A NEW BANGIOPHYCIDEAN ALGA FROM ALABAMA1

A new species of red algae, Boldia angustata sp. nov., was discovered near Tuscaloosa, Alabama, during the spring of 1968. It differs significantly from the only previously described species, Boldia erythrosiphon Herndon, in length and width of young and mature thalli, cell size, shape of nuclei in first-order cells, shape of intercalary filaments, morphology of filaments derived from monospores, ontogenetic development of erect plants, morphology of the basal system, and regularity of first-order cells.     

The Abutilon Mosaic Virus (AbMV) in Different Leaf Tissues of Several Host Species of Malvaceae

Cytological changes occurring after infection by Abutilon Mosaic Virus (AbMV) have been investigated in the host plants Abutilon sellovianum Rgl., Malva parviflora L., Malva silvestris L., and Sida micrantha Schr. Two types of virus-like inclusions were found in different tissues: particles of 16–18 nm in diameter and elongated filaments with 6–8 nm in diameter. The particles are detectable in the nuclei (Abutilon sellovianum, Malva spec.) and cytoplasm (Malva spec.) of cells in the bundle area, and the filaments accumulate in the nuclei (Sida micrantha) and the plastids (Malva spec.) of leaf mesophyll cells.     

Ultrastructural and morphometrical analyses of the brown adipocyte nucleus in a hibernating dormouse

Summary— The fine morphology, size, and perichromatin granule frequency were analysed in brown adipocyte nuclei from hibernating, arousing, and euthermic dormice, Muscardinus avellanarius. Unusual nuclear structural constituents such as nuclear amorphous bodies, coiled body-like constituents and bundles of nucleoplasmic filaments were described as typical of hibernating nuclei. Morphometrical findings showed significant difference in total nuclear and nucleolar size in the three physiological conditions investigated as well as decreasing frequency of perichromatin granules in nuclei of hibernating to euthermic animals. A possible involvement of these granules in the intranuclear transport or storage of pre-mRNA is discussed in the context of other experimental evidence.     

Ultrastructure of human dermal blood vessels with special reference to the endothelial filaments.

The ultrastructure of endothelial cytoplasmic filaments of small blood vessels from the human dermis has been described. The material consisted of biopsies from normal abdominal and thoracic skin and also from the skin of patients with urticaria pigmentosa. Most vessels were surrounded by multiple layers of basal lamina and corresponded to the small venules of the subpapillary dermis. The wall of many vessels was composed by endothelial cells with clear cytoplasm which was rich in filaments and by endothelial cells with a dense cytoplasm which was poor in filaments. Some vessels had walls composed of clear endothelial cells only. The filaments varied in diameter between 80-120 A. Curling, recoiling and whorling of cytoplasmic filaments were obvious in endothelial cells of contracted vessels. Bulging of endothelial nuclei and nuclear indentations were seen in the skin lesion of urticaria pigmentosa. The possibility that the clear endothelial cells which are rich in filaments may be more actively involved in contraction than the dense cells, is discussed.     

Charakterisierung des Regenerationsprozesses im Caulonema eines Mooses durch autoradiographische Bestimmung der DNS-Synthese

Summary Ten-cell-long filaments of the caulonema of Funaria hygrometrica were isolated and labeled with ³H-thymidine. During the process of regeneration this precursor is incorporated into the nucleus and the chloroplasts. The nuclei of aged cells are preferentially labeled, even the nuclei of such cells which probably will no longer divide.From these facts it is concluded that DNA synthesis can occur during the process of regeneration irrespectively of a following cell division.     

Ultrastructure of vegetative organization and cell division in the freshwater red algaCompsopogon

Summary Uniseriate filaments of the freshwater red algaCompsopogon coeruleus were examined by transmission electron microscopy for details of vegetative organization and cell division with the goal of providing useful taxonomic characters. Each cell's single, complex chloroplast contains a peripheral encircling thylakoid, and unlike the vast majority of red algae, the cis-regions of dictyosomes are not consistently juxtaposed with mitochondria. These subcellular features, which are present in all examined genera in theCompsopogonales, Erythropeltidales, andRhodochaetales, along with certain unique reproductive characteristics, unify these three orders. During mitosis in uncorticated axial cells, a small, ring-shaped nucleus associated organelle (NAO) is located at each division pole, an intranuclear spindle comes to a moderately acute focus at the flattened, fenestrated metaphase-anaphase division poles and perinuclear ER partially encloses dividing nuclei, including a well-developed interzonal midpiece. The cleavage furrow penetrates the large, central vacuolar region to separate daughter nuclei. These cell division features most closely resemble the pattern described for the orderCeramiales. Our observations of vegetative and dividing cells ofC. coeruleus supplement the growing volume of evidence in favour of uniting all red algae into a single class without subclass designations.Abbreviations ER endoplasmic reticulum - IZM interzonal midpiece - MT microtubule - MTOC microtubule organizing center - NAO nucleus associated organelle - NE nuclear envelope - PER perinuclear endoplasmic reticulum     

Ultrastructure and histochemistry of the supportive structures associated with the radula of the slug,Limax maximus

The odontophore and connective tissue-filled portion of the radular sac (called the “collostyle”) of the slug, Limax maximus, were examined by light and electron microscopy. While both of these structures grossly resemble vertebrate cartilage, neither is composed of a type of tissue with the microscopic appearance and histochemical properties of cartilage. The roughly U-shaped odontophore possesses a thin capsule composed of connective tissue. The parenchyma of the odontophore consists of modified muscle cells which are organized into irregular groups by incomplete trabeculae composed of conventional muscle cells. The odontophoral cells are variable in size; they contain glycogen-filled “cores” as well as bundles of peripherally located filaments resembling myofilaments; and they are innervated like muscle cells. The nuclei of the cells are located eccentrically in the glycogen-filled portions of the cells and typically contain prominent nucleoli. The nuclei are surrounded by multiple small Golgi complexes and pleomorphic dense bodies resembling lysosomes. The extracellular matrix of the odontophore is very sparse and contains glycogen and fibrillar material but no histochemically demonstrable acidic mucosubstances. The collostyle consists of a gelatinous type of tissue somewhat like vertebrate mucoid connective tissue. The abundant extracellular matrix contains cross banded filaments, a flocculent material disposed in wavy indefinite strands, and small electron-dense particles. The matrix contains histochemically demonstrable neutral and weakly acidic mucosubstances. The cell population of the collostyle includes solitary muscle cells and fibrocytes containing large quantities of glycogen.     

The Plant Nucleoskeleton: Ultrastructural Organization and Identification of NuMA Homologues in the Nuclear Matrix and Mitotic Spindle of Plant Cells

In the present work we investigate the structural organization of the nucleoskeleton ofAllium cepameristematic root cells. Resinless sections reveal for the first time a residual filamentous network in plant nuclei. This network is composed of branched knobbed filaments with associated globular structures, connected to the lamina and to the dense aggregates of different sizes. Results of immunoblotting show that many components of this network are homologues of intermediate filament-type proteins. NuMA, a coiled-coil protein related to intermediate filaments, found in animal cells, can also be detected in this plant nuclear matrix system. Immunofluorescence reveals a diffuse distribution of the animal NuMA homologues in plant nuclear core filaments in interphase. Resinless immunoelectron microscopy further reveals a distribution along the extended filaments and the dense aggregates. During mitosis, in contrast to the accumulation at the poles in animal cells, NuMA homologues in plant onion cells show a diffuse pattern, which may correspond to the spindle matrix. Our data are the first report of the conservation in plants of NuMA proteins, which may be involved in both nuclear and mitotic spindle organizations.     

Organization of statocysts in the Otoplanidae (Plathelminthes): an ultrastructural analysis with implications for the phylogeny of the Proseriata

Summary The statocyst of otoplanids is enveloped by a bipartite capsule which consists of two different extracellular matrices. This capsule encircles three different types of aciliary cells: several peripherally located flattened parietal cells, one central statolith forming cell (lithocyte) and two clusters of accessory cells. Intracapsular lumina exist which are different from extracapsular intercellular spaces. The accessory cells most probably represent those structures that are mainly involved in nervous conduction. These cells extend cytoplasmatic processes towards different peripheral regions of the statocyst where processes of outer nerve cells penetrate the capsule. The statocyst does not seem to represent a more evolved equilibrium receptor system but may function as a relatively simple aciliary sense organ suitable for positive geotactic behaviour. The otoplanid statocyst corresponds to statocysts in other lithophorous proseriates but not to statocysts in other taxa of the free-living Plathelminthes. The monophyly of a taxon Lithophora within the Proseriata is corroborated by this autapomorphic characteristic.Abbreviations ac accessory cell(s) - c capsule of the statocyst - ce cerebrum - ci cephalic intestine - co capsule opening - cp cell process(es) of accessory cell(s) and cell(s) containing filaments - ecm extracellular matrix - fc cell(s) containing filaments - ic intercellular spaces within the capsule - mc muscle cell(s) - n lobed nucleus of the lithocyte - nac nucleus (nuclei) of accessory cell(s) - nc nerve cell(s) - npc nucleus (nuclei) of parietal cell(s) - pc parietal cell(s) - s statolith - sc statolith cell (lithocyte)     

Gill ultrastructure and symbiotic bacteria in Codakia orbicularis (Bivalvia,Lucinidae)

Summary The cellular organization of the gill, which harbors symbiotic bacteria, is described in juveniles and adults of Codakia orbicularis, a large tropical Lucinidae. The ciliary zone is similar in every species of Lucinidae described and includes the large clear cell which has been previously described as an intermediary cell. The intermediary zone is composed of a few narrow unciliated cells, which bind adjacent filaments together and constitute channels through which sea water circulates along the abfrontal part of the filaments. The lateral zone is more complex in C. orbicularis than in other Lucinidae, being composed of four cell types and differentiated into two distinct regions. The bacteriocytes and intercalary cells occupy the outermost bacteriocyte zone, while mucocytes and numerous cells crowded with proteinic, cystine-rich granules constitute the innermost secretory zone which has not been described in other species. The newly described granule cells are considered to be a key factor in the storage and metabolic conversion of sulfur compounds.     

Intermediate filament systems are collapsed onto the nuclear surface after isolation of nuclei from tissue culture cells

Standard procedures for the biochemical isolation and purification of tissue culture cell nuclei are very similar to recently described methods for the preparation of detergent-resistant cytoskeletons. But the latter in addition to extracted nuclei contain cytoplasmic filament systems. We, therefore, investigated the distribution of these filamentous systems during nuclear isolation both by immunofluorescence microscopy and by SDS-gel electrophoresis. The intermediate filaments copurify with each single isolated nucleus. The majority of the filaments is collapsed onto isolated nuclei and still constitutes a filamentous system. This can be shown by partially unfolding the collapsed filament systems.     

Reorganization of the system of intermediate filaments and detection of the organization centers after centrifugation of cells attached to a substrate

Cultured pig kidney epithelial cells were centrifuged at 20,000 gav so that the centrifugation force was oriented parallel to the substrate, fixed and processed for indirect immunofluorescent staining with tubulin and vimentin antibodies. After a 2 hour centrifugation vimentin filaments aggregated in the centripetal parts of the cells (probably, because of their association with floating lipid vesicles). Microtubule-organizing centers were found near the centripetal poles of the nuclei, which migrated in the direction of the centrifugal force. The distribution of the cytoplasmic microtubules did not change during centrifugation. The staining of the cultures one hour after centrifugation revealed vimentin-containing spots with radiating intermediate filaments in most of the cells. These spots were localized near the cell nuclei; double immunofluorescent staining with tubulin and vimentin antibodies showed that their position was identical to that of the microtubule-organizing centers. Similar foci of vimentin filaments were seen in the cells after a 3-4 hour centrifugation. Probably, these structures participate in organizing the intermediate filament cytoskeleton in cells.     

Characterization of a 65 kDa NIF in the nuclear matrix of the monocot Allium cepa that interacts with nuclear spectrin‐like proteins

Plant cells have a well organized nucleus and nuclear matrix, but lack orthologues of the main structural components of the metazoan nuclear matrix. Although data is limited, most plant nuclear structural proteins are coiled‐coil proteins, such as the NIFs (nuclear intermediate filaments) in Pisum sativum that cross‐react with anti‐intermediate filament and anti‐lamin antibodies, form filaments 6–12 nm in diameter in vitro, and may play the role of lamins. We have investigated the conservation and features of NIFs in a monocot species, Allium cepa, and compared them with onion lamin‐like proteins. Polyclonal antisera against the pea 65 kDa NIF were used in 1D and 2D Western blots, ICM (imunofluorescence confocal microscopy) and IEM (immunoelectron microscopy). Their presence in the nuclear matrix was analysed by differential extraction of nuclei, and their association with structural spectrin‐like proteins by co‐immunoprecipitation and co‐localization in ICM. NIF is a conserved structural component of the nucleus and its matrix in monocots with M_r and pI values similar to those of pea 65 kDa NIF, which localized to the nuclear envelope, perichromatin domains and foci, and to the nuclear matrix, interacting directly with structural nuclear spectrin‐like proteins. Its similarities with some of the proteins described as onion lamin‐like proteins suggest that they are highly related or perhaps the same proteins.     

A re-examination of the morphology, ultrastructure and classification of genera in the Lemaneaceae (Batrachospermales, Rhodophyta)

Vegetative and reproductive morphology and ultrastructure were examined for the three genera of the freshwater red algal family Lemaneaceae: Lemanea (two species, seven populations), Paralemanea (two species, three populations) and Psilosiphon (one species, one population). Psilosiphon is readily distinguished from the other two genera in having an outer cortex composed of well-defined filaments interconnected with a dense medulla (both cell types being little vacuolated), spores cleaving off obliquely, putative spermatangia scattered on the thallus surface and reproduction by adventitious filaments. Based on the distinctness of this genus (and corroborated by molecular phylogenies in preparation), a new family is described, the Psilosiphonaceae. Lemanea and Paralemanea appear to be closely related, with an outer cortex that has cells of increasing size and vacuolation from the periphery to the interior and not in obvious rows, a central lumen that contains few ray cells but no medullary filaments, sexual reproduction with spermatangia in distinct clusters, and carpospores in chains, some of which can germinate in the thallus lumen. Lemanea and Paralemanea have distinguishing characteristics that the other genus does not: for Lemanea, hair cells, ray cells abutting the outer cortex and spermatangia in patches; for Paralemanea, no hair cells or ray cells appressed to the outer cortex, inner cortical filaments surrounding the central axis and spermatangia in rings.     

Comparative morphology and systematics of Chondrymenia lobata from the Mediterranean Sea and a phylogeny of the Chondrymeniaceae fam. nov. (Rhodophyta) based on rbcL sequence analyses

The Chondrymeniaceae Rodríguez-Prieto, G. Sartoni, S.-M. Lin & Hommersand, fam. nov., is proposed for Chondrymenia lobata. Analyses of rbcL sequences place the new family in a large gigartinalean assemblage that comprises the Cystocloniaceae–Solieriaceae complex. Plants are decumbent and growth takes place by division of multiple apical cells at the margin of the blade. Thalli consist of an outer cortex of subspherical to elongate cortical cells arranged in anticlinal rows, a subcortex of cells cross-linked by lateral arms, and a large central medulla composed of primary medullary filaments intermixed with numerous rhizoidal filaments. Male stages are reported in monoecious individuals. Inactive carpogonial branches consist of a two-celled filament that is directed inwards from the supporting cell. Functional carpogonial branches are oriented outwardly, with the carpogonia and trichogynes pointed towards the thallus surface. After presumed fertilization, the carpogonium fuses with the hypogynous cell and transfers the zygote nucleus. The hypogynous cell, in turn, fuses with the supporting cell which contains many haploid nuclei. The resulting fusion cell functions as an auxiliary cell that cuts off a single gonimoblast initial, which produces the gonimoblast filaments. Gametophytic cells close to the auxiliary cell unite with it to form a placental fusion network of variable size and outline, and a placental fusion cell. Proximal gonimoblast cells fuse with the placental fusion cell, while the distal cells differentiate into branched chains of subspherical carposporangia. The superficial similarity of the outwardly developed osteolate cystocarp is responsible for Kylin's (1956) placement of Chondrymenia in his family Sarcodiaceae; however, the manner in which the placenta is formed is more like that seen in the Cystocloniaceae–Solieriaceae complex.     

Organization of the cytoskeleton in the coenocytic algaVaucheria longicaulis var.macounii: an experimental study

Summary The organization of the cytoskeleton of vegetative filaments ofVaucheria longicaulis Hoppaugh var.macounii Blum is investigated by fluorescence microscopy using monoclonal anti -tubulin antibodies and fluorescein (FITC)-labelled phalloidin. Confocal laser scanning microscopy observations give further information on the distribution of the cytoskeletal elements. Phalloidin labelling reveals F-actin bundles in the cortical cytoplasm of both fixed and unfixed vegetative filaments of this alga. In addition a more diffuse fluorescent component, seen at higher magnification to be made up of thinner F-actin bundles, can also be detected in unfixed cells. The distribution of the F-actin bundles resemble that of filamentous structures observed with differential interference contrast (DIC) microscopy in living cells. These structures seem to correspond to the microtubule associated reticulum (MAR) described in literature and overall the evidence suggests that actin and MAR elements are co-distributed. F-actin bundles are always found in association with focal masses (foci) of phalloidin-positive material. Foci are also observed by DIC microscopy associated with the cytoplasmic filamentous structures in living cells.Depolymerization of F-actin with cytochalasin D and the subsequent repolymerization that occurs on transfer ofVaucheria vegetative filaments to cytochalasin-free medium suggest that these foci are involved in the organization of the F-actin array. Immunofluorescence for -tubulin reveals microtubule bundles that are shorter in length and straighter in configuration than microfilament bundles. Microtubule bundles are associated with spot-like focal structures that, in many instances, show a close relationship with respect to nuclei. Oryzalin and cold temperature cause the depolymerization of the microtubule bundles and suggest, in conjunction with repolymerization studies, that these fluorescent spots associated with the ends of the microtubule bundles are involved in their organization; hence, they represent microtubule organizing centres or MTOCs. The importance of both microfilament and microtubule bundle focal regions is discussed with respect to the apical growth exhibited by the vegetative filaments of this alga.     

Organization of the nuclear pore complex in Saccharomyces cerevisiae

Fractions enriched for nuclear pore complexes (NPCs) have been isolated from Saccharomyces cerevisiae. The sequential extraction of nuclei with detergent, nucleases, and salt reveals an organization of the yeast NPC similar to other eukaryotes. Yeast NPCs contain a 30-nm “ring” structure not previously described in other organisms. This structure appears to organize 10-nm filaments into an assembly which exhibits an eight-fold rotational symmetry. Some proteins in the NPC fraction are capable of forming intermediate-sized filaments. These studies suggest that some component of the nuclear pore complex organizes an interaction between nuclear and cytoplasmic networks of intermediate filaments.     

Direct studies of nuclear movements in Schizophyllum commune

Summary Measurements of nuclear positions in apical cells of homokaryotic mycelia and dikaryotic mycelium of Schizophyllum commune showed that nuclei occupied a near central position in most cases. Forward nuclear movements observed in living hyphal apices occurred at rates within the range of hyphal growth and could account for the maintenance of centrally located nuclei. Opposed nuclear movements followed mitosis and greatly exceeded the rate of hyphal growth. Septum disruption and rapid nuclear movements characterized an A _xB_mut homokaryon. Neither cytoplasmic streaming nor actively participating granules or filaments could account for any of these nuclear movements.     

Involvement of microtubules and 10-nm filaments in the movement and positioning of nuclei in syncytia

Previous studies (Holmes, K.V., and P.W. Choppin. J. Exp. Med. 124:501- 520; J. Cell Biol. 39:526-543) showed that infection of baby hamster kidney (BHK21-F) cells with the parainfluenza virus SV5 causes extensive cell fusion, that nuclei migrate in the syncytial cytoplasm and align in tightly-packed rows, and that microtubules are involved in nuclear movement and alignment. The role of microtubules, 10-nm filaments, and actin-containing microfilaments in this process has been investigated by immunofluorescence microscopy using specific antisera, time-lapse cinematography, and electron microscopy. During cell fusion, micro tubules and 10-nm filaments from many cells form large bundles which are localized between rows of nuclei. No organized bundles of actin fibers were detected in these areas, although actin fibers were observed in regions away from the aligned nuclei. Although colchicine disrupts microtubules and inhibits nuclear movement, cytochalasin B (CB; 20-50 microgram/ml) does not inhibit cell fusion or nuclear movement. However, CB alters the shape of the syncytium, resulting in long filamentous processes extending from a central region. When these processes from neighboring cells make contact, fusion occurs, and nuclei migrate through the channels which are formed. Electron and immunofluorescence microscopy reveal bundles of microtubules and 10-nm filaments in parallel arrays within these processes, but no bundles of microfilaments were detected. The effect of CB on the structural integrity of microfilaments at this high concentration (20 microgram/ml) was demonstrated by the disappearance of filaments interacting with heavy meromyosin. Cycloheximide (20 microgram/ml) inhibits protein synthesis but does not affect cell fusion, the formation of microtubules and 10-nm filament bundles, or nuclear migration and alignment; thus, continued protein synthesis is not required. The association of microtubules and 10-nm filaments with nuclear migration and alignment suggests that microtubules and 10-nm filaments are two components in a system which serves both cytoskeletal and force-generating functions in intracellular movement and position of nuclei.     

CONTACT-INHIBITED REVERTANT CELL LINES ISOLATED FROM SV40-TRANSFORMED CELLS : II. Ultrastructural Study

The ultrastructural appearances of normal 3T3, SV40-transformed 3T3 (SV-3T3), and F1A revertant cell lines are compared. Both confluent and subconfluent cultures are described after in situ embedding of the cells for electron microscopy. There is striking nuclear pleomorphism in F1A revertant cells, with many cells having large nuclei compared to the less variable nuclear morphology of both normal 3T3 and SV-3T3 cells. Under the culture conditions used, deep infoldings of the nuclear envelope are prominent in growing cells, e.g., subconfluent normal 3T3 and confluent SV-3T3 cells. Such infoldings are infrequently seen in cultures which display contact inhibition of growth, e.g., normal 3T3 or F1A revertant cells grown just to confluence. In confluent cultures, the cytoplasmic organelles in revertant cells closely resemble those of normal 3T3 cells. In both normal and revertant cells in confluent culture, the peripheral cytoplasm (ectoplasm) has many 70 A filaments (alpha filaments), which are frequently aggregated into bundles. Alpha filaments are also abundant in the ectoplasm near regions of cell-to-cell apposition and in the motile cell processes (filopodia). The abundance and state of aggregation of alpha filaments correlates with contact inhibition of movement and growth in these cell lines since fewer bundles of alpha filaments are seen in growing cells than in contact-inhibited cells. This observation suggests that these filaments may be an important secondary component in the regulation of contact inhibition of movement and, possibly, of growth in normal and revertant cells.