Project description:Cancer cells have to constantly adapt their metabolism to support aberrant cell proliferation. However, the functional link between metabolic reprogramming and cell cycle progression remain largely unexplored. Mitochondria rely on the transfer of multiple lipids from the endoplasmic reticulum (ER) to their membranes to be functional. Several mitochondrial-derived metabolites influence cancer cell proliferation by modulating the epigenome. Here we show that the loss of STARD7, a lipid transfer protein whose expression is enhanced in breast cancer, leads to a profound metabolic reprogramming characterized by the increased synthesis of Carnitine derivatives and S-Adenosyl-L-methionine (SAM). Elevated SAM levels causes the accumulation of H3K27 trimethylation, a repressive mark, on many gene promoters coding for candidates involved in cell cycle progression and in the response to oxidative stress. As a result, STARD7 deficiency triggers cell cycle arrest, at least through defective ERa- and EGFR-dependent signaling pathways as well as to autophagy and ciliogenesis. Collectively, our data define STARD7 as a critical candidate involved in cell cycle progression in breast cancer.

Project description:Somatic cells can be reprogrammed to a pluripotent state by nuclear transfer into oocytes, yet developmental arrest often occurs. While incomplete transcriptional reprogramming is known to cause developmental failure, reprogramming also involves concurrent changes in gene expression, cell cycle progression and nuclear structure. Here we study cellular reprogramming events in human and mouse nuclear transfer (NT) embryos prior to embryonic genome activation. We show that genetic instability marked by frequent chromosome segregation errors and DNA damage arise prior to, and independent of, transcriptional activity. These errors occur following transition through DNA replication and are repaired by BRCA1. In the absence of mitotic nuclear remodeling, DNA replication is delayed and errors are exacerbated in subsequent mitosis. These results demonstrate that independent of gene expression, cell type-specific features of cell cycle progression constitute a barrier sufficient to prevent the transition from one cell type to another during reprogramming.

Project description:Metabolic reprogramming is critical for tumor initiation and progression. However, the exact impact of specific metabolic changes on cancer progression is poorly understood. Here, we integrate multimodal analyses of primary and metastatic clonally-related clear cell renal cancer cells (ccRCC) grown in physiological media to identify key stage-specific metabolic vulnerabilities. We show that a VHL loss-dependent reprogramming of branched-chain amino acid catabolism sustains the de novo biosynthesis of aspartate and arginine enabling tumor cells with the flexibility of partitioning the nitrogen of the amino acids depending on their needs. Importantly, we identify the epigenetic reactivation of argininosuccinate synthase (ASS1), a urea cycle enzyme suppressed in primary ccRCC, as a crucial event for metastatic renal cancer cells to acquire the capability to generate arginine, invade in vitro and metastasize in vivo. Overall, our study uncovers a mechanism of metabolic flexibility occurring during ccRCC progression, paving the way for the development of novel stage-specific therapies.

Project description:Reprogramming is achieved within a single cell cycle after mouse nuclear transfer

Project description:<p>Metabolic reprogramming is critical for tumor initiation and progression. However, the exact impact of specific metabolic changes on cancer progression is poorly understood. Here, we integrate multimodal analyses of primary and metastatic clonally-related clear cell renal cancer cells (ccRCC) grown in physiological media to identify key stage-specific metabolic vulnerabilities. We show that a VHL loss-dependent reprogramming of branched-chain amino acid catabolism sustains the de novo biosynthesis of aspartate and arginine enabling tumor cells with the flexibility of partitioning the nitrogen of the amino acids depending on their needs. Importantly, we identify the epigenetic reactivation of argininosuccinate synthase (ASS1), a urea cycle enzyme suppressed in primary ccRCC, as a crucial event for metastatic renal cancer cells to acquire the capability to generate arginine, invade in vitro and metastasize in vivo. Overall, our study uncovers a novel mechanism of metabolic flexibility occurring during ccRCC progression, paving the way for the development of novel stage-specific therapies</p>

Project description:Cancer cells exhibit a well-documented, yet poorly understood, dependence on exogenous methionine, despite retaining the capacity to convert homocysteine to methionine. In contrast, non-tumorigenic cells can proliferate when methionine is replaced by homocysteine. To investigate the mechanistic basis of this methionine dependence, we examined how methionine metabolism impacts cell cycle progression. We identified carboxy-methylation of the catalytic subunit of Protein Phosphatase 2A (PP2A) as a critical node linking methionine availability to proliferation. PP2A methylation was found to be highly sensitive to intracellular S-adenosylmethionine (SAM) levels, with reduced methylation correlating with impaired proliferation under methionine restriction. Overexpression of Protein Phosphatase Methylesterase-1 (PME-1), which demethylates PP2A, or expression of a Leu309-deleted PP2A mutant that mimics the demethylated form, was sufficient to reduce proliferation even in methionine-independent cells. These findings support a model in which methionine limitation lowers SAM availability, thereby decreasing PP2A methylation and impairing cell cycle progression. Our study reveals a novel mechanistic link between methionine metabolism and the cell cycle and suggests that PP2A methylation plays a key role in the unique methionine dependence of cancer cells.

Project description:The complexity and heterogeneity of cancer cells are under-represented by the current experimental models which revolve around primary tumor cells, cancer cell lines, and rodent models. We used the transformed cell model in our studies. IMR90 and BJ fibroblast cells were transformed by three oncogenic genetic factors, SV40 Large-T antigen, H-Ras and human telomerase (hTERT). These transformed cells can grow under anchorage independent conditions, are self-sufficient in growth signals, have decreased sensitivity to apoptosis, and showed recurrent chromosomal abnormalities. Further characterization of transformed cells through cell cycle profiling and mass spectrometry analysis also revealed an increased fraction in the G2/M phase, and an up-regulation of Ku70. Furthermore, transformed cells exhibited increased telomerase activity that was not accountable by hTERT overexpression alone. Microarray results revealed that hTERT overexpression promoted cell migration and the initiation of DNA damage responses; two cellular processes that are important in cancer progression. Collectively, these data imply that IMR90 transformed cell model is an invaluable tool for cancer studies. Our results in the systematic study of this model helped us identify possible early events in cancer transformation and reveal the extra-telomeric effects of telomerase in cell migration and DNA damage initiation. IMR90 and BJ fibroblast cells were transformed by three oncogenic genetic factors, SV40 Large-T antigen, H-Ras and human telomerase (hTERT). Through microarray analysis, gene expression of transformed cells were compared against control cells.

Project description:Neuroendocrine transdifferentiation (NED) of prostate cancer cells and aberrant activation of survival pathways involved in tumorigenesis are among the events that lead to the development of resistance to anti-androgen therapy and are associated with poor prognosis in patients with castration resistance prostate cancer (CRPC). Most of these molecular events appear to be mediated by epigenetic mechanisms, in particular DNA methylation. In this study, we evaluated the antitumor activity and epigenetic modulation of two epigenetic drugs, 5-aza-2’-deoxycytidine (AZA) and S-adenosylmethionine (SAM) in two human CRPC cell lines with NED (NED-CRPC), DU-145 and PC-3. The effects of AZA and SAM on the cell growth proliferation, cell cycle, apoptosis, migration and genome-wide DNA methylation profiling have been evaluated through MTT assay, DNA flow cytometry with propidium iodide, and Annexin V-FITC/propidium iodide staining, wound-healing assay and Infinium450k microarray, respectively. Both epigenetic drugs showed a prominent antitumor activity in NED-CRPC cell line exerted through perturbation of cell cycle progression, induction of apoptosis and migration arrest. AZA and SAM reversed NED in DU-145 and PC-3, respectively. Moreover, AZA treatment profoundly modified DNA methylation pattern, sustaining a pervasive hypomethylation of the genome, with a relevant effect on several pathways involved in regulation of cell migration, cell proliferation and apoptosis. Among these, the Wnt/beta-catenin signaling appeared to be the most directly involved. In conclusion, both AZA and SAM showed a relevant antitumor activity on NED-CRPC cell lines. This opens a new scenario in the therapy of this lethal variant of prostate cancer.

Project description:Emerging evidence indicates that metabolic dysregulation drives prostate cancer (PCa) progression and metastasis. AMPK is a master regulator of metabolism although its role in PCa remains unclear. Here we show that genetic and pharmacological activation of AMPK provides a dramatic protective effect on PCa progression in vivo. We show that AMPK activation induces PGC1-alpha expression leading to a catabolic metabolic reprogramming of PCa cells. This catabolic state is characterised by increased mitochondrial gene expression, increased fatty acid oxidation, decreased lipogenic potential, decreased cell proliferation and decreased cell invasiveness. Together, these changes inhibit PCa disease progression. Additionally, we identify a gene network involved in cell cycle regulation that is inhibited by AMPK activation. Strikingly, we show a strong correlation between this gene network and PGC1-alpha gene expression in human PCa. Taken together our findings strongly support the use of AMPK activators for clinical treatment of PCa to improve patient outcome.

Project description:FOXM1 is a key transcription factor regulating cell cycle progression, DNA damage response, and a host of other hallmark cancer features, but the role of the FOXM1 cistrome in driving estrogen receptor-positive (ER+) vs. ER- breast cancer clinical outcomes remains undefined. Chromatin immunoprecipitation sequencing (ChIP-Seq) coupled with RNA sequencing (RNA-Seq) analyses was used to identify FOXM1 target genes in breast cancer cells (MCF-7) where FOXM1 expression was either induced by cell proliferation or repressed by p53 upregulation.