For All the Primate FANS: Optimized Isolation of Nuclei from Frozen Postmortem Primate Brain for Fluorescence-Assisted Nuclei Sorting (FANS).

IF 3.9 3区工程技术 Q2 BIOLOGY

Yale Journal of Biology and Medicine Pub Date : 2025-06-30 eCollection Date: 2025-06-01 DOI:10.59249/LLUJ2834

Elaine E Guevara, Begün Erbaba, Gregory M Cresswell, Melissa K Edler, Chet C Sherwood

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引用次数: 0

Abstract

Epigenetic alterations are cell type-specific and require methods like single cell sequencing and cell type sorting by flow cytometry. These methods often rely on the availability of fresh tissue, yet postmortem frozen tissue is typically the only material available from non-experimental subjects, including humans and other nonhuman primates (NHP). Many insights can be gained from analysis of these precious samples. To this end, we developed a protocol for isolating intact nuclei from small starting amounts of postmortem frozen chimpanzee (Pan troglodytes) cerebral cortex tissue. Isolated nuclei can be input directly into single cell epigenomics protocols like ATAC-seq or can be immunostained for enrichment of neuronal nuclei via fluorescent-activated nuclei sorting (FANS) followed by bulk epigenetic methods like methylome sequencing. We adapted and optimized this protocol based on existing human brain tissue protocols. Our protocol specifically addresses challenges presented by postmortem frozen NHP brain tissue, including high levels of myelin debris and reduced RNA integrity. We include key steps and troubleshooting guidance to improve nuclei quality and sorting outcomes, and we also discuss limitations and considerations for researchers interested in using these methods.

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所有灵长类动物的FANS：优化分离冷冻死后灵长类动物大脑的细胞核荧光辅助细胞核分选（FANS）。

表观遗传改变是细胞类型特异性的，需要单细胞测序和流式细胞术细胞类型分选等方法。这些方法通常依赖于新鲜组织的可用性，而死后的冷冻组织通常是来自非实验对象（包括人类和其他非人类灵长类动物）的唯一材料。从分析这些珍贵的样品中可以获得许多见解。为此，我们制定了一项从少量死后冷冻黑猩猩（Pan troglodytes）大脑皮层组织中分离完整细胞核的方案。分离的细胞核可以直接输入到单细胞表观基因组学方案中，如ATAC-seq，或者可以通过荧光活化细胞核分选（FANS）进行免疫染色，然后通过甲基组测序等大量表观遗传学方法富集神经元细胞核。我们在现有人类脑组织协议的基础上对该协议进行了调整和优化。我们的方案专门解决了死后冷冻NHP脑组织所带来的挑战，包括髓磷脂碎片水平高和RNA完整性降低。我们包括关键步骤和故障排除指导，以提高核质量和分选结果，我们还讨论了对使用这些方法感兴趣的研究人员的限制和注意事项。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Yale Journal of Biology and Medicine Biochemistry, Genetics and Molecular Biology-General Biochemistry,Genetics and Molecular Biology

CiteScore

5.00

自引率

0.00%

发文量

期刊介绍： The Yale Journal of Biology and Medicine (YJBM) is a graduate and medical student-run, peer-reviewed, open-access journal dedicated to the publication of original research articles, scientific reviews, articles on medical history, personal perspectives on medicine, policy analyses, case reports, and symposia related to biomedical matters. YJBM is published quarterly and aims to publish articles of interest to both physicians and scientists. YJBM is and has been an internationally distributed journal with a long history of landmark articles. Our contributors feature a notable list of philosophers, statesmen, scientists, and physicians, including Ernst Cassirer, Harvey Cushing, Rene Dubos, Edward Kennedy, Donald Seldin, and Jack Strominger. Our Editorial Board consists of students and faculty members from Yale School of Medicine and Yale University Graduate School of Arts & Sciences. All manuscripts submitted to YJBM are first evaluated on the basis of scientific quality, originality, appropriateness, contribution to the field, and style. Suitable manuscripts are then subject to rigorous, fair, and rapid peer review.