Department of Psychiatry, Nagoya University Graduate School of Medicine, Nagoya, Japan.
Department of Neuroscience I, Research Institute of Environmental Medicine, Nagoya University, Nagoya, Japan.
Transl Psychiatry. 2022 Feb 26;12(1):84. doi: 10.1038/s41398-022-01851-y.
Several large-scale whole-exome sequencing studies in patients with schizophrenia (SCZ) and autism spectrum disorder (ASD) have identified rare variants with modest or strong effect size as genetic risk factors. Dysregulation of cellular calcium homeostasis might be involved in SCZ/ASD pathogenesis, and genes encoding L-type voltage-gated calcium channel (VGCC) subunits Ca1.1 (CACNA1S), Ca1.2 (CACNA1C), Ca1.3 (CACNA1D), and T-type VGCC subunit Ca3.3 (CACNA1I) recently were identified as risk loci for psychiatric disorders. We performed a screening study, using the Ion Torrent Personal Genome Machine (PGM), of exon regions of these four candidate genes (CACNA1C, CACNA1D, CACNA1S, CACNA1I) in 370 Japanese patients with SCZ and 192 with ASD. Variant filtering was applied to identify biologically relevant mutations that were not registered in the dbSNP database or that have a minor allele frequency of less than 1% in East-Asian samples from databases; and are potentially disruptive, including nonsense, frameshift, canonical splicing site single nucleotide variants (SNVs), and non-synonymous SNVs predicted as damaging by five different in silico analyses. Each of these filtered mutations were confirmed by Sanger sequencing. If parental samples were available, segregation analysis was employed for measuring the inheritance pattern. Using our filter, we discovered one nonsense SNV (p.C1451* in CACNA1D), one de novo SNV (p.A36V in CACNA1C), one rare short deletion (p.E1675del in CACNA1D), and 14 NSstrict SNVs (non-synonymous SNV predicted as damaging by all of five in silico analyses). Neither p.A36V in CACNA1C nor p.C1451* in CACNA1D were found in 1871 SCZ cases, 380 ASD cases, or 1916 healthy controls in the independent sample set, suggesting that these SNVs might be ultra-rare SNVs in the Japanese population. The neuronal splicing isoform of Ca1.2 with the p.A36V mutation, discovered in the present study, showed reduced Ca-dependent inhibition, resulting in excessive Ca entry through the mutant channel. These results suggested that this de novo SNV in CACNA1C might predispose to SCZ by affecting Ca homeostasis. Thus, our analysis successfully identified several ultra-rare and potentially disruptive gene variants, lending partial support to the hypothesis that VGCC-encoding genes may contribute to the risk of SCZ/ASD.
几项针对精神分裂症(SCZ)和自闭症谱系障碍(ASD)患者的全外显子组测序大型研究已经确定了具有中等或较大效应大小的罕见变异作为遗传风险因素。细胞钙稳态的失调可能与 SCZ/ASD 的发病机制有关,最近编码 L 型电压门控钙通道(VGCC)亚基 Ca1.1(CACNA1S)、Ca1.2(CACNA1C)、Ca1.3(CACNA1D)和 T 型 VGCC 亚基 Ca3.3(CACNA1I)的基因被确定为精神疾病的风险基因。我们使用 Ion Torrent Personal Genome Machine(PGM)对 370 名日本精神分裂症患者和 192 名自闭症患者的这四个候选基因(CACNA1C、CACNA1D、CACNA1S、CACNA1I)的外显子区域进行了筛选研究。通过对未在 dbSNP 数据库中注册或东亚人群数据库中频率低于 1%的生物相关突变进行过滤,筛选出潜在的破坏性突变,包括无义、移码、规范剪接位点单核苷酸变异(SNV)和 5 种不同的计算分析预测为有害的非同义 SNV。通过 Sanger 测序对这些经过过滤的突变进行了验证。如果有父母样本,我们采用了遗传分析来测量遗传模式。使用我们的筛选器,我们发现了一个无义 SNV(CACNA1D 中的 p.C1451*),一个新的 SNV(CACNA1C 中的 p.A36V),一个罕见的短缺失(CACNA1D 中的 p.E1675del)和 14 个 NSstrict SNVs(5 种计算分析均预测为有害的非同义 SNV)。在独立样本集中,CACNA1C 中的 p.A36V 或 CACNA1D 中的 p.C1451*均未在 1871 例精神分裂症病例、380 例自闭症病例或 1916 例健康对照中发现,提示这些 SNV 可能是日本人群中的超罕见 SNV。本研究发现的携带 p.A36V 突变的 Ca1.2 神经元剪接异构体显示出 Ca 依赖性抑制减少,导致通过突变通道的 Ca 内流增加。这些结果表明,CACNA1C 中的这个新的 SNV 可能通过影响钙稳态而导致精神分裂症的易感性。因此,我们的分析成功地鉴定了几个超罕见且具有潜在破坏性的基因变异,部分支持了 VGCC 编码基因可能导致 SCZ/ASD 风险的假说。
