Targeting mitophagy in Parkinson's disease.

The genetics and pathophysiology of Parkinson's disease (PD) strongly implicate mitochondria in disease aetiology. Elegant studies over the last two decades have elucidated complex molecular signaling governing the identification and removal of dysfunctional mitochondria from the cell, a process of mitochondrial quality control known as mitophagy. Mitochondrial deficits and specifically reduced mitophagy are evident in both sporadic and familial PD. Mendelian genetics attributes loss-of-function mutations in key mitophagy regulators PINK1 and Parkin to early-onset PD. Pharmacologically enhancing mitophagy and accelerating the removal of damaged mitochondria are of interest for developing a disease-modifying PD therapeutic. However, despite significant understanding of both PINK1-Parkin-dependent and -independent mitochondrial quality control pathways, the therapeutic potential of targeting mitophagy remains to be fully explored. Here, we provide a summary of the genetic evidence supporting the role for mitophagy failure as a pathogenic mechanism in PD. We assess the tractability of mitophagy pathways and prospects for drug discovery and consider intervention points for mitophagy enhancement. We explore the numerous hit molecules beginning to emerge from high-content/high-throughput screening as well as the biochemical and phenotypic assays that enabled these screens. The chemical and biological properties of these reference compounds suggest many could be used to interrogate and perturb mitochondrial biology to validate promising drug targets. Finally, we address key considerations and challenges in achieving preclinical proof-of-concept, including in vivo mitophagy reporter methodologies and disease models, as well as patient stratification and biomarker development for mitochondrial forms of the disease.

Direct Evidence of the Presence of Cross-Linked Aß Dimers in the Brains of Alzheimer's Disease Patients.

Brain-derived amyloid-ß (Aß) dimers are associated with Alzheimer's disease (AD). However, their covalent nature remains controversial. This feature is relevant, as a covalent cross-link has been proposed to make brain-derived dimers (brain dimers) more synaptotoxic than Aß monomers and would also make them suitable candidates for biomarker development. To resolve this controversy, we here present a three-step approach. First, we validated a type of synthetic cross-linked Aß (CL Aß) dimers, obtained by means of the photoinduced cross-linking of unmodified proteins (PICUP) reaction, as well-defined mimics of putative brain CL Aß dimers. Second, we used these PICUP CL Aß dimers as standards to improve the isolation of brain Aß dimers and to develop state-of-the-art mass spectrometry (MS) strategies to allow their characterization. Third, we applied these MS methods to the analysis of brain Aß dimer samples allowing the detection of the CL [Aß(6-16)]2 peptide comprising a dityrosine cross-link. This result demonstrates the presence of CL Aß dimers in the brains of patients with AD and opens up avenues for establishing new therapeutic targets and developing novel biomarkers for this disease.

PI3 k/akt inhibition induces apoptosis through p38 activation in neurons.

Accumulating evidence suggests that the PI3K/AKT pathway is a pro-survival signalling system in neurons. Therefore, the inhibition of this pathway may be implicated in the degeneration of neurons in Parkinson's disease (PD), Alzheimer's disease (AD), and other neurological disorders. Here we study the participation of the mitogen-activated protein kinase (MAPK) pathway on apoptosis induced by PI3K/AKT inhibition in cultured cerebellar granule cells (CGCs). LY294002, a specific PI3K/AKT inhibitor, selectively activated the p38 MAPK kinase pathway and enhanced c-Jun phosphorylation, but did not activate JNK. The pharmacological inhibitors SB203580 (p38 inhibitor) and SP600125 (a JNK inhibitor) protected primary cultures of rat CGCs from LY294002-induced apoptosis. Furthermore, both compounds decreased the phosphorylation of c-Jun and lowered mRNA levels of the pro-apoptotic gene dp5, a direct target of c-Jun. Taken together, our data demonstrate that PI3K/AKT inhibition induces neuronal apoptosis, a process that is mediated by the activation of p38 MAPK/c-Jun/dp5.

Study of the pathways involved in apoptosis induced by PI3K inhibition in cerebellar granule neurons.

In the present study we focused in the PI3K/Akt pathway which plays a key role in neuronal survival. Here we show that inhibition of PI3K/Akt by means of LY294002 induces apoptosis via a caspase-dependent and calpain-independent pathway in cerebellar granule neurons (CGNs). This finding was confirmed using zVAD-fmk, a widely caspase inhibitor that prevents apoptosis. For this purpose, we compared two models of apoptosis in CGNs, namely inhibition of PI3K/Akt, and serum potassium deprivation (S/K deprivation). In contrast to the S/K deprivation model, caspase-3 was not activated when PI3K is inhibited. Likewise, CDK5 activation was not involved in this apoptotic process, because calpain activation is responsible for the formation of CDK5/p25 neurotoxic form. However, S/K deprivation activated calpain, as it is shown by α-spectrin breakdown, and favoured the formation of CDK5/p25. Moreover, although PI3K/Akt inhibition enhanced pRbser780 phosphorylation, no increase in the expression of cell-cycle proteins, namely: cyclin D, cyclin E, CDK2 or CDK4, was detected. Furthermore, BrdU incorporation assay did not shown any increase in DNA synthesis. Likewise, PI3K/Akt inhibition increased GSK3ß activity and c-Jun phosphorylation, which implicates these two pathways in this apoptotic route. Although previous reports suggest that apoptosis induced in CGNs by LY294002 and S/K deprivation causes PI3K inhibition and increases GSK3ß activity and c-Jun phosphorylation activation, our results demonstrate substantial differences between them and point to a key role of GSK3ß in the apoptosis induced in CGNs in the two models tested.

Oxidative stress-induced DNA damage and cell cycle regulation in B65 dopaminergic cell line.

Reactive oxygen species and oxidative stress are associated with neuronal cell death in many neurodegenerative conditions. However, the exact molecular mechanisms triggered by oxidative stress in neurodegeneration are still unclear. This study used the B65 rat neuroblastoma cell line as a model to study the molecular events that occur after H(2)O(2) treatment. Treatment of B65 cells with H(2)O(2) rapidly up-regulated the DNA damage pathway involved in double-strand breakage. Subsequently, proteins involved in p53 regulation, such as sirtuin 1 and STAT1, were modified. In addition, H(2)O(2) treatment altered the pattern of cell cycle protein expression. Specifically, a decrease was found in the expression of cyclin D1, cdk4 and surprisingly the levels of cyclin A and the retinoblastoma protein phosphorylated at ser780 were increased. Furthermore, this study shows that pre-treatment of B65 cells with 50 microM trolox confers almost total protection against apoptotic cell death and restores the cell cycle. Likewise, the increase in retinoblastoma phosphorylation was attenuated by KU-55993, a selective ATM inhibitor, and also by trolox. These observations indicate that DNA damage and oxidative stress are responsible for cell cycle regulation. In summary, this study describes the molecular mechanisms involved in cell cycle alterations induced by oxidative stress in B65 cells. These findings highlight the relevance of ATM in the regulation of cell cycle after oxidative stress.