Project description:Epidemiological surveys first indicated that obesity and type II diabetes generated by lipid rich diets may be efficiently inherited, both paternally and maternally. This apparent exception to the fundamental law of non heritability of acquired characters was more recently documented in laboratory organisms but the transgenerational signal remained a matter of speculation. Here we show that experimental transfer to healthy one-cell embryos of testis RNA prepared from males raised on high-fat-diet (HFD) results in the development of obesity and diabetes in the adult. Body weight, fasting glucose levels, response to insulin, glucose tolerance, RNA levels of leptin and stearoyl-CoA desaturase were all affected in mice born after RNA microinjection to the same extent as in the progenitors and in their sexual offspring. Surprisingly, neither microarray hybridization nor deep sequencing of the inducer and control RNAs showed a differential expression of known regulators of adipogenesis, but only modest variations in a series of transcripts. Transgenerational maintenance appears as one instance of the RNA-mediated heredity of epigenetic traits previously demonstrated in experimental systems ranging from the worm to the mouse. The relationship between lipid-rich diet and changes in testicular RNAs on one side and the nature of the mark imprinted on the one-cell embryo by RNA transfer and responsible for pathological developments at later stages are questions of interest for future studies. Two experimental groups composed of four individuals. Controls = M1N,M2N,TN1,TN2 and Experimentals= M1W,M2W,M3W,M5W.

Project description:Gene expression analysis of testis RNA obtained from mice fed on High Fat and Standard diets. The aim of the study is to identify differentially expressed transcript in testis of the obese males which might be involved in the RNA-mediated paternal heredity of diet-induced obesity and typeII diabete Total RNA obtained from testis of mice fed on High Fat and standard diets

Project description:Gene expression analysis of testis RNA obtained from mice fed on High Fat and Standard diets. The aim of the study is to identify differentially expressed transcript in testis of the obese males which might be involved in the RNA-mediated paternal heredity of diet-induced obesity and typeII diabete

Project description:Epidemiological surveys first indicated that obesity and type II diabetes generated by lipid rich diets may be efficiently inherited, both paternally and maternally. This apparent exception to the fundamental law of non heritability of acquired characters was more recently documented in laboratory organisms but the transgenerational signal remained a matter of speculation. Here we show that experimental transfer to healthy one-cell embryos of testis RNA prepared from males raised on high-fat-diet (HFD) results in the development of obesity and diabetes in the adult. Body weight, fasting glucose levels, response to insulin, glucose tolerance, RNA levels of leptin and stearoyl-CoA desaturase were all affected in mice born after RNA microinjection to the same extent as in the progenitors and in their sexual offspring. Surprisingly, neither microarray hybridization nor deep sequencing of the inducer and control RNAs showed a differential expression of known regulators of adipogenesis, but only modest variations in a series of transcripts. Transgenerational maintenance appears as one instance of the RNA-mediated heredity of epigenetic traits previously demonstrated in experimental systems ranging from the worm to the mouse. The relationship between lipid-rich diet and changes in testicular RNAs on one side and the nature of the mark imprinted on the one-cell embryo by RNA transfer and responsible for pathological developments at later stages are questions of interest for future studies.

Project description:Long non-coding RNAs (lncRNAs) play an important role in epigenetic regulation, and abnormalities may lead to male infertility. To investigate whether lncRNAs are involved in intergenerational inheritance of obesity and obesity-induced decline in fertility, we divided mice into obesity (F0 mice fed a high-fat diet, F0-HFD) and non-obese (F0 mice fed normal chow, F0-NC) model groups and their male offspring (F1-HFD and F1-NC, respectively). We examined the differences in the expression levels of lncRNAs and mRNAs in the F0-HFD/F0-NC and F1-HFD/F1-NC groups. The results revealed similar expression patterns in the F1-HFD/F0-HFD groups at both the lncRNA and mRNA levels. The maximum difference in the lncRNA expression was observed between the F0-HFD and F0-NC groups. The differentially expressed lncRNA targets and mRNAs identified in our study are mainly involved in GnRH signalling pathway, metabolic process, and Hippo signalling pathway; similarly expressed lncRNAs and mRNAs in F1-HFD/F0-HFD are closely linked with G-protein coupled receptor signalling pathway, pancreatic polypeptide receptor activity, and lysine biosynthesis, which may play an important role in the molecular mechanism of intergenerational inheritance of obesity. Furthermore, potential genes that might play important roles in the pathogenesis of obesity-related low fertility were revealed by lncRNA-and mRNA-interaction studies based on the microarray expression profiles. In conclusion, we found that lncRNA could be involved in obesity-induced infertility by expressing abnormalities, which could act as genetic vectors of paternal inheritance of obesity.

Project description:[This corrects the article DOI: 10.18632/oncotarget.18138.].

Project description:To investigate whether lncRNAs are involved in intergenerational inheritance of obesity and obesity-induced decline in fertility, we divided mice into obesity (F0 mice fed a high-fat diet, F0-HFD) and non-obese (F0 mice fed normal chow, F0-NC) model groups and their male offspring (F1-HFD and F1-NC, respectively). We examined the differences in the expression levels of lncRNAs and mRNAs in the F0-HFD/F0-normal and F1-HFD/F1-normal groups. The results revealed similar expression patterns in the F1-HFD/F0-HFD groups at both the lncRNA and mRNA levels. The maximum difference in the lncRNA expression was observed between the F0-HFD and F0-NC groups. The differentially expressed lncRNA targets and mRNAs identified in our study are mainly involved in GnRH signalling pathway, metabolic process, and Hippo signalling pathway; similarly expressed lncRNAs and mRNAs in F1-HFD/F0-HFD are closely linked with G-protein coupled receptor signalling pathway, pancreatic polypeptide receptor activity, and lysine biosynthesis, which may play an important role in the molecular mechanism of intergenerational inheritance of obesity. Furthermore, potential genes that might play important roles in the pathogenesis of obesity-related low fertility were revealed by lncRNA-and mRNA-interaction studies based on the microarray expression profiles. In conclusion, we found that lncRNA could be involved in obesity-induced infertility by expressing abnormalities, which could act as genetic vectors of paternal inheritance of obesity.

Project description:OBJECTIVES:Paternally inherited alterations in epigenetic programming are emerging as relevant factors in numerous disease states, including the growth and metabolic defects observed in fetal alcohol spectrum disorders. In rodents, chronic paternal alcohol use induces fetal growth restriction, as well as sex-specific alterations in insulin signaling and lipid homeostasis in the offspring. Based on previous studies, we hypothesized that the observed metabolic irregularities are the consequence of paternally inherited alterations liver x receptor (LXR) activity. METHODS:Male offspring of alcohol-exposed sires were challenged with a high-fat diet and the molecular pathways controlling glucose and lipid homeostasis assayed for LXR-induced alterations. RESULTS:Similar to findings in studies employing LXR agonists we found that the male offspring of alcohol-exposed sires display resistance to diet-induced obesity and improved glucose homeostasis when challenged with a high-fat diet. This improved metabolic adaptation is mediated by LXRα trans-repression of inflammatory cytokines, releasing IKKβ inhibition of the insulin signaling pathway. Interestingly, paternally programmed increases in LXRα expression are liver-specific and do not manifest in the pancreas or visceral fat. CONCLUSIONS:These studies identify LXRα as a key mediator of the long-term metabolic alterations induced by preconception paternal alcohol use.

Project description:Dietary fiber is regarded to improve host metabolic disorders through modulating gut microbiota. The study was to investigate the effects of inulin with different degree of polymerization (DP) on adiposity, related metabolic syndrome, and the possible mechanisms from the points of gut microbiota and metabolite changes. C57Bl/6J male mice were randomly allocated to normal diet (ND) group, high-fat diet (HFD) group, two HFD groups with short-chain inulin (HFD-S) and medium and long-chain inulin (HFD-ML) for 8 weeks. Compared with HFD treatment, ML-inulin supplementation significantly decreased weight gain, hepatic steatosis, chronic inflammation, and increased insulin sensitivity, energy expenditure and thermogenesis. This could be mimicked by S-inulin supplementation to some degree although it is not as effective as ML inulin. Also, mice treated with S and ML inulin had a remarkable alternation in the composition of gut microbiota and increased the production of short-chain fatty acids (SCFAs). However, reduced serum levels of essential fatty acids, vitamins B1 and B3 by HFD were further decreased by both inulin supplementations. ML inulin can prevent HFD-induced obesity and the associated metabolic disorders, and may be used as novel gut microbiota modulator to prevent HFD-induced gut dysbiosis and metabolic disorders.

Project description:High-sucrose diets are common in daily life but harmful to human health. Cyclocarya paliurus leaves (CPL) are a kind of tea used to alleviate metabolic diseases and are widely used in China. However, the effects of CPL on high-sucrose-induced obesity are unknown. This study aimed to describe the changes in gut metabolism induced by a high-sucrose diet and to reveal the potential mechanisms through which CPL alleviate high-sucrose diet-induced obesity. A high-sucrose-induced obesity model was generated in C57BL/6J and KM mice. The effects of CPL on obese mice were evaluated, and changes in the gut microbiota and intestinal metabolites induced by CPL treatment were observed. Furthermore, the fecal microbiota transplantation (FMT) method was used to prove that the effects of CPL on high-sucrose induced obesity depend on the changes of gut microbiota. The results of the C57BL/6J mouse experiment revealed that high-sucrose intake induced fat deposition and altered the gut microbiota. CPL treatment decreased fat deposition and alleviated disorders of the gut microbiota. Furthermore, CPL treatment increased the utilization of amnio acids, long fatty acids and saccharides and produced more bile acids, indole derivatives and less trimethylamine (TMA). A confirmatory experiment in KM mice also revealed that CPL can alleviate obesity, ameliorate intestinal metabolic disorders, and upregulate the expression of tight junction proteins in the intestinal mucosa. These results demonstrated that CPL could prevent high sucrose-induced obesity and generate more beneficial intestinal microbial metabolites but less harmful intestinal microbial metabolites.