Possible roles of beta-catenin in evagination of the optic primordium in rat embryos

The roles of beta-catenin in evagination of the optic primordium in rat embryos were studied using immunostaining. High levels of beta-catenin appeared transiently in the evaginating optic primordium. Evagination of the optic primordium was suppressed in embryos treated with LiCl. In deficient optic vesicles of these embryos, accumulation of beta-catenin was decreased. Deficient optic vesicles also showed suppression of cyclin D1 accumulation and bromodeoxyuridine incorporation, no break in the deposition of laminin and type IV collagen at the basement membrane (BM) and prevention of the change in distribution of microtubules and microfilaments. These results suggest that beta-catenin regulates cell proliferation, breakdown of BM and changes in cell shape in the evaginating optic primordium to cause optic vesicle formation.     

The embryonic development of the flatworm <Emphasis Type="Italic">Macrostomum</Emphasis> sp.

Macrostomid flatworms represent a group of basal bilaterians with primitive developmental and morphological characteristics. The species Macrostomum sp., raised under laboratory conditions, has a short generation time of about 2–3 weeks and produces a large number of eggs year round. Using live observation, histology, electron microscopy and immunohistochemistry we have carried out a developmental analysis of Macrostomum sp. Cleavage (stages 1–2) of this species follows a modified spiral pattern and results in a solid embryonic primordium surrounded by an external yolk layer. During stage 3, cells at the anterior and lateral periphery of the embryo evolve into the somatic primordium which gives rise to the body wall and nervous system. Cells in the center form the large yolk-rich gut primordium. During stage 4, the brain primordium and the pharynx primordium appear as symmetric densities anterior-ventrally within the somatic primordium. Organ differentiation commences during stage 5 when the neurons of the brain primordium extend axons that form a central neuropile, and the outer cell layer of the somatic primordium turns into a ciliated epidermal epithelium. Cilia also appear in the lumen of the pharynx primordium, in the protonephridial system and, slightly later, in the lumen of the gut. Ultrastructurally, these differentiating cells show the hallmarks of platyhelminth epithelia, with a pronounced apical assembly of microfilaments (terminal web) inserting at the zonula adherens, and a wide band of septate junctions underneath the zonula. Terminal web and zonula adherens are particularly well observed in the epidermis. During stage 6, the somatic primordium extends around the surface dorsally and ventrally to form a complete body wall. Muscle precursors extend myofilaments that are organized into a highly regular orthogonal network of circular, diagonal and longitudinal fibers. Neurons of the brain primordium differentiate a commissural neuropile that extends a single pair of ventro-lateral nerve trunks (the main longitudinal cords) posteriorly. The primordial pharynx lumen fuses with the ventral epidermis anteriorly and the gut posteriorly, thereby generating a continuous digestive tract. The embryo adopts its final shape during stages 7 and 8, characterized by the morphallactic lengthening of the body into a U-shaped form and the condensation of the nervous system.Edited by J. Campos-Ortega     

Embryogenesis in Najas marina L.: Structural and histochemical approach

In Najas marina L. few polysaccharide grains are observed in zygote, basal cell and embryonal cells until the initiation of embryonic shoot-apex. With the formation of the shoot-apex, numerous polysaccharide grains engorge in the embryonal cells. The basal cell wall, subjacent to the nucellus, stains intensely with PAS (Peiodic Schiff's)-reaction. The concentration of proteins and RNA increases in the basal cell.Interestingly, the embryo shows intraseminal germination. The cells of embryonic shoot-apex, embryonic leaves, root primordium and procambial cells show a few polysaccharide grains while the cells of hypocotyledonary and cotyledonary regions are engorged with polysaccharide (starch) grains. Uniform distribution of proteins and RNA is observed in the embryonic shoot-apex, embryonic-leaves, root primordium and procambium, but the cells of hypocotyledonary and cotyledonary zones exhibit a low profile for these metabolites. The initial root-primordium remains quiescent. Three or 4 epidermal cells, subjacent to this quiescent primordium, differentiate; show densely stained, polarised, protein bands; and act as the future root primordium.The nucleus of the basal cell becomes polyploid and densely stains for proteins, RNA and DNA. At the globular proembryo stage, numerous nucleolar bodies migrate towards the periphery of the nucleus and at the 3-leaf embryo stage, these nucleolar bodies, rich in proteins and RNA, are located in the cytoplasm revealing nucleo-cytoplasmic interaction. The basal cell that never divides, but only enlarges, is persistent in the mature seed.     

Zebrafish hhex, nk2.1a, and pax2.1 regulate thyroid growth and differentiation downstream of Nodal-dependent transcription factors

During zebrafish development, the thyroid primordium initiates expression of molecular markers such as hhex and nk2.1a in the endoderm prior to pharynx formation. As expected for an endodermally derived organ, initiation of thyroid development depends on Nodal signalling. We find that it also depends on three downstream effectors of Nodal activity, casanova (cas), bonnie and clyde (bon), and faust (fau)/gata5. Despite their early Nodal-dependent expression in the endoderm, both hhex and nk2.1a are only required relatively late during thyroid development. In hhex and nk2.1a loss-of-function phenotypes, thyroid development is initiated and arrests only after the primordium has evaginated from the pharyngeal epithelium. Thus, like pax2.1, both hhex and nk2.1a have similarly late roles in differentiation or growth of thyroid follicular cells, and here, we show that all three genes act in parallel rather than in a single pathway. Our functional analysis suggests that these genes have similar roles as in mammalian thyroid development, albeit in a different temporal mode of organogenesis.     

Extracellular and Intracellular Correlates of Organ Initiation in the Embryonic Chick Thyroid

Apical and basal bundles of microfilaments have been suggestedas intracellular structures which might cause cellular contractionsleading to bending movements during organogenesis. Microfilamentbundles may have a different role in some organ primordia. Theembryonic chick thyroid develops as an evagination of the pharyngealfloor at the level of the anterior attachment of the heart.The developing thyroid is confined to a pocket surrounded bythe developing aortic arches, ventral aorta, and truncus arteriosus.Initiation of thyroid evagination is accompanied by the formationof grooves as two concentric rings in the basal surface of theplacode near its margins. The cells surrounding the groovescontain longitudinally oriented bundles of microfilaments andmicrotubules. Other microfilament bundles are present at thecell apices and bases. The primordium almost doubles in volumeduring the period of evagination, but the area of pharyngealfloor that it occupies undergoes virtually no increase. A modelis presented which describes the role of microfilament bundlesduring thyroid evagination as stabilizing cellular dimensions.The bending movements are thought to result from cell elongation,increase in cell numbers, and confinement of the thyroid toa limited space by the developing truncus arteriosus and itsbranches.     

Myosin V plays an essential role in the thyroid hormone-dependent endocytosis of type II iodothyronine 5'-deiodinase

In astrocytes, thyroxine modulates type II iodothyronine 5'-deiodinase levels by initiating the binding of the endosomes containing the enzyme to microfilaments, followed by actin-based endocytosis. Myosin V is a molecular motor thought to participate in vesicle trafficking in the brain. In this report, we developed an in vitro actin-binding assay to characterize the thyroid hormone-dependent binding of endocytotic vesicles to microfilaments. Thyroxine and reverse triiodothyronine (EC(50) levels approximately 1 nm) were >100-fold more potent than 3,5,3'-triiodothyronine in initiating vesicle binding to actin fibers in vitro. Thyroxine-dependent vesicle binding was calcium-, magnesium-, and ATP-dependent, suggesting the participation of one or more myosin motors, presumably myosin V. Addition of the myosin V globular tail, lacking the actin-binding head, specifically blocked thyroid hormone-dependent vesicle binding, and direct binding of the myosin V tail to enzyme-containing endosomes was thyroxine-dependent. Progressive NH(2)-terminal deletion of the myosin V tail and domain-specific antibody inhibition studies revealed that the thyroxine-dependent vesicle-tethering domain was localized to the last 21 amino acids of the COOH terminus. These data show that myosin V is responsible for thyroid hormone-dependent binding of primary endosomes to the microfilaments and suggest that this motor mediates the actin-based endocytosis of the type II iodothyronine deiodinase.     

Melanoma Cell Adhesion Molecule (MCAM) expression in the myogenic lineage during early chick embryonic development

We describe the expression pattern of cMCAM, a cell adhesion molecule of the immunoglobulin superfamily, in early chick embryonic development by in situ hybridisation. An initial ectodermal domain of expression is subsequently expanded, and cMCAM is expressed in the neural crest cells, otic vesicle, heart primordium, notochord and endoderm. In addition, cMCAM expression localises in the myotome once the somite cells have been specified. An in vitro murine cellular system allowed us to confirm that MCAM expression coincides with the onset of myogenic cell determination.     

Invagination of the otic placode: normal development and experimental manipulation

The inner ear forms from paired ectodermal primordia that lie to either side of the developing hindbrain. Initially each primordium forms a shallow depression in the ectodermal surface. Invagination to form an otic pit coincides with the formation of several deep folds in the epithelial surface. An initial fold appears parallel to the embryonic axis and at the junction of the rhombencephalon with somitomeric mesoderm. This is followed by formation of cranial and caudal folds perpendicular to the axis and minor folds that are within the pit formed by earlier folding. The central region of the otic primordium remains in close apposition to the lateral surface of the neural tube during the process of fold formation, until the otic pit becomes quite deep. At that time, mesenchymal cells penetrate between the two layers. Experimental analysis of invagination supports the conclusion that otic invagination is controlled differently from that of similar organ primordia, such as the eye and thyroid. Whereas these other primordia can be stimulated to undergo normal morphogenetic shape changes precociously by treatments that presumably activate motile processes in the cytoskeleton, the same conditions have little effect on the otic placode. Similarly, neither inhibitors of calcium transport nor inactivators of calmodulin activity prevent otic pit formation, while these drugs block invagination of other primordia. These results suggest that otic invagination may be caused by changes in the surrounding tissues rather than by an activation of motility within the primordium.     

Binding of Radioactive Benzylpenicillin to Sporulating Bacillus Cultures: Chemistry and Fluctuations in Specific Binding Capacity

The chemistry of the binding of (14)C-benzylpenicillin to sporulating cultures of Bacillus megaterium and B. subtilis is similar to that in a 4-hr vegetative culture of Staphylococcus aureus. Unlabeled penicillins prevent the binding of (14)C-benzylpenicillin, but benzylpenicilloic acid and benzylpenilloic acid do not. Bound antibiotic can be removed from cells with neutral hydroxylamine at 25 C. Sporulating cultures display two intervals of enhanced binding, whereas binding to stationaryphase S. aureus cells remains constant. The first period of increased binding activity occurs during formation of the spore septum or cell wall primordium development, and the second coincides with cortex biosynthesis.     

Early thyroid development requires a Tbx1-Fgf8 pathway

The thyroid develops within the pharyngeal apparatus from endodermally-derived cells. The many derivatives of the pharyngeal apparatus develop at similar times and sometimes from common cell types, explaining why many syndromic disorders express multiple birth defects affecting different structures that share a common pharyngeal origin. Thus, different derivatives may share common genetic networks during their development. Tbx1, the major gene associated with DiGeorge syndrome, is a key player in the global development of the pharyngeal apparatus, being required for virtually all its derivatives, including the thyroid. Here we show that Tbx1 regulates the size of the early thyroid primordium through its expression in the adjacent mesoderm. Because Tbx1 regulates the expression of Fgf8 in the mesoderm, we postulated that Fgf8 mediates critical Tbx1-dependent interactions between mesodermal cells and endodermal thyrocyte progenitors. Indeed, conditional ablation of Fgf8 in Tbx1-expressing cells caused an early thyroid phenotype similar to that of Tbx1 mutant mice. In addition, expression of an Fgf8 cDNA in the Tbx1 domain rescued the early size defect of the thyroid primordium in Tbx1 mutants. Thus, we have established that a Tbx1->Fgf8 pathway in the pharyngeal mesoderm is a key size regulator of mammalian thyroid.     

The effect of inhibitors upon intracellular cyclic AMP levels and chick myoblast differentiation.

The small free-living nematode Caenorhabditis elegans is usually found as a hermaphrodite, but occasionally true males appear in the population. This study provides an account of gonadogenesis in the normal male and in a mutant that is a temperature-sensitive sex transformer.Male and hermaphrodite gonads develop from morphologically identical primordia. The small primordial gonad lies on the ventral side of the worm in the coelomic cavity. The gonadial primordium contains four nuclei at parturition. As this primordium develops in a hermaphrodite, it produces a double-armed, mirror symmetrical gonad that produces first sperm and then eggs. In the male, however, this primordium develops into an asymmetrical structure composed of a ventrally located testis, a loop region, a seminal vesicle, and a vas deferens. The male gonad presents a linear sequence of nuclei in successive stages of spermatogenesis beginning with a mitotic region in the testis, followed by clearly distinguishable stages of meiosis throughout the loop region to the seminal vesicle.A temperature-sensitive sex transformer mutant, tsB202, has been isolated. tsB202 carries an autosomal recessive mutation in linkage group II that at restrictive temperature transforms an XX hermaphrodite into a phenotypic male, complete with a normal male gonad and vestigial external genitalia. These transformed males are classified as pseudomales because they do not exhibit mating behavior. Temperature shift experiments have determined the specific temporal sequences of gonadogenesis, oogenesis, and spermatogenesis. Proper manipulation of the temperature regimen causes the production of intersexes. In one intersex, a male gonad complete with sperm, seminal vesicle, and vas deferens also contains oocytes. In another intersex produced by the complementary temperature shift, a hermaphrodite-shaped gonad develops that produces only sperm and no oocytes.     

Meiotic maturation of mouse oocytes in vitro: inhibition of maturation at specific stages of nuclear progression.

In vitro studies of meiotic maturation of mouse oocytes have been carried out in the presence of several drugs. The individual steps of nuclear progression, including dissolution of the nuclear (germinal vesicle) membrane, condensation of dictyate chromatin into compact bivalents, formation of the first metaphase spindle, and extrusion of the first polar body, are each susceptible to one or more of these drugs. Germinal vesicle breakdown, the initial morphological feature characteristic of meiotic maturation, is inhibited by dibutyryl cyclic AMP. However, even in the presence of dibutyryl cyclic AMP, the nuclear membrane becomes extremely convoluted and condensation of chromatin is initiated but aborts at a stage short of compact bivalents. Germinal vesicle breakdown and chromatin condensation take place in an apparently normal manner in the presence of puromycin, Colcemid, or cytochalasin B. Nuclear progression is blocked at the circular bivalent stage when oocytes are cultured continuously in the presence of puromycin or Colcemid, whereas oocytes cultured in the presence of cytochalasin B proceed to the first meiotic metaphase, form an apparently normal spindle, and arrest. Emission of a polar body is inhibited by all of these drugs. The inhibitory effects of these drugs on meiotic maturation are reversible to varying degrees dependent upon the duration of exposure to the drug and upon the nature of the drug. These studies suggest that dissolution of the mouse oocyte's germinal vesicle and condensation of chromatin are not dependent upon concomitant protein synthesis or upon microtubules. On the other hand, the complete condensation of chromatin into compact bivalents apparently requires breakdown of the germinal vesicle. Failure of homologous chromosomes to separate after normal alignment on the meiotic spindle in the presence of cytochalasin B suggest that microfilaments may be involved in nuclear progression at this stage of maturation. Cytokinesis, in the form of polar body formation, is blocked when any one of the earlier events of maturation fails to take place.     

Some morphogenetic features of the adenohypophysial primordium of early Xenopus laevis tadpoles

Summary The adenohypophyses of Xenopus laevis tadpoles at developmental stages 20 to 46 (Nieuwkoop and Faber, 1956) were studied. From its first appearance at about stage 20 to 21, the adenohypophysial primordium passes through four morphogenetic phases, each characterized by internal events. The first phase (stages 20 to about 33/34) is characterized by extensive proliferation of the primordium. During the second phase (stages 33/34 to about 37/38), the growth of the primordium is arrested. This arrest coincides with the attainment of secretory function. The primordium is claviform in shape at these stages. The third phase, roughly stage 39, is characterized by a thorough reorganization of the adenohypophysial cells, leading to the formation of the pars distalis and pars intermedia. The shape of the primordium changes, and its volume temporarily increases. The last phase is characterized by the organization of the pars distalis cells into cell cords which possibly demonstrate a functional relation to a specialized region (the hilus) of the adenohypo-physis-brain interspace. Acknowledgements. Grants from the Faculty of Mathematics and Science, University of Lund, the Royal Physiographic Society, Lund, and the Swedish Natural Sience Research Council are gratefully acknowledged     

A role for actin-driven secretion in auxin-induced growth

In epidermal cells of Zea mays coleoptiles, actin microfilaments are organized in fine strands during cell elongation, but are bundled in response to signals that inhibit growth. This bundling response is accompanied by an increased membrane association of extracted actin. Brefeldin A, an inhibitor of vesicle secretion, increases the membrane association of actin, causes a bundling of cortical actin microfilaments, and reduces the sensitivity of cell elongation to auxin. A model is proposed where auxin controls the dynamics of an actin subpopulation that guides vesicles loaded with components of the auxin-signaling machinery towards the cell poles.     

Synapsin I is structurally similar to ATP-utilizing enzymes.

Synapsins are abundant synaptic vesicle proteins with an essential regulatory function in the nerve terminal. We determined the crystal structure of a fragment (synC) consisting of residues 110-420 of bovine synapsin I; synC coincides with the large middle domain (C-domain), the most conserved domain of synapsins. SynC molecules are folded into compact domains and form closely associated dimers. SynC monomers are strikingly similar in structure to a family of ATP-utilizing enzymes, which includes glutathione synthetase and D-alanine:D-alanine ligase. SynC binds ATP in a Ca2+-dependent manner. The crystal structure of synC in complex with ATPgammaS and Ca2+ explains the preference of synC for Ca2+ over Mg2+. Our results suggest that synapsins may also be ATP-utilizing enzymes.     

Cortical granule translocation is microfilament mediated and linked to meiotic maturation in the sea urchin oocyte

Cortical granules exocytose after the fusion of egg and sperm in most animals, and their contents function in the block to polyspermy by creating an impenetrable extracellular matrix. Cortical granules are synthesized throughout oogenesis and translocate en masse to the cell surface during meiosis where they remain until fertilization. As the mature oocyte is approximately 125 micro m in diameter (Lytechinus variegatus), many of the cortical granules translocate upwards of 60 micro m to reach the cortex within a 4 hour time window. We have investigated the mechanism of this coordinated vesicular translocation event. Although the stimulus to reinitiate meiosis in sea urchin oocytes is not known, we found many different ways to reversibly inhibit germinal vesicle breakdown, and used these findings to discover that meiotic maturation and cortical granule translocation are inseparable. We also learned that cortical granule translocation requires association with microfilaments but not microtubules. It is clear from endocytosis assays that microfilament motors are functional prior to meiosis, even though cortical granules do not use them. However, just after GVBD, cortical granules attach to microfilaments and translocate to the cell surface. This latter conclusion is based on organelle stratification within the oocyte followed by positional quantitation of the cortical granules. We conclude from these studies that maturation promoting factor (MPF) activation stimulates vesicle association with microfilaments, and is a key regulatory step in the coordinated translocation of cortical granules to the egg cortex.