Your search keyword '"Bayle JH"' showing total 4 results

1. A field of myocardial-endocardial NFAT signaling underlies heart valve morphogenesis.

Author

Chang CP, Neilson JR, Bayle JH, Gestwicki JE, Kuo A, Stankunas K, Graef IA, and Crabtree GR

Subjects

Animals, Calcineurin metabolism, Cell Differentiation genetics, Cells, Cultured, DNA-Binding Proteins genetics, Embryo, Nonmammalian, Endocardium cytology, Gene Expression Regulation, Developmental genetics, Heart Valves cytology, Heart Valves metabolism, Mesoderm cytology, Mesoderm metabolism, Mice, Mice, Transgenic, Morphogenesis genetics, Myocardium cytology, NFATC Transcription Factors, Repressor Proteins genetics, Repressor Proteins metabolism, Signal Transduction genetics, Transcription Factors genetics, Zebrafish, DNA-Binding Proteins metabolism, Endocardium embryology, Endocardium metabolism, Heart Valves embryology, Myocardium metabolism, Nuclear Proteins, Transcription Factors metabolism, Vascular Endothelial Growth Factor A metabolism

Abstract

The delicate leaflets that make up vertebrate heart valves are essential for our moment-to-moment existence. Abnormalities of valve formation are the most common serious human congenital defect. Despite their importance, relatively little is known about valve development. We show that the initiation of heart valve morphogenesis in mice requires calcineurin/NFAT to repress VEGF expression in the myocardium underlying the site of prospective valve formation. This repression of VEGF at E9 is essential for endocardial cells to transform into mesenchymal cells. Later, at E11, a second wave of calcineurin/NFAT signaling is required in the endocardium, adjacent to the earlier myocardial site of NFAT action, to direct valvular elongation and refinement. Thus, NFAT signaling functions sequentially from myocardium to endocardium within a valvular morphogenetic field to initiate and perpetuate embryonic valve formation. This mechanism also operates in zebrafish, indicating a conserved role for calcineurin/NFAT signaling in vertebrate heart valve morphogenesis.

Published

2004

2. Hyperphenylalaninemia and impaired glucose tolerance in mice lacking the bifunctional DCoH gene.

Author

Bayle JH, Randazzo F, Johnen G, Kaufman S, Nagy A, Rossant J, and Crabtree GR

Subjects

Alleles, Amino Acid Sequence, Animals, Blotting, Northern, Blotting, Western, Cataract genetics, Cell Nucleus metabolism, DNA metabolism, Dimerization, Electroporation, Gene Deletion, Genetic Complementation Test, Glucose metabolism, Hepatocyte Nuclear Factor 1, Hepatocyte Nuclear Factor 1-alpha, Hepatocyte Nuclear Factor 1-beta, Humans, Liver metabolism, Mice, Mice, Knockout, Models, Molecular, Molecular Sequence Data, Mutation, Phenylketonurias pathology, Sequence Homology, Amino Acid, Time Factors, Tissue Distribution, Transcription Factors metabolism, Transcription, Genetic, Transcriptional Activation, Transfection, DNA-Binding Proteins, Glucose Intolerance genetics, Hydro-Lyases genetics, Nuclear Proteins, Phenylketonurias genetics

Abstract

The bifunctional protein DCoH (Dimerizing Cofactor for HNF1) acts as an enzyme in intermediary metabolism and as a binding partner of the HNF1 family of transcriptional activators. HNF1 proteins direct the expression of a variety of genes in the liver, kidney, pancreas, and gut and are critical to the regulation of glucose homeostasis. Mutations of the HNF1alpha gene underlie maturity onset diabetes of the young (MODY3) in humans. DCoH acts as a cofactor for HNF1 that stabilizes the dimeric HNF1 complex. DCoH also catalyzes the recycling of tetrahydrobiopterin, a cofactor of aromatic amino acid hydroxylases. To examine the roles of DCoH, a targeted deletion allele of the murine DCoH gene was created. Mice lacking DCoH are viable and fertile but display hyperphenylalaninemia and a predisposition to cataract formation. Surprisingly, HNF1 function in DCoH null mice is only slightly impaired, and mice are mildly glucose-intolerant in contrast to HNF1alpha null mice, which are diabetic. DCoH function as it pertains to HNF1 activity appears to be partially complemented by a newly identified homolog, DCoH2.

Published

2002

3. Structural basis of dimerization, coactivator recognition and MODY3 mutations in HNF-1alpha.

Author

Rose RB, Bayle JH, Endrizzi JA, Cronk JD, Crabtree GR, and Alber T

Subjects

Binding Sites, Crystallography, X-Ray, Dimerization, Hepatocyte Nuclear Factor 1, Hepatocyte Nuclear Factor 1-alpha, Hepatocyte Nuclear Factor 1-beta, Humans, Hydro-Lyases antagonists & inhibitors, Hydro-Lyases chemistry, Hydrogen Bonding, Models, Biological, Models, Molecular, Protein Structure, Secondary, Substrate Specificity, Transcription Factors genetics, Transcriptional Activation, DNA-Binding Proteins, Diabetes Mellitus, Type 2 genetics, Hydro-Lyases metabolism, Mutation genetics, Nuclear Proteins, Transcription Factors chemistry, Transcription Factors metabolism

Abstract

Maturity-onset diabetes of the young type 3 (MODY3) results from mutations in the transcriptional activator hepatocyte nuclear factor-1alpha (HNF-1alpha). Several MODY3 mutations target the HNF-1alpha dimerization domain (HNF-p1), which binds the coactivator, dimerization cofactor of HNF-1 (DCoH). To define the mechanism of coactivator recognition and the basis for the MODY3 phenotype, we determined the cocrystal structure of the DCoH-HNF-p1 complex and characterized biochemically the effects of MODY3 mutations in HNF-p1. The DCoH-HNF-p1 complex comprises a dimer of dimers in which HNF-p1 forms a unique four-helix bundle. Through rearrangements of interfacial side chains, a single, bifunctional interface in the DCoH dimer mediates both HNF-1alpha binding and formation of a competing, transcriptionally inactive DCoH homotetramer. Consistent with the structure, MODY3 mutations in HNF-p1 reduce activator function by two distinct mechanisms.

Published

2000

4. The carboxyl-terminal domain of the p53 protein regulates sequence-specific DNA binding through its nonspecific nucleic acid-binding activity.

Author

Bayle JH, Elenbaas B, and Levine AJ

Subjects

Alternative Splicing, Amino Acid Sequence, Animals, Base Sequence, Mice, Molecular Sequence Data, Oligodeoxyribonucleotides, Tumor Suppressor Protein p53 chemistry, Tumor Suppressor Protein p53 genetics, DNA metabolism, DNA-Binding Proteins metabolism, Tumor Suppressor Protein p53 metabolism

Abstract

The murine p53 protein contains two nucleic acid-binding sites, a sequence-specific DNA-binding region localized between amino acid residues 102-290 and a nucleic acid-binding site without sequence specificity that has been localized to residues 364-390. Alternative splicing of mRNA generates two forms of this p53 protein. The normal, or majority, splice form (NSp53) retains its carboxyl-terminal sequence-nonspecific nucleic acid-binding site, which can negatively regulate the sequence-specific DNA-binding site. The alternative splice form of p53 (ASp53) replaces amino acid residues 364-390 with 17 different amino acids. This protein fails to bind nucleic acids nonspecifically and is constitutive for sequence-specific DNA binding. Thus, the binding of nucleic acids at the carboxyl terminus regulates sequence-specific DNA binding by p53. The implications of these findings for the activation of p53 transcriptional activity following DNA damage are discussed.

Published

1995