A humanized yeast model for studying TRAPP complex mutations; proof-of-concept using variants from an individual with a TRAPPC1-associated neurodevelopmental syndrome

Erta Zykaj, Chelsea Abboud, Paria Asadi, Simane Warsame, Brittany Greco, Marcos López-Sánchez, Drago Bratkovic, Aashiq Kachroo, Luis Alberto Pérez-Jurado, Michael Sacher
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Abstract

Variants in membrane trafficking proteins are known to cause rare disorders with severe symptoms. The highly conserved transport protein particle (TRAPP) complexes are key membrane trafficking regulators that are also involved in autophagy. Pathogenic genetic variants in specific TRAPP subunits are linked to neurological disorders, muscular dystrophies, and skeletal dysplasias. Characterizing these variants and their phenotypes is important for understanding general and specialized roles of TRAPP subunits as well as for patient diagnosis. Patient-derived cells are not always available, which poses a limitation for the study of these diseases. Therefore, other systems, like the yeast Saccharomyces cerevisiae, can be used to dissect the mechanisms at the intracellular level underlying these disorders. The development of CRISPR/Cas9 technology in yeast has enabled a scar-less editing method that creates an efficient humanized yeast model. In this study, core yeast subunits were humanized by replacing their human orthologs, and TRAPPC1, TRAPPC2, TRAPPC2L, TRAPPC6A, and TRAPPC6B were found to successfully replace their yeast counterparts. This system was used for studying the first reported individual with an autosomal recessive disorder caused by biallelic TRAPPC1 variants, a girl with a severe neurodevelopmental disorder and myopathy. We show that the maternal variant (TRAPPC1 p.(Val121Alafs*3)) is non-functional while the paternal variant (TRAPPC1 p.(His22_Lys24del)) is conditional-lethal and affects secretion and non-selective autophagy in yeast. This parallels defects seen in fibroblasts derived from this individual which also showed membrane trafficking defects and altered Golgi morphology, all of which were rescued in the human system by wild type TRAPPC1. This study suggests that humanized yeast can be an efficient means to study TRAPP subunit variants in the absence of human cells, and can assign significance to variants of unknown significance (VUS). This study lays the foundation for characterizing further TRAPP variants through this system, rapidly contributing to disease diagnosis.
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研究 TRAPP 复合体突变的人源化酵母模型;使用 TRAPPC1 相关神经发育综合征患者的变异体进行概念验证
众所周知,膜转运蛋白的变异可导致症状严重的罕见疾病。高度保守的转运蛋白颗粒(TRAPP)复合物是关键的膜转运调节因子,也参与自噬。特定 TRAPP 亚基的致病基因变异与神经系统疾病、肌肉萎缩症和骨骼发育不良有关。鉴定这些变异及其表型对于了解 TRAPP 亚基的一般和特殊作用以及诊断患者非常重要。患者衍生细胞并不总是可用的,这对这些疾病的研究造成了限制。因此,可以利用酵母等其他系统来剖析这些疾病的细胞内机制。CRISPR/Cas9技术在酵母中的发展使无疤痕编辑方法成为可能,这种方法可以创建高效的人源化酵母模型。在这项研究中,通过替换酵母核心亚基的人类同源物实现了人源化,并发现 TRAPPC1、TRAPPC2、TRAPPC2L、TRAPPC6A 和 TRAPPC6B 成功替换了酵母对应物。该系统被用于研究首个报道的由双侧TRAPPC1变体引起的常染色体隐性遗传疾病患者--一名患有严重神经发育障碍和肌病的女孩。我们发现,母系变体(TRAPPC1 p.(Val121Alafs*3) )是无功能的,而父系变体(TRAPPC1 p.(His22_Lys24del) )是条件致死的,会影响酵母的分泌和非选择性自噬。这与从该个体衍生的成纤维细胞中发现的缺陷相似,这些成纤维细胞也表现出膜贩运缺陷和高尔基体形态改变,而在人类系统中,野生型 TRAPPC1 能挽救所有这些缺陷。这项研究表明,在没有人类细胞的情况下,人源化酵母是研究 TRAPP 亚基变体的有效方法,并能对意义不明的变体(VUS)进行鉴定。这项研究为通过该系统进一步鉴定 TRAPP 变异奠定了基础,从而为疾病诊断做出快速贡献。
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