Project description:Purpose: Many mammalian genes exhibit circadian expression patterns concordant with periodic binding of transcription factors, chromatin modifications and chromosomal interactions. We determined whether lamina-associated domains (LADs) display oscillatory circadian patterns of interaction with nuclear lamin B1 during hte circadian cycle, and identified any relationship to changes in gene expression patterns in oscillatory LADs or in their vinicity. Methods: To this end, we mapped LADs by chromatin immunoprecipitation-sequencing (ChIP-seq) of lamin B1 (LMNB1) (antibody ab16048, Abcam) from mouse livers colected every 6 h, for 30 h, after entrainment of the circadian clock by 24-h fasting and refeeding. Gene expression profiles were also analyzed by RNA-sequencing (RNA-seq) at the same time points. Results and Conclusions: We report periodic interactions of chromatin domains with nuclear lamin B1, suggesting rhythmic associations of fractions of the genome with the nuclear lamina. Entrainment of the circadian clock by fasting and refeeding is accompanied in mouse liver by a gain of lamin-chromatin interactions followed by oscillations in these interactions at hundreds of lamina-associated domains (LADs). A subset of these oscillations exhibit periodicity and affect one or both LAD borders or entire stand-alone LADs. Periodic LADs are however not a dominant feature of these variable LADs, as most LADs are conserved during the circadian cycle. LAD oscillations are for the most part asynchronous between the 5’ and 3’ ends of LADs. Periodic LADs also uncoupled from gene expression patterns, periodic or not, within or in vicinity of these LADs. Accordingly, periodic genes, including central clock-control genes, are located megabases away from LADs, suggesting their residence in a transcriptionally permissive environment throughout the circadian cycle. Our data suggest autonomous oscillatory associations of fractions of the genome with the nuclear lamina, providing new evidence for rhythmic spatial configurations of chromatin. However, our data also argue that periodic LADs constitute a minor fraction of variable LADs, and reflect stochasticity in variable lamin-chromatin interactions during the circadian cycle.

Project description:Cell-autonomous circadian oscillations strongly influence tissue physiology and pathophysiology of peripheral organs. Recent in vivo findings in the heart demonstrate that the circadian clock controls oscillatory gene expression programs in the adult myocardium. However, whether in vitro human embryonic stem (ES) cell-derived cardiomyocytes can establish circadian rhythmicity is unknown. Here we report that while undifferentiated human ES cells do not possess a functional clock, oscillatory expression of known core clock genes emerges during directed cardiac differentiation, with robust rhythms in day 30 cardiomyocytes. Our data reveal a stress related oscillatory network of genes that underlies a time-dependent response to doxorubicin, a frequently used anti-cancer drug with cardiotoxic side effects. These results provide a set of oscillatory genes that is relevant to functional cardiac studies and that can be deployed to uncover the potential contribution of the clock to other processes such as cardiac regeneration.

Project description:Aim: Innate circadian rhythms are critical for optimal tissue-specific functions, including skeletal muscle, a major insulin-sensitive tissue responsible for glucose homeostasis. We determined whether transcriptional oscillations are associated with CpG methylation changes in skeletal muscle. Materials & methods: We performed rhythmicity analysis on the transcriptome and CpG methylome of circadian synchronized myotubes. Results: We identified several transcripts and CpG-sites displaying oscillatory behavior, which were enriched with GO terms related to metabolism and development. Oscillating CpG methylation was associated with rhythmic expression of 31 transcripts. Conclusion: Although circadian oscillations may be regulated by rhythmic DNA methylation, strong rhythmic associations between transcriptome and CpG methylation were not identified. This resource constitutes a transcriptomic/epigenomic atlas of skeletal muscle and regulation of circadian rhythms.

Project description:Aim: Innate circadian rhythms are critical for optimal tissue-specific functions, including skeletal muscle, a major insulin-sensitive tissue responsible for glucose homeostasis. We determined whether transcriptional oscillations are associated with CpG methylation changes in skeletal muscle. Materials & methods: We performed rhythmicity analysis on the transcriptome and CpG methylome of circadian synchronized myotubes. Results: We identified several transcripts and CpG-sites displaying oscillatory behavior, which were enriched with GO terms related to metabolism and development. Oscillating CpG methylation was associated with rhythmic expression of 31 transcripts. Conclusion: Although circadian oscillations may be regulated by rhythmic DNA methylation, strong rhythmic associations between transcriptome and CpG methylation were not identified. This resource constitutes a transcriptomic/epigenomic atlas of skeletal muscle and regulation of circadian rhythms.

Project description:The circadian clock drives the oscillatory expression of thousands of genes across all tissues and bears significant implications for human health. RNA-seq time-series experiments interrogate the mechanistic links between transcriptional rhythms and phenotypic outcomes. Analysis methods must overcome the challenges of sparse temporal sampling, noisy data, and non-strictly periodic dynamics. Moreover, there remains a need for differential cycling analysis methods that can identify complex changes in rhythmicity for 2-sample comparisons across experimental conditions. We present TimeChange -- a non-parametric and model-free method for the quantification of differential dynamics across experimental conditions. The method leverages a data transformation technique known as time-delay embedding to reconstruct the underlying state space for each gene-of-interest. Takens’ embedding theorem implies that rhythmic dynamics will exhibit circular patterns in the embedded space. TimeChange non-parametrically compares the distributions of points in the embedded space via the Fasano-Franceschini test to assess whether the topological structures differ significantly between phenotypes, thereby quantifying differences in transcriptional dynamics without requiring knowledge of the underlying model. Application of TimeChange to synthetic data shows that it accurately identifies changes in transcriptomic dynamics, including differences in amplitude/peaked-ness; changes in sawtooth asymmetries; and trending oscillatory drifts (e.g. linear, damped, and contractile). We further show that the method has potential utility beyond circadian dynamics. For instance, initial tests of TimeChange using erg rowing-machine data shows accurate classification of differential stroke dynamics in real time, suggesting potential uses of TimeChange in the field of sports science and medicine.

Project description:Genome-wide expression analysis of two circadian oscillatory mechanisms in the mouse liver; To identify the genes of which the circadian expression is regulated by endogenous glucocorticoids, we performed DNA microarray analysis using hepatic RNA from adrenalectomized (ADX) and sham-operated mice. Mice were housed in a 12:12 h light-dark cycle (LD12:12; lights on at zeitgeber time (ZT) 0) for at least two weeks before the day of the experiment. Liver samples were dissected, quickly frozen, and stored in liquid nitrogen. Total RNA was purified from pools of 3 animal tissues collected at each time-point using ISOGEN (Nippon Gene Co., Ltd., Japan). Hybridization to Affymetrix GeneChip (MG-U74Av2) arrays proceeded as described (Oishi K et al., J Biol Chem, 278, 41519-41527, 2003). The average difference (AD) value for each gene was provided by GeneChip software. To identify putative glucocorticoid-regulated circadian genes, we compared AD values between two time points (ZT2 and ZT14) in sham operated and in ADX mice. We applied three criteria to the selection of putative glucocorticoid-regulated circadian genes: (i) the AD value is marked as “present” by the GeneChip software in at least one of two time points, (ii) the AD value exhibits a 2-fold or greater change in sham-operated mice and (iii) the fold change is below 2-fold in ADX mice. We identified 169 genes that fluctuated between day and night in the livers of sham-operated mice. Among these, 100 lost circadian rhythmicity in ADX mice. On the other hand, the circadian expression of clock or clock-related genes such as mPer2 and DBP remained almost totally intact in the liver of ADX mice. The present study showed that the circadian expression of one type of liver genes in the mouse is governed by core components of the circadian clock such as CLOCK and BMAL1, and the other depends on endogenous glucocorticoids.

Project description:the nature of the interaction between RNA and Polycomb repressive complex 2 (PRC2) has been an area of intensive investigation. Although PRC2 is now established as a bona fide RNA-binding protein, specific motifs have not been fully elucidated, nor has the association of PRC2-RNA complexes with active genes been reconciled. Here we employ denaturing CLIP to identify RNA motifs demonstrating high-affinity binding to PRC2 (Kd 11-80 nM). Mutating the motifs diminishes binding affinity in vitro and attenuates PRC2’s repressive function in vivo. A large fraction of interactions occurs at promoter-proximal regions and associates with POL-II pausing. Furthermore, although PRC2-associated nascent transcripts are highly expressed, ablating PRC2 further increases their expression. Thus, PRC2-RNA interactions are rheostats that operate at the level of transcription elongation to fine-tune gene activity, explaining why they frequently occur within active genes. PRC2-RNA interactions also impact expression of neighboring genes, supporting the classical model that RNA targets PRC2 to gene in cis. Our study supports a model in which RNA specifically targets PRC2 for two repressive functions — (i) control of POL-II pausing, and (ii) marking chromatin with H3K27me3.

Project description:Oscillatory lysosomal activity for disposal of the components of the cellular clock is essential to sustain organismal circadian rhythms

Project description:Membrane type I-matrix metalloproteinase (MT1-MMP/Mmp14) is an unusual MMP because it is essential for survival in mice with multiple organ systems being affected for reasons that are unclear. Here, we show that the protein (MT1-MMP) and gene (Mmp14) are under strict circadian clock control and conditional knockout in fibroblasts leads to ~16% of the proteome losing or inverting circadian rhythmicity. The result is loss of the actin cytoskeleton and cell-matrix adhesions and major imbalance of the matrisome. Lack of collagen-I monomer turnover results in excess fibril formation in the absence of Mmp14. In the absence of Mmp14, paired-like homeodomain transcription factor 2 (Pitx2) is upregulated and remains in the nucleus where it drives Plod2 expression. The overall result is accumulation of collagen fibrils and elevated pyridinoline crosslinking that renders collagen fibrils insoluble. In conclusion, Mmp14 is a master regulator of circadian rhythms affecting the actin cytoskeleton and cell microenvironment.

Project description:The role of Polycomb group (PcG) was studied on RNA Polymerase II (Pol II) pausing phenomenon. Wild type and Polycomb mutant (esc) embryos were used for ChIP-Seq experiments using Pol II and histone methylation antibodies. Enhanced Pol II occupancy was observed for thousands of genes in esc mutant embryos, including genes not known to be bound by PRC2 or having H3K27me3 associated. Most of these genes exhibit a concomitant reduction in H3K27me3 and increase in H3K4me3 at promoter-proximal regions. Silent genes lacking promoter-associated paused Pol II in wild-type embryos are converted into “poised” genes with paused Pol II in esc mutants. We suggest that this conversion of silent genes into poised genes might render differentiated cell types susceptible to switches in identity in PcG mutants. ChIP-Seq data was generated for antibodies against Pol-II, H3K4me3, H3K27me3 in both wild type and esc mutant Drosophila embryos (0-2hr, 8-12hr, and 18-24hr embryos). In addition GRO-Seq data was generated for 18-24hr esc mutant embryos.