Immunohistochemical localization of bursin in epithelial cells of the avian bursa of Fabricius.

Antibodies to the avian B-cell-differentiating hormone bursin (lysyl-histidyl-glycine amide) were raised in mice and rabbits by immunizing with bursin conjugates in Freund's adjuvant. Immunohistochemical staining with these bursin-specific antibodies was restricted to follicular and dendritic reticular epithelial cells of the bursa of Fabricius, and was not found in control avian tissues.

Antibodies to thymopoietin following implantation of paper disks derivatized with synthetic Cys-thymopoietin.

A synthetic peptide corresponding to Cys-thymopoietin 28-39 was synthesized and coupled by diazo linkages to aminophenyl thioether-derivatized paper disks. Disks were implanted in the peritoneal cavities of mice, initially after soaking in complete Freund's adjuvant and subsequently, at 3 week intervals, without further treatment. After four implantations, 6/6 mice developed antibodies reacting with the synthetic peptide and with native thymopoietin. In contrast, mice conventionally immunized with peptide alone (six mice) or with peptide complexed with thyroglobulin (six mice) all failed to develop antibodies. Mice immunized with disks derivatized with Cys-thymopoietin 9-20, corresponding to the other hydrophilic region of thymopoietin, also failed to develop antibodies. Thymopoietin 28-39 corresponds to an antigenic hydrophilic region of thymopoietin that contains the pentapeptide active site (thymopoietin 32-36, Arg-Lys-Asp-Val-Tyr).

Immunohistochemical localization of thymopoietin with an antiserum to synthetic Cys-thymopoietin28-39.

Thymopoietin-containing cells in the thymus were identified immunohistochemically using murine antiserum generated by immunization with synthetic Cys-thymopoietin28-39 (Cys-TP28-39). human thymopoietin, This antiserum, previously shown to react with both bovine and human thymopoietin, gave reactivity restricted to cortical and medullary epithelial cells of bovine and human thymus. Monoclonal antibodies with reactivity restricted to native bovine thymopoietin did not react with tissue sections of bovine thymus; most likely the epitopes recognized by monoclonal antibodies are not expressed on the inactive precursor forms of thymopoietin within thymic epithelial cells.

Mechanism of formation, ultrastructure, and function of the cytoplasmic bridge system during morphogenesis in Volvox.

The cytoplasmic bridge system that links all cells of a Volvox embryo and plays a crucial role in morphogenesis is shown to form as a result of localized incomplete cytokinesis; sometimes bridge formation occurs before other regions of the cell have begun to divide. Vesicles, believed to be derived from the cell interior, align along the presumptive cleavage furrow in the bridge-forming region. Apparently it is where these vesicles fail to fuse that bridges are formed. Conventional and high voltage transmission electron microscopy analyses confirm that bridges are regularly spaced; they possess a constant, highly ordered structure throughout cleavage and inversion. Concentric cortical striations (similar to those observed previously in related species) ring each bridge throughout its length and continue out under the plasmalemma of the cell body to abut the striations of neighboring bridges. These striations are closely associated with an electron-dense material that coats the inner face of the membrane throughout the bridge region and appears to be thickest near the equator of each bridge. In addition to the parallel longitudinal arrays of cortical microtubules that traverse the cells, we observed microtubules that angle into and through the bridges during cleavage; however, the latter are not seen once inversion movements have begun. During inversion, bridge bands undergo relocation relative to the cell bodies without any loss of integrity or change in bridge spacing. Observation of isolated cell clusters reveals that it is the sequential movement of individual cells with respect to a stationary bridge system, and not actual movement of the bridges, that gives rise to the observed relocation.

Morphogenesis in Volvox: analysis of critical variables.

Inversion, the process by which Volvox embryos turn inside out, was analyzed by a combination of geometrical and experimental techniques. It was shown that simple geometric figures are adequate to represent cell shapes during inversion and that cell volumes remain constant as cell shapes change and the embryo inverts. The first stage of inversion, phialopore opening, results from the release of compressive forces as the embryo withdraws from its surrounding vesicle during a two-stage contraction of each cell around its radial axis. Premature phialopore opening occurs when withdrawal of the embryo from the vesicle is elicited artificially by exposure to either calcium ionophore or hypertonic solutions. The major event of inversion, generation of negative curvature, requires both microtubule-driven elongation of cells (to produce a classical "flask" shape) and cytochalasin-sensitive active migration of cytoplasmic bridges to the outermost ends of flask cells. Colchicine, cyclic GMP and isobutyl methyl xanthine (individually) block both normal elongation and bridge migration; cytochalasin D blocks bridge migration selectively. Flask cell formation and bridge migration are adequate to account for the negative curvature observed. An asymmetric bending of flask cell stalks along the ring of maximum curvature accounts for the fact that the embryo is not constricted in a "purse-string" fashion as negative curvature is generated. Inversion of the posterior hemisphere involves an elastic snap-through resulting from a combination of compressive stresses generated by inversion of the anterior hemisphere and the circumferential restraint imposed by cells at the equator. We conclude that the observed changes in cell shape and the migration of cytoplasmic bridges are the result of an ordered process of membrane-cytoskeletal interactions, and both necessary and sufficient to account for the morphogenetic process of inversion in Volvox.

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.