RRY Inhibits Amyloid-ß1-42 Peptide Aggregation and Neurotoxicity.

BACKGROUND: Current understanding of amyloid-ß protein (Aß) aggregation and toxicity provides an extensive list of drugs for treating Alzheimer's disease (AD); however, one of the most promising strategies for its treatment has been tri-peptides. OBJECTIVE: The aim of this study is to examine those tri-peptides, such as Arg-Arg-Try (RRY), which have the potential of Aß1-42 aggregating inhibition and Aß clearance. METHODS: In the present study, in silico, in vitro, and in vivo studies were integrated for screening tri-peptides binding to Aß, then evaluating its inhibition of aggregation of Aß, and finally its rescuing cognitive deficit. RESULTS: In the in silico simulations, molecular docking and molecular dynamics determined that seven top-ranking tri-peptides could bind to Aß1-42 and form stable complexes. Circular dichroism, ThT assay, and transmission electron microscope indicated the seven tri-peptides might inhibit the aggregation of Aß1-42 in vitro. In the in vivo studies, Morris water maze, ELISA, and Diolistic staining were used, and data showed that RRY was capable of rescuing the Aß1-42-induced cognitive deficit, reducing the Aß1-42 load and increasing the dendritic spines in the transgenic mouse model. CONCLUSION: Such converging outcomes from three consecutive studies lead us to conclude that RRY is a preferred inhibitor of Aß1-42 aggregation and treatment for Aß-induced cognitive deficit.

Generation of hypoimmunogenic human pluripotent stem cells.

Polymorphic HLAs form the primary immune barrier to cell therapy. In addition, innate immune surveillance impacts cell engraftment, yet a strategy to control both, adaptive and innate immunity, is lacking. Here we employed multiplex genome editing to specifically ablate the expression of the highly polymorphic HLA-A/-B/-C and HLA class II in human pluripotent stem cells. Furthermore, to prevent innate immune rejection and further suppress adaptive immune responses, we expressed the immunomodulatory factors PD-L1, HLA-G, and the macrophage "don't-eat me" signal CD47 from the AAVS1 safe harbor locus. Utilizing in vitro and in vivo immunoassays, we found that T cell responses were blunted. Moreover, NK cell killing and macrophage engulfment of our engineered cells were minimal. Our results describe an approach that effectively targets adaptive as well as innate immune responses and may therefore enable cell therapy on a broader scale.

Cholestane-3ß, 5α, 6ß-triol suppresses neuronal hyperexcitability via binding to voltage-gated sodium channels.

Neuronal hyperexcitability is identified as a critical pathological basis of epileptic seizures. Cholestane-3ß, 5α, 6ß-triol (Triol) is a major metabolic oxysterol of cholesterol. Although its neuroprotective effect on ischemia-induced neuronal injury and negative modulation of voltage-gated sodium (Nav) channels were well established, the physical binding site of triol to sodium channels and its effects on neuronal hyperexcitability have not yet been explored. In this study, we utilized molecular docking and molecular dynamics simulation to investigate the interaction between triol and Nav Channels. Our results demonstrated that triol binds to the indole ring of Trp122 of the Nav Channel in silico with a high biological affinity. We further found that triol negatively modulates the action potentials bursts of hippocampal neurons by cell-attached patch recording. Moreover, triol significantly inhibits low Mg2+-induced hyperexcitability in vitro. In addition, triol attenuates pentylenetetrazole (PTZ)-induced convulsive-form behavioral deficits in vivo. Together, our results suggest that triol suppresses neuronal hyperexcitability via binding to Nav channel, indicating that triol might be an attractive lead compound for the treatment of neuronal hyperexcitability-related neurological disorders, especially epileptic seizures.

EGAR, A Food Protein-Derived Tetrapeptide, Reduces Seizure Activity in Pentylenetetrazole-Induced Epilepsy Models Through α-Amino-3-Hydroxy-5-Methyl-4-Isoxazole Propionate Receptors.

A primary pathogeny of epilepsy is excessive activation of α-amino-3-hydroxy-5-methyl-4-isoxazole propionate receptors (AMPARs). To find potential molecules to inhibit AMPARs, high-throughput screening was performed in a library of tetrapeptides in silico. Computational results suggest that some tetrapeptides bind stably to the AMPAR. We aligned these sequences of tetrapeptide candidates with those from in vitro digestion of the trout skin protein. Among salmon-derived products, Glu-Gly-Ala-Arg (EGAR) showed a high biological affinity toward AMPAR when tested in silico. Accordingly, natural EGAR was hypothesized to have anticonvulsant activity, and in vitro experiments showed that EGAR selectively inhibited AMPAR-mediated synaptic transmission without affecting the electrophysiological properties of hippocampal pyramidal neurons. In addition, EGAR reduced neuronal spiking in an in vitro seizure model. Moreover, the ability of EGAR to reduce seizures was evaluated in a rodent epilepsy model. Briefer and less severe seizures versus controls were shown after mice were treated with EGAR. In conclusion, the promising experimental results suggest that EGAR inhibitor against AMPARs may be a target for antiepilepsy pharmaceuticals. Epilepsy is a common brain disorder characterized by the occurrence of recurring, unprovoked seizures. Twenty to 30 % of persons with epilepsy do not achieve adequate seizure control with any drug. Here we provide a possibility in which a natural and edible tetrapeptide, EGAR, can act as an antiepileptic agent. We have combined computation with in vitro experiments to show how EGAR modulates epilepsy. We also used an animal model of epilepsy to prove that EGAR can inhibit seizures in vivo. This study suggests EGAR as a potential pharmaceutical for the treatment of epilepsy.

Silibinin inhibits acetylcholinesterase activity and amyloid ß peptide aggregation: a dual-target drug for the treatment of Alzheimer's disease.

Alzheimer's disease (AD) is characterized by amyloid ß (Aß) peptide aggregation and cholinergic neurodegeneration. Therefore, in this paper, we examined silibinin, a flavonoid extracted from Silybum marianum, to determine its potential as a dual inhibitor of acetylcholinesterase (AChE) and Aß peptide aggregation for AD treatment. To achieve this, we used molecular docking and molecular dynamics simulations to examine the affinity of silibinin with Aß and AChE in silico. Next, we used circular dichroism and transmission electron microscopy to study the anti-Aß aggregation capability of silibinin in vitro. Moreover, a Morris Water Maze test, enzyme-linked immunosorbent assay, immunohistochemistry, 5-bromo-2-deoxyuridine double labeling, and a gene gun experiment were performed on silibinin-treated APP/PS1 transgenic mice. In molecular dynamics simulations, silibinin interacted with Aß and AChE to form different stable complexes. After the administration of silibinin, AChE activity and Aß aggregations were down-regulated, and the quantity of AChE also decreased. In addition, silibinin-treated APP/PS1 transgenic mice had greater scores in the Morris Water Maze. Moreover, silibinin could increase the number of newly generated microglia, astrocytes, neurons, and neuronal precursor cells. Taken together, these data suggest that silibinin could act as a dual inhibitor of AChE and Aß peptide aggregation, therefore suggesting a therapeutic strategy for AD treatment.

Melaleuca alternifolia concentrate inhibits in vitro entry of influenza virus into host cells.

Influenza virus causes high morbidity among the infected population annually and occasionally the spread of pandemics. Melaleuca alternifolia Concentrate (MAC) is an essential oil derived from a native Australian tea tree. Our aim was to investigate whether MAC has any in vitro inhibitory effect on influenza virus infection and what mechanism does the MAC use to fight the virus infection. In this study, the antiviral activity of MAC was examined by its inhibition of cytopathic effects. In silico prediction was performed to evaluate the interaction between MAC and the viral haemagglutinin. We found that when the influenza virus was incubated with 0.010% MAC for one hour, no cytopathic effect on MDCK cells was found after the virus infection and no immunofluorescence signal was detected in the host cells. Electron microscopy showed that the virus treated with MAC retained its structural integrity. By computational simulations, we found that terpinen-4-ol, which is the major bioactive component of MAC, could combine with the membrane fusion site of haemagglutinin. Thus, we proved that MAC could prevent influenza virus from entering the host cells by disturbing the normal viral membrane fusion procedure.