Potential neuroprotective strategies against tauopathy

Structural modeling of GSK3β implicates the inactive (DFG-out) conformation as the target bound by TDZD analogs

Glycogen synthase kinase-3β (GSK3β) controls many physiological pathways, and is implicated in many diseases including Alzheimer’s and several cancers. GSK3β-mediated phosphorylation of target residues in microtubule-associated protein tau (MAPTAU) contributes to MAPTAU hyperphosphorylation and subsequent formation of neurofibrillary tangles. Inhibitors of GSK3β protect against Alzheimer’s disease and are therapeutic for several cancers. A thiadiazolidinone drug, TDZD-8, is a non-ATP-competitive inhibitor targeting GSK3β with demonstrated efficacy against multiple diseases. However, no experimental data or models define the binding mode of TDZD-8 with GSK3β, which chiefly reflects our lack of an established inactive conformation for this protein. Here, we used metadynamic simulation to predict the three-dimensional structure of the inactive conformation of GSK3β. Our model predicts that phosphorylation of GSK3β Serine9 would hasten the DFG-flip to an inactive state. Molecular docking and simulation predict the TDZD-8 binding conformation of GSK3β to be inactive, and are consistent with biochemical evidence for the TDZD-8–interacting residues of GSK3β. We also identified the pharmacophore and assessed binding efficacy of second-generation TDZD analogs (TDZD-10 and Tideglusib) that bind GSK3β as non-ATP-competitive inhibitors. Based on these results, the predicted inactive conformation of GSK3β can facilitate the identification of novel GSK3β inhibitors of high potency and specificity.

O-GlcNAc cycling shows neuroprotective potential in C. elegans models of neurodegenerative disease

C. elegans has proven to be an excellent organism in which to model human neurodegenerative disease.(1) (-) (7) The worm's simple nervous system, lineage, and neural maps, easily scored movement phenotypes, and robust forward and reverse genetics make it optimal for studying age-dependent processes on a reasonable time scale. A popular approach has been the introduction of transgenes expressing GFP-tagged proteotoxic human proteins into neurons leading to visible aggregation or movement phenotypes.(2) (,) (4) (,) (6) (,) (8) (-) (13) In addition, the maintenance of proteostasis networks has been extensively studied using the power of worm genetics.(8) (-) (13) These networks include genes involved in insulin-like signaling, the heat shock response, the response to hypoxia, and mTOR and AMPK pathways linked to aging.(14) Another pathway with suggestive links to neurodegeneration is the O-GlcNAc cycling pathway, a nutrient-dependent post-translational modification known to be altered in brains from patients with Alzheimer disease.(15) (-) (19) In this commentary, we summarize our recent findings showing that viable mutants of O-GlcNAc cycling in C. elegans dramatically alter the neurotoxicity of four distinct C. elegans models of neurodegenerative disease.(7) Mutants in O-GlcNAc cycling alter the toxicity of mutant tau, polyglutamine expansion reporters, and amyloid β-peptide. The findings further suggest that O-GlcNAc cycling acts at many steps in the lifecycle of aggregation-prone targets. The C. elegans system is likely to continue to provide insights into this complex problem. The involvement of O-GlcNAc cycling in the maintenance of proteostasis raises the possibility of targeting the enzymes catalyzing this critical post-translational modification for therapeutic intervention.

Twice is better: highlights of the second meeting focused on tau biology and pathology

It is an exciting time for tau researchers as it is now generally accepted that abnormal tau species are required to mediate the toxic effects of amyloid β-peptide oligomers in Alzheimer's disease. Tau may play multiple roles in neurophysiology and there may be further pathologically relevant tau alterations, besides hyperphosphorylation and aggregation. The recent Biology and Pathology of Tau and its Role in Tauopathies II meeting explored these various aspects of tau, and presentations at the meeting, described in the following articles in this issue of Biochemical Society Transactions, are outlined in the present paper.