Location of cellulose and callose in pollen tubes and grains of Nicotiana tabacum

The distribution of cellulose and callose in the walls of pollen tubes and grains of Nicotiana tabacum L. was examined by electron microscopy using gold-labelled cellobiohydrolase for cellulose and a (1,3)-β-D-glucan-specific monoclonal antibody for callose. These probes provided the first direct evidence that cellulose co-locates with callose in the inner, electron-lucent layer of the pollen-tube wall, while both polymers are absent from the outer, fibrillar layer. Neither cellulose nor callose are present in the wall at the pollen-tube tip or in cytoplasmic vesicles. Cellulose is first detected approximately 5–15 μm behind the growing tube tip, just before a visible inner wall layer commences, whereas callose is first observed in the inner wall layer approximately 30 μm behind the tip. Callose was present throughout transverse plugs, whereas cellulose was most abundant towards the outer regions of these plugs. This same distribution of cellulose and callose was also observed in pollen-tube walls of N. alata Link et Otto, Brassica campestris L. and Lilium longiflorum Thunb. In pollen grains of N. tabacum, cellulose is present in the intine layer of the wall throughout germination, but no callose is present. Callose appears in grains by 4 h after germination, increasing in amount over at least the first 18 h, and is located at the interface between the intine and the plasma membrane. This differential distribution of cellulose and callose in both pollen tubes and grains has implications for the nature of the β-glucan biosynthetic machinery. Received: 20 February 1988 / Accepted: 25 March 1998     

A novel callose synthase from pollen tubes of Nicotiana

Pollen-tube cell walls are unusual in that they are composed almost entirely of callose, a (1,3)--linked glucan with a few 6-linked branches. Regulation of callose synthesis in pollen tubes is under developmental control, and this contrasts with the deposition of callose in the walls of somatic plant cells which generally occurs only in response to wounding or stress. The callose synthase (uridine-diphosphate glucose: 1,3--d-glucan 3--d-glucosyl transferase, EC 2.4.1.34) activities of membrane preparations from cultured pollen tubes and suspension-cultured cells of Nicotiana alata Link et Otto (ornamental tobacco) exhibited different kinetic and regulatory properties. Callose synthesis by membrane preparations from pollen tubes was not stimulated by Ca²⁺ or other divalent cations, and exhibited Michaelis-Menten kinetics only between 0.25 mM and 6 mM uridine-diphosphate glucose (K _m 1.5–2.5 mM); it was activated by -glucosides and compatible detergents. In contrast, callose synthesis by membrane preparations from suspension-cultured cells was dependent on Ca²⁺, and in the presence of 2 mM Ca²⁺ exhibited Michaelis-Menten kinetics above 0.1 mM uridine-diphosphate glucose (K _m 0.45 mM); it also required a -glucoside and low levels of compatible detergent for full activity, but was rapidly inactivated at higher levels of detergent. Callose synthase activity in pollen-tube membranes increased ten fold after treatment of the membranes with trypsin in the presence of detergent, with no changes in cofactor requirements. No increase in callose synthase activity, however, was observed when membranes from suspension-cultured cells were treated with trypsin. The insoluble polymeric product of the pollen-tube enzyme was characterised as a linear (1,3)--d-glucan with no 6-linked glucosyl branches, and the same product was synthesised irrespective of the assay conditions employed.Abbreviations Ara l-arabinose - CHAPS 3-[(3-cholamidopropyl)dimethylammonia]-1-propane sulphonic acid - DAP diphenylamine-aniline-phosphoric acid stain - Gal d-galactose - Glc d-glucose - Man d-mannose - Mes 2-(N-morpholino)ethane sulphonic acid - Rha d-rhamnose - Rib d-ribose - TFA trifluoroacetic acid - UDPGlc uridine-diphosphate glucose - Xyl d-xylose This research was supported by funds from a Special Research Centre of the Australian Research Council. H.S. was funded by a Melbourne University Postgraduate Scholarship and an Overseas Postgraduate Research Studentship; S.M.R. was supported by a Queen Elizabeth II Research Fellowship. We thank Bruce McGinness and Susan Mau for greenhouse assistance, and Deborah Delmer and Adrienne Clarke for advice and encouragement throughout this project.     

Transport of rosettes from the golgi apparatus to the plasma membrane in isolated mesophyll cells ofZinnia elegans during differentiation to tracheary elements in suspension culture

Summary Rosettes of six particles have been visualized by freeze-fracture in the protoplasmic fracture (PF) faces of: a) the plasma membrane, b) Golgi cisternae, and c) Golgi-derived vesicles in mesophyll cells ofZinnia elegans that had been induced to differentiate synchronously into tracheary elements in suspension culture. These rosettes have been observed previously in the PF face of the plasma membranes of a variety of cellulose-synthesizing cells and are thought to be important in cellulose synthesis. InZinnia tracheary elements, the rosettes are localized in the membrane over regions of secondary wall thickening and are absent between thickenings. The observation of rosettes in the Golgi cisternae and vesicles suggests that the Golgi apparatus is responsible for the selective transport and exocytosis of rosettes in higher plants, as has been previously indicated in the algaMicrasterias (Giddings et al. 1980). The data presented indicate that the Golgi apparatus has a critical role in the control of cell wall deposition because it is involved not only in the synthesis and export of matrix components but also in the export of an important component of the cellulose synthesizing apparatus. The rosettes are present in the plasma membrane and Golgi vesicles throughout the enlargement of the secondary thickening, suggesting that new rosettes must be continually inserted into the membrane to achieve complete cell wall thickening.Abbreviations EF Golgi vesicles, exoplasmic fracture; the plasma membrane, extracellular fracture - PF protoplasmic fracture     

Wall Thickenings - Moss Protonema Apical Cell Reaction to Lead

Two-days-old protonemata of Funaria hygrometrica Hedw. growing in in vitro conditions were treated with 4 M PbCl₂ for 48 h. After this time grey or brown colour thickenings of the cell wall appeared in protonemata cells. They were then localized in tip parts of apical cells. Electron microscopical (TEM) observations showed that the thickenings were structurally connected with the wall and sometimes they included lead deposits. Cytochemically it was found that they contained pectic polysaccharides, callose, lipid substances (probably suberin or sporopollenin) and only few cellulose. Other compounds of cell wall, e.g. lignin and cutin were not detected.     

The wall ofPinus sylvestris L. pollen tubes

Summary The wall ofPinus sylvestris pollen and pollen tubes was studied by electron microscopy after both rapid-freeze fixation and freeze-substitution (RF-FS) and chemical fixation. Fluorescent probes and antibodies (JIM7 and JIM5) were used to study the distribution of esterified pectin, acidic pectin and callose. The wall texture was studied on shadow-casted whole mounts of pollen tubes after extraction of the wall matrix. The results were compared to current data of angiosperms. TheP. sylvestris pollen wall consists of a sculptured and a nonsculptured exine. The intine consists of a striated outer layer, that stretches partly over the pollen tube wall at the germination side, and a striated inner layer, which is continuous with the pollen tube wall and is likely to be partly deposited after germination. Variable amounts of callose are present in the entire intine. No esterified pectin is detected in the intine and acidic pectin is present in the outer intine layer only. The wall of the antheridial cell contains callose, but no pectin is detectable. The wall between antheridial and tube cell contains numerous plasmodesmata and is bordered by coated pits, indicating intensive communication with the tube cell. Callose and esterified pectin are present in the tip and the younger parts of the pollen tubes, but both ultimately disappear from the tube. Sometimes traces in the form of bands remain present. No acidic pectin is detected in either tip or tube. The wall of the pollen tube tip has a homogenous appearance, but gradually attains a fibrillar character at aging, perhaps because of the disappearance of callose and pectin. No secondary wall formation or callose lining can be seen wilh the electron microscope. The densily of the cellulose microfibrils (CMF) is much lower in the tip than in the tube. Both show CMF in all but axial and nontransverse orientations. In conclusion,P. sylvestris and angiosperm pollen tubes share the presence of esterified pectin in the tip, the oblique orientations of the CMF, and the gradual differentiation of the pollen tube wall, indicating a possible relation to tip growth. The presence of acidic pectin and the deposition of a secondary-wall or callose layer in angiosperms but not inP. sylvestris indicales that these characteristics are not related to tip growth, but probably represent adaptations to the fast and intrastylar growth of angiosperms.Abbreviations CMF cellulose microfibrils - II inner intine - NE nonsculptured exine - OI outer intine - RF-FS rapid-freeze fixation freeze-substitution - SE sculptured exine - SER smooth endoplasmic reliculum - SV secretory vesicles     

Genetic and physical characterization of putP, the proline carrier gene of Escherichia coli K12

Summary Two new mutants of E. coli K12, strains PT9 and PT32 were isolated, that were defective in proline transport. They had no high affinity proline transport activity, but their cytoplasmic membranes retained proline binding activity with altered sensitivity to inhibition by p-chloromercuribenzoate(pCMB). The lesion was mapped at the putP gene, which is located at min 23 on the revised E. coli genetic map (Bachmann 1983) as a composite gene in the proline utilization gene cluster, putP, putC, and putA, arranged in this order. The putC gene was shown to regulate the synthesis of proline dehydrogenase (putA gene product).Hybrid plasmids carrying the put region (Motojima et al. 1979; Wood et al. 1979) were used to construct the physical map of the put region. The possible location of the putP gene in the DNA segment was determined by subcloning the putP gene, genetic complementation, and recombination analyses using several proline transport mutants.Abbreviations pCMB p-chloromercuribenzoate - DM Davis and Mingioli - Ap ampicillin - NTG N-methyl-N-nitro-N-nitrosoguanidine - EMS ethylmethane sulfonate - Str streptomycin - Tet tetracycline - Ac l-azetidine-2-carboxylic acid - DHP 3, 4-dehydro-d,l-proline - MTT 3-(4,5-dimethyl-2)2,5-diphenyl tetrazolium bromide - Tris tris(hydroxymethyl)aminomethane - EDTA ethylenediamine tetraacetic acid - Kan kanamycin - Spc spectinomycin     

Callose deposition and breakdown, followed by phytomelan synthesis in the seed coat ofGasteria verrucosa (Mill.) H. Duval

Summary In the seed coat ofGasteria verrucosa the deposition of phytomelan takes place during seed development in three stages. Phytomelan is a black cell wall material which is chemically very inert. First the radial walls and part of the transverse cell wall of the outer epidermis of the outer integument become thickened by exocytosis of dictyosome vesicles. Callose is deposited at the tangential plasma membrane against those walls. After the callose deposition about two thirds of the original cell volume is filled with callose. During the second stage the callose is broken down, probably into glucose monomers or small polymers. At the same time cellulose is deposited at the outer tangential plasma membrane, forming a wall between the dissolving callose and the plasma membrane. In the third phase small granules appear in the solution of dissolved callose. which grow out and finally fuse to form a block of phytomelan, consisting of spherical 15-nm units. Remarkable is the function of the callose: it determines the size of the phytomelan block, and it probably functions as carbohydrate source for the phytomelan synthesis and/or for the cellulose inner layer. In this study transmission electron microscopy and cryo scanning electron microscopy are used to study the three developmental stages of the formation of the phytomelan layer.     

Cellobiose phosphorylase (EC 2.4.1.20) of Cellulomonas: occurrence,induction, and its role in cellobiose metabolism

The occurrence of cellobiose cleavage by phosphorolysis and by hydrolysis was investigated in Cellulomonas spec., C. uda, C. flavigena, and C. cartalyticum. Cellobiose phosphorylase (EC 2.4.1.20) was shown to be produced by Cellulomonas spec. when cellobiose or cellulose was used as sole source of energy and carbon but not with glycerol or glucose. Using inhibitors of protein synthesis as well as double labelling techniques it was shown that cellobiose phosphorylase is synthesized de novo in Cellulomonas spec. Aryl--D-glucosidase which was shown to be present in crude extracts of this microorganism as well is not involved in cellobiose cleavage.Abbreviations oNPGluc ortho-nitrophenyl--D-glucopyranoside - oNPGlucase ortho-nitrophenyl--D-glucopyranoside hydrolase (aryl--D-glucosidase) - CMC carboxymethyl-cellulose - CMCase carboxymethyl-cellulase - PAGE polyacrylamde disc gel electrophoresis Parts of this work were presented on the Herbsttagung der Gesellschaft für Biologische Chemie (Schimz et al. 1979) and on the 14th FEBS Meeting (Schimz et al. 1981)     

Tip cell growth and the frequency and distribution of particle rosettes in the plasmalemma: Experimental studies inFunaria protonema cells

Summary ComparingFunaria protonema tip cells of different age and of experimentally modified growth rate (by changing the light-dark-regime, by application of colchicine and of D₂O and by plasmolysis) we found that the site and intensity of growth are related closely to the distribution and frequency of particle rosettes in the PF of the plasma membrane. The results confirm previous suggestions that the rosettes are involved in cellulose fibril formation and that they have a rather short life time (about 10–15 minutes,Reiss et al. 1984). The appearance of rosettes seems to depend on the exocytosis of Golgi vesicle containing wall matrix material. Morphometric calculations suggest that each Golgi vesicle may incorporate one rosette into the plasmalemma in caulonema tip cells.     

Orientation of microfibrils and microtubules in developing tension-wood fibres of Japanese ash (Fraxinus mandshurica var. japonica)

The orientation of cellulose microfibrils (MFs) and the arrangement of cortical microtubules (MTs) in the developing tension-wood fibres of Japanese ash (Fraxinus mandshurica Rupr. var. japonica Maxim.) trees were investigated by electron and immunofluorescence microscopy. The MFs were deposited at an angle of about 45° to the longitudinal axis of the fibre in an S-helical orientation at the initiation of secondary wall thickening. The MFs changed their orientation progressively, with clockwise rotation (viewed from the lumen side), from the S-helix until they were oriented approximately parallel to the fibre axis. This configuration can be considered as a semihelicoidal pattern. With arresting of rotation, a thick gelatinous (G-) layer was developed as a result of the repeated deposition of parallel MFs with a consistent texture. Two types of gelatinous fibre were identified on the basis of the orientation of MFs at the later stage of G-layer deposition. Microfibrils of type 1 were oriented parallel to the fibre axis; MFs of type 2 were laid down with counterclockwise rotation. The counterclockwise rotation of MFs was associated with a variation in the angle of MFs with respect to the fibre axis that ranged from 5° to 25° with a Z-helical orientation among the fibres. The MFs showed a high degree of parallelism at all stages of deposition during G-layer formation. No MFs with an S-helical orientation were observed in the G-layer. Based on these results, a model for the orientation and deposition of MFs in the secondary wall of tension-wood fibres with an S₁ + G type of wall organization is proposed. The MT arrays changed progressively, with clockwise rotation (viewed from the lumen side), from an angle of about 35–40° in a Z-helical orientation to an angle of approximately 0° (parallel) to the fibre axis during G-layer formation. The parallelism between MTs and MFs was evident. The density of MTs in the developing tension-wood fibres during formation of the G-layer was about 17–18 per m of wall. It appears that MTs with a high density play a significant role in regulating the orientation of nascent MFs in the secondary walls of wood fibres. It also appears that the high degree of parallelism among MFs is closely related to the parallelism of MTs that are present at a high density.Abbreviations FE-SEM field emission scanning electron microscopy - G gelatinous layer - MF cellulose microfibril - MT cortical microtubule - S₁ outermost layer of the secondary wall - TEM transmission electron microscopy We thank Dr. Y. Akibayashi, Mr. Y. Sano and Mr. T. Itoh of the Faculty of Agriculture, Hokkaido University, for their experimental or technical assistance.     

Cloning and expression of theClostridium thermocellum celS gene inEscherichia coli

Clostridium thermocellum ATCC 27405 produces an extremely complicated multi-component cellulase aggregate (cellulosome) highly active on crystalline cellulose. From the cellulosome, two subunits, CelS (or S _s ;M _r = 82 000) and CelL (or S _l , CipA;M _r = 250 000), have been identified as essential for crystalline cellulose degradation [Wu et al. (1988) Biochemistry 27:1703]. We have determined the DNA sequence of thecelS gene from four cloned DNA fragments encompassing this gene [Wang et al. (1993) J Bacteriol 175:1293]. To express the entirecelS gene inEscherichia coli, thecelS structural gene was amplified by the polymerase chain reaction (PCR) employing the PCR primers corresponding to sequences flanking the desired gene. This PCR product (2.1 x 10³ bases; 2.1 kb) was cloned into anE. coli expression vector pRSET B. Subsequent expression of the cloned gene resulted in a fusion protein (rCelS;M _r = 86 000) as inclusion bodies. The rCelS protein was recognized specifically by an anti-CelS antiserum in a Western blot analysis. The inclusion bodies were purified and solubilized in 5m urea. The refolded rCelS produced very little reducing sugar from carboxymethylcellulose. However, it showed a higher activity on the crystalline cellulose (Avicel) and an even higher activity on phosphoricacid-swollen Avicel. These results indicate that the CelS is an exoglucanase.     

Intercellular protuberances in the ground tissue ofCocos nucifera L.

Summary Prolific filamentous intercellular protuberances have been observed in the intercellular spaces of the ground parenchyma tissue in the stems ofCocos nucifera. They are visually similar to some intercellular material reported in several other plant tissues but their chemical composition is unknown. Tests for lignin, cellulose, callose, suberin and waxes have proved negative and those for pectin inconclusive. The amount of intercellular material is closely related to the thickness of the parenchyma cell wall and the protuberances appear to be produced continuously by an active cytoplasm.     

Composition of the cell wall formed by protoplasts isolated from cell suspension cultures of Vinca rosea

The biochemistry of cell-wall regeneration in protoplasts obtained from Vinca rosea L. (Catharanthus roseus (L.) G. Don) cells grown in suspension culture by isolating the regenerated wall and the extracellular polysaccharides of protoplasts cultured for various periods, and investigating their composition. Gas-liquid chromatography and tracer studies with D-[U-¹⁴C]glucose showed that the sugar composition of the extracellular polysaccharides was similar to that of the original cell culture, consisting mainly of polyuronide and 3,6-linked arabinogalactan. the regenerated cell wall was composed of non-cellulosic glucans having 1,3- and 1,4-linkages, while its content in pectic and hemicellulosic components was very low.     

Ultrastructure of cell wall and plugs of tobacco pollen tubes after chemical extraction of polysaccharides

Tobacco pollen tubes grown in vitro and from pollinated tobacco styles were treated by chemical solvents to remove one or more of the following polysaccharides from the tube walls: pectin (ethylenediamine tetraacetic acid); hemicellulose (alkali); callose (alkali; potassium hypochlorite); cellulose (cuprammonium); and all polysaccharides with exception of cellulose (H₂O₂/glacial acetic acid). Both the inner tube wall, which we had regarded as the secondary wall, and the plugs contained, in addition to callose, microfibrils of cellulose and non-cellulosic microfibrils that had pectin-like properties. When using the expressions callosic or callose layer and callose plugs in reference to pollen tubes, one should realize that they do not imply the exclusive presence of callose in the inner tube wall layer and its localized thickenings.Extended version of a contribution (poster) presented at the International Symposium Advances in Plant Cytoembryology in Lublin, Poland, in June 1980 Dedicated to Professor J. Straub (Köln-Vogelsang) on his 70th birthday in 1981     

Detection in situ and characterization of lignin in the<Emphasis Type="Italic"> G</Emphasis>-layer of tension wood fibres of<Emphasis Type="Italic"> Populus deltoides</Emphasis>

The occurrence of lignin in the additional gelatinous (G-) layer that differentiates in the secondary wall of hardwoods during tension wood formation has long been debated. In the present work, the ultrastructural distribution of lignin in the cell walls of normal and tension wood fibres from poplar (Populus deltoides Bartr. ex Marshall) was investigated by transmission electron microscopy using cryo-fixation–freeze-substitution in association with immunogold probes directed against typical structural motifs of lignin. The specificity of the immunological probes for condensed and non-condensed guaiacyl and syringyl interunit linkages of lignin, and their high sensitivity, allowed detection of lignin epitopes of definite chemical structures in the G-layer of tension wood fibres. Semi-quantitative distribution of the corresponding epitopes revealed the abundance of syringyl units in the G-layer. Predominating non-condensed lignin sub-structures appeared to be embedded in the crystalline cellulose matrix prevailing in the G-layer. The endwise mode of polymerization that is known to lead to these types of lignin structures appears consistent with such an organized cellulose environment. Immunochemical labelling provides the first visualization in planta of lignin structures within the G-layer of tension wood. The patterns of distribution of syringyl epitopes indicate that syringyl lignin is deposited more intensely in the later phase of fibre secondary wall assembly. The data also illustrate that syringyl lignin synthesis in tension wood fibres is under specific spatial and temporal regulation targeted differentially throughout cell wall layers.Abbreviations G-layer Gelatinous layer - G Guaiacyl monomeric unit - PATAg Periodic acid–thiocarbohydrazide–silver proteinate - S Syringyl monomeric unit     

Repetitive somatic embryogenesis in peanut cotyledon cultures by continual exposure to 2,4-d

Somatic embryos from immature cotyledons in peanut (Arachis hypogaea) were initiated on media supplemented with 2,4-dichlorophenoxyacetic acid (2,4-d). Over 90% primary embryogenesis and 41–46% repetitive embryogenesis were obtained 12 weeks after initiation by maintaining embryogenic cultures on medium containing 20 mg 1^-1 2,4-d. Maintenance of cultures on medium with 30 or 40 mg I^-1 2,4-d resulted in lower primary and secondary embryogenesis, and proliferation of nonembryogenic callus. Transfer of embryogenic cultures to a secondary medium with 10 or 20 mg I^-1 2,4-d significantly enhanced secondary embryogenesis compared to basal medium without the growth regulator. The use of Murashige & Skoog versus Finer's media had no significant effect on embryogenesis (85–95%), repetitive embryogenesis (11–37%) or mean embryo number. Secondary embryogenesis was also maintained for over one year by repeated subculture of isolated somatic embryos on medium with 20 mg I^-1 2,4-d.Abbreviations B5 Gamborg et al. medium (Gamborg et al. 1968) - 2,4-d 2,4-dichlorophenoxyacetic acid - FN Finer & Nagasawa medium (Finer & Nagasawa 1968) - MS Murashige & Skoog medium (Murashige & Skoog 1962)     

Distribution of cell wall components in<Emphasis Type="Italic"> Sphagnum</Emphasis> hyaline cells and in liverwort and hornwort elaters

Spiral secondary walls are found in hyaline cells of Sphagnum, in the elaters of most liverworts, and in elaters of the hornwort Megaceros. Recent studies on these cells suggest that cytoskeletal and ultrastructural processes involved in cell differentiation and secondary wall formation are similar in bryophytes and vascular plant tracheary elements. To examine differences in wall structure, primary and secondary wall constituents of the hyaline cells of Sphagnum novo-zelandicum and elaters of the liverwort Radula buccinifera and the hornwort Megaceros gracilis were analyzed by immunohistochemical and chemical methods. Anti-arabinogalactan–protein antibodies, JIM8 and JIM13, labeled the central fibrillar secondary wall layer of Megaceros elaters and the walls of Sphagnum leaf cells, but did not label the walls of Radula elaters. The CCRC-M7 antibody, which detects an arabinosylated (16)-linked -galactan epitope, exclusively labeled hyaline cells in Sphagnum leaves and the secondary walls of Radula elaters. Anti-pectin antibodies, LM5 and JIM5, labeled the primary wall in Megaceros elaters. LM5 also labeled the central layer of the secondary wall but only during formation. In Radula elaters, JIM5 and another anti-pectin antibody, JIM7, labeled the primary wall. The distribution of arabinogalactan–proteins and pectic polysaccharides restricted to specific wall types and stages of development provides evidence for the developmental and functional regulation of cell wall composition in bryophytes. Monosaccharide-linkage analysis of Sphagnum leaf cell walls suggests they contain polysaccharides similar to those of higher plants. The most abundant linkage was 4-Glc, typical of cellulose, but there was also evidence for xyloglucans, 4-linked mannans, 4-linked xylans and rhamnogalacturonan-type polysaccharides.Abbreviations AGP Arabinogalactan–protein - Araf Arabinofuranose - Fucp Fucopyranose - GalAp Galacturonopyranose - Galp Galactopyranose - GlcAp Glucuronopyranose - HGA Homogalacturonan - Manp Mannopyranose - RG Rhamnogalacturonan - Rhap Rhamnopyranose - XG Xyloglucan - Xylp Xylopyranose     

A polysaccharide fraction from the red seaweed Champia novae-zealandiae Rhodymeniales,Rhodophyta

The polysaccharide recovered after extraction of Champia novae-zealandiae is a galactan with alternating 3-linked d-galactopyranosyl units sulfated at the 2-position, and 4-linked galactopyranosyl units sulfated at both the 2- and 3-positions that are predominantly of the l- and partly of the d-configuration. Other minor substitution includes 6-O-methyl ether or 4,6-pyruvate acetal on the 3-linked residues. Techniques used in determining the structure include infrared and ¹³C-NMR spectroscopy, and GC-MS analysis of alditol acetate derivatives produced by reductive hydrolysis/acetylation of native, methylated, and/or desulfated samples. These results are of particular interest because 4-linked 2,3-desulfated galactosyl residues have not been encountered as major constituents of red algal polysaccharides.     

Temporal and spatial changes of cellulose synthesis inClosterium acerosum (Schrank) Ehrenberg during cell growth

The amount and distribution of wall microfibril synthesis were investigated in the cell-division cycle ofClosterium acerosum. Electron-microscopic examination and a methylation analysis of alkali-extracted wall fragments showed that alkali-extracted wall was mainly composed of microfibrils and that the microfibrils ofC. acerosum were 4-linked glucans, i.e., cellulose. Cellulose synthesis was measured as incorporation of¹⁴C, fed to cells as NaHCO₃, into extracted wall fragments. Extensive cellulose synthesis was coincident with septum formation, continued for more than 6 h and then ceased. It was found by microautoradiography that cellulose synthesis after cell division was essentially restricted to the expanding new semicells. Such a restricted distribution of cellulose synthesis was maintained for more than 6 h after septum formation, i.e., for more than 2 h after the cessation of expansion; afterwards, cellulose synthesis in some, but not all, cells became extended to the old semicells, and then ceased. Considerable cellulose synthesis also took place in the band-like expanding part of non-divided cells, indicating that cell division was not necessarily required for the induction of cellulose synthesis and the latter was coupled with cell expansion. Extension of cellulose synthesis to old semicells was brought about in divided cells by treatment with 3 mM colchicine, 28 M vinblastine, 50 M isopropyl-N-phenylcarbamate or 1 M isopropyl-N(3-chlorophenyl)carbamate, indicating that microtubules are involved in the limitation of cellulose synthesis to the new semicells.Abbreviations CIPC isopropyl-N(3-chlorophenyl)carbamate - DPO 2,5-diphenyloxazole - IPC isopropyl-N-phenylcarbamate     

Building flax fibres: more than one brick in the walls

The objective of the review is to provide fundamental knowledge on the chemical composition and structural characteristics of flax fibres. These are long and multinucleate cells without septum or partition (average length 2–5 cm) and have a secondary wall of very large thickness (5–15 μm). Fibres are gathered in bundles of one to three dozen cells that encircle the vascular cylinder. The bundle cohesion is insured by pectins, accumulating in the primary wall and cell junctions. In contrast, lignin, which is present in very low amount, does not seem to play a major role in bundle cohesion. At maturity, secondary wall is characterised by (i) a high level of cellulose with microfibrils locked into an almost axial direction and (ii) 5–15% non-cellulosic polysaccharides (NCPs). The chemical composition of NCPs depends on growth stage, indicating important cell wall remodelling, fibre position and variety. Despite the large disparity of the results reported in the literature, galactose appears to be the predominant sugar of NCPs, and β-1-4-galactan together with rhamnogalacturonan of type I (RG-I) and polygalacturonic acid (PGA) become, with fibre maturity, the most abundant tightly bound NCPs. Glycine-rich proteins (GRPs) and arabinogalactan-proteins (AGPs), also present in flax fibres, are both characterised by appreciable levels of glycine and acidic amino acid and are deficient in hydroxyproline, and may contribute to the cross-linking of pectins. (Galacto)glucomanans/glucans rather than xylans consist of cross-linking polymers in fibre secondary wall. A model is proposed where cellulose microfibrils, tethered by cross-linking (galacto)glucomanans/glucans, are embedded in a pectic matrix.