The vasculature and limb development

The developing vascular pattern of the embryonic chick limb results from a combination of two properties: the intrinsic self-assembly and branching properties of the vascular cells and the extrinsic information associated with the expanding mitotic population of mesenchymal cells; and the inhibitory factors which restrict the entrance of vessels into particular domains and/or decrease the branching frequency of such vessels. It is hypothesized that an important component of limb pattern formation is the interplay between the dividing population of mesenchymal cells and the intrinsic properties of the vascular cells. It is further asserted that the presence of particular vascular elements may, indeed, be 'positional information'. Two examples are cited involving aspects of limb duplication to support this possibility; it is suggested that vascular vessel size of a host limb may dictate the polarity of duplication events. The presented hypothesis emphasizes that the interplay between the intrinsic properties of self-assembly into tissues and extrinsic factors which establish boundaries and morphologies is involved in both vascular and limb pattern formation.     

A mathematical model of the mechanism of vertebrate somitic segmentation.

A mathematical model for the mechanism of periodic pattern formation in the process of somitogenesis is proposed. It is assumed that the metameric arrangement first appears before somite formation at the stage of transition of mesodermal cells into a polarized state. The model is based on the assumption that besides the mechanism of contact cell polarization there exists a mechanism of polarization suppression due to excretion of some chemical substance by polarized cells. Periodicity appears as a result of interaction of a kinematic wave of somitogenic cell determination with the cell cycles of mesodermal cells.     

A novel approach to studying the migratory morphology of embryonic mesenchymal cells

A polarized morphology, defined by extension of an anterior pseudopod, is essential for the amoeboid migration of embryonic mesenchymal cells. Leukocytes adopt a similar morphology immediately following suspension in simple buffers containing chemotactic factors. Polarization in suspension therefore provides a rapid and sensitive screening assay for putative regulators of leukocyte migration. The aim of the present study was to investigate whether this assay might also be used to study the motile behaviour of embryonic mesenchymal cells. Primary cultures of mesenchymal cells were established from explants of stage 28 chick embryo corneal-limbal stroma. Serum-starved, subconfluent cultures were harvested using ethylene-diamine tetra-acetic acid and resuspended in Hanks' solution for up to 15 min at 37 degrees C. A variety of cell shapes, including spherical cells, blebbed cells, and cells with either non-polarized or polarized pseudopodia were observed. The proportions of cells with pseudopodia increased significantly over time. Treatment of cells with the chemotactic mitogen platelet derived growth factor-BB (PDGF-BB, homodimer isoform) suppressed blebbing and increased both pseudopod formation and polarization. Optimal polarization occurred in concentrations of PDGF-BB that are similar to those required for optimal chemotaxis (10 ng x mL(-1)). The polarization observed in the absence of PDGF-BB suggests that the migration of cells examined in this study might be controlled at least in part by some intrinsic mechanism. In addition, the strong polarization response to PDGF-BB confirms the role for this growth factor during corneal development. Observations of mesenchymal cell morphology in suspension, therefore provide novel data regarding the motile behaviour of embryonic cells.     

The role of tensile fields and contact cell polarization in the morphogenesis of amphibian axial rudiments

Summary The role of stretching-generated tensile stresses upon the organization of axial rudiments have been studied. Pieces of the dorsal wall ofXenopus laevis andRana temporaria embryos at the late gastrula stage were rotated through 90°, transplanted into the field of neurulation tensions of another embryo and replaced by ventral tissues already insensitive to inductive influences. The axial rudiments which developed from rotated and transplanted dorsal tissues oped from rotated and transplanted dorsal tissues almost completely reorientated according to the tensile patterns in adjacent host tissues. Some of the donor cells changed their presumptive fates in accordance with their new positions in the host tensile field. Transplanted ventral tissues were involved in the morphogenetic movements specific for the dorsal regions and imitated some typical dorsal structures. In the regions without pronounced tensions the structure of transplanted axial rudiments was chaotic. It is suggested that the organization of the axial structures is established and maintained by tensile fields created by uniformly polarized cells. Cell polarization can be transmitted by contact from host to donor tissues. The specificity of this propagating process and its morphogenetical role is discussed.     

Embryonic polarity: protein stability in asymmetric cell division

Recent work on pattern formation in Caenorhabditis elegans has uncovered a new mechanism of asymmetric cell division: the cytoplasm is polarized by cortical proteins, and this polarization then influences the stability of other maternally expressed proteins that in turn determine early embryonic cell fates.     

Generation of Bilateral Symmetry in the Ectoderm of the Tubifex Embryo: Involvement of Cell–cell Interactions

In embryos of the oligochaete annelid Tubifex, most ectodermal tissues are derived from four bilateral pairs of embryonic stem cells called teloblasts (ectoteloblasts N, O, P and Q). Ectoteloblasts are generated on both left and right sides of the embryo through an invariable sequence of cell divisions of a proteloblast, NOPQ, and they are positioned in a mirror symmetric pattern relative to the embryonic midline. This mirror symmetry of ectoteloblast arrangement gives rise to the generation of bilateral symmetry in the ectoderm. Here we review results of our recent experiments on Tubifex tubifex that were designed to gain an insight into the mechanisms underlying the generation of the bilaterally symmetric organization of ectoteloblasts. Cell transplantation experiments have shown that nascent NOPQ cells can be polarized according to positional information residing in the embryo. If a left NOPQ cell is transplanted to the right side of a host embryo, it exhibits polarity comparable to that of right NOPQ cells. It has also been shown that contact between NOPQ cells serves as an external cue for their polarization. Another series of cell transplantation experiments have suggested that the competence of NOPQ cells to respond to external cues becomes undetectable shortly before the production of the first teloblast (N) from the NOPQ cell. Another series of experiments utilizing cell ablation techniques have shown that teloblasts N, P and Q are specified to express the N, P and Q fates, respectively, as early as their birth. In contrast, the O teloblast and its progeny are initially pluripotent and their fate becomes restricted through inductive signals emanating from its sister P lineage. On the basis of these findings, we have proposed a model for polarization of ectodermal teloblastogenesis in the Tubifex embryo.     

Organogenesis of the Caenorhabditis elegans intestine

The intestine of Caenorhabditis elegans is an epithelial tube consisting of only 20 cells and is derived clonally from a single embryonic blastomere called E. We describe the cellular events that shape the intestine. These events include cytoplasmic polarization of cells in the intestinal primordium, the intercalation of specific sets of cells, the generation of an extracellular cavity within the primordium, and adherens junction formation. The polarization of the intestinal primordium is associated with the generation of an asymmetric microtubule cytoskeleton, and microtubule function plays a role in subsequent cell polarity. We show that an isolated E blastomere is capable of generating polarized intestinal cells, indicating that some of the major events in intestinal organogenesis do not depend upon interactions with surrounding tissues. We compare and contrast intestinal organogenesis with some of the basic steps in development of a second epithelial organ, the pharynx, and suggest how these differences lead to organs with distinct shapes.     

Role of laminin A chain in the development of epithelial cell polarity

Kidney organ culture was used to study the conversion of embryonic mesenchymal cells into a polarized, differentiated kidney epithelium. We examined the expression of laminin, a basement membrane glycoprotein, during this conversion. The B chains of laminin were constitutively expressed, whereas the appearance of the A chain of laminin was dependent on embryonic induction and coincided with the onset of cell polarization. Antisera against the carboxy-terminal end of laminin inhibited polarization but did not affect the developmental events that precede polarization. Antisera against N-terminal parts of laminin failed to inhibit morphogenesis. Since the fragments at the carboxy-terminal end contain parts of the A chain, we suggest that the appearance of this chain is fundamental for initiation of cell polarity.     

The Polarization of Light in a Tropical Rain Forest1

The light environment within forests presents complex patterns of brightness and spectral distribution of light. The polarized light field is no less complex. Using an imaging polarized light analyzer, we examined the natural fields of linearly polarized light in the tropical rain forest of Guatopo National Park, Venezuela. We found that the celestial polarization pattern remains visible underneath the forest canopy, although cloud and fog coverage may diffuse the light and reduce the polarization signal. We characterized several distinct light environments, each having a characteristic polarized light field. Furthermore, objects throughout the forest reflect light that is polarized in a predictable fashion depending upon the material, structure, and orientation of the reflecting surface. As a consequence of these patterns in the distribution of polarized light, some functions of polarization vision, such as navigation, must be limited to the spaces exposed to several extended portions of the sky, while others, such as remote sensing of surface orientation, object detection, and breaking of camouflage would be useful throughout the forest. The polarization of light adds another dimension to the complexity of the rain forest photic environment.     

Physical mechanism of spatial organization in epithelial morphogenesis

The morphogenetic movements of embryonic epithelia are preceded by their marking into motor active and passive zones. It is carried out as a result of spontaneous splitting of the epithelial layer to domains of morphologically polarized (motor active) and isotropic cells. Processes of the cellular level are dependent on the global supracellular organization. The mechanism of selforganization of macroscopic supracellular order in the course of cell polarization is analysed. A number of more elementary properties of the embryonic material inferred from the experiments proves to be sufficient for the initiation of such mechanism.     

Apical-basal polarity, Wnt signaling and vertebrate organogenesis

Wnt proteins elicit several distinct signal transduction cascades and regulate multiple cellular processes that have proven essential for embryonic development in all metazoans investigated. During embryonic development, epithelial cells become polarized along two axes: apical/basal and within the plane of the tissue. Growing evidence suggests that polarization along each axis is essential for normal embryonic development and that this polarization is regulated in part by the different branches of the Wnt pathway. Here, we review the role of A/B cell polarity in vertebrate organogenesis with a focus on the involvement of canonical Wnt signaling in this process.     

Patterns and properties of polarized light in air and water

Natural sources of light are at best weakly polarized, but polarization of light is common in natural scenes in the atmosphere, on the surface of the Earth, and underwater. We review the current state of knowledge concerning how polarization and polarization patterns are formed in nature, emphasizing linearly polarized light. Scattering of sunlight or moonlight in the sky often forms a strongly polarized, stable and predictable pattern used by many animals for orientation and navigation throughout the day, at twilight, and on moonlit nights. By contrast, polarization of light in water, while visible in most directions of view, is generally much weaker. In air, the surfaces of natural objects often reflect partially polarized light, but such reflections are rarer underwater, and multiple-path scattering degrades such polarization within metres. Because polarization in both air and water is produced by scattering, visibility through such media can be enhanced using straightforward polarization-based methods of image recovery, and some living visual systems may use similar methods to improve vision in haze or underwater. Although circularly polarized light is rare in nature, it is produced by the surfaces of some animals, where it may be used in specialized systems of communication.     

Choosing sides: establishment of polarity in zygotes of fucoid algae

The acquisition and expression of polarity during early embryogenesis underlies developmental pattern. In many multicellular organisms an initial asymmetric division of the zygote is critical to the determination of different cell fates of the early embryonic cells. Zygotes of the marine fucoid algae are initially apolar and become polarized in response to external cues. This results in an initial asymmetric division of the zygote. Subsequent divisions occur in a highly ordered spatial and temporal pattern. A combination of cell biological and biochemical studies is providing new details, and some controversies concerning the mechanisms by which zygotic polarity is acquired and amplified. Here, we discuss some of the more recent studies that are allowing improved understanding of polarization in this system.     

Polarization of blastomeres in the cleaving rabbit embryo

Cellular polarization is believed to be a crucial event in the differentiative divergence of the two cell lineages leading to the blastocyst in rodent embryos. This study was undertaken to determine if rabbit embryos exhibited cellular polarization prior to blastocyst formation and to define the embryonic stage at which polarization was first apparent. Polarity was assayed by observation of the pattern of binding of FITC-Con A to dissociated blastomeres from three stages of rabbit embryos. Scanning electron microscopy on the dissociated cells confirmed the fluorescence results. Fifty-one percent of blastomeres in 38- to 66-cell rabbit embryos exhibited an intense pole of FITC-Con A binding and a single pole of microvilli. Only 2% of blastomeres at the 17- to 34-cell stage were similarly polarized and none were polarized at the 8- to 16-cell stage. In addition, during attempts to remove the mucin coat and zona pellucida from the rabbit embryos prior to their dissociation, it was found that the protease sensitivity of these coats also changed at the 38- to 66-cell stage. Prior to this time, although the mucin coat disappeared after 30 min in 0.5% pronase, the zona required approximately 1.5-2.5 hr in pronase for even partial removal. At the 38- to 66-cell stage, pronase dissolved the mucin coat within 10 min and the zona pellucida within 20 min. The zona was resistant to 0.1% proteinase K at all stages examined.     

Molecular networks controlling epithelial cell polarity in development

During embryonic development, polarized epithelial cells are either formed during cleavage or formed from mesenchymal cells. Because the formation of epithelia during embryogenesis has to occur with high fidelity to ensure proper development, embryos allow a functional approach to study epithelial cell polarization in vivo. In particular, genetic model organisms have greatly advanced our understanding of the generation and maintenance of epithelial cell polarity. Many novel and important polarity genes have been identified and characterized in invertebrate systems, like Drosophila melanogaster and Caenorhabditis elegans. With the rapid identification of mammalian homologues of these invertebrate polarity genes, it has become clear that many important protein domains, single proteins and even entire protein complexes are evolutionarily conserved. It is to be expected that the field of epithelial cell polarity is just experiencing the 'top of the iceberg' of a large protein network that is fundamental for the specific adhesive, cell signalling and transport functions of epithelial cells.     

Studies on conformation of F-actin in muscle fibers in the relaxed state, rigor, and during contraction using fluorescent phalloidin

F-actin in a glycerinated muscle fiber was specifically labeled with fluorescent phalloidin-(fluorescein isothiocyanate) FITC complex at 1:1 molar ratio. Binding of phalloidin-FITC to F-actin affected neither contraction of the fiber nor its regulation by Ca2+. Comparison of polarized fluorescence from phalloidin-FITC bound to F-actin in the relaxed state, rigor, and during isometric contraction of the fiber revealed that the changes in polarization accompanying activation are quantitatively as well as qualitatively different from those accompanying transition of the fiber from the relaxed state to rigor. The extent of the changes of polarized fluorescence during isometric contraction increased with decreasing ionic strength, in parallel with increase in isometric tension. On the other hand, polarized fluorescence was not affected by addition of ADP or by stretching of the fiber in rigor solution. It is concluded from these observations that conformational changes in F-actin are involved in the process of active tension development.     

Extensive nonmuscle expression and epithelial apicobasal localization of the Drosophila ALP/Enigma family protein,Zasp52

This study describes the broad tissue distribution and subcellular localization of Drosophila Zasp52, which is related to the large family of ALP (α-actinin associated protein)/Enigma PDLIM (PDZ and LIM domain) proteins of vertebrates. Results demonstrate that ZCL423 is a protein trap insertion in the Zasp52 locus tagging multiple endogenous splice isoforms with GFP. While Zasp52 has been previously characterized in muscle tissues primarily, visualization of GFP fluorescence in Zasp52 protein trap lines revealed expression in many nonmuscle tissues including the central nervous system, secretory glands, and epithelial tissues constituting the embryonic epidermis, the somatic follicle cell layer encapsulating the germline during oogenesis, and imaginal disc precursors to the adult body. In epithelial cells, Zasp52 typically accumulated basally, adjacent to integrin adhesion sites, and apically along adherens junctions, particularly enriched near junctional vertices of multicellular interfaces. Also Zasp52 showed polarized accumulation at the leading edge of migrating cell populations and morphogenetic boundaries similarly enriched for myosin. As such, Zasp52 GFP protein traps may be useful molecular markers for dynamic epithelial rearrangements. Moreover, the pattern of Zasp52 expression within nonmuscle tissues reveals potential functional roles in cell–cell and cell–matrix adhesion, specifically at sites of increased actomyosin contractile tension. In these contexts, the investigation of Zasp52 may provide insights into the functions of numerous PDLIM proteins of the metazoan lineages.