Publications (32) View all
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Article: HoxA and HoxB cluster genes subdivide the digestive tract into morphological domains during chick development.
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ABSTRACT: The digestive tract exhibits region-specific morphology and cytodifferentiation along the anteroposterior axis. We analyzed the spatial expression patterns of Hox genes belonging to the HoxA and HoxB cluster (Hoxa-4 approximately a-9, Hoxb-5 approximately b-9) in the developing chick digestive tract. The expression domains of these Hox genes correlated with morphological subdivision of the digestive tract along the anteroposterior axis.Mechanisms of Development 04/2001; 101(1-2):233-6. · 2.83 Impact Factor -
Article: Coordinated expression of Hoxb genes and signaling molecules during development of the chick respiratory tract.
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ABSTRACT: To elucidate the molecular mechanism for regulating the region-specific morphogenesis of the chicken respiratory tract, we analyzed the spatiotemporal expression patterns of the Hoxb genes, Bmp-2, Bmp-4, Wnt-5a, and Wnt-11 in the developing respiratory tract. We found region-specific expression of these genes in the mesenchymal layer of the respiratory tract. Before bronchial branching proceeds, Hoxb genes show nested expression patterns around the ventral-distal tip of the lung bud. As morphogenesis proceeds, these expression domains correspond to the morphological subdivisions of the chick respiratory tract. Hoxb-5 and Hoxb-6 expression domains demarcate the trachea, bronchial tree, and air sacs. Particularly the expression domains of Hoxb-6 to -9 correspond to the morphological subdivisions of the air sacs along the proximodistal axis. Bmp-4 and Bmp-2 are expressed throughout the entire pulmonary mesenchyme and its dorsal half, respectively. Wnt-5a and Wnt-11 are expressed in the tracheal mesenchyme. Interestingly, the expression domain of Bmp-2 is complementary to the Hoxb-6 domain. The respiratory mesenchyme influences the process of epithelial branching during morphogenesis. By tissue recombination experiments, we found that the dorsal and the ventral pulmonary mesenchyme, demarcated by Hoxb-6 expression, have different inductive capacities toward the tracheal epithelium. These observations suggest the possibility that Hoxb genes are involved in the system specifying regional differences in morphogenesis and cytodifferentiation of respiratory tract. In addition, it is possible that BMPs and WNTs mediate region-specific epithelial-mesenchymal interaction in this system.Developmental Biology 12/2000; 227(1):12-27. · 4.07 Impact Factor -
Article: Antagonistic signaling by Caronte, a novel Cerberus-related gene, establishes left-right asymmetric gene expression.
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ABSTRACT: Left-right asymmetry is initiated during chick embryogenesis in small domains near Hensen's node. Subsequently, broad asymmetric gene expression domains are established in the lateral plate mesoderm, ultimately determining the directionality of morphogenetic events. The transfer of asymmetric information from the node to the lateral plate is mediated by Caronte (Car), a novel member of the Cerberus/Dan gene family, which induces targets by antagonizing symmetrically expressed BMP signals. In addition, BMP antagonism by Car induces asymmetric expression of Lefty in the midline, preventing spread of left-sided signals to the contralateral side.Cell 10/1999; 98(5):573-83. · 32.40 Impact Factor -
Article: Distinct signaling molecules control Hoxa-11 and Hoxa-13 expression in the muscle precursor and mesenchyme of the chick limb bud.
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ABSTRACT: The limb muscles, originating from the ventrolateral portion of the somites, exhibit position-specific morphological development through successive splitting and growth/differentiation of the muscle masses in a region-specific manner by interacting with the limb mesenchyme and the cartilage elements. The molecular mechanisms that provide positional cues to the muscle precursors are still unknown. We have shown that the expression patterns of Hoxa-11 and Hoxa-13 are correlated with muscle patterning of the limb bud (Yamamoto et al., 1998) and demonstrated that muscular Hox genes are activated by signals from the limb mesenchyme. We dissected the regulatory mechanisms directing the unique expression patterns of Hoxa-11 and Hoxa-13 during limb muscle development. HOXA-11 protein was detected in both the myogenic cells and the zeugopodal mesenchymal cells of the limb bud. The earlier expression of HOXA-11 in both the myogenic precursor cells and the mesenchyme was dependent on the apical ectodermal ridge (AER), but later expression was independent of the AER. HOXA-11 expression in both myogenic precursor cells and mesenchyme was induced by fibroblast growth factor (FGF) signal, whereas hepatocyte growth factor/scatter factor (HGF/SF) maintained HOXA-11 expression in the myogenic precursor cells, but not in the mesenchyme. The distribution of HOXA-13 protein expression in the muscle masses was restricted to the posterior region. We found that HOXA-13 expression in the autopodal mesenchyme was dependent on the AER but not on the polarizing region, whereas expression of HOXA-13 in the posterior muscle masses was dependent on the polarizing region but not on the AER. Administration of BMP-2 at the anterior margin of the limb bud induced ectopic HOXA-13 expression in the anterior region of the muscle masses followed by ectopic muscle formation close to the source of exogenous BMP-2. In addition, NOGGIN/CHORDIN, antagonists of BMP-2 and BMP-4, downregulated the expression of HOXA-13 in the posterior region of the muscle masses and inhibited posterior muscle development. These results suggested that HOXA-13 expression in the posterior muscle masses is activated by the posteriorizing signal from the posterior mesenchyme via BMP-2. On the contrary, the expression of HOXA-13 in the autopodal mesenchyme was affected by neither BMP-2 nor NOGGIN/CHORDIN. Thus, mesenchymal HOXA-13 expression was independent of BMP-2 from polarizing region, but was under the control of as yet unidentified signals from the AER. These results showed that expression of Hox genes is regulated differently in the limb muscle precursor and mesenchymal cells.Development 07/1999; 126(12):2771-83. · 6.60 Impact Factor -
Article: Hox gene expression, AV-1 antigen expression, and cartilage pattern formation in chick recombinant limb buds.
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ABSTRACT: A recombinant limb bud composed of dissociated and reaggregated mesenchyme and an ectodermal jacket develops a limblike structure with bifurcated and segmented cartilage. We compared the cartilage structure formed from recombinants that were composed of mesenchymal cells derived from the limb bud progress zone at various stages. In the case of recombinants containing distal mesenchyme of early-stage limb buds (stage 18 or 20), long and thick cartilage structures were formed in the proximal region, and segmented digitlike structures were formed in the distal region. On the contrary, in the case of recombinants containing distal mesenchyme of late-stage limb buds (stage 25 or 27), only poorly developed cartilage structures were formed. Next, we analyzed expression patterns of the position-specific genes HoxA11, A13 and D12 and the position-specific antigen AV-1 protein in recombinants containing distal mesenchyme of stage 20 limb buds (stage 20 recombinants) or stage 25 limb buds (stage 25 recombinants). In stage 20 recombinants, HoxA11 was expressed throughout the mesenchyme, but HoxA13 was expressed only in the distal half of the mesenchyme. In stage 25 recombinants, HoxA13 was expressed throughout the mesenchyme, but HoxA11 was only faintly expressed. The expression pattern of HoxD12 was similar to that of HoxA13 in both stage 20 and stage 25 recombinants, and no asymmetric expression pattern, which is observed in normal limb buds, was detected. AV-1 antigen was expressed in the core region of stage 20 recombinants, and anteroposterior asymmetry, which is observed in the anterior-ventral-distal region of normal limb buds, was not found. No AV-1 expression was observed in stage 25 recombinants. These results suggest that the mesenchyme in recombinants shows spatially controlled gene/protein expressions along the proximodistal axis, and that these differences in gene/protein expressions may affect cartilage pattern formation in recombinants.Journal of Experimental Zoology 05/1998; 281(1):26-35.
