Project description:Transcription factor (TF) expression and dosage regulate developmental cell fate decisions. Increased TF dosage has been predicted to enhance expression of high-affinity target genes but also increase the binding of lower-affinity loci. The relative importance of high- versus lower-affinity TF binding in guiding cell fate decisions remains unclear. To test the roles of TF dosage, we examined the effects of increasing the dosage of MyoD1, the “master regulator of myogenesis”, on skeletal muscle differentiation. Unexpectedly, increased MyoD1 dosage inhibited canonical myogenesis and redirected myoblast differentiation towards forming spontaneously contracting myotubes. This novel phenotype was driven by the MyoD1-dose-dependent upregulation of non-myogenic genes, including cell adhesion genes whose ectopic expression also inhibited classical myogenic differentiation and enabled myotube contraction. Live-cell single-molecule imaging showed that elevated MyoD1 dosage increased total chromatin binding and CUT&RUN profiling demonstrated that this increase occurred via preferential binding to lower-affinity loci. Integration of CUT&RUN, ATAC-seq and RNA-seq experiments revealed that increased MyoD1 binding correlated to the upregulation of otherwise unexpressed or lowly expressed genes. These findings suggest that increased MyoD1 dosage induced a selective gene regulatory expansion from high- to lower-affinity cis-regulatory elements, leading to activation of a broader ensemble of target genes, revealing a TF dose-dependent mechanism that can trigger distinct developmental programs.

Project description:The study investigates how MyoD1 dosage controls myogenic cell fate, employing bulk RNA-seq, ATAC-seq, and CUT&RUN. We determined genome-wide transcriptional, chromatin accessibility, and MyoD1 binding profiles in C2C12 myoblasts expressing endogenous Halo-tagged MyoD1 or doxycycline-inducible Halo–MyoD1, under growth and differentiation conditions with low or high MyoD1 dosage.

Project description:Abstract Hippo pathway downstream effectors Yap and Taz play key roles in cell proliferation and regeneration, regulating gene expression especially via interaction with Tead transcription factors. To investigate their role in skeletal muscle stem cells, we analysed Taz in vivo and ex vivo in comparison to Yap. Taz was expressed in activated satellite cells. siRNA knockdown or constitutive expression of wildtype or constitutively active TAZ mutants showed that TAZ promoted proliferation, a function that was shared with YAP. However, at later stages of myogenesis, TAZ also enhanced myogenic differentiation of myoblasts, whereas YAP inhibits such differentiation. Functionally, while muscle growth was mildly affected in Taz (gene symbol Wwtr1-/-) knockout mice, there were no overt effect on regeneration. However, conditional knockout of Yap in satellite cells of Pax7Cre-ERT2/+ : Yapflox/flox : Rosa26Lacz mice produced a marked regeneration deficit. To identify potential mechanisms, microarray analysis showed many common Taz/Yap targets, but Taz also regulates some genes independently of Yap, including myogenic genes such as Pax7, Myf5 and Myod1. Proteomic analysis of Yap/Taz revealed many common binding partners, but Taz also interacts with proteins distinct from Yap, that are mainly involved in myogenesis and aspects of cytoskeleton organization. Neither TAZ nor YAP bind members of the Wnt destruction complex but both extensively changed expression of Wnt and Wnt-cross talking genes with known roles in myogenesis. Finally, TAZ operates through Tead4 to enhance myogenic differentiation. In summary, Taz and Yap have overlapping functions in promoting myoblast proliferation but Taz then switches to promote myogenic differentiation.

Project description:Basic helix-loop-helix (bHLH) pioneer transcription factors Myod1 and Ascl1 are biochemically related but produce fundamentally different outcomes when expressed in fibroblasts: Myod1 produces muscle cells and Ascl1 induces neurons. Here, we sought to investigate the molecular mechanisms explaining the differential activity. Surprisingly, we found a large overlap in the overall binding patterns of Ascl1 and Myod1 in fibroblasts, with both transcription factors accessing both neuronal and myogenic targets. We also observed similar changes in chromatin accessibility and transcriptional activation. Yet, Myod1 predominantly induced a muscle program and Ascl1 a neuronal program. We found that differences in binding affinity at key targets resulted in largely distinct reprogramming outcomes. Accordingly, exchanging Myod1’s C-terminal protein-protein interacting domain and DNA-binding basic domain with those of Ascl1 induces an Ascl1-like binding and converts Myod1 into a pro-neuronal factor. Finally, we found that co-expression of Myod1 with the transcriptional repressor Myt1l inhibits induction of the muscle program and yields functional neuronal cells. Our findings are compatible with the notion that pioneer factor activity is associated with high-affinity protein-DNA and suggest that promiscuous binding of pioneer factors can induce unspecific lineage features which need to be kept in check by co-factor interactions.

Project description:Basic helix-loop-helix (bHLH) pioneer transcription factors Myod1 and Ascl1 are biochemically related but produce fundamentally different outcomes when expressed in fibroblasts: Myod1 produces muscle cells and Ascl1 induces neurons. Here, we sought to investigate the molecular mechanisms explaining the differential activity. Surprisingly, we found a large overlap in the overall binding patterns of Ascl1 and Myod1 in fibroblasts, with both transcription factors accessing both neuronal and myogenic targets. We also observed similar changes in chromatin accessibility and transcriptional activation. Yet, Myod1 predominantly induced a muscle program and Ascl1 a neuronal program. We found that differences in binding affinity at key targets resulted in largely distinct reprogramming outcomes. Accordingly, exchanging Myod1’s C-terminal protein-protein interacting domain and DNA-binding basic domain with those of Ascl1 induces an Ascl1-like binding and converts Myod1 into a pro-neuronal factor. Finally, we found that co-expression of Myod1 with the transcriptional repressor Myt1l inhibits induction of the muscle program and yields functional neuronal cells. Our findings are compatible with the notion that pioneer factor activity is associated with high-affinity protein-DNA and suggest that promiscuous binding of pioneer factors can induce unspecific lineage features which need to be kept in check by co-factor interactions.

Project description:Basic helix-loop-helix (bHLH) pioneer transcription factors Myod1 and Ascl1 are biochemically related but produce fundamentally different outcomes when expressed in fibroblasts: Myod1 produces muscle cells and Ascl1 induces neurons. Here, we sought to investigate the molecular mechanisms explaining the differential activity. Surprisingly, we found a large overlap in the overall binding patterns of Ascl1 and Myod1 in fibroblasts, with both transcription factors accessing both neuronal and myogenic targets. We also observed similar changes in chromatin accessibility and transcriptional activation. Yet, Myod1 predominantly induced a muscle program and Ascl1 a neuronal program. We found that differences in binding affinity at key targets resulted in largely distinct reprogramming outcomes. Accordingly, exchanging Myod1’s C-terminal protein-protein interacting domain and DNA-binding basic domain with those of Ascl1 induces an Ascl1-like binding and converts Myod1 into a pro-neuronal factor. Finally, we found that co-expression of Myod1 with the transcriptional repressor Myt1l inhibits induction of the muscle program and yields functional neuronal cells. Our findings are compatible with the notion that pioneer factor activity is associated with high-affinity protein-DNA and suggest that promiscuous binding of pioneer factors can induce unspecific lineage features which need to be kept in check by co-factor interactions.

Project description:Basic helix-loop-helix (bHLH) pioneer transcription factors Myod1 and Ascl1 are biochemically related but produce fundamentally different outcomes when expressed in fibroblasts: Myod1 produces muscle cells and Ascl1 induces neurons. Here, we sought to investigate the molecular mechanisms explaining the differential activity. Surprisingly, we found a large overlap in the overall binding patterns of Ascl1 and Myod1 in fibroblasts, with both transcription factors accessing both neuronal and myogenic targets. We also observed similar changes in chromatin accessibility and transcriptional activation. Yet, Myod1 predominantly induced a muscle program and Ascl1 a neuronal program. We found that differences in binding affinity at key targets resulted in largely distinct reprogramming outcomes. Accordingly, exchanging Myod1’s C-terminal protein-protein interacting domain and DNA-binding basic domain with those of Ascl1 induces an Ascl1-like binding and converts Myod1 into a pro-neuronal factor. Finally, we found that co-expression of Myod1 with the transcriptional repressor Myt1l inhibits induction of the muscle program and yields functional neuronal cells. Our findings are compatible with the notion that pioneer factor activity is associated with high-affinity protein-DNA and suggest that promiscuous binding of pioneer factors can induce unspecific lineage features which need to be kept in check by co-factor interactions.

Project description:Basic helix-loop-helix (bHLH) pioneer transcription factors Myod1 and Ascl1 are biochemically related but produce fundamentally different outcomes when expressed in fibroblasts: Myod1 produces muscle cells and Ascl1 induces neurons. Here, we sought to investigate the molecular mechanisms explaining the differential activity. Surprisingly, we found a large overlap in the overall binding patterns of Ascl1 and Myod1 in fibroblasts, with both transcription factors accessing both neuronal and myogenic targets. We also observed similar changes in chromatin accessibility and transcriptional activation. Yet, Myod1 predominantly induced a muscle program and Ascl1 a neuronal program. We found that differences in binding affinity at key targets resulted in largely distinct reprogramming outcomes. Accordingly, exchanging Myod1’s C-terminal protein-protein interacting domain and DNA-binding basic domain with those of Ascl1 induces an Ascl1-like binding and converts Myod1 into a pro-neuronal factor. Finally, we found that co-expression of Myod1 with the transcriptional repressor Myt1l inhibits induction of the muscle program and yields functional neuronal cells. Our findings are compatible with the notion that pioneer factor activity is associated with high-affinity protein-DNA and suggest that promiscuous binding of pioneer factors can induce unspecific lineage features which need to be kept in check by co-factor interactions.

Project description:Transcription factors and DNA regulatory binding motifs are fundamental components of the gene regulatory network (GRN). Here, by using genome-wide occupancy profiling of master regulators of MyoGenesis (MyoD and MyoGenin), we show their extensive occupancy in the extragenic enhancer regions coinciding with RNA synthesis (i.e. eRNA). In particular, multiple regions coding for eRNAs were observed within regulatory region of MYOD1, including previously characterized Distal Regulatory Regions (DRR) and Core Enhancer (CE). While CERNA enhanced RNA polymerase II (PolII) occupancy and transcription at MYOD1, DRRRNA acted in trans to activate the downstream MyoGenic GRN. The deployment of transcriptional machinery to appropriate loci is contingent on chromatin accessibility, a rate-limiting step preceding PolII assembly. By nuclease sensitivity assay, we show that eRNAs increase genomic access to the transcriptional complex at defined regulatory regions. In conclusion, our data suggest eRNAs establish a cell-type-specific transcriptional circuitry by directing chromatin-remodeling events. Examination of MyoD and MyoG binding events and production of RNA at the enhancer sites during myogenic differentiation. We performed RNAi against enhancer-derived RNA (DRRi) which resulted in reduction of chromatin accessiblity and RNA polymerase II occupancy at defined regulatory elements. In complementary experiments, overexpression of DRR-RNA (pHAN_DRR1.2) resulted in early activation of MyoG. GFPi and GFP overexpression (pHAN_GFP) were used as control in these experiments, respectively.

Project description:Transcription factors (TFs) regulate gene expression by interacting with DNA in a sequence-specific manner. High-throughput in vitro technologies, such as PBMs and HT-SELEX, have revealed the DNA binding specificities of hundreds of TFs. However, they have limited ability to reliably identify lower affinity binding sites, which are increasingly recognized as important for precise spatial and temporal control of gene expression. To address this limitation, we developed a novel technology to measure protein affinity to DNA by in vitro transcription and RNA sequencing (PADIT-seq). Using PADIT-seq, we comprehensively assayed the binding preferences of four human and two yeast TFs to all possible 10-bp DNA sequences, detecting hundreds of novel lower affinity binding sites. The expanded repertoire of lower affinity binding sites unexpectedly revealed that nucleotides flanking high affinity DNA binding sites create overlapping lower affinity sites that together modulate TF genomic occupancy in vivo. We propose a model where TF binding is not determined by individual binding sites, but rather by the sum of multiple, overlapping binding sites. Formation of such extended recognition sequences stems from an inherent property of TF binding sites to interweave each other. Consequently, competition between paralogous TFs for shared high-affinity binding sites is controlled by flanking nucleotides that create differential numbers of overlapping lower affinity binding sites. Noncoding variants alter multiple, overlapping binding sites to influence gene expression and human traits, including diseases.