FINE STRUCTURE STUDIES OF PHLEUM ROOT MERISTEM CELLS. II. MITOTIC ASYMMETRY AND CELLULAR DIFFERENTIATION

Avers , Charlotte J. (Douglass Coll., Rutgers—The State U., New Brunswick, N.J.) Fine structure studies of Phleum root meristem cells. II. Mitotic asymmetry and cellular differentiation. Amer. Jour. Bot. 50(2): 140–148. Illus. 1963.—An electron microscopical study showed that ultrastructural differences distinguished the cell dividing symmetrically from that undergoing asymmetrical division in timothy grass epidermis. The spindle orientation led to cytokinesis which produced either equal- or unequal-sized sister cells, but the mitotic apparatus itself varied in the mitoses. In asymmetrical cells, the basal pole showed more extensive endoplasmic reticulum (ER) polarizations, which intruded into the spindle area during metaphase and anaphase. Such ER polarity was not obvious in symmetrical mitosis or in the apical end of asymmetrically dividing cells. The mitotic sequence is described photographically. Foci of ER were observed as early as prophase in the polar region, and it is suggested that there is a resemblance to astral ray foci seen in prophase of animal cell mitosis. Cell plate formation could be detected in anaphase by accumulations of vesicles and ER fragments along the spindle equator. Phragmosomes apparently were not involved in cell plate formation in Phleum, unlike Allium, cytokinesis. The mitotic asymmetry is discussed as a consequence of an intracellular gradient separate from the intercellular gradient of differentiation along the entire length of growing root tip epidermis.     

纵胞藻切段再生的初步研究

作者将纵胞藻切成1.5—3mm长的切段,用PES培养液,室内漫射光进行培养,成功地得到大量纵胞藻再生植株。通过实验探讨,作者认为纵胞藻的切段再生现象可能是该种海藻营养繁殖的一种形式。     

DEVELOPMENTAL STUDY OF BRANCHED RHIZOPHORES IN THREE SELAGINELLA SPECIES

A morphogenetic investigation was made of the rhizophore of three large-sized tropical Selaginella species. The rhizophores of Selaginella delicatula, S. caudata, and S. plana arise exogenously at the points of branching of the main stems. In S. delicatula they are initiated at the junction of the second youngest branching. The rhizophore apical meristem has a tetrahedral apical cell and is capless. The rhizophores are usually three or four times dichotomously branched in S. delicatula and S. plana and four or five times in S. caudata. In S. delicatula, dichotomous branching of the rhizophore involves formation of two new apical cells subsequent to loss of an original apical cell. A pair of roots is formed endogenously from inner cells below the dermal layer at the apex of ultimate rhizophore branches. The finding that the rhizophore is an autonomously branched, leafless, and capless axis leads us to argue that Selaginella rhizophores, like lepidodendrid rhizomorphs, are fundamental axial organs that coordinate with the stem and root.     

Developmental anatomy of the shoot apical cell,rhizophore and root ofSelaginella uncinata

The developmental anatomy of the shoot apex, rhizophore and root ofSelaginella uncinata was examined by the semi-thin section method. The shoot apex has a single, lens-shaped apical cell with two cutting faces. Rhizophore primordia are initiated exogenously at the branching point of the second youngest lateral shoot. The rhizophore apex has a tetrahedral apical cell with three cutting faces. A pair of root primordia is initiated endogenously from inner cells of the rhizophore apex, after the rhizophore apical cell becomes unidentifiable losing its activity, and subsequently a root cap is formed from the distal face of the root apical cell. During the course of successive root branching the apical cell in an original root apical meristem becomes unidentifiable and then a new apical cell is initiated in each of the bifurcated root apical meristems. The root branching mode seems to be equivalent to the described dichotomous branching mode of fern shoots. Our results demonstrate a distinct morphogenetical difference between the rhizophore and the root, and confirm the exogenous origin of the rhizophore, as described for other species ofSelaginella. This evidence indicates that the rhizophore is not an aerial root but a leafless, root-producing axial organ.     

Head activator does not qualitatively alter head morphology in regenerates ofHydra oligactis

Summary The characterization of head activator (HA) as a morphogen capable of increasing the number of tentacles regenerated by hydra was re-examined. Gastric tissue was excised from HA-treated whole animals and allowed to regenerate. At the cellular level the differentiation of head-specific ectodermal epithelial cells was monitored by quantifying monoclonal antibody, CP8, labeling. This labeling has been correlated with a rise in head activation potential and the determination of tissue to form head structures (Javois et al. 1986). At the morphological level tentacle number was monitored. HA-treated regenerates began the head patterning processes and evaginated tentacles sooner than controls but did not produce extra tentacles. The kinetics of CP8 labeling did not reveal major differences between treated and control regenerates after the initiation of head-specific epithelial cell differentiation. HA appeared to act more like a growth factor stimulating the differentiation of head-specific cell types rather than a morphogen which altered head morphology. An additional aspect of the study examined axial-specific effects of HA on the initiation and extent of head-specific epithelial cell differentiation. The cellular response of ectodermal epithelial cells to HA was dependent on their original axial location. More CP8⁺ tissue differentiated in regenerates of apical as opposed to mid-gastric origin.     

A scanning electron microscopic study of differentiation of the digital pad in regenerating digits of the kenyan reed frog,Hyperolius viridiflavus ferniquei

Newly metamorphosed Kenyan reed frogs, Hyperolius viridiflavus ferniquei, are able to regenerate amputated digits. The terminal digital pad is also completely reformed. Differentiation of the regenerating digital pad was studied by scanning electron microscopy. External differentiation of the digital pad began late in the second postamputational week with the appearance of small patches of specialized epidermal cells on the ventral surface of the regenerating digit. The differentiation of the pad spread out radially until late in the fourth week, when its overall shape approximated that of the normal digital pad. The appearance of patches of digital pad epidermis on the ends of spike regenerates arising from the forearm was also confirmed.     

Immunohistochemical localization of a proto-cadherin fat tumour-suppressor homolog in the regenerating tail of lizard suggests a role in apical growth control

The present immunohistochemical and western blotting study evaluates the localization of a proto-cadherin which gene is overexpressed in the regenerating blastema of the lizard Podarcis muralis. Bioinformatic analysis suggests that the antibody recognizes FAT1/2 proteins. Western blot indicates a main band around 50 kDa, a likely fragment derived from the original membrane-bound large protein. Immunofluorescence shows main labelling in differentiating wound keratinocytes, lower in ependyma, mesenchyme and extracellular matrix of the blastema. The apical epidermal peg contains keratinocytes with labelled peripheral cytoplasm, as confirmed using ultrastructural immunogold that also reveals most labelling located along the cell surface of mesenchymal cells. Myoblasts and differentiating myotubes of regenerating muscles are less intensely labelled. The regenerating cartilaginous tube contains sparse labelled chondroblasts, especially in external and internal perichondria. In regenerating scales, differentiating beta-cells appear immunofluorescent mainly along the cell perimeter. In more differentiated muscle, cartilage and connective tissues of the new tail, the labelling lowers or disappears. The observations indicate that FAT1/2 proto-cadherins are present in the apical blastema where an intense remodelling takes place for the growth of the new tail but where also a tight control of cell division and migration is active and may regulate potential tumorigenic process.     

Asymmetric protoplast fusions between wild species and breeding lines of potato – effect of recipients and genome stability

 The objective of this study was to investigate if in asymmetric protoplast fusion experiments the ploidy of the recipient line (di-haploid and tetraploid) has an influence on the extent of the asymmetry of the regenerating fusion products. Nineteen different experiments with the wild species Solanum bulbocastanum and Solanum circaeifolium as donors (irradiated with 210 Gy) and different breeding lines (di-haploid and tetraploid) were carried out. The degree of genome elimination was determined by measuring the relative DNA content using flow cytometry. The data showed that the loss of DNA in hybrid plants was significantly higher for 4x, compared to 2x, plants as recipients. In addition, the stability of asymmetry in the fusion products was studied. For this purpose differences in asymmetry in individual shoots originating from the same callus were analysed. A large variation in the DNA content of individual shoots was detected. Of the 4x to 6x shoots 44% had the same DNA content as another shoot originating from the same callus, 19% had a DNA content between 4x and 6x but different from any other analysed shoot originating from the same callus, 2% were chimeras and 35% had a completely different DNA content (eutetraploid, euhexaploid, eupolyploid or asymmetric with a ploidy level above 6x). RFLP-analysis with single-copy probes of 12 regenerates from six calli (two regenerates per callus) confirmed the assumption that the different regenerates of one callus originate from the same single cell. The analysis of selected regenerates cultivated for a period of more than 1 year demonstrated that the genome of asymmetric regenerates might change during cultivation. Received: 30 April 1998 / Accepted: 24 July 1998     

Über den Verzweigungsvorgang beiPsilotum undSelaginella mit Anmerkungen zum Begriff der Dichotomie

After a critical evaluation of the concept of dichotomous branching in Cormophytes the shoot apical meristems ofPsilotum triquetrum andSelaginella speciosa are described. InPsilotum only the terminal meristems of the cryptophilic shoots have a three sided apical cell. Those of the photophilic shoots lack a typical apical cell.Selaginella has a two sided apical cell. The process of branching is independent from apical cells. It is due to an equal or unequal fractionation of the initial zone of the shoot apex which embraces all tissues above the leaf producing zone of the apical meristem.

Herrn Univ.-Prof. Dr.Walter Leinfellner zum 70. Geburtstag gewidmet.     

Differentiation-associated modulation of heparan sulfate structure and function in CaCo-2 colon carcinoma cells

Heparan sulfate species expressed by different cell and tissue types differ in their structural and functional properties. Limited information is available on differences in regulation of heparan sulfate biosynthesis within a single tissue or cell population under different conditions. We have approached this question by studying the effect of cell differentiation on the biosynthesis and function of heparan sulfate in human colon carcinoma cells (CaCo-2). These cells undergo spontaneous differentiation in culture when grown on semipermeable supports; the differentiated cells show phenotypic similarity to small intestine enterocytes. Metabolically labeled heparan sulfate was isolated from the apical and basolateral media from cultures of differentiated and undifferentiated cells. Compositional analysis of disaccharides, derived from the contiguous N-sulfated regions of heparan sulfate, indicated a greater proportion of 2-O- sulfated iduronic acid units and a smaller amount of 6-O-sulfated glucosamine units in differentiated than in undifferentiated cells. By contrast, the overall degree of sulfation, the chain length and the size distribution of the N-acetylated regions were similar regardless the differentiation status of the cells. The structural changes were found to affect the binding of heparan sulfate to the long isoform of platelet-derived growth factor A chain but not to fibroblast growth factor 2. These findings show that heparan sulfate structures change during cell differentiation and that heparan sulfate-growth factor interactions may be affected by such changes.      

Human B cell differentiation by Fc fragment. III. Effect of IL-1 and IL-2 on differentiation of human B lymphocytes induced by Fc fragments of human IgG

The human Fc fragment of IgG, when added to blood mononuclear cells in vitro, induces B cell differentiation after 6 days of culture. This activity requires the presence of T cells and monocytes. This work explores the roles of interleukin 1 (IL-1) and interleukin 2 (IL-2) in B cell differentiation induced by Fc fragments. Peripheral blood mononuclear cells (PBMC) from normal donors were examined for plasma cell differentiation following stimulation with Fc fragment (15 and 30 micrograms/ml) with or without IL-1 (6 U/ml) or IL-2 (2 U/ml). Results indicate that both IL-1 and IL-2 accelerated B cell differentiation by the Fc fragment to 3 days of culture, compared to 6 days required with the Fc fragment alone. The time required for differentiation was not further shortened when both IL-1 and IL-2 were present in culture; both IL-1 and IL-2 were able to partially induce B differentiation alone at 6 days of culture. The importance of IL-2 in B cell differentiation was further supported by the finding that antibodies specific for the IL-2 receptor blocked B cell differentiation induced by Fc fragments, with or without additional IL-1 or IL-2. The depletion of monocytes also blocked B cell differentiation and the requirement for monocytes could not be replaced by exogenous IL-1; however, Fc fragments were shown to induce monocytes to secrete IL-1 beta after 24 hr in culture. These results suggest that accelerated differentiation of B cells into plasma cells requires a double signal provided by Fc fragments and IL-1 or IL-2. Monocytes are necessary for Fc fragment-induced differentiation and cannot be replaced by either IL-1 or IL-2.     

Formative and proliferative cell divisions,cell differentiation,and developmental changes in the meristem of Azolla roots

The root of the water fern Azolla is a compact higher-plant organ, advantageous for studies of cell division, cell differentiation, and morphogenesis. The cell complement of A. filiculoides Lam. and A. pinnata R.Br. roots is described, and the lineages of the cell types, all derived ultimately from a tetrahedral apical cell, are characterised in terms of sites and planes of cell division within the formative zone, where the initial cells of the cell files are generated. Subsequent proliferation of the initial cells is highly specific, each cell type having its own programme of divisions prior to terminal differentiation. Both formative and proliferative divisions (but especially the former) occur in regular sequences. Two enantiomorphic forms of root develop, with the dispositions of certain types of cell correlating with the direction, dextrorse or sinistrorse, of the cell-division sequence in the apical cells. Root growth is determinate, the apical cell dividing about 55 times, and its cell-cycle duration decreasing from an initial 10 h to about 4 h during the major phase of root development. Sites of proliferation progress acropetally during aging, but do not penetrate into the zone of formative divisions. The detailed portrait of root development that was obtained is discussed with respect to genetic and epigenetic influences; quantal and non-quantal cell cycles; variation in cell-cycle durations; relationships between cell expansion and cell division: the role of the apical cell; and the limitation of the total number of mitotic cycles during root formation.     

Healing modes correlate with visuotectal pattern formation in regenerating embryonic Xenopus retina

After removal of the nasal or the temporal two-thirds of the embryonic (stage 32) eye, the remaining one-third sized fragment undergoes wound healing and then, in most cases, regenerates to form a new eye. Using gross anatomy and histology techniques, we categorized eye fragments into three healing mode categories over the first 24 hr after surgery (stage 37-38). Representative animals were reared through metamorphosis and their visuotectal projections were assayed using standard electrophysiology techniques. In the "rounded-up" healing mode, the cut edges of the fragment pinch to close the wound; retinal cell type layers (pigmented retinal epithelium (pre), photoreceptors, interneurons, ganglion cells) and a lens are present by 24 hr postsurgery. No extraneous or disorganized cells are present either internal or external to the fragments. These fragments regenerated to form normal projections 83% of the time and pattern duplicated projections only 17% of the time. In the "intermediate" healing mode, wound closure is not complete by 24 hr post surgery and groups of disorganized cells are present in the fragment and amassed between the healing cut edges. These fragments formed pattern duplicated projections 72% of the time. In the tongue healing mode, an ectopic mass of cells, contiguous with the main body of the fragment, forms a supernumerary retina in the region of the ablation. At 24 hr post surgery, the cells of the main body fragment form retinal layers; the cells of the tongue, excluding the presence of differentiated pre cells, remain undifferentiated, resembling ciliary margin. The cut edges of the main body fragment eventually fuse with the tongue to form a single eyeball. Tongue fragments formed pattern duplicated projections 100% of the time. In addition, pattern duplicated points derived from nasal fragments appeared most often in the posterior region of the tectum, the normal site of innervation of the nasal retina. This differed significantly from temporal fragment derived duplicated points which appeared more often in the front of the tectum, the normal site of innervation by temporal retina. Thus, the specificity of pattern duplicated innervation is related to the positional values remaining in the fragment after partial retinal ablation. The data indicate that cell movements during healing, whether overt as in the tongue healing mode, or remaining internal to the fragment as in the intermediate healing mode, are intimately correlated with pattern forming mechanisms which underlie pathological visuotectal duplication.     

Typology of ephemerid chloride cells

Summary The tracheal gills of 16 species of mayfly larvae were studied with regard to the chloride cells. The ephemerid chloride cells occur as two main types: single cells and cell complexes. The single chloride cells are characterized by deep tubular or slit-like infoldings of the apical cell membrane, whereas the chloride cell complexes show numerous intercellular channels resulting from cellular interdigitation at the basolateral side. According to the structural organization of the apices, the ephemerid chloride cells may be classified into caviform, coniform, bulbiform and filiform types. In the caviform type (single chloride cell), the apex retracts to form an apical cavity similar to teleost chloride cells. In the other types (chloride cell complexes), there is a progressive extension of the central cell apex into or beyond the cuticle in the form of cones, bulbs or filaments. The common feature of all types is the differentiation of the cuticle into thin porous plates or envelopes covering or surrounding the various forms of apices.Histochemical precipitation of sodium and chloride in the apical region suggests that all types have basically the same function of salt absorption. The population of the various types differs with the species. However, there seem to be some taxonomic regularities with respect to the families. No relation was found between the types of chloride cells and habitat of the species.Supported by the National Science Foundation.     

A head signal influences apical migration of interstitial cells in Hydra vulgaris

Although interstitial cells of hydra can migrate either apically or basally along the body column, there is a distinct bias toward apical cell accumulation. This apical bias could be produced by a local vectorial property of the tissue or it may be controlled by a more global property, such as a signal from the apical head region. The migration behavior of BrdU-labeled interstitial cells was examined in several types of grafts to distinguish between these two general types of migration control. Grafting BrdU-labeled midgastric region tissue into a host in either the normal or the reverse orientation had no effect on the apical bias, indicating that a local vectorial cue was probably not guiding cells apically. In grafts with heads or with feet at both ends of the body column, there was no directional bias in migration if the labeled tissue was equidistant from both ends. In the two-headed grafts, if the labeled tissue was closer to one end, there was a bias in the direction of the closer head. The results suggest that a graded signal emanating from the head creates the apical bias and may attract cells via chemotaxis. The apical bias is enhanced in decapitated animals regenerating a head, indicating that the attracting signal is present and is possibly stronger in regenerating heads. The signal for cell migration may be involved in a patterning process underlying head regeneration.     

THE ONTOGENY OF CARBONIFEROUS ARTICULATES: THE APEX OF SPHENOPHYLLUM

Twig apices of Sphenophyllum lescurianum, S. constrictum, and two new Sphenophyllum taxa are described in transverse and longitudinal section from middle and upper Pennsylvanian age specimens. In all of the species the single apical cell has the shape of a tetrahedron, with a triangular upper surface and three internal cutting faces. Segment cells are produced from each of the cutting surfaces in a dextrorse or sinistrorse direction, depending upon the species. The central portion of each segment cell contributes to the initiation of the procambium, while the remaining outer portion undergoes a vertical and subsequent horizontal division to form segment cells. Segment cells are aligned in vertical tiers beneath the respective apical cell cutting faces, with the individual leaves positioned directly beneath a tier of segment cells. Leaf primordia are first observed as a series of surface undulations below the apex, with an intercalary meristem located directly beneath each primordium. The vegetative apical organization of Sphenophyllum is demonstrated to be very similar to the type of organization found at the stem tips of Catamites and Equisetum.     

MORPHOLOGY AND MOLECULAR PHYLOGENY OF A NEW MARINE SAND‐DWELLING PROROCENTRUM SPECIES,P. TSAWWASSENENSE (DINOPHYCEAE,PROROCENTRALES), FROM BRITISH COLUMBIA,CANADA1

A new marine benthic, sand‐dwelling Prorocentrum species from the temperate region of the Pacific coast of British Columbia, Canada, is described using LM and EM and molecular phylogenetic analyses. The cells have a broad oval shape, 40.0–55.0 μm long and 30.0–47.5 μm wide, and a wide U‐shaped periflagellar area on the right thecal plate. The left thecal plate consists of a straighter apical outline in the form of a raised ridge. Five to six delicate apical spines in the center of the periflagellar area are present. The nucleus is located in the posterior region of the cell, and a conspicuous pusule is located in the anterior region of the cell. The cells have golden‐brown chloroplasts with a compound, intrachloroplast pyrenoid that lacks a starch sheath. The thecal plates are smooth with round pores of two different sizes. The larger pores are arranged in a specific pattern of radial rows that are evenly spaced around the plate periphery and of irregular rows (or double rows) that form an incomplete “V” at the apical end of the plates. Large pores are absent in the center of the left and right thecal plates. The intercalary band is striated transversely and also has faint horizontal striations. Trichocysts and two types of mucocysts are present. The molecular phylogenetic position of Prorocentrum tsawwassenense sp. nov. was inferred using SSU rDNA sequences. This new species branched with high support in a Prorocentrum clade containing both benthic and planktonic species.     

Cellular succession in the epithelium lining the pharyngeal cavity of planarians

Regardin cell renewal of planarian epithelial tissue, little is known at present except for the epidermis (Tyler, 1984). According to Skaer (1965), the definitive epidermal cells in planarian embryos originate in the parenchyma where they develop as precursor cells which then migrate into the epidermis. This process of development is also reported in regenerating planarians (Spiegelman & Dudley, 1973; Morita & Best, 1974; Hori, 1978). Recently the validity of Skaer's conclusion has clearly been confirmed by Ishii & Sakurai (1998) using SEM and TEM.The present study deals with the origin and renewal of cells of another epithelium — that lining the pharyngeal cavity of a freshwater planarian Dugesia japonica. This epithelium is known to consist of cells with secretory granduls of fingerprint-like structure (Ishii, 1966; Bowen & Ryder, 1973; Gamo & Garcia-Corrales, 1988; Asai, 1991). The characteristic feature of these specific granules, as well as epitheliosomes (Tyler, 1984) of the epidermis, is very useful as a cell marker for distinguishing cell types and following cell differentiation. Gamo & Garcia-Corrales (1988) claimed the cell populations of the pharyngeal epithelium of Dugesia gonocephala is morphologically and functionally heterogeneous. The sequence of morphological alteration offers the oppurtunity to distinguish at least three functional stages. These represent different adaptive forms of a single cell type, and indicate transformation from one to the next induced by cell renewal. It suggests a beta cell (noeblast) origin of the epithelial cells.In the present study SEM observations revealed theat there are morphologically three distinct cell types which are considered to be juvenile, mature, and senile cells respectively, judging from the differences in cells and the many transitional forms among them (Fig. 1). When observed by TEM, the cytoplasmic patterns of these cell types are correspondingly different from one another, similarly the surface specializations of the plasma membranes of each cell type which facilitate their identification by TEM also vary. Apparently alterations of cell morphology are involved in ageing in a single cell type. Morphological features of each cell type are summarized. Juveniles (R) rarely occur, are small cells provided with prominent apical ruffles and considered to be phagocytic because the cells often contain newly formed phagosomes. Mature cells (F) predominate, are large, polygonal, flat cells, presumably with an intense secretory activity. The cells contain many profiles of granular ER and a small number of specific (secretory) granules. Senile cells (M) are intermittently distributed, irregularly contoured cells with heavy surface microvilli. The specific granules are dense in the apical cytoplasm, and profiles of granular ER decease in number.The precursor epithial cells that are seen in the parenchyma exhibit a considerable degree of differentiation before their translocation into the lining. The primordial cells observed are neoblast-like, with several cohromatoid bodies and many free ribosomes (Morita et al., 1969). These results obtain thus support the evidence and prediction of Gamo & Garcia-Corrales (1988). The observed mode of cell replacement appears to be the same as found in the epidermis (Lentz, 1967).     

QUANTITATIVE STUDIES OF THE VEGETATIVE SHOOT APEX OF EQUISETUM SCIRPOIDES

Equisetum scirpoides Michx., propagated from a single clone, was grown in a controlled growth chamber at 24 ± 1 C under a photoperiod of 16 hr light/8 hr darkness. The apical cell of aerial vegetative shoots gives rise to derivatives (merophytes) in a helical sequence. Each newly formed merophyte divides anticlinally to form two superposed cells that are parallel to a lateral face of the apical cell. Radial longitudinal divisions then take place in the two superposed cells. Shoot tips were fixed every 2 hr for 24 hr to determine the mitotic index of the apical cell, six subjacent cells, and the remaining cells above the level of leaf initiation. Average mitotic indices for the 24-hr period were 3.9%, 3.9%, and 7.0%, respectively. The results indicate that the apical cell is quite active mitotically; there was no clear evidence of endopolyploidy in cells of the shoot apex, young leaves or in the developing cortex, based upon cytophotometric measurements of DNA content.