Project description:Intrauterine growth restriction (IUGR) affects 7-10% of pregnancies and is associated with cardiovascular remodeling and dysfunction which persists into adulthood. The underlying subcellular remodeling and cardiovascular programming events are still poorly documented. Cardiac muscle is central in the fetal adaptive mechanism to IUGR given its high energetic demands. The energetic homeostasis depends on the correct interaction of several molecular pathways and the adequate arrangement of intracellular energetic units (ICEUs), where mitochondria interact with the contractile machinery and the main cardiac ATPases to enable a quick and efficient energy transfer. We studied subcellular cardiac adaptations to IUGR in an experimental rabbit model. We evaluated the ultrastructure of ICEUs with transmission electron microscopy and observed an altered spatial arrangement in IUGR, with significant increases in cytosolic space between mitochondria and myofilaments. A global decrease of mitochondrial density was also observed. In addition, we conducted a global gene expression profile by advanced bioinformatics tools to assess the expression of genes involved in the cardiomyocyte energetic metabolism, and identified four gene modules with a coordinated over-representation in IUGR: oxygen homeostasis (GO: 0032364), mitochondrial respiratory chain complex I (GO:0005747), oxidative phosphorylation (GO: 0006119) and NADH dehydrogenase activity (GO:0003954). These findings might contribute to changes in energetic homeostasis in IUGR. The potential persistence and role of these changes in long term cardiovascular programming deserves further investigation. In this study, we used gene expression arrays to investigate differences between two experimental groups: IUGR and control. The design includes paired samples.

Project description:Intrauterine growth restriction (IUGR) affects 7-10% of pregnancies and is associated with cardiovascular remodeling and dysfunction which persists into adulthood. The underlying subcellular remodeling and cardiovascular programming events are still poorly documented. Cardiac muscle is central in the fetal adaptive mechanism to IUGR given its high energetic demands. The energetic homeostasis depends on the correct interaction of several molecular pathways and the adequate arrangement of intracellular energetic units (ICEUs), where mitochondria interact with the contractile machinery and the main cardiac ATPases to enable a quick and efficient energy transfer. We studied subcellular cardiac adaptations to IUGR in an experimental rabbit model. We evaluated the ultrastructure of ICEUs with transmission electron microscopy and observed an altered spatial arrangement in IUGR, with significant increases in cytosolic space between mitochondria and myofilaments. A global decrease of mitochondrial density was also observed. In addition, we conducted a global gene expression profile by advanced bioinformatics tools to assess the expression of genes involved in the cardiomyocyte energetic metabolism, and identified four gene modules with a coordinated over-representation in IUGR: oxygen homeostasis (GO: 0032364), mitochondrial respiratory chain complex I (GO:0005747), oxidative phosphorylation (GO: 0006119) and NADH dehydrogenase activity (GO:0003954). These findings might contribute to changes in energetic homeostasis in IUGR. The potential persistence and role of these changes in long term cardiovascular programming deserves further investigation.

Project description:Hexokinase catalyzes the first committed step in glucose metabolism by phosphorylating glucose to produce glucose-6-phosphate. Highly glycolytic proliferating cells such as cancer cells take advantage of HK2 expression to accelerate glucose metabolism even in the presence of oxygen. This acceleration not only provides sufficient glycolytic intermediates to support the anabolic demands of the cells but also inevitably accompanies increased formation of metabolic end products such as lactate. Currently, the effect of lactate caused by HK2-mediated metabolic alteration is largely unknown. A recent study found that lactate plays a role in an epigenetic alteration known as histone lactylation. Here, using RNA-seq and CUT&Tag chromatin profiling, we study the effect of HK2 and lactate on gene expression via histone lactylation (H3K18la).

Project description:Hexokinase catalyzes the first committed step in glucose metabolism by phosphorylating glucose to produce glucose-6-phosphate. Highly glycolytic proliferating cells such as cancer cells take advantage of HK2 expression to accelerate glucose metabolism even in the presence of oxygen. This acceleration not only provides sufficient glycolytic intermediates to support the anabolic demands of the cells but also inevitably accompanies increased formation of metabolic end products such as lactate. Currently, the effect of lactate caused by HK2-mediated metabolic alteration is largely unknown. A recent study found that lactate plays a role in an epigenetic alteration known as histone lactylation. Here, using RNA-seq and CUT&Tag chromatin profiling, we study the effect of HK2 and lactate on gene expression via histone lactylation (H3K18la).

Project description:Regulation of gene expression by the CtBP family of NADH-sensitive transcriptional regulators, in MCF7 cells under normoxia and hypoxia. To determine the effect of CtBP knockdown on gene expression in MCF7 we transfected cells with an siRNA (5′-GGGAGGACCUGGAGAAGUUdTdT-3′/3′-dTdTCCCUCCUGGACCUCUUCAA-5′, obtained from Ambion) targetting both CtBP1 and CtBP2 (versus control siRNA). After 48 hours cells were either transferred to a hypoxic chamber (1% oxygen), or maintained in normoxia, for 18 hours.

Project description:To discover the core gene expression features of CtBP1, CtBP2 differently regulated in ovarian cancer SKOV3 cells. The compared the whole transcript expression profiling between CtBP1 knockdown, CtBP2 knockdown and scramble control in ovarian cancer skov3 cells.

Project description:A unifying characteristic of aggressive cancers is a profound anabolic shift in metabolism to enable sustained proliferation and biomass expansion. The ribosome is centrally situated to sense metabolic states but whether it impacts systems that promote cellular survival is unknown. Here, through integrated chemical-genetic analyses, we find that a dominant transcriptional effect of blocking protein translation in cancer cells is complete inactivation of heat shock factor 1 (HSF1), a multifaceted transcriptional regulator of the heat-shock response and many other cellular processes essential for tumorigenesis. Translational flux through the ribosome reshapes the transcriptional landscape and links the fundamental anabolic processes of protein production and energy metabolism with HSF1 activity. Targeting this link deprives cancer cells of their energy and chaperone armamentarium thereby rendering the malignant phenotype unsustainable. We used ChIP-Seq to examine affect of rocaglates and cycloheximide on HSF1 genomic occupancy in MCF7 and M0-91 cancer cells.

Project description:Brain tumor initiating cells (BTICs), also known as cancer stem cells, hijack high-affinity glucose uptake normally active in brain to maintain energy demands in dynamic tumor microenvironments. Using unbiased metabolomics and genomic analyses, we discovered that de novo purine synthesis is functionally upregulated in BTICs, mediating glucose-sustained anabolic metabolism. Inhibiting purine synthesis abrogated BTIC growth, self-renewal, and in vivo tumor formation by depleting intracellular pools of purine nucleotides, supporting purine synthesis as potential therapeutic point of fragility. In contrast, differentiated brain tumor cells retained proliferative potential with targeting of purine biosynthetic enzymes, suggesting a selective dependence in BTICs. Upstream transcriptional activation of purine synthesis is mediated by MYC. Elevated expression of purine synthetic enzymes correlates with poor prognosis in glioblastoma patients. Collectively, our results suggest that a stem-like state in brain cancer is associated with metabolic reprogramming to fuel tumor hierarchy, revealing potential BTIC cancer dependencies amenable to targeted therapy.

Project description:Molecular mechanisms triggered by high dietary beta-carotene (BC) intake in lung are largely unknown. We performed microarray gene expression analysis on lung tissue of BC supplemented beta-carotene 15,150-monooxygenase 1 knockout (Bcmo1-/-) mice, which are—like humans—able to accumulate BC. Our main observation was that the genes were regulated in an opposite direction in male and female Bcmo1-/- mice by BC. The steroid biosynthetic pathway was overrepresented in BC-supplemented male Bcmo1-/- mice. Testosterone levels were higher after BC supplementation only in Bcmo1-/- mice, which had, unlike wild-type (Bcmo1+/+) mice, large variations. We hypothesize that BC possibly affects hormone synthesis or metabolism. Since sex hormones influence lung cancer risk, these data might contribute to an explanation for the previously found increased lung cancer risk after BC supplementation (ATBC and CARET studies). Moreover, effects of BC may depend on the presence of frequent human BCMO1 polymorphisms, since these effects were not found in wild-type mice.

Project description:A unifying characteristic of aggressive cancers is a profound anabolic shift in metabolism to enable sustained proliferation and biomass expansion. The ribosome is centrally situated to sense metabolic states but whether it impacts systems that promote cellular survival is unknown. Here, through integrated chemical-genetic analyses, we find that a dominant transcriptional effect of blocking protein translation in cancer cells is complete inactivation of heat shock factor 1 (HSF1), a multifaceted transcriptional regulator of the heat-shock response and many other cellular processes essential for tumorigenesis. Translational flux through the ribosome reshapes the transcriptional landscape and links the fundamental anabolic processes of protein production and energy metabolism with HSF1 activity. Targeting this link deprives cancer cells of their energy and chaperone armamentarium thereby rendering the malignant phenotype unsustainable. Gene Expression Data We used microarrays to examine affect of rocaglates on gene expression in cancer cell lines. MCF7 breast cancer cells were treated with either 200 nM Rocaglamide A or DMSO, as a control. Two biological replicates for all samples.