- Abassah-Oppong, Samuel;
- Mannion, Brandon J;
- Zoia, Matteo;
- Rouco, Raquel;
- Tissieres, Virginie;
- Spurrell, Cailyn H;
- Roland, Virginia;
- Darbellay, Fabrice;
- Ljubojevic, Anja;
- Gamart, Julie;
- Festa-Daroux, Tabitha A;
- Sullivan, Carly S;
- Rodríguez-Carballo, Eddie;
- Fukuda-Yuzawa, Yoko;
- Hunter, Riana;
- Novak, Catherine S;
- Plajzer-Frick, Ingrid;
- Tran, Stella;
- Akiyama, Jennifer A;
- Dickel, Diane E;
- Lopez-Rios, Javier;
- Barozzi, Iros;
- Andrey, Guillaume;
- Visel, Axel;
- Pennacchio, Len A;
- Cobb, John;
- Osterwalder, Marco
ABSTRACT
Gene deserts are defined as genomic regions devoid of protein coding genes and spanning more than 500 kilobases, collectively encompassing about 25% of the human genome. Approximately 30% of all gene deserts are enriched for conserved elements with cis -regulatory signatures. These are located predominantly near developmental transcription factors (TFs) but despite predicted critical functions, the transcriptional contributions and biological necessity of most gene deserts remain elusive. Here, we explore the cis -regulatory impact of a gene desert flanking the Shox2 gene, a TF indispensable for proximal limb, craniofacial and cardiac pacemaker development. Using a functional genomics approach in mouse embryos we identify the gene desert as a hub for numerous Shox2 -overlapping enhancers arranged in a globular chromatin domain with tissue-specific features. In accordance, using endogenous CRISPR deletion, we demonstrate that the gene desert interval is essential for Shox2 transcriptional control in developing limbs, craniofacial compartments, and the heart. Phenotypically, gene desert ablation leads to pacemaker-related embryonic lethality due to Shox2 depletion in the cardiac sinus venosus. We show that this role is partially mediated through a distal gene desert enhancer, providing evidence for intra-gene desert regulatory robustness. Finally, we uncover a multi-layered functional role of the gene desert by revealing an additional requirement for stylopod morphogenesis, mediated through an array of proximal limb enhancers (PLEs). In summary, our study establishes the Shox2 gene desert as a fundamental genomic unit that controls pleiotropic gene expression through modular arrangement and coordinated dynamics of tissue-specific enhancers.