabidopsis (Arabidopsis thaliana) hypocotyls, where Cel12A induced creep in wild-type but not in xyloglucan-deficient (xxt1/xxt2) walls. Our results are incompatible with the common depiction of xyloglucan as a load-bearing tether spanning the 20- to 40-nm spacing between cellulose microfibrils, but they do implicate a minor xyloglucan component in wall mechanics. The structurally important xyloglucan may be located in limited regions of tight contact between microfibrils.     

Structure of cellulose-deficient secondary cell walls from the irx3 mutant of Arabidopsis thaliana

In the Arabidopsis mutant irx3, truncation of the AtCesA7 gene encoding a xylem-specific cellulose synthase results in reduced cellulose synthesis in the affected xylem cells and collapse of mature xylem vessels. Here we describe spectroscopic experiments to determine whether any cellulose, normal or abnormal, remained in the walls of these cells and whether there were consequent effects on other cell-wall polysaccharides. Xylem cell walls from irx3 and its wild-type were prepared by anatomically specific isolation and were examined by solid-state NMR spectroscopy and FTIR microscopy. The affected cell walls of irx3 contained low levels of crystalline cellulose, probably associated with primary cell walls. There was no evidence that crystalline cellulose was replaced by less ordered glucans. From the molecular mobility of xylans and lignin it was deduced that these non-cellulosic polymers were cross-linked together in both irx3 and the wild-type. The disorder previously observed in the spatial pattern of non-cellulosic polymer deposition in the secondary walls of irx3 xylem could not be explained by any alteration in the structure or cross-linking of these polymers and may be attributed directly to the absence of cellulose microfibrils which, in the wild-type, scaffold the organisation of the other polymers into a coherent secondary cell wall.     

The endo-1,4-β-glucanase Korrigan exhibits functional conservation between gymnosperms and angiosperms and is required for proper cell wall formation in gymnosperms

The evolution of compositional polymers and their complex arrangement and deposition in the cell walls of terrestrial plants included the acquisition of key protein functions. A membrane-bound endoglucanase, termed Korrigan (KOR), has been shown to be required for proper cellulose synthesis. To date, no extensive characterization of the gymnosperm KOR has been undertaken. Characterization of the white spruce (Picea glauca) gene encoding KOR (PgKOR) shows conserved protein features such as polarized targeting signals and residues predicted to be essential for catalytic activity. The rescue of the Arabidopsis thaliana kor1-1 mutant by the expression of PgKOR suggests gene conservation, providing evidence for functional equivalence. Analyses of endogenous KOR expression in white spruce revealed the highest expression in young developing tissues, which corresponds with primary cell wall development. Additionally, RNA interference of the endogenous gymnosperm gene substantially reduced growth and structural glucose content, but had no effect on cellulose ultrastructure. Partial functional conservation of KOR in gymnosperms suggests that its role in cell wall synthesis dates back to 300 million yr ago (Mya), predating angiosperms, which arose 130 Mya, and shows that proteins contributing to proper cellulose deposition are important conserved features of vascular plants.     

Higher plant cellulose synthases

Cellulose, an aggregate of unbranched polymers of β-1,4-linked glucose residues, is the major component of wood and thus paper, and is synthesized by plants, most algae, some bacteria and fungi, and even some animals. The genes that synthesize cellulose in higher plants differ greatly from the well-characterized genes found in Acetobacter and Agrobacterium sp. More correctly designated as 'cellulose synthase catalytic subunits', plant cellulose synthase (CesA) proteins are integral membrane proteins, approximately 1,000 amino acids in length. The sequences for more than 20 full-length CesA genes are available, and they show high similarity to one another across the entire length of the encoded protein, except for two small regions of variability. There are a number of highly conserved residues, including several motifs shown to be necessary for processive glycosyltransferase activity. No crystal structure is known for cellulose synthase proteins, and the exact enzymatic mechanism is unknown. There are a number of mutations in cellulose synthase genes in the model organism Arabidopsis thaliana. Some of these mutants show altered morphology due to the lack of a properly developed primary or secondary cell wall. Others show resistance to well-characterized cellulose biosynthesis inhibitors.     

Genetic evidence that cellulose synthase activity influences microtubule cortical array organization

To identify factors that influence cytoskeletal organization we screened for Arabidopsis (Arabidopsis thaliana) mutants that show hypersensitivity to the microtubule destabilizing drug oryzalin. We cloned the genes corresponding to two of the 131 mutant lines obtained. The genes encoded mutant alleles of PROCUSTE1 and KORRIGAN, which both encode proteins that have previously been implicated in cellulose synthesis. Analysis of microtubules in the mutants revealed that both mutants have altered orientation of root cortical microtubules. Similarly, isoxaben, an inhibitor of cellulose synthesis, also altered the orientation of cortical microtubules while exogenous cellulose degradation did not. Thus, our results substantiate that proteins involved in cell wall biosynthesis influence cytoskeletal organization and indicate that this influence on cortical microtubule stability and orientation is correlated with cellulose synthesis rather than the integrity of the cell wall.