Imprinting at the KBTBD6 locus involves species-specific m ternal methylation and monoallelic expression in livestock animals

Background The primary differentially methylated regions(DMRs) which are maternally hypermethylated serve as imprinting control regions(ICRs) that drive monoallelic gene expression, and these ICRs have been investigated due to their implications in mammalian development. Although a subset of genes has been identified as imprinted, in-depth comparative approach needs to be developed for identification of species-specific imprinted genes. Here, we examined DNA methylation status and allelic expression at the KBTBD6 locus across species and tissues and explored potential mechanisms of imprinting.Results Using whole-genome bisulfite sequencing and RNA-sequencing on parthenogenetic and normal porcine embryos, we identified a maternally hypermethylated DMR between the embryos at the KBTBD6 promoter Cp G island and paternal monoallelic expression of KBTBD6. Also, in analyzed domesticated mammals but not in humans, non-human primates and mice, the KBTBD6 promoter Cp G islands were methylated in oocytes and/or allelically methyl-ated in tissues, and monoallelic KBTBD6 expression was observed, indicating livestock-specific imprinting. Further analysis revealed that these Cp G islands were embedded within transcripts in porcine and bovine oocytes which coexisted with an active transcription mark and DNA methylation, implying the presence of transcription-dependent imprinting.Conclusions In this study, our comparative approach revealed an imprinted expression of the KBTBD6 gene in domesticated mammals, but not in humans, non-human primates, and mice which implicates species-specific evolution of genomic imprinting.

DNA methylation in poultry:a review

As an important epigenetic modification,DNA methylation is involved in many biological processes such as animal cell differentiation,embryonic development,genomic imprinting and sex chromosome inactivation.As DNA methylation sequencing becomes more sophisticated,it becomes possible to use it to solve more zoological problems.This paper reviews the characteristics of DNA methylation,with emphasis on the research and application of DNA methylation in poultry.

Reduced non-CpG methylation is a potential epigenetic target after spinal cord injury

DNA methylation is a critical epigenetic regulator in the occurrence and development of diseases and is closely related to various functional responses in relation to spinal cord injury.To investigate the role of DNA methylation in spinal cord injury,we constructed a library with reduced-representation bisulfite sequencing data obtained at various time points(day 0-42)after spinal cord injury in mice.Global DNA methylation levels,specifically non-CpG(CHG and CHH)methylation levels,decreased modestly following spinal cord injury.Stages post-spinal cord injury were classified as early(day 0-3),intermediate(day7-14),and late(day 28-42)based on similarity and hie rarchical cluste ring of global DNA methylation patterns.The non-CpG methylation level,which included CHG and CHH methylation levels,was markedly reduced despite accounting for a minor proportion of total methylation abundance.At multiple genomic sites,including the 5’untranslated regions,promoter,exon,intron,and 3’untranslated regions,the non-CpG methylation level was markedly decreased following spinal cord injury,whereas the CpG methylation level remained unchanged at these locations.Approximately one-half of the differentially methylated regions were located in intergenic areas;the other differentially methylated regions in both CpG and non-CpG regions were cluste red in intron regions,where the DNA methylation level was highest.The function of genes associated with differentially methylated regions in promoter regions was also investigated.From Gene Ontology analysis results,DNA methylation was implicated in a number of essential functional responses to spinal cord injury,including neuronal synaptic connection creation and axon regeneration.Notably,neither CpG methylation nor non-CpG methylation was implicated in the functional response of glial or inflammatory cells.In summary,our work elucidated the dynamic pattern of DNA methylation in the spinal co rd following injury and identified reduced nonCpG methylation as an epigenetic target after spinal cord injury in mice.

Genome-Wide Analysis of DNA Methylation in Soybean

Cytosine methylation is an important mechanism for dynamical regulation of gene expression and trans- posable element （TE） mobility during plant developmental processes. Here, we identified the transcription start sites of genes using high-throughput sequencing and then analyzed the DNA methylation status in soybean roots, stems, leaves, and cotyledons of developing seeds at single-base resolution. Profiling of DNA methylation in different organs revealed 2162 differentially methylated regions among organs, and a portion of hypomethylated regions were correlated with high expression of neighboring genes. Because of the different distribution of class I TEs （retrotransposons） and class II TEs （DNA transposons）, the promoters of the lowest-expressed genes showed higher levels of CG and CHG methyla- tion but a lower level of CHH methylation. We further found that the CHH methylation level of class II TEs was higher than class I TEs, possibly due to the presence of more smRNAs in class II TEs. In cotyledons of developing seeds, smRNA abundance was roughly positively correlated with hypermethylated regions but negatively related to hypomethylated regions. These studies provide significant insights into the complicated interplays among DNA methylation, smRNA abundance, TE distribution, and gene expression in soybean.

Epigenome-wide DNA methylation study of whole blood in patients with sporadic amyotrophic lateral sclerosis

Background:Epigenetics,and especially DNA methylation,contributes to the pathogenesis of sporadic amyotrophic lateral sclerosis(SALS).This study aimed to investigate the role of DNA methylation in SALS using whole blood of SALS patients.Methods::In total,32 SALS patients and 32 healthy controls were enrolled in this study.DNA was isolated from whole blood collected from the participants.DNA methylation profiles were generated using Infinium MethylationEPIC BeadChip.Results:We identified 34 significant differentially methylated positions(DMPs)in whole blood from SALS patients,compared with the healthy controls.Of these DMPs,five were hypermethylated and 29 were hypomethylated;they corresponded to 13 genes.For the DMPs,ATAD3B and BLK were hypermethylated,whereas DDO,IQCE,ABCB1,DNAH9,FIGN,NRP1,TMEM87B,CCSAP,ST6GALNAC5,MYOM2,and RUSC1-AS1 were hypomethylated.We also identified 12 differentially methylated regions(DMRs),related to 12 genes(NWD1,LDHD,CIS,IQCE,TNF,PDE1C,LGALS1,CSNK1E,LRRC23,ENO2,ELOVL2,and ELOVL2-AS1).According to data from the Kyoto Encyclopedia of Genes and Genomes database,DNAH9 and TNF are involved in the amyotrophic lateral sclerosis(ALS)pathway.Correlation analysis between clinical features and DNA methylation profiling indicated that the methylation level of ELOVL2 and ARID1B was positively associated with the age of onset(r=0.86,adjust P=0.001)and disease duration(r=0.83,adjust P=0.01),respectively.Conclusions:We found aberrant methylation in DMP-and DMR-related genes,implying that many epigenetic alterations,such as the hypomethylation of DNAH9 and TNF,play important roles in ALS etiology.These findings can be helpful for developing new therapeutic interventions.