CNS & Neurological Disorders - Drug Targets (Formerly Current Drug Targets - CNS & Neurological Disorders) - Volume 19, Issue 7, 2020

Glial cells, including microglia and astrocytes, facilitate the survival and health of all cells within the Central Nervous System (CNS) by secreting a range of growth factors and contributing to tissue and synaptic remodeling. Microglia and astrocytes can also secrete cytotoxins in response to specific stimuli, such as exogenous Pathogen-Associated Molecular Patterns (PAMPs), or endogenous Damage-Associated Molecular Patterns (DAMPs). Excessive cytotoxic secretions can induce the death of neurons and contribute to the progression of neurodegenerative disorders, such as Alzheimer’s disease (AD). The transition between various activation states of glia, which include beneficial and detrimental modes, is regulated by endogenous molecules that include DAMPs, cytokines, neurotransmitters, and bioactive lipids, as well as a diverse group of mediators sometimes collectively referred to as Resolution-Associated Molecular Patterns (RAMPs). RAMPs are released by damaged or dying CNS cells into the extracellular space where they can induce signals in autocrine and paracrine fashions by interacting with glial cell receptors. While the complete range of their effects on glia has not been described yet, it is believed that their overall function is to inhibit adverse CNS inflammatory responses, facilitate tissue remodeling and cellular debris removal. This article summarizes the available evidence implicating the following RAMPs in CNS physiological processes and neurodegenerative diseases: cardiolipin (CL), prothymosin α (ProTα), binding immunoglobulin protein (BiP), heat shock protein (HSP) 10, HSP 27, and αB-crystallin. Studies on the molecular mechanisms engaged by RAMPs could identify novel glial targets for development of therapeutic agents that effectively slow down neuroinflammatory disorders including AD.

Many efforts have been made to develop therapeutic agents for Alzheimer’s Disease (AD) based on the amyloid cascade hypothesis, but there is no effective therapeutic agent at present. Now, much attention has been paid to infiltrate pathogens in the brain as a trigger of AD. These pathogens, or their virulence factors, may directly cross a weakened blood-brain barrier, reach the brain and cause neurological damage by eliciting neuroinflammation. Moreover, there is growing clinical evidence of a correlation between periodontitis and cognitive decline in AD patients. Recent studies have revealed that microglial cathepsin B is increasingly induced by lipopolysaccharide of Porphylomonas gingivalis, a major pathogen of periodontal disease. Moreover, gingipains produced by P. gingivalis play critical roles in neuroinflammation mediated by microglia and cognitive decline in mice. Furthermore, an orally bioavailable and brain-permeable inhibitor of gingipain is now being tested in AD patients. It is largely expected that clinical studies countering bacterial virulence factors may pave the way to establish the prevention and early treatment of AD.

Background: Fibroblast Growth Factor (FGF) 2 (also referred to as basic FGF) is a multifunctional growth factor that plays a pivotal role in the pro-survival, pro-migration and prodifferentiation of neurons. Method: Because alterations in FGF2 levels are suggested to contribute to the pathogenesis of schizophrenia, we investigated serum levels of FGF2 in the Gunn rat, a hyperbilirubinemia animal model of schizophrenic symptoms. Results: The enzyme-linked immunosorbent assay showed that the serum levels of FGF2 in Gunn rats were 5.09 ± 0.236 pg/mL, while those in the normal strain Wistar rats, serum levels were 11.90 ± 2.142 pg/mL. The serum FGF2 levels in Gunn rats were significantly lower than those in Wistar rats. We also measured serum levels of Unconjugated Bilirubin (UCB) and found a significant negative correlation between UCB and FGF2 in terms of serum levels in all the rats studied. Conclusion: Since it is known that FGF2 regulates dopaminergic neurons and have antineuroinflammatory effects, our finding suggests that low FGF2 levels may contribute to the pathogenesis of schizophrenia, in which imbalanced dopamin-ergic signaling and neuroinflammation are supposed to play certain roles.

Recent studies implicate microbiota-brain communication as an essential factor for physiology and pathophysiology in brain function and neurodevelopment. One of the pivotal mechanisms about gut to brain communication is through the regulation and interaction of gut microbiota on the host immune system. In this review, we will discuss the role of microbiota-immune systeminteractions in human neurological disorders. The characteristic features in the development of neurological diseases include gut dysbiosis, the disturbed intestinal/Blood-Brain Barrier (BBB) permeability, the activated inflammatory response, and the changed microbial metabolites. Neurological disorders contribute to gut dysbiosis and some relevant metabolites in a top-down way. In turn, the activated immune system induced by the change of gut microbiota may deteriorate the development of neurological diseases through the disturbed gut/BBB barrier in a down-top way. Understanding the characterization and identification of microbiome-immune- brain signaling pathways will help us to yield novel therapeutic strategies by targeting the gut microbiome in neurological disease.

Background: Parkinson’s Disease (PD) is characterized by both motor and non-motor symptoms. The presynaptic neuronal protein, α-Synuclein, plays a pivotal role in PD pathogenesis and is associated with both genetic and sporadic origin of the disease. Ursolic Acid (UA) is a well-known bioactive compound found in various medicinal plants, widely studied for its anti-inflammatory and antioxidant activities. Objective: In this research article, the neuroprotective potential of UA has been further explored in the Rotenone-induced mouse model of PD. Methods: To investigate our hypothesis, we have divided mice into 4 different groups, control, drug only control, Rotenone-intoxicated group, and Rotenone-intoxicated mice treated with UA. After the completion of dosing, behavioral parameters were estimated. Then mice from each group were sacrificed and the brains were isolated. Further, the biochemical tests were assayed to check the balance between the oxidative stress and endogenous anti-oxidants; and TH (Tyrosine Hydroxylase), α-Synuclein, Akt (Serine-threonine protein kinase), ERK (Extracellular signal-regulated kinase) and inflammatory parameters like Nuclear Factor-ΚB (NF-ΚB) and Tumor Necrosis Factor- α (TNF-α) were assessed using Immunohistochemistry (IHC). Western blotting was also done to check the expressions of TH and α-Synuclein. Moreover, the expression levels of PD related genes like α-Synuclein, β-Synuclein, Interleukin-1β (IL-1β), and Interleukin-10 (IL-10) were assessed by using Real-time PCR. Results: The results obtained in our study suggested that UA significantly reduced the overexpression of α-Synuclein and regulated the phosphorylation of survival-related kinases (Akt and ERK) apart from alleviating the behavioral abnormalities and protecting the dopaminergic neurons from oxidative stress and neuroinflammation. Conclusion: Thus, our study shows the neuroprotective potential of UA, which can further be explored for possible clinical intervention.

Background: Withania somnifera (WS), also referred to as Medhya Rasayana (nootropic or rejuvenating), has traditionally been prescribed for various neurological ailments, including dementia. Despite substantial evidence, pharmacological roles of WS, neither as nootropic nor as an antidementia agent, are well-understood at the cellular and molecular levels. Objectives: We aimed at elucidating the pharmacological action mechanisms of WS root constituents against Alzheimer’s Disease (AD) pathology. Methods: Various bioinformatics tools and resources, including DAVID, Cytoscape, NetworkAnalyst and KEGG pathway database were employed to analyze the interaction of WS root bioactive molecules with the protein targets of AD-associated cellular processes. We also used a molecular simulation approach to validate the interaction of compounds with selected protein targets. Results: Network analysis revealed that β-sitosterol, withaferin A, stigmasterol, withanolide A, and withanolide D are the major constituents of WS root that primarily target the cellular pathways such as PI3K/Akt signaling, neurotrophin signaling and toll-like receptor signaling and proteins such as Tropomyosin receptor Kinase B (TrkB), Glycogen Synthase Kinase-3β (GSK-3β), Toll-Like Receptor 2/4 (TLR2/4), and β-secretase (BACE-1). Also, the in silico analysis further validated the interaction patterns and binding affinity of the major WS compounds, particularly stigmasterol, withanolide A, withanolide D and β-sitosterol with TrkB, GSK-3β, TLR2/4, and BACE-1. Conclusion: The present findings demonstrate that stigmasterol, withanolide A, withanolide D and β-sitosterol are the major metabolites that are responsible for the neuropharmacological action of WS root against AD-associated pathobiology, and TrkB, GSK-3β, TLR2/4, and BACE-1 could be the potential druggable targets.