Project description:Metformin is the therapy of choice for treating type 2 diabetes and is currently repurposed for a wide range of diseases including aging. Recent evidence implicates the gut microbiota as a site of metformin action. Combining two tractable genetic models, the bacterium E. coli and the nematode C. elegans, we performed C. elegans RNAseq to investigate the role of the metformin sensitive OP50 and metformin resistant OP50-MR E. coli microbiota in the drug effects on the host. Our data suggest an evolutionarily conserved bacterial mediation of metformin effects on host lipid metabolism and lifespan.

Project description:The Warburg effect, consisting of increased glucose uptake and glycolysis, provides metabolic energy as well as cellular building blocks for tumor growth. Inhibition of the Warburg effect with 2-deoxyglucose (2DG) has been explored in clinical trials with limited efficacy. Blockage of glycolysis can induce autopahgy resulting in alternative energy generation through oxidative phosphorylation providing a potential bypass of the effects of inhibition of glycolysis. Here in we demonstrate that activation of AMPK, as a consequence of energetic stress, induces mitochondrial energy production potentially bypassing the effects of glycolysis inhibition. We thus combined blockage of glycolysis by 2DG with inhibition of the electron transfer complex I (ETC1) in the mitochondria with the clinically applicable antidiabetic drug metformin. The combination resulted in activation of AMPK and autopahgy that however rendered eventual depletion of ATP and cell death. Furthermore, combined inhibition of glycolysis and mitochondrial respiration inhibited tumor growth and markedly decreased metastatic capacity in vivo. In order to understand the mechanism of these metabolic inhibitors, we performed whole genome transcriptional analysis. Human SK-4 esophageal cancer cell lines were treated with 5 different treatment groups [2 deoxy glucose (4mM), Metformin (5mM), AICAR (2mM), 2 deoxy glucose (4mM) plus Metformin (5mM) and 2 deoxy glucose (4mM) plus AICAR (2mM)] with non treated control groups for 12 hrs. Each groups was quadruplicated. Microarray experiments and data analysis were done at Dept. of Systems Biology, MDACC (Houston, USA)

Project description:Metformin is a kind of widely used antidiabetic agent, which regulates glucose homeostasis through inhibiting liver glucose production and increasing glucose uptake in muscle. Recent studies suggest that metformin exhibits anticancer properties in a variety of cancers. Although several antitumor mechanisms have been proposed for metformin action, its mode of action in human liver cancer remains not elucidated. In our study we investigated the underlying molecular mechanisms of metformin’s antitumor effect on Huh-7 cells of hepatocellular carcinoma (HCC) in vitro. RNA sequencing (RNA-seq) was performed to explore the effect of metformin on the transcriptome of Huh-7 cells. The results revealed that 4518 genes (with log2 fold change>1 or < -1, p-adjusted value<0.05) were differentially expressed in Huh-7 cells with treatment of 25mM metformin compared to 0mM metformin including 1812 up-regulated and 2706 down-regulated genes. Gene ontology and KEGG pathway analyses identified 54 classical pathways which were significantly enriched, and 16 pathways are closely associated with cancer, such as cell cycle, DNA replication, ECM-receptor interaction and so on. We selected 11 differentially expressed genes, which are closely associated with HCC to validate their differential expressions through quantitative real-time reverse transcription PCR (qRT-PCR). The result exhibited that the genes of FASN, MCM6, MCM5, MARCKS, FADS2, CXCL1, BMP4, SKP2, KNG1, PCNA were down-regulated and DUSP1 is significantly up-regulated in Huh-7 cells with treatment of 25mM metformin. These differentially expressed genes and pathways might play a crucial part in the antitumor effect of metformin, and might be potential targets of metformin treating HCC. Further investigations are required to evaluate the metformin mechanisms of anti-cancer action in vivo.

Project description:Retroelements, the prevalent class of plant transposons, have major impacts on host genome integrity and evolution. They produce multiple proteins from highly compact genomes and, similarly to viruses, must have evolved original strategies to optimize gene expression, although this aspect has been seldom investigated thus far. Here, we have established a high-resolution transcriptome/translatome map for the near-entirety of Arabidopsis thaliana transposons, using two distinct DNA methylation mutants in which transposon expression is broadly de-repressed. The value of this map to study potentially intact and transcriptionally active transposons in Arabidopsis thaliana is illustrated by our comprehensive analysis of the co-transcriptional and translational features of Ty1/Copia elements, a family of young and active retroelements in plant genomes, and how such features impact their biology. Genome-wide transcript profiling revealed a unique and widely conserved alternative splicing event coupled to premature termination that allows for the synthesis of a short subgenomic RNA solely dedicated to production of the Gag structural protein and preferentially associates with polysomes for efficient translation. Mutations engineered in a transgenic version of the Arabidopsis EVD Ty1/Copia element further show how alternative splicing is crucial for the appropriate coordination of full length and subgenomic RNA transcription. We propose that this hitherto undescribed genome expression strategy, conserved amongst plant Ty1/Copia elements, enables an excess of structural versus catalytic components, mandatory for mobilization.

Project description:Metformin, a commonly used drug prescribed to treat type-2 diabetes, has been found to extend health span and delay cancer incidence and progression. Here, we report that starting chronic treatment with low dose of metformin (0.1% w/w in diet) at one year of age extends health and lifespan in male mice, while a higher dose (1% w/w) was toxic. Treatment with low dose metformin mimicked some of the benefits of calorie restriction, such as improved physical performance, increased insulin sensitivity, and reduced LDL and cholesterol levels. At a molecular level, metformin increased AMP-activated protein kinase activity without attenuation of the mitochondrial electron transport chain activities. Metformin treatment resulted in lower chronic inflammation and increased antioxidant protection, suggesting that the ability of metformin to improve health of laboratory animals may stem from these factors. Our results support that metformin supplementation could be beneficial in extending health and lifespan in humans.

Project description:We describe an application of deep sequencing and de novo assembly of short RNA reads to investigate small interfering (si)RNAs mediated immunity in leaf samples from eight tree taxa naturally occurring in Wytham Woods, Oxfordshire, UK. BLAST search for homologues of contigs in the GenBank identified siRNA populations against a number of RNA viruses and a Ty1-copia retrotransposons in these tree species.

Project description:Here we investigate the nature of cellular heterogeneity in the gene expression of aging and characterize the changes that metformin causes in mouse adipose and muscle at the single-cell resolution. The single cell transcriptomes of ~13,000 cells were captured using single-cell RNA-sequencing, resulting in gene expression data for 13 cell types from the visceral adipose tissue stromal-vascular fraction and ~5,000 cells from 12 cell types from the gastrocnemius muscle. The study design featured three groups of male C57BL/6J mice that corresponded to three-month-old controls (young), 18-month-old controls (old), and 18-month-olds treated with 1000 ppm (0.1% w/w) metformin for 6 weeks (treated). Our analyses demonstrate that metformin’s age-associated changes results in the modulation of an old to young expression profile via a cell type-specific manner. This reversion is demonstrated by significant changes observed in cell-type proportions and the degree of cell-cell heterogeneity. Additionally, metformin is known to restore the dysregulation due to age in autophagy and immune response in adipose, hypoxia in muscle, and inflammatory responses in both tissues. In our data, we detect evidence of these processes at play where endothelial cells, macrophages, and stem/progenitor cells respond most effectively to metformin’s gerotherapeutic response compared to other cell types. We further characterize metformin’s role in reverting age-associated cell-type-specific shifts in the transcriptional space by investigating changes in gene expression distributions and gene regulatory network dynamics.

Project description:The unfolded protein response (UPR) is a cellular defense mechanism against glucose deprivation, a cell condition that occurs in solid tumors. A key feature of the UPR is the activation of the transcription program that allows the cell to cope with endoplasmic reticulum (ER) stress. We used micoarrays to show that the UPR transcription program is disrupted by the antitumor macrocyclic compound versipelostatin (VST) and antidiabetic biguanides metformin, buformin and phenformin, depending on cellular glucose availability. Keywords: stress response, drug response

Project description:In organisms ranging from vertebrates to plants, major components of centromeres are rapidly-evolving repeat sequences, such as tandem repeats (TRs) and transposable elements (TEs). These repeats harbor centromere-specific histone H3 (CENH3), which also evolves rapidly. Complete centromere structures recently determined in human and Arabidopsis suggest frequent integration and purging of retrotransposons within the TR regions of centromeres. Despite the high impact of “centrophilic” retrotransposons on the paradox of rapid centromere evolution, the mechanisms involved in centromere targeting remain poorly understood in any organism. Here we show that both Ty3 and Ty1/Copia LTR elements rapidly turnover within the centromeric TRs of Arabidopsis species. We demonstrate that the Ty1/Copia element Tal1 (Transposon of Arabidopsis lyrata 1) integrates de novo into regions occupied by CENH3 in A. thaliana, and that ectopic expansion of the CENH3 region results in spread of Tal1 integration regions. The integration spectra of chimeric TEs revealed the key structural variations responsible for the contrasting chromatin targeting specificities to centromeres versus gene-rich regions, which have recurrently converted during the evolution of these TEs. Our findings reveal the impact of centromeric chromatin on TE-mediated rapid centromere evolution, with relevance across eukaryotic genomes.

Project description:In organisms ranging from vertebrates to plants, major components of centromeres are rapidly-evolving repeat sequences, such as tandem repeats (TRs) and transposable elements (TEs). These repeats harbor centromere-specific histone H3 (CENH3), which also evolves rapidly. Complete centromere structures recently determined in human and Arabidopsis suggest frequent integration and purging of retrotransposons within the TR regions of centromeres. Despite the high impact of “centrophilic” retrotransposons on the paradox of rapid centromere evolution, the mechanisms involved in centromere targeting remain poorly understood in any organism. Here we show that both Ty3 and Ty1/Copia LTR elements rapidly turnover within the centromeric TRs of Arabidopsis species. We demonstrate that the Ty1/Copia element Tal1 (Transposon of Arabidopsis lyrata 1) integrates de novo into regions occupied by CENH3 in A. thaliana, and that ectopic expansion of the CENH3 region results in spread of Tal1 integration regions. The integration spectra of chimeric TEs revealed the key structural variations responsible for the contrasting chromatin targeting specificities to centromeres versus gene-rich regions, which have recurrently converted during the evolution of these TEs. Our findings reveal the impact of centromeric chromatin on TE-mediated rapid centromere evolution, with relevance across eukaryotic genomes.