Regulation of the chicken embryonic myosin light-chain (L23) gene: existence of a common regulatory element shared by myosin alkali light-chain genes

A skeletal muscle-specific enhancer regulated by factors binding to E and CArG boxes is present in the promoter of the mouse myosin light-chain 1A gene

The mouse myosin light-chain 1A (MLC1A) gene, expressed in the atria of the adult heart, is one of the first muscle genes to be activated when skeletal as well as cardiac muscles form in the embryo. It is also transcribed in skeletal muscle cell lines at the onset of differentiation. Transient transfection assays of mouse skeletal muscle cell lines with DNA constructs containing MLC1A promoter fragments fused to the chloramphenicol acetyltransferase (CAT) gene show that the first 630 bp of the promoter is sufficient to direct expression of the reporter gene during myotube formation. Two E boxes located at bp -76 and -519 are necessary for this regulation. MyoD and myogenin proteins bind to them as heterodimers with E12 protein and, moreover, transactivate them in cotransfection experiments with the MLC1A promoter in nonmuscle cells. Interestingly, the effect of mutating each E box is less striking in primary cultures than in the C2 or Sol8 muscle cell line. A DNA fragment from bp -36 to -597 confers tissue- and stage-specific activity to the herpes simplex virus thymidine kinase promoter in both orientations, showing that the skeletal muscle-specific regulation of the MLC1A gene is under the control of a muscle-specific enhancer which extends into the proximal promoter region. At bp -89 is a diverged CArG box, CC(A/T)6AG, which binds the serum response factor (SRF) in myotube nuclear extracts, as does the wild-type sequence, CC(A/T)6GG. Both types of CArG box also bind a novel myotube-enriched complex which has contact points with the AT-rich part of the CArG box and adjacent 3' nucleotides. Mutations within the CArG box distinguish between the binding of this complex and binding of SRF; only SRF binding is directly involved in the specific regulation of the MLC1A gene in skeletal muscle cell lines.

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

Transcriptional control of the cardiac/slow skeletal alkali myosin light-chain (MLC1c/1s) gene is mediated, in part, by two highly conserved AT-rich cis-acting elements present in the immediate 5' flanking region. These elements cooperate to form an enhancer that can impart tissue specificity to heterologous promoters that are themselves not tissue specific in their pattern of expression. In the chicken, one of these elements matches the binding site for myocyte-specific enhancer-binding factor 2, while the other is a cis-acting element present in the transcriptional control regions of all striated alkali MLC genes (except MLC3f) and is referred to as the MLC box. The central decanucleotide core region of the MLC box closely resembles the CArG (CC[A/T]6GG) box of the serum response element, and the binding of muscle nuclear protein complexes to this element can be competed for with a synthetic serum response element. On the basis of their competition profiles and requirements for nonspecific competitor, two nuclear protein complexes, which compete for binding to the CArG-like region of the MLC box, have been identified. One of the complexes binds to a mutation of the CArG-like region that inactivates transcription of a linked reporter gene, while binding of the other complex is inhibited by this mutation. This latter complex reacts with an antibody to serum response factor (SRF) and exhibits the same binding characteristics as purified SRF. These results demonstrate that transcriptional control of the chicken MLC1c/1s gene resides in an upstream enhancer that is composed of two separate AT-rich elements, both of which are required to drive expression of a linked reporter gene. The binding of a nuclear protein complex containing SRF to one of these elements, the MLC box, is required for gene activation and apparently inhibited by other nuclear factors whose binding overlaps that of the SRF complex.

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

Transcriptional control of the cardiac/slow skeletal alkali myosin light-chain (MLC1c/1s) gene is mediated, in part, by two highly conserved AT-rich cis-acting elements present in the immediate 5' flanking region. These elements cooperate to form an enhancer that can impart tissue specificity to heterologous promoters that are themselves not tissue specific in their pattern of expression. In the chicken, one of these elements matches the binding site for myocyte-specific enhancer-binding factor 2, while the other is a cis-acting element present in the transcriptional control regions of all striated alkali MLC genes (except MLC3f) and is referred to as the MLC box. The central decanucleotide core region of the MLC box closely resembles the CArG (CC[A/T]6GG) box of the serum response element, and the binding of muscle nuclear protein complexes to this element can be competed for with a synthetic serum response element. On the basis of their competition profiles and requirements for nonspecific competitor, two nuclear protein complexes, which compete for binding to the CArG-like region of the MLC box, have been identified. One of the complexes binds to a mutation of the CArG-like region that inactivates transcription of a linked reporter gene, while binding of the other complex is inhibited by this mutation. This latter complex reacts with an antibody to serum response factor (SRF) and exhibits the same binding characteristics as purified SRF. These results demonstrate that transcriptional control of the chicken MLC1c/1s gene resides in an upstream enhancer that is composed of two separate AT-rich elements, both of which are required to drive expression of a linked reporter gene. The binding of a nuclear protein complex containing SRF to one of these elements, the MLC box, is required for gene activation and apparently inhibited by other nuclear factors whose binding overlaps that of the SRF complex.

Both a ubiquitous factor mTEF-1 and a distinct muscle-specific factor bind to the M-CAT motif of the myosin heavy chain beta gene

The A element, a fourteen base pair sequence in the rabbit myosin heavy chain (HC) beta promoter (-276/-263), contains the M-CAT motif, a cis-acting element found in several muscle-specific genes. The A element is essential for muscle-specific transcription of the myosin HC beta gene. Recently, we have identified both muscle-specific and ubiquitous factors (A1 and A2 factors, respectively) that bind to the A element. Since the sequence of the A element is very similar to the GTIIC motif in the SV40 enhancer, we examined the relationship between A-element-binding factors and a GTIIC binding factor TEF-1, recently isolated from HeLa cells. The GTIIC motif was bound by the A1 and A2 factors in muscle nuclear extracts and competed with the A element for DNA-protein complex formation. Antibody against human TEF-1 'supershifted' the ubiquitous A2 factor-DNA complex, but did not alter the mobility of the muscle-specific A1 factor-DNA complex. We isolated a murine cDNA clone (mTEF-1) from a cardiac cDNA library. The clone is highly homologous to Hela cell TEF-1. The in vitro transcription/translation product of mTEF-1 cDNA bound to the A element, and the DNA binding property of mTEF-1 was identical to that of the A2 factor. Transfection of mTEF-1 cDNA into muscle and non-muscle cells confirmed that mTEF-1 corresponds to A2, but not to A1 factors. The mTEF-1 mRNA is expressed abundantly in skeletal and cardiac muscles, kidney and lung, but it is also expressed at lower levels in other tissues. These results suggest that the M-CAT binding factors consist of two different factors; the ubiquitous A2 is encoded by mTEF-1, but the muscle-specific A1 factor is distinct from mTEF-1.

A new serum-responsive, cardiac tissue-specific transcription factor that recognizes the MEF-2 site in the myosin light chain-2 promoter

We have identified a serum-responsive, cardiac tissue-specific transcription factor, BBF-1, that recognizes an AT-rich sequence (element B), identical to the myocyte enhancer factor (MEF-2) target site, in the cardiac myosin light chain-2 (MLC-2) promoter. Deletion of the element B sequence alone from the cardiac MLC-2 promoter causes, as does that of the MEF-2 site from other promoters and the enhancer of skeletal muscle genes, a marked reduction of transcription. BBF-1 is distinguishable from cardiac MEF-2 on the basis of immunoprecipitation with an antibody which recognizes MEF-2 but not BBF-1. Unlike MEF-2, BBF-1 is present exclusively in nuclear extracts from cardiac muscle cells cultured in a medium containing a high concentration of serum. Removal of serum from culture medium abolishes BBF-1 activity selectively with a concomitant loss of the positive regulatory effect of element B on MLC-2 gene transcription, indicating that there is a correlation between the BBF-1 binding activity and the tissue-specific role of the element B (MEF-2 site) sequence. The loss of element B-mediated activation of transcription is reversed following the refeeding of cells with serum-containing medium. These data demonstrate that cardiac muscle cells contain two distinct protein factors, MEF-2 and BBF-1, which bind to the same target site but that, unlike MEF-2, BBF-1 is serum inducible and cardiac tissue specific. BBF-1 thus appears to be a crucial member of the MEF-2 family of proteins which will serve as an important tool in understanding the regulatory mechanism(s) underlying cardiogenic differentiation.

A new serum-responsive, cardiac tissue-specific transcription factor that recognizes the MEF-2 site in the myosin light chain-2 promoter

We have identified a serum-responsive, cardiac tissue-specific transcription factor, BBF-1, that recognizes an AT-rich sequence (element B), identical to the myocyte enhancer factor (MEF-2) target site, in the cardiac myosin light chain-2 (MLC-2) promoter. Deletion of the element B sequence alone from the cardiac MLC-2 promoter causes, as does that of the MEF-2 site from other promoters and the enhancer of skeletal muscle genes, a marked reduction of transcription. BBF-1 is distinguishable from cardiac MEF-2 on the basis of immunoprecipitation with an antibody which recognizes MEF-2 but not BBF-1. Unlike MEF-2, BBF-1 is present exclusively in nuclear extracts from cardiac muscle cells cultured in a medium containing a high concentration of serum. Removal of serum from culture medium abolishes BBF-1 activity selectively with a concomitant loss of the positive regulatory effect of element B on MLC-2 gene transcription, indicating that there is a correlation between the BBF-1 binding activity and the tissue-specific role of the element B (MEF-2 site) sequence. The loss of element B-mediated activation of transcription is reversed following the refeeding of cells with serum-containing medium. These data demonstrate that cardiac muscle cells contain two distinct protein factors, MEF-2 and BBF-1, which bind to the same target site but that, unlike MEF-2, BBF-1 is serum inducible and cardiac tissue specific. BBF-1 thus appears to be a crucial member of the MEF-2 family of proteins which will serve as an important tool in understanding the regulatory mechanism(s) underlying cardiogenic differentiation.

cis-acting elements responsible for muscle-specific expression of the myosin heavy chain beta gene

The 5' flanking region of the rabbit myosin heavy chain (HC) beta gene extending 295 bp upstream from the cap site provides muscle-specific transcriptional activity. In this study, we have identified and functionally characterized cis-acting elements that regulate the muscle-specific expression within this region. By using linker-scanner (LS) mutants between -295 bp and a putative TATA box, we found five distinct positive cis-acting sequences necessary for transcription: element A, the sequences between -276 and -263, which contains a putative M-CAT motif in an inverted orientation; B, the sequences between -207 and -180; C, the sequences between -136 and -127; D, the sequences between -91 and -80; and E, a TATA consensus sequence at -28. The fragment containing both A and B elements dramatically enhanced the expression of the chloramphenicol acetyltransferase (CAT) gene driven by a heterologous promoter in differentiated muscle cells, whereas fragments containing either A or B elements alone had little or no effect in either muscle or nonmuscle cells. Therefore, these two elements appear to act cooperatively in determining a high level of muscle- and stage-specific expression. Unlike the typical enhancer element, this region functions in an orientation-dependent manner. In contrast, the fragment containing C and D elements activates the heterologous promoter in both muscle and nonmuscle cells in an orientation-independent manner.

Both muscle-specific and ubiquitous nuclear factors are required for muscle-specific expression of the myosin heavy-chain beta gene in cultured cells

Expression of the myosin heavy-chain beta gene is controlled by multiple cis-acting regulatory elements in the 5' flanking region; two of these, referred to as A (-276 to -263) and B (-207 to -180), are essential for conferring muscle-specific activation on homologous and heterologous promoters. Here we report on the identification of nuclear protein factors that specifically bind to these two elements. By using the A element as a probe, as well as nuclear extracts from muscle cells, we found two protein-DNA complexes that displayed distinct bands in a gel mobility shift assay but had identical methylation interference patterns. One complex was present mainly in nuclear extracts from undifferentiated muscle and nonmuscle cells, whereas the other was observed mainly in nuclear extracts from differentiated muscle cells. Thus, the muscle-specific complex formation with the A element appears to be involved in determining tissue-specific expression. Furthermore, competition analysis demonstrated that the A-element-binding factors also bind to the muscle-CAT motif in the cardiac troponin T gene. By using the B element as a probe, we saw similar patterns of gel-shifted bands and methylation interference in nonmuscle and muscle nuclear extracts. In addition, both elements A and B were found to be necessary for tissue-specific expression, suggesting that the muscle-specific activation of the myosin heavy-chain beta gene may require interaction between a muscle-specific and a ubiquitous protein-DNA complex.

Both muscle-specific and ubiquitous nuclear factors are required for muscle-specific expression of the myosin heavy-chain beta gene in cultured cells

Expression of the myosin heavy-chain beta gene is controlled by multiple cis-acting regulatory elements in the 5' flanking region; two of these, referred to as A (-276 to -263) and B (-207 to -180), are essential for conferring muscle-specific activation on homologous and heterologous promoters. Here we report on the identification of nuclear protein factors that specifically bind to these two elements. By using the A element as a probe, as well as nuclear extracts from muscle cells, we found two protein-DNA complexes that displayed distinct bands in a gel mobility shift assay but had identical methylation interference patterns. One complex was present mainly in nuclear extracts from undifferentiated muscle and nonmuscle cells, whereas the other was observed mainly in nuclear extracts from differentiated muscle cells. Thus, the muscle-specific complex formation with the A element appears to be involved in determining tissue-specific expression. Furthermore, competition analysis demonstrated that the A-element-binding factors also bind to the muscle-CAT motif in the cardiac troponin T gene. By using the B element as a probe, we saw similar patterns of gel-shifted bands and methylation interference in nonmuscle and muscle nuclear extracts. In addition, both elements A and B were found to be necessary for tissue-specific expression, suggesting that the muscle-specific activation of the myosin heavy-chain beta gene may require interaction between a muscle-specific and a ubiquitous protein-DNA complex.

Natural and synthetic DNA elements with the CArG motif differ in expression and protein-binding properties

DNA elements with the CC(A/T)6GG, or CArG, motif occur in promoters that are under different regulatory controls. CArG elements from the skeletal actin, c-fos, and myogenin genes were tested for their abilities to confer tissue-specific expression on reporter genes when the individual elements were situated immediately upstream from a TATA element. The c-fos CArG element, also referred to as the serum response element (SRE), conferred basal, constitutive expression on the test promoter. The CArG motif from the myogenin gene was inactive. The skeletal actin CArG motif functioned as a muscle regulatory element (MRE) in that basal expression was detected only in muscle cultures. Muscle-specific expression from the 28-bp MRE and the 2.3-kb skeletal actin promoter was trans repressed by the Fos and Jun proteins. The expression and factor-binding properties of a series of synthetic CArG elements were analyzed. Muscle-specific expression was conferred by perfect 28-bp palindromes on the left and right halves of the skeletal actin MRE. Chimeric elements of the skeletal actin MRE and the c-fos SRE differed in their expression properties. Muscle-specific expression was observed when the left half of the MRE was fused to the right half of the SRE. Constitutive expression was conferred by a chimera with the right half of the MRE fused to the left half of the SRE and by chimeras which exchanged the central CC(A/T)6GG sequences. At least three distinct proteins specifically bound to these CArG elements. The natural and synthetic CArG elements differed in their affinities for these proteins; however, muscle-specific expression could not be attributed to differences in the binding of a single protein. Furthermore, the MRE did not bind MyoD or the myogenin-E12 heterodimer, indicating that muscle-specific expression from this element does not involve a direct interaction with these helix-loop-helix proteins. These data demonstrate that the conserved CArG motifs form the core of a family of functionally different DNA regulatory elements that may contribute to the tissue-specific expression properties of their cognate promoters.

Natural and synthetic DNA elements with the CArG motif differ in expression and protein-binding properties

DNA elements with the CC(A/T)6GG, or CArG, motif occur in promoters that are under different regulatory controls. CArG elements from the skeletal actin, c-fos, and myogenin genes were tested for their abilities to confer tissue-specific expression on reporter genes when the individual elements were situated immediately upstream from a TATA element. The c-fos CArG element, also referred to as the serum response element (SRE), conferred basal, constitutive expression on the test promoter. The CArG motif from the myogenin gene was inactive. The skeletal actin CArG motif functioned as a muscle regulatory element (MRE) in that basal expression was detected only in muscle cultures. Muscle-specific expression from the 28-bp MRE and the 2.3-kb skeletal actin promoter was trans repressed by the Fos and Jun proteins. The expression and factor-binding properties of a series of synthetic CArG elements were analyzed. Muscle-specific expression was conferred by perfect 28-bp palindromes on the left and right halves of the skeletal actin MRE. Chimeric elements of the skeletal actin MRE and the c-fos SRE differed in their expression properties. Muscle-specific expression was observed when the left half of the MRE was fused to the right half of the SRE. Constitutive expression was conferred by a chimera with the right half of the MRE fused to the left half of the SRE and by chimeras which exchanged the central CC(A/T)6GG sequences. At least three distinct proteins specifically bound to these CArG elements. The natural and synthetic CArG elements differed in their affinities for these proteins; however, muscle-specific expression could not be attributed to differences in the binding of a single protein. Furthermore, the MRE did not bind MyoD or the myogenin-E12 heterodimer, indicating that muscle-specific expression from this element does not involve a direct interaction with these helix-loop-helix proteins. These data demonstrate that the conserved CArG motifs form the core of a family of functionally different DNA regulatory elements that may contribute to the tissue-specific expression properties of their cognate promoters.

Tissue-specific transcription of the cardiac myosin light-chain 2 gene is regulated by an upstream repressor element

Physiological expression of the cardiac muscle myosin light-chain 2 (MLC-2) gene in chickens is restricted to cardiac muscle tissue only, at least during the late embryonic to adult stages of development. The mechanism by which cardiac MLC-2 gene expression is repressed in differentiated noncardiac muscle tissues is unknown. Using sequential 5'-deletion mutants of the cardiac MLC-2 promoter introduced into primary skeletal muscle cells in culture, we have demonstrated that a 89-bp region, designated the cardiac-specific sequence (CSS), is essential for repression of cardiac MLC-2 expression in skeletal muscle. Removal of the CSS sequence alone allows transcription in skeletal muscle cells without affecting the transcriptional activity of the promoter in cardiac muscle cells. DNase I footprinting and gel shift assays indicate that protein binding to sequences in the CSS domain occurs readily in nuclear extracts obtained from skeletal muscle but not in extracts isolated under identical conditions from cardiac muscle. Thus, it appears that a negative regulatory mechanism accounts for the lack of expression of the cardiac MLC-2 gene in skeletal muscle and that the CSS element and its binding proteins are important functional components of the regulatory apparatus which ensures the developmental program for cardiac tissue-specific gene expression.

Tissue-specific transcription of the cardiac myosin light-chain 2 gene is regulated by an upstream repressor element

Physiological expression of the cardiac muscle myosin light-chain 2 (MLC-2) gene in chickens is restricted to cardiac muscle tissue only, at least during the late embryonic to adult stages of development. The mechanism by which cardiac MLC-2 gene expression is repressed in differentiated noncardiac muscle tissues is unknown. Using sequential 5'-deletion mutants of the cardiac MLC-2 promoter introduced into primary skeletal muscle cells in culture, we have demonstrated that a 89-bp region, designated the cardiac-specific sequence (CSS), is essential for repression of cardiac MLC-2 expression in skeletal muscle. Removal of the CSS sequence alone allows transcription in skeletal muscle cells without affecting the transcriptional activity of the promoter in cardiac muscle cells. DNase I footprinting and gel shift assays indicate that protein binding to sequences in the CSS domain occurs readily in nuclear extracts obtained from skeletal muscle but not in extracts isolated under identical conditions from cardiac muscle. Thus, it appears that a negative regulatory mechanism accounts for the lack of expression of the cardiac MLC-2 gene in skeletal muscle and that the CSS element and its binding proteins are important functional components of the regulatory apparatus which ensures the developmental program for cardiac tissue-specific gene expression.