An initial blueprint for myogenic differentiation

Blais, Alexandre; Tsikitis, Mary; Acosta‐Alvear, Diego; Sharan, Roded; Kluger, Yuval; Dynlacht, Brian David

doi:10.1101/gad.1281105

Cited by 395 publications

(440 citation statements)

References 54 publications

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“…While maintaining a high correlation with transcriptional programs of primary myoblasts, C2C12 myoblasts are less prone to spontaneous differentiation [4,35], and thus they are a system of choice for genome-wide studies of histone modification and associated transcriptional regulators, including p300 in myotubes and proliferating myoblasts [16]. To study the role of p300 in the early steps of differentiation, we performed p300 ChIP-seq analysis in C2C12 myoblasts differentiated for 24 hours in comparison to proliferating myoblasts.…”

Section: Resultsmentioning

confidence: 99%

“…Previous studies have examined the role of p300 in myotube formation by comparing global p300 occupancy and histone modification of mature myotubes generated from C2C12 myoblasts [16]. Although an in vitro system, it mirrors the molecular processes of primary myoblasts; however, C2C12 myoblast are more synchronized to differentiate and fuse into post-mitotic myotubes [4,35]. Comprehensive gene expression analyses have also shown that myogenic differentiation ensues in a stepwise fashion, where sequential activation of a specific set of genes restructures the cells one step at a time toward the differentiated phenotype [48].…”

Section: Discussionmentioning

confidence: 99%

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Loci-specific histone acetylation profiles associated with transcriptional coactivator p300 during early myoblast differentiation

et al. 2018

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Molecular regulation of stem cell differentiation is exerted through both genetic and epigenetic determinants over distal regulatory or enhancer regions. Understanding the mechanistic action of active or poised enhancers is therefore imperative for control of stem cell differentiation. Based on the genome-wide co-occurrence of different epigenetic marks in committed proliferating myoblasts, we have previously generated a 14-state chromatin state model to profile rexinoid-responsive histone acetylation in early myoblast differentiation. Here, we delineate the functional mode of transcription regulators during early myogenic differentiation using genome-wide chromatin state association. We define a role of transcriptional coactivator p300, when recruited by muscle master regulator MyoD, in the establishment and regulation of myogenic loci at the onset of myoblast differentiation. In addition, we reveal an enrichment of loci-specific histone acetylation at p300 associated active or poised enhancers, particularly when enlisted by MyoD. We provide novel molecular insights into the regulation of myogenic enhancers by p300 in concert with MyoD. Our studies present a valuable aptitude for driving condition-specific chromatin state or enhancers pharmacologically to treat muscle-related diseases and for the identification of additional myogenic targets and molecular interactions for therapeutic development.Abbreviations: MRF: Muscle regulatory factor; HAT: Histone acetyltransferase; CBP: CREB-binding protein; ES: Embryonic stem; ATCC: American type culture collection; DM: Differentiation medium; DMEM: Dulbecco’s Modified Eagle Medium; GM: Growth medium; GO: Gene ontology; GREAT: Genomic regions enrichment of annotations tool; FPKM: Fragments per kilobase of transcript per million; GEO: Gene expression omnibus; MACS: Model-based analysis for ChIP-seq

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Loci-specific histone acetylation profiles associated with transcriptional coactivator p300 during early myoblast differentiation

et al. 2018

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“…Early ChIP-chip studies in mammalian genomes utilized various types of PCR amplicon arrays, including arrays tiling a specific genomic region of interest [28], CpG island arrays [29], and promoter arrays [30]. Promoter arrays covering roughly −750 bp to +250 bp relative to transcription start sites have been used to analyze binding of HNF1α, HNF4α, and HNF6 in post-mortem human liver and pancreas [31] and muscle regulatory TFs MyoD, myogenin, and MEF2 in differentiating murine C2C12 skeletal muscle cells [32].…”

Section: Chip-chipmentioning

confidence: 99%

DNA microarray technologies for measuring protein–DNA interactions

Bulyk

2006

Current Opinion in Biotechnology

153

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SummaryDNA binding proteins play key roles in many cellular processes, including transcriptional regulation and replication. Microarray-based technologies permit high-throughput identification of binding sites and functional roles of these proteins. In particular, microarray readout either of chromatin immunoprecipitation ('ChIP-chip') or of DNA adenine methyltransferase fusion proteins ('DamID') enables the identification of in vivo genomic target sites of proteins. A complementary approach, in vitro binding of proteins directly to double-stranded DNA microarrays ('protein binding microarrays'), permits rapid characterization of their DNA binding site sequence specificities. Recent advances in DNA microarray synthesis technologies have permitted the definition of proteins' DNA binding sites at much higher resolution and coverage, and further advances in these and emerging technologies will further increase the efficiencies of these exciting new approaches.

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“…The robust increase in ankrd1 expression after various physiological stimuli or pathological insults suggests the gene appears to be involved in responding to muscle-specific stresses, such as biomechanical stretch, hypertrophic remodeling and sarcomeric dysfunction (Miller et al, 2003;Blais et al, 2005). Although a high stress-induced level of the ankrd1 mRNA results from a rapid burst of gene transcription (Kanai et al, 2001), it is increasingly more recognized that posttranscriptional regulation can also be an important mechanism in terms of controlling ankrd1 transcript and protein abundance (Zolk et al, 2003;Samaras et al, 2007;Witt et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Intron retention generates ANKRD1 splice variants that are co-regulated with the main transcript in normal and failing myocardium

Torrado

Iglesias

Nespereira

et al. 2009

Gene

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The cardiac ankyrin repeat domain 1 protein (ANKRD1, also known as CARP) has been extensively characterized with regard to its proposed functions as a cardio-enriched transcriptional co-factor and stressinducible myofibrillar protein. The present results show the occurrence of alternative splicing by intron retention events in the pig and human ankrd1 gene. In pig heart, ankrd1 is expressed as four alternatively spliced transcripts, three of which have non-excised introns: ankrd1-contained introns 6, 7 and 8 (i.e., ankrd1-i6,7,8), ankrd1-contained introns 7 and 8 (i.e., ankrd1-i7,8), and ankrd1 retained only intron 8 (i.e., ankrd1-i8). In the human heart, two orthologues of porcine intron-retaining ankrd1 variants (i.e., ankrd1-i8 and ankrd1-i7,8) are detected. We demonstrate that these newly-identified intron-retaining ankrd1 transcripts are functionally intact, efficiently translated into protein in vitro and exported to the cytoplasm in cardiomyocytes in vivo. In the piglet heart, both the intronless and intron-retaining ankrd1 mRNAs are co-expressed in a chamber-dependent manner being more abundant in the left as compared to the right myocardium. Our data further indicate co-upregulation of the ankrd1 spliced variants in myocardium in the porcine model of diastolic heart failure. Most significantly, we demonstrate that in vivo forced expression of recombinant intronless ankrd1 markedly increases the levels of intron-retaining ankrd1 variants (but not of the endogenous main transcript) in piglet myocardium, suggesting that ANKRD1 may positively regulate the expression of its own intron-containing RNAs in response to cardiac stress. Overall, our findings demonstrate that in cardiomyocytes ANKRD1 can exist in multiple isoforms which may contribute to the functional diversity of this factor in heart development and disease. Abbreviations ANKRD1, ankyrin repeat domain 1 protein; MARPs, muscle ankyrin repeat proteins; SRF, serum response factor; HF, heart failure; DHF, diastolic HF; LV/RV, left/right ventricular myocardium; LA/RA, left/right atrial

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An initial blueprint for myogenic differentiation

Cited by 395 publications

References 54 publications

Loci-specific histone acetylation profiles associated with transcriptional coactivator p300 during early myoblast differentiation

Loci-specific histone acetylation profiles associated with transcriptional coactivator p300 during early myoblast differentiation

DNA microarray technologies for measuring protein–DNA interactions

Intron retention generates ANKRD1 splice variants that are co-regulated with the main transcript in normal and failing myocardium

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