Sex chromosome differentiation via changes in the Y chromosome repeat landscape in African annual killifishes Nothobranchius furzeri and N. kadleci.

IF 2.4 4区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Chromosome Research Pub Date : 2022-12-01 DOI:10.1007/s10577-022-09707-3

Jana Štundlová, Monika Hospodářská, Karolína Lukšíková, Anna Voleníková, Tomáš Pavlica, Marie Altmanová, Annekatrin Richter, Martin Reichard, Martina Dalíková, Šárka Pelikánová, Anatolie Marta, Sergey A Simanovsky, Matyáš Hiřman, Marek Jankásek, Tomáš Dvořák, Joerg Bohlen, Petr Ráb, Christoph Englert, Petr Nguyen, Alexandr Sember

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Abstract

Homomorphic sex chromosomes and their turnover are common in teleosts. We investigated the evolution of nascent sex chromosomes in several populations of two sister species of African annual killifishes, Nothobranchius furzeri and N. kadleci, focusing on their under-studied repetitive landscape. We combined bioinformatic analyses of the repeatome with molecular cytogenetic techniques, including comparative genomic hybridization, fluorescence in situ hybridization with satellite sequences, ribosomal RNA genes (rDNA) and bacterial artificial chromosomes (BACs), and immunostaining of SYCP3 and MLH1 proteins to mark lateral elements of synaptonemal complexes and recombination sites, respectively. Both species share the same heteromorphic XY sex chromosome system, which thus evolved prior to their divergence. This was corroborated by sequence analysis of a putative master sex determining (MSD) gene gdf6Y in both species. Based on their divergence, differentiation of the XY sex chromosome pair started approximately 2 million years ago. In all populations, the gdf6Y gene mapped within a region rich in satellite DNA on the Y chromosome long arms. Despite their heteromorphism, X and Y chromosomes mostly pair regularly in meiosis, implying synaptic adjustment. In N. kadleci, Y-linked paracentric inversions like those previously reported in N. furzeri were detected. An inversion involving the MSD gene may suppress occasional recombination in the region, which we otherwise evidenced in the N. furzeri population MZCS-121 of the Limpopo clade lacking this inversion. Y chromosome centromeric repeats were reduced compared with the X chromosome and autosomes, which points to a role of relaxed meiotic drive in shaping the Y chromosome repeat landscape. We speculate that the recombination rate between sex chromosomes was reduced due to heterochiasmy. The observed differences between the repeat accumulations on the X and Y chromosomes probably result from high repeat turnover and may not relate closely to the divergence inferred from earlier SNP analyses.

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通过Y染色体重复序列景观变化的非洲年生鳉性染色体分化。

同态性染色体及其更替在硬骨鱼中很常见。我们研究了非洲年生鳉(Nothobranchius furzeri)和N. kadleci两个姐妹种的几个种群的新生性染色体的进化，重点研究了它们的重复景观。我们将重复组的生物信息学分析与分子细胞遗传学技术相结合，包括比较基因组杂交、卫星序列荧光原位杂交、核糖体RNA基因(rDNA)和细菌人工染色体(BACs)，以及SYCP3和MLH1蛋白的免疫染色，分别标记突触复合物的外侧元件和重组位点。这两个物种都有相同的异型XY性染色体系统，因此在它们分化之前就已经进化了。这是证实了序列分析假定的主性别决定(MSD)基因gdf6Y在两个物种。根据它们的分化，XY性染色体的分化始于大约200万年前。在所有人群中，gdf6Y基因都位于Y染色体长臂上富含卫星DNA的区域内。尽管X和Y染色体具有异型性，但在减数分裂中，它们大多有规律地配对，这意味着突触调节。在N. kadleci中，检测到与先前报道的N. furzeri相似的y连锁顺中心倒置。涉及MSD基因的反转可能会抑制该区域偶尔的重组，我们在林波波支系缺乏这种反转的N. furzeri种群MZCS-121中证实了这一点。与X染色体和常染色体相比，Y染色体的着丝粒重复次数减少，这表明放松减数分裂驱动在形成Y染色体重复景观中的作用。我们推测性染色体之间的重组率由于异交而降低。观察到的X和Y染色体重复序列积累之间的差异可能是由高重复序列周转率引起的，可能与早期SNP分析推断的差异无关。

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来源期刊

Chromosome Research 生物-生化与分子生物学

CiteScore

4.70

自引率

3.80%

发文量

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.