VALVE MORPHOGENESIS AND THE MICROTUBULE CENTER IN THREE SPECIES OF THE DIATOM NITZSCHIA1

The relationship of cell organelles to valve morphogenesis was investigated in three species of Nitzschia. One, N. sigmoidea (Nitzsch) W. Sm., showed consistent ability to generate both nitzschioid and hantzschioid symmetry in daughter cells following cytokinesis; the other two maintained nitzschioid symmetry stably. From previous work with Hantzschia, a certain sequence of events could be anticipated in the cytoplasm. In two significant areas–the behavior of the Microtubule Center (MC) and its microtubule (MT) system, and the central origin of the silicalemma–not only were the results unexpected, but the three species showed fundamental differences among themselves. In N. sigmoidea, the silicalemma (and the future raphe region) arises centrally on the cleavage furrow, and after some lateral expansion, the silicalemmas and their associated organelles move in opposite directions in daughter cells, so that the raphe and the raphe canals end up along the girdle side of the cell as expected. However, the MCs never become associated with their silicalemma, remaining throughout near the girdle bands. In N. sigma (Kütz) W. Sm., the silicalemmas arise centrally and after lateral growth, move in opposite directions to generate nitzschioid symmetry. In this case, the MCs move to the vicinity of but never close to the silicalemmas, and follow them distantly during their lateral movement. In N. tryblionella Hantzsch, the new silicalemmas arise opposite one another, on one side of the daughter cells; each MC soon moves very close to its silicalemma, and remains thus through most of valve morphogenesis. Later, only one silicalemma/MC complex moves laterally, establishing the nitzschioid symmetry in both daughter cells. In all three species, as in Hantzschia, linear arrays of mitochondria aligned along MTs occupy the forming raphe canal, and microfilaments line the outer edge of the expanding silicalemma. The fibulae (the wall struts arching across the raphe canal) in Hantzschia always grow from the valve surface to the girdle surface of the forming valves. In these three Nitzschiae, this invariably happens in only one daughter cell of any pair; in the other, all the fibulae grow from the girdle surface to the valve surface. An explanation of these variations is proposed: that the morphogenetic machinery of Nitzschia and Hantzschia have a common origin, with present Nitzschiae having undergone considerable diversification at the intracellular level, causing the unstable cell symmetry exhibited by several modern species. Perhaps a taxonomic distinction between Hantzschia and Nitzschia lies in whether the morphogenetic machinery associated with valve morphogenesis moves laterally in the same or in opposite directions.     

VALVE MORPHOGENESIS IN THE PENNATE DIATOM NAVICULA CUSPIDATA1

The deposition of siliceous valves during asexual reproduction of the pennate diatom, Navicula cuspidata Kütz., is described with emphasis on the cytoplasmic components involved. The events accompanying valve secretion are similar to those already known from other pennate species. After mitosis, the microtubule centre (MC) moves to the center of the cleavage furrow where silica deposition is initiated inside a tubular silicalemma, and it remains associated with the prospective central nodule during valve growth. Microtubules (MTs), emanating from the MC, run parallel to the prospective raphe and together with the raphe fibres, appear to be involved with raphe development. Multiple raphe fibres occupy the maturing raphe fissure, in contrast to the single fibre of Pinnularia viridis, P. maior and Hantzschia amphioxys. The fibers exhibit a periodic substructure and are often opposed to the silicalemma where they may inhibit silica deposition and control the shaping of the raphe fissure. In contrast with the above species, in N. cuspidata MTs are clustered strictly opposite the raphe and lose their association with the MC which degenerates before the valves are mature. The primary role of MTs may be the stabilization of the cytoplasmic region where initial silicification occurs. Mitochondria and endoplasmic reticulum are not involved in molding valve growth in this species. Evidence for vesicle involvement in silica transport and deposition was limited. The possible contributions provided by comparative studies on the ultrastructure of valve morphogenesis towards elucidating the control of valve formation and the taxonomy of diatoms are discussed briefly.     

Aspects of morphogenesis and function of diatom cell walls with implications for taxonomy

Summary Aspects of morphogenesis and morphology of diatom cell walls are reviewed to highlight functional correlations between wall structures and three-dimensional cytoplasmic activities during the cell cycle. Morphogenesis of the siliceous valve within the silica deposition vesicle is discussed in the light of the dependency on a precisely orchestrated moulding machinery, involving the cytoskeleton, mitochondria, endoplasmic reticulum, spacer vesicles produced by the Golgi apparatus, and the plasmalemma, in combination with adhesion of the cells to parts of the parental wall and localized plasmolyses. Sensitivity of morphogenetic events to fluctuations of external factors has implications for taxonomy.Abbreviations CF cleavage furrows - cPL cleavage plasmalemma - GB girdle bands - LP labiate process - LPA labiate process apparatus - MC microtubule center - mLP macro labiate process - MT microtubule - MTOC microtubules organizing center - PL plasmalemma - SDV silica deposition vesicle - SL SDV membrane - SpV spacer vesicles Dedicated to Professor Peter Sitte on the occasion of his 65th birthday     

VALVE MORPHOGENESIS IN THE PENNATE DIATOM ACHNANTHES COARCTATA

Mitosis and valve morphogenesis in the pennate diatom Achnanthes coarctata (Bréb. in W. Sm.) Grun. are described. After cytokinesis, both daughter nuclei and their microtubule centers (MCs) are found near one side of the cell. Each new tubular silica deposition vesicle (SDV) arises centrally, forming a single rib running the length of the cell. Each MC then migrates around its nucleus and positions itself directly adjacent to the new SDV. The enlarging silicalemmas with their associated MCs, nuclei, microtubules (MTs) and microfilaments (MFs) appear in mirror image in the daughter cells. Both SDVs soon generate a second longitudinal rib alongside the first; the gap between the ribs ultimately becomes the future raphe fissure. The MC, MTs and nucleus are associated with each fissure. However, the subsequent behavior of the valve secreting machinery now becomes quite different in the daughter cells. In the cell that will form a raphid valve, the silicalemma, flanked by MFs, expands laterally in both directions over the cleavage furrow. Within the expanding SDV, silica secretion continues, eventually generating the structure of the mature valve, and during this phase the raphe fissure becomes delineated as in other raphid diatoms. In the other daughter cell, however, the MC and its MTs withdraw from the silicalemma, and the SDV moves laterally across the cleavage furrow until the double rib is at the corner of the cell. As silica is secreted into this expanding SDV, the raphe fissure completely fills in. This valve, therefore, lacks a raphe when mature and has a symmetry quite different from that of the valve formed in the other daughter cell. These events are compared with the course of morphogenesis described for other raphid diatoms.     

VALVE MORPHOGENESIS IN SURIRELLA (BACILLARIOPHYCEAE)1

Valve morphogenesis in two Surirellae (S. ovalis Brebisson and S. robusta Ehrenberg) is described. Mitosis takes place at the broad end of the cell. After cleavage, a new Microtubule Center (MC) arises near each spindle pole and moves to the adjacent plasmalemma. Soon, a specific group of microtubules (MTs) extends from very near the MC around the periphery of the cell. Concurrently, the new tubular Silica Deposition Vesicle (SDV) grows around the periphery of the cell close to these MTs. A double rib of silica is rapidly formed inside the SDV; the space between the ribs becomes the raphe. Mitochondria line up along the MTs, and the SDV may be molded around these to create the canal raphe. Soon, the SDV expands in two directions to create the face and the mantle of the new valve. Meanwhile, each daughter nucleus, accompanied by the MC, moves to its interphase position at the center of the cell; this movement is colchicine-sensitive. As in several other pennate diatoms, an interruption in the raphe of the mature valve coincides with the initial position of the MC. The canal raphe thickens rapidly around the mitochondria; a rudimentary raphe fiber may be associated with the creation of a tiny curvature at the inner raphe fissure. As the SDV expands in the large S. robusta, the daughter cell protoplasts slowly shrink by plasmolysis, thereby creating the complex curved surface of the new valve surmounted by the arching canal raphes which are now quite rigid. In S. ovalis, the daughter cell protoplasts remain appressed and therefore the new valve surface is basically flat. The symmetry of Surirella is quite different from that of other pennate diatoms. However, the cytoplasmic events accompanying valve morphogenesis are similar in all important respects to those described in other raphid pennate diatoms, and clearly supports a naviculoid origin for this genus.     

Microtubule organization,mesophyll cell morphogenesis,and intercellular space formation inAdiantum capillus veneris leaflets

Summary Mesophyll cells (MCs) ofAdiantum capillus veneris are elongated and highly asymmetric, bearing several lateral branches and forming a meshwork resembling aerenchyma. Young MCs are polyhedral and display oppositely arranged walls and transverse cortical microtubules (Mts). Their morphogenesis is accomplished in three stages. At first they become cylindrical. Intercellular space (IS) canals, containing PAS-positive material, open through their junctions and expand laterally. During the second stage the cortical Mts form a reticulum of bundles, externally of which an identical reticulum of wall thickenings, containing bundles of parallel cellulose microfibrils, emerges. MCs do not grow in girth in the regions of wall thickenings, where constrictions form and new ISs open. Thus, MCs obtain a multi-lobed form. At the third morphogenetic stage MCs display a multi-axial growth. During this process, additional Mt rings are assembled at the base of cell lobes accompanied by similarly organized wall thickenings-cellulose microfibrils. Consequently, cell lobes elongate to form lateral branches, where MCs attach one another, while the IS labyrinth broadens considerably. Colchicine treatment, destroying Mts, inhibits MC morphogenesis and the concomitant IS expansion, but does not affect IS canal formation. These observations show that: (a) MC morphogenesis inA. capillus veneris is an impressive phenomenon accurately controlled by highly organized cortical Mt systems. (b) The disposition of Mt bundles between neighbouring MCs is highly coordinated, (c) The perinuclear cytoplasm does not appear to be involved in cortical Mt formation. Cortical sites seem to participate in Mt bundling, (d) Although extensive IS canals open before Mt bundling, the Mtdependent MC morphogenesis contributes in IS formation.Abbreviations EM electron microscopy - ER endoplasmic reticulum - IS intercellular space - MC mesophyll cell - MSB microtubule stabilizing buffer - Mt microtubule - PBS phosphate buffered saline     

OVERLOOKED HETEROPOLARITY IN SURIRELLA CF. FASTUOSA (BACILLARIOPHYTA) AND RELATIONSHIPS BETWEEN VALVE MORPHOGENESIS AND AUXOSPORE DEVELOPMENT

Surirella cf. fastuosa is an apparently isopolar elliptic marine raphid diatom. We observed cells before and after sexual reproduction in monoclonal cultures using light and scanning electron microscopy (LM and SEM). After sexual reproduction cells were approximately twice as large as before, in valve length and width. The stria and infundibula densities were stable during the life cycle. Subtle morphological differences were detectable between the two poles of the frustule. One pole (pole A) was characterized by endings of the external raphe fissure that turned toward the valve face, continuity of the domed wall of the raphe canal externally, an elliptic chamber visible internally, a shallow nick in the interior of the valvocopula. The other pole (pole B) was with the following: straight endings of the external raphe fissures, a dent in the domed wall of the raphe canal externally, a double chamber internally, presence of the open ends of the valvocopula nearby, a deep nick in the valvocopula. Furthermore, at pole A virgae developed at an early stage in morphogenesis, whereas at pole B they were not formed. In the auxospores, pole A was situated beneath the primary transverse perizonial band. Pole A is suggested to be homologous with the head pole in heteropolar Surirella and is the “protopole” likely equivalent to the central nodule in naviculoid taxa. Pole B is homologous with the foot pole in heteropolar Surirella and is the “synaptic pole” formed by fusion of components equivalent to both poles of naviculoid taxa.     

Early local differentiation of the cell wall matrix defines the contact sites in lobed mesophyll cells of Zea mays

Background and Aims

The morphogenesis of lobed mesophyll cells (MCs) is highly controlled and coupled with intercellular space formation. Cortical microtubule rings define the number and the position of MC isthmi. This work investigated early events of MC morphogenesis, especially the mechanism defining the position of contacts between MCs. The distributions of plasmodesmata, the hemicelluloses callose and (1 → 3,1 → 4)-β-d-glucans (MLGs) and the pectin epitopes recognized by the 2F4, JIM5, JIM7 and LM6 antibodies were studied in the cell walls of Zea mays MCs.

Methods

Matrix cell wall polysaccharides were immunolocalized in hand-made sections and in sections of material embedded in LR White resin. Callose was also localized using aniline blue in hand-made sections. Plasmodesmata distribution was examined by transmission electron microscopy.

Results

Before reorganization of the dispersed cortical microtubules into microtubule rings, particular bands of the longitudinal MC walls, where the MC contacts will form, locally differentiate by selective (1) deposition of callose and the pectin epitopes recognized by the 2F4, LM6, JIM5 and JIM7 antibodies, (2) degradation of MLGs and (3) formation of secondary plasmodesmata clusterings. This cell wall matrix differentiation persists in cell contacts of mature MCs. Simultaneously, the wall bands between those of future cell contacts differentiate with (1) deposition of local cell wall thickenings including cellulose microfibrils, (2) preferential presence of MLGs, (3) absence of callose and (4) transient presence of the pectins identified by the JIM5 and JIM7 antibodies. The wall areas between cell contacts expand determinately to form the cell isthmi and the cell lobes.

Conclusions

The morphogenesis of lobed MCs is characterized by the early patterned differentiation of two distinct cell wall subdomains, defining the sites of the future MC contacts and of the future MC isthmi respectively. This patterned cell wall differentiation precedes cortical microtubule reorganization and may define microtubule ring disposition.     

Structure and assembly of the cortical microtubule cytoskeleton in the green alga,Boodlea coacta

Summary Examination was made of the structure and assembly of the cortical microtubule (MT) cytoskeleton in the coenocytic green algaBoodlea coacta (Dickie) Murray et De Toni by immunofluorescence microscopy. Cortical MTs inBoodlea protoplasts are arranged randomly but some show a meridional arrangement within 6 h after protoplast formation. At 6–9 h such MTs become highly concentrated and parallel to each other in certain areas. At 12 h the concentration is uniformly high throughout the cell, indicating the completion of high density meridional arrangement of cortical MTs. Cortical MTs exhibiting a high density, meridional arrangement show characteristic disassembly by treatment with 10 M amiprophos-methyl (APM) or cold treatment (0 °C). Disassembly occurs by each MT unit at positions skipping 30–40 m in the transverse direction, and neighboring MTs subsequently disassemble to form MT groups. Each group becomes slender and then disappears completely within the following 24 h. The meridional arrangement of cortical MTs is disrupted by N-ethylmaleimide (NEM) accompanied by a remarkable reduction in density. The remaining MTs form groups at 30–40 m intervals from each other, as also occurs with drug or cold treatment, but disruption and density return to normal levels following removal of NEM. It appears that there are meridionally oriented channels, anchor-rich and anchor-poor, in the plasma membrane. The channels could be distributed alternately and anchors could be deposited in a cross-linking manner with cortical MTs to form a stable cortical MT-cytoskeleton. MTs comprising the cortical MT cytoskeleton could be oriented by meridionally oriented channels of anchors which are distributed following establishment of cell polarity.Abbreviations APM amiprophos-methyl - MT microtubule - MTOC microtubule organizing center - NEM N-ethylrnaleimide     

The microtubule cytoskeleton in developing cysts of the green algaAcetabularia: Involvement in cell wall differentiation

Summary Cysts of the green algaAcetabularia develop a unique lid structure to enable the release of gametes. This lid is separated from the rest of the thick cellulose cell wall by a circular fault line formed within the fibrillar texture of the wall. By immunofluorescence microscopy, we show that, prior to the first division of the single cyst nucleus, the radially symmetrical, perinuclear microtubule system which is a remnant carried over from previous developmental stages of cyst morphogenesis transforms into a circular microtubule band (CMB) around the nucleus. This band consisting of only a few bundled microtubules beneath the plasma membrane encircles the cyst nucleus at a distance of 75 to 100m. In a previous fine structural study, a lid-forming apparatus (LFA) was described as a circular band of rod-like structures in the plane of the plasma membrane, demarcating the contour of the future lid. Both the CMB and the LFA are superimposed on the rim of the lid. We therefore propose that the microtubule band is a component of the LFA identical with the rod-like structures. Formation of the CMB and, hence, lid formation are blocked by the microtubule-specific herbicide Oryzalin but not by the actin filament-disrupting inhibitor cytochalasin D. Upon recovery from Oryzalin treatment, the nuclei but not the prospective sites of the CMBs serve as nucleation centers, indicating that the CMB is not formed by a pre-existing template in the plasma membrane. This suggests that the dynamic behavior of the microtubules within the perinuclear microtubule cytoskeleton gives rise to the CMB. Since the stage of CMB assembly marks the beginning of cell wall formation, it is proposed that the CMB determines the position of the lid by spatially controlling cell wall deposition. On the basis of current hypotheses, two scenarios for the role of the LFA/CMB in lid formation are discussed.Abbreviations CMB circular microtubule band - EGTA ethylene glycol bis-(-aminoethyl ether) N,N,N,N-tetraacetic acid - FITC fluorescein isothiocyanate - LFA lid-forming-apparatus - MAP microtubule-associated protein - MT microtubule - MTOC microtubuleorganizing center Dedicated to the memory of Professor Oswald Kiermayer     

Interactions of Bovine Brain Tubulin with Pyridostigmine Bromide and N,N′-Diethyl-m-Toluamide

Pyridostigmine bromide (PB), an inhibitor of acetylcholinesterase, has been used as a prophylactic for nerve gas poisoning. N,N-diethyl-m-toluamide (DEET) is the active ingredient in most insect repellents and is thought to interact synergistically with PB. Since PB can inhibit the binding of organophosphates to tubulin and since organophosphates inhibit microtubule assembly, we decided to examine the effects of PB and DEET on microtubule assembly as well as their interactions with tubulin, the subunit protein of microtubules. We found that PB binds to tubulin with an apparent K _d of about 60 M. PB also inhibits microtubule assembly in vitro, although at higher concentrations PB induces formation of tubulin aggregates of high absorbance. Like PB, DEET is a weak inhibitor of microtubule assembly and also induces formation of tubulin aggregates. Many tubulin ligands stabilize the conformation of tubulin as measured by exposure of sulfhydryl groups and hydrophobic areas and stabilization of colchicine binding. PB appears to have very little effect on tubulin conformation, and DEET appears to have no effect. Neither compound interferes with colchicine binding to tubulin. Our results raise the possibility that PB and DEET may exert some of their effects in vivo by interfering with microtubule assembly or function, although high intracellular levels of these compounds would be required.     

Microtubules do not control orientation of secondary cell wall microfibril deposition inMicrasterias

Summary The influence of the microtubule disorganizing substances amiprophos-methyl (APM) and colchicine on secondary wall formation inMicrasterias denticulata was investigated by the freezeetch technique. The results reveal that neither microtubule inhibitor changes the pattern of microfibril deposition. The application of APM or colchicine also does not cause any structural alterations of the microfibrils or of the protoplasmic (Pf) and the exoplasmic (Ef) fracture face of the plasma membrane, thus indicating that microtubules are not involved in secondary wall formation inM. denticulata. However, since areas of the plasma membrane which collapsed upon freeze-etching are restricted to the Pf-face of cells treated with microtubule inhibitors, cortical microtubules may function as mechanical support during secondary wall formation. In the cortical cytoplasm filamentous structures are found in close spatial relationship and an almost parallel alignment to rosettes of the plasma membrane.     

A planar microtubule-organizing zone in guard cells of Allium: experimental depolymerization and reassembly of microtubules

The generation of the unique radial array of microtubules (MTs) in stomatal guard cells raises questions about the location and activities of relevant MT-organizing centers. By using tubulin immunofluorescence microscopy, we studied the pattern of depolymerization and reassembly of MTs in guard cells of Allium cepa L. Chilling at 0°C reduces the MTs to small remnants that surround the nuclear surface of cells in the early postcytokinetic stage, or form a dense layer along the central portion of the ventral wall in older guard cells. A rapid reassembly on rewarming restores either MTs extending from the nuclear surface randomly throughout the cytoplasm in very young cells, or an array of MTs radiating from the dense layer at the ventral wall later in development. A similar pattern of depolymerization and reassembly is achieved by incubation with 100 M colchicine followed by a brief irradiation with ultraviolet (UV) light. Incubation with 200 M colchicine leads to a complete depolymerization that leaves only a uniform, diffuse cytoplasmic fluorescence. Nonetheless, UV irradiation of developing guard cells induces the regeneration of a dense layer of MTs at the ventral wall. The layer is again positioned centrally along the wall, even if the nucleus has been displaced by centrifugation in the presence of cytochalasin D. Neither the regenerated layer nor the perinuclear MTs seen earlier are related to the staining pattern of serum 5051, which reportedly binds to centrosomal material in animal and plant cells. The results support the view that, soon after cytokinesis, a planar MT-organizing zone is established in the cortex along the central portion of the ventral wall, which then generates the radial MT array.Abbreviations GC guard cell - MT microtubule - MTOC microtubule-organizing center - UV ultraviolet To whom correspondence should be addressed.     

Metabolic inhibitors and mitosis: II. Effects of dinitrophenol/deoxyglucose and nocodazole on the microtubule cytoskeleton

Summary To examine the effects exerted on the microtubule (MT) cytoskeleton by dinitrophenol/deoxyglucose (DNP/DOG) and nocodazole, live PtK₁ cells were treated with the drugs and then fixed and examined by immunofluorescence staining and electronmicroscopy. DNP/DOG had little effect on interphase MTs. In mitotic cells, kinetochore and some astral fibers were clearly shortened in metaphase figures by DNP/DOG. Nocodazole rapidly broke down spindle MTs (except those in the midbody), while interphase cells showed considerable variation in the susceptibility of their MTs. Nocodazole had little effect on MTs in energy-depleted (DNP/DOG-treated) cells. When cytoplasmic MTs had all been broken down by prolonged nocodazole treatment and the cells then released from the nocodazole block into DNP/DOG, some MT reassembly occurred in the ATP-depleted state. MTs in permeabilized, extracted cells were also examined with antitubulin staining; the well-preserved interphase and mitotic arrays of MTs showed no susceptibility to nocodazole. In contrast, MTs suffered considerable breakdown by ATP, GTP and ATPS; AMPPNP had little effect. This susceptibility of extracted MT cytoskeleton to nucleotide phosphates was highly variable; some interphase cells lost all MTs, most were severely affected, but some retained extensive MT networks; mitotic spindles were diminished but structurally coherent and more stable than most interphase MT arrays.We suggest that: 1. in the living cell, ATP or nucleotide triphosphates (NTPs) are necessary for normal and nocodazole-induced MT disassembly; 2. the NTP requirement may be for phosphorylation; 3. shortening of kinetochore fibers may be modulated by compression and require ATP; 4. many of these results cannot be accomodated by the dynamic equilibrium theory of MT assembly/disassembly; 5. the use and role of ATP on isolated spindles may have to be reevaluated due to the effects ATP has on the spindle cytoskeleton of permeabilized cells.     

A combined morphological and molecular approach to Nitzschia varelae sp. nov., with discussion of symmetry in Bacillariaceae

A previously unknown member of the Bacillariaceae was discovered almost simultaneously in four different brackish coastal wetlands on the Atlantic and Mediterranean coasts of the Iberian Peninsula. It appears to tolerate a wide range of salinities but was never common in samples where it occurred. The frustules were consistently hantzschioid (i.e. with the raphe systems always on the same side of the frustule) and the valve outline was asymmetrical about the apical plane, two features that have until recently been considered characteristic of Hantzschia. Molecular phylogenies based on rbcL and LSU rDNA indicated, however, that the new species does not belong in Hantzschia but among the several disparate lineages that comprise the paraphyletic genus Nitzschia. This finding, coupled with the recent discovery of other diatoms with constant hantzschioid symmetry but with a morphology very similar to the type species of Nitzschia, is discussed in relation to the status and characterization of Hantzschia as an independent genus. It is concluded that, while a core of hantzschioid species may exist that can be classified together, corresponding to the traditional understanding of the genus Hantzschia, there is no single morphological feature common to all of them that can be used to diagnose the group and differentiate it from the various hantzschioid lineages that are separate from true Hantzschia and currently placed in e.g. Nitzschia or Cymbellonitzschia. Testing whether a hantzschioid species does or does not belong to Hantzschia will in many cases require molecular evidence. Although the new coastal species does not belong to the same lineage as the type species of Nitzschia, N. sigmoidea, it is described for the moment as N. varelae Carballeira, D.G. Mann & Trobajo, sp. nov., until there is a better understanding of generic limits in the Bacillariaceae following a wider molecular and morphological survey of that family.     

Effects of microtubule-inhibitors on nuclear migration and rhizoid differentiation in germinating fern spores (Onoclea sensibilis)

Summary Germinating spores of the sensitive fern,Onoclea sensibilis L., undergo premitotic nuclear migration before a highly asymmetric cell division partitions each spore into a large protonemal cell and a small rhizoid initial. Nuclear movement and subsequent rhizoid formation were inhibited by the microtubule (MT) inhibitors, colchicine, isopropyl-N-3-chlorophenyl carbamate (CIPC) and griseofulvin. Colchicine prevented polar nuclear movement and cell division so that spores developed into enlarged, uninucleate single cells. CIPC and griseofulvin prevented nuclear migration, but not cell division, so that spores divided into daughter cells of approximately equal size. In colchicine-treated spores, MT were not observed at any time during germination. CIPC prevented MT formation at a time coincident with nuclear movement in the control and caused a disorientation of the spindle MT. Both colchicine and CIPC appeared to act at a time prior to the onset of normal nuclear movement. The effects of colchicine were reversible but those of CIPC were not. Cytochalasin b had no effect upon nuclear movement or rhizoid differentiation. These results suggests that MT mediate nuclear movement and that a highly asymmetric cell division is essential for rhizoid differentiation.     

Possible involvement of membrane fluidity in helicoidal microfibrillar orientation in the coenocytic green alga,Boergesenia forbesii

Summary Microfibrillar textures and orientation of cellulose microfibrils (MFs) in the coenocytic green alga,Boergesenia forbesii, were investigated by fluorescence and electron microscopy. Newly formed aplanosporic spherical cells inBoergesenia start to form cellulose MFs on their surfaces after 2 h of culture at 25°C. Microfibrillar orientation becomes random, fountain-shaped, and helicoidal after 2, 4, and 5 h, respectively. The fountain orientation of MFs is usually apparent prior to helicoidal MF orientation and thus may be considered to initiate helicoid formation. Microfibrils continue to take on the helicoidal arrangement during the growth ofBoergesenia thallus. The helicoidal orientation of MFs occurs through gradual counterclockwise change in MF deposition by terminal complexes (TCs) viewed from inside the cell. On the dorsal side of curving TC impressions in helicoidal texture formation on a freeze-fractured plasma membrane, the aggregation of intramembranous particles (IMPs) occurs. Membrane flow may thus possibly affect the regulation of helicoidal orientation inBoergesenia. Following treatment with 3 M amiprophos-methyl (APM) or 1 mM colchicine, cortical microtubules (MTs) completely disappear within 24 h but helicoidal textures formation is not affected. With 15 M cytochalasin B or 30 M phalloidin, however, the helicoidal orientation of MFs becomes random. Treatment with CaCl₂ (10 mM) causes the helicoidal MF orientation of cells to become random, but co-treatment with N-(6-aminohexyl)-5-chloro-1-naphthalene sulfonamide (W-7) (100 mM) prevents this effect, though W-7 has no effect on the helicoidal MF formation. It thus follows that MF orientation inBoergesenia possibly involves actin whose action may be regulated by calmodulin.Abbreviations APM amiprophos-methyl - DMSO dimethylsulfoxide - IMP intramembranous particle - MF microfibril - MT microtubule - TC terminal complex; W-7 N-(6-aminohexyl)-5-chloro-1-naphthalene sulfonamide     

PHYLOGENETIC POSITION OF TOXARIUM,A PENNATE‐LIKE LINEAGE WITHIN CENTRIC DIATOMS (BACILLARIOPHYCEAE)1

The diatom genus Toxarium Bailey has been treated as a pennate because of its elongate shape and benthic lifestyle (it grows attached to solid substrata in the marine sublittoral). Yet its valve face lacks all structures that would ally it with the pennates, such as apical labiate processes, a midrib (sternum) subtending secondary ribs and rows of pores extending perpendicularly out from the midrib, or a raphe system. Instead, pores are scattered irregularly over the valve face and only form two distinct rows along the perimeter of the valve face. In our nuclear small subunit rDNA phylogenies, Toxarium groups with bi‐ and multipolar centrics, as sister to Lampriscus A. Schmidt. Thus, the genus acquired a pennate‐like shape and lifestyle independently from that of the true pennates. The two species known, T. hennedyanum Grunow and T. undulatum Bailey, differ only in a single feature: the valve perimeter of the former shows only a central expansion, whereas that of the latter possesses in addition a regular undulation. Yet both forms were observed in our monoclonal cultures, indicating that the two taxa represent extremes in a plasticity range. Toxarium resembles another elongate and supposedly araphid diatom, Ardissonea De Notaris, in being motile. Cells can move at speeds of up to 4 μm·s ^{? 1} 1 Received 7 June 2002. Accepted 4 October 2002. through secretion of mucilage from the cell poles or they remain stationary for longer periods, when they form short polysaccharide stalks. Division during longer periods of quiescence leads to the formation of small colonies of linked or radiating cells.     

The cytochrome P450 2D‐mediated formation of serotonin from 5‐methoxytryptamine in the brain in vivo: a microdialysis study

The cytochrome P450 2D (CYP2D) mediates synthesis of serotonin from 5‐methoxytryptamine (5‐MT), shown in vitro for cDNA‐expressed CYP2D‐isoforms and liver and brain microsomes. We aimed to demonstrate this synthesis in the brain in vivo. We measured serotonin tissue content in brain regions after 5‐MT injection into the raphe nuclei (Model‐A), and its extracellular concentration in rat frontal cortex and striatum using an in vivo microdialysis (Model‐B) in male Wistar rats. Naïve rats served as control animals. 5‐MT injection into the raphe nuclei of PCPA‐(tryptophan hydroxylase inhibitor)‐pretreated rats increased the tissue concentration of serotonin (from 40 to 90% of the control value, respectively, in the striatum), while the CYP2D inhibitor quinine diminished serotonin level in some brain structures of those animals (Model‐A). 5‐MT given locally through a microdialysis probe markedly increased extracellular serotonin concentration in the frontal cortex and striatum (to 800 and 1000% of the basal level, respectively) and changed dopamine concentration (Model‐B). Quinine alone had no effect on serotonin concentration; however, given jointly with 5‐MT, it prevented the 5‐MT‐induced increase in cortical serotonin in naïve rats and in striatal serotonin in PCPA‐treated animals. These results indicate that the CYP2D‐catalyzed alternative pathway of serotonin synthesis from 5‐MT is relevant in the brain in vivo, and set a new target for the action of psychotropics.