TY - JOUR
T1 - GPATCH11 variants cause mis-splicing and early-onset retinal dystrophy with neurological impairment
AU - Zanetti, Andrea
AU - Dujardin, Gwendal
AU - Fares-Taie, Lucas
AU - Amiel, Jeanne
AU - Roger, Jérôme E.
AU - Audo, Isabelle
AU - Robert, Matthieu P.
AU - David, Pierre
AU - Jung, Vincent
AU - Goudin, Nicolas
AU - Guerrera, Ida Chiara
AU - Moriceau, Stéphanie
AU - Amana, Danielle
AU - Assia Batzir, Nurit
AU - Bachar-Zipori, Anat
AU - Basel Salmon, Lina
AU - Boddaert, Nathalie
AU - Briault, Sylvain
AU - Bruel, Ange Line
AU - Costet-Fighiera, Christine
AU - Coutinho Santos, Luisa
AU - Gitiaux, Cyril
AU - Kaminska, Karolina
AU - Kuentz, Paul
AU - Orenstein, Naama
AU - Philip-Sarles, Nicole
AU - Plutino, Morgane
AU - Quinodoz, Mathieu
AU - Santos, Cristina
AU - Sigaudy, Sabine
AU - Soeiro e Sá, Mariana
AU - Sofrin, Efrat
AU - Sousa, Ana Berta
AU - Sousa-Luis, Rui
AU - Thauvin-Robinet, Christel
AU - van Dijk, Erwin L.
AU - Zaafrane-Khachnaoui, Khaoula
AU - Zur, Dinah
AU - Kaplan, Josseline
AU - Rivolta, Carlo
AU - Rozet, Jean Michel
AU - Perrault, Isabelle
N1 - Publisher Copyright:
© The Author(s) 2024.
PY - 2024/12
Y1 - 2024/12
N2 - Here we conduct a study involving 12 individuals with retinal dystrophy, neurological impairment, and skeletal abnormalities, with special focus on GPATCH11, a lesser-known G-patch domain-containing protein, regulator of RNA metabolism. To elucidate its role, we study fibroblasts from unaffected individuals and patients carrying the recurring c.328+1 G > T mutation, which specifically removes the main part of the G-patch domain while preserving the other domains. Additionally, we generate a mouse model replicating the patients’ phenotypic defects, including retinal dystrophy and behavioral abnormalities. Our results reveal a subcellular localization of GPATCH11 characterized by a diffuse presence in the nucleoplasm, as well as centrosomal localization, suggesting potential functions in RNA and cilia metabolism. Transcriptomic analysis performed on mouse retina detect dysregulation in both gene expression and splicing activity, impacting key processes such as photoreceptor light responses, RNA regulation, and primary cilia-associated metabolism. Proteomic analysis of mouse retina confirms the roles GPATCH11 plays in RNA processing, splicing, and transcription regulation, while also suggesting additional functions in synaptic plasticity and nuclear stress response. Our research provides insights into the diverse roles of GPATCH11 and identifies that the mutations affecting this protein are responsible for a recently characterized described syndrome.
AB - Here we conduct a study involving 12 individuals with retinal dystrophy, neurological impairment, and skeletal abnormalities, with special focus on GPATCH11, a lesser-known G-patch domain-containing protein, regulator of RNA metabolism. To elucidate its role, we study fibroblasts from unaffected individuals and patients carrying the recurring c.328+1 G > T mutation, which specifically removes the main part of the G-patch domain while preserving the other domains. Additionally, we generate a mouse model replicating the patients’ phenotypic defects, including retinal dystrophy and behavioral abnormalities. Our results reveal a subcellular localization of GPATCH11 characterized by a diffuse presence in the nucleoplasm, as well as centrosomal localization, suggesting potential functions in RNA and cilia metabolism. Transcriptomic analysis performed on mouse retina detect dysregulation in both gene expression and splicing activity, impacting key processes such as photoreceptor light responses, RNA regulation, and primary cilia-associated metabolism. Proteomic analysis of mouse retina confirms the roles GPATCH11 plays in RNA processing, splicing, and transcription regulation, while also suggesting additional functions in synaptic plasticity and nuclear stress response. Our research provides insights into the diverse roles of GPATCH11 and identifies that the mutations affecting this protein are responsible for a recently characterized described syndrome.
UR - http://www.scopus.com/inward/record.url?scp=85209708687&partnerID=8YFLogxK
U2 - 10.1038/s41467-024-54549-8
DO - 10.1038/s41467-024-54549-8
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C2 - 39572588
AN - SCOPUS:85209708687
SN - 2041-1723
VL - 15
JO - Nature Communications
JF - Nature Communications
IS - 1
M1 - 10096
ER -