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

Catala, F.; Wanner, R.; Barton, Paul J.R.; Cohen, Arlette; Wright, Woodring E.; Buckingham, Margaret

doi:10.1128/mcb.15.8.4585

Cited by 88 publications

(82 citation statements)

References 63 publications

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“…32 Myl4, another regeneration marker overexpressed in the mouse models here studied, is related to myotube formation, as it is transcribed in skeletal muscle during the start of muscle differentiation. 33 Tnnt2, coding for troponin type 2, is also expressed at the beginning of regeneration and was found overexpressed in DMD patients, which was associated with the active regeneration in dystrophic muscle. Figure 5 Enriched functional categories.…”

Section: Characterization Of the Dystrophic Processmentioning

confidence: 99%

Comparative transcriptome analysis of muscular dystrophy models Largemyd, Dmdmdx/Largemyd and Dmdmdx: what makes them different?

2016

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Muscular dystrophies (MD) are a clinically and genetically heterogeneous group of Mendelian diseases. The underlying pathophysiology and phenotypic variability in each form are much more complex, suggesting the involvement of many other genes. Thus, here we studied the whole genome expression profile in muscles from three mice models for MD, at different time points: Dmd mdx (mutation in dystrophin gene), Large myd − / − (mutation in Large) and Dmd mdx /Large myd − / − (both mutations). The identification of altered biological functions can contribute to understand diseases and to find prognostic biomarkers and points for therapeutic intervention. We identified a substantial number of differentially expressed genes (DEGs) in each model, reflecting diseases' complexity. The main biological process affected in the three strains was immune system, accounting for the majority of enriched functional categories, followed by degeneration/regeneration and extracellular matrix remodeling processes. The most notable differences were in 21-day-old Dmd mdx , with a high proportion of DEGs related to its regenerative capacity. A higher number of positive embryonic myosin heavy chain (eMyHC) fibers confirmed this. The new Dmd mdx /Large myd − / − model did not show a highly different transcriptome from the parental lineages, with a profile closer to Large myd − / − , but not bearing the same regenerative potential as Dmd mdx . This is the first report about transcriptome profile of a mouse model for congenital MD and Dmd mdx /Large myd . By comparing the studied profiles, we conclude that alterations in biological functions due to the dystrophic process are very similar, and that the intense regeneration in Dmd mdx involves a large number of activated genes, not differentially expressed in the other two strains.

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Section: Characterization Of the Dystrophic Processmentioning

confidence: 99%

Comparative transcriptome analysis of muscular dystrophy models Largemyd, Dmdmdx/Largemyd and Dmdmdx: what makes them different?

2016

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“…Li et al (41) further demonstrated that deletion of a region containing two CArG boxes in the mouse SM22␣ gene (another highly specific SMC marker) resulted in a significant drop in transcriptional activity in cultured SMCs. Thus, similar to several cardiac-and skeletal muscle-specific genes (42)(43)(44), CArG-SRF interaction appears to serve as a common transcriptional activation mechanism for multiple SM-specific genes.…”

Section: Carg Boxes 1 and 2 Function As Recognition Sites For Srf Or mentioning

confidence: 99%

Expression of the Smooth Muscle Myosin Heavy Chain Gene Is Regulated by a Negative-acting GC-rich Element Located between Two Positive-acting Serum Response Factor-binding Elements

Madsen

Hershey

Hautmann

et al. 1997

Journal of Biological Chemistry

100

105

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To identify cis-and trans-acting factors that regulate smooth muscle-specific gene expression, we studied the smooth muscle myosin heavy chain gene, a rigorous marker of differentiated smooth muscle. A comparison of smooth muscle myosin heavy chain promoter sequences from multiple species revealed the presence of a highly conserved 227-base pair domain (nucleotides ؊1321 to ؊1095 in rat). Results of a deletion analysis of a 4.3-kilobase pair segment of the rat promoter (nucleotides ؊4220 to ؉88) demonstrated that this domain was necessary for maximal transcriptional activity in smooth muscle cells. Gel-shift analysis and site-directed mutagenesis demonstrated that one true CArG and another CArG-like element contained within this domain were both recognized by the serum response factor and were both required for the positive activity attributable to this domain. Additional studies demonstrated that mutation of a GC-rich sequence within the 227-base pair conserved domain resulted in a nearly 100% increase in transcriptional activity. Gel-shift analysis showed that this GC-rich repressor element was recognized by both Sp1 and Sp3. These data demonstrate that transcriptional control of the smooth muscle myosin heavy chain gene is highly complex, involving both negative and positive regulatory elements, including CArG sequences found in the promoters of multiple smooth muscle differentiation marker genes.Intimal migration and proliferation of vascular smooth muscle cells (SMCs) 1 are known to play an integral role in development of atherosclerotic disease (1, 2), and numerous factors have been identified that have growth promoting and/or chemotactic activity for SMCs (2). An additional feature of SMCs within atherosclerotic lesions is that cells exhibit marked differences in morphology and protein expression patterns as compared with normal medial SMCs (3-6), a process referred to as "phenotypic modulation" (7). This is characterized by decreased expression of proteins that are characteristic of differentiated SMCs, including the SM isoforms of contractile proteins, as well as altered growth regulatory properties, lipid metabolism, matrix production, and decreased contractility (reviewed in Ref. 8). Of particular significance, many of these phenotypic alterations in intimal SMCs cannot simply be viewed as a consequence of atherosclerotic disease, but rather are likely to play a major role in its development and/or progression.Although the SMC exhibits a high degree of plasticity and, unlike skeletal and cardiac myocytes, does not undergo terminal differentiation, it is a very specialized cell, whose differentiated function is dependent upon the coordinate regulation of a large number of cell type-specific/selective products, including contractile proteins, receptors, signal transduction molecules, and ion channels (8). Contractile proteins that are highly abundant and specific to the SMC represent obvious candidates for studying molecular control of SMC differentiation. Consequently, it is not unexpected that the bes...

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“…Because the G-to-A 3Ј-end divergence in MyoD-CArG is similar to that reported previously in MLC1A-CArG-box, shown to be functional in binding SRF (Catala et al, 1995), we investigated whether MLC1A-CArG also binds MEF2 proteins during differentiation. Anti-MEF2 supershift experiments with MLC1A probe show that MLC1A-CArG only bound SRF but not MEF2 proteins ( Figure 2B, right lanes).…”

Section: Myod-carg Element: a Unique Hybrid Sequence Composed Of Bindmentioning

confidence: 88%

“…Interestingly, a divergent CArG sequence in MLC1A gene, described as functional (Catala et al, 1995), contains the same 3Ј G-to-A divergence as the MyoD-SMB element. In addition, the decanucleotide core sequences are identical in both cases, with the exception of one nucleotide divergence (A to T) in the A/T tract of MLC1A CArG.…”

Section: Myod-smb Element Is a Unique Hybrid Sequence Capable Of Bindmentioning

confidence: 99%

Identification of a New Hybrid Serum Response Factor and Myocyte Enhancer Factor 2-binding Element in MyoD Enhancer Required for MyoD Expression during Myogenesis

L’honoré

Rana

Arsic

et al. 2007

MBoC

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MyoD is a critical myogenic factor induced rapidly upon activation of quiescent satellite cells, and required for their differentiation during muscle regeneration. One of the two enhancers of MyoD, the distal regulatory region, is essential for MyoD expression in postnatal muscle. This enhancer contains a functional divergent serum response factor (SRF)-binding CArG element required for MyoD expression during myoblast growth and muscle regeneration in vivo. Electrophoretic mobility shift assay, chromatin immunoprecipitation, and microinjection analyses show this element is a hybrid SRF-and MEF2 Binding (SMB) sequence where myocyte enhancer factor 2 (MEF2) complexes can compete out binding of SRF at the onset of differentiation. As cells differentiate into postmitotic myotubes, MyoD expression no longer requires SRF but instead MEF2 binding to this dual-specificity element. As such, the MyoD enhancer SMB element is the site for a molecular relay where MyoD expression is first initiated in activated satellite cells in an SRF-dependent manner and then increased and maintained by MEF2 binding in differentiated myotubes. Therefore, SMB is a DNA element with dual and stage-specific binding activity, which modulates the effects of regulatory proteins critical in controlling the balance between proliferation and differentiation. INTRODUCTIONSkeletal muscle repair is fulfilled by satellite cells, quiescent myogenic progenitors located between the basement membrane and myofibers in both growing and mature muscle (Mauro, 1961;Schultz et al., 1978;Muir et al., 1965;Bischoff and Heintz 1994;Yablonka-Reuveni, 1995). They undergo mitogenic activation in response to exercise or damageinduced signals proliferate, differentiate, and fuse into preexisting or newly formed myofibers during muscle regeneration (Grounds and Yablonka-Reuveni, 1993;Schultz and McCormick, 1994).Among basic helix-loop-helix (bHLH) myogenic regulatory factors (MRFs), MyoD is the earliest to be induced and detected both in vivo upon muscle regeneration with activation of satellite cells and in ex vivo in cell lines derived from such precursors (Fü tchbauer and Westphal, 1992;Grounds et al., 1992). Indeed, after isolation, activated satellite cells enter the cell cycle and express MyoD concomitantly with proliferating cell nuclear antigen (Smith et al., 1994;Yablonka-Reuveni and Rivera, 1994). This finding suggested a possible role for MyoD during satellite cell activation in regeneration (Yablonka-Reuveni and Rivera, 1994;Yablonka-Reuveni et al., 1999). In agreement with this, we have reported an early induction of MyoD 4 -6 h after entry of quiescent myoblasts into the cell cycle . In addition, muscles from MyoDϪ/Ϫ mutant mice are severely deficient in regenerative capacity after injury, supporting an essential role of MyoD in adult muscle (Megeney et al., 1996). Both in vivo and ex vivo studies using isolated myofibers and primary cultured myoblasts from MyoDϪ/Ϫ mice show that without MyoD, satellite cells undergo enhanced self-renewal rather than giving ...

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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

Cited by 88 publications

References 63 publications

Comparative transcriptome analysis of muscular dystrophy models Largemyd, Dmdmdx/Largemyd and Dmdmdx: what makes them different?

Comparative transcriptome analysis of muscular dystrophy models Largemyd, Dmdmdx/Largemyd and Dmdmdx: what makes them different?

Expression of the Smooth Muscle Myosin Heavy Chain Gene Is Regulated by a Negative-acting GC-rich Element Located between Two Positive-acting Serum Response Factor-binding Elements

Identification of a New Hybrid Serum Response Factor and Myocyte Enhancer Factor 2-binding Element in MyoD Enhancer Required for MyoD Expression during Myogenesis

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