TMEM175 deficiency impairs lysosomal and mitochondrial function and increases α-synuclein aggregation.

Parkinson disease (PD) is a neurodegenerative disorder pathologically characterized by nigrostriatal dopamine neuron loss and the postmortem presence of Lewy bodies, depositions of insoluble α-synuclein, and other proteins that likely contribute to cellular toxicity and death during the disease. Genetic and biochemical studies have implicated impaired lysosomal and mitochondrial function in the pathogenesis of PD. Transmembrane protein 175 (TMEM175), the lysosomal K+ channel, is centered under a major genome-wide association studies peak for PD, making it a potential candidate risk factor for the disease. To address the possibility that variation in TMEM175 could play a role in PD pathogenesis, TMEM175 function was investigated in a neuronal model system. Studies confirmed that TMEM175 deficiency results in unstable lysosomal pH, which led to decreased lysosomal catalytic activity, decreased glucocerebrosidase activity, impaired autophagosome clearance by the lysosome, and decreased mitochondrial respiration. Moreover, TMEM175 deficiency in rat primary neurons resulted in increased susceptibility to exogenous α-synuclein fibrils. Following α-synuclein fibril treatment, neurons deficient in TMEM175 were found to have increased phosphorylated and detergent-insoluble α-synuclein deposits. Taken together, data from these studies suggest that TMEM175 plays a direct and critical role in lysosomal and mitochondrial function and PD pathogenesis and highlight this ion channel as a potential therapeutic target for treating PD.

Deletion of CD14 attenuates Alzheimer's disease pathology by influencing the brain's inflammatory milieu.

Alzheimer's disease (AD) is characterized by the deposition of ß-amyloid (Aß)-containing plaques within the brain that is accompanied by a robust microglial-mediated inflammatory response. This inflammatory response is reliant upon engagement of innate immune signaling pathways involving the toll-like receptors (TLRs). Studies assessing the roles of TLRs in AD pathogenesis have yielded conflicting results. We have assessed the roles of the TLRs through genetic inactivation of the TLR2/4 coreceptor, CD14, in a transgenic murine model of AD. Transgenic mice lacking CD14 exhibited reduced insoluble, but not soluble, levels of Aß at 7 months of age. This corresponded with decreased plaque burden resulting from a reduction in number and size of both diffuse and thioflavin S-positive plaques and an overall reduction in the number of microglia. These findings are inconsistent with the established actions of these receptors. Moreover, loss of CD14 expression was associated with increased expression of genes encoding the proinflammatory cytokines Tnfα and Ifnγ, decreased levels of the microglial/macrophage alternative activation markers Fizz1 and Ym1, and increased expression of the anti-inflammatory gene Il-10. Thus, the loss of CD14 resulted in a significant change in the inflammatory environment of the brain, likely reflecting a more heterogeneous population of microglia within the brains of the animals. The reduction in plaque burden was not a result of changes in the expression of various Aß degrading enzymes or proteins associated with Aß clearance. These data suggest that CD14 is a critical regulator of the microglial inflammatory response that acts to modulate Aß deposition.

Aging African green monkeys manifest transcriptional, pathological, and cognitive hallmarks of human Alzheimer's disease.

While many preclinical models of Alzheimer's disease (AD) have been reported, none fully recapitulate the disease. In an effort to identify an appropriate preclinical disease model, we characterized age-related changes in 2 higher order species, the African green monkey (AGM) and the rhesus macaque. Gene expression profiles in the dorsolateral prefrontal cortex and the visual cortex showed age-related changes in AGMs that are strikingly reminiscent of AD, whereas aged rhesus were most similar to healthy elderly humans. Biochemically, age-related changes in AGM cerebrospinal fluid levels of tau, phospho-tau, and amyloid beta were consistent with AD. Histologically, aged AGMs displayed pathological hallmarks of the disease, plaques, and 2 AGMs showed evidence of neurofibrillary tangle-like structures. We hypothesized and confirmed that AGMs have age-related cognitive deficits via a prefrontal cortex-dependent cognition test, and that symptomatic treatments that improve cognition in AD patients show efficacy in AGMs. These data suggest that the AGM could represent a novel and improved translational model to assist in the development of therapeutics for AD.

Response to comments on "ApoE-directed therapeutics rapidly clear ß-amyloid and reverse deficits in AD mouse models".

The data reported in the Technical Comments by Fitz et al., Price et al., Tesseur et al., and Veeraraghavalu et al. replicate and validate our central conclusion that bexarotene stimulates the clearance of soluble ß-amyloid peptides and results in the reversal of behavioral deficits in mouse models of Alzheimer's disease (AD). The basis of the inability to reproduce the drug-stimulated microglial-mediated reduction in plaque burden is unexplained. However, we concluded that plaque burden is functionally unrelated to improved cognition and memory elicited by bexarotene.

Ibuprofen attenuates oxidative damage through NOX2 inhibition in Alzheimer's disease.

Considerable evidence points to important roles for inflammation in Alzheimer's disease (AD) pathophysiology. Epidemiological studies have suggested that long-term nonsteroidal anti-inflammatory drug (NSAID) therapy reduces the risk for Alzheimer's disease; however, the mechanism remains unknown. We report that a 9-month treatment of aged R1.40 mice resulted in 90% decrease in plaque burden and a similar reduction in microglial activation. Ibuprofen treatment reduced levels of lipid peroxidation, tyrosine nitration, and protein oxidation, demonstrating a dramatic effect on oxidative damage in vivo. Fibrillar ß-amyloid (Aß) stimulation has previously been demonstrated to induce the assembly and activation of the microglial nicotinamide adenine dinucleotide phosphate (NADPH) oxidase leading to superoxide production through a tyrosine kinase-based signaling cascade. Ibuprofen treatment of microglia or monocytes with racemic or S-ibuprofen inhibited Aß-stimulated Vav tyrosine phosphorylation, NADPH oxidase assembly, and superoxide production. Interestingly, Aß-stimulated Vav phosphorylation was not inhibited by COX inhibitors. These findings suggest that ibuprofen acts independently of cyclooxygenase COX inhibition to disrupt signaling cascades leading to microglial NADPH oxidase (NOX2) activation, preventing oxidative damage and enhancing plaque clearance in the brain.

ApoE-directed therapeutics rapidly clear ß-amyloid and reverse deficits in AD mouse models.

Alzheimer's disease (AD) is associated with impaired clearance of ß-amyloid (Aß) from the brain, a process normally facilitated by apolipoprotein E (apoE). ApoE expression is transcriptionally induced through the action of the nuclear receptors peroxisome proliferator-activated receptor gamma and liver X receptors in coordination with retinoid X receptors (RXRs). Oral administration of the RXR agonist bexarotene to a mouse model of AD resulted in enhanced clearance of soluble Aß within hours in an apoE-dependent manner. Aß plaque area was reduced more than 50% within just 72 hours. Furthermore, bexarotene stimulated the rapid reversal of cognitive, social, and olfactory deficits and improved neural circuit function. Thus, RXR activation stimulates physiological Aß clearance mechanisms, resulting in the rapid reversal of a broad range of Aß-induced deficits.