Getting into shape: epidermal morphogenesis in Caenorhabditis elegans embryos

The change in shape of the C. elegans embryo from an ovoid ball of cells into a worm-shaped larva is driven by three events within the cells of the hypodermis (epidermis): (1) intercalation of two rows of dorsal cells, (2) enclosure of the ventral surface by hypodermis, and (3) elongation of the embryo. While the behavior of the hypodermal cells involved in each of these processes differs dramatically, it is clear that F-actin and microtubules have essential functions in each of these processes, whereas contraction of actomyosin structures appears to be involved specifically in elongation. Molecular analysis of these processes is revealing components specific to C. elegans as well as components found in other systems. Since C. elegans hypodermal cells demonstrate dramatically different behaviors during intercalation, enclosure and elongation, the study of cytoskeletal dynamics in these processes may reveal both unique and conserved activities during distinct epithelial morphogenetic movements. BioEssays 23:12-23, 2001.     

Microtubules and Microfilaments in Amphibian Neurulation

In the salamander embryo, the morphogenetic movements of neurulationare correlated with two cell shape changes in the neural epithelium:elongation and apical constriction of the columnar neural platecells. Cells first elongate to form the flat open neural plateand then constrict apically as the plate rolls up to form theneural tube. Evidence is presented that these cell shape changesare intrinsic to the cells themselves and that they play a causalrole in the morphogenetic movements. Neural plate cells containnumerous microtubules oriented parallel to the axis of elongation.These microtubules are critical to the elongation process. Possiblemechanisms for microtubule function in cell elongation are considered.During apical constriction the cells contain bundles of microfilamentswhich encircle the cell apex in purse-string fashion. Evidenceis presented which suggests that microfilament bundles playan active role in apical constriction, and that this localizedcontraction is produced by filament sliding.     

Cell shape changes and the mechanism of inversion in Volvox

Inversion is a dominant aspect of morphogenesis in Volvox. In this process, the hollow, spheroidal Volvox embryo turns inside-out through a small opening called the phialopore to bring flagella from its inner to its outer surface. Analyses of intact, sectioned, and fragmented embryos by light, scanning electron, and transmission electron microscopy, suggest that shape changes preprogrammed into the cells cause inversion. First, cells throughout the embryo change from pear to spindle shape, which causes the embryo to contract and the phialopore to open. Then cells adjacent to the phialopore become flask-shaped, with long, thin stalks at their outer ends. Simultaneously, the cytoplasmic bridges joining all adjacent cells migrate from the midpoint of the cells to the stalk tips. Together, these changes cause the lips of cells at the phialopore margin to curl outward. Now cells progressively more distal to the phialopore become flask-shaped while the more proximal cells become columnar, causing the lips to curl progressively further over the surface of the embryo until the latter has turned completely inside-out. Fine structural analysis reveals a peripheral cytoskeleton of microtubules that is apparently involved in cellular elongation. Cell clusters isolated before inversion undergo a similar program of shape changes; this suggests that the changes in cellular shape are the cause rather than an effect of the inversion process.     

Alpha spectrin is essential for morphogenesis and body wall muscle formation in Caenorhabditis elegans

A common feature of multicellular animals is the ubiquitous presence of the spectrin cytoskeleton. Although discovered over 30 yr ago, the function of spectrin in non-erythrocytes has remained elusive. We have found that the spc-1 gene encodes the only alpha spectrin gene in the Caenorhabditis elegans genome. During embryogenesis, alpha spectrin localizes to the cell membrane in most if not all cells, starting at the first cell stage. Interestingly, this localization is dependent on beta spectrin but not beta(Heavy) spectrin. Furthermore, analysis of spc-1 mutants indicates that beta spectrin requires alpha spectrin to be stably recruited to the cell membrane. Animals lacking functional alpha spectrin fail to complete embryonic elongation and die just after hatching. These mutant animals have defects in the organization of the hypodermal apical actin cytoskeleton that is required for elongation. In addition, we find that the process of elongation is required for the proper differentiation of the body wall muscle. Specifically, when compared with myofilaments in wild-type animals the myofilaments of the body wall muscle in mutant animals are abnormally oriented relative to the longitudinal axis of the embryo, and the body wall muscle cells do not undergo normal cell shape changes.     

A Putative Catenin–Cadherin System Mediates Morphogenesis of the Caenorhabditis elegans Embryo

During morphogenesis of the Caenorhabditis elegans embryo, hypodermal (or epidermal) cells migrate to enclose the embryo in an epithelium and, subsequently, change shape coordinately to elongate the body (Priess, J.R., and D.I. Hirsh. 1986. Dev. Biol. 117:156– 173; Williams-Masson, E.M., A.N. Malik, and J. Hardin. 1997. Development [Camb.]. 124:2889–2901). We have isolated mutants defective in morphogenesis that identify three genes required for both cell migration during body enclosure and cell shape change during body elongation. Analyses of hmp-1, hmp-2, and hmr-1 mutants suggest that products of these genes anchor contractile actin filament bundles at the adherens junctions between hypodermal cells and, thereby, transmit the force of bundle contraction into cell shape change. The protein products of all three genes localize to hypodermal adherens junctions in embryos. The sequences of the predicted HMP-1, HMP-2, and HMR-1 proteins are related to the cell adhesion proteins α-catenin, β-catenin/Armadillo, and classical cadherin, respectively. This putative catenin–cadherin system is not essential for general cell adhesion in the C. elegans embryo, but rather mediates specific aspects of morphogenetic cell shape change and cytoskeletal organization.The morphology of the animal body and its tissues arise as embryonic cells change their shapes and/or positions (Mittenthal and Jacobson, 1990). Many of these changes are mediated by dynamic rearrangements of cytoskeletal components (Wessells et al., 1971). Cells can organize diverse patterns of microtubules and actin filaments, and movement of actin filaments by myosin proteins is thought to generate the force that drives many morphogenetic processes. An important step toward understanding the mechanical basis of morphogenesis is the identification and characterization of molecules that pattern the cytoskeleton and translate force into concerted cell movements. For cells to change shape coordinately or move relative to each other, forces generated within an individual cell must be transmitted to adhesive junctions at the plasma membrane and exerted on neighboring cells or the extracellular matrix (Gumbiner, 1996). The best characterized cell–cell junction is the adherens junction. This type of junction usually forms a subapical, beltlike structure that mechanically links the lateral surfaces of adjacent epithelial cells. Adherens junctions contain transmembrane proteins of the cadherin family that mediate homotypic adhesion. Cadherins are thought to connect to the actin cytoskeleton indirectly through the proteins α-catenin and β-catenin. Catenin–cadherin complexes also are associated with sites of contact between blastomeres in vertebrate and invertebrate embryos. In Drosophila, mice, and Xenopus, gene inactivation of catenins or cadherins disrupts general cell adhesion and apicobasal polarity of blastomeres and epithelial cells (Heasman et al., 1994; Larue et al., 1994; Haegel et al., 1995; Cox et al., 1996; Müller and Wieschaus, 1996; Kafron et al., 1997; Torres et al., 1997). Thus, it has been difficult to define direct requirements for these proteins in cytoskeletal organization and morphogenesis, although there is evidence for specific roles in tracheal cell migration (Tanaka-Matakatsu et al., 1996) and axon outgrowth (Iwai et al., 1997) in Drosophila.The Caenorhabditis elegans embryo provides a model system for studying how cells move and change shape to generate body and tissue morphologies. At hatching, the outermost cellular layer of the body consists of a monolayer of 85 epithelial cells called hypodermal cells that are linked together by adherens junctions (White, 1988). During embryogenesis, hypodermal cells are involved in two distinct processes that transform the initially ellipsoidal mass of embryonic cells into a long, thin worm; these processes are called body enclosure and body elongation (Sulston et al., 1983; Priess and Hirsh, 1986; Williams-Masson et al., 1997). The hypodermal cells are born on the dorsal surface of the embryo. As the hypodermal cells develop adherens junction connections, they begin to spread as a sheet across the embryo until the contralateral edges of the sheet meet at the ventral midline. In the anterior of the embryo, ventral hypodermal cells on the periphery of the spreading sheet develop filopodial extensions that may function to draw the contralateral edges of the sheet together (Williams-Masson et al., 1997). In the posterior of the embryo, the contralateral edges appear to be drawn together by a purse-string–like contraction that completes the enclosure process (Williams-Masson et al., 1997). In several respects, these processes are similar to epithelial cell movements described in a variety of systems, such as wound healing in vertebrates (Martin and Lewis, 1992) and dorsal closure in Drosophila (Young et al., 1993). At the completion of body enclosure in C. elegans, the apical surfaces of the hypodermal cells resemble rectangles that are elongated along the circumferential contour of the embryo''s body. These apical surfaces begin to change shape, constricting along the circumferential contour of the body and elongating along the anterior–posterior (longitudinal) axis. The coordinate changes in the shapes of the hypodermal cells appear to cause the body to decrease in circumference and to elongate about fourfold along its longitudinal axis (Sulston et al., 1983; Priess and Hirsh, 1986). Before body elongation, the apical cytoskeleton of each hypodermal cell reorganizes to form an array of parallel actin filament bundles oriented along the circumferential contour of the body (Priess and Hirsh, 1986; Costa et al., 1997). The parallel filament bundles bridge two opposing sides of each hypodermal cell, apparently connecting to the subapical adherens junction. Contraction of the filament bundles has been proposed as the force that elongates the embryo; the bundles become shorter and thicker during elongation, and drugs that disrupt actin filament organization prevent elongation. Apical constriction of cells has been shown in other systems to drive the invagination of epithelial sheets; because of the closed, cylindrical geometry of the hypodermal sheet in C. elegans, an analogous apical constriction might instead drive body elongation (Priess and Hirsh, 1986). Although the morphology and properties of the hypodermal cells strongly suggest that they mediate body elongation, almost all of the elongation-defective mutants described thus far have mutations in genes encoding muscle or basement membrane components. Body-wall muscles underlie the hypodermis, separated by a basement membrane (Hresko et al., 1994; diagram in Fig. ​Fig.88 a). Mutations in any of several genes that eliminate embryonic muscle contraction prevent elongation beyond a twofold increase in body length; this phenotype is called Pat¹ (paralyzed, arrested elongation at twofold; Williams and Waterston, 1994). Some of the genes of the Pat class have been shown to encode muscle-specific proteins. Because the muscles and myofilaments are oriented longitudinally, muscle contraction would be expected to oppose body elongation; thus, it is not yet understood why muscle function is required for complete elongation. The genes let-2 and emb-9 encode basement membrane collagens, and mutations in these genes produce elongation defects similar to those of Pat mutants (Guo et al., 1991; Sibley et al., 1993; Williams and Waterston, 1994). The only gene identified that is both required for proper body elongation and apparently expressed in hypodermal cells is let-502 (Wissmann et al., 1997). The predicted LET-502 protein is related to Rho-binding kinases, which can activate myosin light chain kinase, suggesting that LET-502 could have a role in hypodermal cells for the contraction of the array of actin filament bundles. Open in a separate windowFigure 8Models of morphogenetic forces and molecular organization at hypodermal cell junctions. (A) Oblique view of a schematic cross-section of an embryo after fusion of the dorsal hypodermal cells. CFBs are shown as thin lines, and adherens junctions are shown as thick lines. Bands of longitudinally oriented body wall muscles (m) are shown underlying the hypodermal cells. (B) Mechanical model of forces between the dorsal hypodermis and a lateral hypodermal cell. The connection between each CFB and the adherens junction (AJ) is represented as an open circle. In the lateral hypodermal cell, the connections are pulled downward by contraction of the CFBs within the lateral cell itself and pulled upward as CFBs in the dorsal cell contract. Note that the adherens junction at the two ends of the lateral cell (shown as two springs) are oriented such that they could dissipate some of the force exerted by contractions in the dorsal cell. (C) Two molecular models for the linkage between a filament (CF) in a CFB to a filament (AJF) in the adherens junction. HMR-1 is shown at the membrane contacts between two cells and associated with HMP-2. In the top cell, HMP-1 links a CF and an AJF directly; in the bottom cell, HMP-1 links different AJFs together while another factor (X) provides the link between the AJFs and CFs. To expand our understanding of the molecular basis for morphogenesis, we have isolated and characterized a group of mutants that display similar defects in embryo morphogenesis. In this paper, we present evidence that a C. elegans catenin–cadherin system mediates morphogenetic cell shape changes and specific aspects of cytoskeletal organization. We show that the genes hmp-1, hmp-2, and hmr-1 are required for the proper migration of hypodermal cells during body enclosure and for body elongation. We demonstrate that hmp-1, hmp-2, and hmr-1 can encode proteins related to α-catenin, β-catenin, and cadherin, respectively. We show that the protein products of these genes are localized to adherens junctions in the hypodermis. Our results indicate that these proteins anchor the parallel actin filament bundles to the adherens junctions in hypodermal cells and that this coupling translates the force of bundle contraction into cell shape change.     

Mutations in the FASS gene uncouple pattern formation and morphogenesis in Arabidopsis development.

The pattern of cell division is very regular in Arabidopsis embryogenesis, enabling seedling structures to be traced back to groups of cells in the early embryo. Recessive mutations in the FASS gene alter the pattern of cell division from the zygote, without interfering with embryonic pattern formation: although no primordia of seedling structures can be recognised by morphological criteria at the early-heart stage, all elements of the body pattern are differentiated in the seedling. fass seedlings are strongly compressed in the apical-basal axis and enlarged circumferentially, notably in the hypocotyl. Depending on the width of the hypocotyl, fass seedlings may have up to three supernumerary cotyledons. fass mutants can develop into tiny adult plants with all parts, including floral organs, strongly compressed in their longitudinal axis. At the cellular level, fass mutations affect cell elongation and orientation of cell walls but do not interfere with cell polarity as evidenced by the unequal division of the zygote. The results suggest that the FASS gene is required for morphogenesis, i.e., oriented cell divisions and position-dependent cell shape changes generating body shape, but not for cell polarity which seems essential for pattern formation.     

pix-1 Controls Early Elongation in Parallel with mel-11 and let-502 in Caenorhabditis elegans

Cell shape changes are crucial for metazoan development. During Caenorhabditis elegans embryogenesis, epidermal cell shape changes transform ovoid embryos into vermiform larvae. This process is divided into two phases: early and late elongation. Early elongation involves the contraction of filamentous actin bundles by phosphorylated non-muscle myosin in a subset of epidermal (hypodermal) cells. The genes controlling early elongation are associated with two parallel pathways. The first one involves the rho-1/RHOA-specific effector let-502/Rho-kinase and mel-11/myosin phosphatase regulatory subunit. The second pathway involves the CDC42/RAC-specific effector pak-1. Late elongation is driven by mechanotransduction in ventral and dorsal hypodermal cells in response to body-wall muscle contractions, and involves the CDC42/RAC-specific Guanine-nucleotide Exchange Factor (GEF) pix-1, the GTPase ced-10/RAC and pak-1.In this study, pix-1 is shown to control early elongation in parallel with let-502/mel-11, as previously shown for pak-1. We show that pix-1, pak-1 and let-502 control the rate of elongation, and the antero-posterior morphology of the embryos. In particular, pix-1 and pak-1 are shown to control head, but not tail width, while let-502 controls both head and tail width. This suggests that let-502 function is required throughout the antero-posterior axis of the embryo during early elongation, while pix-1/pak-1 function may be mostly required in the anterior part of the embryo. Supporting this hypothesis we show that low pix-1 expression level in the dorsal-posterior hypodermal cells is required to ensure high elongation rate during early elongation.     

Structure and function of the microtubular cytoskeleton during megasporogenesis and embryo sac development in Gasteria verrucosa (Mill.) H. Duval

Summary Using immunocytochemical techniques, tubulin distribution in various stages of meiosis and embryo sac development was studied. In the archespore cell some microtubules appeared to be randomly oriented. During zygotene and pachytene, when the cell volume increases, a large number of microtubules in dispersed configurations and bundles were observed. During this stage the nucellar cells divide, and their parallel cortical microtubules play an important role in preparing the direction of cell enlargement. The protoderm cells show anticlinal-directed cortical microtubules. It can be concluded that the enlargement of the meiocyte during these early meiotic stages is influenced both by its own cytoskeleton and by growth of the nucellus. Thereafter, the microtubules function directly in meiosis and disappear for the greater part until the two-nucleate coenocyte is formed. In a four-nucleate coenocyte microtubules reappear around the nucleus; in a young synergid, randomly oriented microtubules are involved in cell shaping during the formation of the filiform apparatus; in the synergids of the mature embryo sac, many parallel arrays of microtubules are present. Microtubules are less abundant in other cells. It is concluded that the cytomorphogenesis of the developing coenocyte and embryo sac are due to cell growth of the nucellar cells together with vacuolation of the coenocyte.     

Differential regulation of cellulose orientation at the inner and outer face of epidermal cells in the Arabidopsis hypocotyl

It is generally believed that cell elongation is regulated by cortical microtubules, which guide the movement of cellulose synthase complexes as they secrete cellulose microfibrils into the periplasmic space. Transversely oriented microtubules are predicted to direct the deposition of a parallel array of microfibrils, thus generating a mechanically anisotropic cell wall that will favor elongation and prevent radial swelling. Thus far, support for this model has been most convincingly demonstrated in filamentous algae. We found that in etiolated Arabidopsis thaliana hypocotyls, microtubules and cellulose synthase trajectories are transversely oriented on the outer surface of the epidermis for only a short period during growth and that anisotropic growth continues after this transverse organization is lost. Our data support previous findings that the outer epidermal wall is polylamellate in structure, with little or no anisotropy. By contrast, we observed perfectly transverse microtubules and microfibrils at the inner face of the epidermis during all stages of cell expansion. Experimental perturbation of cortical microtubule organization preferentially at the inner face led to increased radial swelling. Our study highlights the previously underestimated complexity of cortical microtubule organization in the shoot epidermis and underscores a role for the inner tissues in the regulation of growth anisotropy.     

The Mup-4 Locus in Caenorhabditis Elegans Is Essential for Hypodermal Integrity, Organismal Morphogenesis and Embryonic Body Wall Muscle Position

mup-4 is a member of a set of genes essential for correct embryonic body wall muscle cell positions in Caenorhabditis elegans. The mup-4 phenotype is variably expressed and three discrete arrest phenotypes arise during the phase of embryonic development when the worm elongates from a ball of cells to its worm shape (organismal morphogenesis). Mutants representing two of the phenotypic classes arrest without successful completion of elongation. Mutants of the third phenotypic class arrest after completion of elongation. Mutants that arrest after elongation display profound dorsal and ventral body wall muscle cell position abnormalities and a characteristic kinked body shape (the Mup phenotype) due to the muscle cell position abnormalities. Significantly, genetic mosaic analysis of mup-4 mutants demonstrates that mup-4 gene function is essential in the AB lineage, which generates most of the hypodermis (epidermis), a tissue with which muscle interacts. Consistent with the genetic mosaic data, phenotypic characterizations reveal that mutants have defects in hypodermal integrity and morphology. Our analyses support the conclusion that mup-4 is essential for hypodermal function and that this function is necessary for organismal morphogenesis and for the maintenance of body wall muscle position.     

Time-lapse video microscopy analysis reveals astral microtubule detachment in the yeast spindle pole mutant cnm67

Saccharomyces cerevisiae cnm67Delta cells lack the spindle pole body (SPB) outer plaque, the main attachment site for astral (cytoplasmic) microtubules, leading to frequent nuclear segregation failure. We monitored dynamics of green fluorescent protein-labeled nuclei and microtubules over several cell cycles. Early nuclear migration steps such as nuclear positioning and spindle orientation were slightly affected, but late phases such as rapid oscillations and insertion of the anaphase nucleus into the bud neck were mostly absent. Analyzes of microtubule dynamics revealed normal behavior of the nuclear spindle but frequent detachment of astral microtubules after SPB separation. Concomitantly, Spc72 protein, the cytoplasmic anchor for the gamma-tubulin complex, was partially lost from the SPB region with dynamics similar to those observed for microtubules. We postulate that in cnm67Delta cells Spc72-gamma-tubulin complex-capped astral microtubules are released from the half-bridge upon SPB separation but fail to be anchored to the cytoplasmic side of the SPB because of the absence of an outer plaque. However, successful nuclear segregation in cnm67Delta cells can still be achieved by elongation forces of spindles that were correctly oriented before astral microtubule detachment by action of Kip3/Kar3 motors. Interestingly, the first nuclear segregation in newborn diploid cells never fails, even though astral microtubule detachment occurs.     

Shaping of the sperm nucleus in Marsilea: A distinction between factors responsible for shape generation and shape determination

Spermiogenesis in Marsilea vestita involves the elongation of a roughly spherical nucleus into a spiral that is composed of four to five gyres. A ribbon of microtubules is associated with the outer edge of the nucleus throughout the shaping process. In order to observe nuclear morphogenesis in the absence of microtubules, developing microspores were treated with drugs that are known to affect microtubule assembly. Spermatids cultured in the presence of colchicine from the beginning of spermiogenesis do not form a microtubule ribbon. The nuclei of these cells change from a spherical to an irregular shape with elongate branches or loops. The normal spiral nucleus and elongate rod of condensed chromatin are not formed and the pattern of chromatin condensation is also abnormal. These observations indicate that in Marsilea microtubules do not provide the mechanical force for nuclear shape generation. Bulk chromatin condensation can also be eliminated as the force behind nuclear shaping, because during normal development the chromatin condenses only after nuclear shaping is well advanced. We suggest that a force-generating system is located near or is a part of the nuclear envelope. Microtubules may, however, be important in the determination of the final shape of the nucleus either by organizing or directing the force-generating system or by externally restricting or guiding the shaping nucleus. Microtubules may also function in controlling the pattern of chromatin condensation.     

Patterns of actin filaments during cell shaping in developing mesophyll of wheat (Triticum aestivum L.).

Young leaves of wheat exhibit a smooth developmental gradient with meristematic cells at the base and highly differentiated cells at the tip. During differentiation, mesophyll cells attain a lobed outline resembling tube-shaped balloons with almost regularly spaced isthmi. Microfilament patterns in developing wheat mesophyll cells were investigated using fluorescent-labeled phalloidin. Various patterns were found, including delicate arrays of transversely oriented microfilaments in the cortex of the cytoplasm. A close correlation between changes in the patterns of cortical microfilaments, microtubules, cell wall microfibrils, and cell shape was observed. The fine arrays of transversely oriented microfilaments coaligned with bands of microtubules occurring during cell elongation. These bands were found beneath sites of intense wall deposition. It has recently been proposed that the resulting hoops of wall reinforcement prevent cell expansion in the corresponding regions and thus give rise to the peculiar cell shape. When cell expansion ceased, and the typical lobed cell shape was attained, a dense network of microfilaments was retained in the cytoplasm, which was in contrast to what has been described for the microtubular arrays.     

Inner cell allocation in the mouse morula: the role of oriented division during fourth cleavage

Two populations of blastomeres become positionally distinct during fourth cleavage in the mouse embryo; the inner cells become enclosed within the embryo and the outer cells form the enclosing layer. The segregation of these two cell populations is important for later development, because it represents the initial step in the divergence of placental and fetal lineages. The mechanism by which the inner cells become allocated has been thought to involve the oriented division of polarized 8-cell blastomeres, but this has never been examined in the intact embryo. By using the technique of time-lapse cinemicrography, we have been able for the first time to directly examine the division planes of 8-cell blastomeres during fourth cleavage, and find that there are three, rather than two, major division plane orientations; anticlinal (perpendicular to the outer surface of the blastomere), periclinal (parallel to the outer surface of the blastomere), and oblique (at an angle between the other two). The observed frequencies of each type of division plane orientation provide evidence that the inner cells of the morula must derive from oriented division of 8-cell blastomeres, in accordance with the polarization hypothesis. Analysis of fourth cleavage division plane orientation with respect to either lineage or division order reveals that it is not associated with lineage from either the 2- or the 4-cell stage, but has a slight statistical association with fourth cleavage division order. The lack of association between division plane orientation and lineage supports the prediction that packing patterns and intercellular interactions within the 8-cell embryo during compaction play a role in determining fourth cleavage division plane orientation and thus, the positional fate of the daughter 16-cell blastomeres.     

Analysis of the role of microfilaments and microtubules in acquisition of bipolarity and elongation of fibroblasts in hydrated collagen gels

Fibroblasts in situ reside within a collagenous stroma and are elongate and bipolar in shape. If isolated and grown on glass, they change from elongate to flat shape, lose filopodia, and acquire ruffles. This shape change can be reversed to resemble that in situ by suspending the cells in hydrated collagen gels. In this study of embryonic avian corneal fibroblasts grown in collagen gels, we describe for the first time the steps in the acquisition of the elongate shape and analyze the effect of cytoskeleton-disrupting drugs on filopodial activity, assumption of bipolarity, and cell elongation within extracellular matrix. We have previously shown by immunofluorescence that filopodia contain actin but not myosin and are free of organelles. The cell cortex is rich in actin and the cytosol, in myosin. By using antitubulin, we show in the present study that microtubules are aligned along the long axis of the bipolar cell body. The first step in assumption of the elongate shape is extension of filopodia by the round cells suspended in collagen, and this is not significantly affected by the drugs we used: taxol to stabilize microtubules; nocodazole to disassemble microtubules; and cytochalasin D to disrupt microfilaments. The second step, movement of filopodia to opposite ends of the cell, is disrupted by cytochalasin, but not by taxol or nocodazole. The third step, extension of pseudopodia and acquisition of bipolarity similarly requires intact actin, but not microtubules. If fibroblasts are allowed to become bipolar before drug treatment, moreover, they remain so in the presence of the drugs. To complete the fourth step, extensive elongation of the cell, both intact actin and microtubules are required. Retraction of the already elongated cell occurs on microtubule disruption, but retraction requires an intact actin cytoskeleton. We suggest that the cell interacts with surrounding collagen fibrils via its actin cytoskeleton to become bipolar in shape, and that microtubules interact with the actin cortex to bring about the final elongation of the fibroblast.     

Progress in understanding the role of microtubules in plant cells

Microtubules have long been known to play a key role in plant cell morphogenesis, but just how they fulfill this function is unclear. Transverse microtubules have been thought to constrain the movement of cellulose synthase complexes in order to generate transverse microfibrils that are essential for elongation growth. Surprisingly, some recent studies demonstrate that organized cortical microtubules are not essential for maintaining or re-establishing transversely oriented cellulose microfibrils in expanding cells. At the same time, however, there is strong evidence that microtubules are intimately associated with cellulose synthesis activity, especially during secondary wall deposition. These apparently conflicting results provide important clues as to what microtubules do at the interface between the cell and its wall. I hypothesize that cellulose microfibril length is an important parameter of wall mechanics and suggest ways in which microtubule organization may influence microfibril length. This concept is in line with current evidence that links cellulose synthesis levels and microfibril orientation. Furthermore, in light of new evidence showing that a wide variety of proteins bind to microtubules, I raise the broader question of whether a major function of plant microtubules is in modulating signaling pathways as plants respond to sensory inputs from the environment.     

砂仁种子的解剖学和组织化学研究

砂仁种子包括假种皮、种皮、外胚乳、内胚乳与胚。假种皮由内表皮、外表皮及其间的６－９层薄壁细胞组成。种皮分为外种皮、中种皮与内种皮。外种皮由１层表皮细胞构成,其壁增厚并略木质化。中种皮包括各含１层细胞的下层皮和半透明细胞层与含３－５层细胞的色素层;下皮层与色素层细胞均含有红综色素,后者的壁呈网状增厚。内种皮由１层内切向壁与径向壁非常增厚的石细胞构成。种皮表面具有许多疣状突起,它们是体积较小的表皮细胞     

The RhoGAP RGA-2 and LET-502/ROCK achieve a balance of actomyosin-dependent forces in C. elegans epidermis to control morphogenesis

Embryonic morphogenesis involves the coordinate behaviour of multiple cells and requires the accurate balance of forces acting within different cells through the application of appropriate brakes and throttles. In C. elegans, embryonic elongation is driven by Rho-binding kinase (ROCK) and actomyosin contraction in the epidermis. We identify an evolutionary conserved, actin microfilament-associated RhoGAP (RGA-2) that behaves as a negative regulator of LET-502/ROCK. The small GTPase RHO-1 is the preferred target of RGA-2 in vitro, and acts between RGA-2 and LET-502 in vivo. Two observations show that RGA-2 acts in dorsal and ventral epidermal cells to moderate actomyosin tension during the first half of elongation. First, time-lapse microscopy shows that loss of RGA-2 induces localised circumferentially oriented pulling on junctional complexes in dorsal and ventral epidermal cells. Second, specific expression of RGA-2 in dorsal/ventral, but not lateral, cells rescues the embryonic lethality of rga-2 mutants. We propose that actomyosin-generated tension must be moderated in two out of the three sets of epidermal cells surrounding the C. elegans embryo to achieve morphogenesis.     

The cytoskeleton and epidermal morphogenesis in C. elegans

During Caenorhabditis elegans development, the process of epidermal elongation converts the bean-shaped embryo into the long thin shape of the larval worm. Epidermal elongation results from changes in the shape of epidermal cells, which in turn result from changes in the epidermal cytoskeleton, the extracellular matrix, and in cell-matrix adhesion junctions. Here, we review the roles of cytoskeletal filament systems in epidermal cell shape change during elongation. Genetic and cell biological analyses have established that all three major cytoskeletal filament systems (actin microfilaments, microtubules, and intermediate filaments (IFs)) play distinct and essential roles in epidermal cell shape change. Recent work has also highlighted the importance of communication between these systems for their integrated function in epidermal elongation. Epidermal cells undergo reciprocal interactions with underlying muscle cells, which regulate the position and function of IF-containing cell-matrix adhesion structures within the epidermis. Elongation thus exemplifies the reciprocal tissue interactions of organogenesis.