The wound response of the siphonous green algal genusCaulerpa III: Composition and origin of the wound plugs

Summary A complex, higly sulphated glucoxylomannogalactan has been extracted in a yield of about 1% dry weight fromC. simpliciuscula. This polysaccharide is similar in composition to sulphated polysaccharides previously isolated from otherCaulerpa species (Mackie andPercival, 1961). The most likely location of this compound in the unwounded cell is in the vacuole. This polysaccharide appears as the major component in wound plugs, forming a viscoelastic barrier between the protoplasm and the external environment. The properties of the sulphated polysaccharide were studied in an effort to understand the physiology and mechanism of wound plug formation.     

Discharge papilla development in the phycomycete Allomyces

The process of discharge papilla (DP) formation in Allomyces macrogynus was studied by light and electron microscopy. The plug of the DP was first deposited between the plasmalemma and the wall of the zoosporangium (ZS). The wall above the plug subsequently was eroded away. Deposition of a new inner wall layer in the sporangium held the plug in place and thickening of the layer formed a collar around the plug. Further deposition of material after this stage resulted in the characteristic pulley-shape. The plug material appeared homogeneous in electron micrographs but there was evidence of an outer layer. Digestion of the plug at the time of spore release was from within.Abbreviations DP discharge papilla - ZS zoosporangium     

The relationship of echinate inclusions and coated vesicles on wound healing inNitella flexilis (Characeae)

Summary Wound healing in internodal cells of the freshwater algaNitella flexilis (Characeae) was studied in the light and electron microscope. Immediately after punctation of the cell wall a wound plug is formed which stops outflow of cytoplasm. The plug consists of echinate inclusions which are normally located in the central vacuole. A wound wall consisting of pectin and cellulose microfibrils is formed beneath the plug within one to several hours. During that time the wound shows intensive fluorescence when treated with chlorotetracycline indicating transmembrane Ca²⁺ fluxes. Numerous coated pits and vesicles are found at the plasmalemma. The glycosomes undergo pronounced structural changes. Neither plug nor wound wall formation depend on actin filaments or microtubules as shown by inhibitor experiments with cytochalasin and amiprophos-methyl. The function of the coated vesicles and their interrelationship with other cell organelles is discussed.     

Endocytosis of 1,3-β-glucans by broad bean cells at the penetration site of the cowpea rust fungus (haploid stage)

Te penetration hypha of basidiospore-derived infection structures of the cowpea rust fungus (Uromyces vignae Barclay) in epidermal cells of the nonhost, broad bean (Vicia faba L.), was studied with the electron microscope after high-pressure freezing and freeze substitution. After fungal invasion of the epidermis, a plug in the penetration hypha separated the infection structures on the cuticle from the intraepidermal vesicle of the fungus. The plug and the fungal cell wall reacted with a polyclonal 1,3-β-glucan antibody. The plug in the haploid stage seems to have a task similar to the septum formed in the diploid stage of the fungus. Around the penetration hypha, the plant wall stained darkly and a papilla was deposited by the plant. In the papilla, 1,3-β-glucans were labelled by a monoclonal and a polyclonal antibody. In the infected epidermal cell, clathrin-coated pits, coated vesicles, partially coated reticula and multivesicular bodies were found. The contents of the coated pits, coated vesicles, partially coated reticula and multivesicular bodies bound to monoclonal and polyclonal 1,3-β-glucan antibodies. Accumulation and uptake of this paramural material into the plant cell by endocytosis is concentrated at the fungal penetration site. It may influence the host-parasite interaction.     

An ultrastructural approach to the adaptive role of the cell wall in the intertidal algaFucus virsoides

Summary The ultrastructure of the cell wall and the distribution of alginate, cellulose and fucoidans were studied in the intertidal algaFucus virsoides. Microanalysis and precipitation with KPA revealed a cation localization in the wall, mainly corresponding with sulphated polysaccharide distribution. Thus, the adaptive resistance to changes in ionic environment seems to take place through a cation binding to the cell wall polysaccharides, principally at the thallus surface, employing an avoidance mechanism.Supported by a M.P.I. grant.     

Observation of Woronin bodies in Arthrinium aureum by scanning electron microscopy

Woronin bodies are cytoplasmic organelles of filamentous fungi that can be observed on one, or both sides of each septum. The goal of this paper is to illustrate the presence of them in hyphae of Arthrinium aureum by means of scanning electron microscopy and to show that they act as a safety plug to close septa pores in hypha. Results show that Woronin bodies as an immediate response to prevent a cytoplasm loss. Results support hypothesis proposed previously in literature. This revised version was published online in June 2006 with corrections to the Cover Date.     

Ultrastructure of hyphae and ascospores in the genus Eremascus eidam

Hyphae and ascospores of Eremascus fertilis and E. albus were studied in ultrathin sections. The lateral wall of the hyphae had a thick electron-light inner layer and a thin dark outer layer. The septa had a simple central pore with or without a plug, and there were Woronin bodies in the vicinity. The wall of the ascospores of E. fertilis showed a thick light inner layer and a thin dark outer layer. In the wall of the spores of E. albus a dark fibrillar layer was present between the light inner layer and the dark outer layer. The spores of this species germinated with a tube the wall of which was continuous with a newly formed layer inside the spore wall.This investigation was supported by the Netherlands Organization for the Advancement of Pure Research (Z. W. O.)     

Comparative ultrastructure of the zoospores of nine species ofNeochloris (Chlorophyta)

Nine species ofNeochloris can be divided into three groups on the basis of comparative ultrastructure of the flagellar apparatus, the cell wall and the pyrenoid of zoospores. In Group I,N. wimmeri andN. minuta, zoospores are thin-walled, pyrenoids are penetrated by stromal channels, and the basal bodies are in the clockwise absolute orientation and connected by the distal and two proximal fibers. In Group II,N. aquatica, N. vigenis, N. terrestris, N. pyenoidosa, andN. pseudostigmatica, zoospores are naked or covered by fuzzy material, pyrenoids are covered by a continuous starch sheath or invaginated by cytoplasmic channels, basal bodies are directly opposed, the distal fiber is differentiated into a ribbed structure at the central region, a striated microtubule-associated component (SMAC) is continuous between opposite two-membered rootlets and connected to the ribbed structure, proximal ends of basal bodies are covered by partial caps, each two-membered rootlet and a basal body are connected by a striated fiber to the X-membered rootlet associated with the opposite basal body, and the basal bodies, when oriented at wide angles, are joined at their proximal ends by core extensions. In Group III,N. pseudoalveolaris andN. cohaerens, zoospores are naked, pyrenoids are traversed by parallel thylakoids, basal bodies are in the counterclockwise absolute orientation and overlapped, and each X-membered rootlet is connected to the end of the opposite basal body by a terminal cap. It is suggested that the genusChlorococcopsis gen. nov. be erected for the Group I species. Group II, which includes the type species,N. aquatica, should be preserved asNeochloris. The group appears to be closely related to the coenobial generaPediastrum, Hydrodictyon, andSorastrum, and to have affinities with the coenocytic generaSphaeroplea andAtractomorpha as well. It is also suggested that the genusParietochloris gen. nov. be erected in thePleurastrophyceae for the species of Group III.     

Paramural bodies of Albugo candida

The paramural bodies of Albugo candida were formed solely by elaboration of the plasmalemma. Two major forms were recognized: one consisting of plasmalemmal invaginations projecting into the cytoplasm; the other appearing like a pocket containing a number of vesicles and tubules. It is suggested that the first is the basic form of paramural body. In sporangia the paramural bodies break away from the plasmalemma and undergo autodigestion while in vegetative hyphae their tubules and lamellae break up into vesicles that are finally sequestered into the wall.     

Bipolar budding in yeasts — an electron microscope study

Bud formation in yeasts with bipolar budding was studied by electron microscopy of thin sections.Budding in yeasts of the speciesSaccharomycodes ludwigii, Hanseniaspora valbyensis andWickerhamia fluorescens resulted in concentric rings of scar ridges on the wall of the mother cell. The wall between the ridges consisted of the scar plug left by the former budding and opened up in the formation of the next bud. The wall of the bud arose from under the wall of the mother cell.In the yeasts of the speciesNadsonia elongata more than one bud might be formed from the same plug.InSchizoblastosporion starkeyi-henricii the scar ridges were close together and apparently not separated by the entire plug.In all species a cross wall was formed between mother cell and bud which consisted of an electron-light layer between two layers of more electron-dense material. The cells separated along the light layer.The authors wish to thank Dr J. A. Barnett for corrections of the English text, and Mr J. Cappon for drawing Fig. 1.     

Copulatory Plug Displacement Evidences Sperm Competition in Lemur catta

Male displacement of copulatory (sperm) plugs from female vaginas provides further evidence for sperm competition in ring-tailed lemurs (Lemur catta), a gregarious prosimian species with a multimale, multifemale mating system. During two mating seasons, I studied two groups of free-ranging ring-tailed lemurs on St. Catherines Island, GA, USA. I observed 22 mating pairs in which males achieved penile intromission. Copulatory plug displacement by males occurred in 9 cases. Plugs were displaced during copulation by male penes upon withdrawl following deep vaginal thrusting. In every case of copulatory plug displacement, the male displacing a plug mated to ejaculation with the estrous female. In a mating system in which females typically mate with more than one male during estrous, often in succession, copulatory plug displacement may function to disrupt or preclude other males' successful insemination of estrous females. The effects of sperm plug displacement on paternity in Lemur catta are unknown, as no study had heretofore documented copulatory plug displacement in this species. The first-male mating advantage suggested for Lemur catta should be re-evaluated where mating order is known, and copulatory plug displacement during mating, or lack thereof, is identified. Because there is a tendency for first-mating males to mate-guard for longer periods of time in Lemur catta, the latency period between the first mate's ejaculation and that of subsequent mates may be an important determinant of male fertilization success.     

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.     

The fine structure of ascospore shape and development inCeratocystis fimbriata

Ascospore development inCeratocystis fimbriata Ell. & Halst. commenced in an eight-nucleate ascus. A single vesicle formed along the periphery of the ascus from fragments of ascospore delimiting membranes, surrounded all eight nuclei and eventually invaginated, first forming pouches with open ends, then finally enclosing each of the eight nuclei in a separate sac, thus delimiting ascospores. Pairing of the ascospores followed and brim formation occurred at the contact area between two ascospores. Osmiophilic bodies contributed to the formation of brim-like appendages by fusing to the ascospore walls. Additional brims were observed at opposite ends of the ascospores giving them a double-brimmed appearance.Abbreviations AV ascus vesicle - DM delimiting membrane - EV electron translucent bodies - G granules - M mitochondria - N nucleus - OB osmiophilic bodies - PMV plasmamembrane vesicles - PW primary wall - SW secondary wall     

Tapetum plastids ofOlea europaea L.

Summary The plastid ontogenesis inOlea europaea tapetum has been studied. Tapetum plastids start their development as proplastids and differentiate into elaioplasts. At the end of their development the tapetal cells degenerate and are substituted by roundish lipidic masses which will later form an exine coating (Pollenkitt). During their ontogenesis the plastids are characteristically associated with membrane outlines of mostly smooth ER, which appear to be correlated with lipid accumulation inside the plastids.     

Cell wall metabolism during fruiting of the basidiomycete Schizophyllum commune

During the development of fruit bodies of the basidiomycete Schizophyllum commune, the alkali-insoluble (R glucan) and alkali-soluble (S glucan) cell wall fractions are synthesized during the entire course of morphogenesis. The water soluble glucan (WSG) is not synthesized after an early stage. There is also a relative increase in the proportion of S glucan during development which appears related to a change in the proportion of the components synthesized. Data are also presented to show that several fruiting mutants also have specific cell wall differences, and that there is a significant contribution to cell wall structure by genes which do not cause a macroscopically observable change in phenotype.     

The ultrastructural development of the macrogamete ofEimeria stiedai

Summary The development of the macrogamete ofEimeria. stiedai in the epithelial cells of the bile ducts of rabbits was studied by electron microscopy. A macrogamete was first identified by the presence of a large central nucleus with prominent nucleolus, and subsequently by the appearance of wall forming bodies. The macrogamete was limited by an outer single membrane under which there were remnants of a second membrane. The parasitophorous vacuole, in which the macrogamete was located, was often narrow and it contained no intravacuolar-tubules or -folds. As macrogametogony proceeded wall forming bodies of Type I and II, canaliculi, electron pale spaces (lipid) and polysaccharide granules increased in number. Granular endoplasmic reticulum, mitochondria and Golgi bodies were present throughout.     

Cytoplasmic reorganization accompanies the deposition of a bipolar cell wall in the large-celled red alga Anotrichium tenue

The filamentous red alga Anotrichium tenue C. Aghard (Naegeli) (formerly Griffithsia tenuis C. Aghard; Baldock, 1976, Aust. T. Bot. 24, 509–593) has large (1–2 mm long), cylindrical, multinucleate cells that exhibit a daily, cyclic redistribution of chloroplasts. Chloroplasts accumulate in the mid-region of each growing cell during the day; consequently, filaments appear banded with a light apical end-band, a dark mid-band and a light basal end-band in each growing cell. Chloroplasts disperse at night so that the bands are no longer visible and the cells appear evenly pigmented. Anotrichium tenue also has a type of cell elongation, known as bipolar band growth, in which new material is added to the microfibrillar part of the wall in bands located at the apical and basal poles of elongating cells. This site of wall growth corresponds to the position of the light-colored end-bands present during the day. Here we examine the structural relationship between the cytoplasmic bands and the wall-growth bands. Our results show that, in addition to the previously described bipolar wall bands, there is a non-microfibrillar wall band in the mid-region of the cell. This wall component apparently branches from near the top of the microfibrillar outer wall and terminates near but not at the bottom of the cell. It contains nodules of sulphated polysaccharide material secreted from a band of vesicles, which co-localize with the chloroplasts in the mid-band. The outer wall appears to enclose the entire cell. Nuclei do not redistribute with the chloroplasts or wall vesicles into the mid-band but remain evenly distributed throughout the cytoplasm. Each wall component grows by a different mechanism. We show that two types of wall growth, diffuse and the bipolar-type of tip growth, occur in the same cell and we propose that the observed segregation of the cytoplasm supports localized growth of the unique inner wall component. Additionally, we show that A. tenue is an excellent model for study of the role and mechanism of cytoplasmic compartmentalization and cell polarity during plant cell growth.We wish to thank Dr. Richard Cloney (University of Washington and Dr. Tom Schroeder (Friday Harbor Laboratories, Friday Harbor, Wash.) for helpful discussions and critical review of this work. We also thank Dr. Susan Waaland (University of Washington) for sharing her original observations on the chloroplast banding phenomenon in Anotrichium tenue. We are grateful to the Friday Harbor Laboratories for the use of their space and facilities. This research was supported by funds from the Washington Sea Grant Program (awarded to J.R.W.) and by the Developmental Biology Training Grant, predoctoral fellowship, National Institutes of Health, No. HD07183 to A.W.S.     

Ultrastructure of Cysts of Naegleria spp: A Comparative Study*

SYNOPSIS. Ultrastructure of cysts of Naegleria gruberi, Naegleria fowleri, and Naegleria jadini was compared by transmission electron microscopy. Pores in the cyst wall were observed in all 3 species. In N. gruberi they were surrounded by a collar and sealed with a relatively large mucoid plug; no such collar was seen around the pores in the other 2 species, in which the plug was smaller than that in N. gruberi. An electron-dense plaque serving as an additional pore closure was present in all 3 species. In N. gruberi, the cyst wall consisted of an inner thick and an outer thin layer; however, only the inner component was present in cysts of N. fowleri and N. jadini, which had a smooth appearance. At the ultrastructural level, excystment of N. fowleri involved digestion of the mucoid plug and emergence of the trophozoite through the pore. Some digestion of the cyst wall also appeared to take place during excystment.     

Ultrastructural Studies on the Microconidia of Botrytis cinerea Pers. and their Phialoconidial Development

The genesis and ultrastructure of microconidia of Botrytis cinerea Pers. were studied, using TEM and SEM. Microconidia are produced in flask-shaped, terminal or lateral phialides. The first microconidium develops holoblastically, subsequent microconidia are formed enteroblastically, in basipetal succession from a fixed conidiogenous locus. Mature microconidia are characterized by a two-layered spore wall covered by mucilage, a single, sickle-shaped nucleus, one or two large lipid bodies, a few mitochondria of the cristae-type, ribosomes, sparse endoplasmatic reticulum close to the plasmalemma and a small amount of cytoplasma. The basal septum which is surrounded by a collar-like rim is perforated by a simple central pore with a pore plug. Differences in genesis and ultrastructure of microconidia compared with macroconidia are discussed in relation to the function of these two spore types.     

Ultrastructural research on cell wall regeneration by cultured pollen protoplasts of Lilium longiflorum

Summary Protoplasts from pollen grains of Lilium longiflorum regenerate amorphous cellulosic cell walls in culture, during which some precursors of cellulose are polymerized, thus producing progressively harder cellulosic cell walls as the period of culture continues. It is presumed that the components of the cell wall regenerated during 1 week in culture differ from those of the intine of the pollen grain wall. The regenerated cell wall is formed by means of large smooth vesicles; in addition, numerous coated vesicles and pits aid in wall regeneration. The pollen tube that germinates from the 8-day-old cultured protoplast has numerous Golgi bodies and many vesicles which build the pollen tube wall. The tube wall has two layers just like a normal pollen tube wall.