Alzheimer's Disease-Associated ß-Amyloid Is Rapidly Seeded by Herpesviridae to Protect against Brain Infection.

Amyloid-ß peptide (Aß) fibrilization and deposition as ß-amyloid are hallmarks of Alzheimer's disease (AD) pathology. We recently reported Aß is an innate immune protein that protects against fungal and bacterial infections. Fibrilization pathways mediate Aß antimicrobial activities. Thus, infection can seed and dramatically accelerate ß-amyloid deposition. Here, we show Aß oligomers bind herpesvirus surface glycoproteins, accelerating ß-amyloid deposition and leading to protective viral entrapment activity in 5XFAD mouse and 3D human neural cell culture infection models against neurotropic herpes simplex virus 1 (HSV1) and human herpesvirus 6A and B. Herpesviridae are linked to AD, but it has been unclear how viruses may induce ß-amyloidosis in brain. These data support the notion that Aß might play a protective role in CNS innate immunity, and suggest an AD etiological mechanism in which herpesviridae infection may directly promote Aß amyloidosis.

Memory retrieval by activating engram cells in mouse models of early Alzheimer's disease.

Alzheimer's disease (AD) is a neurodegenerative disorder characterized by progressive memory decline and subsequent loss of broader cognitive functions. Memory decline in the early stages of AD is mostly limited to episodic memory, for which the hippocampus has a crucial role. However, it has been uncertain whether the observed amnesia in the early stages of AD is due to disrupted encoding and consolidation of episodic information, or an impairment in the retrieval of stored memory information. Here we show that in transgenic mouse models of early AD, direct optogenetic activation of hippocampal memory engram cells results in memory retrieval despite the fact that these mice are amnesic in long-term memory tests when natural recall cues are used, revealing a retrieval, rather than a storage impairment. Before amyloid plaque deposition, the amnesia in these mice is age-dependent, which correlates with a progressive reduction in spine density of hippocampal dentate gyrus engram cells. We show that optogenetic induction of long-term potentiation at perforant path synapses of dentate gyrus engram cells restores both spine density and long-term memory. We also demonstrate that an ablation of dentate gyrus engram cells containing restored spine density prevents the rescue of long-term memory. Thus, selective rescue of spine density in engram cells may lead to an effective strategy for treating memory loss in the early stages of AD.