Transcriptional regulation of the Drosophila melanogaster muscle myosin heavy-chain gene

Hess, Norbert; Singer, Phillip A.; Trinh, Kien; Nikkhoy, Massoud; Bernstein, Sanford I.

doi:10.1016/j.modgep.2006.11.007

Cited by 16 publications

(21 citation statements)

References 61 publications

(68 reference statements)

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“…For Act57B, both MEF2 and CF2 sites that we have mapped are within 600 bp of the transcription start site. In contrast, for Mhc most of the candidate sites are located in the first intron, at least 800 bp away from the transcription start site (21). On the other hand, putative binding sites for MEF2 and CF2 are in relatively close proximity to the TnI transcription start site (34).…”

Section: Discussionmentioning

confidence: 93%

“…Both of the enhancers that we tested have predicted binding sites for MEF2 and CF2 proteins (TnI [34] and Mhc [21]); however, our studies are the first direct functional tests of whether MEF2 and CF2 can transcriptionally activate these enhancers. Our findings suggest strongly that the collaboration of MEF2 and CF2 during fly embryonic muscle development is a general and important phenomenon.…”

Section: Discussionmentioning

confidence: 96%

“…The Mhc reporter construct, pMHC-LacZ1, harboring the genomic sequence from positions Ϫ2759 to ϩ 2124 of the Myosin heavy chain gene was kindly provided by S. I. Bernstein (San Diego State University, San Diego, CA) (21).…”

Section: Methodsmentioning

confidence: 99%

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Myocyte Enhancer Factor 2 and Chorion Factor 2 Collaborate in Activation of the Myogenic Program in Drosophila

Kelly

Bryantsev

Cripps

2008

Molecular and Cellular Biology

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The process of myogenesis requires the coordinated activation of many structural genes whose products are required for myofibril assembly, function, and regulation. Although numerous reports have documented the importance of the myogenic regulator myocyte enhancer factor 2 (MEF2) in muscle differentiation, the interaction of MEF2 with cofactors is critical to the realization of muscle fate. We identify here a genomic region required for full MEF2-mediated activation of actin gene expression in Drosophila, and we identify the zinc finger transcriptional regulator chorion factor 2 (CF2) as a factor functioning alongside MEF2 via this region. Furthermore, although both MEF2 and CF2 can individually activate actin gene expression, we demonstrate that these two factors collaborate in regulating the Actin57B target gene in vitro and in vivo. More globally, MEF2 and CF2 synergistically activate the enhancers of a number of muscle-specific genes, and loss of CF2 function in vivo results in reductions in the levels of several muscle structural gene transcripts. These findings validate a general importance of CF2 alongside MEF2 as a critical regulator of the myogenic program, identify a new regulator functioning with MEF2 to control cell fate, and provide insight into the network of regulatory events that shape the developing musculature.

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Section: Discussionmentioning

confidence: 93%

Section: Discussionmentioning

confidence: 96%

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Myocyte Enhancer Factor 2 and Chorion Factor 2 Collaborate in Activation of the Myogenic Program in Drosophila

Kelly

Bryantsev

Cripps

2008

Molecular and Cellular Biology

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“…To confirm these results, we performed a functional rescue experiment with the MHC emb transgene (Fig. 5C), which uses the endogenous MHC promoter to express a MHC cDNA specifically in somatic muscle (Hess et al, 2007;Wells et al, 1996). If Hoip regulated either ribosome biogenesis or processing of an mRNA whose protein product activates MHC transcription, then MHC emb would not be expected to rescue MHC protein expression in hoip 1 embryos.…”

Section: Post-transcriptional Regulation Of Mhcmentioning

confidence: 97%

Post-transcriptional regulation of myotube elongation and myogenesis by Hoi Polloi

et al. 2013

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SUMMARYStriated muscle development requires the coordinated expression of genes involved in sarcomere formation and contractility, as well as genes that determine muscle morphology. However, relatively little is known about the molecular mechanisms that control the early stages of muscle morphogenesis. To explore this facet of myogenesis, we performed a genetic screen for regulators of somatic muscle morphology in Drosophila, and identified the putative RNA-binding protein (RBP) Hoi Polloi (Hoip). Hoip is expressed in striated muscle precursors within the muscle lineage and controls two genetically separable events: myotube elongation and sarcomeric protein expression. Myotubes fail to elongate in hoip mutant embryos, even though the known regulators of somatic muscle elongation, target recognition and muscle attachment are expressed normally. In addition, a majority of sarcomeric proteins, including Myosin Heavy Chain (MHC) and Tropomyosin, require Hoip for their expression. A transgenic MHC construct that contains the endogenous MHC promoter and a spliced open reading frame rescues MHC protein expression in hoip embryos, demonstrating the involvement of Hoip in pre-mRNA splicing, but not in transcription, of muscle structural genes. In addition, the human Hoip ortholog NHP2L1 rescues muscle defects in hoip embryos, and knockdown of endogenous nhp2l1 in zebrafish disrupts skeletal muscle development. We conclude that Hoip is a conserved, post-transcriptional regulator of muscle morphogenesis and structural gene expression.

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“…To generate MHC-RFP construct, a 2.5-kb MHC promoter region 32 rat ANF cDNA was amplified from the genomic DNA of the UAS-ANF-GFP transgenic fly and inserted into pRed-H-Pelican in frame with RFP. The 2.5-kb MHC promoter region was then inserted before the basal promoter upstream of the ANF-RFP fusion protein.…”

Section: Generation Of Mhc-anf-rfp and Mhc-rfp Transgenic Linesmentioning

confidence: 99%

An In Vivo Functional Analysis System for Renal Gene Discovery in Drosophila Pericardial Nephrocytes

Zhang¹,

Zhao²,

Han

2013

Journal of the American Society of Nephrology

133

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The difficulty in accessing mammalian nephrons in vivo hinders the study of podocyte biology. The Drosophila nephrocyte shares remarkable similarities to the glomerular podocyte, but the lack of a functional readout for nephrocytes makes it challenging to study this model of the podocyte, which could potentially harness the power of Drosophila genetics. Here, we present a functional analysis of nephrocytes and establish an in vivo system to screen for renal genes. We found that nephrocytes efficiently take up secreted fluorescent protein, and therefore, we generated a transgenic line carrying secreted fluorescent protein and combined it with a nephrocyte-specific driver for targeted gene knockdown, allowing the identification of genes required for nephrocyte function. To validate this system, we examined the effects of knocking down sns and duf, the Drosophila homologs of nephrin and Neph1, respectively, in pericardial nephrocytes. Knockdown of sns or duf completely abolished the accumulation of the fluorescent protein in pericardial nephrocytes. Examining the ultrastructure revealed that the formation of the nephrocyte diaphragm and lacunar structure, which is essential for protein uptake, requires sns. Our preliminary genetic screen also identified Mec2, which encodes the homolog of mammalian Podocin. Taken together, these data suggest that the Drosophila pericardial nephrocyte is a useful in vivo model to help identify genes involved in podocyte biology and facilitate the discovery of renal disease genes.

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Transcriptional regulation of the Drosophila melanogaster muscle myosin heavy-chain gene

Cited by 16 publications

References 61 publications

Myocyte Enhancer Factor 2 and Chorion Factor 2 Collaborate in Activation of the Myogenic Program in Drosophila

Myocyte Enhancer Factor 2 and Chorion Factor 2 Collaborate in Activation of the Myogenic Program in Drosophila

Post-transcriptional regulation of myotube elongation and myogenesis by Hoi Polloi

An In Vivo Functional Analysis System for Renal Gene Discovery in Drosophila Pericardial Nephrocytes

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