Topological mixing and irreversibility in animal chromosome evolution

Animal chromosomes can persist with recognizable homology over hundreds of millions of years, in spite of homology-obfuscating processes such as chromosomal fusion and translocation. The frequency and pace of these major genome structural changes are unknown, and it remains unclear whether or how they impact long-term genome evolution. Here, we compare whole chromosomal sequences of 3,631 genomes from 2,291 species spanning all major animal clades and show that animal karyotypes evolve primarily via karyotype contraction, associated with increased rates of chromosomal fusion-with-mixing and dispersion that largely obey chromosomal algebra ¹ , or karyotype expansion, which breaks up ancestral linkage groups and forms new chromosomal elements via non-algebraic changes. We show that chromosomal changes can be associated with major extinction events. Using a multi-scale encoding of pan-animal genome homology and a manifold representation of genomic changes, we find that genome evolution is not only driven by changes at the chromosomal level, but that subchromosomal mixing and irreversibility define clade-specific evolution. Using this ‘evolutionary genome topology’ approach, we calculate extrema of irreversible genomic configurations and identify species that occupy intermediate manifold positions, providing evidence for distinct macro-evolutionary trajectories. We propose that investigation of mixed state accumulation around important gene loci (such as Hox) will be crucial in capturing and further study of clade-specific regulatory innovations.