Functionally Annotating Regulatory Elements in the Equine Genome Using Histone Mark ChIP-Seq

Kingsley, Nicole B.; Kern, Colin; Creppe, Catherine; Hales, Erin N.; Zhou, Huaijun; Kalbfleisch, Theodore S.; MacLeod, James N.; Petersen, Jessica L; Finno, Carrie J.

doi:10.3390/genes11010003

Cited by 38 publications

(53 citation statements)

References 64 publications

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“…Heterochromatin and silencer sequences were shown to be depleted for GC content ( Glass and Natoli, 2016 ) like our H3K27me3-enriched regions (see Table 2 for GC content summary). We found a clear bimodal distribution of active promoters and enhancers around the TSS ( Figure 3 ) as has been reported by others for a variety of tissue types ( Kingsley et al, 2020 ). At the TSS there was a slight depression in signal reflecting this nucleosome depletion that would allow for the positioning of the initiation complex and RNA polymerase along the chromatin.…”

Section: Discussionsupporting

confidence: 86%

“…Several groups estimated that over 90% of causal mutations that explain phenotypic variation laid outside of genes within regulatory elements ( Hindorff et al, 2009 ; Maurano et al, 2012 ; Albert and Kruglyak, 2015 ). Currently, little is known regarding in vivo tissue annotation of regulatory elements in livestock species ( Villar et al, 2015 ; Zhao et al, 2015 ; Wang et al, 2017 , 2018 ; Naval-Sanchez et al, 2018 ; Nguyen et al, 2018 ; Fang et al, 2019 ; Hall et al, 2020 ; Kingsley et al, 2020 ). Therefore, the FAANG consortium recognized this need and formed a global network of researchers for epigenetic discovery in food animal species ( Andersson et al, 2015 ; Tuggle et al, 2016 ; Giuffra and Tuggle, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

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Genome-Wide Histone Modifications and CTCF Enrichment Predict Gene Expression in Sheep Macrophages

et al. 2021

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Alveolar macrophages function in innate and adaptive immunity, wound healing, and homeostasis in the lungs dependent on tissue-specific gene expression under epigenetic regulation. The functional diversity of tissue resident macrophages, despite their common myeloid lineage, highlights the need to study tissue-specific regulatory elements that control gene expression. Increasing evidence supports the hypothesis that subtle genetic changes alter sheep macrophage response to important production pathogens and zoonoses, for example, viruses like small ruminant lentiviruses and bacteria like Coxiella burnetii. Annotation of transcriptional regulatory elements will aid researchers in identifying genetic mutations of immunological consequence. Here we report the first genome-wide survey of regulatory elements in any sheep immune cell, utilizing alveolar macrophages. We assayed histone modifications and CTCF enrichment by chromatin immunoprecipitation with deep sequencing (ChIP-seq) in two sheep to determine cis-regulatory DNA elements and chromatin domain boundaries that control immunity-related gene expression. Histone modifications included H3K4me3 (denoting active promoters), H3K27ac (active enhancers), H3K4me1 (primed and distal enhancers), and H3K27me3 (broad silencers). In total, we identified 248,674 reproducible regulatory elements, which allowed assignment of putative biological function in macrophages to 12% of the sheep genome. Data exceeded the FAANG and ENCODE standards of 20 million and 45 million useable fragments for narrow and broad marks, respectively. Active elements showed consensus with RNA-seq data and were predictive of gene expression in alveolar macrophages from the publicly available Sheep Gene Expression Atlas. Silencer elements were not enriched for expressed genes, but rather for repressed developmental genes. CTCF enrichment enabled identification of 11,000 chromatin domains with mean size of 258 kb. To our knowledge, this is the first report to use immunoprecipitated CTCF to determine putative topological domains in sheep immune cells. Furthermore, these data will empower phenotype-associated mutation discovery since most causal variants are within regulatory elements.

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Section: Discussionsupporting

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Genome-Wide Histone Modifications and CTCF Enrichment Predict Gene Expression in Sheep Macrophages

et al. 2021

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“…As this locus on ECA13 contains no annotated protein-coding genes and no functional data currently exists for eyelid tissue or Meibomian glands, the equine data collected for the Functional Annotation of Animal Genomes (FAANG) project, including RNA-seq [ 26 , 27 ] and ChIP-seq data [ 28 ] from two clinically healthy Thoroughbred mares, were evaluated to develop additional hypotheses on the functional mechanisms of this variant. To investigate if there was tissue-specific variation in gene expression in clinically normal horses, the three genes near the deletion ( FAM20C , PRKAR1B and PDGFA ) were assessed in the RNA-seq data.…”

Section: Resultsmentioning

confidence: 99%

“…As the deletion identified is located in an intergenic region, computational analyses were performed to assess the potential regulatory role of this region as the cause of distichiasis. The annotated locations of FAM20C , PDGFA and PRKAR1B from the FAANG RNA-seq data were visualized using IGV [ 28 , 29 ]. Publicly available equine FAANG ChIP-Seq data (H3K4me1, H3K4me, H3K27ac, and H3K27me3) from eight tissues (adipose, brain, heart, lamina, liver, lung, ovary, skeletal muscle) were assessed to investigate potential regulatory regions [ 30 ].…”

Section: Methodsmentioning

confidence: 99%

Whole genome sequencing identified a 16 kilobase deletion on ECA13 associated with distichiasis in Friesian horses

et al. 2020

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Background Distichiasis, an ocular disorder in which aberrant cilia (eyelashes) grow from the opening of the Meibomian glands of the eyelid, has been reported in Friesian horses. These misplaced cilia can cause discomfort, chronic keratitis, and corneal ulceration, potentially impacting vision due to corneal fibrosis, or, if secondary infection occurs, may lead to loss of the eye. Friesian horses represent the vast majority of reported cases of equine distichiasis, and as the breed is known to be affected with inherited monogenic disorders, this condition was hypothesized to be a simply inherited Mendelian trait. Results A genome wide association study (GWAS) was performed using the Axiom 670 k Equine Genotyping array (MNEc670k) utilizing 14 cases and 38 controls phenotyped for distichiasis. An additive single locus mixed linear model (EMMAX) approach identified a 1.83 Mb locus on ECA5 and a 1.34 Mb locus on ECA13 that reached genome-wide significance (pcorrected = 0.016 and 0.032, respectively). Only the locus on ECA13 withstood replication testing (p = 1.6 × 10− 5, cases: n = 5 and controls: n = 37). A 371 kb run of homozygosity (ROH) on ECA13 was found in 13 of the 14 cases, providing evidence for a recessive mode of inheritance. Haplotype analysis (hapQTL) narrowed the region of association on ECA13 to 163 kb. Whole-genome sequencing data from 3 cases and 2 controls identified a 16 kb deletion within the ECA13 associated haplotype (ECA13:g.178714_195130del). Functional annotation data supports a tissue-specific regulatory role of this locus. This deletion was associated with distichiasis, as 18 of the 19 cases were homozygous (p = 4.8 × 10− 13). Genotyping the deletion in 955 horses from 54 different breeds identified the deletion in only 11 non-Friesians, all of which were carriers, suggesting that this could be causal for this Friesian disorder. Conclusions This study identified a 16 kb deletion on ECA13 in an intergenic region that was associated with distichiasis in Friesian horses. Further functional analysis in relevant tissues from cases and controls will help to clarify the precise role of this deletion in normal and abnormal eyelash development and investigate the hypothesis of incomplete penetrance.

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“…Following ENCODE and Roadmap Epigenomics projects 8 , the Functional Annotation of Animal Genomes (FAANG) initiative 24 , although still in its infancy, has made great progress towards annotating functional elements in many tissues across multiple domestic species including pigs [25][26][27][28][29][30] . Here, we present 95 new genome-wide sequencing datasets from six gut-associated porcine tissues and integrate them with 128 previously published FAANG datasets from eight biologically distinct tissues.…”

Section: Significant Enrichment Of Variants Associated With Human Commentioning

confidence: 99%

Pig genome functional annotation enhances biological interpretations of complex traits and comparative epigenomics

Zhou

Pan

Yao

et al. 2021

Preprint

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The functional annotation of livestock genomes is crucial for understanding the molecular mechanisms that underpin complex traits of economic importance, adaptive evolution and comparative genomics. Here, we provide the most comprehensive catalogue to date of regulatory elements in the pig (Sus scrofa) by integrating 223 epigenomic and transcriptomic data sets, representing 14 biologically important tissues. We systematically describe the dynamic epigenetic landscape across tissues by functionally annotating 15 different chromatin states and defining their tissue-specific regulatory activities. We demonstrate that genomic variants associated with complex traits and adaptive evolution in pig are significantly enriched in active promoters and enhancers. Furthermore, we reveal distinct tissue-specific regulatory selection between Asian and European pig domestication processes. Compared with human and mouse epigenomes, we show that porcine regulatory elements are more conserved in DNA sequence, under both rapid and slow evolution, than those under neutral evolution across pig, mouse, and human. Finally, we provide novel biological insights on tissue-specific regulatory conservation and demonstrate that, depending on the traits, mouse or pig might be more appropriate biomedical models for different complex traits and diseases in humans through integrating comparative epigenomes with 47 human genome-wide association studies.

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Functionally Annotating Regulatory Elements in the Equine Genome Using Histone Mark ChIP-Seq

Cited by 38 publications

References 64 publications

Genome-Wide Histone Modifications and CTCF Enrichment Predict Gene Expression in Sheep Macrophages

Genome-Wide Histone Modifications and CTCF Enrichment Predict Gene Expression in Sheep Macrophages

Whole genome sequencing identified a 16 kilobase deletion on ECA13 associated with distichiasis in Friesian horses

Pig genome functional annotation enhances biological interpretations of complex traits and comparative epigenomics

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