Project description:Micro RNAs (miRNAs) are a class of small, non-coding RNA species that play critical roles throughout cellular development and regulation. miRNA expression patterns taken from various tissue types often point to the cellular lineage of an individual tissue

Project description:Regeneration of missing body parts can be observed in diverse animal phyla, but it remains unclear to which extent these capacities rely on shared or divergent principles. Research into this question requires detailed knowledge about the involved molecular and cellular principles in suitable reference models. By combining single-cell RNA sequencing and mosaic transgenesis in the marine annelid Platynereis dumerilii, we map cellular profiles and lineage restrictions during posterior regeneration. Our data reveal cell-type specific injury responses, re-expression of positional identity factors, and the re-emergence of stem cell signatures in multiple cell populations. Epidermis and mesodermal coelomic tissue produce distinct putative posterior stem cells (PSCs) in the emerging blastema. A novel mosaic transgenesis strategy reveals both developmental compartments and lineage restrictions during regenerative growth. Our work supports the notion that posterior regeneration involves dedifferentiation, and reveals molecular and mechanistic parallels between annelid and vertebrate regeneration.

Project description:Evaluating RNA quality and transcriptomic profile of beef muscle tissue over time post-mortem may provide insight on RNA degradation and underlying biological and functional mechanisms influencing the biochemical changes occurring post-mortem that transform muscle tissue to meat. RNA-sequencing was performed on longissimus thoracis et lumborum (LTL) muscle samples collected at 5 time points [0 h (45 min post-mortem), 6 h, 24 h, 48 h, and 72 h (drip cooler)] post-mortem from British Continental crossbred beef heifers (n=7). Processed mRNA reads were aligned to the ARS-UCD1.2 bovine genome assembly. Differential expression (DE) analysis identified from 51 to 1434 upregulated and 27 to 2256 downregulated DE genes at individual time points compared to time 0 h, showing a trend of both up and downregulated genes increasing over time . Gene ontology and KEGG pathway term enrichment analyses revealed significant enrichment of biological and molecular functions relating to cellular energy, oxidative stress and NADH activity specific to early time points, as well as cellular signaling and transport and ribosome activity at specific to late time points. This study also revealed that LTL muscle tissue samples, collected as late as 72 h post-mortem remained at a high RNA integrity, suggesting opportunities for late sampling regimes for RNA-Seq analysis of post-mortem muscle tissue and the potential for larger studies to associate desirable meat quality traits with post-mortem transcriptome activity. Additionally, this study highlights the need to evaluate non-coding genetic features involved with epigenetic regulation in post-mortem muscle tissue, as indicated by non-coding RNA transcripts detected post-mortem, including small nucleolar RNA, mitochondrial DNA genes, and long non-coding RNA.

Project description:We describe a chemical method to label and purify 4-thiouridine (s4U) -containing RNA. We demonstrate that methanethiolsulfonate (MTS) reagents form disulfide bonds with s4U more efficiently than the commonly used HPDP-biotin, leading to higher yields and less biased enrichment. This increase in efficiency allowed us to use s4U-labeling to study global microRNA (miRNA) turnover in proliferating cultured human cells without perturbing global miRNA levels or the miRNA processing machinery. This improved chemistry will enhance methods that depend on tracking different populations of RNA such as 4-thiouridine-tagging to study tissue-specific transcription and dynamic transcriptome analysis (DTA) to study RNA turnover. s4U metabolic labeling of RNA in 293T cells, followed by biochemical enrichment of labeled RNA with two biotinylation reagents, RNAs >200nt and miRNAs in separate experiments

Project description:Tissue specific expression of non-coding RNAs

Project description:Our structural and biochemical studies show that S. cerevisiae RNA Polymerase II (RNAPII) homodimerizes through the stalk domain (formed by the Rpb4-Rpb7 subunits). To explore the biological impact of disrupting this interaction we introduced a triple point mutation at the RNAPII dimerization interface in Rpb7 (Q96A, H97A, F109K). To test the impact of the dimerization mutant on RNA synthesis and 3' end processing in WT and Rpb7-QHF cells, we labelled nascent transcripts with 4tU which enabled subsequent biotinylation and purification of newly-synthesized transcripts. Nascent transcripts were then used to prepare strand-specific RNA-seq libraries.

Project description:We report a method for high throughput mapping of transcriptional enhancers, genomic regulatory regions that activate lineage-specific transcription. Since tissue-specific enhancers are bound by the transcriptional co-activator p300, we developed murine knock-in alleles that permit Cre-dependent, lineage-specific p300 in vivo biotinylation and high affinity pulldown on immobilized streptavidin. Subsequent next generation sequencing of p300-bound genomic DNA identified lineage-specific enhancers. By driving this system with lineage-specific Cre transgenes, we mapped enhancers active in embryonic endothelial cells/blood or skeletal muscle. Analysis of these enhancer sequences identified new transcription factor heterodimer motifs that likely regulate transcription in these lineages. Furthermore, we identified candidate enhancers that regulate adult heart- or lung- specific endothelial cell specialization.

Project description:The molecular chaperone heat shock protein 90 (HSP90) is thought to buffer genetic variation uncoupling phenotypic outcome from individual genotypes. HSP90 thus acts as an evolutionary capacitor by facilitating an accumulation of natural genetic variation. The molecular mechanism underlying the buffering ability is unclear, and HSP90-contingent genetic variation maps both to coding and non-coding parts of the genome. Our genome-wide data indicate that a compromised chaperoning activity of HSP90 causes derepression of endogenous retroviruses (ERVs) in mouse somatic cells. This results in an upregulation of host genes located in the neighborhood of pre-existing ERVs insertion sites. We provide genetic and biochemical evidence that HSP90 cooperates with KAP1/ SETDB1 histone methyltranferase pathway to repress ERVs. Individual mouse strains have unique integration sites of ERVs in their genomes. Consequently distinct genes are responsive to HSP90 inhibitor in different mouse strains depending on the position of the genes vis-à-vis strain-specific ERV insertion sites. Since ERVs have been exapted to drive novel transcriptional networks during mammalian evolution, HSP90 may have acted as a capacitor by buffering variation caused by ERV in non-coding regions of the genome. Our studies provide the first molecular framework by which HSP90 can mitigate genetic variation in gene-regulatory regions affecting gene expression and phenotypes.

Project description:Transcriptional regulation controls various cellular functions via the interactionsbetween cell-type-specific transcription factors (TFs) and their chromosomaltargets. While multiple TFs capable of converting cell fates from one to anotherhave been reported, only a few systematic studies aiming to understand thefate conversion potential of numerous individual TFs have been reported. Here,we propose an iTF-seq method (pooled induction of individual TFs followed bysingle-cell RNA sequencing) to identify potent TFs capable of converting cellfates and elucidate their lineage specification potential at a single-cell level.Enabling metabolic biotinylation of TFs during the process, the method allowssubsequent multi-omics approaches to understand underlying actionmechanisms of TFs during cell fate changes. Our pilot iTF-seq of 80 TFs inmouse embryonic stem (ES) cells has identified multiple previously known andunknown TFs triggering transcriptome changes within one day of TF induction.Subsequent tests revealed that Gcm1 and Otx2 function as activators andpioneer factors, while they resulted in distinct cell fates and gene expressionprograms upon induction.

Project description:Developmental programs often rely on parallel morphogenetic mechanisms that guarantee precise tissue architecture. While redundancy constitutes an obvious selective advantage, little is known on how novel morphogenetic mechanisms emerge during evolution. In zebrafish, rhombomeric boundaries behave as an elastic barrier, preventing cell intermingling between adjacent compartments. Here, we identify the fundamental role of the small-GTPase Rac3b in actomyosin cables assembly at hindbrain boundaries. We show the novel rac3b/rfng/sgca regulatory cluster, which is specifically expressed at the boundaries, emerged in the Ostariophysi superorder by chromosomal rearrangement that generated new cis-regulatory interactions. By combining 4C-seq, ATAC-seq, transgenesis and CRISPR-induced deletions, we characterized this regulatory domain, identifying hindbrain boundaries-specific cis-regulatory elements. Our results suggest that the capacity of boundaries to act as an elastic mesh for segregating rhombomeric cells evolved by cooption of critical genes to a novel regulatory block, refining the mechanisms for hindbrain segmentation.