The giant axolotl genome uncovers the evolution, scaling, and transcriptional control of complex gene loci

Siegfried Schloissnig; Akane Kawaguchi; Sergej Nowoshilow; Francisco José Calazans Falcón; Leo Otsuki; Pietro Tardivo; Nataliya Timoshevskaya; Melissa C. Keinath; Jeramiah J. Smith; S. Randal Voss; Elly M. Tanaka

doi:10.1073/pnas.2017176118

The giant axolotl genome uncovers the evolution, scaling, and transcriptional control of complex gene loci

Siegfried Schloissnig(Research Institute of Molecular Pathology), Akane Kawaguchi(Research Institute of Molecular Pathology), Sergej Nowoshilow(Research Institute of Molecular Pathology), Francisco José Calazans Falcón(Research Institute of Molecular Pathology), Leo Otsuki(Research Institute of Molecular Pathology), Pietro Tardivo(Research Institute of Molecular Pathology), Nataliya Timoshevskaya(University of Kentucky), Melissa C. Keinath(University of Kentucky), Jeramiah J. Smith(University of Kentucky), S. Randal Voss(University of Kentucky), Elly M. Tanaka(Research Institute of Molecular Pathology)

Proceedings of the National Academy of Sciences

April 7, 2021

10.1073/pnas.2017176118

Cited by 128Open Access

Full Text

Abstract

Significance The axolotl is an important model organism because it is a tetrapod with a similar body plan to humans. Unlike humans, the axolotl regenerates limbs and other complex tissues. Therefore, the axolotl contributes to understanding evolution, development, and regeneration. With sophisticated tools for gene modification and tissue labeling, a fully assembled genome sequence was a sorely missing resource. Assembly was difficult because the genome size is 10× that of humans. Here, we use a cross-linking strategy called Hi-C to link together fragmented genome sequences to chromosome scale. We show that gene regulation occurs over very large genomic distances and that mitotic chromosomes are packaged efficiently.

Related Papers

No related papers found

Powered by citation graph analysis