TY - JOUR T1 - A gene desert required for regulatory control of pleiotropic <em>Shox2</em> expression and embryonic survival JF - bioRxiv DO - 10.1101/2020.11.22.393173 SP - 2020.11.22.393173 AU - Samuel Abassah-Oppong AU - Brandon J. Mannion AU - Virginie Tissières AU - Eddie Rodríguez-Carballo AU - Anja Ljubojevic AU - Fabrice Darbellay AU - Tabitha A. Festa AU - Carly S. Sullivan AU - Guy Kelman AU - Riana D. Hunter AU - Catherine S. Novak AU - Ingrid Plajzer-Frick AU - Stella Tran AU - Jennifer A. Akiyama AU - Iros Barozzi AU - Guillaume Andrey AU - Javier Lopez-Rios AU - Diane E. Dickel AU - Axel Visel AU - Len A. Pennacchio AU - John Cobb AU - Marco Osterwalder Y1 - 2020/01/01 UR - http://biorxiv.org/content/early/2020/11/22/2020.11.22.393173.abstract N2 - The Shox2 homeodomain transcriptional regulator is known for its critical functions during mouse embryogenesis, enabling accurate development of limbs, craniofacial structures, neural populations and the cardiac conduction system. At the genomic level, the Shox2 gene is flanked by an extensive gene desert, a continuous non-coding genomic region spanning over 500 kilobases that contains a multitude of evolutionarily conserved elements with predicted cis-regulatory activities. However, the transcriptional enhancer potential of the vast majority of these elements in combination with the biological necessity of the gene desert have not yet been explored. Using transgenic reporter assays in mouse embryos to validate an extensive set of stringent epigenomic enhancer predictions, we identify several novel gene desert enhancers with distinct tissue-specific activities in Shox2 expressing tissues. 4C-seq chromatin conformation capture further uncovers a repertoire of gene desert enhancers with overlapping activities in the proximal limb, in a compartment essential for Shox2-mediated stylopod formation. Leveraging CRISPR/Cas9 to delete the gene desert region contained in the Shox2 topologically associated domain (TAD), we demonstrate that this complex cis-regulatory platform is essential for embryonic survival and required for control of region-specific Shox2 expression in multiple developing tissues. While transcription of Shox2 in the embryonic limb is only moderately affected by gene desert loss, Shox2 expression in craniofacial and cardiac domains is nearly abolished. In particular, Shox2 transcripts in the sinus venosus (SV) encompassing the sinoatrial node (SAN) were depleted in embryos lacking the gene desert, likely accounting for the embryonic lethality due to Shox2-dependency of the SAN pacemaker. Finally, we discover a 1.5kb SV enhancer within the deleted gene desert region, which may act as a genomic module controlling the development of the cardiac conduction system. In summary, our results identify a gene desert indispensable for pleiotropic patterning and highlight the importance of these extensive regulatory landscapes for embryonic development and viability.Competing Interest StatementThe authors have declared no competing interest. ER -