Michael Kessel scite author profile

Exposure of murine embryos to teratogenic doses of retinoic acid (RA) induced homeotic transformations of vertebrae. Posterior transformations occurred along the complete body axis after RA administration on day 7 of gestation and were accompanied by anterior shifts of Hox gene expression domains in embryos. Anterior transformations of vertebrae in the caudal half of the vertebral column were induced on day 8.5. We suggest that the identity of a vertebral segment is specified by a combination of functionally active Hox genes, a "Hox code." In this concept the sequential activation of Hox genes defines sequentially more posterior axial levels, while mesodermal cells leave the primitive streak. Exogenous RA interferes with the normal establishment of Hox codes and thus with axial specification.

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miR-34/449 miRNAs are required for motile ciliogenesis by repressing cp110

Song

Walentek

Sponer

et al. 2014

Nature

195

259

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SummaryThe miR-34/449 family consists of six homologous miRNAs at three genomic loci. Redundancy of miR-34/449 miRNAs and their dominant expression in multiciliated epithelia suggest a functional significance in ciliogenesis. Here, we report that mice deficient for all miR-34/449 miRNAs exhibited postnatal mortality, infertility, and strong respiratory dysfunction caused by defective mucociliary clearance. In both mouse and Xenopus, miR-34/449-deficient multiciliated cells (MCCs) exhibited a significant decrease in cilia length and number, due to defective basal body maturation and apical docking. The effect of miR-34/449 on ciliogenesis was mediated, at least in part, by post-transcriptional repression of Cp110, a centriolar protein suppressing cilia assembly. cp110 knockdown in miR-34/449-deficient MCCs restored ciliogenesis by rescuing basal body maturation and docking. Altogether, our findings elucidate conserved cellular and molecular mechanisms through which miR-34/449 regulate motile ciliogenesis.

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The cell-cycle regulator geminin inhibits Hox function through direct and polycomb-mediated interactions

Luo¹,

Yang

Takihara

et al. 2004

Nature

197

243

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Embryonic development is tightly controlled. The clustered genes of the Hox family of homeobox proteins play an important part in regulating this development and also proliferation. They specify embryonic structures along the body axis, and are associated with normal and malignant cell growth. The cell-cycle regulator geminin controls replication by binding to the licensing factor Cdt1, and is involved in neural differentiation. Here, we show that murine geminin associates transiently with members of the Hox-repressing polycomb complex, with the chromatin of Hox regulatory DNA elements and with Hox proteins. Gain- and loss-of-function experiments in the chick neural tube demonstrate that geminin modulates the anterior boundary of Hoxb9 transcription, which suggests a polycomb-like activity for geminin. The interaction between geminin and Hox proteins prevents Hox proteins from binding to DNA, inhibits Hox-dependent transcriptional activation of reporter and endogenous downstream target genes, and displaces Cdt1 from its complex with geminin. By establishing competitive regulation, geminin functions as a coordinator of developmental and proliferative control.

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Murine Developmental Control Genes

Kessel

Gruß

1990

Science

564

203

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Various strategies have been used to isolate genes that participate in the regulation of mouse development. Gene families that have been identified on the basis of their homology to motifs within Drosophila control genes or human transcription factor genes, namely homeobox (Hox), paired-box (Pax), and POU genes, can be compared with respect to gene organization, structure, and expression patterns. The functions of these genes can be analyzed molecularly in vitro and in vivo with the use of available mouse mutants or transgenic mice. In addition, it has been possible to generate gain- or loss-of-function mutations by random or targeted introduction of transgenes. Models derived from these studies can reveal the successive steps of developmental control on a genetic level.

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Michael Kessel

Homeotic transformations of murine vertebrae and concomitant alteration of Hox codes induced by retinoic acid

miR-34/449 miRNAs are required for motile ciliogenesis by repressing cp110

The cell-cycle regulator geminin inhibits Hox function through direct and polycomb-mediated interactions

Murine Developmental Control Genes

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