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 ER?- 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:S-adenosyl methionine (SAM) is a ubiquitous methyl donor that was reported to have chemo- protective activity against liver cancer, however the molecular footprint of SAM has been unknown. We show here that SAM selectively inhibits growth, transformation and invasiveness of hepatocellular carcinoma cell lines but not normal primary liver cells. Analysis of the transcriptome of SAM treated and untreated cancer cell lines HepG2 and SKHep1 and primary liver cells reveals pathways involved in cancer and metastasis that are upregulated in cancer cells and silenced by SAM. Analysis of the methylome using bisulfite mapping of captured promoters and enhancers reveals that SAM hyper-methylates and silences genes in pathways of growth and metastasis that are activated in liver cancer cells. Depletion of two SAM silencing targets similarly reduces cellular transformation and invasiveness. Taken together these data provide a molecular foundation for SAM as an anticancer agent.

Project description:S-adenosyl methionine (SAM) is a ubiquitous methyl donor that was reported to have chemo- protective activity against liver cancer, however the molecular footprint of SAM has been unknown. We show here that SAM selectively inhibits growth, transformation and invasiveness of hepatocellular carcinoma cell lines but not normal primary liver cells. Analysis of the transcriptome of SAM treated and untreated cancer cell lines HepG2 and SKHep1 and primary liver cells reveals pathways involved in cancer and metastasis that are upregulated in cancer cells and silenced by SAM. Analysis of the methylome using bisulfite mapping of captured promoters and enhancers reveals that SAM hyper-methylates and silences genes in pathways of growth and metastasis that are activated in liver cancer cells. Depletion of two SAM silencing targets similarly reduces cellular transformation and invasiveness. Taken together these data provide a molecular foundation for SAM as an anticancer agent.

Project description:Epigenetics (DNA methylation) profiling of bovine in vitro cultured expanded blastocysts (EB) comparing control non-treated expanded blastocysts with SAM-treated expanded blastocysts. S-Adenosyl methionine (SAM) is the global methyl donor providing methyl

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:Reyes-Palomares2012 - a combined model hepatic polyamine and sulfur aminoacid metabolism - version2 Mammalian polyamine metabolism consists of a bi-cycle with two required entrances, omithine and S-adenosyl methionine (SAM), and several alternative exists. The relevant regulatory roles of the short half-life enzymes ornithine decarboxylase (ODC), S-adenosyl methione decarboxylase (SAMDC) and spermindine/spermine acetyl transferase (SSAT) in polyamine metabolism are well studied, and has been modelled here. This model is described in the article: A combined model of hepatic polyamine and sulfur amino acid metabolism to analyze S-adenosyl methionine availability. Reyes-Palomares A, Montañez R, Sánchez-Jiménez F, Medina MA Amino Acids, February 2012, Volume 42, Issue 2-3, pp 597-610 Abstract: Many molecular details remain to be uncovered concerning the regulation of polyamine metabolism. A previous model of mammalian polyamine metabolism showed that S-adenosyl methionine availability could play a key role in polyamine homeostasis. To get a deeper insight in this prediction, we have built a combined model by integration of the previously published polyamine model and one-carbon and glutathione metabolism model, published by different research groups. The combined model is robust and it is able to achieve physiological steady-state values, as well as to reproduce the predictions of the individual models. Furthermore, a transition between two versions of our model with new regulatory factors added properly simulates the switch in methionine adenosyl transferase isozymes occurring when the liver enters in proliferative conditions. The combined model is useful to support the previous prediction on the role of S-adenosyl methionine availability in polyamine homeostasis. Furthermore, it could be easily adapted to get deeper insights on the connections of polyamines with energy metabolism. Notes by the author: This model combines BIOMD0000000190 and BIOMD0000000268 from BioModels Database, both models include corrections respect to their originals publications. To simulate a MATI/MATIII switch to MATII in proliferating liver: We set to 0 the Vmax parameters of MATI and MATIII We included MATII reaction equation. We add a regulation factor dependent of SAM levels in ODC and SAMDCe rates of synthesis (66.5/[SAM]). H2O2 was increased in a 50 % according to an initial state ofproliferating and regenerating liver. This model is hosted on BioModels Database and identified by: MODEL1305060001 . To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models . To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:One-carbon metabolism is a universal hub for cellular metabolism and epigenetic regulation.1–3 Here, we report that formaldehyde (FA), a one-carbon unit that organisms produce in substantial quantities through folate metabolism,4 is a regulator of the one-carbon cycle via the biosynthesis of S-adenosyl-L-methionine (SAM), an essential one-carbon building block for synthesis of nucleotides, amino acids, and methylated nucleic acids and proteins.5 Activity-based protein profiling (ABPP) in mouse liver tissue identifies FA-sensitive cysteine sites across the proteome, revealing several one-carbon cycle targets including S-adenosylmethionine synthetase isoform 1 (MAT1A), the terminal enzyme in SAM biosynthesis. Biochemical studies of the formaldehyde-MAT1A interaction establish FA-dependent inhibition of MAT1A activity through a conserved C120 site, as the MAT2A isoform lacking this cysteine is not FA-sensitive. CRISPR knockout-generated HepG2 cell models that predominantly express either MAT1A or MAT2A show that MAT1A-positive cells respond to FA treatment in a dose-dependent manner by decreasing their SAM levels and downstream RNA methylation, whereas the MAT2A-positive cells are not affected by FA. Our findings reveal an unexpected interplay between SAM and FA, two central one-carbon units to influence the overall methylation potential of the cell.

Project description:KDELR2 promotes breast cancer proliferation via HDAC3-mediated cell cycle progression

Project description:This study examines the therapeutic plausibility of using universal methyl group donor S-adenosylmethionine (SAM) to block breast cancer development, growth, and metastasis. cancer. Anti-tumor and anti-metastatic activity of SAM was evaluated through a series of studies in vitro using two different human breast cancer cell lines and in vivo using a MDA-MB-231 xenograft model of breast cancer. The data shown in this array is obtained from control and SAM-treated MDA-MB-231 cell lines.

Project description:Transcriptome (total RNA) profiling of bovine in vitro cultured expanded blastocysts (EB) comparing control non-treated expanded blastocysts with SAM-treated expanded blastocysts. S-Adenosyl methionine (SAM) is the global methyl donor providing methyl group for variety of biomolecules such as DNA , histone, RNA, lipids and etc.