A STUDY OF CELL WALL AND FLAGELLA FORMATION DURING CELL DIVISION IN THE SCALY GREEN ALGA,SCHERFFELIA DUBIA (CHLOROPHYTA)1

The thecate green flagellate Scherffelia dubia (Perty) Pascher divides within the parental cell wall into two progeny cells. It sheds all four flagella before cell division, and the maturing progeny cells regenerate new walls and flagella. By synchronizing cell division, we observed mitosis, cytokinesis, cell maturation, flagella extension, and cell wall formation via differential interference contrast microscopy of live cells and serial thin‐section EM. Synthesis of thecal and flagellar scales is spatially and temporally strictly separated. Flagellar scales are collected in a pool during late interphase. Before prophase, Golgi stacks divide, flagella are shed, the parental theca separates from the plasma membrane, and flagellar scales are deposited on the plasma membrane near the flagellar bases. At prophase, Golgi bodies start to synthesize thecal scales, continuing into interphase after cytokinesis. During cytokinesis, vesicles containing thecal scales coalesce near the cell posterior, forming a cleavage furrow that is initially oriented slightly diagonal to the longitudinal cell axis but later becomes transverse. After the progeny nuclei have moved into opposite directions, resulting in a “head to tail” orientation of the progeny cells, theca biogenesis is completed and flagellar scale synthesis resumes. Progeny cells emerge through a hole near the posterior end of the parental theca with four flagella of about 8 μm long. The precise timing of flagellar and thecal scale synthesis appears to be an evolutionary adaptation in a scaly green flagellate for the thecal condition, necessary for the evolution of the phycoplast and thus multicellularity in the Chlorophyta.     

Reversion of protoplasts and spheroplasts in the yeast Nadsonia elongata

Summary The time rate of regeneration of the cell wall and reversion of protoplasts of the yeast Nadsonia elongata to cells of normal shape and size has been compared with the capability for regeneration of spheroplasts of this yeast. Nearly all protoplasts in a given culture were able to regenerate new walls and had usually reverted to cells of normal appearance by the 30th h of cultivation. Spheroplasts required only half this time to do this. These results can be interpreted as evidence that regeneration of a wall by protoplasts does not depend upon the presence of a cell wall primer, because the proportion of reverting protoplasts (which lack wall remnants) was the same as that of reverting spheroplasts (which possess them). The presence of wall remnants in spheroplasts appears to have merely an accelerating effect on the formation of a new wall and on subsequent reversion of the spheroplasts to complete cells of normal shape and size.     

Morphology of ovarian changes in the garden lizard, Calotes versicolor

Ovarian changes during the reproductive cycle of the oviparous garden lizard (Calotes versicolor) are described. It ovulates from last week of June to first week of September but most often in July and August when the monsoon occurs. The number of eggs ovulated vary from 10 to 32. After ovulation, the ovaries are reduced in size. From October to May, the ovaries contain small pre-vitellogenic follicles, which increase in size in June when most of yolk deposition occurs. Several nuclei are seen in the ooplasm of pre-vitellogenic follicles; they are finally absorbed before yolk deposition starts. Follicular atresia generally occurs in follicles with polymorphic granulosae, in post-ovulatory ovaries. Presumably interstitial gland cells are formed by the hypertrophy of the theca interna cells of atretic follicles. Pre-ovulatory follicles have highly vascularized thecae and invaginations of the follicular epithelium. After ovulation, the follicle cells hypertrophy to form the luteal cell mass filling the follicular cavity. Fibroblasts, which appear to arise from the theca interna, invade the luteal cell mass and form septa. Capillaries occur in the luteal cell mass.     

Sexual auxosporulation of the marine diatom Navicula directa var. directa

Sexual auxosporulation was observed in a mixed culture of two strains of Navicula directa var. directa. Two gametes did not re‐arrange in their gametangium and each adhered to the inner surfaces of the gametangial theca. Each of the two gametes of one gametangium fused with a gamete of the other gametangium iso‐gamously. As a result, two zygotes and hence two auxo‐spores were produced per paired gametangia. As the gametangial thecae kept close to the gametes during fusion, the zygote became associated with two different thecae. The presence of type IB2a of Geitler's (1973) system was confirmed by the present observations.     

2-KETO-SUGAR ACIDS IN GREEN FLAGELLATES: A CHEMICAL MARKER FOR PRASINOPHYCEAN SCALES1,2

The chemical composition of cell walls (thecae) of three taxa of scaly green flagellates (Prasinophyceae) was investigated. The theca of Tetraselmis striata, Tetraselmis tetrathele, and Scherffelia dubia consists mainly of carbohydrate (80% of dry weight), with proteins (5%), calcium (4%), and sulfate (6%) as minor components. The principal sugars (60% of dry weight) are the 2-keto-sugar acids 3-deoxy-manno-2-octulosonic acid (KDO), 3-deoxy-manno-5-O-methyl-2-octulosonic acid (5OMeKDO), and 3-deoxy-lyxo-2-heptulosaric acid (DHA). Arabinose, gulose, galactose, galacturonic acid, and in S. dubia, xylose and rhamnose were also found. Examination of scale preparations from Mantoniella squamata, Mesostigma viride, Pyramimonas amylifera, and Nephroselmis olivacea revealed that the 2-keto-sugar acids were always associated with the presence of typical prasinophycean scales on the cell surface. In contrast, 2-keto-sugar acids were not detected in the cell wall of Chlamydomonas reinhardtii nor in polymer preparations from the culture medium of Chlamydomonas reinhardtii, Dunaliella bioculata, Dunaliella primolecta, Asteromonas gracilis, Hafniomonas reticulate, Pedinomonas tuberculata, Monomastix sp., and Micromonas pusilla. We conclude that 2-keto-sugar acids are chemical markers for prasinophycean scales.     

Regenerated cell wall of carrot protoplasts isolated from suspension-cultured cells

Protoplasts of Daucus carota L. cultured in a synthetic liquid medium resumed cell division after about 4 days of cultivation. During this lag period, nucleic acid and protein showed only slight increases but the protoplasts commenced cell-wall regeneration soon after the removal of lytic enzymes. The originally spherical protoplasts became ellipsoidal before they underwent division. Radioactive glucose and myo-inositol were readily utilized by the protoplasts. Most of the radioactivity, however, appeared in extracellular polysaccharides and only a small portion was deposited in the regenerated wall. The sugar composition of new cell wall, as studies by chemical analysis and incorporation of labelled precursors, was shown to be considerably different from that of normal cell wall.     

Seaweed protoplasts: status,biotechnological perspectives and needs

Protoplasts are living plant cells without cell walls which offer a unique uniform single cell system that facilitates several aspects of modern biotechnology, including genetic transformation and metabolic engineering. Extraction of cell wall lytic enzymes from different phycophages and microbial sources has greatly improved protoplast isolation and their yield from a number of anatomically more complex species of brown and red seaweeds which earlier remained recalcitrant. Recently, recombinant cell wall lytic enzymes were also produced and evaluated with native ones for their potential abilities in producing viable protoplasts from Laminaria. Reliable procedures are now available to isolate and culture protoplasts from diverse groups of seaweeds. To date, there are 89 species belonging to 36 genera of green, red and brown seaweeds from which successful protoplast isolation and regeneration has been reported. Of the total species studied for protoplasts, most belonged to Rhodophyta with 41 species (13 genera) followed by Chlorophyta and Phaeophyta with 24 species each belonging to 5 and 18 genera, respectively. Regeneration of protoplast-to-plant system is available for a large number of species, with extensive literature relating to their culture methods and morphogenesis. In the context of plant genetic manipulation, somatic hybridization by protoplast fusion has been accomplished in a number of economically important species with various levels of success. Protoplasts have also been used for studying foreign gene expression in Porphyra and Ulva. Isolated protoplasts are also exploited in numerous miscellaneous studies involving membrane function, cell structure, bio-chemical synthesis of cell walls etc. This article briefly reviews the status of various developments in seaweed protoplasts research and their potentials in genetic improvement of seaweeds, along with needs that must to be fulfilled for effective realization of the objectives envisaged for protoplast research.     

Protoplast induction in Chlorella pyrenoidosa

Chlorella pyrenoidosa (UTEX 1230) cells in late log phase of growth were induced to form viable protoplasts by enzymatic digestion only when incubated in 2-deoxy-d-glucose (2DG) for 24 h. The combination of hemicellulase (4% w/v), Cellulysin (4% w/v), and glucuronidase (5% v/v) with 0.8 M mannitol and 8 mM CaCl₂ in modified Bristol's solution, was most effective for obtaining viable protoplasts as determined by light and electron microscopy, and vital staining with primuline (0.01% w/v). Resistance of cell walls to extensive extraction (acetolysis), and infrared analysis indicated that sporopollenin is a component of the cell wall. Transmission electron miscroscopy of acetolysed cell walls also allowed visualization of the laminate nature of the wall. This is the first report of successful induction of protoplasts from algae which contain sporopollenin in their cell walls.     

Protoplast isolation and culture from carob (Ceratonia siliqua) hypocotyls: ability of regenerated protoplasts to produce mannose-containing polysaccharides

The aim of this study was to isolate protoplasts from carob (Ceratonia siliqua L.) embryonic tissues with the ability to regenerate cell walls, divide and synthesize galactomannan, a valuable polysaccharide for industry. Protoplasts isolated from carob hypocotyl hooks regenerated cell walls within 24 h. The first divisions of the regenerated cells were observed after 2 days of culture. The highest percentage that successfully divided was achieved when the seedlings were grown under diffuse light, the hypocotyl hooks were plasmolysed for 1 h before incubation in the protoplast isolation solution and the protoplasts were cultured under diffuse light. After 9 days of culture, cell clusters, consisting of eight cells, had been produced, which underwent further mitotic divisions and which were expected to lead to callus formation. Polysaccharide and oligosaccharide synthesis during protoplast regeneration was studied by radiolabelling with exogenous d ‐[U‐¹⁴C]glucose, d ‐[U‐¹⁴C]mannose or d ‐[2‐³H]mannose, which gave rise to uniform, moderately specific and highly specific labelling, respectively. As revealed by the radioactivity distribution in cell wall monosaccharides, the regenerants deposited new wall polymers that differed markedly from those being synthesized by the hypocotyls from which the protoplasts had been isolated. The regenerants deposited large amounts of callose and smaller amounts of galactose‐, arabinose‐ and mannose‐containing polymers. The latter included glucuronomannan, as demonstrated by a new method involving partial acid hydrolysis followed by β‐glucuronidase (EC 3.2.1.31) digestion. The regenerating protoplasts also released soluble extracellular carbohydrates: polysaccharides which appeared to be mainly acidic arabinogalactans, and oligosaccharides which were mainly neutral and contained glucose, galactose and mannose. We conclude that regenerating carob protoplasts are a useful system for studying carbohydrate secretion, including mannose‐rich poly‐ and oligosaccharides.     

Electron microscopic observations of cell regeneration from cultured protoplasts ofAmmi visnaga

Summary Protoplasts ofAmmi visnaga initiated cell wall formation within 2 days in culture; after 13 days the new cells were enclosed by a cell wall similar to the walls on the original cultured cells. Budding occurred in protoplasts with little or no detectable cell wall. No evidence was obtained for direct participation of any organelle in cell wall formation. The cytoplasm of regenerating cells contained numerous organelles and appeared typical of actively growing plant cells; they were easily distinguished from degenerate cells and protoplasts. While coated vesicles were common, spiny vesicles occurred in only a few cells. Sustained cell division yielded multicellular aggregates. Multinucleate protoplasts, formed by spontaneous fusion, did not divide; some of them contained annulate lamellae with few pore complexes.Supported by the National Research Council of Canada, Grant A6304.     

SCANNING ELECTRON MICROSCOPY OF THECAE OF THE DINOFLAGELLATE GENUS ORNITHOCERCUS1

Members of the genus Ornithocercus are all tropical oceanic species in which the theca is extended in the form of elaborate wing-like projections, the lists, supported by ribs. This paper illustrates the topography of 6 of the species. The theca is penetrated by numerous simple pores opening flush with the outer surface. On the inner side of the thecae the pores have a raised rim. The hypotheca of all species examined except O. splendidus have shallow depressions, the areolae, over most of the surface. Secondary thickening of mature cell walls deepens the appearance of the areolae, and increases their extent over the hypotheca in O. quadratus. The number of pores is not directly correlated with the areolae but seems rather to be a function of cell size. A comparison of the surface features confirms views that O. splendidus occupies a relatively isolated phenetic position. It also confirms the close similarity of O. steinii with O. thumii. Unexpectedly it suggested a phenetic closeness between O. magnificus and O. quadratus on the basis of hypothecal structure and rib features of the left sulcal list. O. heteroporus could not be subjected to the same degree of study and its position cannot be commented on. Some theoretical hydrodynamic and morphogenetic problems in Ornithocercus are discussed.     

Structure and formation of the perforated theca defining the Pelagophyceae (Heterokonta), and three new genera that substantiate the diverse nature of the class

The pelagophytes, a morphologically diverse class of marine heterokont algae, have been historically united only by DNA sequences. Recently we described a novel perforated theca (PT) encasing cells from the Pelagophyceae and hypothesized it may be the first morphological feature to define the class. Here we consolidate that observation, describing a PT for the first time in an additional seven pelagophyte genera, including three genera new to science. We established clonal cultures of pelagophytes collected from intertidal pools located around Australia, and established phylogenetic trees based on nuclear 18S rDNA and plastid rbcL, psaA, psaB, psbA and psbC gene sequences that led to the discovery of three new species: Wyeophycus julieharrissiae and Chromopallida australis form a distinct lineage along with Ankylochrysis lutea within the Pelagomonadales, while Pituiglomerulus capricornicus is sister genus to Chrysocystis fragilis in the Chrysocystaceae (Sarcinochrysidales). Using fixation by high-pressure freezing for electron microscope observations, a distinctive PT was observed in the three new genera described in this paper, as well as four genera not previously investigated: Chrysoreinhardia, Sargassococcus, Sungminbooa and Andersenia. The mechanism of PT formation is novel, being fabricated from rafts in Golgi-derived vesicles before being inserted into an established PT. Extracellular wall and/or mucilage layers assemble exterior to the PT in most pelagophytes, the materials likewise secreted by Golgi-derived vesicles, though the mechanism of secretion is novel. Secretory vesicles never fuse with the plasma membrane as in classic secretion and deposition, but rather relocate extracellularly beneath the PT and disintegrate, the contents having to pass through the PT prior to wall and/or mucilage synthesis. This study substantiates the diverse nature of pelagophytes, and provides further evidence that the PT is a sound morphological feature to define the Pelagophyceae, with all 14 of the 20 known genera studied to date by TEM possessing a PT.     

Isolation of protoplasts from cereal leaves

Summary Mature leaves of Secale cereale cut into narrow strips and incubated for 18 h in a mixture of cellulase (Meicelase) and pectinase (Pectinol R10) produced quantities of protoplasts. Under the same conditions leaves of Triticum aestivum, Hordeum vulgare and Avena sativa also produce protoplasts but in lower yields. The wheat and rye protoplasts in culture appear to regenerate a cell wall but only a very small proportion undergo cell division.     

Comparison of cell wall regeneration on maize protoplasts isolated from leaf tissue and suspension cultured cells

Summary The cell wall regeneration on protoplasts derived from maize mesophyll cells was compared with wall regeneration on protoplasts derived from suspension cultured cells using light microscopy, transmission electron microscopy, and mass spectrometry. The time course of cell wall regeneration has shown that the mesophyll protoplasts regenerated walls much slower than the protoplasts derived from cultured cells. Moreover, cell wall materials on the mesophyll protoplasts were often unevenly distributed. Electron microscopy has further demonstrated that the mesophyll protoplasts have less organized and compact walls than the protoplasts from cultured cells. Chemical analysis revealed that the mesophyll protoplasts had a lower ratio ofβ-(1–3)-glucan toβ-(1–4)-glucan than protoplasts from cultured cells. The significance of these results for the viability and development of protoplasts in culture is discussed. National Research Council of Canada paper no. 32458.     

Conditions that affect binding of DNA by cultured plant cells and protoplasts: An autoradiographic analysis

Summary The binding of the¹⁴C-labelledSalmonella typhimurium DNA or³H-labelled soybean SB-1 DNA to cultured soybean cells (Glycine max L. Merr.) (SB-1) could be increased at least 100-fold by choosing the proper incubation conditions. The uptake of DNA by cells could completely be inhibited by the addition of an excess of unlabelled thymidine, indicating that the observed uptake of DNA by cells most probably is simply uptake of DNA degradation products. Autoradiograms, prepared from SB-1 protoplasts that were previously incubated with DNA, showed that the DNA was not associated with the protoplasts, but only with aggregates of cell wall material contaminating the protoplast preparation. When protoplasts and DNA were incubated in the presence of DEAE-dextran, the amount of DNAse resistant radioactivity increased 40 times. Again, the autoradiograms showed that most if not all DNAse-resistant material was associated with cell wall materials. Our observation that it is cell wall contaminants in protoplast preparations which account for most of the DNA binding demonstrates the need for caution in interpreting experiments on the binding and uptake of DNA by plant protoplasts.NRCC No. 16353.     

MITOSIS, CELL WALL AND FLAGELLA SYNTHESIS IN SYNCHRONIZED CULTURES OF THE PRASINOPHYTE, SCHERFFELIA DUBIA

Cell division occurs within the parental cell wall, yielding two progeny cells. Since Scherffelia dubia sheds all four flagella prior to cell division, the maturing progeny cells must regenerate new cell walls and flagella during and/or after cytokinesis. To better understand these processes, we have synchronized cell division in cultures of S. dubia and observed all stages of mitosis, cytokinesis, and progeny cell maturation, including flagella and cell wall formation, via DAPI staining of fixed cells, DIC microscopy of live cells embedded in agarose and standard TEM. Microscopical observations revealed the following sequence of events: 1) Golgi stacks divide during late interphase and immediately begin producing theca scales; 2) deflagellation and release of the parental cell wall from the plasma membrane occurs during early prophase; 3) synthesis of theca and flagella scales within the Golgi and/or scale reticulum continues throughout mitosis; 4) during cytokinesis, a coalescence of vesicles containing theca scales at the posterior end of the cell results in a cleavage furrow slightly diagonal to the cells' longitudinal axis (40 min); 5) post-mitotic nascent basal body formation and flagella elongation at the inherited basal bodies (and later at the mature nascent basal bodies) occurs concurrently with continued cell wall synthesis; 6) the cleavage furrow rotates into a transverse position (35 min); 7) reorientation of the nuclei results in a "head to tail" orientation of the maturing progeny cells; and 8) matured progeny cells emerge from the posterior end of the parental theca not before 8 hrs after the onset of mitosis.     

A study of cell wall regeneration of protoplasts inMarchantia polymorpha L.

Protoplasts ofMarchantia polymorpha L. were isolated from suspension cells. Regeneration of cell walls on the surface of the protoplasts began within a few hr of cultivation. New cell walls completely covered the surface of the protoplasts within 48 hr. Coumarin and 2,6-dichlorobenzonitrile treatment inhibited the formation of the new cell wall. In the initial stage of cell wall regeneration, endoplasmic reticula developed remarkably close to the plasma membrane in the protoplasts, but no development of Golgi bodies was observed at the same locus. This may suggest that the Golgi bodies do not play an active role in the cell wall formation, at least not in very early periods of cell wall regeneration. The development of endoplasmic reticula and an ultrastructural change of plasma membrane from smooth to rough may be important in the cell wall formation of protoplasts.     

Über die Abgrenzung derChlorosarcinales von denChlorococcales

It is proposed to use amongst other characters the type of cell division in order to delimit theChlorosarcinales from theChlorococcales. A definition of the two processes of division occuring in these orders is given. It differs from that of other authors. In theChlorosarcinales only those genera should be assembled in which vegetative daughter cells arise by bipartition followed by firm association of the wall between the daughter cells with that of the mother cell. In contrast, autospores, the vegetative daughter cells of a number ofChlorococcales, develop by multiple division, their cell walls are formed all around the protoplasts and are free from that of the mother cell. The chlorococcalean generaTrebouxia andDictyochloropsis incorporate species which multiply by zoo-, aplano- and autospores as well as others having no autospores. Autospores possibly have arisen more than once during evolution.

     

ISOLATION AND CHARACTERIZATION OF A CELL WALL‐DEFECTIVE MUTANT OF CHLAMYDOMONAS MONOICA (CHLOROPHYTA)1

Cell wall–defective strains of Chlamydomonas have played an important role in the development of transformation protocols for introducing exogenous DNA (foreign genes or cloned Chlamydomonas genes) into C. reinhardtii. To promote the development of similar protocols for transformation of the distantly related homothallic species, C. monoica, we used UV mutagenesis to obtain a mutant strain with a defective cell wall. The mutant, cw‐1, was first identified on the basis of irregular colony shape and was subsequently shown to have reduced plating efficiency and increased sensitivity to lysis by a non‐ionic detergent as compared with wild‐type cells. Tetrad analysis of crosses involving the cw‐1 mutant confirmed 2:2 segregation of the cw:cw⁺ phenotypes, indicating that the wall defect resulted from mutation of a single nuclear gene. The phenotype showed incomplete penetrance and variable expressivity. Although some cells had apparently normal cell walls as viewed by TEM, many cells of the cw‐1 strain had broken cell walls and others were protoplasts completely devoid of a cell wall. Several cw‐1 isolates obtained from crosses involving the original mutant strain showed a marked enhancement of the mutant phenotype and may prove especially useful for future work involving somatic cell fusions or development of transformation protocols.