在三维保存的间期细胞核上进行联合免疫荧光和DNA荧光原位杂交,以研究三维核组织的变化。
Combined immunofluorescence and DNA FISH on 3D-preserved interphase nuclei to study changes in 3D nuclear organization.
作者信息
Chaumeil Julie, Micsinai Mariann, Skok Jane A
机构信息
Department of Pathology, New York University School of Medicine, NY, USA.
出版信息
J Vis Exp. 2013 Feb 3(72):e50087. doi: 10.3791/50087.
Abstract
Fluorescent in situ hybridization using DNA probes on 3-dimensionally preserved nuclei followed by 3D confocal microscopy (3D DNA FISH) represents the most direct way to visualize the location of gene loci, chromosomal sub-regions or entire territories in individual cells. This type of analysis provides insight into the global architecture of the nucleus as well as the behavior of specific genomic loci and regions within the nuclear space. Immunofluorescence, on the other hand, permits the detection of nuclear proteins (modified histones, histone variants and modifiers, transcription machinery and factors, nuclear sub-compartments, etc). The major challenge in combining immunofluorescence and 3D DNA FISH is, on the one hand to preserve the epitope detected by the antibody as well as the 3D architecture of the nucleus, and on the other hand, to allow the penetration of the DNA probe to detect gene loci or chromosome territories (1-5). Here we provide a protocol that combines visualization of chromatin modifications with genomic loci in 3D preserved nuclei.
摘要
使用DNA探针在三维保存的细胞核上进行荧光原位杂交,随后进行三维共聚焦显微镜检查(3D DNA FISH),是在单个细胞中可视化基因座、染色体亚区域或整个区域位置的最直接方法。这种分析类型有助于深入了解细胞核的整体结构以及核空间内特定基因组位点和区域的行为。另一方面,免疫荧光可用于检测核蛋白(修饰的组蛋白、组蛋白变体和修饰剂、转录机制和因子、核亚区室等)。将免疫荧光和3D DNA FISH相结合的主要挑战在于,一方面要保留抗体检测到的表位以及细胞核的三维结构,另一方面要使DNA探针能够穿透以检测基因座或染色体区域(1-5)。在这里,我们提供了一种方案,可在三维保存的细胞核中结合染色质修饰与基因组位点的可视化。
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