Understanding the autistic brain and the involvement of genetic, non-genetic, and numerous signaling pathways in the etiology and pathophysiology of autism spectrum disorder (ASD) is complex, as is evident from various studies. Apart from multiple developmental disorders of the brain, autistic subjects show a few characteristics like impairment in social communications related to repetitive, restricted, or stereotypical behavior, which suggests alterations in neuronal circuits caused by defects in various signaling pathways during embryogenesis. Most of the research studies on ASD subjects and genetic models revealed the involvement of mutated genes with alterations of numerous signaling pathways like Wnt, hedgehog, and Retinoic Acid (RA). Despite significant improvement in understanding the pathogenesis and etiology of ASD, there is an increasing awareness related to it as well as a need for more in-depth research because no effective therapy has been developed to address ASD symptoms. Therefore, identifying better therapeutic interventions like “novel drugs for ASD” and biomarkers for early detection and disease condition determination are required. This review article investigated various etiological factors as well as the signaling mechanisms and their alterations to understand ASD pathophysiology. It summarizes the mechanism of signaling pathways, their significance, and implications for ASD.
As acetylcholinesterase (AChE) plays a crucial role in advancing Alzheimer’s disease (AD), its inhibition is a promising approach for treating AD. Sulindac is an NSAID of the aryl alkanoic acid class, consisting of a indene moiety, which showed neuroprotective behavior in recent studies. In this study, newer Indene analogs were synthesized and evaluated for their in vitro AChE inhibition. Additionally, compared with donepezil as the standard drug, these Indene analogs were accessed for their cell line-based toxicity study on SH-SY5Y cell line. The molecule SD-30, having hydrogen bond donor (HBD) at para-position, showed maximum AChE inhibition potential (IC50 13.86 ± 0.163 µM) in the indene series. Further, the SD-30 showed maximum BuChE inhibition potential (IC50 = 48.55 ± 0.136 µM) with a selectivity ratio of 3.50 and reasonable antioxidant properties compared to ascorbic acid (using DPPH assay). SD-30 (at a dose level: of 10 µM, 20 µM) effectively inhibited AChE-induced Aβ aggregation and showed no significant toxicity up to 30 mM against SH-SY5Y cell lines.
The SARS-CoV-2 viruses had made a great impact on humankind and the world economy. Phylogenetic analysis revealed the newly identified B.1.617.1 and B.1.617.2 lineages possessed with few key mutations predominantly circulating. The signature mutations possessed by these lineages are situated in the RBD motif of S protein. Reports revealed variants L452R, T478K, and E484Q harbours in enhancement with hACE2 binding while P681R situated in furin cleavage site resulting in better transmissibility. To gain a deeper understanding of the impact of these variants (L452R, T478K and E484Q) binding with hACE2, structural dynamics at the interface between S-RBD protein and hACE2 were studied. We performed our dynamics studies with both single mutant complex (L452R, T478K and E484Q) and in the combination of triple mutants (L452R + T478K + E484Q) at 100ns in contrast with the wild type. Interfacial docking interactions and Molecular Mechanics approach exhibited that the spike mutants -L452R, T478K and E484Q harbour with higher binding affinity on hACE2 in contrast with its native spike protein. The presence of interfacial residue, intermolecular contacts such as hydrogen bonding, salt bridge and non-hydrogen bonded interactions might be the reason for its higher binding affinity. Hence the findings from our study unravelled plausible mechanism for the increase in affinities of mutants to hACE2 thus leading to higher transmissibility and infection of emerging variants. Further, the conformational alterations in the course of dynamics at the RBD motif led to enhancement of hACE2 binding and immune escape. These results suggest that the structural changes introduced by these variants enhance the binding affinities of the S protein with the hACE2 that could form the basis to further aid in designing therapeutics that could inhibit at the interface of S protein and hACE2 receptor.
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