Comprehensive binary interaction mapping of τ phosphotyrosine sites with SH2 domains in the human genome: Implications for the rational design of self-inhibitory phosphopeptides to target τ hyperphosphorylation signaling in Alzheimer's Disease.

Human microtubule-associated protein Tau (τ) is abundant in the axons of neurons where it stabilizes microtubule bundles; abnormally hyperphosphorylated τ is a hallmark of Alzheimer's disease (AD) and related tauopathies. The hyperphosphorylation events can be recognized by phosphotyrosine-recognition domain SH2 (Src homology 2) to elicit downstream τ signaling in AD pathology. In this study, a comprehensive binary interaction map (CBIM) of all the 6 τ phosphotyrosine sites with 120 SH2 domains in the human genome was systematically created at structural level using computational analyses and binding assays, from which we were able to identify those of strong and moderate binding pairs of sites to domains. It is found that the SH2-recognition specificity of different τ phosphotyrosine sites has been evolutionally optimized to become roughly orthogonal to each other, and thus these site phosphorylations would regulate different but probably partially overlapped biological functions in τ signaling. Some SH2 groups such as SRC, RIN, PLCG, SOCS and SH2D were revealed to have effective binding potency as compared to others; they could be regarded as potential τ-associated proteins to transduce the downstream signaling. We further determined the systematic binding affinities of 6 τ-phosphopeptides to the 11 SH2 domains in SRC group, from which the FYN-τ18 and YES-τ29 pairs were identified as strong binders. Subsequently, rational molecular design was performed on τ18 and τ29 to derive a number of τ-phosphopeptide mutants with increased affinity; they are self-inhibitory candidates to competitively target τ hyperphosphorylation events in AD. In addition, it is revealed that the primary anchor pY0 and secondary anchor X+3 of τ-phosphopeptides play an important role in SRC-group SH2 recognition, which confer stability and specificity to the SH2-phosphopeptide binding, respectively.

Computational systematic selectivity of the Fasalog inhibitors between ROCK-I and ROCK-II kinase isoforms in Alzheimer's disease.

Human Rho-associated coiled-coil forming kinase (ROCK) is a class of essential neurokinases that consists of two structurally conserved isoforms ROCK-I and ROCK-II; they have been revealed to play distinct roles in the pathogenesis of Alzheimer's disease (AD) and other neurological disorders. Selective targeting of the two kinase isoforms with small-molecule inhibitors is a great challenge due to the surprisingly high homology in kinase domain (92 %) and the full identity in kinase active site (100 %). Here, we describe a computational protocol to systematically profile the selectivity of Fasudil and its 25 analogs (termed as Fasalogs) between the two kinase isoforms. It is suggested that the substitution of Fasudil's 1,4-diazepane moiety with rigid ring such as Ripasudil and Dimehtylfasudil would render the resulting inhibitors of ROCK-II over ROCK-I (II-o-I) selectivity, while the substitution with long, flexible group such as H-89 and BDBM92607 tends to have I-o-II selectivity. Structural analysis reveals that the inhibitor affinity is not only determined by the identical active site, but also contributed from the non-identical first and second shells of the site as well as other non-conserved kinase regions, which can indirectly influence the active site and inhibitor binding through allosteric effect. A further kinase assay basically confirms the computational findings, which also exhibits a good consistence with theoretical selectivity over 10 tested samples (Rp = 0.89). In particular, the Fasalog compounds Dimehtylfasudil and H-89 are identified as II-o-I and I-o-II selective inhibitors. They can be considered as promising lead molecular entities to develop new specific ROCK isoform-selective Fasalog inhibitors.

Dihydrotanshinone I Increase Amyloid-ß Clearance and Decrease Tau Phosphorylation via Enhancing Autophagy.

INTRODUCTION: The plaques formed by amyloid-ß (Aß) accumulation and neurofibrillary tangles formed by hyper-phosphorylated tau protein are the 2 major pathologies of Alzheimer's disease (AD). Recently, autophagy is considered to be a self-degradation process of preserved cytoplasmic abnormal substances, including Aß and tau. METHODS: α-Screen assay is used to discover a new mammalian target of rapamycin (mTOR) signaling inhibitor, and laser scanning confocal microscopic analysis is used to investigate the autophagy formation. Lastly, ELISA and Western blot assays are used to identify the mTOR signaling inhibitor effect on Aß and tau and the underlying mechanism. RESULTS: In the current study, we discover that dihydrotanshinone I (DTS I), extracted from Radix Salviae, can obviously inhibit mTOR phosphorylation and increase autophagy via increasing AMPK phosphorylation. Further study demonstrates that DTS I increases Aß clearance and decreases Tau phosphorylation through autophagy enhancement involved with AMPK/mTOR pathway. CONCLUSION: Our study indicates that DTS I can increase Aß clearance and decrease Tau phosphorylation via autophagy enhancing involved with AMPK/mTOR pathway, which highlights the therapeutic potential of DTS I for the treatment of AD.

Overexpression of MicroRNA-9a-5p Ameliorates NLRP1 Inflammasome-mediated Ischemic Injury in Rats Following Ischemic Stroke.

The nucleotide oligomerization domain (NOD)-like receptor (NLR) pyrin domain-containing protein 1 (NLRP1) inflammasome has been shown to contribute to brain injury after ischemic stroke. Our previous study showed that microRNA-9a-5p (miR-9a-5p) ameliorates ischemic injury by regulating neuronal autophagy in rats subjected to middle cerebral artery occlusion (MCAO) surgery. The aims of this study were to investigate whether miR-9a-5p can influence the NLRP1 inflammasome following ischemic stroke and to clarify the mechanism involved. We found that MCAO in rats increased the level of NLRP1 inflammasome proteins, including NLRP1 receptor, ASC and precursor caspase-1, which induced higher levels of cleaved caspase-1, mature interleukin-1ß (IL-1ß) and interleukin-18 (IL-18). Similarly, the levels of the NLRP1 inflammasome proteins, cleaved caspase-1, mature IL-1ß and IL-18 were elevated in SY-5Y cells exposed to oxygen-glucose deprivation (OGD). Further investigation showed that NLRP1 was a target of miR-9a-5p and was downregulated by miR-9a-5p overexpression and upregulated by miR-9a-5p inhibition. Moreover, overexpression of miR-9a-5p not only decreased the levels of NLRP1, ASC and precursor caspase-1 but also reduced the levels of IL-1ß and IL-18 in MCAO rats and OGD cells. Therefore, we conclude that miR-9a-5p is involved in NLRP1 inflammasome-mediated ischemic injury, which further suggests that the overexpression of miR-9 may be an effective way to ameliorate brain injury following ischemic stroke.