在疟原虫血液阶段的无性复制过程中,核孔复合体会发生 Nup221 交换。

IF 3.7 2区 生物学 Q2 MICROBIOLOGY
mSphere Pub Date : 2024-11-11 DOI:10.1128/msphere.00750-24
James Blauwkamp, Sushma V Ambekar, Tahir Hussain, Gunnar R Mair, Josh R Beck, Sabrina Absalon
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引用次数: 0

摘要

疟原虫是疟疾的病原体,它们进行闭合有丝分裂,核包膜不会破裂。与酵母的闭合有丝分裂不同,疟原虫在共享的细胞质中进行多轮不同步的核分裂。这样,在受感染的红细胞内形成子细胞之前,就形成了一个多核生物体。在这一复制过程中,完整的核孔复合体(NPC)及其成分核多聚酶在寄生虫的生长过程中发挥了关键作用,促进了选择性双向核细胞质运输和基因组的组织。在这里,我们利用超微结构扩展显微镜在单个细胞核水平上研究了伯格希氏疟原虫整个 24 小时血期复制周期中的核多聚酶。我们的研究结果表明,这些核多聚蛋白分布在细胞核周围,并在有丝分裂过程中负责核内微管成核的中心粒斑块周围形成以前未曾描述过的莲座状结构。我们通过单质粒标记系统(包括标记质粒和Cre重组酶)将重组诱导标记交换系统应用于伯格氏疟原虫,提供了NPC形成动态的证据,证明了Nup221在寄生虫无性复制过程中的更替。我们的数据揭示了伯格氏疟原虫血液阶段复制过程中 NPC 的分布及其平衡:由疟原虫引起的疟疾仍然是一个严峻的全球健康挑战,据估计,2022年将有2.49亿病例,60多万人死亡,主要影响五岁以下儿童。了解疟原虫的核动态,尤其是其独特的有丝分裂过程,对于开发新型治疗策略至关重要。我们的研究利用超微结构扩展显微镜等先进的显微镜技术,揭示了寄生虫无性复制期间核孔复合体(NPC)的组织和周转。通过阐明这些以前未知的 NPC 分布和平衡方面的问题,我们对寄生虫有丝分裂的分子机制提出了宝贵的见解。这些发现加深了我们对寄生虫生物学的理解,并可能为今后旨在确定抗疟疾药物开发新靶点的研究提供信息。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Nuclear pore complexes undergo Nup221 exchange during blood-stage asexual replication of Plasmodium parasites.

Plasmodium parasites, the causative agents of malaria, undergo closed mitosis without breakdown of the nuclear envelope. Unlike closed mitosis in yeast, Plasmodium berghei parasites undergo multiple rounds of asynchronous nuclear divisions in a shared cytoplasm. This results in a multinucleated organism prior to the formation of daughter cells within an infected red blood cell. During this replication process, intact nuclear pore complexes (NPCs) and their component nucleoporins play critical roles in parasite growth, facilitating selective bi-directional nucleocytoplasmic transport and genome organization. Here, we utilize ultrastructure expansion microscopy to investigate P. berghei nucleoporins at the single nucleus level throughout the 24-hour blood-stage replication cycle. Our findings reveal that these nucleoporins are distributed around the nuclei and organized in a rosette structure previously undescribed around the centriolar plaque, responsible for intranuclear microtubule nucleation during mitosis. By adapting the recombination-induced tag exchange system to P. berghei through a single plasmid tagging system, which includes the tagging plasmid as well as the Cre recombinase, we provide evidence of NPC formation dynamics, demonstrating Nup221 turnover during parasite asexual replication. Our data shed light on the distribution of NPCs and their homeostasis during the blood-stage replication of P. berghei parasites.

Importance: Malaria, caused by Plasmodium species, remains a critical global health challenge, with an estimated 249 million cases and over 600,000 deaths in 2022, primarily affecting children under five. Understanding the nuclear dynamics of Plasmodium parasites, particularly during their unique mitotic processes, is crucial for developing novel therapeutic strategies. Our study leverages advanced microscopy techniques, such as ultrastructure expansion microscopy, to reveal the organization and turnover of nuclear pore complexes (NPCs) during the parasite's asexual replication. By elucidating these previously unknown aspects of NPC distribution and homeostasis, we provide valuable insights into the molecular mechanisms governing parasite mitosis. These findings deepen our understanding of parasite biology and may inform future research aimed at identifying new targets for anti-malarial drug development.

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来源期刊
mSphere
mSphere Immunology and Microbiology-Microbiology
CiteScore
8.50
自引率
2.10%
发文量
192
审稿时长
11 weeks
期刊介绍: mSphere™ is a multi-disciplinary open-access journal that will focus on rapid publication of fundamental contributions to our understanding of microbiology. Its scope will reflect the immense range of fields within the microbial sciences, creating new opportunities for researchers to share findings that are transforming our understanding of human health and disease, ecosystems, neuroscience, agriculture, energy production, climate change, evolution, biogeochemical cycling, and food and drug production. Submissions will be encouraged of all high-quality work that makes fundamental contributions to our understanding of microbiology. mSphere™ will provide streamlined decisions, while carrying on ASM''s tradition for rigorous peer review.
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