Phase Separation of Plant Cell Wall Polysaccharides and Its Implications for Cell Wall Assembly

Concentrated binary mixtures of polymers in solution commonly exhibit immiscibility, resolving into two separate phases each of which is enriched in one polymer. The plant cell wall is a concentrated polymer assembly, and phase separation of the constituent polymers could make an important contribution to its structural organization and functional properties. However, to our knowledge, there have been no published reports of the phase behavior of cell wall polymers, and this phenomenon is not included in current cell wall models. We fractionated cell walls purified from the pericarp of unripe tomatoes (Lycopersicon esculentum) by extraction with cyclohexane diamine tetraacetic acid (CDTA), Na2CO3, and KOH and examined the behavior of concentrated mixtures. Several different combinations of fractions exhibited phase separation. Analysis of coexisting phases demonstrated the immiscibility of the esterified, relatively unbranched pectic polysaccharide extracted by CDTA and a highly branched, de-esterified pectic polysaccharide present in the 0.5 N KOH extract. Some evidence for phase separation of the CDTA extract and hemicellulosic polymers was also found. We believe that phase separation is likely to be a factor in the assembly of pectic polysaccharides in the cell wall and could, for example, provide the basis for explaining the formation of the middle lamella.     

被子植物生殖细胞的细胞壁

本文综述了国内外有关被子植物生殖细胞壁的资料,概述了它的形成、发育、性质和功能;在这些方面,生殖细胞壁的特征因植物种类而异。     

植物细胞壁松弛蛋白——膨胀素

膨胀素(expansin,也称作扩张素或扩张蛋白)是一种引起植物细胞壁松弛的蛋白质,在植物细胞伸展以及一系列涉及细胞壁修饰的生命活动中起着关键作用。膨胀素由多基因家族编码,目前的研究表明膨胀素超家族由4个基因亚家族构成。膨胀素存在于不同的种属植物中,并克隆了大量的扩张蛋白基因。综述了近年来国内外有关膨胀素基因和蛋白的结构特征及作用机制等方面的研究进展。     

植物细胞壁松弛因子

植物细胞壁的松弛是细胞伸长必需的一个生理过程,发生于植物生长发育的各个阶段。研究发现参与细胞壁松弛的因子有多种,主要包括膨胀素（expansin）、木葡聚糖内转糖苷酶/水解酶（XTH）、糖基水解酶和羟基自由基（·OH）四大类。本文主要对这些细胞壁松弛因子的结构特征、作用机制及其在植物生理过程中的作用等方面的研究进展进行综述。     

Cell Wall and Morphological Changes Induced by Temperature Shift in Bacillus subtilis Cell Wall Mutants

Bacillus subtilis RUB1012 and RUB1013 have the following phenotype when grown at 45 degrees C: no growth on tryptose blood agar base, growth as clumps of spheres in broth culture, a slow autolysis rate, and a low proportion of teichoic acid to peptidoglycan. Revertants of strain RUB1012 (RUB2032, RUB2012, and RUB2042) that could grow on tryptose blood agar base were isolated. Each revertant had a different proportion of teichoic acid to peptidoglycan. The nanomoles of phosphorus per milligram of cell wall at the nonpermissive temperature were 141, 160, 236, and 541 for strain RUB1012 and revertants RUB2032, 2012, and 2042, respectively, as compared with 1,100 for the parent strain. With most bacteriophage tested, plating efficiency was related to the amount of glucosylated teichoic acid. Scanning electron microscopy was used to study strain RUB2032 during a shift from growth at 30 degrees C to growth at 45 degrees C. The change from rod to sphere began with the thickening of the cylindrical portion of the cell. Caps of the cells appeared to be immune to the thickening process. During growth, the cells became progressively shorter and thicker, and cell separation was inhibited. When cells of strain RUB2032 were shifted from growth at 45 degrees C to growth at 30 degrees C, accumulation of an amorphous material on the outer surfaces of the cells preceded the change from sphere to rod morphology. Cells remained clumped, with rods appearing at the periphery of the clumps. Analysis by DNA-mediated transformation and PBS1-mediated transduction indicated that strains RUB1012 and RUB1013 have multiple mutations mapping in the same region as other cell wall mutations.     

A Bacterial Cell Wall Stain1

A new method is given to stain bacterial cell walls, especially of Escherichia coli and Bacillus cereus. The cells are smeared in water on a slide and, as soon as air-dry, are stained 3-4 minutes with a 1 % aqueous solution of new fuchsin. The smear is washed with water until the stain ceases to run and is then allowed to air dry. The slide is placed on a 50°C. warm plate for 10-20 seconds, and the smear is then covered with a thin film of a 1-2% solution of Congo red at a pH of about 9.5. The smear is ready for observation as soon as dry or it may be washed with water if desired before observation.     

植物细胞壁蛋白质组学研究进展

植物细胞壁蛋白质在细胞代谢和发育调控、细胞壁组分修饰、信号转导及胁迫响应等生物学事件中具有重要功能.最近,国内外学者开展了大量植物细胞壁蛋白质组学的研究工作,并取得了巨大进展.本文详述了细胞壁蛋白质的分类、提取、鉴定及生物信息学分析的最新进展,总结了植物细胞壁蛋白质组学的应用和面临的挑战,提出了植物细胞壁蛋白质组学研究的框架图,以期为植物细胞壁蛋白质组学的广泛研究提供借鉴.     

Plant Cell Wall Matrix Polysaccharide Biosynthesis

The wall of an expanding plant cell consists primarily of cellulose microfibrils embedded in a matrix of hemicellulosic and pectic polysaccharides along with small amounts of structural and enzymatic proteins. Matrix polysaccharides are synthesized in the Golgi and exported to the cell wall by exocytosis, where they intercalate among cellulose microfibrils, which are made at the plasma membrane and directly deposited into the cell wall. Involvement of Golgi glucan synthesis in auxin-induced cell expansion has long been recognized; however, only recently have the genes corresponding to glucan synthases been identified. Biochemical purification was unsuccessful because of the labile nature and very low abundance of these enzymes. Mutational genetics also proved fruitless. Expression of candidate genes identified through gene expression profiling or comparative genomics in heterologous systems followed by functional characterization has been relatively successful. Several genes from the cellulose synthase-like （Csl） family have been found to be involved in the synthesis of various hemicellulosic glycans. The usefulness of this approach, however, is limited to those enzymes that probably do not form complexes consisting of unrelated proteins. Nonconventional approaches will continue to incrementally unravel the mechanisms of Golgi polysaccharide biosynthesis.     

Cell Wall Autolysis During Kiwifruit Development

Cell walls prepared from developing kiwifruits showed autolyticactivity. The proteins extracted from active walls were alsoable to release carbohydrates from inactive cell walls. Analysisof the sugars released, using both procedures, showed that uronicacids were the major component, especially during the firsthours of incubation, although neutral sugars such as glucoseand galactose were also present. Most of the carbohydrates autolyticallyreleased from the cell wall eluted in the void volume on a BioGel P2 column. However, carbohydrates released from inactivecell walls by the protein extract mostly eluted in the monosaccharideuronic acid and glucose peaks. The autolytic activity of isolatedcell walls, as well as the glycosylhydrolase activity of theproteins extracted from the cell walls, showed important changesduring fruit development. The differences between autolyticactivity and the glycosylhydrolase activity against the cellwall suggest that the glycosylhydrolases ‘in muro’are subjected to some regulatory mechanism which disappearswith their extraction. Finally, the role of glycosylhydrolases,such as polygalacturonases and galactosidases, in relation tocell wall changes in fruits, is discussed.Copyright 1998 Annalsof Botany Company Actinidia deliciosa; autolysis; cell wall enzymes; fruit growth; glycosylhydrolases; kiwifruit.     

Subunit Cell Wall of Sulfolobus acidocaldarius

The cell wall of Sulfolobus acidocaldarius has been isolated. Cells were mechanically disrupted with a French press, and the cytoplasmic membrane was removed by extracting cell-envelope fragments with Triton X-100. The Triton-insoluble cell wall material retained the characteristic subunit structure when examined in the electron microscope. Isolated cell wall fragments formed in open sheets that were easily separated from cytoplasmic contamination. Chemical studies showed that the Triton-insoluble cell wall fragments consisted of lipoprotein with small amounts of carbohydrate and hexosamine. The amino acid composition indicated a highly charged hydrophobic cell surface. The presence of diaminopimelic acid with only traces of muramic acid indicates that the cell envelope does not have a rigid peptidoglycan layer. The results of chemical analyses and electron microscopy suggest a wall-membrane interaction stabilizing the cell envelope. The chemical and physical properties of this type of cell envelope would appear to form the basis for a new major division of bacteria with the definitive characteristics of a morphologically distinct subunit cell wall devoid of peptidoglycan.     

Cell Wall Protein in Bacillus subtilis

The cell wall of Bacillus subtilis 168 contains protein that is refractory to removal by salts, detergents, and denaturants.     

植物原生质体的细胞壁再生

细胞壁作为植物细胞重要的组成部分,在决定细胞形状、维持机械支撑、吸收养分等方面发挥重要功能。因此,揭示植物细胞壁合成的调控机制具有重大的生物学意义。基于植物组织水平研究细胞壁的生物合成具有难以控制时间尺度、观察空间狭小等局限性。原生质体作为去除细胞壁的单个细胞是研究细胞壁再生的理想系统。在过去的几十年里报道了大量关于植物原生质体再生细胞壁的研究,但是关于细胞壁再生的机制尚不清楚。该综述介绍了目前应用于植物原生质体再生细胞壁研究的主要技术和取得的研究进展,并且对该领域的后续发展进行了展望,为进一步阐明植物细胞壁生物合成的机制提供理论参考。     

Cell Wall Assembly in Saccharomyces cerevisiae

An extracellular matrix composed of a layered meshwork of β-glucans, chitin, and mannoproteins encapsulates cells of the yeast Saccharomyces cerevisiae. This organelle determines cellular morphology and plays a critical role in maintaining cell integrity during cell growth and division, under stress conditions, upon cell fusion in mating, and in the durable ascospore cell wall. Here we assess recent progress in understanding the molecular biology and biochemistry of cell wall synthesis and its remodeling in S. cerevisiae. We then review the regulatory dynamics of cell wall assembly, an area where functional genomics offers new insights into the integration of cell wall growth and morphogenesis with a polarized secretory system that is under cell cycle and cell type program controls.