The role of serotonin within the microbiota-gut-brain axis in the development of Alzheimer’s disease: A narrative review

Alzheimer’s disease (AD) is the most common cause of dementia, accounting for more than 50 million patients worldwide. Current evidence suggests the exact mechanism behind this devastating disease to be of multifactorial origin, which seriously complicates the quest for an effective disease-modifying therapy, as well as impedes the search for strategic preventative measures. Of interest, preclinical studies point to serotonergic alterations, either induced via selective serotonin reuptake inhibitors or serotonin receptor (ant)agonists, in mitigating AD brain neuropathology next to its clinical symptoms, the latter being supported by a handful of human intervention trials. Additionally, a substantial amount of preclinical trials highlight the potential of diet, fecal microbiota transplantations, as well as pre- and probiotics in modulating the brain’s serotonergic neurotransmitter system, starting from the gut. Whether such interventions could truly prevent, reverse or slow down AD progression likewise, should be initially tested in preclinical studies with AD mouse models, including sufficient analytical measurements both in gut and brain. Thereafter, its potential therapeutic effect could be confirmed in rigorously randomized controlled trials in humans, preferentially across the Alzheimer’s continuum, but especially from the prodromal up to the mild stages, where both high adherence to such therapies, as well as sufficient room for noticeable enhancement are feasible still. In the end, such studies might aid in the development of a comprehensive approach to tackle this complex multifactorial disease, since serotonin and its derivatives across the microbiota-gut-brain axis might serve as possible biomarkers of disease progression, next to forming a valuable target in AD drug development. In this narrative review, the available evidence concerning the orchestrating role of serotonin within the microbiota-gut-brain axis in the development of AD is summarized and discussed, and general considerations for future studies are highlighted.     

早期电针干预对SAMP8小鼠学习记忆能力和海马磷酸化Tau蛋白水平的影响

目的:探讨早期电针"百会""大椎""肾俞"穴对快速老化小鼠(SAMP8小鼠)学习记忆能力和海马磷酸化Tau蛋白表达的影响,为临床电针治疗阿尔茨海默病(AD)时间点的选择提供参考。方法:将36只3月龄SAMP8小鼠随机分为模型组、3月龄电针组、9月龄电针组,每组12只;以12只同龄正常老化SAMR1小鼠作为空白对照组。3月龄电针组及9月龄电针组分别于小鼠3月龄及9月龄时予电针"百会""大椎""肾俞"穴治疗(连续波,2 Hz,1.5~2 mA),20 min/次,每日1次,8 d为一疗程,疗程间隔2 d,共治疗3个疗程。每组小鼠在水迷宫检测学习记忆能力结束后统一于10月龄取材;免疫组织化学法、免疫蛋白印迹法(Western blot)检测小鼠海马磷酸化Tau蛋白的表达,实时荧光定量PCR法检测小鼠海马Tau mRNA表达。结果:与空白对照组比较,模型组小鼠逃避潜伏期明显延长(P<0.01),原平台象限停留时间较短,跨越平台次数减少(P<0.01),海马磷酸化Tau蛋白及Tau mRNA表达较高(P<0.01);与模型组比较,3月龄电针组及9月龄电针组小鼠逃避潜伏期缩短(P<0.05),原平台象限停留时间延长,跨越平台次数增多(P<0.05),小鼠海马磷酸化Tau蛋白及Tau mRNA表达降低(P<0.05);与9月龄电针组比较,3月龄电针组小鼠逃避潜伏期缩短(P<0.05),原平台象限停留时间延长,跨越平台次数增多(P<0.05),海马磷酸化Tau蛋白及Tau mRNA表达降低(P<0.01)。结论:早期电针干预能更有效地改善SAMP8小鼠学习记忆能力并降低其海马磷酸化Tau蛋白水平。     

生慧汤对APP/PS1雄性AD小鼠海马内APP代谢产物的昼夜变化影响＊

目的研究生慧汤对APP/PS1（β-amyloid precursor protein/presenilin 1246E）小鼠海马内β淀粉样前体蛋白（Amyloid precursor protein，APP）代谢产物昼夜表达的影响。方法 将56只雄性APP/PS1双转基因痴呆模型小鼠随机分为4组，分别为：痴呆模型组、褪黑素治疗组（0.78 mg·kg^-1·d^-1）、生慧汤高剂量组（27.0 g·kg^-1·d^-1）、生慧汤低剂量组（13.5 g·kg^-1·d^-1），每组14只；对照组为14只雄性C57BL/6J小鼠，连续给药30天。采用Morris水迷宫检测小鼠学习记忆能力，采用酶联免疫吸附检测（ELISA）检测不同时间段取出的海马组织sAPPα含量。对海马β淀粉样蛋白_1-40、β淀粉样蛋白_1-42表达进行免疫印迹分析。免疫组化（IHC）检测海马CA1区Aβ_1-40蛋白的表达。结果 Morris水迷宫结果表明，与对照组相比，模型组上平台潜伏期明显延长、穿越平台次数明显减少（P<0.01）；与模型组相比，生慧汤不同剂量组上平台潜伏期明显缩短（P<0.01、P<0.05），穿越平台次数明显增加（P<0.05）。ELISA结果表明，与对照组相比，模型组的sAPPα总量、各时间段（12：00、24：00）sAPPα含量明显减少（P<0.01）；与模型组相比，生慧汤不同剂量组sAPPα总量明显增多（P<0.01、P<0.05），生慧汤高剂量组仅能增加12：00 sAPPα含量（P<0.01），生慧汤低剂量组仅能增加24：00 sAPPα含量（P<0.05）。对照组sAPPα含量具有明显昼夜差异（P<0.01）。模型组sAPPα含量的昼夜差异性消失（P>0.05）。生慧汤高剂量组sAPPα含量具有昼夜差异（P<0.01），生慧汤低剂量组sAPPα含量不具有昼夜差异（P>0.05）。Western blot结果显示，与对照组相比，模型组Aβ_1-40、Aβ_1-42蛋白表达明显增加（P<0.01）；与模型组相比，生慧汤高剂量组Aβ_1-40、Aβ_1-42蛋白表达减少（P<0.05、P<0.01）；生慧汤低剂量组仅能减少Aβ_1-40蛋白的表达（P<0.05），对Aβ_1-42蛋白表达无影响（P>0.05）。免疫组化结果表明，与对照组相比，模型组Aβ_1-40表达明显增加（P<0.01）；与模型组相比，生慧汤不同剂量组Aβ_1-40表达不同程度减少（P<0.01、P<0.05）。结论 生慧汤能够改善5月龄APP/PS1阿尔茨海默病模型小鼠的学习记忆障碍，其机制可能与恢复海马内APP代谢产物sAPPα的昼夜节律性表达、从而减少Aβ的沉积有关。     

The extracellular matrix enriched with membrane metalloendopeptidase and insulin‐degrading enzyme suppresses the deposition of amyloid‐beta peptide in Alzheimer's disease cell models

Amyloid plaque is a typical feature of Alzheimer's disease (AD) and is one of the targets for AD therapy. Membrane metalloendopeptidase (MME) and insulin‐degrading enzyme (IDE) are two types of proteases that could cleave beta‐amyloid (Aβ) peptides generated by neuron cells of AD patients. Extracellular matrix (ECM) plays a crucial role in regulating tissue‐specific functions and is an ideal biomaterial for tissue repair. In this study, we extracted the liquid ECM enriched with collagen‐binding‐domain‐fused IDE or MME from human foreskin fibroblast cells. We found that these ECM biomaterials reduced the aggregation of Aβ peptides, prevented the formation of amyloid plaques, and also suppressed phosphorylation of Tau protein in AD cell models. Overall, our research provides a novel ECM biomaterial that can be potentially used for AD therapy.     

Spect-neuropsychology correlations in very mild Alzheimer's disease and amnesic mild cognitive impairment

BackgroundThe purpose of this study was to explore the clinical and brain functional abnormalities in patients with mild Alzheimer’s Disease (AD) and patients with amnesic Mild Cognitive Impairment (aMCI).Methodswe used resting spect-neuropsychology correlations method.ResultsWe found that parieto-temporal associative cortex, mainly involving the inferior parietal lobule, posterior cingulate and middle temporal gyrus, is compromised early in AD. These results suggest that the dysfunction in these areas contributes to cognitive decline in the storage of verbal information, drawing abilities and non-verbal abstract reasoning in AD. The aMCI group showed hypoperfusion primarily involving the frontal areas bilaterally, and this correlated with the impairment in free delayed recall on a verbal memory task.ConclusionOur results underlie the clinical differences between AD and aMCI patients that might reflect the involvement of different degenerative mechanisms in these groups.     

Anosognosia in patients with Alzheimer's disease: current perspectives

Alzheimer?s disease (AD) is a neurodegenerative disease characterised by neurocognitive impairments, especially memory impairment, as core symptoms linked to reductions in activities of daily life. As marginal symptoms, neuropsychiatric symptoms (NPSs) appear during the progressive course of the disease. A lack of self‐awareness (anosognosia) of cognitive and functional impairments is often seen in patients with AD, and associations between anosognosia and other NPSs have been previously reported. To account for anosognosia pathogenesis neurocognitively, the cognitive awareness model (CAM) has been helpful for explaining the stream of events from sensory input to behavioural/affective and metacognitive outputs. According to CAM, there are three types of anosognosia: (i) primary anosognosia, (ii) executive anosognosia, and (iii) mnemonic anosognosia. These types of anosognosia are generated from different neurocognitive modulations leading to metacognitive outputs or behavioural/affective regulations. Primary anosognosia is considered to be caused by deficits in the metacognitive awareness system (MAS). While preserved MAS function is associated with milder depression and anxiety in AD, a severer depressive mood in patients with mild AD can inversely cause self‐underestimation. The modulation of executive anosognosia is thought to be associated with dangerous/disinhibition behaviours and apathy among NPS sub‐symptoms, via impairments of comparator mechanism (Cm) within the central executive system. Other neurobehavioral reactions linked to self‐awareness include ‘denying’ and ‘confabulation’, and each of these reactions is thought to be affected by the MAS and a Cm. Denial of one?s own memory impairments appears as a defensive reaction to protect against dysphoric feelings, and the confabulatory comment is instantly reaction constructed by fabrications according to misinterpretations of memory information about oneself. Similarly, the innovative development of a theoretical model (CAM) has contributed to explaining the mechanism of anosognosia and some neurobehavioral outputs from a neurocognitive perspective.     

Diffusion MRI detects early brain microstructure abnormalities in 2‐month‐old 3×Tg‐AD mice

The 3×Tg‐AD mouse is one of the most studied animal models of Alzheimer's disease (AD), and develops both amyloid beta deposits and neurofibrillary tangles in a temporal and spatial pattern that is similar to human AD pathology. Additionally, abnormal myelination patterns with changes in oligodendrocyte and myelin marker expression are reported to be an early pathological feature in this model. Only few diffusion MRI (dMRI) studies have investigated white matter abnormalities in 3×Tg‐AD mice, with inconsistent results. Thus, the goal of this study was to investigate the sensitivity of dMRI to capture brain microstructural alterations in 2‐month‐old 3×Tg‐AD mice. In the fimbria, the fractional anisotropy (FA), kurtosis fractional anisotropy (KFA), and radial kurtosis (K_┴) were found to be significantly lower in 3×Tg‐AD mice than in controls, while the mean diffusivity (MD) and radial diffusivity (D_┴) were found to be elevated. In the fornix, K_┴ was lower for 3×Tg‐AD mice; in the dorsal hippocampus MD and D_┴ were elevated, as were FA, MD, and D_┴ in the ventral hippocampus. These results indicate, for the first time, dMRI changes associated with myelin abnormalities in young 3×Tg‐AD mice, before they develop AD pathology. Morphological quantification of myelin basic protein immunoreactivity in the fimbria was significantly lower in the 3×Tg‐AD mice compared with the age‐matched controls. Our results demonstrate that dMRI is able to detect widespread, significant early brain morphological abnormalities in 2‐month‐old 3×Tg‐AD mice.