Synthesis Of Cell Wall Polymers Research Articles

Central Sugar Metabolism and the Cell Wall.

ABSTRACTThe human opportunistic pathogen Aspergillus fumigatus is recognized for its versatile cell wall when it comes to remodeling its components in adaptation to external threats, and this remodeling renders it refractory to antifungals targeting cell wall biosynthesis. A specific role for general sugar metabolism in the regulation of the synthesis of cell wall polymers has been previously demonstrated. Delving deeper into central sugar metabolism may reveal unexpected fundamental aspects in cell wall construction, as shown by the work of Zhou and coworkers (Y. Zhou, K. Yan, Q. Qin, O.G. Raimi, et al., mBio 13:e01426-22, 2022, https://doi.org/10.1128/mbio.01426-22) on the roles of the phosphoglucose isomerase of A. fumigatus in cell wall biosynthesis.

The essential role of fungal peroxisomes in plant infection.

Several filamentous fungi are ecologically and economically important plant pathogens that infect a broad variety of crops. They cause high annual yield losses and contaminate seeds and fruits with mycotoxins. Not only powerful infection structures and detrimental toxins, but also cell organelles, such as peroxisomes, play important roles in plant infection. In this review, we summarize recent research results that revealed novel peroxisomal functions of filamentous fungi and highlight the importance of peroxisomes for infection of host plants. Central for fungal virulence are two primary metabolic pathways, fatty acid β‐oxidation and the glyoxylate cycle, both of which are required to produce energy, acetyl‐CoA, and carbohydrates. These are ultimately needed for the synthesis of cell wall polymers and for turgor generation in infection structures. Most novel results stem from different routes of secondary metabolism and demonstrate that peroxisomes produce important precursors and house various enzymes needed for toxin production and melanization of appressoria. All these peroxisomal functions in fungal virulence might represent elegant targets for improved crop protection.

The Suitability of Orthogonal Hosts to Study Plant Cell Wall Biosynthesis.

Plant cells are surrounded by an extracellular matrix that consists mainly of polysaccharides. Many molecular components involved in plant cell wall polymer synthesis have been identified, but it remains largely unknown how these molecular players function together to define the length and decoration pattern of a polysaccharide. Synthetic biology can be applied to answer questions beyond individual glycosyltransferases by reconstructing entire biosynthetic machineries required to produce a complete wall polysaccharide. Recently, this approach was successful in establishing the production of heteromannan from several plant species in an orthogonal host—a yeast—illuminating the role of an auxiliary protein in the biosynthetic process. In this review we evaluate to what extent a selection of organisms from three kingdoms of life (Bacteria, Fungi and Animalia) might be suitable for the synthesis of plant cell wall polysaccharides. By identifying their key attributes for glycoengineering as well as analyzing the glycosidic linkages of their native polymers, we present a valuable comparison of their key advantages and limitations for the production of different classes of plant polysaccharides.

UMP Pyrophosphorylase: A Moonlighting Protein with Essential Functions in Chloroplast Development and Photosynthesis Establishment.

Pyrimidine nucleotides (e.g. deoxy-CTP, deoxy-TTP, UTP, and CTP) are essential building blocks for DNA and RNA synthesis in all organisms. In plants, Suc and cell wall polymer synthesis depend on pyrimidine nucleotide-derived substrates, such as UDP-Glc, and important classes of membrane lipids are

A Novel FC116/BC10 Mutation Distinctively Causes Alteration in the Expression of the Genes for Cell Wall Polymer Synthesis in Rice.

We report isolation and characterization of a fragile culm mutant fc116 that displays reduced mechanical strength caused by decreased cellulose content and altered cell wall structure in rice. Map-based cloning revealed that fc116 was a base substitution mutant (G to A) in a putative beta-1,6-N-acetylglucosaminyltransferase (C2GnT) gene (LOC_Os05g07790, allelic to BC10). This mutation resulted in one amino acid missing within a newly-identified protein motif “R, RXG, RA.” The FC116/BC10 gene was lowly but ubiquitously expressed in the all tissues examined across the whole life cycle of rice, and slightly down-regulated during secondary growth. This mutant also exhibited a significant increase in the content of hemicelluloses and lignins, as well as the content of pentoses (xylose and arabinose). But the content of hexoses (glucose, mannose, and galactose) was decreased in both cellulosic and non-cellulosic (pectins and hemicelluloses) fractions of the mutant. Transcriptomic analysis indicated that the typical genes in the fc116 mutant were up-regulated corresponding to xylan biosynthesis, as well as lignin biosynthesis including p-hydroxyphenyl (H), syringyl (S), and guaiacyl (G). Our results indicate that FC116 has universal function in regulation of the cell wall polymers in rice.

Modifying plant cell walls for bioenergy production.

Abstract Predictions about future supply of crude oil, increase in greenhouse gases and burgeoning human population have recently necessitated a search for sustainable and environmentally responsible sources of alternative energy. Bioconversion of organic biomass, largely derived from plant residues, to biofuels has been viewed as one of the most attractive avenues of research. More than half of the plant biomass produced on earth consists of cell walls that are enriched in carbohydrate polymers such as cellulose and hemicellulose. Breakdown of these carbohydrate polymers by pre-treatments and cellulolytic enzymes to monomer sugars (saccharification) which is followed by fermentation of sugars to bioethanol is one of the favoured ways of producing biofuels. Presence of phenolic compounds in form of lignin hinders access of cell wall degrading enzymes to carbohydrates, and genetic engineering of genes and metabolic pathways involved in cell wall formation could dramatically alter the outcome for biofuel production. In recent years, several reports have described such approaches that improve saccharification efficiency and this review discusses some of those advances. Another approach is to use quantitative trait locus (QTL) mapping and/or association mapping to identify genes/molecular markers that are associated with cell wall polymer synthesis. These candidate genes can be used for marker-assisted breeding and/or could be manipulated using transgenic approaches. A combination of these techniques is likely to provide novel tools in producing feedstocks for efficient use of selected plant biomass in biofuel production.

Virus-Induced Gene Silencing Offers a Functional Genomics Platform for Studying Plant Cell Wall Formation

Virus-induced gene silencing (VIGS) is a powerful genetic tool for rapid assessment of plant gene functions in the post-genomic era. Here, we successfully implemented a Tobacco Rattle Virus (TRV)-based VIGS system to study functions of genes involved in either primary or secondary cell wall formation in Nicotiana benthamiana plants. A 3-week post-VIGS time frame is sufficient to observe phenotypic alterations in the anatomical structure of stems and chemical composition of the primary and secondary cell walls. We used cell wall glycan-directed monoclonal antibodies to demonstrate that alteration of cell wall polymer synthesis during the secondary growth phase of VIGS plants has profound effects on the extractability of components from woody stem cell walls. Therefore, TRV-based VIGS together with cell wall component profiling methods provide a high-throughput gene discovery platform for studying plant cell wall formation from a bioenergy perspective.

Preparative enzymatic synthesis of polyprenyl-pyrophosphoryl- N-acetylglucosamine, an essential lipid intermediate for the biosynthesis of various bacterial cell envelope polymers

The WecA transferase is an integral membrane protein and a member of the polyprenyl phosphate N-acetylhexosamine-1-phosphate transferase superfamily. It initiates the biosynthesis of various bacterial cell envelope components such as the lipopolysaccharide O-antigen. We report on the first large-scale enzymatic synthesis, purification, and characterization of the undecaprenyl-pyrophosphoryl- N-acetylglucosamine product of the WecA transferase. This is an essential lipid intermediate for the biosynthesis of various bacterial cell envelope components. Its availability in a pure form will allow the biochemical and structural characterization of the various enzymes requiring it as a substrate for the synthesis of cell wall polymers.

Two Leucine-Rich Repeat Receptor Kinases Mediate Signaling, Linking Cell Wall Biosynthesis and ACC Synthase in Arabidopsis

The plant cell wall is a dynamic structure that changes in response to developmental and environmental cues through poorly understood signaling pathways. We identified two Leu-rich repeat receptor-like kinases in Arabidopsis thaliana that play a role in regulating cell wall function. Mutations in these FEI1 and FEI2 genes (named for the Chinese word for fat) disrupt anisotropic expansion and the synthesis of cell wall polymers and act additively with inhibitors or mutations disrupting cellulose biosynthesis. While FEI1 is an active protein kinase, a kinase-inactive version of FEI1 was able to fully complement the fei1 fei2 mutant. The expansion defect in fei1 fei2 roots was suppressed by inhibition of 1-aminocyclopropane-1-carboxylic acid (ACC) synthase, an enzyme that converts Ado-Met to ACC in ethylene biosynthesis, but not by disruption of the ethylene response pathway. Furthermore, the FEI proteins interact directly with ACC synthase. These results suggest that the FEI proteins define a novel signaling pathway that regulates cell wall function, likely via an ACC-mediated signal.

Sucrose synthase is associated with the cell wall of tobacco pollen tubes.

Sucrose synthase (Sus; EC 2.4.1.13) is a key enzyme of sucrose metabolism in plant cells, providing carbon for respiration and for the synthesis of cell wall polymers and starch. Since Sus is important for plant cell growth, insights into its structure, localization, and features are useful for defining the relationships between nutrients, growth, and cell morphogenesis. We used the pollen tube of tobacco (Nicotiana tabacum) as a cell model to characterize the main features of Sus with regard to cell growth and cell wall synthesis. Apart from its role during sexual reproduction, the pollen tube is a typical tip-growing cell, and the proper construction of its cell wall is essential for correct shaping and direction of growth. The outer cell wall layer of pollen tubes consists of pectins, but the inner layer is composed of cellulose and callose; both polymers require metabolic precursors in the form of UDP-glucose, which is synthesized by Sus. We identified an 88-kD polypeptide in the soluble, plasma membrane and Golgi fraction of pollen tubes. The protein was also found in association with the cell wall. After purification, the protein showed an enzyme activity similar to that of maize (Zea mays) Sus. Distribution of Sus was affected by brefeldin A and depended on the nutrition status of the pollen tube, because an absence of metabolic sugars in the growth medium caused Sus to distribute differently during tube elongation. Analysis by bidimensional electrophoresis indicated that Sus exists as two isoforms, one of which is phosphorylated and more abundant in the cytoplasm and cell wall and the other of which is not phosphorylated and is specific to the plasma membrane. Results indicate that the protein has a role in the construction of the extracellular matrix and thus in the morphogenesis of pollen tubes.

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.

In vitro studies on mode of action of antifungal 8.O.4′-neolignans occurring in certain species of Virola and related genera of Myristicaceae

Neutral racemic antifungal alcohols of 8.O.4′-neolignan type, were evaluated for inhibitory activity towards the fungal cell wall, using the whole cell Neurospora crassa hyphal growth inhibition assay. Results strongly suggested that these compounds could act by inhibiting cell wall polymer synthesis or assembly. Active compounds were tested for their inhibitory activities against (1,3)- β-glucan synthase, an enzyme that catalyzes the synthesis of the major wall polymer (1,3)- β-glucan. Although these compounds were found to be inhibitors of the enzyme (inhibition ranging between 2 and 72% at 250 μg/ml), comparison of these results with those from agar dilution assays, allow us to infer that these compounds do not act via the inhibition of glucan synthase. In addition, ketones with same pattern of substitution as alcohols, which have no antifungal properties in agar dilution assays, still displayed similar glucan synthase inhibition.

Molecular basis of cell integrity and morphogenesis in Saccharomyces cerevisiae

In fungi and many other organisms, a thick outer cell wall is responsible for determining the shape of the cell and for maintaining its integrity. The budding yeast Saccharomyces cerevisiae has been a useful model organism for the study of cell wall synthesis, and over the past few decades, many aspects of the composition, structure, and enzymology of the cell wall have been elucidated. The cell wall of budding yeasts is a complex and dynamic structure; its arrangement alters as the cell grows, and its composition changes in response to different environmental conditions and at different times during the yeast life cycle. In the past few years, we have witnessed a profilic genetic and molecular characterization of some key aspects of cell wall polymer synthesis and hydrolysis in the budding yeast. Furthermore, this organism has been the target of numerous recent studies on the topic of morphogenesis, which have had an enormous impact on our understanding of the intracellular events that participate in directed cell wall synthesis. A number of components that direct polarized secretion, including those involved in assembly and organization of the actin cytoskeleton, secretory pathways, and a series of novel signal transduction systems and regulatory components have been identified. Analysis of these different components has suggested pathways by which polarized secretion is directed and controlled. Our aim is to offer an overall view of the current understanding of cell wall dynamics and of the complex network that controls polarized growth at particular stages of the budding yeast cell cycle and life cycle.

Molecular basis of cell integrity and morphogenesis in Saccharomyces cerevisiae.

In fungi and many other organisms, a thick outer cell wall is responsible for determining the shape of the cell and for maintaining its integrity. The budding yeast Saccharomyces cerevisiae has been a useful model organism for the study of cell wall synthesis, and over the past few decades, many aspects of the composition, structure, and enzymology of the cell wall have been elucidated. The cell wall of budding yeasts is a complex and dynamic structure; its arrangement alters as the cell grows, and its composition changes in response to different environmental conditions and at different times during the yeast life cycle. In the past few years, we have witnessed a profilic genetic and molecular characterization of some key aspects of cell wall polymer synthesis and hydrolysis in the budding yeast. Furthermore, this organism has been the target of numerous recent studies on the topic of morphogenesis, which have had an enormous impact on our understanding of the intracellular events that participate in directed cell wall synthesis. A number of components that direct polarized secretion, including those involved in assembly and organization of the actin cytoskeleton, secretory pathways, and a series of novel signal transduction systems and regulatory components have been identified. Analysis of these different components has suggested pathways by which polarized secretion is directed and controlled. Our aim is to offer an overall view of the current understanding of cell wall dynamics and of the complex network that controls polarized growth at particular stages of the budding yeast cell cycle and life cycle.

The sensitivity of archaebacteria to antibiotics

Summary Most of the species of the two largest groups of archaebacteria - halobacteria (9 strains) and methanogens (10 strains) - were tested by the agar diffusion test for their sensitivity to 28 well-known antibiotics including typical inhibitors of membrane function and the synthesis of cell wall polymers, protein or RNA. Archaebacteria were found to be insensitive to many antibiotics acting against eubacteria and eucaryotes, e.g. those inhibiting the synthesis or cross-linkage of the peptide subunit of murein or the synthesis of RNA. They are, however, sensitive towards inhibitors of the lipid cycle of the biosynthesis of cell wall polymers, to the protein inhibitor chloramphenicol, and to the feed additives lasalocid and monensin, which interfere with the membrane function. It remains to be shown, whether this insensitivity to many of the antibiotics is due to the impermeability of the cytoplasmic membrane or to the inactivation of the antibiotic by the cell rather than to the lack of a particular target for the antibiotic. It is pointed out that the very characteristic sensitivity pattern of archaebacteria may serve as a guideline in the search for further biochemical and molecular differences between archaebacteria, eubacteria, and eucaryotes, and that it may also be helpful in designing selective media for the enrichment and isolation of new types of archaebacteria or in controlling mixed populations of eubacteria, archaebacteria, and eucaryotes, e.g. in the rumen and in biogas plants.

Effect of Inhibition of Deoxyribonucleic Acid and Protein Synthesis on the Direction of Cell Wall Growth in Streptococcus faecalis

Selective inhibition of protein synthesis in Streptococcus faecalis (ATCC 9790) was accompanied by a rapid and severe inhibition of cell division and a reduction of enlargement of cellular surface area. Continued synthesis of cell wall polymers resulted in rapid thickening of the wall to an extent not seen in exponential-phase populations. Thus, the normal direction of wall growth was changed from a preferential feeding out of new wall surface to that of thickening existing cell surfaces. However, the overall manner in which the wall thickened, from nascent septa toward polar regions, was the same in both exponential-phase and inhibited populations. In contrast, selective inhibition of deoxyribonucleic acid (DNA) synthesis using mitomycin C was accompanied by an increase in cellular surface area and by division of about 80% of the cells in random populations. Little or no wall thickening was observed until the synthesis of macromolecules other than DNA was impaired and further cell division ceased. Concomitant inhibition of both DNA and protein synthesis inhibited cell division but permitted an increase in average cell volume. In such doubly inhibited cells, walls thickened less than in cells inhibited for protein synthesis only. On the basis of the results obtained, a model for cell surface enlargement and cell division is presented. The model proposes that: (i) each wall enlargement site is influenced by an individual chromosome replication cycle; (ii) during chromosome replication peripheral surface enlargement would be favored over thickening (or septation); (iii) a signal associated with chromosome termination would favor thickening (and septation) at the expense of surface enlargement; and (iv) a factor or signal related to protein synthesis would be required for one or more of the near terminal stages of cell division or cell separation, or both.