Synthesis and inhibition studies towards the discovery of benzodiazepines as potential antimalarial compounds.

The target-based discovery of therapeutics against apicoplast, an all-important organelle is an overriding perspective. MEP pathway, an accredited drug target provides an insight into the importance of apicoplast in the survival of the parasite. In this study, we present the rational design strategy employing sustainable catalysis for the synthesis of benzodiazepine (BDZ) conformers followed by their biological evaluation as prospective inhibitors against the potential target of the IPP pathway, 1-deoxy-D-xylulose-5-phosphatereductoisomerase (DXR). The study reported the inhibitory profile of 8c and 6d against the quintessential step of the only drug target in the erythrocytic stages of parasite development. The potential compounds were identified to represent a novel class of inhibitors that serve as the lead molecules to impede the pathway and further affect the survival of the parasite.

Aryldiazoquinoline based multifunctional small molecules for modulating Aß42 aggregation and cholinesterase activity related to Alzheimer's disease.

Research continues to find a breakthrough for the treatment of Alzheimer's Disease (AD) due to its complicated pathology. Presented herein is a novel series of arydiazoquinoline molecules investigated for their multifunctional properties against the factors contributing to Alzheimer's disease (AD). The inhibitory properties of fourteen closely related aryldiazoquinoline derivatives have been evaluated for their inhibitory effect on Aß42 peptide aggregation. Most of these molecules inhibited Aß42 fibrillation by 50-80%. Selected molecules were also investigated for their binding behaviour to preformed Aß40 aggregates indicating a nanomolar affinity. In addition, these compounds were further investigated as cholinesterase inhibitors. Interestingly, some of the compounds turned out to be moderate in vitro inhibitors for AChE activity with IC50 values in low micro molar range. The highest anti-AChE activity was shown by compound labelled as 2a with an IC50 value of 6.2 µM followed by 2b with IC50 value of 7.0 µM. In order to understand the inhibitory effect, binding of selected molecules to AChE enzyme was studied using molecular docking. In addition, cell toxicity studies using Neuro2a cells were performed to assess their effect on neuronal cell viability which suggests that these molecules possess a non-toxic molecular framework. Overall, the study identifies a family of molecules that show good in vitro anti-Aß-aggregation properties and moderately inhibit cholinesterase activity.