Project description:The molecular circadian clock, which controls rhythmic 24-hour oscillation of genes, proteins, and metabolites, is disrupted across many human cancers. Deregulated expression of MYC oncoprotein has been shown to alter expression of molecular clock genes, leading to a disruption of molecular clock oscillation across cancer types. It remains unclear what benefit cancer cells gain from suppressing clock oscillation, and how this loss of molecular clock oscillation impacts global gene expression and metabolism in cancer. We hypothesized that MYC suppresses oscillation of gene expression and metabolism to instead upregulate pathways involved in biosynthesis in a static, non-oscillatory fashion. To test this, cells from distinct cancer types with inducible MYC or the closely related N-MYC were examined, using detailed time-series RNA-sequencing and metabolomics, to determine the extent to which MYC activation disrupts global oscillation of genes, gene expression, programs, and metabolites. We focused our analyses on genes, pathways, and metabolites that changed in common across multiple cancer cell line models. We report here that MYC disrupted over 85% of oscillating genes, while instead promoting enhanced ribosomal and mitochondrial biogenesis and suppressed cell attachment pathways. Notably, when MYC is activated, biosynthetic programs that were formerly circadian flipped to being upregulated in an oscillation-free manner. Further, activation of MYC ablates the oscillation of nutrient transporter proteins while greatly upregulating transporter expression, cell surface localization, and intracellular amino acid pools. Finally, we report that MYC disrupts metabolite oscillations and the temporal segregation of amino acid metabolism from nucleotide metabolism. Our results demonstrate that MYC disruption of the molecular circadian clock releases metabolic and biosynthetic processes from circadian control, which may provide a distinct advantage to cancer cells.

Project description:Circadian clock is a highly conserved regulatory system which could coordinate many physiological processes with external stimuli, displaying oscillation with a periodicity of ~24 hour. Dysfunction of circadian clock has been involved in the pathogenesis of a broad spectrum of diseases such as metabolic diseases and chronic kidney disease. However the role of circadian clock in diabetic nephropathy remains largely unknown.

Project description:The molecular circadian clock, which controls rhythmic 24-hour oscillation of genes, proteins, and metabolites, is disrupted across many human cancers. Deregulated expression of MYC oncoprotein has been shown to alter expression of molecular clock genes, leading to a disruption of molecular clock oscillation across cancer types. However, it remained unclear how this loss of molecular clock oscillation impacted global gene expression and metabolism in cancer, and what benefit cancer cells might gain from suppressing clock oscillation. We hypothesized that MYC suppresses oscillation of gene expression and metabolism to instead upregulate pathways involved in biosynthesis in a static, non-oscillatory fashion. To test this, we utilized cells from distinct cancer types with inducible MYC or the closely related N-MYC to determine, using detailed time-series RNA-sequencing and metabolomics, the extent to which MYC activation disrupts global oscillation of genes, gene expression, programs, and metabolites. We focused our analyses on genes, pathways, and metabolites that changed in common across multiple cancer cell line models. We report here that MYC disrupted over 85% of oscillating genes, while instead promoting enhanced ribosomal and mitochondrial biogenesis and suppressed cell attachment pathways. Notably, when MYC is activated, biosynthetic programs that were formerly circadian flipped to being upregulated in an oscillation-free manner. Further, activation of MYC ablates the oscillation of nutrient transporter glycosylation while greatly upregulating transporter expression, cell surface localization, and intracellular amino acid pools. Finally, we report that MYC disrupts metabolite oscillations and the temporal segregation of amino acid metabolism from nucleotide metabolism. Our results demonstrate that MYC disruption of the molecular circadian clock releases metabolic and biosynthetic processes from circadian control, which may provide a distinct advantage to cancer cells.

Project description:The molecular circadian clock, which controls rhythmic 24-hour oscillation of genes, proteins, and metabolites, is disrupted across many human cancers. Deregulated expression of MYC oncoprotein has been shown to alter expression of molecular clock genes, leading to a disruption of molecular clock oscillation across cancer types. However, it remained unclear how this loss of molecular clock oscillation impacted global gene expression and metabolism in cancer, and what benefit cancer cells might gain from suppressing clock oscillation. We hypothesized that MYC suppresses oscillation of gene expression and metabolism to instead upregulate pathways involved in biosynthesis in a static, non-oscillatory fashion. To test this, we utilized cells from distinct cancer types with inducible MYC or the closely related N-MYC to determine, using detailed time-series RNA-sequencing and metabolomics, the extent to which MYC activation disrupts global oscillation of genes, gene expression, programs, and metabolites. We focused our analyses on genes, pathways, and metabolites that changed in common across multiple cancer cell line models. We report here that MYC disrupted over 85% of oscillating genes, while instead promoting enhanced ribosomal and mitochondrial biogenesis and suppressed cell attachment pathways. Notably, when MYC is activated, biosynthetic programs that were formerly circadian flipped to being upregulated in an oscillation-free manner. Further, activation of MYC ablates the oscillation of nutrient transporter glycosylation while greatly upregulating transporter expression, cell surface localization, and intracellular amino acid pools. Finally, we report that MYC disrupts metabolite oscillations and the temporal segregation of amino acid metabolism from nucleotide metabolism. Our results demonstrate that MYC disruption of the molecular circadian clock releases metabolic and biosynthetic processes from circadian control, which may provide a distinct advantage to cancer cells.

Project description:Recent reports indicate hypoxia influences the clock through the transcriptional activities of hypoxia inducible factors (HIFs) at clock genes. Unexpectedly, we uncover a profound disruption of the circadian clock and diurnal transcriptome when hypoxic cells are permitted to acidify, recapitulating the tumor microenvironment. Buffering against acidification or inhibiting lactic acid production fully rescues circadian oscillation. Acidification of several human and murine cell lines, as well as primary murine T cells, suppresses mechanistic target of rapamycin complex 1 (mTORc1) signaling, a key regulator of translation in response to metabolic status. We find acid drives peripheral redistribution of normally perinuclear lysosomes, inhibiting lysosome-bound mTOR. Restoring mTORc1 signaling and the translation it governs rescues clock oscillation, revealing a model in which lactic acid produced during the cellular metabolic response to hypoxia suppresses the circadian clock through diminished translation of clock constituents.

Project description:Circadian rhythms are daily physiological and behavioral changes governed by an internal molecular clock, and dysfunctions in circadian rhythms have long been associated with various neurodegenerative diseases. Abnormal sleep-wake cycle often precedes the onset of cognitive and motor symptoms in patients, while the pathological changes may further exacerbate the disturbance in circadian cycle. It is unclear whether dysregulated circadian rhythm is a consequence of, or a contributing factor for, neurodegeneration. In addition, the evidence directly connecting the neurodegeneration-associated proteins to core circadian clock gene expression remains sparse. Here we show that FUS, a RNA-binding protein implicated in the pathogenesis of ALS and frontotemporal dementia, exhibits a bi-directional regulation with circadian rhythm. Our meta-analysis of RNAseq datasets and subsequent biochemical analysis revealed FUS as a gene regulated by circadian oscillation. Furthermore, NR1D1 binds the FUS promoter and regulates the amplitude of FUS oscillation. Meanwhile, FUS is recruited by transcriptional co-repressor PSF, and is found in the same complex as Bmal-Clock to repress Per2 expression. More strikingly, in cells and brain tissues from homozygous knock-in rats, the pathogenic R521C mutant FUS significantly alters the oscillation patterns of core circadian genes even at young age. Therefore, our results have revealed a novel bi-directional mechanism whereby dysregulated circadian clock and FUS expression may exacerbate neurodegeneration via mutual influence.

Project description:Wilms Tumor, the most common pediatric kidney cancer, evolves from the failure of terminal differentiation of the embryonic kidney. Here we show that over-expression of the heterochronic regulator Lin28 during kidney development in mice markedly expands nephrogenic progenitors by blocking their final wave of differentiation, ultimately resulting in pathology highly reminiscent of Wilms tumor. Gene expression analysis was performed on a total of 8 kidneys samples, including 4 tumors samples from Lin28 transgenic mice and 4 control kidneys

Project description:The oscillation status of the circadian clock during late gestation is not clear. To gain a better understanding on the oscillation state of the clock and possible influences by maternal cues, we performed transcriptome analyses on the fetal liver tissue during late gestation. Fetal liver transcriptome data were analyzed and compared to adult mouse data in the public database: GSE11923 and GSE13093 (only samples GSM327130 to GSM327141). Re-analyzed (gc-RMA) data from GSE11923 and GSE13093 linked below as supplementary files. Fetal mouse liver tissues were collected at four hours intervals across embryonic day 18 and day 19. Groups 1 and 2.

Project description:Wilms tumors are pediatric cancers thought to arise from kidney-specific stem cells. In order to identify transcriptional and epigenetic mechanisms that drive these malignant cells, we compared genomewide chromatin profiles of Wilms tumors to embryonic stem (ES) cells and normal kidney. Data represent examination of genome-wide chromatin modifications in primary Wilms tumors, fetal and mature kidney.

Project description:The oscillation status of the circadian clock during late gestation is not clear. To gain a better understanding on the oscillation state of the clock and possible influences by maternal cues, we performed transcriptome analyses on the fetal liver tissue during late gestation. Fetal liver transcriptome data were analyzed and compared to adult mouse data in the public database: GSE11923 and GSE13093 (only samples GSM327130 to GSM327141). Re-analyzed (gc-RMA) data from GSE11923 and GSE13093 linked below as supplementary files.