Browsing by Subject "Chromatin immunoprecipitation sequencing"

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    Adipocyte-Specific ATAC-Seq with Adipose Tissues Using Fluorescence-Activated Nucleus Sorting
    (MyJove Corporation, 2023-03-17) Kim, Kyungchan; Taleb, Solaema; So, Jisun; Wann, Jamie; Roh, Hyun Cheol; Biochemistry and Molecular Biology, School of Medicine
    Assay for transposase-accessible chromatin with high-throughput sequencing (ATAC-seq) is a robust technique that enables genome-wide chromatin accessibility profiling. This technique has been useful for understanding the regulatory mechanisms of gene expression in a range of biological processes. Although ATAC-seq has been modified for different types of samples, there have not been effective modifications of ATAC-seq methods for adipose tissues. Challenges with adipose tissues include the complex cellular heterogeneity, large lipid content, and high mitochondrial contamination. To overcome these problems, we have developed a protocol that allows adipocyte-specific ATAC-seq by employing fluorescence-activated nucleus sorting with adipose tissues from the transgenic reporter Nuclear tagging and Translating Ribosome Affinity Purification (NuTRAP) mouse. This protocol produces high-quality data with minimal wasted sequencing reads while reducing the amount of nucleus input and reagents. This paper provides detailed step-by-step instructions for the ATAC-seq method validated for the use of adipocyte nuclei isolated from mouse adipose tissues. This protocol will aid in the investigation of chromatin dynamics in adipocytes upon diverse biological stimulations, which will allow for novel biological insights.
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    Global mapping of BMAL1 protein-DNA interactions in human retinal Müller cells
    (Molecular Vision, 2024-11-10) Luo, Qianyi; Sangani, Neel; Abhyankar, Surabhi; Somalraju, Sahiti; Janga, Sarath Chandra; Bhatwadekar, Ashay D.; Ophthalmology, School of Medicine
    The circadian clock, a conserved biologic timekeeping mechanism, is pivotal in orchestrating rhythmic physiologic processes. While extensively studied in the central clock, the involvement of BMAL1 in peripheral clocks, particularly in human Müller cells, remains underexplored. Müller cells, critical for retinal homeostasis, may unveil novel insights into circadian regulation. Employing ChIP-sequencing, we comprehensively mapped BMAL1 binding sites in human Müller cells. The analysis identified 275 reproducible peaks, with predominant distribution across promoters (26.6%), intronic (26.3%), and intergenic (22.1%) regions, with 80% of these confident peaks linked to protein-coding genes. Differential peak analysis revealed 89 unique genes significantly enriched with BMAL1 sites in their promoters, while functional enrichment of the associated genes indicated key biologic processes such as circadian regulation of gene expression, photoperiodism, and glucocorticoid receptor signaling pathway regulation. Motif analysis revealed a highly conserved 6-nucleotide motif, CACGTG, appearing in 89.09% of the peaks. Analysis of the binding sites across genomic regions highlighted the robust BMAL1 binding, further confirmed by qPCR validation of circadian targets such as G6PC3, CIART, PER1, and TXNIP, which are critical for Müller cell health, along with SHMT2 and MALAT1, which have emerged as novel genes that may have implications for Müller cell health. Our findings unveil the regulatory landscape of BMAL1 in Müller cells, contributing to a broader understanding of the clock-mediated mechanism in ocular tissues. These insights hold therapeutic potential for circadian-related retinal diseases, presenting avenues for chronotherapeutic interventions.