The extracellular polysaccharides of the red microalgae: Chemistry and rheology

Cells of red microalgae encapsulated within sulphated polysaccharides, are thought to have a wide range of potential industrial applications. Our group is thus carrying out a comprehensive research program aimed at bringing these biopolymers into industrial use. The program includes physiological studies on polysaccharide production, outdoor cultivation of the microalgae, and characterisation of the polysaccharides. Chemical composition and structure and physicochemical properties were investigated for the polysaccharides of three red microalgae, Porphyridium sp., P. aerugineum and Rhodella reticulata. Differences were found among the three species in the composition of the monosugars, half ester sulphate groups and glucuronic acid content, but a disaccharide isolated was identical in all the species examined. This disaccharide is thought to be the basic building block of these polysaccharides. In addition, monosugar sulphates were isolated and characterised. Fractionation by charge showed the polysaccharides to be heterogenous and composed of at least two fractions that differed in their composition. Although the polysaccharides differed in composition, their rheological characteristics were found to be similar. Aqueous solutions of the biopolymers were stable over a wide range of pH values and temperatures and were compatible with monovalent cations. Mixtures of the algal polysaccharides with locust bean gum exhibited synergism and syneresis. When the gel strength was compared with that of agar gel at the same concentration the polysaccharide gels were found to be weaker.     

Ultrastructure of vegetative organization and cell division in the freshwater red algaCompsopogon

Summary Uniseriate filaments of the freshwater red algaCompsopogon coeruleus were examined by transmission electron microscopy for details of vegetative organization and cell division with the goal of providing useful taxonomic characters. Each cell's single, complex chloroplast contains a peripheral encircling thylakoid, and unlike the vast majority of red algae, the cis-regions of dictyosomes are not consistently juxtaposed with mitochondria. These subcellular features, which are present in all examined genera in theCompsopogonales, Erythropeltidales, andRhodochaetales, along with certain unique reproductive characteristics, unify these three orders. During mitosis in uncorticated axial cells, a small, ring-shaped nucleus associated organelle (NAO) is located at each division pole, an intranuclear spindle comes to a moderately acute focus at the flattened, fenestrated metaphase-anaphase division poles and perinuclear ER partially encloses dividing nuclei, including a well-developed interzonal midpiece. The cleavage furrow penetrates the large, central vacuolar region to separate daughter nuclei. These cell division features most closely resemble the pattern described for the orderCeramiales. Our observations of vegetative and dividing cells ofC. coeruleus supplement the growing volume of evidence in favour of uniting all red algae into a single class without subclass designations.Abbreviations ER endoplasmic reticulum - IZM interzonal midpiece - MT microtubule - MTOC microtubule organizing center - NAO nucleus associated organelle - NE nuclear envelope - PER perinuclear endoplasmic reticulum     

The endomembrane system of differentiating carposporangia in the red algaChondria tenuissima: Occurrence and participation in secretion of polysaccharidic and proteinaceous substances

Summary The endomembrane system during carposporogenesis inChondria tenuissima was studied using electron microscopy and histochemistry. Profiles of the nucleus are convoluted, resulting in a highly increased surface area. Stacked cisternae are found within the peripheral part of the nucleus. Vesicles, tubules and membrane bound fibrillar bodies occur within the nucleoplasm. The endoplasmic reticulum surrounds the nuclear envelope.The endoplasmic reticulum and the Golgi apparatus, together with small transition vesicles, represent a functional unit. They form two different secretory substances during carposporogenesis. In young stages, carbohydrates are produced by normal dictyosomes within large, normal exocytotic Golgi vesicles. They do not react positively with PAS or Thiéry method and are believed to represent cell wall material. In later stages, the central area of the Golgi cisternae becomes filled with electron dense material. The individual cisternae are transformed into cored vesicles at the trans-face of the dictyosomes. The dense core of the vesicles is proteinaceous and stains with coomassie brilliant blue R. The peripheral fibrillar material is polysaccharidic and reacts positively using the Thiéry method. The contents of the cored vesicles are believed to participate in carpospore attachment. The ER gives rise to cytolysosomes in which starch grains are sequestrated and digested. Mucilaginous sacs seem to be similarly formed.     

Jasmonates promote abscission in bean petiole expiants: Its relationship to the metabolism of cell wall polysaccharides and cellulase activity

Jasmonic acid (JA) and its methyl ester (JA-Me) promoted the abscission of bean petiole expiants in the dark and light, and the activity of these compounds was almost same. JA and JA-Me did not enhance ethylene production in bean petiole expiants in the light, indicating that the abscission-promoting effects of these compounds are not the result of ethylene. Cells in the petiole adjacent to the abscission zone expanded during abscission but not in the pulvinus, and JA-Me promoted cell expansion in the petiole and the pulvinus. JA-Me had no effect on the total amounts of pectic and hemicellulosic polysaccharides in 2-mm segments of the abscission region, which included 1 mm of pulvinus and 1 mm of petiole from the abscission zone. On the other hand, the total amounts of cellulosic polysaccharides in this region were reduced significantly by the addition of JA-Me in the light. JA-Me had no effect on the neutral sugar composition of hemicellulosic polysaccharides during abscission. The decrease in the endogenous levels of UDP-sugars in the petiole adjacent to the abscission zone was accelerated during abscission by the addition of JA-Me in the light. Cellulase activities of pulvinus and petiole in 10-day-old seedlings were enhanced by the addition of JA. These results suggest that the promoting effect of JA or JA-Me on the abscission of bean petiole explants is due to the change of sugar metabolism in the abscission zone, in which the increase in cellulase activity involves the degradation of cell wall polysaccharides. Jasmonic acid (JA) and its methyl ester (JA-Me) are considered to be putative plant hormones for a number of reasons, including their wide occurrence in the plant kingdom, biologic, activities in multiple aspects at low concentrations, and their interaction with other plant hormones (for reviews see Parthier 1991, Hamberg and Gardner 1992, Sembdner and Parthier 1993, Ueda et al. 1994a). We have already reported that JA and JA-Me and C₁₈-unsaturated fatty acids, which are considered to be the substrates of the biosynthesis of jasmonates, are powerful senescence-promoting substances (Ueda et al. 1982b, 1991a). Senescence symptoms induced by these compounds are identical to those of natural senescence. Recently we have also found that JA inhibited indole-3-acetic acid (IAA)-induced elongation of oat (Avena sativa L. cv. Victory) coleoptile segments by inhibiting the synthesis of cell wall polysaccharides (Ueda et al. 1994b, 1995). These facts led us to study the mode of actions of JA and JA-Me on promoting abscission, which is considered the last dramatic phenomenon of senescence. In this paper we report that JA and JA-Me promote abscission in bean (Phaseolus vulgaris L. cv. Masterpiece) petiole expiants and that the changes in the metabolism of cell wall polysaccharides in the petiole and the pulvinus adjacent to the abscission zone are involved in the promotive effects of these compounds.Abbreviations ABA abscisic acid - ACC 1-aminocyclopropane-1-carboxylic acid - DCB 2,6-dichlorobenzonitrile - HPLC high performance liquid chromatography - IAA indole-3-acetic acid - JA jasmonic acid - JA-Me methyl jasmonate - MES 2-(N-morpholino)ethane-sulfonic acid, monohydrate - TCA trichloroacetic acid - Tris 2-amino-2-hydroxymethy-1,3-propanediole     

Update on the possible mode of action of the jasmonates: Focus on the metabolism of cell wall polysaccharides in relation to growth and development

Jasmonic acid (JA) and its related compounds (jasmonates) applied to plant tissues exert either inhibitory or promotive effects in growth and developmental processes, which in some ways are similar to abscisic acid. However, little is known about the mode of action of the jamonates at the tissue or organ levels. Here, we review partial evidence for the physiological action of the jasmonates on cell elongation and abscission.
Jasmonates inhibit the IAA-induced cell elongation of oat coleoptile segments not by affecting energy production, osmoregulation and cell wall loosening, but by inhibiting the synthesis of cell wall polysaccharides. The inhibition is partially reversed by simultaneous application of sucrose. Inhibition of IAA-induced elongation by JA is only observed in monocotyledons, not in dicotyledons. These effects suggest that jasmonates exert their inhibitory effect on cell elongation by affecting the metabolism of the cell wall polysaccharides in monocotyledons.
Jasmonates promote the abscission of bean petiole explants without enhancing ethylene production. Cells in the petiole adjacent to the abscission zone expand during abscission. In the abscission zone, jasmonates decrease the amount of cellulosic but not that of noncellulosic polysaccharides. Jasmonates increase the activities of cellulase and decrease the levels of UDP-sugars, which are important intermediates for the synthesis of cell wall polysaccharides in the abscission zone, probably resulting in the decreased level of cellulose and the mechanical weakness of cell walls.
Thus, it is suggested that jasmonates exert their multiple physiological effects by affecting the metabolic processes of cell wall polysaccharides.     

In-situ Raman microprobe studies of plant cell walls: Macromolecular organization and compositional variability in the secondary wall of Picea mariana (Mill.) B.S.P.

Native-state organization and distribution of cell-wall components in the secondary wall of woody tissue from P. mariana (Black Spruce) have been investigated using polarized Raman microspectroscopy. Evidence for orientation is detected through Raman intensity variations resulting from rotations of the exciting electric vector with respect to cell-wall geometry. Spectral features associated with cellulose and lignin were studied. The changes in cellulose bands indicate that the pyranose rings of the anhydroglucose repeat units are in planes perpendicular to the cross section, while methine C–H bonds are in planes parallel to the cross section. Changes in bands associated with lignin indicate that the aromatic rings of the phenyl-propane units are most often in the plane of the cell-wall surface. However, regions where lignin orientation departs from this pattern also occur. These results represent direct evidence of molecular organization with respect to cellular morphological features in woody tissue, and indicate that cell-wall components are more highly organized than had been recognized. Studies carried out in order to establish the usefulness and sensitivity of the Raman technique to differences of composition within the cell walls provide evidence of variations in the distribution of cellulose and lignin. Such compositional differences were more prominent between the walls of different cells than within a particular cell wall.     

Cell walls of algae in the volvocales: Their sensitivity to a cell wall lytic enzyme and labeling with an anti-cell wall glycopeptide ofChlamydomonas reinhardtii

A cell wall lytic enzyme (gamete wall-autolysin) and a polyclonal antiserum raised against one of the major cell wall glycopeptides ofChlamydomonas reinhardtii were used to study their cross-reactivities with the cell walls of variety of members of the Volvocales. Lytic enzyme was able to digest completely the cell walls of five species ofChlamydomonas (C. reinhardtii group), six species ofGonium and two species ofAstrephomene. The colonial structures ofGonium andAstrephomene were broken into individual cells by exposure to the enzyme and protoplasts were then formed. These organisms also showed a strong cross-reactivity with anti-cell wall glycopeptide by an indirect-immunofluorescence test. The cell walls ofChlamydomonas angulosa, Dysmorphococcus globosus, Pandorina morum, Eudorina elegans, Volvulina steinii, Pleodorina california andVolvox carteri all showed a strong cross-reactivity to the antibody, although they were insensitive to the lytic enzyme. Many other species ofChlamydomonas, Carteria crucifera, Chlorogonium elongatum, Polytoma uvella, Haematococcus lacustris, Lobomonas piriformis, Phacotus lenticularis, Pteromonas angulosa, Stephanosphera pluvialis, andPyrobotrys casinoensis had cell walls which were resistant to the enzyme and showed no or weak cross-reactivity with the antibody. Based on the results, a possible evolutionary sequence from a unicellular relative ofC. reinhardtii to the multicellular algae is discussed.