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Browsing by Author "Holland, Steven M."
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Item Genetically programmed alternative splicing of NEMO mediates an autoinflammatory disease phenotype(The American Society for Clinical Investigation, 2022) Lee, Younglang; Wessel, Alex W.; Xu, Jiazhi; Reinke, Julia G.; Lee, Eries; Kim, Somin M.; Hsu, Amy P.; Zilberman-Rudenko, Jevgenia; Cao, Sha; Enos, Clinton; Brooks, Stephen R.; Deng, Zuoming; Lin, Bin; de Jesus, Adriana A.; Hupalo, Daniel N.; Piotto, Daniela G.P.; Terreri, Maria T.; Dimitriades, Victoria R.; Dalgard, Clifton L.; Holland, Steven M.; Goldbach-Mansky, Raphaela; Siegel, Richard M.; Hanson, Eric P.; Pediatrics, School of MedicineHost defense and inflammation are regulated by the NF-κB essential modulator (NEMO), a scaffolding protein with a broad immune cell and tissue expression profile. Hypomorphic mutations in inhibitor of NF-κB kinase regulatory subunit gamma (IKBKG) encoding NEMO typically present with immunodeficiency. Here, we characterized a pediatric autoinflammatory syndrome in 3 unrelated male patients with distinct X-linked IKBKG germline mutations that led to overexpression of a NEMO protein isoform lacking the domain encoded by exon 5 (NEMO-Δex5). This isoform failed to associate with TANK binding kinase 1 (TBK1), and dermal fibroblasts from affected patients activated NF-κB in response to TNF but not TLR3 or RIG-I-like receptor (RLR) stimulation when isoform levels were high. By contrast, T cells, monocytes, and macrophages that expressed NEMO-Δex5 exhibited increased NF-κB activation and IFN production, and blood cells from these patients expressed a strong IFN and NF-κB transcriptional signature. Immune cells and TNF-stimulated dermal fibroblasts upregulated the inducible IKK protein (IKKi) that was stabilized by NEMO-Δex5, promoting type I IFN induction and antiviral responses. These data revealed how IKBKG mutations that lead to alternative splicing of skipping exon 5 cause a clinical phenotype we have named NEMO deleted exon 5 autoinflammatory syndrome (NDAS), distinct from the immune deficiency syndrome resulting from loss-of-function IKBKG mutations.Item Somatic mutational landscape of hereditary hematopoietic malignancies caused by germline variants in RUNX1, GATA2, and DDX41(American Society of Hematology, 2023) Homan, Claire C.; Drazer, Michael W.; Yu, Kai; Lawrence, David M.; Feng, Jinghua; Arriola-Martinez, Luis; Pozsgai, Matthew J.; McNeely, Kelsey E.; Ha, Thuong; Venugopal, Parvathy; Arts, Peer; King-Smith, Sarah L.; Cheah, Jesse; Armstrong, Mark; Wang, Paul; Bödör, Csaba; Cantor, Alan B.; Cazzola, Mario; Degelman, Erin; DiNardo, Courtney D.; Duployez, Nicolas; Favier, Remi; Fröhling, Stefan; Rio-Machin, Ana; Klco, Jeffery M.; Krämer, Alwin; Kurokawa, Mineo; Lee, Joanne; Malcovati, Luca; Morgan, Neil V.; Natsoulis, Georges; Owen, Carolyn; Patel, Keyur P.; Preudhomme, Claude; Raslova, Hana; Rienhoff, Hugh; Ripperger, Tim; Schulte, Rachael; Tawana, Kiran; Velloso, Elvira; Yan, Benedict; Kim, Erika; Sood, Raman; Hsu, Amy P.; Holland, Steven M.; Phillips, Kerry; Poplawski, Nicola K.; Babic, Milena; Wei, Andrew H.; Forsyth, Cecily; Fan, Helen Mar; Lewis, Ian D.; Cooney, Julian; Susman, Rachel; Fox, Lucy C.; Blombery, Piers; Singhal, Deepak; Hiwase, Devendra; Phipson, Belinda; Schreiber, Andreas W.; Hahn, Christopher N.; Scott, Hamish S.; Liu, Paul; Godley, Lucy A.; Brown, Anna L.; NISC Comparative Sequencing Program; Pediatrics, School of MedicineIndividuals with germ line variants associated with hereditary hematopoietic malignancies (HHMs) have a highly variable risk for leukemogenesis. Gaps in our understanding of premalignant states in HHMs have hampered efforts to design effective clinical surveillance programs, provide personalized preemptive treatments, and inform appropriate counseling for patients. We used the largest known comparative international cohort of germline RUNX1, GATA2, or DDX41 variant carriers without and with hematopoietic malignancies (HMs) to identify patterns of genetic drivers that are unique to each HHM syndrome before and after leukemogenesis. These patterns included striking heterogeneity in rates of early-onset clonal hematopoiesis (CH), with a high prevalence of CH in RUNX1 and GATA2 variant carriers who did not have malignancies (carriers-without HM). We observed a paucity of CH in DDX41 carriers-without HM. In RUNX1 carriers-without HM with CH, we detected variants in TET2, PHF6, and, most frequently, BCOR. These genes were recurrently mutated in RUNX1-driven malignancies, suggesting CH is a direct precursor to malignancy in RUNX1-driven HHMs. Leukemogenesis in RUNX1 and DDX41 carriers was often driven by second hits in RUNX1 and DDX41, respectively. This study may inform the development of HHM-specific clinical trials and gene-specific approaches to clinical monitoring. For example, trials investigating the potential benefits of monitoring DDX41 carriers-without HM for low-frequency second hits in DDX41 may now be beneficial. Similarly, trials monitoring carriers-without HM with RUNX1 germ line variants for the acquisition of somatic variants in BCOR, PHF6, and TET2 and second hits in RUNX1 are warranted.