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SRX19045479: GSM6935945: NMR, Liver, H3K27ac, NMR34, do17587; Heterocephalus glaber; ChIP-Seq
1 ILLUMINA (Illumina HiSeq 4000) run: 7.6M spots, 379.2M bases, 124.3Mb downloads

External Id: GSM6935945_r1
Submitted by: Queen Mary University of London
Study: Epigenomic analysis of regulatory evolution in mole rats
show Abstracthide Abstract
Changes in gene regulation have long been though to underlie most phenotypic differences between species. Subterranean rodents, and in particular the naked mole-rat (NMR), have attracted substantial attention due to their proposed phenotypic adaptations, which include hypoxia tolerance, metabolic changes and cancer resistance. However, it is largely unknown what regulatory changes may associate with these phenotypic traits, and whether these are unique to the NMR, the mole-rat clade or also present in other mammals. Here, we undertook a comparative genomics approach to identify genome-wide promoter and enhancer regions harbouring epigenomic hallmarks of regulatory activity, in heart and liver from two mole-rat species (NMR and DMR) and two rodent outgroups. To identify promoters and enhancers displaying robust shifts in regulatory activity in the mole-rat clade, we adapted and applied a phylogenetic modeling approach to quantitatively compare epigenomic signals at orthologous locations, while accounting for phylogenetic distance and inter-species variation. This method identified thousands of orthologous promoter and enhancer regions with increased activity in ancestral or single-species mole-rat branches, as well as hundreds of promoters and enhancers with reduced activity in mole-rats versus other rodents. These elements underlie both shared tissue-specific changes in gene regulation associated with mole-rat evolution, which include metabolic and functional adaptations in heart and liver. Moreover, by comparing mole-rat specific changes in promoters and enhancers between ancestral and single-species branches, our data revealed a number of candidate pathways with stepwise regulatory changes during mole-rat evolution. Lastly, we analysed the genomic properties of non-alignable promoters and enhancers in mole-rats, and report (i) their overlap with specific repetitive elements and transcription factor binding sites; and (ii) their association with metabolic gene functions. On the whole, these comparative analyses reveal mole-rat specific epigenomic changes across orthologous and non-mappable promoters and enhancers - which inform previously reported mole-rat adaptations from a gene regulation perspective. Overall design: Chromatin immunoprecipitation sequencing (ChIP-seq) for histone postranslational modifications H3K27ac, H3K4me3 and H3K4me1 in liver and heart tissues from naked mole-rat, damaraland mole-rat, guinea pig and mouse (with three to six biological replicates)
Sample: NMR, Liver, H3K27ac, NMR34, do17587
SAMN32756487 • SRS16462236 • All experiments • All runs
Library:
Name: GSM6935945
Instrument: Illumina HiSeq 4000
Strategy: ChIP-Seq
Source: GENOMIC
Selection: ChIP
Layout: SINGLE
Construction protocol: Tissues were prepared by direct perfusion of the liver with PBS, followed by dicing the whole organs (liver and heart) in small pieces around 1cm3. Blood clots within the heart ventricles were removed. Cross-linking of the diced tissue was performed in 1% formaldehyde solution for 20 min, addition of 250 mM glycine and incubation for a further 10 min to neutralize the formaldehyde. After homogenization of cross-linked tissues in a dounce tissue grinder, samples were washed twice with PBS and lysed according to published protocols (SCHMIDT et al. 2009 for ChIP and Krijger et al. 2020 for 4C) to solubilize DNA-protein complexes. For ChIP, chromatin was fragmented to 300 bp average size by sonication on a Misonix sonicator 3000 with a 418 tip (1/16 inch diameter). Chromatin from 50-200 mg of dounced tissue was used for each ChIP experiment using antibodies against H3K4me3 (millipore 05-1339), H3K27ac (abcam ab4729), H3K4me1 (abcam ab8895), TBX5 (Insight bio sc-515536), RXRA (sc-553), FOXA1 (ab70382), HNF4A (ARP31946), CEBPA (sc-9314) and HNF6 (sc-13050). For 4C, locus-specific 4C templates were made using two rounds of enzyme digestion (primary and secondary) and ligation. Purified 4C templates were amplified by inverse PCR with bait-specific primers. Illumina sequencing libraries were prepared from ChIP-enriched or 4C-enriched DNA using ThruPLEX DNA-seq library preparation kit (Takara Bio) or NEBNext Ultra II DNA Library Prep Kit for Illumina with up to 10ng of input DNA and 8-15 PCR cycles. After PCR, libraries were pooled in equimolar concentrations and sequenced on Illumina HiSeq 4000, NextSeq 500 or NovaSeq 6000 instruments. ChIP-Seq, 4C-Seq
Runs: 1 run, 7.6M spots, 379.2M bases, 124.3Mb
Run# of Spots# of BasesSizePublished
SRR230930807,583,696379.2M124.3Mb2023-08-21

ID:
26213582

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