Cloning and embryonic expression of six wnt genes in the medaka (Oryzias latipes) with special reference to expression of wnt5a in the pectoral fin buds

WNTs are secreted signaling molecules which control cell differentiation and proliferation. They are known to play essential roles in various developmental processes. Wnt genes have been identified in a variety of animals, and it has been shown that their amino acid sequences are highly conserved throughout evolution. To investigate the role of wnt genes during fish development from the evolutionary viewpoint, six medaka wnt genes (wnt4, wnt5a, wnt6, wnt7b, wnt8b and wnt8-like) were isolated and their embryonic expression was examined. These wnt genes were expressed in various tissues during embryonic development, and most of their expression patterns were conserved or comparable to those of other vertebrates. Thus, these wnt genes may be useful as molecular markers to investigate development and organogenesis using the medaka. Focus was on wnt5a, which was expressed in the pectoral fin buds, because its expression pattern was particularly comparable to that in tetrapod limbs. Its detailed expression pattern was further examined during pectoral fin bud development. The conservation and diversification of Wnt5a expression through the evolutionary transition from fish fins to tetrapod limbs is discussed.     

Preparation of chiral 4-benzyloxymethyldihydrofuran-2-one using lipase-catalyzed kinetic resolution: synthesis of (-)-virginiae butanolide C (VB C)

Lipase-catalyzed kinetic resolution of the N,N-dialkyl-3-benzyloxymethyl-4-hydroxybutanamide 10a,b afforded the acetate 11a,b with (R) configuration, whereas the N-monoalkyl-3-benzyloxymethyl-4-hydroxybutanamide 10c-e gave the acetate 11c-e with (S) configuration. The butanamide 10 smoothly cyclized to give chiral 4-benzyloxymethyldihydrofuran-2-one 9 without racemization, which was effectively transformed into highly stereocontrolled virginiae butanolide C (VB C).     

Induction of hypersensitive cell death by hydrogen peroxide produced through polyamine degradation in tobacco plants

Screening immediate-early responding genes during the hypersensitive response (HR) against tobacco mosaic virus infection in tobacco (Nicotiana tabacum) plants, we identified a gene encoding ornithine decarboxylase. Subsequent analyses showed that other genes involved in polyamine biosynthesis were also up-regulated, resulting in the accumulation of polyamines in apoplasts of tobacco mosaic virus-infected leaves. Inhibitors of polyamine biosynthesis, alpha-difluoromethyl-ornithine, however, suppressed accumulation of polyamines, and the rate of HR was reduced. In contrast, polyamine infiltration into a healthy leaf induced the generation of hydrogen peroxide and simultaneously caused HR-like cell death. Polyamine oxidase activity in the apoplast increased up to 3-fold that of the basal level during the HR, and its suppression with a specific inhibitor, guazatine, resulted in reduced HR. Because it is established that hydrogen peroxide is one of the degradation products of polyamines, these results indicate that one of the biochemical events in the HR is production of polyamines, whose degradation induces hydrogen peroxide, eventually resulting in hypersensitive cell death.     

Expression and function of the Ror-family receptor tyrosine kinases during development: lessons from genetic analyses of nematodes,mice, and humans

Receptor tyrosine kinases (RTKs) play crucial roles in various developmental processes. Ror-family RTKs are characterized by the intracellular tyrosine kinase domains, highly related to those of the Trk-family RTKs, and by the extracellular Frizzled-like cysteine-rich domains (CRDs) and Kringle domains. Rors are evolutionally conserved among Caenorhabditis elegans, Aplysia, Drosophila melanogaster, Xenopus, mice, and humans. In D. melanogaster and mammals, pairs of structurally related Rors are found, while a single Ror protein is identified in C. elegans or Aplysia. In Aplysia and D. melanogaster, Rors are expressed exclusively in developing nervous systems. On the other hand, rather widespread expression of Rors was observed in C. elegans and mammals. Mutations in Ror of C. elegans cause inappropriate axon outgrowth as well as defects in cell migration and asymmetric cell division. It has also been reported that the nematode Ror possesses kinase-dependent and kinase-independent functions. Mouse Rors, Ror1, and Ror2, are expressed mainly in migrating neural crest cells and mesenchymal cells, and Ror2-deficient mice exhibit skeletal abnormalities and ventricular septal defects in the heart. Although Ror1-deficient mice exhibit no apparent skeletal or cardiac abnormalities, Ror1/Ror2 double mutant mice show markedly enhanced skeletal and cardiac abnormalities compared with Ror2 mutant mice, indicating genetic interaction of Ror1 and Ror2. In humans, mutations within Ror2 have been found in two genetic skeletal disorders, recessive Robinow syndrome and dominant Brachydactyly type B (BDB), further emphasizing critical functions of Ror2 during developmental morphogenesis. In this article, we also discuss the signaling machinery mediated by Ror-family RTKs with a particular emphasis on our recent structure-function analyses of Ror-family RTKs.     

Protein kinase Cdelta is responsible for constitutive and DNA damage-induced phosphorylation of Rad9

The mammalian homolog of the Schizosaccharomyces pombe Rad9 is involved in checkpoint signaling and the induction of apoptosis. While the mechanisms responsible for the regulation of human Rad9 (hRad9) are not known, hRad9 is subject to hyperphosphorylation in the response of cells to DNA damage. The present results demonstrate that protein kinase Cdelta (PKCdelta) associates with Rad9 and that DNA damage induces this interaction. PKCdelta phosphorylates hRad9 in vitro and in cells exposed to genotoxic agents. The functional significance of the interaction between hRad9 and PKCdelta is supported by the finding that activation of PKCdelta is necessary for formation of the Rad9-Hus1-Rad1 complex. We also show that PKCdelta is required for binding of hRad9 to Bcl-2. In concert with these results, inhibition of PKCdelta attenuates Rad9-mediated apoptosis. These findings demonstrate that PKCdelta is responsible for the regulation of Rad9 in the Hus1-Rad1 complex and in the apoptotic response to DNA damage.     

An expression pattern screen for genes involved in the induction of the posterior nervous system of zebrafish

The posterior nervous system, including the hindbrain and the spinal cord, has been shown to be formed by the transformation of neural plate of anterior character by signals derived from non-axial mesoderm. Although secreted factors, such as fibroblast growth factors (FGFs), Wnts, retinoic acid (RA) and Nodal, have been proposed to be the posteriorizing factors, the mechanism how neural tissue of posterior character is induced and subsequently specified along the anteroposterior axis remains elusive. To identify intercellular signaling molecules responsible for posteriorization of the neural plate as well as to find molecules induced intracellularly by the posteriorizing signal in the caudal neural plate, we screened by in situ hybridization for genes specifically expressed in posterior tissues, including the posterior neural plate and non-axial mesoderm when posteriorization of the neural plate takes place. From a subtracted library differentiating anterior versus posterior neural plate, 420 cDNA clones were tested, out of which 76 cDNA fragments showed expression restricted to the posterior tissue. These clones turned out to represent 32 different genes, including one novel secreted factor and one transmembrane protein. Seven genes were induced by non-axial mesodermal implants and bFGF beads, suggesting that these are among the early-response genes of the posteriorizing signal. Thus, our approach employing cDNA subtraction and subsequent expression pattern screening allows us to clone candidate genes involved in a novel signaling pathway contributing to the formation of the posterior nervous system.     

Defect in cell wall integrity of the yeast saccharomyces cerevisiae caused by a mutation of the GDP-mannose pyrophosphorylase gene VIG9

The Saccharomyces cerevisiae VIG9 gene encodes GDP-mannose pyrophosphorylase, which synthesizes GDP-mannose from GTP and mannose-1-phosphate. Although the null mutant was lethal, the vig9 mutants so far obtained showed no growth defect but immature protein glycosylation and drug hypersensitivity. During our search for cell-wall mutants, we found a novel temperature-sensitive mutant, JS30, which required an osmotic stabilizer for viability. JS30 excreted cell surface proteins in the medium without any indication of cell lysis. Although conventional genetic analysis using mating was impossible, by detailed characterization of JS30 including an in vitro enzyme assay and nucleotide sequencing, we found the defect of JS30 was due to a mutation in the VIG9 gene. These results indicated a critical role of GDP-mannose in maintenance of cell-wall integrity.