MSX1 Gene Polymorphisms in Patients with non-Syndromic Cleft lip and Palate: A Tertiary Care Centre Based Case-Control Study from Central Kerala.

OBJECTIVE: The purpose of this study was to investigate the contribution of MSX1 gene polymorphisms to the risk of developing NSCLP. DESIGN: Case-Control Study. SETTING: A tertiary care centre. PATIENTS/PARTICIPANTS: The sample consisted of 200 subjects (100 cases and 100 controls). INTERVENTIONS: None. MAIN OUTCOME MEASURE(S): Genotyping was performed by restriction fragment length polymorphism. Allele and genotype frequencies were calculated between patients and controls and analyzed using online Web Tools such as SISA and SNPstats. The MSX1 gene polymorphisms c. 799 GT, c.458 CA can be risk factors in the development of orofacial clefts. RESULTS: In the cases, an association was found between NSCLP and c.799 and c.458 of the MSX1 gene when compared with the control. The dominant and overdominant models, c. 799 GT, c.458 CA genotypes and c. 799 T, c.458 A alleles in the population are said to be the main risk factors to develop the NSCLP in our study population. The genotype variation of c 799 G/T and c.458 C/A are revealed to be specifically contributing to an NSCLP-type Cleft lip and Palate. It is worth noting that NSCLP females in the study population showed a stronger association with heterozygous genotypes of c.799 and c.458. However, further investigation with a larger cohort is necessary to confirm these findings. CONCLUSION: Overall the results of the study revealed that MSX1 c 799 G > T and c.458 C > A can be considered as one of the genetic risk factors in the formation of Non-Syndromic Cleft Lip and Palate in the study population.

Neuroprotective effects of dietary plants and phytochemicals against radiation-induced cognitive and behavioral deficits: a comprehensive review of evidence and prospects for future research.

Exposure to ionizing radiation (IR) is a common occurrence in clinical practice and incidents involving nuclear detonation or nuclear reactor accidents. IR triggers cellular events that result in oxidative stress and damage to macromolecules, rendering it harmful. While the central nervous system (CNS) was once believed to be resistant to radiation, emerging evidence suggests that even small doses of IR can adversely impact the brain. Exposure to an unsafe dose of radiation can cause increased permeability of the blood-brain barrier (BBB), neuronal apoptosis, reduced neurogenesis, impaired synaptic plasticity, and cognitive dysfunction. In recent years, the potential benefits of dietary agents and phytochemicals for mental health and radiation-induced damage have been widely investigated. Despite this, few studies have explored the protective effects of plants against radiation-induced brain damage. Here, we present a review collating evidence on the beneficial effects of dietary plants on radiation-induced brain damage based on behavioral studies. Notably, Amaranthus paniculatus, Grewia asiatica, Lycium barbarum, and phytochemicals such as vitamin E, corilagin, curcumin, resveratrol, and ursolic acid have demonstrated potential in mitigating radiation-induced damage to the CNS. Furthermore, preliminary studies have indicated that alpha-tocopherol and the micronutrient selenium have neuroprotective effects in cancer survivors previously treated with radiation to the brain. This review focuses exclusively on behavioral outcomes to assess the impact of ionizing radiation on the CNS and the effectiveness of dietary plants and phytochemicals as neuroprotective agents against radiation-induced neuronal damage.

In situ engineering of Au-Ag alloy embedded PEDOT nanohybrids at a solvent/non-solvent interface for the electrochemical enzyme-free detection of histamine.

Steadfast efforts have been made to develop novel materials and incorporate them into functional devices for practical applications, pushing the research on electroactive materials to the forefront of nano electronics. Liquid/liquid interface-assisted polymerization offers a scalable methodology to fabricate hybrid materials with multifunctional applications, in contrast to the conventional and ubiquitous routes. Here, we explored this efficient and versatile approach toward the in situ tailoring of Au-Ag alloy nanostructures with a conducting polymer, poly(3,4-ethylene-dioxythiophene) (PEDOT). With the appropriate choice of organic and inorganic phases for the distribution of monomer and oxidant, the miscibility restraints of the reactants in a single phase were alleviated. Effective nanostructure tuning of highly crystalline and electroactive PEDOT/Au-Ag alloy has been achieved by varying the molar ratio of Au3+/Ag+ in the reaction mixture. The as-synthesized composite is further explored to detect neuromodulator histamine (HA), which displays high sensitivity with a limit of detection (LOD) of 1.5 nM, and selectivity even in the presence of various interfering analogs of 10-fold concentration. Subsequently, density functional theory (DFT) simulations are employed to assess the mode of interaction between HA and the electroactive surfaces. The competency to detect HA in preserved food entails its potential in food spoilage monitoring. Furthermore, the detection of histamine generated by sub-cultured human neuronal cells SH-SY5Y proves its practical viability in health monitoring devices.

An integrated chemo-informatics and in vitro experimental approach repurposes acarbose as a post-ischemic neuro-protectant.

The increasing prevalence of ischemic stroke combined with limited therapeutic options highlights the compelling need for continued research into the development of future neuro-therapeutics. Death-Associated Protein Kinase 1 (DAPK1) and p53 protein-protein interaction serve as a signaling point for the convergence of apoptosis and necrosis in cerebral ischemia. In this study, we used an integrated chemo-informatics and in vitro experimental drug repurposing strategy to screen potential small-molecule inhibitors of DAPK1-p53 interaction from the United States of America Food and Drug Administration (FDA) approved drug database exhibiting post-ischemic neuroprotective and neuro-regenerative efficacy and mechanisms. The computational docking and molecular dynamics simulation of FDA-approved drugs followed by an in vitro experimental validation identified acarbose, an anti-diabetic medication and caloric restriction mimetic as a potential inhibitor of DAPK1-p53 interaction. The evaluation of post-ischemic neuroprotective and regenerative efficacy and mechanisms of action for acarbose was carried out using a set of experimental methods, including cell viability, proliferation and differentiation assays, fluorescence staining, and gene expression analysis. Post-ischemic administration of acarbose conferred significant neuroprotection against ischemia-reperfusion injury in vitro. The reduced fluorescence emission in cells stained with pS20 supported the potential of acarbose in inhibiting the DAPK1-p53 interaction. Acarbose prevented mitochondrial and lysosomal dysfunction, and favorably modulated gene expression related to cell survival, inflammation, and regeneration. BrdU staining and neurite outgrowth assay showed a significant increase in cell proliferation and differentiation in acarbose-treated group. This is the first study known to provide mechanistic insight into the post-ischemic neuroprotective and neuro-regenerative potential of acarbose. Our results provide a strong basis for preclinical studies to evaluate the safety and neuroprotective efficacy of acarbose against ischemic stroke. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1007/s13205-022-03130-5.

ISCHEMIRs: Finding a Way Through the Obstructed Cerebral Arteries.

MicroRNAs (miRNAs) are small (19-25 nucleotides) non-coding single-stranded RNAs that control post-transcriptional gene expression. miRNAs are abundantly expressed in the brain, where they play key roles during neuronal differentiation, synaptogenesis, and plasticity. It is also becoming increasingly evident that miRNAs are involved in the etiology of several neurological disorders. Mounting evidence indicates that miRNAs have the ability to regulate the expression profiles of genes in signaling pathways associated with cerebrovascular diseases such as ischemic stroke, subarachnoid hemorrhage, and vascular dementia. For instance, miR-21 is involved in ischemic stroke pathology through atherosclerosis and provides neuroprotection by its anti-apoptotic features. miR-497 induces neuronal death and miR-210 is upregulated in hypoxic cells. Deregulated expression of miRNAs in response to ischemic stroke has enabled the use of miRNA as an efficient non-invasive biomarker. Antagomirs are often effective against neuronal apoptosis and can induce neuroregeneration following ischemia. Moreover, the advent of systems biology has introduced novel computational tools to identify the link between miRNAs, target genes and transcription factors involved in the stroke pathology and its treatment. This review describes the emerging role of miRNAs in neuroprotection and focuses on a subset of miRNAs that act as central players in ischemic stroke.

Glycogen synthase kinase-ß3 in ischemic neuronal death.

Glycogen synthase kinase 3ß (GSK-3ß) is implicated in diverse cellular processes such as cell signaling and survival. Accumulating lines of evidence indicate that increased GSK-3ß activity contributes to neuronal death and pathogenesis of ischemic stroke. Considering predominant roles of GSK-3ß in neuronal apoptosis, modulation of this protein kinase is a reliable strategy for ischemic neuroprotection. In this review, we survey and synthesize the current knowledge about the role of GSK-3ß in neuroprotection following the ischemic stroke.

A combination of 3D-QSAR modeling and molecular docking approach for the discovery of potential HIF prolyl hydroxylase inhibitors.

Suppression of HIF prolyl hydroxylase (PHD) activity by small molecule inhibitors leads to the stabilization of HIF and offers a potential therapeutic option for treating ischemic disorders. In this study, pharmacophore based QSAR modeling, virtual screening and molecular docking approaches were concurrently used to identify target-specific PHD inhibitors with better ADME properties and to readily minimize false positives and false negatives. A 3D-QSAR based method was used to generate a pharmacophore hypothesis (AAAN). The obtained 3D-QSAR model has an excellent correlation coefficient value (r2 = 0.99), Fisher ratio (F = 386) and exhibited good predictive power (q2 = 0.64). The hypothesis was validated and utilized for chemical database screening and the retrieved compounds were subjected to molecular docking for further refinement. Quantitative AAAN hypothesis comprised three H-bond accepter and one negative ionizable group feature and it give good predictive ability because all the QSAR information it was providing matched with the active site information. The hypothesis was validated and used as a 3D query for database screening. After manual selection, molecular docking and further refinement, based on the molecular interactions of inhibitors with the essential amino acids residues, 12 candidates with good ADME and blood brain barrier permeability values were selected as potential PHD inhibitors.

In silico prediction of novel inhibitors of the DNA binding activity of FoxG1.

Forkhead box (Fox) proteins are a superfamily of evolutionarily conserved transcriptional regulators, which control a wide spectrum of biological processes. FoxG1 is a transcriptional repressor, whose function has been elucidated recently. FoxG1 overexpression was found to be associated with medulloblastoma and hepatoblastoma. It was suggested that the inhibition of FoxG1 could be a potential target for the development of molecular therapeutics in such type of cancers. Since, experimentally derived structure for FoxG1 is unavailable in any of the structural databases, modeling of the DNA binding domain of this protein was carried out. Potential binding sites on the protein surface were predicted. Pharmacophoric features were derived from the binding site that lies near the protein-DNA binding interface and this pharmacophore was employed for virtual screening of compounds. To the best of our knowledge, this is the first pharmacophore model proposed for screening inhibitors of FoxG1, which may interfere with its transcriptional repressor functionality. The interactions of the binding site residues with the top scoring ligand hits were analyzed. These ligands may be used for the development of potential inhibitors of FoxG1 protein.