Transcriptional control of the chicken cardiac myosin light-chain gene is mediated by two AT-rich cis-acting DNA elements and binding of serum response factor.

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Mol Cell Biol. 1993 November; 13(11): 6907-6918

Transcriptional control of the chicken cardiac myosin light-chain gene is mediated by two AT-rich cis-acting DNA elements and binding of serum response factor.

N Papadopoulos and M T Crow

Laboratory of Cardiovascular Science, National Institute on Aging, Baltimore, Maryland 21224.

ABSTRACT

Transcriptional control of the cardiac/slow skeletal alkalimyosin light-chain (MLC1c/1s) gene is mediated, in part, bytwo highly conserved AT-rich cis-acting elements present inthe immediate 5' flanking region. These elements cooperate toform an enhancer that can impart tissue specificity to heterologouspromoters that are themselves not tissue specific in their patternof expression. In the chicken, one of these elements matchesthe binding site for myocyte-specific enhancer-binding factor2, while the other is a cis-acting element present in the transcriptionalcontrol regions of all striated alkali MLC genes (except MLC3f)and is referred to as the MLC box. The central decanucleotidecore region of the MLC box closely resembles the CArG (CC[A/T]6GG)box of the serum response element, and the binding of musclenuclear protein complexes to this element can be competed forwith a synthetic serum response element. On the basis of theircompetition profiles and requirements for nonspecific competitor,two nuclear protein complexes, which compete for binding tothe CArG-like region of the MLC box, have been identified. Oneof the complexes binds to a mutation of the CArG-like regionthat inactivates transcription of a linked reporter gene, whilebinding of the other complex is inhibited by this mutation.This latter complex reacts with an antibody to serum responsefactor (SRF) and exhibits the same binding characteristics aspurified SRF. These results demonstrate that transcriptionalcontrol of the chicken MLC1c/1s gene resides in an upstreamenhancer that is composed of two separate AT-rich elements,both of which are required to drive expression of a linked reportergene. The binding of a nuclear protein complex containing SRFto one of these elements, the MLC box, is required for geneactivation and apparently inhibited by other nuclear factorswhose binding overlaps that of the SRF complex.

Mol Cell Biol. 1993 November; 13(11): 6907-6918

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