染色体级基因组组装和遗传图谱揭示了濒危大西洋孢子虫的异型性和巨型性。

IF 3.5 2区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY BMC Genomics Pub Date : 2024-11-20 DOI:10.1186/s12864-024-11025-3
Nicolas S Locatelli, Sheila A Kitchen, Kathryn H Stankiewicz, C Cornelia Osborne, Zoe Dellaert, Holland Elder, Bishoy Kamel, Hanna R Koch, Nicole D Fogarty, Iliana B Baums
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引用次数: 0

摘要

背景:在珊瑚的进化史上,它们已经适应了海平面上升和海洋温度升高,但目前还不清楚它们对快速变化的反应速度。基因组结构和其中包含的遗传多样性可能会突出它们的适应潜力:我们展示了极度濒危的大西洋尖孔动物--棕榈尖孔动物(Acropora palmata)和鹿角尖孔动物(A. cervicornis)的染色体级基因组组装和连接图。基因组组装图和连接图都被解析为 14 条染色体,其中包含基因含量和共线性。物种间的重复和染色体排列基本保持不变。Acroporidae 科和 Acropora 属表现出许多在系统发育上具有重要意义的基因家族扩展。随着系统发育距离的增加,宏基因组减少。尽管如此,硬骨鱼类与其他亲缘关系较远的刺胞动物相比,共享 21 个刺胞动物祖先连锁群中的 6 个,以及许多裂变和融合事件。利用基因分型阵列构建了一个棕榈虫家族和 16 个鹿角虫家族的遗传连锁图谱。棕榈虫和鹿角虫的共识图谱跨度分别为 1,013.42 cM 和 927.36 cM。这两个物种都表现出较高的全基因组重组率(3.04 至 3.53 cM/Mb)和明显的性别差异,即所谓的 "杂合性"(heterochiasmy),据估计雌性图谱的重组率要高出 2 至 2.5 倍:我们在此介绍的染色体尺度的组合和遗传图谱,是对极度濒危的大西洋尖嘴鱼基因组景观的首次详细观察。这些数据集揭示了大西洋尖孔动物的适应能力并不受重组率的限制。姊妹物种之间保持着大合成,很少有序列差异大的基因,这可能成为它们之间的繁殖障碍。在大西洋针孔虫中,尽管两个姊妹物种的基因组具有高水平的大对称性和基因共线性,但它们之间的杂交产生的 F1 杂交种繁殖力有限。现在,这些资源共同促成了全基因组关联研究和数量性状位点的发现,这两种工具有助于这些物种的保护。
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Chromosome-level genome assemblies and genetic maps reveal heterochiasmy and macrosynteny in endangered Atlantic Acropora.

Background: Over their evolutionary history, corals have adapted to sea level rise and increasing ocean temperatures, however, it is unclear how quickly they may respond to rapid change. Genome structure and genetic diversity contained within may highlight their adaptive potential.

Results: We present chromosome-scale genome assemblies and linkage maps of the critically endangered Atlantic acroporids, Acropora palmata and A. cervicornis. Both assemblies and linkage maps were resolved into 14 chromosomes with their gene content and colinearity. Repeats and chromosome arrangements were largely preserved between the species. The family Acroporidae and the genus Acropora exhibited many phylogenetically significant gene family expansions. Macrosynteny decreased with phylogenetic distance. Nevertheless, scleractinians shared six of the 21 cnidarian ancestral linkage groups as well as numerous fission and fusion events compared to other distantly related cnidarians. Genetic linkage maps were constructed from one A. palmata family and 16 A. cervicornis families using a genotyping array. The consensus maps span 1,013.42 cM and 927.36 cM for A. palmata and A. cervicornis, respectively. Both species exhibited high genome-wide recombination rates (3.04 to 3.53 cM/Mb) and pronounced sex-based differences, known as heterochiasmy, with 2 to 2.5X higher recombination rates estimated in the female maps.

Conclusions: Together, the chromosome-scale assemblies and genetic maps we present here are the first detailed look at the genomic landscapes of the critically endangered Atlantic acroporids. These data sets revealed that adaptive capacity of Atlantic acroporids is not limited by their recombination rates. The sister species maintain macrosynteny with few genes with high sequence divergence that may act as reproductive barriers between them. In the Atlantic Acropora, hybridization between the two sister species yields an F1 hybrid with limited fertility despite the high levels of macrosynteny and gene colinearity of their genomes. Together, these resources now enable genome-wide association studies and discovery of quantitative trait loci, two tools that can aid in the conservation of these species.

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来源期刊
BMC Genomics
BMC Genomics 生物-生物工程与应用微生物
CiteScore
7.40
自引率
4.50%
发文量
769
审稿时长
6.4 months
期刊介绍: BMC Genomics is an open access, peer-reviewed journal that considers articles on all aspects of genome-scale analysis, functional genomics, and proteomics. BMC Genomics is part of the BMC series which publishes subject-specific journals focused on the needs of individual research communities across all areas of biology and medicine. We offer an efficient, fair and friendly peer review service, and are committed to publishing all sound science, provided that there is some advance in knowledge presented by the work.
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