AD中不依赖前体的β -淀粉样蛋白过量产生:线粒体功能障碍可能引发不对称rna依赖的β - app mRNA扩增。驱动阿尔茨海默病的引擎

V. Volloch, B. Olsen, S. Rits
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In FAD, the initial increase in the production of Aβ is mutations-based and occurs relatively early in life, whereas in SAD it is coerced by an aging-contingent component, but both lead to mechanistically identical self-perpetuating mutual Aβ/mitochondrial dysfunction feedback cycles, an engine that drives, via RNA-dependent βAPP mRNA amplification, overproduction of beta-amyloid and, consequently, AD; hence drastic difference in the age of onset, yet profound pathological and symptomatic similarity in the progression, of familial and sporadic forms of Alzheimer's disease. Interestingly, the recent findings that mitochondrial microprotein PIGBOS interacts with the ER in mitigating the unfolded protein response indicate a possible connection between mitochondrial dysfunction and ER stress, implicated in activation of RNA-dependent mRNA amplification pathway. The possible involvement of mitochondrial dysfunction in βAPP mRNA amplification makes it a promising therapeutic target. 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引用次数: 9

摘要

本研究将βAPP mRNA的rna依赖性扩增定义为阿尔茨海默病中β -淀粉样蛋白过量产生的分子基础。在这个过程中,βAPP mRNA作为RNA依赖性RNA聚合酶RdRp复合物的模板。由此产生的反义RNA利用两个互补元件自引其延伸:3'端和内部,位于与βAPP mRNA编码部分对应的反义片段内。延伸产生βAPP mRNA的3'端片段,这是发夹结构反义/正RNA分子的一部分。在发夹环的3'端切割产生编码βAPP c端片段的RNA终产物。由于每个传统的βAPP mRNA都可以重复用作模板,因此该过程构成了不对称的mRNA扩增。扩增mRNA的5'端翻译起始密码子是紧邻a β编码段的AUG,并在框架内。该密码子的翻译独立于βAPP过量产生Aβ。这种过程可以发生在人类身上,但不会发生在小鼠和其他动物身上,因为自引所需的βAPP反义RNA片段几乎没有互补性。这解释了为什么阿尔茨海默病只发生在人类身上,并暗示βAPP mRNA扩增在阿尔茨海默病中是必要的。因此,在AD中,β -淀粉样蛋白的产生有两种途径:βAPP蛋白水解途径和βAPP mRNA扩增途径,它们独立于βAPP,对β分泌酶抑制不敏感。这表明,在只有蛋白水解途径起作用的健康人群中,BACE抑制作用应该会抑制Aβ的产生,事实也确实如此。然而,由于β app非依赖性通路在AD中起主导作用,BACE抑制在阿尔茨海默病中没有作用。从生理学角度来看,β -淀粉样蛋白过量产生的程度足以触发淀粉样蛋白级联,最终导致AD,这需要βAPP mRNA的非对称rna依赖扩增,没有它就无法达到。反过来,mRNA扩增过程的发生依赖于RdRp复合物的诱导组分在某些胁迫下的激活,例如编码细胞外基质蛋白的mRNA扩增时的内质网胁迫。在阿尔茨海默病的情况下,这种诱导似乎是由与线粒体功能障碍相关的压力触发的,这种现象与AD密切相关。线粒体功能障碍与AD之间的因果关系在家族性、FAD和散发性SAD病例中似乎非常不同。在FAD中,βAPP蛋白水解异常导致的Aβ水平升高或毒性物质增多会触发线粒体功能障碍,激活mRNA扩增并增加Aβ的产生,从而加强循环。因此,在FAD中,线粒体功能障碍是淀粉样蛋白级联的内在组成部分。在SAD中,与衰老相关的线粒体功能障碍激活βAPP mRNA的扩增,并增强Aβ的产生。这会导致进一步的线粒体功能障碍,循环重复,退化加剧。因此,在SAD中,最初的线粒体功能障碍在疾病之前出现,独立于Aβ产生的增加,并在上游出现,即在SAD中,线粒体病理在层次上取代了Aβ病理。这是提出线粒体级联假说的主要原因。但就MCH而言,该疾病的核心是淀粉样蛋白级联在淀粉样蛋白级联假说中定义,ACH。与该核心相关的线粒体功能障碍在SAD中起致病作用,在FAD中起辅助作用。在FAD中,Aβ产生的初始增加是基于突变的,发生在生命的相对早期,而在SAD中,它是由衰老因素强制的,但两者都会导致机制相同的自我延续的相互Aβ/线粒体功能障碍反馈循环,这是一个引擎,通过rna依赖性βAPP mRNA扩增,驱动β -淀粉样蛋白的过度产生,从而导致AD;因此,家族性和散发形式的阿尔茨海默病在发病年龄上存在巨大差异,但在进展中存在深刻的病理和症状相似性。有趣的是,最近的研究发现,线粒体微蛋白PIGBOS与内质网相互作用,减轻了未折叠蛋白的反应,这表明线粒体功能障碍与内质网应激之间可能存在联系,涉及rna依赖性mRNA扩增途径的激活。线粒体功能障碍可能参与βAPP mRNA扩增,使其成为一个有希望的治疗靶点。在这方面,最近使用抗糖尿病药物二甲双胍减轻甚至逆转a β诱导的代谢缺陷的成功令人鼓舞。
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Precursor-Independent Overproduction of Beta-Amyloid in AD: Mitochondrial Dysfunction as Possible Initiator of Asymmetric RNA-Dependent βAPP mRNA Amplification. An Engine that Drives Alzheimer's Disease.
The present study defines RNA-dependent amplification of βAPP mRNA as a molecular basis of beta-amyloid overproduction in Alzheimer's disease. In this process, βAPP mRNA serves as a template for RNA-dependent RNA polymerase, RdRp complex. The resulting antisense RNA self-primes its extension utilizing two complementary elements: 3'-terminal and internal, located within an antisense segment corresponding to the coding portion of βAPP mRNA. The extension produces 3'-terminal fragment of βAPP mRNA, a part of a hairpin-structured antisense/sense RNA molecule. Cleavage at the 3' end of the hairpin loop produces RNA end product encoding a C-terminal fragment of βAPP. Since each conventional βAPP mRNA can be used repeatedly as a template, the process constitutes an asymmetric mRNA amplification. The 5'-most translation initiation codon of the amplified mRNA is the AUG preceding immediately and in-frame the Aβ-coding segment. Translation from this codon overproduces Aβ independently of βAPP. Such process can occur in humans but not in mice and other animals where segments of βAPP antisense RNA required for self-priming have little, if any, complementarity. This explains why Alzheimer's disease occurs exclusively in humans and implies that βAPP mRNA amplification is requisite in AD. In AD, therefore, there are two pathways of beta-amyloid production: βAPP proteolytic pathway and βAPP mRNA amplification pathway independent of βAPP and insensitive to beta-secretase inhibition. This implies that in healthy humans, where only the proteolytic pathway is in operation, Aβ production should be suppressed by the BACE inhibition, and indeed it is. However, since βAPP-independent pathway operating in AD is by far the predominant one, BACE inhibition has no effect in Alzheimer's disease. It appears that, physiologically, the extent of beta-amyloid overproduction sufficient to trigger amyloid cascade culminating in AD requires asymmetric RNA-dependent amplification of βAPP mRNA and cannot be reached without it. In turn, the occurrence of mRNA amplification process depends on the activation of inducible components of RdRp complex by certain stresses, for example the ER stress in case of amplification of mRNA encoding extracellular matrix proteins. In case of Alzheimer's disease, such an induction appears to be triggered by stresses associated with mitochondrial dysfunction, a phenomenon closely linked to AD. The cause-and-effect relationships between mitochondrial dysfunction and AD appear to be very different in familial, FAD, and sporadic, SAD cases. In FAD, increased levels or more toxic species of Aβ resulting from the abnormal proteolysis of βAPP trigger mitochondrial dysfunction, activate mRNA amplification and increase the production of Aβ, reinforcing the cycle. Thus in FAD, mitochondrial dysfunction is an intrinsic component of the amyloid cascade. The reverse sequence is true in SAD where aging-related mitochondrial dysfunction activates amplification of βAPP mRNA and enhances the production of Aβ. This causes further mitochondrial dysfunction, the cycle repeats and degeneration increases. Thus in SAD, the initial mitochondrial dysfunction arises prior to the disease, independently of and upstream from the increased Aβ production, i.e. in SAD, mitochondrial pathology hierarchically supersedes Aβ pathology. This is the primary reason for the formulation of the Mitochondrial Cascade Hypothesis. But even in terms of the MCH, the core of the disease is the amyloid cascade as defined in the amyloid cascade hypothesis, ACH. The role of mitochondrial dysfunction in relation to this core is causative in SAD and auxiliary in FAD. In FAD, the initial increase in the production of Aβ is mutations-based and occurs relatively early in life, whereas in SAD it is coerced by an aging-contingent component, but both lead to mechanistically identical self-perpetuating mutual Aβ/mitochondrial dysfunction feedback cycles, an engine that drives, via RNA-dependent βAPP mRNA amplification, overproduction of beta-amyloid and, consequently, AD; hence drastic difference in the age of onset, yet profound pathological and symptomatic similarity in the progression, of familial and sporadic forms of Alzheimer's disease. Interestingly, the recent findings that mitochondrial microprotein PIGBOS interacts with the ER in mitigating the unfolded protein response indicate a possible connection between mitochondrial dysfunction and ER stress, implicated in activation of RNA-dependent mRNA amplification pathway. The possible involvement of mitochondrial dysfunction in βAPP mRNA amplification makes it a promising therapeutic target. Recent successes in mitigating, and even reversing, Aβ-induced metabolic defects with anti-diabetes drug metformin are encouraging in this respect.
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