Department of Industrial and Environmental Engineering, Graduate School of Environment, Gachon University, Seongnam 13120, Republic of Korea.
Department of Bionano Technology, Gachon Medical Research Institute, Gachon University, Seongnam 13120, Republic of Korea.
Int J Mol Sci. 2024 Nov 7;25(22):11959. doi: 10.3390/ijms252211959.
Alzheimer's disease (AD) is a complex neurodegenerative disorder influenced by various genetic factors. In addition to the well-established amyloid precursor protein (), Presenilin-1 (), Presenilin-2 (), and apolipoprotein E (), several other genes such as Sortilin-related receptor 1 (), Phospholipid-transporting ATPase ABCA7 (), Triggering Receptor Expressed on Myeloid Cells 2 (), Phosphatidylinositol-binding clathrin assembly protein (), and clusterin () were implicated. These genes contribute to neurodegeneration through both gain-of-function and loss-of-function mechanisms. While it was traditionally thought that heterozygosity in autosomal recessive mutations does not lead to disease, haploinsufficiency was linked to several conditions, including cancer, autism, and intellectual disabilities, indicating that a single functional gene copy may be insufficient for normal cellular functions. In AD, the haploinsufficiency of genes such as and may play significant yet under-explored roles. Paradoxically, heterozygous knockouts of or can impair synaptic plasticity and alter the expression of genes involved in oxidative phosphorylation and cell adhesion. Animal studies examining haploinsufficient AD risk genes, such as vacuolar protein sorting-associated protein 35 (), sirtuin-3 (), and , have shown that their knockout can exacerbate neurodegenerative processes by promoting amyloid production, accumulation, and inflammation. Conversely, haploinsufficiency in , beta-secretase 1 (), and transmembrane protein 59 () was reported to confer neuroprotection by potentially slowing amyloid deposition and reducing microglial activation. Given its implications for other neurodegenerative diseases, the role of haploinsufficiency in AD requires further exploration. Modeling the mechanisms of gene knockout and monitoring their expression patterns is a promising approach to uncover AD-related pathways. However, challenges such as identifying susceptible genes, gene-environment interactions, phenotypic variability, and biomarker analysis must be addressed. Enhancing model systems through humanized animal or cell models, utilizing advanced research technologies, and integrating multi-omics data will be crucial for understanding disease pathways and developing new therapeutic strategies.
阿尔茨海默病(AD)是一种复杂的神经退行性疾病,受多种遗传因素影响。除了已确立的淀粉样前体蛋白()、早老素-1()、早老素-2()和载脂蛋白 E(),还有其他几个基因,如分选连接蛋白相关受体 1()、磷脂转运 ATP 酶 ABCA7()、髓样细胞触发受体 2()、磷酸肌醇结合网格蛋白装配蛋白()和聚集素(),也与 AD 有关。这些基因通过功能获得和功能丧失机制导致神经退行性变。虽然传统上认为常染色体隐性突变的杂合性不会导致疾病,但单倍体不足与多种疾病有关,包括癌症、自闭症和智力障碍,这表明单个功能性基因拷贝可能不足以维持正常细胞功能。在 AD 中,基因如和的单倍体不足可能发挥重要但尚未充分探索的作用。矛盾的是,或的杂合敲除会损害突触可塑性,并改变参与氧化磷酸化和细胞黏附的基因的表达。研究 AD 风险基因(如液泡蛋白分选相关蛋白 35()、Sirtuin-3()和)的动物研究表明,它们的敲除会通过促进淀粉样蛋白的产生、积累和炎症而加剧神经退行性过程。相反,报道称,在和基因中存在单倍体不足会通过潜在地减缓淀粉样蛋白沉积和减少小胶质细胞激活来提供神经保护作用。鉴于其对其他神经退行性疾病的影响,AD 中单倍体不足的作用需要进一步探索。模拟基因敲除的机制并监测其表达模式是揭示 AD 相关途径的有前途的方法。然而,必须解决一些挑战,如鉴定易感基因、基因-环境相互作用、表型变异性和生物标志物分析。通过人类化动物或细胞模型增强模型系统,利用先进的研究技术,并整合多组学数据,对于理解疾病途径和开发新的治疗策略将至关重要。
