Center for Medical Genetics, Keio University School of Medicine, Tokyo, Japan.
Department of Life Science and Medical Bio-Science, Waseda University, Tokyo, Japan.
Hum Mol Genet. 2022 Dec 16;31(24):4173-4182. doi: 10.1093/hmg/ddac166.
Collapsin response mediator protein 2 (Crmp2) is an evolutionarily well-conserved tubulin-binding cytosolic protein that plays critical roles in the formation of neural circuitry in model organisms including zebrafish and rodents. No clinical evidence that CRMP2 variants are responsible for monogenic neurogenic disorders in humans presently exists. Here, we describe two patients with de novo non-synonymous variants (S14R and R565C) of CRMP2 and intellectual disability associated with hypoplasia of the corpus callosum. We further performed various functional assays of CRMP2 variants using zebrafish and zebrafish Crmp2 (abbreviated as z-CRMP2 hereafter) and an antisense morpholino oligonucleotide [AMO]-based experimental system in which crmp2-morphant zebrafish exhibit the ectopic positioning of caudal primary (CaP) motor neurons. Whereas the co-injection of wild-type z-CRMP2 mRNA suppressed the ectopic positioning of CaP motor neurons in Crmp2-morphant zebrafish, the co-injection of R566C or S15R, z-CRMP2, which corresponds to R565C and S14R of human CRMP2, failed to rescue the ectopic positioning. Transfection experiments of zebrafish or rat Crmp2 using plasmid vectors in HeLa cells, with or without a proteasome inhibitor, demonstrated that the expression levels of mutant Crmp2 protein encoded by R565C and S14R CRMP2 variants were decreased, presumably because of increased degradation by proteasomes. When we compared CRMP2-tubulin interactions using co-immunoprecipitation and cellular localization studies, the R565C and S14R mutations weakened the interactions. These results collectively suggest that the CRMP2 variants detected in the present study consistently led to the loss-of-function of CRMP2 protein and support the notion that pathogenic variants in CRMP2 can cause intellectual disabilities in humans.
collapsin 反应介体蛋白 2(Crmp2)是一种进化上高度保守的微管结合胞质蛋白,在包括斑马鱼和啮齿动物在内的模式生物的神经回路形成中发挥关键作用。目前没有临床证据表明 CRMP2 变体是导致人类单基因神经发育障碍的原因。在这里,我们描述了两名患有从头非同义变异(S14R 和 R565C)的 CRMP2 和伴有胼胝体发育不全的智力障碍患者。我们进一步使用斑马鱼和斑马鱼 Crmp2(简称 z-CRMP2)以及基于反义 morpholino 寡核苷酸(AMO)的实验系统对 CRMP2 变体进行了各种功能测定,在该系统中,crmp2 突变体斑马鱼的尾部初级(CaP)运动神经元异位定位。虽然野生型 z-CRMP2 mRNA 的共注射抑制了 Crmp2 突变体斑马鱼中 CaP 运动神经元的异位定位,但 R566C 或 S15R 的共注射,与人类 CRMP2 的 R565C 和 S14R 相对应,未能挽救异位定位。用质粒载体在 HeLa 细胞中转染斑马鱼或大鼠 Crmp2,用或不用蛋白酶体抑制剂,表明由 R565C 和 S14R CRMP2 变体编码的突变型 Crmp2 蛋白的表达水平降低,推测是由于蛋白酶体的降解增加所致。当我们使用免疫共沉淀和细胞定位研究比较 CRMP2-微管相互作用时,R565C 和 S14R 突变削弱了相互作用。这些结果共同表明,本研究中检测到的 CRMP2 变体一致导致 CRMP2 蛋白的功能丧失,并支持 CRMP2 中的致病性变体可导致人类智力障碍的观点。
