The cell wall of the chlamydomonad flagellate,Gloeomonas kupfferi (Volvocales,Chlorophyta)

Summary The large unicellular flagellate,Gloeomonas kupfferi, has recently been used as an important tool in chlamydomonad cell biology research, especially in studies dealing with the structure and function of the endomembrane system. However, little is known about the main secretory product, the cell wall. This study presents structural, chemical and immunological information about this wall. This 850–900 nm thick matrix is highly elaborate and consists of three distinct layers: an inner stratum (325 nm thick) consisting of tightly interwoven fibers, a medial crystalline layer consisting of 22–23 nm subunits and an outer wall layer (500 nm thick) of outwardlyradiating fibrils. Rapid freeze-deep etch analysis reveals that the 35–40 nm fibers of the outer layer form a quasi-lattice of 160 nm subunits. The outer wall can be removed from whole pellets using the chelator, CDTA. The medial wall complex can be solubilized by perchlorate. SDS-gel electrophoresis reveals that the perchlorate soluble-material consists of five high molecular weight glycoproteins and five major low molecular weight glycoproteins. The electrophoretic profile is roughly similar to that ofChlamydomonas reinhardtii. Antibodies were successfully raised against the outer wall component and were shown to label the outer wall layer.     

Synthesis of the inner cell wall layer of the chlamydomonad flagellate,Gloeomonas kupfferi

Summary An antibody to the inner wall layer ofGloeomonas kupfferi was isolated and used in a developmental analysis of cell wall processing, secretion and extracellular assembly. The focus of the processing of this matrix layer is the endomembrane system, in particular the Golgi apparatus (GA) and contractile vacuole (CV). During interphase, inner wall materials are processed in the GA, packaged in trans face vesicles and transported to the CV, the final internal depository of wall precursors until release to the cell surface. During cell division, significant changes occur in the inner wall layer processing. Early on in cytokinesis, the GA does not label with our antibody, suggesting that other wall layers are being processed. In later stages of cytokinesis, the GA changes in morphology and begins to produce inner wall layer materials. These wall precursors are shuttled to the CV where they are released around the daughter cell protoplasts. The first wall layer that is formed around daughter cells is the crystalline median wall layer. Once assembled, the inner wall layer condenses upon the crystalline layer and grows in size.     

The cell wall of Chlamydomonas reinhardtii gametes: Composition,structure and autolysin-mediated shedding and dissolution

The cell walls of Chlamydomonas gametes are multilayered structures supported on frameworks of polypeptides extending from the plasma membrane. The wall-polypeptide catalogue reported by Monk et al. (1983, Planta 158, 517–533) and extended by U.W. Goodenough et al. (1986, J. Cell Biol. 103, 405–417) was re-evaluated by comparative analysis of mechanically isolated cell walls purified from several strains. The extracellular locus of wall polypeptides was verified by in vivo iodogen-catalysed iodination and by autolysin-mediated elimination of the bulk of these polypeptides from the cell surface. Three (w15, w16, w17) and possibly four (w14) polypeptides were located to the most exterior aspect of the wall because of their susceptibility to Enzymobeadcatalysed iodination and their retention by a cell-wall-less mutant. The composition of shed walls stabilised with ethylenediaminetetraacetic acid during natural mating and kinetic analysis of the dissolution of walls purified from a bald-2 mutant demonstrated the rapid and specific destruction of polypeptide w3. Differential solubilisation of wall polypeptides occurred after loss of w3. Wall dissolution, characterised by the generation of fishbone structures from the W2 layer, gave as many as four additional polypeptides. Charged detergents and sodium perchlorate extracted a comparable range of polypeptides at room temperature from mechanically isolated walls, i.e. components of the W4–W6 layers, hot sodium dodecyl sulphate solubilised framework polypeptides, while reducing agent was required to solubilise the W2 layer. A model of wall structure is presented.Abbreviations DTE dithioerythritol - EDTA ethylenediaminetetraacetic acid - M_r relative molecular mass - SDS-PAGE sodium dodecyl sulphate-polyacrylamide gel electrophoresis - Tris 2-amino-2-(hydroxymethyl)-1,3-propanediol     

Cytochemical and biochemical observations on the cell wall of the spore ofGlomus epigaeum

Summary The cell wall of the spore ofGlomus epigaeum Daniels and Trappe, which has fibrillar subunits regularly arranged in arcs, was studied ultrastructurally and biochemically.The periodic acid/thiocarbohydrazide/silver proteinate (PATAg) reaction for polysaccharide location (Thiéry 1967) and the silver methenamine reaction for protein location (Swift 1968) were performed on whole spores, progressively alkaline-extracted and autoclaved spores, and untreated and alkaline-extracted cell wall fractions. The cytochemical results and those obtained from frozen sections indicated that the fibrils forming the main structure of the outer and inner wall consist of chitin. Quantitative determinations showed that chitin is the most important component (47%) of the alkali-insoluble residue and represents 27.2% of the whole cell wall fraction. It occurs predominantly as the acetylated form. Cytochemical and biochemical observations showed that the matrix surrounding the fibrils is made of alkali-soluble, PATAg positive polysaccharides (4.98% of the whole cell wall fraction). Monomers were identified by gas liquid chromatography as being -lactone of glucuronic acid, and glucose, rhamnose and mannose. Alkali-soluble proteins are an important part of the matrix, being spread mostly throughout the inner wall and constituting a large portion (55.1 %) of the alkali-soluble fraction.From the results we derive a model in which the chemical components are interconnected to build up a macromolecular network, in agreement with electron-microscopic observations.     

Comparative ultrastructure of pyrenoids inTrebouxia (Microthamniales,Chlorophyta)

Pyrenoid ultrastructure has been investigated from cultures of all 26 species ofTrebouxia with the aim of establishing pyrenoids as a taxonomic character. Different arrangements and forms of thylakoid lamellae within the pyrenoid matrix allow eight pyrenoid types to be distinguished. Each type is characteristic of a group of species. Thegigantea- andimpressa-type are similar, differing only in the form of the tubules: short, branched tubules mark thegigantea-type; ± long and straight invaginations theimpressa-type. Thearboricola-type is characterized by meandering pyrenoid membranes developing from lamellae parallel with each other in young autospores. Pyrenoids of thegelatinosa-type are traversed by thin parallel-arranged tubules. Few thylakoids with a curved profile are typical of theirregularis-type. Thecorticola-type is different from all others in having a distinct starch sheath closely connected with the pyrenoid matrix and no pyrenoglobuli being associated with the pyrenoid membranes. No true pyrenoids have been found inT. magna andT. erici. Within the chloroplast, they have indistinct areas with pyrenoglobuli, but without differentiated thylakoids. Pyrenoid morphology is stable in culture on different media as well as in phycobionts within lichen thalli. Comparing the pyrenoid of a lichenizedTrebouxia with that from cultured species, the identification of the phycobiont within the lichen thallus is possible, without the need of culturing the algae. This has been shown in species ofParmelia andHypogymnia. New aspects for the taxonomy and systematics ofTrebouxia are discussed.Dedicated to Prof. DrLothar Geitler on the occasion of the 90th anniversary of his birthday.     

Zoospore ultrastructure in species ofTrebouxia andPseudotrebouxia (Chlorophyta)

Zoospore ultrastructure (incl. flagellar apparatus) has been investigated in three species ofTrebouxia (T. glomerata, T. erici, T. pyriformis) and one species ofPseudotrebouxia (P. impressa) using an absolute configuration analysis. Zoospores in all taxa studied are nearly identical in ultrastructure and exhibit a very distinctive disposition of cell organelles: cells are naked, biflagellate and considerably flattened along the plane of flagellar beat, the single contractile vacuole is located anteriorly in the ventral region of the cell, the nucleus is anteriorly to centrally located in the dorsal region of the cell. A single dictyosome is located close to the anterior, ventral edge of the nucleus. The chloroplast occupies a posterior position in the cell and usually has an anterior profile in the left region of the cell. There are two branched mitochondria per cell or a single mitochondrial reticulum with profiles anterior to the nucleus (in the dorsal region of the cell), and posterior to the nucleus. In zoospores ofTrebouxia spp. the posterior mitochondrial profile is associated with a microbody, inP. impressa zoospores the anterior mitochondrial profiles are associated with a microbody. The zoospores contain a distinctive system of three ER-cisternae: one system links to both basal bodies and extends to the nucleus, the other two systems subtend the plasmamembrane on the left and right broad cell surfaces and extend to the posterior region of the cell. The flagellar apparatus is structurally identical to that previously described for zoospores ofFriedmannia israelensis and exhibits basal body displacement by one basal body diameter into the 11/5 o'clock direction, a non-striated distal connecting fiber, a cruciate microtubular root system lacking system I fibers and presence of a single system II fiber which connects the basal bodies with the nucleus and runs parallel to one of the ER-strands. The left flagellar roots (X-roots) are subtended by a complex set of amorphous and striated material that connects each left root with both basal bodies.—This study demonstrates the close systematic relationship between the phycobiontsTrebouxia andPseudotrebouxia and the generaFriedmannia, Pleurastrum, andMicrothamnion and supports recent classification schemes which place all these taxa into a single order separate from otherChlorophyta. Dedicated to Prof. DrElisabeth Tschermak-Woess on the occasion of her 70th birthday.     

An autolysin dissolves the inner cell wall layer of the algaPediastrum (Hydrodictyaceae)

Summary An autolysin produced by young colonies ofPediastrum frees them from the vesicle in which they are formed within 12 hours of release of zoospores from the parent cell. The polysaccharide vesicle is derived from the inner wall layer of the parent cell. Refrigeration delays vesicle disintegration; boiling stops it completely. A purified, lyophilized extract of the vesicle fluid added to boiled vesicled colonies removes the vesicle in 2 hours with the release of reducing sugars and polysaccharides.Biogel P2 and P10 chromatography of the products following incubation of the enzyme preparation and wall showed no more than 1% oligosaccharides; the remaining carbohydrates had a molecular weight of several thousand daltons. Analyses of isolated vesicle wall material (70–85% of the dry weight) showed mannose accounting for approximately 50% of the dry weight, with none of the other neutral sugars present (fucose, xylose, galactose and glucose) representing more than 3%. Uronic acids account for 20–25% of the wall weight, and proteins less than 2%. Pediastrum colonies are thus freed from the vesicles in which they are formed by the action of an autolysin they produce. The autolysin acts on the vesicle wall material to generate reducing sugars and cause it to disintegrate into its constituent polysaccharides.     

Cell wall structure of the agarophytes Gracilaria tikvahiae and G. cornea (Rhodophyta) and penetration by the epiphyte Ulva lactuca (Chlorophyta)

Use of light, transmission, and scanning electronmicroscopes revealed that the epidermal cell wall ofthe red algal agarophytes Gracilaria tikvahiaeMcLachlan and G. cornea J. Agardh consists of adecklamelle and outer and inner wall layers. The twospecies differed, with G. cornea having asignificantly thicker outer wall and a more diffusedecklamelle. After induction, the zooids of Ulvalactuca would attach to glass slides and the twospecies of Gracilaria via an adhesion pad. Within a few days, 3–5 celled germlings penetrated thedecklamelle and outer wall layer of both basiphytes. By the time the epiphyte germlings reached the 15celled stage, they had penetrated the inner walllayer. The differences in epidermal cell wallconstruction between the two basiphytes may play arole in the ability of zooids of U. lactuca toattach in nature where epiphytization of G.cornea is infrequent.     

Chemical characterisation and gelling properties of cell wall polysaccharides from species of Ulva (Ulvales,Chlorophyta)

Two alkali-soluble polysaccharide fractions from the cell wall of Ulva rigida were determined to be ,-1,4-linked glucoxylans and a -1,4-linked glucuronan by chemical and NMR spectroscopic analysis. The ¹³C NMR spectrum of water-soluble xyloglucuronorhamnan sulfate from Ulva rigida referred to as ulvan is reported and the ¹³C and ¹H NMR chemical shifts of its major repeating unit, the aldobiuronic acid -D-GlcA-(1,4)-L-Rha, are given. The composition and gelling properties of ulvan from Ulva species from green tides are also reported. The thermoreversible gel required both calcium and borate ions and the shear storage modulus G was ion concentration dependent. The mechanism of gelation and the associations of the different Ulva cell wall soluble polysaccharides are discussed.     

Reconstruction of the flagellar apparatus and microtubular cytoskeleton inPyramimonas gelidicola (Prasinophyceae,Chlorophyta)

Summary The absolute configuration of the flagellar apparatus inPyramimonas gelidicola McFadden et al. has been determined and shows identity withP. obovata, indicating that they are closely related. Comparison with the flagellar apparatus of quadriflagellate zoospores from the more advancedChlorophyceae suggest thatPyramimonas may be a primitive ancestral form. The microtubular cytoskeleton has been examined in detail and is shown to be unusual in that it does not attach to the flagellar apparatus. Cytoskeletal microtubules are nucleated individually, and this is interpreted as an adaptation to the methods of mitosis and scale deployment. In view of the primitive nature of these processes, it is proposed that this type of cytoskeletal organization may represent a less advanced condition than that of the flagellar root MTOCs (microtubule organizing centers) observed in theChlorophyceae.     

Microfibrillar structure of growing cell wall in a coenocytic green alga,Boergesenia forbesii

A fine structure of cell wall lamellae in a coenocytic green algaBoergesenia forbesii was examined by electron microscopy. The wall has a polylamellate structure containing cellulose microfibrils 25 to 30 nm in diameter. The outer surface of the cell was covered by a thin structureless lamella, underneath which existed a lamella containing randomly-oriented microfibrils. The major part of the wall consisted of two types of lamellae, multifibrillar lamella and a transitional, matrix-rich one. In the former, microfibrils were densely arranged more or less parallel with each other. In the transitional lamella, existing between the multifibrillar ones, the microfibril orientation shifted about 30° within the layer. The fibril orientation also shifted 30° between adjacent transitional and multifibrillar layers, and consequently the microfibril orientation in the neighboring multifibrillar layers shifted 90°. It was concluded that the orientation rotated counterclockwise when observed from inside the cell. Each lamella in the thallus wall become thinner with cell expansion, but no reorientation of microfibrils in the outer old layers was observed. In the rhizoid, the outer lamellae sloughed off with the tip growth.     

Ein Beitrag zur Kenntnis vonApatococcus lobatus (Chlorophyta,Chaetophorales, Leptosiroideae)

Comparative investigations on the morphology, life-history, and reproduction of 3 cultivated strains of the atmophytic green algaApatococcus lobatus are presented. Some ultrastructural features are added to the results of earlier investigations, and comments on the systematics and ecology are given. Morphology and cytology of each strain is variable and shows considerable overlapping. The results support the view thatApatococcus consists of a single variable species (A. lobatus) only. For the epiphytic algal associationPleurococcetum vulgaris the more significant termApatococcetum lobati is proposed.

Herrn Prof. Dr.Lothar Geitler zu seinem 90. Geburtstag gewidmet.     

Cell shape in the algaPediastrum (Hydrodictyaceae; Chlorophyta)

Summary Species ofPediastrum, a genus in which the colonies assemble from aggregating zoospores, differ in the number and form of prongs on peripheral cells and the amount of space between cells of the colony; cell shape appears to be genetically based. Peripheral cells of theP. boryanum colony, for example, have two prongs per cell;P. simplex has one prong per cell. Prong extension is suppressed in the interior cells ofP. boryanum, but prong sites have been reported in scanning electron micrographs of the cell walls. A mutant unicellular strain in which cells of the colony separate after attaining typical form reveals several prong sites (6 or more) in each cell. Multiple suppressed prong sites are evident inP. simplex cells as well. Polyeders, 4- and 5-pronged unicells, occur in the life cycle ofP. simplex. Based on these observations and a recent report byMarchant (1979) of a microtubule organizing center associated with the prongs, it is suggested that several microtubule organizing centers are to be found in zoospores ofPediastrum species and may be related to species differences in cell shape.Research supported in part by Argonne Center for Educational Affairs, U.S. Department of Energy, under contract No. W-31-109-ENG-38.     

Trichome structure of fourAphanizomenon taxa (Cyanophyceae) from Czechoslovakia,with notes on the taxonomy and delimitation of the genus

The dimension and variation range of terminal and intercalary cells, heterocysts, and akinetes of fourAphanizomenon taxa occurring in Czechoslovakia were studied. Statistical and graphical procedures were used for evaluation. With regard toA. flos-aquae, the results support the distinction of two varieties (var.flos-aquae and var.klebahnii). In the samples determined asA. gracile two clearly distinguishable morphological types could be found; one of them is recognized as a new species:A. flexuosum. Its diacritical features are established and problems of the intrageneric taxonomy ofAphanizomenon and its demarcation from the genusAnabaena are discussed.Dedicated to Prof. DrLothar Geitler on the occasion of his 90th birthday.     

Epicuticular wax morphology and the taxonomy ofRosa (sectionCaninae, subsectionRubiginosae)

Classification within the genusRosa is problematic due to ± continuous variation of morphological characters. The dogroses, (Rosa, sectionCaninae) are classified only by their unique meiotic system not by directly visible characters. The intrasectional structure remains insufficient, as the characters (glands, hairs and prickles) are known to exhibit great morphological divergence affected by both genetic plasticity and environmental influences. Taxonomy of dogroses follows a highly artificial system which allows us to identify morphospecies, which are not necessarily evolutionary species. However, SEM-studies in theCaninae revealed that all taxa of the subsectionRubiginosae are characterised by a granule type of epicuticular waxes, whereas members from the other subsections (with three exceptions) form triangular rodlets. Comparison with specimens grown under the same conditions confirmed these findings on natural populations and additionally revealed that following artificial hybridism, offspring develop the maternal type of wax structure due to the matroclinal inheritance in this section.     

Ultrastructure of the tapetal cell wall in the stamenless-2 mutant of tomato (Lycopersicon esculentum): correlation between structure and male-sterility

Summary In the stamenless-2 (sl-2) mutant of tomato (Lycopersicon esculentum Mill.), the breakdown in microsporogenesis corresponded with various abnormalities in the ultrastructure of the tapetal cell wall. In some mutant anthers, the inner tangential wall was excessively loosened allowing the passage of tapetal cell wall material and cytoplasmic contents into the anther locule. This presumably altered the osmoticum of the locule and resulted in plasmolysis of the microspores. Membranous fragments commonly observed in the normal tapetal cell wall, and presumed to have a role in transfer of materials from the tapetum to microspores, were absent from thesl-2 mutant. This was associated with reduced transfer of materials, such as lipids, to the developing pollen grains. In addition, a lining of sporopollenin-like deposits that coated the inner tangential wall of the normal tapetum, was discontinuous in the mutant. In mutant anthers where the tapetal cell wall did not loosen, the transfer of all materials was restricted and this resulted in the collapse of sporogenous material.     

A chitin-like glycan in the cell wall of a Chlorella sp. (Chlorococcales,Chlorophyceae)

The stable amino-sugar fraction of the cell wall of the symbiotic Chlorella strain Pbi (Chlorophyceae) was isolated and investigated by sugar analysis, infra-red spectroscopy, lectin binding, enzymatic degradation, X-ray diffraction and electron microscopy. The results indicate the existence of a glycosaminoglycan which can be regarded as a chitin-like glycan. This carbohydrate structure is unusual for algae and reported here for the first time in unicellular chlorophycean algae.Abbreviations FITC fluorescein isothiocyanate - IR infra-red - NMR nuclear magnetic resonance - TFA trifluoroacetic acid - WGA wheat germ agglutinin We thank Peter Zugenmaier, Institut für Physikalische Chemie der Technischen Universität Clausthal-Zellerfeld, Germany, for valuable advice on X-ray diffraction techniques and for taking the Debye-Scherrer images. Wilfried Diekmann and David G. Robinson, Pflanzenphysiologisches Institut der Universität Göttingen, Germany, kindly carried out the freeze-etching. This work was supported by a fellowship from the Friedrich-Ebert-Stiftung to the first author and a grant from the Deutsche Forschungsgemeinschaft to the second author.     

Heliobacterium chlorum: cell organization and structure

The basic cellular organization of Heliobacterium chlorum is described using the freeze-etching technique. Internal cell membranes have not been observed in most cells, leading to the conclusion that the photosynthetic apparatus of these organisms must be localized in the cell membrane of the bacterium. The two fracture faces of the cell membrane are markedly different. The cytoplasmic (PF) face is covered with densely packed particles averaging 8 nm in diameter, while the exoplasmic (EF) face contains far fewer particles, averaging approximately 10 nm in diameter. Although a few differentiated regions were noted within these fracture faces, the overall appearance of the cell membrane was remarkably uniform. The Heliobacterium chlorum cell wall is a strikingly regular structure, composed of repeating subunits arranged in a rectangular pattern at a spacing of 11 nm in either direction. We have isolated cell wall fragments by brief sonication in distilled water, and visualized the cell wall structure by negative staining as well as deep-etching.Abbreviations PF protoplasmic fracture face - EF exoplasmic fracture face     

Composition of the cell wall of Chlorella fusca

Isolated cell walls of mature Chlorella fusca consisted of about 80% carbohydrate, 7% protein, and 13% unidentified material. Mannose and glucose were present in a ratio of about 2.7:1 and accounted for most of the carbohydrate. Minor components were glucuronic acid, rhamnose, and traces of other sugars; galactose was absent. After treatment with 2 M trifluoroacetic acid or with 80% acetic acid/HNO₃ (10/1, v/v), a residue with a mannose/glucose ratio of 0.3:1 was obtained, probably representing a structural polysaccharide. An X-ray diffraction diagram of the walls showed one diffuse reflection at 0.44 nm and no reflections characteristic of cellulose. Walls from young cells contained about 51% carbohydrate, 12% protein, and 37% unidentified material. Mannose and glucose were also the main sugars; their absolute amounts per wall increased 6–7 fold during cell growth. Walls isolated with omission of a dodecylsulphate/mercaptoethanol/urea extraction step had a higher protein content and, with young walls, a significantly higher glucose and fucose content. These data and other published cell wall analyses show a wide variability in cell wall composition of the members of the genus Chlorella.Abbreviations GLC gas liquid chromatography - TFA trifluoroacetic acid