DIFFERENCES IN THE OCCURRENCE AND DISTRIBUTION OF HYDROXYPROLINE-PROTEINS AMONG THE ALGAE

Fifty algae from seven phyla have been examined in order to determine whether they contain protein-bound hydroxyproline and whether this hydroxyproline is concentrated in the cell wall. Green algae, with the exception of Nitella, all contain hydroxyproline, and in most cases it is concentrated in the cell wall. Hydroxyproline is also present in low levels in the brown algae, but here it is concentrated in the soluble proteins. Red algae contain no hydroxyproline. The presence of hydroxyproline in blue-green algae is variable, but when present the levels are low. It appears, then, that the major algal phyla differ with respect to the distribution and occurrence of hydroxyproline-proteins.     

Chemical and in situ characterization of macromolecular components of the cell walls from the green seaweed Codium fragile

A comprehensive analysis of the carbohydrate-containing macromolecules from the coencocytic green seaweed Codium fragile and their arrangement in the cell wall was carried out. Cell walls in this seaweed are highly complex structures composed of 31% (w/w) of linear (1-->4)-beta-D-mannans, 9% (w/w) of pyruvylated arabinogalactan sulfates (pAGS), and low amounts of hydroxyproline rich-glycoprotein epitopes (HRGP). In situ chemical imaging by synchrotron radiation Fourier transform infrared (SR-FTIR) microspectroscopy and by immunolabeling using antibodies against specific cell wall carbohydrate epitopes revealed that beta-d-mannans and pAGS are placed in the middle part of the cell wall, whereas HRGP epitopes (arabinogalactan proteins (AGPs) and extensins) are located on the wall boundaries, especially in the utricle apical zone. pAGS are sulfated at C-2 and/or C-4 of the 3-linked beta-L-arabinopyranose units and at C-4 and/or C-6 of the 3-linked beta-D-galactopyranose residues. In addition, high levels of ketals of pyruvic acid were found mainly at 3,4- of some terminal beta-D-Galp units forming a five-membered ring. Ramification was found at some C-6 of the 3-linked beta-D-Galp units. In agreement with the immunolabeled AGP epitopes, a nonsulfated branched furanosidic arabinan with 5-linked alpha-L-Araf, 3,5-linked alpha-L-Araf, and terminal alpha-L-Araf units and a nonsulfated galactan structure composed of 3-(3,6)-linked beta-D-Galp residues, both typical of type-II AG glycans were found, suggesting that AGP structures are present at low levels in the cell walls of this seaweed. Based on this study, it is starting to emerge that Codium has developed unique cell wall architecture, when compared, not only with that of vascular plants, but also with other related green seaweeds and algae.     

Biochemical and tissue print analyses of hydroxyproline-rich glycoproteins in cell walls of sporophytic maize tissues

In an effort to understand the role of hydroxyproline-rich glycoproteins (HRGPs) in plant cell wall structure, we studied the distribution and physical properties of PC-1-like proteins (PC-1 being the major pericarp HRGP) throughout sporophytic tissues of two maize (Zea mays L.) varieties. We determined total amounts of hydroxyproline, an indicator of HRGPs, and did tissue print and Western blot analysis. We found hydroxyproline in cell walls of stems, leaves, roots, tassels, and silks. We also observed reactivity of anti-PC-1 monoclonal antibodies with anatomical prints of these tissues on nitrocellulose paper. Stem nodes and silks contained the most hydroxyproline and exhibited the strongest reaction with the antibody. PC-1 was localized in vascular bundles and the epidermis of stem tissue. However, localization to a specific cell type in the silk could not be determined at the resolution of the tissue print. The stem node protein had the same electrophoretic mobility as the pericarp protein as determined on Western blots prepared from cationic neutral gels. Protein extracts from silk tissues of both varieties studied contained one protein of the same size/charge as that found in pericarp, as well as some minor variant bands. The data presented here document that cell wall proteins are present in many tissues of the maize plant, although they are primarily in cell types contributing to support.     

A new calcium binding glycoprotein family constitutes a major diatom cell wall component.

Diatoms possess silica-based cell walls with species-specific structures and ornamentations. Silica deposition in diatoms offers a model to study the processes involved in biomineralization. A new wall is produced in a specialized vesicle (silica deposition vesicle, SDV) and secreted. Thus proteins involved in wall biogenesis may remain associated with the mature cell wall. Here it is demonstrated that EDTA treatment removes most of the proteins present in mature cell walls of the marine diatom Cylindrotheca fusiformis. A main fraction consists of four related glycoproteins with a molecular mass of approximately 75 kDa. These glycoproteins were purified to homogeneity. They consist of repeats of Ca2+ binding domains separated by polypeptide stretches containing hydroxyproline. The proteins in the EDTA extract aggregate and precipitate in the presence of Ca2+. Immunological studies detected related proteins in the cell wall of the freshwater diatom Navicula pelliculosa, indicating that these proteins represent a new family of proteins that are involved in the biogenesis of diatom cell walls.     

CELL‐WALL POLYMER MAPPING IN THE COENOCYTIC MACROALGA CODIUM VERMILARA (BRYOPSIDALES,CHLOROPHYTA)1

Cell walls in the coenocytic green seaweed Codium vermilara (Olivi) Chiaje (Bryopsidales, Chlorophyta) are composed of ～32% (w/w) β‐(1→4)‐d‐mannans, ～12% sulfated polysaccharides (SPs), and small amounts of hydroxyproline‐rich glycoprotein‐like (HRGP‐L) compounds of the arabinogalactan proteins (AGPs) and arabinosides (extensins). Similar quantities of mannans and SPs were reported previously in the related seaweed C. fragile (Suringar) Hariot. Overall, both seaweed cell walls comprise ～40%–44% of their dry weights. Within the SP group, a variety of polysaccharide structures from pyruvylated arabinogalactan sulfate and pyruvylated galactan sulfate to pyranosic arabinan sulfate are present in Codium cell walls. In this paper, the in situ distribution of the main cell‐wall polymers in the green seaweed C. vermilara was studied, comparing their arrangements with those observed in cell walls from C. fragile. The utricle cell wall in C. vermilara showed by TEM a sandwich structure of two fibrillar‐like layers of similar width delimiting a middle amorphous‐like zone. By immuno‐ and chemical imaging, the in situ distribution of β‐(1→4)‐d‐mannans and HRGP‐like epitopes was shown to consist of two distinct cell‐wall layers, whereas SPs are distributed in the middle area of the wall. The overall cell‐wall polymer arrangement of the SPs, HRGP‐like epitopes, and mannans in the utricles of C. vermilara is different from the ubiquitous green algae C. fragile, in spite of both being phylogenetically very close. In addition, a preliminary cell‐wall model of the utricle moiety is proposed for both seaweeds, C. fragile and C. vermilara.     

Localization and evolution of septins in algae

Septins are a group of GTP‐binding proteins that are multi‐functional, with a well‐known role in cytokinesis in animals and fungi. Although the functions of septins have been thoroughly studied in opisthokonts (fungi and animals), the function and evolution of plant/algal septins are not as well characterized. Here we describe septin localization and expression in the green algae Nannochloris bacillaris and Marvania geminata. The present data suggest that septins localize at the division site when cytokinesis occurs. In addition, we show that septin homologs may be found only in green algae, but not in other major plant lineages, such as land plants, red algae and glaucophytes. We also found other septin homolog‐possessing organisms among the diatoms, Rhizaria and cryptomonad/haptophyte lineages. Our study reveals the potential role of algal septins in cytokinesis and/or cell elongation, and confirms that septin genes appear to have been lost in the Plantae lineage, except in some green algae.     

Evolution of Protein Targeting into “Complex” Plastids: The “Secretory Transport Hypothesis”

Abstract: In algae different types of plastids are known, which vary in pigment content and ultrastructure, providing an opportunity to study their evolutionary origin. One interesting feature is the number of envelope membranes surrounding the plastids. Red algae, green algae and glaucophytes have plastids with two membranes. They are thought to originate from a primary endocytobiosis event, a process in which a prokaryotic cyanobacterium was engulfed by a eukaryotic host cell and transformed into a plastid. Several other algal groups, like euglenophytes and heterokont algae (diatoms, brown algae, etc.), have plastids with three or four surrounding membranes, respectively, probably reflecting the evolution of these organisms by so‐called secondary endocytobiosis, which is the uptake of a eukaryotic alga by a eukaryotic host cell. A prerequisite for the successful establishment of primary or secondary endocytobiosis must be the development of suitable protein targeting machineries to allow the transport of nucleus‐encoded plastid proteins across the various plastid envelope membranes. Here, we discuss the possible evolution of such protein transport systems. We propose that the secretory system of the respective host cell might have been the essential tool to establish protein transport into primary as well as into secondary plastids.     

Patterns of cell division in the filamentous Desmidiaceae, close green algal relatives of land plants

Patterns of cell division and cross wall formation vary among the charophytes, green algae closely related to land plants. One group of charophytes, the conjugating green algae (Zygnematophyceae), is species-rich and is known to vary substantially in the mode of cell division, but the details of these cell division patterns and their phylogenetic distribution remain poorly understood. We studied cross wall development in filamentous Desmidiaceae (a clade of conjugating green algae) using differential interference contrast and fluorescence light microscopy. All strains investigated had centripetal encroachment of a septum, but with several different developmental patterns. In most cases, cell wall formation was delayed with respect to the Cosmarium-type of cell division, and the cross wall was modified considerably after deposition in a manner specific to the particular clade of filamentous desmids. These characteristics were mapped on a phylogeny estimated from a data set of two organellar genes, and the evolutionary implications of the character state distribution were evaluated. The data suggest a complex history of evolution of cell division in this lineage and also imply that Desmidium and Spondylosium are polyphyletic. These results indicate that many features of the cell shape are determined at the time of cell division in conjugating green algae.     

Cell wall hydroxyproline-polysaccharide associations in Lupinus hypocotyls

Extraction of lupin hypocotyl cell walls with guanidine thiocynate, both before and after dilute acid treatment does not dissolve the hydroxyproline indicating that compounds containing this amino acid are probably covalently linked to insoluble wall constituents other than through acid labile arabinofuranose-hydroxyproline links. Dilute alkali does extract all of the wall hydroxyproline largely as non-dialysable material. Sequential extraction of cell walls with alkali at two temperatures (2° and 22–25°) removes most of the hemicellulose at the lower temperature but only dissolves the hydroxyproline at the higher temperature. Other studies show that the hydroxyproline containing polymer is co-precipitated with hemicellulose-B arabino-xylan. When cell walls from elongating and non-elongating hypocotyl sections are compared using this sequential extraction, the hemicellulose-B arabino-xylan containing hydroxyproline from the non-elongating wall has a much higher proportion of arabinoseand galactose than the same polymer from the elongating wall. Much more of the hydroxyproline from the elongating wall is dialysable. These results indicate more bonding of the hydroxyproline-containing glycoprotein within the wall of non-elongating tissue consistent with its suggested role in stopping cell elongation. It is suggested that the glycoprotein is linked to insoluble wall constituents such as cellulose through galactose or by direct protein to cellulose links.     

Expression of Cell Wall Proteins in Seeds and During Early Seedling Growth of Araucaria araucana is a Response to Wound Stress and is Developmentally Regulated

Araucaria araucana seeds and seedlings respond to wounding after48 h with a 3- to 4-fold increase of hydroxyproline-rich glycoproteins(HRGP) in the cell walls of the embryo and with a 15-fold increasein the cell walls of the megagametophyte. The megagametophytewalls accumulate six times more hydroxyproline per µgof cell wall protein than the embryo in this wound response.Tissue immunoprints of different parts of seeds and seedlingsobtained with polyclonal antibodies raised against HRGP fromcarrot roots or soybean seed coats indicate that the responseis due to an increase in a protein similar to the ones seenin carrot roots or soybean seed coats. Western blots of embryoand megagametophyte cell wall proteins subjected to SDS-PAGEshow three bands that cross-react with these antibodies. Ina native cationic gel system followed by Western blot analysis,only two bands react with these antibodies. Expression of suchproteins in Araucaria araucana seeds seems to be developmentallyregulated and tissue specific, since they are present mainlyin the megagametophyte and the root cap of the embryo. Key words: Araucaria araucana, seeds, seedlings, cell walls, hydroxyproline-rich glycoproteins     

Polygalacturonases Release Cell-Wall-bound Proteins

Purified polygalacturonases from two fungi released proteins from wall fractions prepared from three plant species. Peroxidase activity was associated with the proteins released from the cell walls, and several of the protein fractions released contained hydroxyproline. Cellulase, purified free of pectic enzyme activity, was ineffective in releasing cell wall proteins. Specific inhibition of endopolygalacturonase activity prevented release of the proteins.     

Chloroplast gene arrangement variation within a closely related group of green algae (Trebouxiophyceae, Chlorophyta)

The 22 published chloroplast genomes of green algae, representing sparse taxonomic sampling of diverse lineages that span over one billion years of evolution, each possess a unique gene arrangement. In contrast, many of the >190 published embryophyte (land plant) chloroplast genomes have relatively conserved architectures. To determine the phylogenetic depth at which chloroplast gene rearrangements occur in green algae, a 1.5-4 kb segment of the chloroplast genome was compared across nine species in three closely related genera of Trebouxiophyceae (Chlorophyta). In total, four distinct gene arrangements were obtained for the three genera Elliptochloris, Hemichloris, and Coccomyxa. In Elliptochloris, three distinct chloroplast gene arrangements were detected, one of which is shared with members of its sister genus Hemichloris. Both species of Coccomyxa examined share the fourth arrangement of this genome region, one characterized by very long spacers. Next, the order of genes found in this segment of the chloroplast genome was compared across green algae and land plants. As taxonomic ranks are not equivalent among different groups of organisms, the maximum molecular divergence among taxa sharing a common gene arrangement in this genome segment was compared. Well-supported clades possessing a single gene order had similar phylogenetic depth in green algae and embryophytes. When the dominant gene order of this chloroplast segment in embryophytes was assumed to be ancestral for land plants, the maximum molecular divergence was found to be over two times greater in embryophytes than in trebouxiophyte green algae. This study greatly expands information about chloroplast genome variation in green algae, is the first to demonstrate such variation among congeneric green algae, and further illustrates the fluidity of green algal chloroplast genome architecture in comparison to that of many embryophytes.     

Al-induced cell wall hydroxyproline-rich glycoprotein accumulation is involved in alleviating Al toxicity in rice

Cell wall components such as pectin and hemicelluloses have been proposed to be involved in aluminum resistance mechanisms in plants. However, whether hydroxyproline-rich glycoproteins (HRGPs), one of the most abundant proteins of the cell walls, are involved in Al resistance mechanisms remains elusive. In this study, two rice cultivars Xiushui 03 (Al resistant) and Xiushui 128 (Al sensitive) significantly differing in Al resistance were identified. In the absence of Al, no significant difference was observed in contents of glycoproteins and hydroxyproline in cell wall fractions of these two cultivars. At the early stage of Al toxicity, glycoproteins and hydroxyproline were significantly induced in these two cultivars, but levels of their accumulation in cell walls were much higher in cv. Xiushui 03 than in cv. Xiushui 128. At the late stage of Al toxicity, their accumulation in cell walls dramatically decreased in cv. Xiushui 128 and, however, still kept a high level in cv. Xiushui 03. The finding that Al-induced changes of glycoproteins and hydroxyproline were completely consistent indicates that Al-induced glycoproteins are HRGPs. Further observation utilizing transmission electron microscope showed that HRGPs were greatly accumulated in cell walls leading to thickening of cell walls in cv. Xiushui 03, however, HRGPs and cell walls greatly decreased in cv. Xiushui 128. These data suggest that Al-induced HRGP accumulation in cell walls is involved in alleviating Al toxicity in rice.     

Distribution of the extrinsic proteins as a potential marker for the evolution of photosynthetic oxygen-evolving photosystem II

Distribution of photosystem II (PSII) extrinsic proteins was examined using antibodies raised against various extrinsic proteins from different sources. The results showed that a glaucophyte (Cyanophora paradoxa) having the most primitive plastids contained the cyanobacterial-type extrinsic proteins (PsbO, PsbV, PsbU), and the primitive red algae (Cyanidium caldarium) contained the red algal-type extrinsic proteins (PsO, PsbQ', PsbV, PsbU), whereas a prasinophyte (Pyraminonas parkeae), which is one of the most primitive green algae, contained the green algal-type ones (PsbO, PsbP, PsbQ). These suggest that the extrinsic proteins had been diverged into cyanobacterial-, red algal- and green algal-types during early phases of evolution after a primary endosymbiosis. This study also showed that a haptophyte, diatoms and brown algae, which resulted from red algal secondary endosymbiosis, contained the red algal-type, whereas Euglena gracilis resulted from green algal secondary endosymbiosis contained the green algal-type extrinsic proteins, suggesting that the red algal- and green algal-type extrinsic proteins have been retained unchanged in the different lines of organisms following the secondary endosymbiosis. Based on these immunological analyses, together with the current genome data, the evolution of photosynthetic oxygen-evolving PSII was discussed from a view of distribution of the extrinsic proteins, and a new model for the evolution of the PSII extrinsic proteins was proposed.     

Nonaqueous titration of amino groups in polymeric matrix of plant cell walls

Nonaqueous titration was used for detection of free amino groups in the polymeric matrix of plant cell walls. The content of amino groups varied in the range 0.54–0.91 and total nitrogen in the range 1.0–4.2 mmol per gram dry mass of cell walls depending on the plant species. However, these data on the high content of free amino groups do not correlate with the present day concept that the nitrogen fraction in charged amino groups in plant cell wall proteins, which are assumed to be mainly amino groups of lysine and arginine residues, is about 10%. It is supposed that most detected free amino groups belong to the hydroxy-amino acids hydroxyproline and tyrosine that can be bound at the hydroxyl group with the carbohydrate part of glycoprotein or another structural cell wall polymer.     

Hydroxyproline and Peroxidases in Cell Walls of Pisum sativum: Regulation by Ethylene

Purified cell-wall preparations from the epicotyl of etiolatedPisum sativum contain covalently bound peroxidases and hydroxyproline-richproteins. Towards the end of cell elongation there is a largerise in these wall components and thereafter a continuing slowrise which is associated with increasing age of tissue. Ethyleneat concentrations of 0.1 ppm or more increases both peroxidaseactivity and hydroxyproline levels in the walls, the greatestresponse occurring in immature tissue including the apical hook.Growth of these tissues is highly sensitive to ethylene whichcauses an inhibition of elongation in extending cells and anenhanced lateral cell expansion. We suggest that the effectsof ethylene on wall-bound peroxidase and hydroxyproline areimplicated in the ethylene regulation of cell growth. The covalently bound wall peroxidase was found to be extremelystable and to contain unique isoenzymes which do not occur ineither the cytoplasm or in the peroxidase which is ionicallybound to walls. Ethylene increases peroxidase activity in boththe cytoplasmic and the ionically bound wall fractions, butthere is little or no increase in their hydroxyproline content.The possible relationships between covalently bound wall peroxidaseand hydroxyproline are discussed and we speculate that thisperoxidase may be involved in the hydroxylation of proline inthe walls.     

CELL WALL CARBOHYDRATE EPITOPES IN THE GREEN ALGA OEDOGONIUM BHARUCHAE F. MINOR (OEDOGONIALES,CHLOROPHYTA)1

Cell wall changes in vegetative and suffultory cells (SCs) and in oogonial structures from Oedogonium bharuchae N. D. Kamat f. minor Vélez were characterized using monoclonal antibodies against several carbohydrate epitopes. Vegetative cells and SCs develop only a primary cell wall (PCW), whereas mature oogonial cells secrete a second wall, the oogonium cell wall (OCW). Based on histochemical and immunolabeling results, (1→4)‐β‐glucans in the form of crystalline cellulose together with a variable degree of Me‐esterified homogalacturonans (HGs) and hydroxyproline‐rich glycoprotein (HRGP) epitopes were detected in the PCW. The OCW showed arabinosides of the extensin type and low levels of arabinogalactan‐protein (AGP) glycans but lacked cellulose, at least in its crystalline form. Surprisingly, strong colabeling in the cytoplasm of mature oogonia cells with three different antibodies (LM‐5, LM‐6, and CCRC‐M2) was found, suggesting the presence of rhamnogalacturonan I (RG‐I)–like structures. Our results are discussed relating the possible functions of these cell wall epitopes with polysaccharides and O‐glycoproteins during oogonium differentiation. This study represents the first attempt to characterize these two types of cell walls in O. bharuchae, comparing their similarities and differences with those from other green algae and land plants. This work represents a contribution to the understanding of how cell walls have evolved from simple few‐celled to complex multicelled organisms.     

The distribution of cell wall polymers during antheridium development and spermatogenesis in the Charophycean green alga, Chara corallina

Background and Aims

The production of multicellular gametangia in green plants represents an early evolutionary development that is found today in all land plants and advanced clades of the Charophycean green algae. The processing of cell walls is an integral part of this morphogenesis yet very little is known about cell wall dynamics in early-divergent green plants such as the Charophycean green algae. This study represents a comprehensive analysis of antheridium development and spermatogenesis in the green alga, Chara corallina.

Methods

Microarrays of cell wall components and immunocytochemical methods were employed in order to analyse cell wall macromolecules during antheridium development.

Key Results

Cellulose and pectic homogalacturonan epitopes were detected throughout all cell types of the developing antheridium including the unique cell wall protuberances of the shield cells and the cell walls of sperm cell initials. Arabinogalactan protein epitopes were distributed only in the epidermal shield cell layers and anti-xyloglucan antibody binding was only observed in the capitulum region that initially yields the sperm filaments. During the terminal stage of sperm development, no cell wall polymers recognized by the probes employed were found on the scale-covered sperm cells.

Conclusions

Antheridium development in C. corallina is a rapid event that includes the production of cell walls that contain polymers similar to those found in land plants. While pectic and cellulosic epitopes are ubiquitous in the antheridium, the distribution of arabinogalactan protein and xyloglucan epitopes is restricted to specific zones. Spermatogenesis also includes a major switch in the production of extracellular matrix macromolecules from cell walls to scales, the latter being a primitive extracellular matrix characteristic of green plants.     

Evidence for a Structural Role of Protein in Algal Cell Walls

Load-extension measurements were made on three filamentous algaebefore and after either digestion with proteolytic enzymes ortreatment with dithiothreitol. Large differences in tensileproperties of the walls were observed, particularly after pronasedigestion, in two algae, Cladophora and Chaetomorpha, whichcontain hydroxyproline in the wall. Pronase had little or noeffect on a third alga, Nitella, lacking hydroxyproline. A smallerdifference was found on treatment with dithiothreitol, a specificreducing agent for disulphide bonds. These results suggest thata hydroxyproline containing protein is a structural componentof these algal walls, and that hydroxyproline itself is involvedin the carbohydratepeptide linkage.