Abstract
Integrative gene network approaches enable new avenues of exploration that implicate causal genes in sporadic late-onset Alzheimer’s disease (LOAD) pathogenesis, thereby offering novel insights for drug-discovery programs. We previously constructed a probabilistic causal network model of sporadic LOAD and identified TYROBP/DAP12, encoding a microglial transmembrane signaling polypeptide and direct adapter of TREM2, as the most robust key driver gene in the network. Here, we show that absence of TYROBP/DAP12 in a mouse model of AD-type cerebral Aβ amyloidosis (APPKM670/671NL/PSEN1Δexon9) recapitulates the expected network characteristics by normalizing the transcriptome of APP/PSEN1 mice and repressing the induction of genes involved in the switch from homeostatic microglia to disease-associated microglia (DAM), including Trem2, complement (C1qa, C1qb, C1qc, and Itgax), Clec7a and Cst7. Importantly, we show that constitutive absence of TYROBP/DAP12 in the amyloidosis mouse model prevented appearance of the electrophysiological and learning behavior alterations associated with the phenotype of APPKM670/671NL/PSEN1Δexon9 mice. Our results suggest that TYROBP/DAP12 could represent a novel therapeutic target to slow, arrest, or prevent the development of sporadic LOAD. These data establish that the network pathology observed in postmortem human LOAD brain can be faithfully recapitulated in the brain of a genetically manipulated mouse. These data also validate our multiscale gene networks by demonstrating how the networks intersect with the standard neuropathological features of LOAD.
Highlights
These authors contributed : Jean-Vianney Haure-Mirande, Minghui Wang, Bin Zhang, Sam Gandy, Michelle E
In order to validate in vivo in mice the driver role of TYROBP in sporadic late-onset Alzheimer’s disease (LOAD) and to demonstrate that the manipulation of TYROBP level leads to molecular changes observed human LOAD, we performed a battery of molecular, behavioral, electrophysiological analyses, and generated transcriptomic profiles in 8-month-old WT and APP/PSEN1 mice that were either WT, heterozygous- or homozygous-null for Tyrobp
We previously constructed a molecular network based on whole-genome gene-expression profiling and genotyping data on 1647 autopsied brain tissues from LOAD and nondemented subjects and reported the first LOAD causal network centered on TYROBP [5]
Summary
These authors contributed : Jean-Vianney Haure-Mirande, Minghui Wang, Bin Zhang, Sam Gandy, Michelle E. MNA revealed many facets of the molecularinteraction structures in AD and formally rank-ordered gene subnetworks based on their relevance to AD pathological and clinical traits. One such subnetwork highlighted complement cascade-related molecules, and the key complement subnetwork driver was TYROBP ( known as DAP12), a phagocytosis-related, microglial-enriched, phosphotyrosine phosphoprotein that forms functional complexes with, among others, TREM2 and the complement receptor CR3 [18,19,20,21,22]. Perhaps because both CR3 and TYROBP are obligatory participants in this phenomenon, mice deficient in either C3 (the ligand for CR3) or TYROBP are relatively resistant to Aβ-induced behavioral and electrophysiological pathology even at the young age of 4 months [26, 28]
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