Structure of Plant Cell Walls: X. RHAMNOGALACTURONAN I, A STRUCTURALLY COMPLEX PECTIC POLYSACCHARIDE IN THE WALLS OF SUSPENSION-CULTURED SYCAMORE CELLS

The purification and characterization of a pectic polymer, rhamnogalacturonan I, present in the primary cell walls of dicots is described. Rhamnogalacturonan I accounts for approximately 7% of the mass of the walls isolated from suspension-cultured sycamore cells. As purified, rhamnogalacturonan I has a molecular weight of approximately 200,000 and is composed primarily of l-rhamnosyl, d-galacturonosyl, l-arabinosyl, and d-galactosyl residues. The backbone of rhamnogalacturonan I is thought to be composed predominantly of d-galacturonosyl and l-rhamnosyl residues in a ratio of approximately 2:1. About half of the l-rhamnosyl residues are 2-linked and are glycosidically attached to C(4) of a d-galacturonosyl residue. The other half of the l-rhamnosyl residues are 2,4-linked and have a d-galacturonosyl residue glycosidically attached at C(2). Sidechains averaging 6 residues in length are attached to C(4) of the l-rhamnosyl residues. There are many different sidechains, containing variously linked l-arabinosyl, and/or d-galactosyl residues.     

Studies on the Pectic Substances of Plant Cell Walls: III. DEGRADATION OF CARROT ROOT CELL WALLS BY ENDOPECTATE LYASE PURIFIED FROM ERWINIA AROIDEAE

Pectate lyase was isolated from the cell extract of Erwinia aroideae. The enzyme was further purified to a high degree by a procedure involving ammonium sulfate fractionation and chromatography on CM-Sephadex C-50 and on Sephadex G-200. The enzyme attacked its substrate in an endo fashion and was more active on the sodium salt of acid-insoluble polygalacturonate or pectic acid than it was on the methoxylated pectin. The enzyme had an optimum pH at 9.3, was stimulated by calcium ions, and was completely inhibited by ethylenediaminetetraacetic acid. In addition, the reaction products showed an absorption maximum between 230 and 235 nm and reacted with thiobarbituric acid. These results indicate that the purified enzyme is an endopectate lyase. The endopectate lyase also had the ability to solubilize effectively the pectic fraction from the cell walls of carrot (Daucus carota) root tissue. The enzyme released 30.5% of the wall as soluble products and also liberated all of the galacturonic acid present in the walls. The total neutral sugars released by the enzyme were 10.6% of the walls, which corresponded to 71.5% of noncellulosic neutral sugars. The soluble products were separated into five fractions by DEAE-Sephadex A-50 column chromatography. Based on the analysis of sugar composition of each fraction, the pectic fraction of carrot cell wall is presented.     

Structure of Plant Cell Walls: VIII. A New Pectic Polysaccharide

This paper describes the isolation and characterization of rhamnogalacturonan II, a hitherto unobserved component of the primary cell walls of dicotyledonous plants. Rhamnogalacturonan II constitutes 3 to 4% of the primary cell walls of suspension-cultured sycamore (Acer pseudoplatanus) cells. Rhamnogalacturonan II is a very complex polysaccharide yielding, upon hydrolysis, 10 different monosaccharides including the rarely observed sugars apiose, 2-O-methylxylose, and 2-O-methylfucose. In addition, rhamnogalacturonan II is characterized by the rarely observed glycosyl interconnections of 2-linked glucuronosyl, 3,4-linked fucosyl, and 3-linked rhamnosyl residues. These glycosyl linkages have never previously been detected in primary sycamore cell walls. Evidence is presented which suggests that polysaccharides similar to rhamnogalacturonan II are present in the primary cell walls of the three other dicotyledonous plants examined.     

ANTHERIDIAL FORMATION IN ONOCLEA SENSIBILIS L.: GENESIS OF THE JACKET CELL WALLS

Antheridial initiation in Onoclea sensibilis L., an advanced leptosporangiate fern, begins with the production of a small, wedge-shaped cell within the anterior region of the vegetative cell. This is in contrast to previous reports claiming that the initials are formed by a localized protuberance in the cell wall of the vegetative cell (Campbell, 1886; Davie, 1951; Leung and Naf, 1979; Nayar and Kaur, 1971). The mature antheridium of Onoclea is composed of three uniquely shaped jacket cells surrounding spermatogenous cells. The two funnel-shaped jacket cell walls are shown to form in a lateral circular manner. Except for the production of the antheridial initial cell, jacket cell formation in Onoclea proceeds in accordance with the classical concept of antheridial development in advanced ferns accredited in part to Atkinson (1894), Campbell (1886), Kny (1869), and Strasburger (1869). The classical concept has been contested in more recent years by Davie (1951), Leung and Näf (1979), and Verma and Khullar (1966).     

THE ULTRASTRUCTURE OF PHYCOPELTIS (CHROOLEPIDACEAE: CHLOROPHYTA). I. SPOROPOLLENIN IN THE CELL WALLS

Electron microscope observations on Phycopeltis epiphyton, a subaerial green alga found growing on the leaves of vascular plants and bryophytes, revealed the presence of a densely staining material within the inner and outer zones of the cell walls. This material resists acetolysis, is degraded by chromic acid, is unaffected by ethanolamine and exhibits secondary fluorescence when stained with the fluorochrome Primuline. These characteristics, together with infrared absorption spectra indicate that, on the basis of currently accepted criteria, the densely staining material is a sporopollenin and that it is a major component of the cell wall. Tests for cellulose, chitin, and lignin were negative, and little if any silica is present. It is suggested that negative results in tests for cellulose may be due to a masking effect by the sporopollenin. Comparison of the fine structure of the cell walls of P. epiphyton, pollen grains, and algal cells (known to contain sporopollenin) supports the suggestion that sporopollenin deposition on “unit membranes” is universal. Morphological similarity among sporopollenin lamellae in P. epiphyton, pollen grains, spores of land plants, and the trilaminar sporopollenin sheath in Chlorella, Scenedesmus, and Pediastrum indicates that the structures may be analogous. As in pollen grains, sporopollenin may provide protection against desiccation and parasitism. It may also be involved in the adhesion of Phycopeltis to host plants and in the adhesion between adjacent filaments of the thallus.     

The Structure of Plant Cell Walls: VI. A Survey of the Walls of Suspension-cultured Monocots

The primary cell walls of six suspension-cultured monocots and of a single suspension-cultured gymnosperm have been investigated with the following results: (a) the compositions of all six monocot cell walls are remarkably similar, despite the fact that the cell cultures were derived from diverse tissues; (b) the cell walls of suspension-cultured monocots differ substantially from those of suspension-cultured dicots and from the suspension-cultured gymnosperm; (c) an arabinoxylan is a major component (40% or more by weight) of monocot primary cell walls; (d) mixed β-1,3; β-1,4-glucans were found only in the cell wall preparations of rye grass endosperm cells, and not in the cell walls of any of the other five monocot cell cultures nor in the walls of suspension-cultured Douglas fir cells; (e) the monocot primary cell walls studied contain from 9 to 14% cellulose, 7 to 18% uronic acids, and 7 to 17% protein; (f) hydroxyproline accounts for less than 0.2% of the cell walls of monocots. Similar data on the soluble extracellular polysaccharides secreted by these cells are included.     

益智胚珠的珠心冠原与承珠盘细胞壁的组织化学研究

用组织化学方法研究了益智胚珠中珠心冠原与承珠盘细胞壁的组成。珠心冠原细胞壁含有纤维素、胼胝质、果胶质,但不含栓质。承珠盘细胞壁含有纤维素、木质素、果胶质,也不含栓质。讨论了珠心冠原与承珠盘细胞壁的组成及承珠盘的可能功能。     

The Structure of Plant Cell Walls: VII. Barley Aleurone Cells

The walls of barley (Hordeum vulgare var. Himalaya) aleurone cells are composed of two major polysaccharides, arabinoxylan (85%) and cellulose (8%). The cell wall preparations contain 6% protein, but this protein does not contain detectable amounts of hydroxyproline. The arabinoxylan has a linear 1,4-xylan backbone; 33% of the xylosyl residues are substituted at the 2 and/or 3 position with single arabinofuranosyl residues. The results of in vitro cellulose binding experiments support the hypothesis that noncovalent bonds between the arabinoxylan chains and cellulose fibers play a part in maintaining wall structure. It is suggested that bonding between the arabinoxylan chains themselves is also utilized in forming the walls.     

Host-Pathogen Interactions: XVI. PURIFICATION AND CHARACTERIZATION OF A beta-GLUCOSYL HYDROLASE/TRANSFERASE PRESENT IN THE WALLS OF SOYBEAN CELLS

The fact that fungal glucans will stimulate soybeans to accumulate phytoalexins prompted an investigation of soybean cell beta-1,3-glucanases and beta-glucosidases, as well as the ability of these enzymes to hydrolyze the fungal glucans. Several beta-1,3-glucanases and beta-glucosidases can be solubilized from the walls of suspension-cultured soybean cells by treatment with 1.0 molar sodium acetate buffer. An enzyme, which has been termed beta-glucosylase I, is the dominant beta-1,3-glucanase in the cell wall extracts. Utilizing CM-Sephadex chromatography, hydroxylapatite chromatography, and affinity chromatography, beta-glucosylase I has been purified 71-fold, with 39% recovery, from the mixture of cell wall enzymes. The affinity chromatography column material was prepared by covalently attaching p-aminophenyl-1-beta-d-glucopyranoside, an analog of a beta-glucosylase I substrate, to Sepharose. beta-Glucosylase I, purified by this procedure, yields a single band on isoelectric focusing gels (pH 8.9). However, the purified beta-glucosylase I yields a darkly-staining protein band at an apparent molecular weight of 69,000 and several lightly-staining protein bands in sodium dodecyl sulfate polyacrylamide gels. Additional purification procedures fail to remove these lightly-staining protein bands.beta-Glucosylase I will hydrolyze the beta-glucan substrates, laminarin (3-linked) and lichenan (3- and 4-linked), and therefore, possesses beta-glucanase activity. Studies of the progressive hydrolysis of laminarin by beta-glucosylase I demonstrate that the enzyme hydrolyzes polysaccharide substrates in an exo manner. beta-Glucosylase I will also hydrolyze a variety of low molecular weight beta-glucosides including various beta-linked diglucosides. Thus, beta-glucosylase I also possesses beta-glucosidase activity.Several lines of evidence are presented that the beta-glucanase and the beta-glucosidase activities exhibited by purified beta-glucosylase I preparations are catalyzed by the same enzyme. This evidence includes inhibition studies which indicate that the beta-glucanase and the beta-glucosidase activities of beta-glucosylase I are catalyzed at the same active site. beta-Glucosylase I will also catalyze glucosyl transfer. This catalytic activity is responsible for the observed ability of the enzyme to synthesize di- and trisaccharides from laminarin. The disaccharides formed by beta-glucosylase I-catalyzed transglucosylation are the beta-anomers of the 6-, 4-, 3-, and 2-linked diglucosides in the relative proportions of 10:1:1:1. The ability of beta-glucosylase I to catalyze glucosyl transfer indicates that beta-glucosylase I is biochemically more similar to previously studied beta-glucosidases than to beta-glucanases. This conclusion is supported by the observation that beta-glucosylase I is strongly inhibited by 1,5-d-gluconolactone, an inhibitor of beta-glucosidases but not of beta-glucanases.     

莼菜(Brasenia schreberi)表皮腺毛细胞高尔基体中一种内含物的初步研究(简报)

在不经过任何特殊处理的常规生物样品中,高尔基体扁囊(Saccules)及囊泡(Vacuoles)中的内含物在电镜下常为低电子密度,而最近我们在莼菜(Brasenia schreberi)叶柄及叶片的表皮腺毛细胞中观察到带有高电子密度的高尔基体内含物。在扁囊中,这些内含物多呈波浪形(图版Ⅰ,图1)。这种特殊形态的高尔基体内含物以及这种未经任何特殊处理而显示出高尔基体中某些物质的现象是前人没有报道过的,本文就这种内含物的结构、性质以及其染色机制进行了初步探讨。     

The Structure of Plant Cell Walls: II. The Hemicellulose of the Walls of Suspension-cultured Sycamore Cells

The molecular structure, chemical properties, and biological function of the xyloglucan polysaccharide isolated from cell walls of suspension-cultured sycamore (Acer pseudoplatanus) cells are described. The sycamore wall xyloglucan is compared to the extracellular xyloglucan secreted by suspension-cultured sycamore cells into their culture medium and is also compared to the seed “amyloid” xyloglucans.     

A COMPARISON OF THE HETEROGENEOUS NUCLEAR RNA OF HELA CELLS IN DIFFERENT PERIODS OF THE CELL GROWTH CYCLE

HeLa cells synthesize heterogeneous nuclear RNA (HnRNA) in the G₁, S, and G₂ portions of the cell cycle. HnRNA prepared from these various periods was compared by RNA-DNA hybridization experiments. The results indicated that some of the HnRNA molecules were equivalent at all times in the cell cycle, but limitations in the sensitivity of the hydridization reactions, as well as in the spectrum of hybridizing molecules, restrict the conclusions that can be drawn from these comparisons.     

THE COMPOSITION OF THE DEVELOPING PRIMARY WALL IN ONION ROOT TIP CELLS. II. CYTOCHEMICAL LOCALIZATION

Jensen , William A. (U. California, Berkeley.) The composition of the developing primary wall in onion root tip cells. II. Cytochemical localization. Amer. Jour. Bot. 47(4) : 287—295. Illus. 1960.–The composition of the developing cell wall in the first 2 mm. of the onion root tip was studied using a cytochemical technique that permitted the detection of hemicellulose and the noncellulosic polysaccharides as well as the pectic substances and cellulose. The technique is based on the combination of a differential extraction procedure with the periodic acid-Schiff reaction for carbohydrates. The data obtained indicate that the cells of the apical initials are low in all wall substances but that all of the wall materials are present to some extent. Early in cell development, differences appear in the composition of the walls of the various tissues. The cortical cells are relatively high in the noncellulosic polysaccharides and cellulose while relatively low in the pectic substances and hemicellulose. Very early in development the protoderm is similar to the cortex, but differences develop during the radial enlargement of the cells. During this stage the walls of the protodermal cells are low in the noncellulosic polysaccharides and cellulose and high in pectic substances and hemicellulose. As elongation progresses, these differences are lost and the 2 tissues become very similar. The vascular cell walls are low in the noncellulosic polysaccharides and cellulose and are high in pectic substances and hemicellulose early in development. Later, hemicellulose becomes relatively more important. When the cell wall materials are sequentially extracted, no change in the general morphology of the cell occurs until only the noncellulosic polysaccharides and the cellulose remained. When the noncellulosic polysaccharides are then removed, the cells remain intact but are 30% less in diameter. This suggests that while cellulose is of critical importance, the noncellulosic polysaccharides may play a major role in determining the physical characteristics of the wall.     

THE EFFECTS OF RED BLOOD CELL EXTRACTS ON THE PROLIFERATION OF ERYTHROCYTE PRECURSOR CELLS, IN VIVO

Saline incubation extracts of mature erythrocytes were assayed in vivo by a variety of techniques in order to study their ability to modify the proliferation of maturing erythroid cells. Using comparable extracts from granulocytes and lymphocytes, the specificity of the effect of the red cell extract for erythroid cells was confirmed by measurement of autoradiographic labelling indices, radio-iron incorporation and spleen colony growth. The erythroid cells were found to be very sensitive to the effects of the extract, as little as 10 μg per mouse producing a maximum effect on iron incorporation. It was found that the extract does not block erythroid cell proliferation completely but simply lengthens the cell cycle, mainly by increasing the G₁ phase of the cycle. There was no effect on the committed erythroid precursor cells. The in vivo activity, specificity and non-toxicity to the cells, together with the cells' sensitivity to red cell extract suggest, therefore, that this inhibitor may play a physiological role in the control of red cell production.