Presenilin 2 influences miR146 level and activity in microglia.

Microglia, the resident innate immune cells of the CNS, are the primary defenders against microbes and critical to CNS remodeling. Dysregulation of microglial behavior can lead to unchecked pro-inflammatory activity and subsequent neurodegeneration. The molecular mechanisms leading to chronic inflammation and microglial dysfunction in neurodegenerative diseases are not well-understood. It is known that patients with Presenilin 2 (PS2) mutations develop autosomal dominant Alzheimer disease. We have shown that a lack of normal PS2 function is associated with exaggerated microglia pro-inflammatory responses in vitro. To identify pathways by which PS2 regulates microglia and determine how PS2 dysfunction may lead to altered inflammatory pathways, we pursued an unbiased array approach to assess differential expression of microRNAs between murine PS2 knockout (KO) and wild-type microglia. We identified miR146, a negative regulator of monocyte pro-inflammatory response, as constitutively down-regulated in PS2 KO microglia. Consistent with a state of miR146 suppression, we found that PS2 KO microglia express higher levels of the miR146 target protein interleukin-1 receptor-associated kinase-1, and have increased NFκB transcriptional activity. We hypothesize that PS2 impacts microglial responses through modulation of miR146a. PS2 dysfunction, through aging or mutation, may contribute to neurodegeneration by influencing the pro-inflammatory behavior of microglia. Presenilin 2 (PS2), a membrane associated protease, has been implicated in the pathogenesis of Alzheimer disease. We have previously shown that PS2 plays an important role in curbing the proinflammatory response in microglia. Here, we report the novel finding that PS2 participates in maintaining the basal and cytokine induced expression of the innate immunity regulating microRNA, miR146. These data suggest one mechanism by which PS2 works to reign in proinflammatory microglial behavior and that PS2 dysfunction or deficiency could thus result in unchecked proinflammatory activation contributing to neurodegeneration.

Presenilin structure in mechanisms leading to Alzheimer's disease.

Molecular genetic studies of familial Alzheimer's disease by 1995 had clearly implicated three proteins as critical to Alzheimer's disease (AD), the amyloid-beta protein precursor (AbetaPP) and the two homologous presenilins, PS-1 and PS-2. To account for the roles of these proteins in AD, we had proposed that as an early and critical step in the mechanisms that lead to AD, the PS on the surface of a brain cell engages in a specific receptor-ligand intercellular interaction with AbetaPP on the surface of a neighboring cell. This cell-cell interaction is required to trigger off a cascade of processes that lead to the production of amyloid-beta (Abeta) from AbetaPP, leading to AD. At about this time, however, many established AD researchers had obtained data that appeared to disagree with our proposed mechanism. Their immediate objections to our proposal were based on their conclusions that 1) The PS proteins were exclusively intracellular, and were not expressed at the cell surface, and 2) The topography of the PS proteins in intracellular membranes exhibits either 6 or 8-TM spanning domains, not 7. Here we discuss the evidence for the 6-TM, 7-TM, 8-TM and other models of PS topography and offer possibilities for the differences in interpretation of the various sets of data. We review the experimental demonstration of the cell-surface expression and the 7-TM structure of PS, the functional consequences of this structure, and the findings that PS-1 and PS-2 are members of the superfamily of 7-TM heterotrimeric G-protein coupled receptors (GPCRs).