Project description:Majority of histones are replaced by protamine during spermatogenesis, but small amount of histones are retained in mammalian spermatozoa. Since nucleosomes in spermatozoa influence epigenetic inheritance, it is important how histones are distributed on sperm genome. We have found that the swim-up sperm used in many studies contains about 10% of immature sperm which do not yet complete the histone-to-protamine replacement. We have developed the novel method to purify the histone replacement-completed sperm (HRCS), and to completely solubilize nucleosomes from cross-linked HRCS without MNase digestion. Here, we analyzed H3 binding profiles in total sperm and HRCS by Chromatin IP – sequencing (ChIP-seq) analysis, and DNA methylation profiles in swim-up sperm and HRCS by target bisulfite sequencing (TGSB).
Project description:Increasing evidence indicates that paternal dietary conditions influence the metabolic disorders of offspring. Previous studies suggested the involvement of epigenetic regulation for such phenomena, but the mechanism remains elusive. To reveal the molecular function of stress-dependent epigenetic regulator ATF7 in paternal inheritance of dietry effect on offpring phenotype, we analyzed ATF7-binding profiles in testicular germ cells by ChIP-seq, DNA methylation profiles in sperm by TGBS, small RNA expression profiles in HRCS by RNA-seq,and whole expression profiles in offspring liver by expression array analysis, using wild-type and ATF7 heterozygous mutant mice.
Project description:Majority of histones are replaced by protamine during spermatogenesis, but small amount of histones are retained in mammalian spermatozoa. Since nucleosomes in spermatozoa influence epigenetic inheritance, it is important how histones are distributed on sperm genome. We have found that the swim-up sperm used in many studies contains about 10% of immature sperm which do not yet complete the histone-to-protamine replacement. We have developed the novel method to purify the histone replacement-completed sperm (HRCS), and to completely solubilize nucleosomes from cross-linked HRCS without MNase digestion. Here, we analyzed H3 binding profiles in total sperm and HRCS by Chromatin IP – sequencing (ChIP-seq) analysis, and DNA methylation profiles in swim-up sperm and HRCS by target bisulfite sequencing (TGSB).
Project description:Genome-wide microarray analysis of the effects of swim-training on zebrafish larval development. Zebrafish were subjected to swim-training from 5 days post fertilization (dpf) until 10 dpf. Subsequently, we performed a genome-wide microarray analysis of trained and control fish at 10 dpf. The goal of the project was to investigate the effects of swim-training on the gene expression level during zebrafish larval development
Project description:Genome-wide microarray analysis of the effects of swim-training on zebrafish larval development. Zebrafish were subjected to swim-training from 5 days post fertilization (dpf) until 10 dpf. Subsequently, we performed a genome-wide microarray analysis of trained and control fish at 10 dpf. The goal of the project was to investigate the effects of swim-training on the gene expression level during zebrafish larval development Two-condition experiment: control vs trained fish. RNA was isolated from 10 control fish and from 10 trained fish. Subsequently, each sample was labeled with Cy3 and Cy5 in order to correct for dye bias. Control-Cy3 and Trained-Cy5 were hybridized on array 1 and Trained-Cy5 and Control-Cy3 were hybridized on array 2.
Project description:Genome-wide microarray analysis of the effects of swim-training on caudal fin development in zebrafish larvae. Zebrafish were subjected to swim-training from 5 days post fertilization (dpf) until 10 dpf. Subsequently, we performed a genome-wide microarray analysis on the caudal fins of control and trained fish at 10 dpf. The goal of the project was to investigate the effects of swim-training on the gene expression level during caudal fin development in zebrafish larvae.
Project description:We developed two novel sperm epigenetic clocks by applying Super Learner, an ensemble machine learning algorithm, to predict age from sperm EPIC array DNA methylation data via individual CpG sites and differentially methylated regions (DMRs). Overall, our cox model showed that one-year increase in our developed sperm epigenetic age (SEA) was associated with up to 15% reduction in couples time-to-pregnancy (TTP).
Project description:Genome-wide microarray analysis of the effects of swim-training on caudal fin development in zebrafish larvae. Zebrafish were subjected to swim-training from 5 days post fertilization (dpf) until 10 dpf. Subsequently, we performed a genome-wide microarray analysis on the caudal fins of control and trained fish at 10 dpf. The goal of the project was to investigate the effects of swim-training on the gene expression level during caudal fin development in zebrafish larvae. Two-condition experiment: control vs trained fish. RNA was isolated from pooled caudal fins of 15 control fish (in duplo: pooled control samples (C2 and C3)) and of 15 trained fish (in duplo: pooled trained samples( T2 and T3)). Subsequently, each pooled RNA sample of control and trained caudal fins was labeled with Cy3 and Cy5 in order to correct for dye bias. We included a technical replicate of the labeled C2 and T2 samples.
Project description:The potential that adolescent chemotherapy can impact the epigenetic programming of the germ line to influence later life adult fertility and promote epigenetic inheritance was investigated. Adult males approximately ten years after pubertal exposure to chemotherapy were compared to adult males with no previous exposure. Sperm were collected to examine differential DNA methylation regions (DMR) between the exposed and control populations. A statistically significant signature of DMRs was identified in the chemotherapy exposed male sperm. The DMRs, termed epimutations, were found in CpG desert regions of primarily 1 kilobase size. Gene associations and correlations to genetic mutations (copy number variation) were also investigated. Observations indicate adolescent chemotherapy exposure can promote epigenetic alterations that persist in later life. The germline (i.e. sperm) epimutations identified suggest chemotherapy has the potential to promote epigenetic inheritance to the next generation.