Clinical, , and evidence of as a novel cohesinopathy gene and phenotypic driver of 10q22.3q23.2 genomic disorder.
| Authors | |
| Keywords | |
| Abstract | Cohesin is a fundamental genome-organizing complex that orchestrates three-dimensional chromosome folding and gene expression via DNA loop extrusion. Alterations to genes encoding cohesin subunits and cohesin loaders cause Mendelian disorders, including Cornelia de Lange syndrome (CdLS). By contrast, disruption of factors that remove cohesin from DNA, including and its binding partners and , have not yet been associated with human disease. Here, we explored the relevance of these cohesin release factors in Mendelian disease by establishing a rare disease cohort of deeply phenotyped individuals with heterozygous, predicted damaging variants in (n=27), (n=8), and (n=8), by modeling deficiency in human cell lines and mice, and by aggregating rare disease association statistics from consortia studies. We identified a -related disorder characterized by developmental delay, intellectual disability, and risk of other developmental anomalies including clubfoot. Similarities between individuals with damaging variants and those with large, recurrent 10q22.3q23.2 (10q) deletions (which encompass ) nominate as a driver gene within this genomic disorder region. While carriers of or variants exhibited features of developmental disorders, neither cohort-based statistics nor case phenotyping associated these genes with specific phenotypes. We used CRISPR engineering to generate truncating variants in , as well the 7.8 Mb 10q deletion or duplication in human iPSCs and induced neurons. Transcriptomic analyses identified differentially expressed genes in both models, with highly significant overlap between haploinsufficiency and 10q deletion signatures. Mice with 50% residual expression exhibited mild deficits of growth and learning/memory, whereas those with 25% residual expression displayed birth defects and postnatal lethality, revealing a dosage liability threshold below the level of heterozygosity. In summary, we delineated a novel genetic condition caused by cohesin release factor deficiency, nominated as a driver gene within a genomic disorder region, and further illuminated dosage sensitivity of human cohesin. |
| Year of Publication | 2026
|
| Journal | medRxiv : the preprint server for health sciences
|
| Date Published | 02/2026
|
| DOI | 10.64898/2026.02.23.26346364
|
| PubMed ID | 41810376
|
| Links |