Department of Neuroscience, College of Medicine, Mayo Clinic, 4500 San Pablo Rd., Jacksonville, FL 32224, USA.
Exp Neurol. 2010 Jun;223(2):252-66. doi: 10.1016/j.expneurol.2009.07.035. Epub 2009 Aug 27.
The amyloid beta (Abeta) and tau proteins, which misfold, aggregate, and accumulate in the Alzheimer's disease (AD) brain, are implicated as central factors in a complex neurodegenerative cascade. Studies of mutations that cause early onset AD and promote Abeta accumulation in the brain strongly support the notion that inhibiting Abeta aggregation will prevent AD. Similarly, genetic studies of frontotemporal dementia with parkinsonism linked to chromosome 17 (FTDP-17 MAPT) showing that mutations in the MAPT gene encoding tau lead to abnormal tau accumulation and neurodegeneration. Such genetic studies clearly show that tau dysfunction and aggregation can be central to neurodegeneration, however, most likely in a secondary fashion in relation to AD. Additional pathologic, biochemical, and modeling studies further support the concept that Abeta and tau are prime targets for disease modifying therapies in AD. Treatment strategies aimed at preventing the aggregation and accumulation of Abeta, tau, or both proteins should therefore be theoretically possible, assuming that treatment can be initiated before either irreversible damage is present or downstream, self-sustaining, pathological cascades have been initiated. Herein, we will review recent advances and also potential setbacks with respect to the myriad of therapeutic strategies that are designed to slow down, prevent, or clear the accumulation of either "pathological" Abeta or tau. We will also discuss the need for thoughtful prioritization with respect to clinical development of the preclinically validated modifiers of Abeta and tau pathology. The current number of candidate therapies targeting Abeta is becoming so large that a triage process is clearly needed to insure that resources are invested in a way such that the best candidates for disease modifying therapy are rapidly moved toward clinical trials. Finally, we will discuss the challenges for an appropriate "triage" after potential disease modifying therapies targeting tau and Abeta have entered clinical trials.
淀粉样蛋白β(Abeta)和tau 蛋白错误折叠、聚集并在阿尔茨海默病(AD)脑中积累,被认为是神经退行性级联反应的核心因素。研究导致早发性 AD 并促进脑中 Abeta 积累的突变强烈支持这样一种观点,即抑制 Abeta 聚集将预防 AD。同样,与 17 号染色体相关的额颞叶痴呆伴帕金森病(FTDP-17 MAPT)的遗传研究表明,编码 tau 的 MAPT 基因突变导致异常 tau 积累和神经退行性变。这些遗传研究清楚地表明,tau 功能障碍和聚集可能是神经退行性变的核心,但很可能是继发于 AD。其他病理、生化和建模研究进一步支持这样一种概念,即 Abeta 和 tau 是 AD 中疾病修饰治疗的主要靶点。因此,假设可以在出现不可逆损伤之前或在启动下游、自我维持的病理级联反应之前开始治疗,那么针对预防 Abeta、tau 或两者蛋白聚集和积累的治疗策略应该在理论上是可行的。在此,我们将回顾最近的进展,以及针对旨在减缓、预防或清除“病理性”Abeta 或 tau 积累的多种治疗策略的潜在挫折。我们还将讨论在临床开发 Abeta 和 tau 病理修饰剂方面需要进行深思熟虑的优先级排序。目前针对 Abeta 的候选治疗方法数量如此之多,显然需要进行分类处理,以确保资源的投入方式能够使疾病修饰治疗的最佳候选者迅速进入临床试验。最后,我们将讨论在针对 tau 和 Abeta 的潜在疾病修饰疗法进入临床试验后,进行适当“分类处理”的挑战。