Project description:Protein-coding changes preceded cis-regulatory gains in newly evolved transcription circuit

Project description:Decoding the regulatory circuit by epigenetic regulator MOF in haematopoiesis

Project description:The differentiation of cells into distinct cell types, each of which is heritable for many generations, underlies many biological phenomena. White and opaque cells of the fungal pathogen Candida albicans are two such heritable cell types, each thought to be adapted to unique niches within their human host. To systematically investigate the differences between the two cell types, we performed strand-specific massively-parallel sequencing of RNA from C. albicans white and opaque cells. Combining the resulting data from both cell types, we first substantially re-annotated the C. albicans transcriptome, finding 1443 novel coding and non-coding transcriptionally active regions. Using the new annotation, we compared differences in transcript abundance between the two cell types with the genomic regions bound by the master regulator of the white-opaque switch (Wor1). We found that the revised transcriptional landscape considerably alters our understanding of the circuit governing differentiation. In particular, we can now resolve the poor concordance between binding of the master regulator and the differential expression of adjacent genes, a discrepancy observed in many other studies of cell differentiation. More than one third of the Wor1-bound differentially-expressed transcripts were previously unannotated, which explains the formerly puzzling presence of Wor1 at these positions along the genome. Indeed, many of these newly identified Wor1-regulated genes are non-coding and transcribed antisense to coding transcripts. We also found that 5' and 3' untranslated regions (UTRs) of mRNAs in the circuit are unusually long and that 5' UTRs often differ in length between white and opaque cells. These observations suggest that the use of alternative promoters is widespread in the circuit and that important regulatory information is carried in the long UTRs. Further analysis revealed that the revised Wor1 circuit bears several striking similarities to the Oct4 circuit that specifies the pluripotency of mammalian embryonic stem cells. Additional characteristics shared with the Oct4 circuit suggest a set of general hallmarks characteristic of heritable differentiation states in eukaryotes. RNA-Seq was applied to Candida albicans white and opaque cells to identify novel transcripts and UTRs that are differentially regulated between the two cell types. Two biological replicates each of white and opaque cell cultures. One of the white cell RNA samples was split just after isolation to allow a comparison of the poly(A)-selection and ribo-depletion sample preparation strategies.

Project description:Transcriptional networks have been shown to evolve very rapidly, prompting questions as to how such changes arise and are tolerated. Recent comparisons of transcriptional networks across species have implicated variations in the cis-acting DNA sequences near genes as the main cause of divergence. What is less clear is how these changes interact with trans-acting changes occurring elsewhere in the genetic circuit. Here, we report the discovery of a system of compensatory trans and cis mutations in the yeast AP-1 transcriptional network that allows for conserved transcriptional regulation despite continued genetic change. We pinpoint a single species, the fungal pathogen Candida glabrata, in which a trans mutation has occurred very recently in a single AP-1 family member distinguishing it from its Saccharomyces ortholog. Comparison of chromatin immunoprecipitation profiles between Candida and Saccharomyces shows that, despite their different DNA binding domains, the AP-1 orthologs regulate a conserved block of genes. This conservation is enabled by concomitant changes in the cis-regulatory motifs upstream of each gene. Thus, both trans and cis mutations have perturbed the yeast AP-1 regulatory system in such a way as to compensate for one another. This demonstrates an example of “co-evolution” between a DNA-binding transcription factor and its cis-regulatory site, reminiscent of the co-evolution of protein binding partners. 3 Experiments were performed. Three replicates CgAp1-TAP was ChIPped under MMS treatment (GSM397447..GSM397449), two replicates each of ScYap1R79K and ScYap4K252R (GSM594724..GSM594727), were ChIPped under MMS treatment.

Project description:The advent of next-generation sequencing revealed extensive transcription outside the boundaries of annotated protein-coding genes, giving rise to tens of thousands of long non-coding RNAs (lncRNAs). The functional relevance of these transcripts remains unclear. Compellingly, lncRNA expression is strongly linked with adjacent protein-coding gene expression, suggesting potential cis-regulatory roles. To investigate whether these regulatory roles exist, we examine in detail the timing of lncRNA expression relative to transcripts of known function. If a causal cis-regulatory relationship exists, lncRNA activation must necessarily precede changes in adjacent target gene expression. Here, we report a high temporal resolution RNA-seq time course of synchronized T98G human glioblastoma cells responding to serum stimulation. Detailed profiling of the expression dynamics of lncRNAs and protein-coding genes in these synchronized transitioning human cells provides insight into the feasibility of broad-scale cis-regulatory roles for lncRNAs.

Project description:Most variants associated to diseases are located in non-coding regions of the genome, and are thought to be regulatory in nature. Cis-regulatory SNPs (cis-rSNPs) impacting transcription can be identified through the mapping of differences in allelic expression (AE). We mapped common cis-rSNPs of protein coding and non-coding genes in 3 distinct cell-types. We show 70% sharing across tissues and similar genetically controlled transcription for protein-coding genes and lincRNAs. Candidate cis-rSNPs altering the expression of 42 non-coding RNA overlap SNPs underlying GWAS associations for 39 diseases. We uncover a new class of cis-rSNPs leading to disruption of footprint-derived de novo motifs, predominantly bind by repressive factors and implicated in disease susceptibility through overlaps with GWAS SNPs. Finally, we provide proof-of-principle for a new approach for genome-wide functional validation of transcription factor M-bM-^@M-^S SNP interactions. We perturbed NFM-NM-:B action in lymphoblasts and identified 489 cis-regulated transcripts with altered AE after NFkB perturbation. Altogether, we performed a comprehensive analysis of cis-variation in four cell-populations, and provide new tools for the identification of functional variants associated to complex diseases. Mapping cis-rSNPs across 3 distinct cell types in humans

Project description:The differentiation of cells into distinct cell types, each of which is heritable for many generations, underlies many biological phenomena. White and opaque cells of the fungal pathogen Candida albicans are two such heritable cell types, each thought to be adapted to unique niches within their human host. To systematically investigate the differences between the two cell types, we performed strand-specific massively-parallel sequencing of RNA from C. albicans white and opaque cells. Combining the resulting data from both cell types, we first substantially re-annotated the C. albicans transcriptome, finding 1443 novel coding and non-coding transcriptionally active regions. Using the new annotation, we compared differences in transcript abundance between the two cell types with the genomic regions bound by the master regulator of the white-opaque switch (Wor1). We found that the revised transcriptional landscape considerably alters our understanding of the circuit governing differentiation. In particular, we can now resolve the poor concordance between binding of the master regulator and the differential expression of adjacent genes, a discrepancy observed in many other studies of cell differentiation. More than one third of the Wor1-bound differentially-expressed transcripts were previously unannotated, which explains the formerly puzzling presence of Wor1 at these positions along the genome. Indeed, many of these newly identified Wor1-regulated genes are non-coding and transcribed antisense to coding transcripts. We also found that 5' and 3' untranslated regions (UTRs) of mRNAs in the circuit are unusually long and that 5' UTRs often differ in length between white and opaque cells. These observations suggest that the use of alternative promoters is widespread in the circuit and that important regulatory information is carried in the long UTRs. Further analysis revealed that the revised Wor1 circuit bears several striking similarities to the Oct4 circuit that specifies the pluripotency of mammalian embryonic stem cells. Additional characteristics shared with the Oct4 circuit suggest a set of general hallmarks characteristic of heritable differentiation states in eukaryotes.

Project description:Inflammation is characterized by a biphasic cycle consisting initially of a pro-inflammatory phase which is subsequently resolved by anti-inflammatory processes. The coordination of these two disparate states needs to be highly controlled, suggesting that the regulation of the cytokines that drive these processes are intimately linked. Interleukin-1 beta (IL1B) is a master regulator of pro-inflammation and is encoded within the same topologically associated domain (TAD) as interleukin-37 (IL37). IL37 has recently emerged as a powerful anti-inflammatory cytokine which diametrically opposes the function of IL1B. Within this TAD, we identified a novel long non-coding RNA called AMANZI which negatively regulates IL1B expression and trained immunity through the induction of IL37 transcription. We found that the activation of IL37 occurs through the formation of a dynamic long-range chromatin contact that leads to the temporal delay of anti-inflammatory responses. The common variant rs16944 present in AMANZI augments this regulatory circuit, predisposing individuals to enhanced pro-inflammation or immunosuppression. Our work illuminates a chromatin-mediated biphasic circuit coordinating expression of IL1B and IL37, thereby regulating two functionally opposed states of inflammation from within a single TAD.

Project description:Innate immune cells including myeloid cells exhibit dynamic cellular switches during inflammatory and immune responses against infection. These processes are tightly regulated at different levels including the cis-regulatory elements of immune cells. However, it remains unclear how the dynamic states of cis-regulatory elements of innate immune cells are controlled during inflammatory responses. Here we found that histone methylation regulator PTIP orchestrates inflammatory responses of macrophages through regulating acetylation state of enhancers and promoters. Rapid elevated expression of PTIP is observed in primary human and mouse macrophages upon lipopolysaccharide (LPS) stimulation. Loss of PTIP represses transcription of pro-inflammatory genes, and activates expression of anti-inflammatory genes. Mechanistically, we found that, independent of its function in histone methylation, PTIP interacts with acetyltransferase p300 and deacetylase HDACs, and serves as a beacon to recruit them to specific sites of inflammatory genes respectively. PTIP deficiency alters H3K27 acetylation state of cis-regulatory elements of inflammatory genes. Moreover, PTIP and c-JUN shape a positive and feedforward regulatory circuit. In addition, PTIP deletion sustains immunosuppressive function of tumor-associated macrophages (TAMs) and promotes tumor growth. Overall, our findings uncover a critical role of PTIP in altering the acetylation state of cis-regulatory regions and fine-tuning the inflammatory responses of innate immune cells.

Project description:Innate immune cells including myeloid cells exhibit dynamic cellular switches during inflammatory and immune responses against infection. These processes are tightly regulated at different levels including the cis-regulatory elements of immune cells. However, it remains unclear how the dynamic states of cis-regulatory elements of innate immune cells are controlled during inflammatory responses. Here we found that histone methylation regulator PTIP orchestrates inflammatory responses of macrophages through regulating acetylation state of enhancers and promoters. Rapid elevated expression of PTIP is observed in primary human and mouse macrophages upon lipopolysaccharide (LPS) stimulation. Loss of PTIP represses transcription of pro-inflammatory genes, and activates expression of anti-inflammatory genes. Mechanistically, we found that, independent of its function in histone methylation, PTIP interacts with acetyltransferase p300 and deacetylase HDACs, and serves as a beacon to recruit them to specific sites of inflammatory genes respectively. PTIP deficiency alters H3K27 acetylation state of cis-regulatory elements of inflammatory genes. Moreover, PTIP and c-JUN shape a positive and feedforward regulatory circuit. In addition, PTIP deletion sustains immunosuppressive function of tumor-associated macrophages (TAMs) and promotes tumor growth. Overall, our findings uncover a critical role of PTIP in altering the acetylation state of cis-regulatory regions and fine-tuning the inflammatory responses of innate immune cells.