Regulation and function of axon guidance and adhesion molecules during olfactory map formation

The olfactory system presents a practical model for investigating basic mechanisms involved in patterning connections between peripheral sensory neurons and central targets. Our understanding of olfactory map formation was advanced greatly by the discovery of cAMP signaling as an important determinant of glomerular positioning in the olfactory bulb. Additionally, several cell adhesion molecules have been identified recently that are proposed to regulate homotypic interactions among projecting axons. From these studies a model has emerged to partially explain the wiring of axons from widely dispersed neuron populations in the nasal cavity to relatively stereotyped glomerular positions. These advances have revitalized interest in axon guidance molecules in establishing olfactory topography, but also open new questions regarding how these patterns of guidance cues are established and function, and what other pathways, such as glycosylation, might be involved. This review summarizes the current state of this field and the important molecules that impact on cAMP-dependent mechanism in olfactory axon guidance.     

Zebrafish colgate/hdac1 functions in the non-canonical Wnt pathway during axial extension and in Wnt-independent branchiomotor neuron migration

Vertebrate gastrulation involves the coordinated movements of populations of cells. These movements include cellular rearrangements in which cells polarize along their medio-lateral axes leading to cell intercalations that result in elongation of the body axis. Molecular analysis of this process has implicated the non-canonical Wnt/Frizzled signaling pathway that is similar to the planar cell polarity pathway (PCP) in Drosophila. Here we describe a zebrafish mutant, colgate (col), which displays defects in the extension of the body axis and the migration of branchiomotor neurons. Activation of the non-canonical Wnt/PCP pathway in these mutant embryos by overexpressing DeltaNdishevelled, rho kinase2 and van gogh-like protein 2 (vangl2) rescues the extension defects suggesting that col acts as a positive regulator of the non-canonical Wnt/PCP pathway. Further, we show that col normally regulates the caudal migration of nVII facial hindbrain branchiomotor neurons and that the mutant phenotype can be rescued by misexpression of vangl2 independent of the Wnt/PCP pathway. We cloned the col locus and found that it encodes histone deacetylase1 (hdac1). Our previous results and studies by others have implicated hdac1 in repressing the canonical Wnt pathway. Here, we demonstrate novel roles for zebrafish hdac1 in activating non-canonical Wnt/PCP signaling underlying axial extension and in promoting Wnt-independent caudal migration of a subset of hindbrain branchiomotor neurons.     

Lactosamine differentially affects olfactory sensory neuron projections to the olfactory bulb

During embryonic development, olfactory sensory neurons extend axons that form synapses with the dendrites of projection neurons in glomeruli of the olfactory bulb (OB). The glycosyltransferase beta3GnT1 regulates the expression of 1B2-reactive lactosamine glycans that are mosaically distributed among glomeruli. In newborn beta3GnT1-/- mice, lactosamine expression is lost, and many glomeruli fail to form. To determine the role of lactosamine in OB targeting, we analyzed the trajectories of specific OR axon populations and their reactivity with 1B2 in beta3GnT1-/- mice. mI7 axons and P2 axons, both of which are weakly 1B2+ in wild-type mice, fail to grow to their normal positions in the glomerular layer during early postnatal development and never recover in adult mutant mice. In contrast, many M72 axons, which are always lactosamine negative in wild-type mice, survive but are misguided to the extreme anterior OB in neonatal mutant mice and persist as heterotypic glomeruli, even in adult null mice. These results show that the loss of lactosamine differentially affects each OR population. Those that lose their normal expression of lactosamine fail to form stable connections with mitral and tufted cells in the OB, disappear during early postnatal development, and do not recover in adults. Neurons that are normally lactosamine negative, survive early postnatal degeneration in beta3GnT1-/- mice but extend axons that converge on inappropriate targets in the mutant OB.     

Beckwith-Wiedemann-Syndrom

The Beckwith-Wiedemann syndrome (BWS) is a pediatric overgrowth syndrome with a variable clinical appearance. The phenotype normalizes with age but the diagnosis of BWS is important as syndrome-specific complications may develop, in particular as a result of a 400-fold increased risk of patients developing certain tumor entities, predominantly nephroblastomas (Wilms’ tumors) and hepatoblastomas, within the first years of life. BWS displays a clinical overlap with other syndromes so that an unambiguous molecular diagnostic is required for risk assessment and appropriate therapy. At the molecular level BWS is associated with the chromosomal region 11p15.5, where two clusters with imprinted genes are located. In patients both genetic mutations and in most cases aberrant DNA methylation can be observed, which pathogenically affect the gene dosage of functionally available monoallelically expressed 11p15.5 genes. Currently only a very incomplete genotype-phenotype correlation exists for BWS. Current research projects provide insights in the molecular etiopathogenesis of the syndrome by identifying interacting partners which modify the epigenetic regulation of imprinted 11p15.5-genes.     

Die organogenetische und transitorische rolle der vitellophagen in der darmentwicklung von Galathea (Crustacea,Anomura)

The present study of the development of the different organs of the gut, the vitellophags (primary yolk cells) and the other cell-types concerned with the resorption of the yolk gives the first detailed analysis of an Anomuran development.

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Verzeichnis der Abkürzungen in den Abbilduugen A ₁ 1. Antenne - A ₂ 2. Antenne - Ab Abdomen - Au Auge - B Blastoderm - Bb Blastodermbildung - Bl Blutlakunensystem - Bm Blastomer (Furchungszelle) - Bp Blastoporus - BZ Blutzelle - Ca Cardiamagen - Cf Carapaxfalte - Cp Caudalpapille - DI Drüsenfilter (Magen) - zDk zentraler Dotterkörper - Do Dorsalorgan - pDp primare Dotterpyramide - tDp tertiare Dotterpyramide (Vitellophagenepithel) - DR Rest des intraembryonalen Dottersackes - ieDS intraembryonaler Dottersack - bDv blastodermale Dottervakuole - sDZ sekunddre Dotterzelle - tDZ tertiare Dotterzelle - sE sekunddre Epithelialisierung (der Vitellophagen) - Ec Ectoderm - Ed Enddarm - Eh Eihiille (Chorion) - Ep Entodermplatte - Et Entodermtrichter - Ex Extremitdt (bsw. Extremitätenanlage) - Fsp Furchungsspindel (Teilungsspindel) - H Herz - ID Innendotter - Im Immigration (des Mesentoderms) - In Invagination (des Mesentoderms) - Ke Kern - KL Kopflappen (optischer Lobus) - KM Kaumuskulatur - L Darmlumen - M Mitose - Ma Magen - Md Mitteldarm - dMd dorsaler Mitteldarmdivertikel (dorsaler Mitteldarmblindsack) - Me Mesoderm - McEn Mesentoderm - Mddr Mitteldarmdrüse - Ml Mandibel - Mp ₁ 1. Maxilliped (1. Kieferfuß) - Mp ₂ 2. Maxilliped (2. Kieferfuß) - Mp ₃ 3. Maxilliped (3. Kieferfuß) - Mu Muskulatur - M₁ 1. Maxille - M₂ 2. Maxille - N Ganglien des Nervensystems - Ni Niere (Antennendrüse) - Oe Oesophagus - Ol Oberlippe - Pl Plasma - Py Pylorusmagen - Qv Querverbindung zwischen den Kopflappen - pR perivitelliner Raum - Seg Segment - Sf Sternalfurche - Sto Stomodaeum (Anlage des Vorderdarmes) - TA Thoracoabdominalanlage - Te Telson - Ul Urdarmlumen - V Vitellophage (primare Dotterzelle) - V ₁ Vitellophage 1 (1. Vitellophagengeneration) - V ₂ Vitellophage 2 (2. Vitellophagengeneration) - dV degenerierende Vitellophage - V intravitelline Vitellophage - IV Initialvitellophage (Lumenbildung) - pV perivitelline Vitellophage - Va Vakuole - Vi gelöster Dotter (im Darmlumen) - fZ freie Zellen (im perivitellinen Raum) Ausgeführt mit Mitteln des Schweizerischen Nationalfonds zur Förderung der wissenschaftlichen Forschung and der Freiwillig Akademischen Gesellschaft der Stadt Basel.     

Ultrahistochemical and autoradiographic evidence for epithelial transport in the uterus of the ovoviviparous salamander,Salamandra salamandra (L.) (Amphibia,Urodela)

Summary The uterine epithelium of pregnant females of the terrestrial ovoviviparous Salamandra salamandra is characterized by a considerable enlargement of its basolateral surface. Chloride and cations (among others sodium), preferentially within the intercellular spaces, can be demonstrated ultrahistochemically. There is indirect evidence of Na⁺-K⁺-ATPase activity along the basolateral plasma membranes of the epithelial cells using the Sr-technique for demonstration of a K⁺-NPPase and ³H-ouabain autoradiography. Preliminary measurements reveal a potential difference across the uterine wall of 15–25mV, the lumenal (mucosal) surface being negative with respect to the coelomic (serosal) surface, and a short circuit current of 200–300 A. The possibly electrogenic ion transport is ouabain-sensitive. The results are in agreement with the model of a forward transporting, i.e. absorptive epithelium. An active transport of solute out of the uterine lumen across the epithelium to the subjacent connective tissue and the blood vessels may be involved in the regulation of an intrauterine milieu appropriate for the development of the offspring.I am indebted to Miss Dr. U. Beigel, Zoologisches Institut der Universität Münster, for linguistic help     

Mud mounds: A polygenetic spectrum of fine-grained carbonate buildups

Summary This research report contains nine case studies (part II to X) dealing with Palaeozoic and Mesozoic mud mounds, microbial reefs, and modern zones of active micrite production, and two parts (I and XI) summarizing the major questions and results. The formation of different types ofin situ formed micrites (automicrites) in close association with siliceous sponges is documented in Devonian, Carboniferous, Triassic, Jurassic and Cretaceous mounds and suggests a common origin with a modern facies found within reef caves. Processes involved in the formation of autochthonous micrites comprise: (i) calcifying mucus enriched in Asp and Glu, this type presumably is linked to the formation of stromatolites, thrombolites and massive fabrics; (ii) protein-rich substances within confined spaces (e.g. microcavities) result in peloidal pockets, peloidal coatings and peloidal stromatolites, and (iii) decay of sponge soft tissues, presumably enriched with symbiotic bacteria, lead to the micropeloidal preservation of parts of former sponge bodies. As a consequence, there is strong evidence that the primary production of micrite in place represents the initial cause for buildup development. The mode of precipitation corresponds to biologically-induced, matrix-mediated mineralization which results in high-Mg-calcites, isotopically balanced with inorganic cements or equilibrium skeletal carbonates, respectively. If distinct automicritic fabrics are absent, the source or origin of micrite remains questionable. However, the co-occurring identifiable components are inadequate, by quantity and physiology, to explain the enhanced accumulation of fine-grained calcium carbonate. The stromatolite reefs from the Permian Zechstein Basin are regarded as reminiscent of ancestral (Precambrian) reef facies, considered the precursor of automicrite/sponge buildups. Automicrite/sponge buildups represent the basic Phanerozoic reef type. Analogous facies are still present within modern cryptic reef habitats, where the biocalcifying carbonate factory is restricted in space.     

Evolutionary relationships among the male and female mitochondrial DNA lineages in the Mytilus edulis species complex

A novel form of mitochondrial DNA (mtDNA) inheritance has previously been documented for the blue mussel (Mytilus edulis). Female mussels inherit their mtDNA solely from their mother while males inherit mtDNA from both their mother and their father. In males, the paternal mtDNA is preferentially amplified so that the male gonad is highly enriched for the paternal mtDNA that is then transmitted from fathers to sons. We demonstrate that this mode of mtDNA inheritance also operates in the closely related species M. galloprovincialis and M. trossulus. The evolutionary relationship between the male and female mtDNA lineages is estimated by phylogenetic analysis of 455 nucleotides from the large subunit ribosomal RNA gene. We have found that the male and female lineages are highly divergent; the divergence of these lineages began prior to the speciation of the three species of blue mussels. Further, the separation between the male and female lineages is estimated to have occurred between 5.3 and 5.7 MYA.      

Zebrafish endzone regulates neural crest-derived chromatophore differentiation and morphology

The development of neural crest-derived pigment cells has been studied extensively as a model for cellular differentiation, disease and environmental adaptation. Neural crest-derived chromatophores in the zebrafish (Danio rerio) consist of three types: melanophores, xanthophores and iridiphores. We have identified the zebrafish mutant endzone (enz), that was isolated in a screen for mutants with neural crest development phenotypes, based on an abnormal melanophore pattern. We have found that although wild-type numbers of chromatophore precursors are generated in the first day of development and migrate normally in enz mutants, the numbers of all three chromatophore cell types that ultimately develop are reduced. Further, differentiated melanophores and xanthophores subsequently lose dendricity, and iridiphores are reduced in size. We demonstrate that enz function is required cell autonomously by melanophores and that the enz locus is located on chromosome 7. In addition, zebrafish enz appears to selectively regulate chromatophore development within the neural crest lineage since all other major derivatives develop normally. Our results suggest that enz is required relatively late in the development of all three embryonic chromatophore types and is normally necessary for terminal differentiation and the maintenance of cell size and morphology. Thus, although developmental regulation of different chromatophore sublineages in zebrafish is in part genetically distinct, enz provides an example of a common regulator of neural crest-derived chromatophore differentiation and morphology.