Acentric chromosome congression and alignment on the metaphase plate via kinetochore-independent forces in Drosophila.

IF 3.3 3区 生物学 Q2 GENETICS & HEREDITY Genetics Pub Date : 2024-11-18 DOI:10.1093/genetics/iyae188
Hannah Vicars, Alison Mills, Travis Karg, William Sullivan
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Abstract

Chromosome congression and alignment on the metaphase plate involves lateral and microtubule plus-end interactions with the kinetochore. Here we take advantage of our ability to efficiently generate a GFP-marked acentric X chromosome fragment in Drosophila neuroblasts to identify forces acting on chromosome arms that drive congression and alignment. We find acentrics efficiently congress and align on the metaphase plate, often more rapidly than kinetochore-bearing chromosomes. Unlike intact chromosomes, the paired sister acentrics oscillate as they move to and reside on the metaphase plate in a plane distinct and significantly further from the main mass of intact chromosomes. Consequently, at anaphase onset acentrics are oriented either parallel or perpendicular to the spindle. Parallel-oriented sisters separate by sliding while those oriented perpendicularly separate via unzipping. This oscillation, together with the fact that in the presence of spindles with disrupted interpolar microtubules acentrics are rapidly shunted away from the poles, indicates that distributed plus-end directed forces are primarily responsible for acentric migration. This conclusion is supported by the observation that reduction of EB1 preferentially disrupts acentric alignment. Taken together these studies suggest that plus-end forces mediated by the outer interpolar microtubules contribute significantly to acentric congression and alignment. Surprisingly, we observe disrupted telomere pairing and alignment of sister acentrics indicating that the kinetochore is required to ensure proper gene-to-gene alignment of sister chromatids. Finally, we demonstrate that like mammalian cells, the Drosophila congressed chromosomes on occasion exhibit a toroid configuration.

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果蝇通过与着丝点无关的力量在移相平板上实现同心染色体的聚集和排列
染色体在移相平板上的会聚和排列涉及横向和微管加端与动点的相互作用。在这里,我们利用在果蝇神经母细胞中高效生成带有 GFP 标记的偏心 X 染色体片段的能力,来识别作用于染色体臂上驱动同位和配位的力。我们发现,同心染色体能在移相平板上有效地聚集和排列,其速度往往比着丝粒染色体更快。与完整染色体不同的是,成对的姐妹中心体在移向并驻留在形变板上时会发生摆动,摆动的平面与完整染色体的主体截然不同,且相距甚远。因此,在无丝分裂期开始时,姐妹中心的方向要么平行于纺锤体,要么垂直于纺锤体。平行方向的姐妹花通过滑动分离,而垂直方向的姐妹花则通过拉链分离。这种摆动以及在极间微管中断的纺锤体中尖心会迅速远离两极的事实表明,分布式加端定向力是尖心迁移的主要原因。减少 EB1 会优先破坏中心排列的观察结果也支持这一结论。总之,这些研究表明,由极间外微管介导的正端力对同心和对齐起着重要作用。令人惊讶的是,我们观察到端粒配对和姊妹中心对齐被破坏,这表明需要动点核来确保姊妹染色单体基因间的正确对齐。最后,我们证明,与哺乳动物细胞一样,果蝇的同心染色体有时也会呈现环状结构。
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来源期刊
Genetics
Genetics GENETICS & HEREDITY-
CiteScore
6.90
自引率
6.10%
发文量
177
审稿时长
1.5 months
期刊介绍: GENETICS is published by the Genetics Society of America, a scholarly society that seeks to deepen our understanding of the living world by advancing our understanding of genetics. Since 1916, GENETICS has published high-quality, original research presenting novel findings bearing on genetics and genomics. The journal publishes empirical studies of organisms ranging from microbes to humans, as well as theoretical work. While it has an illustrious history, GENETICS has changed along with the communities it serves: it is not your mentor''s journal. The editors make decisions quickly – in around 30 days – without sacrificing the excellence and scholarship for which the journal has long been known. GENETICS is a peer reviewed, peer-edited journal, with an international reach and increasing visibility and impact. All editorial decisions are made through collaboration of at least two editors who are practicing scientists. GENETICS is constantly innovating: expanded types of content include Reviews, Commentary (current issues of interest to geneticists), Perspectives (historical), Primers (to introduce primary literature into the classroom), Toolbox Reviews, plus YeastBook, FlyBook, and WormBook (coming spring 2016). For particularly time-sensitive results, we publish Communications. As part of our mission to serve our communities, we''ve published thematic collections, including Genomic Selection, Multiparental Populations, Mouse Collaborative Cross, and the Genetics of Sex.
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