先进的荧光纳米显微镜对揭示有丝分裂染色体结构的贡献。

IF 2.4 4区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Chromosome Research Pub Date : 2021-03-01 Epub Date: 2021-03-09 DOI:10.1007/s10577-021-09654-5
S W Botchway, S Farooq, A Sajid, I K Robinson, M Yusuf
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引用次数: 2

摘要

染色质的高阶结构组织及其缩聚过程是结构生物学的关键挑战之一。这对阐明几种疾病状态很重要。为了解决这个长期存在的问题,先进成像方法的发展在提供对有丝分裂染色体结构和压实的理解方面发挥了重要作用。其中有两种快速发展的荧光成像技术,特别是荧光寿命成像(FLIM)和超分辨率显微镜(SRM)。特别是FLIM在染色体研究中的应用一直缺乏,而SRM虽然应用不广泛,但已经取得了成功。这两种技术都能够提供具有纳米信息的荧光成像。SRM或“纳米镜”能够产生小于50纳米分辨率的DNA图像,而FLIM在加上能量转移时可以提供小于20纳米的信息。在这里,我们讨论了这两种方法的优点和局限性,以及它们对有丝分裂染色体研究的贡献。此外,我们强调了新技术的进步如何在染色体科学领域做出贡献的未来前景。
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Contribution of advanced fluorescence nano microscopy towards revealing mitotic chromosome structure.

The organization of chromatin into higher-order structures and its condensation process represent one of the key challenges in structural biology. This is important for elucidating several disease states. To address this long-standing problem, development of advanced imaging methods has played an essential role in providing understanding into mitotic chromosome structure and compaction. Amongst these are two fast evolving fluorescence imaging technologies, specifically fluorescence lifetime imaging (FLIM) and super-resolution microscopy (SRM). FLIM in particular has been lacking in the application of chromosome research while SRM has been successfully applied although not widely. Both these techniques are capable of providing fluorescence imaging with nanometer information. SRM or "nanoscopy" is capable of generating images of DNA with less than 50 nm resolution while FLIM when coupled with energy transfer may provide less than 20 nm information. Here, we discuss the advantages and limitations of both methods followed by their contribution to mitotic chromosome studies. Furthermore, we highlight the future prospects of how advancements in new technologies can contribute in the field of chromosome science.

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来源期刊
Chromosome Research
Chromosome Research 生物-生化与分子生物学
CiteScore
4.70
自引率
3.80%
发文量
31
审稿时长
1 months
期刊介绍: Chromosome Research publishes manuscripts from work based on all organisms and encourages submissions in the following areas including, but not limited, to: · Chromosomes and their linkage to diseases; · Chromosome organization within the nucleus; · Chromatin biology (transcription, non-coding RNA, etc); · Chromosome structure, function and mechanics; · Chromosome and DNA repair; · Epigenetic chromosomal functions (centromeres, telomeres, replication, imprinting, dosage compensation, sex determination, chromosome remodeling); · Architectural/epigenomic organization of the genome; · Functional annotation of the genome; · Functional and comparative genomics in plants and animals; · Karyology studies that help resolve difficult taxonomic problems or that provide clues to fundamental mechanisms of genome and karyotype evolution in plants and animals; · Mitosis and Meiosis; · Cancer cytogenomics.
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