Abstract
Spinocerebellar ataxia type 29 (SCA29) is autosomal dominant congenital ataxia characterized by early-onset motor delay, hypotonia, and gait ataxia. Recently, heterozygous missense mutations in an intracellular Ca(2+) channel, inositol 1,4,5-trisphosphate (IP(3)) receptor type 1 (IP(3)R1), were identified as a cause of SCA29. However, the functional impacts of these mutations remain largely unknown. Here, we determined the molecular mechanisms by which pathological mutations affect IP(3)R1 activity and Ca(2+) dynamics. Ca(2+) imaging using IP(3)R-null HeLa cells generated by genome editing revealed that all SCA29 mutations identified within or near the IP(3)-binding domain of IP(3)R1 completely abolished channel activity. Among these mutations, R241K, T267M, T267R, R269G, R269W, S277I, K279E, A280D, and E497K impaired IP(3) binding to IP(3)R1, whereas the T579I and N587D mutations disrupted channel activity without affecting IP(3) binding, suggesting that T579I and N587D compromise channel gating mechanisms. Carbonic anhydrase-related protein VIII (CA8) is an IP(3)R1-regulating protein abundantly expressed in cerebellar Purkinje cells and is a causative gene of congenital ataxia. The SCA29 mutation V1538M within the CA8-binding site of IP(3)R1 completely eliminated its interaction with CA8 and CA8-mediated IP(3)R1 inhibition. Furthermore, pathological mutations in CA8 decreased CA8-mediated suppression of IP(3)R1 by reducing protein stability and the interaction with IP(3)R1. These results demonstrated the mechanisms by which pathological mutations cause IP(3)R1 dysfunction, i.e., the disruption of IP(3) binding, IP(3)-mediated gating, and regulation via the IP(3)R-modulatory protein. The resulting aberrant Ca(2+) homeostasis may contribute to the pathogenesis of cerebellar ataxia.