York Biomedical Research Institute, Department of Biology, University of York, Heslington, United Kingdom.
Novartis Institute for Tropical Diseases, Emeryville, California, USA.
mBio. 2021 Jun 29;12(3):e0068721. doi: 10.1128/mBio.00687-21. Epub 2021 Jun 15.
During mitosis, eukaryotic cells must duplicate and separate their chromosomes in a precise and timely manner. The apparatus responsible for this is the kinetochore, which is a large protein structure that links chromosomal DNA and spindle microtubules to facilitate chromosome alignment and segregation. The proteins that comprise the kinetochore in the protozoan parasite Trypanosoma brucei are divergent from yeast and mammals and comprise an inner kinetochore complex composed of 24 distinct proteins (KKT1 to KKT23, KKT25) that include four protein kinases, CLK1 (KKT10), CLK2 (KKT19), KKT2, and KKT3. We recently reported the identification of a specific trypanocidal inhibitor of T. brucei CLK1, an amidobenzimidazole, AB1. We now show that chemical inhibition of CLK1 with AB1 impairs inner kinetochore recruitment and compromises cell cycle progression, leading to cell death. Here, we show that KKT2 is a substrate for CLK1 and identify phosphorylation of S508 by CLK1 to be essential for KKT2 function and for kinetochore assembly. Additionally, KKT2 protein kinase activity is required for parasite proliferation but not for assembly of the inner kinetochore complex. We also show that chemical inhibition of the aurora kinase AUK1 does not affect CLK1 phosphorylation of KKT2, indicating that AUK1 and CLK1 are in separate regulatory pathways. We propose that CLK1 is part of a divergent signaling cascade that controls kinetochore function via phosphorylation of the inner kinetochore protein kinase KKT2. In eukaryotic cells, kinetochores are large protein complexes that link chromosomes to dynamic microtubule tips, ensuring proper segregation and genomic stability during cell division. Several proteins tightly coordinate kinetochore functions, including the protein kinase aurora kinase B. The kinetochore has diverse evolutionary roots. For example, trypanosomatids, single-cell parasitic protozoa that cause several neglected tropical diseases, possess a unique repertoire of kinetochore components whose regulation during the cell cycle remains unclear. Here, we shed light on trypanosomatid kinetochore biology by showing that the protein kinase CLK1 coordinates the assembly of the inner kinetochore by phosphorylating one of its components, KKT2, allowing the timely spatial recruitment of the rest of the kinetochore proteins and posterior attachment to microtubules in a process that is aurora kinase B independent.
在有丝分裂过程中,真核细胞必须以精确和及时的方式复制和分离其染色体。负责这一过程的是动粒,它是一个大型蛋白质结构,将染色体 DNA 和纺锤体微管连接起来,以促进染色体的排列和分离。在原生动物寄生虫布氏锥虫中构成动粒的蛋白质与酵母和哺乳动物不同,由一个由 24 种不同蛋白质(KKT1 到 KKT23,KKT25)组成的内动粒复合物组成,其中包括四种蛋白激酶 CLK1(KKT10)、CLK2(KKT19)、KKT2 和 KKT3。我们最近报道了鉴定出一种特定的布氏锥虫 CLK1 的杀锥虫抑制剂,一种苯并咪唑 AB1。我们现在表明,CLK1 的化学抑制物 AB1 会损害内动粒的募集并损害细胞周期进程,导致细胞死亡。在这里,我们表明 KKT2 是 CLK1 的底物,并确定 CLK1 对 S508 的磷酸化对于 KKT2 功能和动粒组装是必不可少的。此外,KKT2 蛋白激酶活性对于寄生虫的增殖是必需的,但对于内动粒复合物的组装不是必需的。我们还表明,极光激酶 AUK1 的化学抑制不影响 CLK1 对 KKT2 的磷酸化,表明 AUK1 和 CLK1 处于不同的调节途径中。我们提出 CLK1 是控制通过磷酸化内动粒蛋白激酶 KKT2 的动粒功能的分歧信号级联的一部分。在真核细胞中,动粒是将染色体连接到动态微管末端的大型蛋白质复合物,确保在细胞分裂过程中正确分离和基因组稳定性。几种蛋白质紧密协调动粒功能,包括蛋白激酶极光激酶 B。动粒具有多种进化根源。例如,单细胞寄生虫原生动物,引起几种被忽视的热带病,拥有独特的动粒成分 repertoire,其在细胞周期中的调控尚不清楚。在这里,我们通过表明蛋白激酶 CLK1 通过磷酸化其成分之一 KKT2 来协调内动粒的组装,从而揭示了锥虫动粒生物学,允许其余动粒蛋白的及时空间募集,并在后 Attachment 到微管上,该过程不依赖于极光激酶 B。
