Genome expansions and regulatory contact entanglement help preserve ancestral metazoan synteny

Chromosomes constitute deeply conserved evolutionary units in many metazoan genomes, with chromosomal fusions and fissions, accompanied by sub-chromosomal rearrangements, rewiring three dimensional genome architecture. How chromatin loops and compartments that define distal regulatory interactions within chromosomes impose functional constraints that affect this long-term evolutionary process (and vice-versa) is an emerging research topic. Genome expansions, especially through transposable element (TE) activity, test these constraints by increasing the genomic distances over which regulatory interactions must function and were thus suggested to be the drivers of chromosomal rearrangements. To study dynamics and stability of such distal interactions in the light of genome expansions, we focus on the cnidarian Hydra vulgaris , which, based on its simple and well-understood biology as well as one of the largest genomes among cnidarians, is particularly suited to test how chromatin loop and genome architecture respond to genome expansion. We investigate genome architecture using Micro-C, single-cell Hi-C (Dip-C), and DNA FISH, and perform comparative analysis using available genomic and epigenomic data. Contrary to prior expectations, our analysis of whole-genome data and particular loci (e.g., Wnt) suggests a scenario where genome expansion did not only result in chromatin loops often reaching several megabases in hydra, but also led to regulatory contact mixing and entanglement, introducing additional constraints to maintain ancestral genomic architecture. Generalizing these findings across hundreds of metazoan genomes, we show a new mechanistic role for genome expansion in yielding entangled long-range regulatory configurations that, in turn, decelerate chromosomal rearrangements, thus maintaining (and not breaking) ancestral regulatory states and synteny.