TM2D genes regulate Notch signaling and neuronal function in Drosophila.

TM2 domain containing (TM2D) proteins are conserved in metazoans and encoded by three separate genes in each model organism species that has been sequenced. Rare variants in TM2D3 are associated with Alzheimer's disease (AD) and its fly ortholog almondex is required for embryonic Notch signaling. However, the functions of this gene family remain elusive. We knocked-out all three TM2D genes (almondex, CG11103/amaretto, CG10795/biscotti) in Drosophila and found that they share the same maternal-effect neurogenic defect. Triple null animals are not phenotypically worse than single nulls, suggesting these genes function together. Overexpression of the most conserved region of the TM2D proteins acts as a potent inhibitor of Notch signaling at the γ-secretase cleavage step. Lastly, Almondex is detected in the brain and its loss causes shortened lifespan accompanied by progressive motor and electrophysiological defects. The functional links between all three TM2D genes are likely to be evolutionarily conserved, suggesting that this entire gene family may be involved in AD. Author summary: Alzheimer's disease (AD) is the most common neurodegenerative disease affecting the aging population. Although many genetic factors have been implicated in its pathogenesis, in vivo functions of many of these genes have not been well defined. In this study, we investigated the function of TM2D3, a conserved gene that has been implicated in late-onset AD through an exome-wide association study, and two closely related genes, TM2D1 and TM2D2, using the fruit fly Drosophila melanogaster. In addition to exhibiting a previously reported maternal-effect neuurodevelopmental phenotype caused by Notch signaling defects during embryogenesis, fly TM2D3 mutants are short lived and display age-dependent motor and electrophysiological defects, providing the first link between this gene and age-dependent neurological phenotypes. Furthermore, TM2D1 and TM2D2 knockout flies phenotypically mimic the loss of TM2D3. Triple knockout of all three TM2D genes resemble the single knockouts, suggesting that these genes likely function together. Together with functional data that implicates TM2D3 in a biological process that is liked to the γ-secretase, a protease that is involved in AD in addition to being required for proper Notch signaling, we propose that all three TM2D family genes may be involved in AD pathogenesis, which warrants further investigation through human genetics studies. [ABSTRACT FROM AUTHOR]