Georg Buchner scite author profile

Inductive interactions between gut endoderm and the underlying mesenchyme pattern the developing digestive tract into regions with specific morphology and functions. The molecular mechanisms behind these interactions are largely unknown. Expression of the conserved homeobox gene Barx1 is restricted to the stomach mesenchyme during gut organogenesis. Using recombinant tissue cultures, we show that Barx1 loss in the mesenchyme prevents stomach epithelial differentiation of overlying endoderm and induces intestine-specific genes instead. Additionally, Barx1 null mouse embryos show visceral homeosis, with intestinal gene expression within a highly disorganized gastric epithelium. Barx1 directs mesenchymal cell expression of two secreted Wnt antagonists, sFRP1 and sFRP2, and these factors are sufficient replacements for Barx1 function. Canonical Wnt signaling is prominent in the prospective gastric endoderm prior to epithelial differentiation, and its inhibition by Barx1-dependent signaling permits development of stomach-specific epithelium. These results define a transcriptional and signaling pathway of inductive cell interactions in vertebrate organogenesis.

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Identification and Characterization of a Novel Serine– Threonine Kinase Gene from the Xp22 Region

Montini

et al. 1998

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MID2, a Homologue of the Opitz Syndrome Gene MID1: Similarities in Subcellular Localization and Differences in Expression During Development

Buchner

Montini

Andolfi

et al. 1999

Human Molecular Genetics

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The B-box family is an expanding new family of genes encoding proteins involved in diverse cellular functions such as developmental patterning and oncogenesis. A member of this protein family, MID1, is the gene responsible for the X-linked form of Opitz G/BBB syndrome, a developmental disorder characterized by defects of the midline structures. We now report the identification of MID2, a new transcript closely related to MID1. MID2 maps to Xq22 in human and to the syntenic region on the mouse X chromosome. The two X-linked genes share the same domains, the same exon-intron organization, a high degree of similarity at the protein level and the same subcellular localization, both being confined to the cytoplasm in association to micro-tubular structures. The expression pattern studied by RNA in situ hybridization in mouse revealed that Mid2 is expressed early in development and the highest level of expression is detected in the heart, unlike Mid1 for which no expression was detected in the developing heart. Together, these data suggest that midin and MID2 have a similar biochemical function but a different physiological role during development.

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Developmental stalling and organ-autonomous regulation of morphogenesis

Milétich

Zhang

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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Timing of organ development during embryogenesis is coordinated such that at birth, organ and fetal size and maturity are appropriately proportioned. The extent to which local developmental timers are integrated with each other and with the signaling interactions that regulate morphogenesis to achieve this end is not understood. Using the absolute requirement for a signaling pathway activity (bone morphogenetic protein, BMP) during a critical stage of tooth development, we show that suboptimal levels of BMP signaling do not lead to abnormal morphogenesis, as suggested by mutants affecting BMP signaling, but to a 24-h stalling of the intrinsic developmental clock of the tooth. During this time, BMP levels accumulate to reach critical levels whereupon tooth development restarts, accelerates to catch up with development of the rest of the embryo and completes normal morphogenesis. This suggests that individual organs can autonomously control their developmental timing to adjust their stage of development to that of other organs. We also find that although BMP signaling is critical for the bud-to-cap transition in all teeth, levels of BMP signaling are regulated differently in multicusped teeth. We identify an interaction between two homeodomain transcription factors, Barx1 and Msx1, which is responsible for setting critical levels of BMP activity in multicusped teeth and provides evidence that correlates the levels of Barx1 transcriptional activity with cuspal complexity. This study highlights the importance of absolute levels of signaling activity for development and illustrates remarkable self-regulation in organogenesis that ensures coordination of developmental processes such that timing is subordinate to developmental structure.

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Identification of a Novel Homolog of the Drosophila staufen Protein in the Chromosome 8q13–q21.1 Region

et al. 1999

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Georg Buchner

The Stomach Mesenchymal Transcription Factor Barx1 Specifies Gastric Epithelial Identity through Inhibition of Transient Wnt Signaling

Identification and Characterization of a Novel Serine– Threonine Kinase Gene from the Xp22 Region

MID2, a Homologue of the Opitz Syndrome Gene MID1: Similarities in Subcellular Localization and Differences in Expression During Development

Developmental stalling and organ-autonomous regulation of morphogenesis

Identification of a Novel Homolog of the Drosophila staufen Protein in the Chromosome 8q13–q21.1 Region

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