TY - JOUR
T1 - Distinct pathophysiological mechanisms of CEP152 variants in microcephaly and brain abnormalities
AU - Hamada, Nanako
AU - AlAbdi, Lama
AU - Uehara, Tomoko
AU - Sasikarn, Looprasertkul
AU - Nishijo, Takuma
AU - Suliman-Lavie, Reut
AU - Hashem, Mais O.
AU - Alfadhel, Majid
AU - Alhefdhi, Shatha
AU - Tabarki, Brahim
AU - Alghamdi, Malak
AU - Iwamoto, Ikuko
AU - Takenouchi, Toshiki
AU - Kosaki, Kenjiro
AU - Shifman, Sagiv
AU - Mizuno, Seiji
AU - Ohno, Nobuhiko
AU - Alkuraya, Fowzan S.
AU - Nagata, Koh Ichi
N1 - Publisher Copyright:
© The Author(s) 2026.
PY - 2026
Y1 - 2026
N2 - CEP152 is essential for centriole function and neurodevelopment, and pathogenic recessive variants in CEP152 cause primary microcephaly. We identified new compound heterozygous CEP152 variants, c.314 G > A,p.(W105*) and c.2689 A > T,p.(K897*), in a microcephalic patient and analyzed them alongside a homozygous variant c.95 A > C,p.(Q32P) associated with severe microcephaly with marked gyral simplification. In vitro assays revealed distinct effects: p.K897* prevented centrosomal localization, p.W105* led to protein degradation, and p.Q32P retained centrosomal targeting but disrupted binding to Polo-like kinase 4, a key centriole biogenesis kinase and CEP152 partner. In vivo, both Cep152W105*/K897* and Cep152Q32P/Q32P knock-in mice displayed microcephaly; notably, Cep152Q32P/Q32P mice also exhibited severe cortical defects during brain development. Cellular analyses revealed centrosome dysfunction, mitotic errors, and increased apoptosis, which were exacerbated in Cep152Q32P/Q32P brains. Morphological examination, including electron microscopy, further demonstrated structural abnormalities of the centrosomes and centrioles in Cep152Q32P/Q32P brains. Electrophysiological and gene expression analyses confirmed variant-specific neuronal impairments, which correlate with clinical severity. Collectively, these findings demonstrate that distinct CEP152 variants disrupt neurodevelopment through different mechanisms, thereby explaining the spectrum of microcephaly severity and associated phenotypes.
AB - CEP152 is essential for centriole function and neurodevelopment, and pathogenic recessive variants in CEP152 cause primary microcephaly. We identified new compound heterozygous CEP152 variants, c.314 G > A,p.(W105*) and c.2689 A > T,p.(K897*), in a microcephalic patient and analyzed them alongside a homozygous variant c.95 A > C,p.(Q32P) associated with severe microcephaly with marked gyral simplification. In vitro assays revealed distinct effects: p.K897* prevented centrosomal localization, p.W105* led to protein degradation, and p.Q32P retained centrosomal targeting but disrupted binding to Polo-like kinase 4, a key centriole biogenesis kinase and CEP152 partner. In vivo, both Cep152W105*/K897* and Cep152Q32P/Q32P knock-in mice displayed microcephaly; notably, Cep152Q32P/Q32P mice also exhibited severe cortical defects during brain development. Cellular analyses revealed centrosome dysfunction, mitotic errors, and increased apoptosis, which were exacerbated in Cep152Q32P/Q32P brains. Morphological examination, including electron microscopy, further demonstrated structural abnormalities of the centrosomes and centrioles in Cep152Q32P/Q32P brains. Electrophysiological and gene expression analyses confirmed variant-specific neuronal impairments, which correlate with clinical severity. Collectively, these findings demonstrate that distinct CEP152 variants disrupt neurodevelopment through different mechanisms, thereby explaining the spectrum of microcephaly severity and associated phenotypes.
UR - https://www.scopus.com/pages/publications/105037867973
U2 - 10.1038/s44321-026-00427-3
DO - 10.1038/s44321-026-00427-3
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C2 - 42086905
AN - SCOPUS:105037867973
SN - 1757-4676
JO - EMBO Molecular Medicine
JF - EMBO Molecular Medicine
ER -