Clarence Tereza, Robert Nicolas S M, Sarigol Fatih, Fu Xiao, Bates Paul A, Simakov Oleg
Biomolecular Modelling Laboratory, The Francis Crick Institute, 1 Midland Road, London NW1 1AT, UK.
Roussos Lab/Center for Disease Neurogenomics, Icahn School of Medicine at Mount Sinai, New York, NY, USA.
iScience. 2023 Feb 4;26(3):106136. doi: 10.1016/j.isci.2023.106136. eCollection 2023 Mar 17.
Animal genomes are organized into chromosomes that are remarkably conserved in their gene content, forming distinct evolutionary units (synteny). Using versatile chromosomal modeling, we infer three-dimensional topology of genomes from representative clades spanning the earliest animal diversification. We apply a partitioning approach using interaction spheres to compensate for varying quality of topological data. Using comparative genomics approaches, we test whether syntenic signal at gene pair, local, and whole chromosomal scale is reflected in the reconstructed spatial organization. We identify evolutionarily conserved three-dimensional networks at all syntenic scales revealing novel evolutionarily maintained interactors associated with known conserved local gene linkages (such as hox). We thus present evidence for evolutionary constraints that are associated with three-, rather than just two-, dimensional animal genome organization, which we term spatiosynteny. As more accurate topological data become available, together with validation approaches, spatiosynteny may become relevant in understanding the functionality behind the observed conservation of animal chromosomes.
动物基因组被组织成染色体,其基因含量高度保守,形成了独特的进化单元(同线性)。利用通用的染色体建模,我们从跨越最早动物分化的代表性进化枝中推断出基因组的三维拓扑结构。我们采用一种使用相互作用球的划分方法来弥补拓扑数据质量的差异。利用比较基因组学方法,我们测试基因对、局部和全染色体尺度上的同线性信号是否反映在重建的空间组织中。我们在所有同线性尺度上识别出进化上保守的三维网络,揭示了与已知保守局部基因连锁(如hox)相关的新的进化上维持的相互作用因子。因此,我们提供了与三维而非二维动物基因组组织相关的进化限制的证据,我们将其称为空间同线性。随着更准确的拓扑数据以及验证方法的出现,空间同线性可能在理解动物染色体观察到的保守性背后的功能方面变得相关。
