An ultrastructural study of carpospores in the red alga <Emphasis Type="Italic">Chondrus pinnulatus</Emphasis> (Harvey) okamura, 1930 (Rhodophyta: Gigartinaceae) from Vostok Bay,the Sea of Japan

The morphological features of carpospores in the red alga Chondrus pinnulatus have been studied using methods of transmission and scanning electron microscopy. Rounded mature carpospores are assembled into groups. Each carpospore is surrounded by a two-layered mucilage wall. The electron-dense cytoplasm contains numerous starch grains, fibrous vesicles, and large clusters of fibrous vesicles. The plastids have well-developed thylakoids and the cell nucleus occupies a nearly central position. The nucleolus is large and loose and is localized near the nuclear membrane. Dictyosomes, small fibrous vesicles, osmiophilic granules, and plastids are localized at the periphery. Mitochondria are arranged near the dictyosomes, plastids, and around the nucleus. A generalized scheme of the fine structure of the carpospore has been proposed for red algae on the basis of our own and literature data.     

ULTRASTRUCTURE OF CARPOSPOROGENESIS IN THE PARASITIC RED ALGA FAUCHEOCOLAX ATTENUATA SETCH. (RHODYMENIALES,RHODYMENIACEAE)

Carpospore differentiation in Faucheocolax attenuata Setch. can be separated into three developmental stages. Immediately after cleaving from the multinucleate gonimoblast cell, young carpospores are embedded within confluent mucilage produced by gonimoblast cells. These carpospores contain a large nucleus, few starch grains, concentric lamellae, as well as proplastids with a peripheral thylakoid and occasionally some internal (photosynthetic) thylakoids. Proplastids also contain concentric lamellar bodies. Mucilage with a reticulate fibrous substructure is formed within cytoplasmic concentric membranes, thus giving rise to mucilage sacs. Subsequently, these mucilage sacs release their contents, forming an initial reticulate deposition of carpospore wall material. Dictyosome vesicles with large, single dark-staining granules also contribute to wall formation and may create a separating layer between the mucilage and carpospore wall. During the latter stages of young carpospores, starch is polymerized in the perinuclear cytoplasmic area and is in close contact with endoplasmic reticulum. Intermediate-aged carpospores continue their starch polymerization. Dictyosomes deposit more wall material, in addition to forming fibrous vacuoles. Proplastids form thylakoids from concentric lamellar bodies. Mature carpospores are surrounded by a two-layered carpospore wall. Cytoplasmic constituents include large floridean starch granules, peripheral fibrous vacuoles, mature chloroplasts and curved dictyosomes that produce cored vesicles which in turn are transformed into adhesive vesicles. Pit connections remain intact between carpospores but begin to degenerate. This degeneration appears to be mediated by microtubules.     

Ultrastructure of the differentiating zygotospores of Porphyra leucosticta (Rhodophyta)

The ultrastructure of zygotosporogenesis is described for the red alga Porphyra leucosticta Thuret. Packets of eight zygotosporangia, each packet derived from a single carpogonium are interspersed among vegetative cells. Zygotospore differentiation in Porphyra can be separated into three developmental stages. (i) Young zygotospores exhibit a nucleus and a large centrally located, lobed plastid with pyrenoid. Mucilage is produced within concentric membrane structures during their dilation, thus resulting in the formation of mucilage sacs. Subsequently, these sacs release their contents, initiating the zygotospore wall formation. Straight‐profiled dictyosomes produce vesicles that also provide wall material. During the later stages of young zygotospores, starch polymerization commences, (ii) Medium‐aged zygotospores are characterized by the presence of fibrous vacuoles. These are formed from the ‘fibrous vacuole associated organelles’. The fibrous vacuoles finally discharge their contents. (iii) Mature zygotospores are recognized by the presence of numerous cored vesicles produced by dictyosomes. Cored vesicles either discharge their contents or are incorporated into the fibrous vacuoles. There is a gradual reduction of starch granules during zygotospore differentiation. Mature zygotospores are surrounded by a fibrous wall, have a large chloroplast with pyrenoid and well‐depicted phycobilisomes but are devoid of starch granules.     

Ultrastructure of post-fertilization development in the red alga Scinaia articulata (Galaxauraceae,Nemaliales, Rhodophyta)

The ultrastructure of the carposporophyte and carposporogenesis is described for the red alga Scinaia articulata Setch. After fertilization, the trichogyne disappears, and the pericarp develops to form a thick protective tissue that surrounds the carposporophyte. The hypogynous cell cuts off both one-celled and two-celled sterile branches. Patches of chromatin are frequently observed in evaginations of the nuclear envelope, which appear to produce vesicles in the cytoplasm of the cell of the sterile branch. Large gonimoblast lobes extend from the carpogonium and cleave to form gonimoblast initials. Subsequently, a fusion cell is formed from fusions of the carpogonium, the hypogynous cell and the basal cell of the carpogonial branch. The mature carposporophyte comprises the fusion cell that is connected to the sterile branch cells, gonimoblast cells and carpospores and is surrounded by extensive mucilage. Young carpospores possess a large nucleus and proplastids with a peripheral thylakoid, but they have few dictyosomes and starch granules and are indistinguishable from gonimoblast cells. Subsequently, dictyosomes are formed, which produce vesicles with an electron-dense granule, which indicates an initiation of wall deposition. Thylakoid formation coincides with incipient starch granule deposition. The nuclear envelope produces fibrous vacuoles and concentric membrane bodies. Carpospores are interconnected by pit connections with two cap layers. Dictyosome activity increases, resulting in the production of vesicles, which either continue to deposit wall material or coalesce to form fibrous vacuoles. The final stage of carposporogenesis is characterized by the massive production of cored vesicles from curved dictyosomes. Mature carpospores are uninucleate and contain fully developed chloroplasts, numerous cored vesicles, numerous starch granules and fibrous vacuoles. The mature carpospore is surrounded by a wall layer and a separating layer, but a carposporangial wall is lacking.     

Ultrastructural Changes in Cortical Cells of Apple (Malus pumila Mill.) Associated with Cold Hardiness

Seasonal ultrastructural changes in cortical cells of apple(Malus pumila Mill.) twigs were studied with special referenceto seasonal variations in cold hardiness. The ultrastructuralcharacteristics could be divided into two major sets: one setthat developed during cold acclimation from September to Januaryand one that developed during deacclimation from February toMay. During cold acclimation, the most striking changes weremicrovacuolation and augmentation of the volume of the cytoplasm.At this stage, the cells became temporarily rich in the organellesthat are involved in protein synthesis, such as vesicular endoplasmicreticulum, polysomes, dictyosomes and vesicles. Plastids thatcontained starch granules, protein-lipid bodies and mitochondriawere also abundant. Each nucleus contained relatively loweramounts of heterochromatin and was located in the central portionof the cell. From mid-November until March, plastids aggregatedaround the nucleus, and the formation of "plastid initials"from the mature plastids, as a results of constriction and subsequentpinching off, was frequently observed. In January, when maximumcold-hardiness was achieved, the starch granules in plastidsdisappeared. The second set of ultrastructural changes, whichincluded fusion of vacuoles, was initiated in late February.During deacclimation, the differentiation of vacuoles proceededin the cells, starch granules reappeared in the plastids andorganelles involved in protein synthesis became abundant. Furthermore,vesicular endoplasmic reticulum observed during the autumn andwinter was replaced by smooth endoplasmic reticulum. In mid-May,when cold hardiness decreased to a low level, most of the cellspace was occupied by a large vacuole. The results suggest that seasonal cytological changes are involvedin the changes in the physical and functional properties ofcold-adapted cells. The seasonal replication of vacuoles andcytoplasm may be related to resistance or susceptibility tothe stress-producing effects of the dehydration that occursduring freezing, and the replication of organelles may be associatedwith the metabolism required for cold acclimation or deacclimation. (Received December 3, 1992; Accepted December 28, 1993)     

ULTRASTRUCTURE OF CARPOSPOROPHYTE DEVELOPMENT IN THE RED ALGA GLOIOSIPHONIA VERTICILLARIS (CRYPTONEMIALES,GLOIOSIPHONIACEAE)

The ultrastructure of carposporophyte development is described for the red alga Gloiosiphonia verticillaris Farl. The auxiliary cell produces gonimoblast initials, which divide to produce two types of gonimoblast cells—the nondividing vacuolate cells and terminal generative gonimoblast cells. The generative gonimoblast cells form clusters of carpospore initials, which eventually differentiate into carpospores. After gonimoblast filaments are formed, the auxiliary cell undergoes autolysis, causing degeneration of septal plugs between the auxiliary cell and adjacent cells, thus forming a fusion cell. Since this cell lacks starch and appears degenerate throughout carposporophyte development, a nutritive function cannot be ascribed to the fusion cell. Carpospore differentiation is simple and proceeds through three developmental stages. Young carpospores structurally resemble gonimoblast cells, because they contain undeveloped plastids, large quantities of floridean starch, and are surrounded by extensive mucilage instead of a distinct wall. In addition, dictyosomes form and begin to produce vesicles with fibrous contents representing carpospore wall material. During the intermediate stage, dictyosomes continue to produce vesicles that contribute additional carpospore wall material, thereby compressing the mucilage and creating a darker-staining layer outside the carpospore wall. Plastids form internal thylakoids by invaginations of the inner membrane of the peripheral thylakoid. The endoplasmic reticulum forms large granular vacuoles that appear to be degraded during subsequent stages of development. Mature carpospores form cored vesicles. They also contain mature chloroplasts, large amounts of floridean starch, and occasionally granular vacuoles. During this stage, interconnecting carpospore-carpospore and carpospore-gonimoblast cell septal plugs begin to undergo degeneration. This process may be mediated by tubular structures.     

Golgi vesicles of uncommon morphology and wall formation in the red alga,Polysiphonia

Summary Golgi bodies of immature carposporangia ofPolysiphonia sp. are composed of a polarized stack of six to ten curved cisternae. The cisternae are surrounded by 50–200 nm diameter slightly granular vesicles.Hypertrophied, fibrillar Golgi cisternae occur in mature carposporangia. Secretory vesicles originate from ends of cisternae and by complete vesiculation of terminal cisternae; 0.6–1.2 m diameter, fibrous vesicles, many with electron dense nucleoids are abundant throughout the cytoplasm of mature sporangia. Vesicles expand, fuse with each other and cluster around starch granules. Some vesicles secrete their content into the spore wall. Morphological analyses of starch granules as well as topographical relations between vesicles, starch granules and the adjacent cytoplasm suggest that these Golgi vesicles function like lysosomes. The significance of these observations is discussed in relation to the composition of plant cell walls and cellular expansion.     

The Ultrastructure of Tetrasporogenesis in the Marine Red Alga Chondria tenuissima (Good, et Woodw.) (Ceramiales, Rhodomelaceae)

Tetraspore development has been studied in Chondria tenuissimausing light and electron microscopy. The transformation of tetrasporangialmother cells into mature tetrasporangia involves a series ofstructural changes, especially of dictyosomes and of the nucleus.The youngest stage of tetrasporogenesis consists of a uninucleatetetraspore mother cell with synaptonemal complexes present duringearly prophase of meiosis I. Mitochondria are aggregated aroundthe nucleus, dictyosome activity is low, and proplastids occurin the peripheral cytoplasm. The cleavage furrows are initiatedalmost concomitantly with commencement of meiosis. When thecleavage furrows are initiated, spherical bodies bounded bytwo membranes are found within the cytoplasm; they develop intovacuoles with fibrillar contents (fv₁), which increase in sizeduring tetraspore development by fusing with each other andwith Golgi vesicles. The Golgi vesicles and the vacuoles withfibrillar contents (fv₁) contribute material to the developingtetraspore wall. During the middle stage of tetraspore formationthe vacuoles with fibrillar contents (fv₁) are dominant, dictyosomeactivity increases, as well as the number of plastids and mitochondria;starch formation also increases. Stacked cisternae of the endoplasmicreticulum are found within the peripheral part of the nucleus.The same nuclear structures are also observed in tetrasporangiaof the marine red alga Gastroclonium clavalum. The final stageis characterized by the disappearance of vacuoles with fibrillarcontents (fv₁) and of the stacked ER within the nucleus, presenceof straight, large dictyosomes which produce cored vesicles,an abundance of starch grains and by the formation of fullydeveloped chlorqplasts. The cored vesicles contain Thiéry-positivematerial and contribute to the formation of vacuoles with fibrouscontents (fv₂) as they are dominant in the tetraspores beforetheir liberation. Rhodophlyla, Chondria, tetrasporogenesis, ultrastructure, Golgi apparatus     

Some unusual features of the ultrastructure of the chloroplasts of the green algal orderCaulerpales and their development

Summary The ultrastructure of developing and mature chloroplasts of members of the green algal orderCaulerpales is described. The mature chloroplasts develop from small starch containing plastids. These small starch containing plastids may also develop into the large amyloplasts characteristic of this order. The thylakoid organizing body (TOB), a system of concentric lamellae found at one end of the plastid, appears to be involved in initial thylakoid membrane synthesis. During early plastid development the first formed thylakoids, the plastid DNA and lipid are closely associated with this body. Many developing plastids also have a number of microfilaments near the chloroplast envelope. These microfilaments extend from the TOB towards the opposite end of the plastid.The size and structure of the mature caulerpalean chloroplast varies greatly between species, as does the size and structure of the TOB. The simplest type of TOB occurs inAvrainvillea erecta and the most complex inCaulerpa cactoides. The membranes of the TOB are connected by crossbridges and they are also connected with the inner chloroplast envelope membrane. The structure of the TOB, its relation to the chloroplast envelope, its association with the thylakoids and its possible functions are described.     

THE ULTRASTRUCTURE OF DEVELOPING LATEX DUCTS IN MAMMILLARIA HEYDERI (CACTACEAE)

Electron microscopy was used to investigate early development of latex ducts in Mammillaria heyderi (Cactaceae). Numerous vesicles (secondary vacuoles) form from invaginations of the plasmalemma near sites of wall thinning, from endoplasmic reticulum (ER), and from vesiculate grana of degenerate plastids. Dictyosomes, though they occur in young duct cells, do not seem to be responsible for the formation of vesicles. Cytoplasmic vesicles may contain fibrillar, globular, or crystalline materials, or may be devoid of any type of particulate matter. They may be responsible for storage of numerous laticiferous components. Lysosomal materials could be stored in some vesicles and contribute to the degradation of the protoplast. Some nuclei contain condensed chromatin and are subject to deformation and collapse. Mitochondria and lipid bodies are common in young duct cells but ER is rare. When ducts form in young tissues, plastids in the lumen do not produce starch grains or extensive membranous networks. The plastids eventually degenerate to become a part of latex. If ducts form in older, established tissues having mature plastids, the plastids undergo extreme modification.     

Differentiation of Non-articulated Laticifers in Poinsettia (Euphorbia pulcherrima Willd.)

Differentiation of non-articulated laticifers in poinsettia(Euphorbia pulcherrima Willd.) was studied ultra-structurally.Growing laticifers show: (1) a multinucleate apical region containingabundant ribosomes but few other differentiated organelles and(2) a sub-apical zone where the cytoplasm is dominated by vacuolesof diverse morphology with latex particles. These particlesappear first within narrow tubular vacuoles developed especiallyin the peripheral cytoplasm. During vacuolation of the laticifer,portions of cytoplasm, including some of the nuclei, becomeisolated by the enlarging and fusing vacuoles; eventually thesebecome lysed, except the latex particles which remain in thecentral vacuole. During differentiation of a laticifer branch,the cytoplasm contains the usual organelles, including a fewmicrobodies and coated vesicles. The plastids that lie withinthe peripheral cytoplasm differentiate into amyloplasts witha single elongated starch grain. Towards the end of differentiationthe cytoplasm becomes restricted to a thin parietal layer, withthe remaining organelles reduced or degenerate, surroundinga central vacuole filled with latex particles. Euphorbia pulcherrima Willd, poinsettia, ultrastructure, differentiation, laticifers     

Plastid Ontogeny in the Corolla Cells of Digitalis purpurea L. cv. Foxy

Initially the corolla plastids of Digitalis purpurea containsmall grana with negatively stained thylakoids. Degenerationof the grana, loss of chlorophyll and the transient accumulationof starch accompany corolla expansion Starch disappears by thetime the anthers dehisce and granular and amorphous phytoferrtindeposits become prominent in the stroma Concomitant with theseparation of the stigmatic lobes the thylakoid system is reducedto a central membranous network enveloping the phytofemtm aggregatesJust prior to corolla abscission the stroma becomes packed withplastoglobuh Although this developmental sequence closely resemblesthat for chromoplasts in yellow and red flowers, fruits andautumn leaves there is no synthesis of carotenoid pigments inthe corollas of Digitalis purpurea At maturity the plastidsare therefore best described as elaioplasts. Digitalis purpurea L., foxglove, corolla, plastids, elaioplasts, phytofemtin, ultrastructure, X-ray microanalysis     

CYTOLOGY OF DIFFERENTIATING TRACHEARY ELEMENTS I. ORGANELLES AND MEMBRANE SYSTEMS

The distribution of organelles, membrane systems, and ribosomes is not at any time obviously related to the pattern of secondary wall in helically thickened tracheary elements in leaves of Beta vulgaris L. (sugar beet) and Cucurbita maxima Duchesne, fixed with potassium permanganate and osmium tetroxide. During the differentiation of the secondary wall, cisternae of the endoplasmic reticulum and dictyosomes are particularly conspicuous, and the dictyosomes are associated with numerous vesicles. Similar vesicles appear to be in various stages of fusion with the secondary wall thickenings. The tracheary elements contain plastids which may include starch granules. Ribosomes occur free in the cytoplasm and in association with endoplasmic membranes.     

蝇子草腺毛的形态发生及超微结构的研究

蝇子草茎叶上着生粘液毛,它是由３个细胞构成的单列腺毛。电镜观察表明,在刚形成的腺毛柄细胞中,质体最发达,而且大多数质体内含有淀粉粒。在柄细胞中,有些质体和液泡膜融合产生小泡,可能以胞饮方式将质体内的淀粉粒降解后的产物转以液泡内。有些质体则可能直接突入液泡并在液泡内降解其淀粉粒。在头细胞发育中,含淀粉粒的质体增多。后期大多数质体消失,同时出现了大量的充满纤丝状物质的小不包和大泡。最后,小泡和大泡相琵     

Ultrastructure of post-fertilization development in the red alga Nienburgia andersoniana (Delesseriaceae, Ceramiales, Rhodophyta)

The ultrastructure of post-fertilization development in Nienburgia andersoniana (J. Ag.) Kyl. is described. Above the auxiliary cell there is a group of four sterile cells. The presence of abundant storage products (starch granules, lipid bodies and protein crystals) in these cells indicates that the sterile cells function as nutrient suppliers to the young auxiliary and gonimoblast cells of the carposporophyte during its early steps of development. Following fertilization and transfer of the diploid nucleus to the auxiliary cell, the trichogyne disappears and large multinucleate gonimoblast initials are produced. These subsequently produce generative gonimoblast cells which cleave successively to form young carpospores. Those of the gonimoblast cells which will not differentiate into carpospores are transformed into cells producing mucilage. Both kinds of gonimoblast cells contain plastids, starch granules, cytoplasmic concentric membrane bodies and small vesicles. Dark-staining spherical masses occurring in the cytoplasm of the auxiliary and gonimoblast cells may represent degenerating haploid nuclei. Septal plugs interconnecting the auxiliary cell and gonimoblast cells increase considerably in size during carposporophyte development. The fusion cell at the late stage of carposporophyte development appears degenerative. Young carpospores have plastids and mitochondria, and concentric membrane bodies that will form mucilage sacs. Medium-aged carpospores have fully developed plastids, starch granules and fibrous vacuoles. Mature carpospores possess, in addition, cored vesicles. The inner pericarp cells contribute large amounts of mucilage to the cytostocarpic cavity and eventually are consumed. © 2003 The Linnean Society of London, Botanical Journal of the Linnean Society , 2003, 142 , 289–299.     

Cotton embryogenesis: The pollen cytoplasm

Summary The ultrastructure and composition of cotton (Gossypium hirsutum) pollen, exclusive of the wall, was examined immediately before and after germination. The pollen grain before germination consists of two parts: the outer layer and a central core. The outer layer contains large numbers of mitochondria and dictyosomes as well as endoplasmic reticulum (ER). The core contains units made of spherical pockets of ER which are lined with lipid droplets and filled with small vesicles; the ER is rich in protein and may contain carbohydrate while the vesicles are filled with carbohydrate. Starch-containing plastids are also present in the core as are small vacuoles. The cytoplasm of the pore regions contains many 0.5 spherical bodies containing carbohydrate. After germination the ER pockets open and the lipid droplets and small vesicles mix with the other portions of the cytoplasm. With germination the pore region becomes filled with mitochondria and small vesicles. The vegetative nucleus is large, extremely dense and contains invaginations filled with coils of ER. A greatly reduced nucleolus is present in the generative cell which is surrounded by a carbohydrate wall. The cytoplasm of the generative cell is dense and contains many ribosomes, a few dictyosomes and mitochondria, many vesicles of several sizes, and some ER. No plastids were identified. The generative nucleus is also dense with masses of DNA clumped near the nuclear membrane. An unusual tubular structure of unknown origin or function was observed in the generative cell.     

Effect of Chloramphenicol on Etiochloroplasts of Wild and Chlorophyll b-Less Barley Genotypes

Greening of etiolated seedlings of wild and Chl b-less barley(Hordeum vulgare L.) genotypes in the presence of D-threochloramphenicol(CAP) led to macrogranal arrangements accompanying the inhibitionof Chl synthesis and an enhancement of the total protein contentin differentiated etiochloroplasts. In treated mutant plastids,protein/Chl ratio reached up to 100. No light-dependent O₂ evolution was detected in CAP-treatedplastids which had deficiency in polypeptides belonging to thephotosystem II (PSII) centres. On the other hand, plastids displayeda high photosystem I (PSI) activity despite the absence of the92 kDa polypeptide linked to the PSI centre. The accumulationof polypeptides ranging from 16 to 20 kDa suggest that theycould originate from primary complexes consisting of few Chlmolecules, but they were sufficient to allow the activity ofthe reaction centres. No accumulation of the 25–27 kDapolypeptides linked to the PSII antenna was detected. The increase in the proportion of trans-₃hexadecenoic acid (16:1tr) in phosphatidylglycerol (PG) of etiochloroplasts from bothtypes after CAP treatment could indicate an alteration of theregulation process of 16:1 tr biosynthesis occurring in plastids.The formation of macrograna could optimize the energy transferin altered thylakoid membranes. The accumulation of PG-16:1tr molecules could be related to the formation of active primarycomplexes in thylakoid when Chl synthesis is altered. (Received March 30, 1988; Accepted June 1, 1988)     

ULTRASTRUCTURAL CHANGES ASSOCIATED WITH UTILIZATION OF METABOLITE RESERVES AND TRICHOME DIFFERENTIATION IN THE PROTOCORM OF VANDA

Certain aspects of protocorm development in Vanda were examined ultrastructurally. The parenchymal cells of the protocorm accumulate substantial quantities of lipid, protein, and carbohydrate reserves which disappear gradually with the senescence of the parenchymatous region. The proteinaceous reserves appear initially as discrete bodies which become intimately associated with clusters of small tubules. The tubules eventually disperse throughout the cytoplasm and disappear following depletion of the protein bodies. The lipid reserves also appear as discrete bodies and are associated with an electron dense, laminated inclusion which appears to increase in size with the disappearance of the lipid bodies. While plastids in the meristematic cells differentiate a well-developed thylakoid system and contain little starch, those of the parenchymal cells contain large starch grains and numerous osmiophilic droplets and develop meager thylakoid systems. Membrane-bound crystalline structures of hexagonal and rhomboid cross section occur frequently in the cytoplasm of senescent parenchyma cells. Trichome initials, which differentiate from the epidermis, contain few conventional organelles and exhibit numerous membrane-bound structures containing many small crystalline inclusions. Numerous vesicles accumulate at the tips of the trichomes in spaces between the cell wall and the plasmalemma.     

Über das Vorkommen kleiner netzartiger Strukturen in den Plastiden

Summary In the chlorotic leaves of the Oenothera hybrid Oe. (lamarckiana x hookeri) velans· ^h hookeri with lamarckiana plastids the differentiation of the chloroplasts is disordered in different ways because of a disharmony between genom and plastom. Some of the plastids possess numerous vesicles and plastoglobuli but only a few isolated grana instead of the normal thylakoid system. Furthermore, the plastids contain lattice-like structures consisting of fibrils with a thickness of approximately 5 to 11 nm. These networks are connected with thylakoids, vesicles or plastoglobuli. They are interpreted as fragments of prolamellar bodies. Sometimes prolamellar bodies are distinctly recognizable in the chloroplasts even though the thylakoid system is rather well differentiated.