GATA transcription factors as potentiators of gut endoderm differentiation

Gene inactivation studies have shown that members of the GATA family of transcription factors are critical for endoderm differentiation in mice, flies and worms, yet how these proteins function in such a conserved developmental context has not been understood. We use in vivo footprinting of mouse em...

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Published in:	Development (Cambridge) Vol. 125; no. 24; pp. 4909 - 4917
Main Authors:	Bossard, P, Zaret, K S
Format:	Journal Article
Language:	English
Published:	England The Company of Biologists Limited 15-12-1998
Subjects:	Animals Base Sequence Binding Sites - genetics Cell Differentiation - genetics DNA Footprinting DNA-Binding Proteins - genetics Endoderm - metabolism Enhancer Elements, Genetic - genetics GATA4 Transcription Factor Gene Expression Regulation, Developmental - genetics Intestines - embryology Intestines - growth & development Mice Mice, Inbred C3H Molecular Sequence Data Nuclear Proteins - analysis RNA, Messenger - analysis Serum Albumin - genetics Transcription Factors - genetics
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Abstract	Gene inactivation studies have shown that members of the GATA family of transcription factors are critical for endoderm differentiation in mice, flies and worms, yet how these proteins function in such a conserved developmental context has not been understood. We use in vivo footprinting of mouse embryonic endoderm cells to show that a DNA-binding site for GATA factors is occupied on a liver-specific, transcriptional enhancer of the serum albumin gene. GATA site occupancy occurs in gut endoderm cells at their pluripotent stage: the cells have the potential to initiate tissue development but they have not yet been committed to express albumin or other tissue-specific genes. The GATA-4 isoform accounts for about half of the nuclear GATA-factor-binding activity in the endoderm. GATA site occupancy persists during hepatic development and is necessary for the activity of albumin gene enhancer. Thus, GATA factors in the endoderm are among the first to bind essential regulatory sites in chromatin. Binding occurs prior to activation of gene expression, changes in cell morphology or functional commitment that would indicate differentiation. We suggest that GATA factors at target sites in chromatin may generally help potentiate gene expression and tissue specification in metazoan endoderm development.
AbstractList	Gene inactivation studies have shown that members of the GATA family of transcription factors are critical for endoderm differentiation in mice, flies and worms, yet how these proteins function in such a conserved developmental context has not been understood. We use in vivo footprinting of mouse embryonic endoderm cells to show that a DNA-binding site for GATA factors is occupied on a liver-specific, transcriptional enhancer of the serum albumin gene. GATA site occupancy occurs in gut endoderm cells at their pluripotent stage: the cells have the potential to initiate tissue development but they have not yet been committed to express albumin or other tissue-specific genes. The GATA-4 isoform accounts for about half of the nuclear GATA-factor-binding activity in the endoderm. GATA site occupancy persists during hepatic development and is necessary for the activity of albumin gene enhancer. Thus, GATA factors in the endoderm are among the first to bind essential regulatory sites in chromatin. Binding occurs prior to activation of gene expression, changes in cell morphology or functional commitment that would indicate differentiation. We suggest that GATA factors at target sites in chromatin may generally help potentiate gene expression and tissue specification in metazoan endoderm development.
Author	P. Bossard K.S. Zaret
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BackLink	https://www.ncbi.nlm.nih.gov/pubmed/9811575$$D View this record in MEDLINE/PubMed
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Snippet	Gene inactivation studies have shown that members of the GATA family of transcription factors are critical for endoderm differentiation in mice, flies and...
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SubjectTerms	Animals Base Sequence Binding Sites - genetics Cell Differentiation - genetics DNA Footprinting DNA-Binding Proteins - genetics Endoderm - metabolism Enhancer Elements, Genetic - genetics GATA4 Transcription Factor Gene Expression Regulation, Developmental - genetics Intestines - embryology Intestines - growth & development Mice Mice, Inbred C3H Molecular Sequence Data Nuclear Proteins - analysis RNA, Messenger - analysis Serum Albumin - genetics Transcription Factors - genetics
Title	GATA transcription factors as potentiators of gut endoderm differentiation
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