A Comprehensive Multispectroscopic and Computational Analysis of the Interaction between Plant-Based Antiplasmodial Compounds and Bovine Serum Albumin.

This study was conducted to explore the interaction between two plant-based antiplasmodial compounds, gartanin and friedelin, and bovine serum albumin (BSA). The objectives aimed to elucidate the binding characteristics, structural changes, and thermodynamic parameters associated with the interaction. Various methods were used including UV-vis, fluorescence, and circular dichroism spectroscopy, supported by molecular docking and molecular dynamics simulation. The results showed a concentration-dependent interaction between the antiplasmodial compounds and BSA, revealing changes in protein conformation and stability. The obtained results showed that the plant products bound with BSA through static quenching with moderate binding affinity (104 M-1) with BSA. Thermodynamic parameters and structural transitions calculated from spectroscopic methods revealed that hydrogen bond and van der Waals forces caused the partial conformational alteration in the secondary structure of BSA as the α-helical content decreased with an increase in ß sheets, random coils, and other structures. Computational analysis provided insights into the binding sites and affinities. The study enhances our understanding of the molecular interactions between BSA protein and antiplamodial compounds obtained from plants, supporting the research of choosing, designing, and optimizing molecules for biomedical applications with a focus on selectively targeting their binding sites.

Comparative investigation on interaction between potent antimalarials and human serum albumin using multispectroscopic and computational approaches.

This study performed a comparative investigation to explore the interaction mechanisms between two potential antimalarial compounds, JMI 346 and JMI 105, and human serum albumin (HSA), a vital carrier protein responsible for maintaining important biological functions. Our aim was to assess the pharmacological efficiency of these compounds while comprehensively analyzing their impact on the dynamic behavior and overall stability of the protein. A comprehensive array of multispectroscopic techniques, including UV-Vis. spectroscopy, steady-state fluorescence analysis, synchronous fluorescence spectroscopy, three-dimensional fluorescence and circular dichroism spectroscopy, docking studies, and molecular dynamics simulations, were performed to probe the intricate details of the interaction between the compounds and HSA. Our results revealed that both JMI 346 and JMI 105 exhibited promising pharmacological effectiveness within the context of malaria therapy. However, JMI 346 was found to exhibit a significantly higher affinity and only minor altered impact on HSA, suggesting a more favorable interaction with the protein on the dynamic behavior and overall stability of the protein in comparison to JMI 105. Further studies can build on these results to optimize the drug-protein interaction and enable the development of more potent and targeted antimalarial treatments.

Recent Updates on Interaction Studies and Drug Delivery of Antimalarials with Serum Albumin proteins.

This review focuses on recent trends in the binding study of various antimalarial agents with serum albumins in detail. Serum albumin has a significant role in the transport of drugs and endogenous ligands. The nature and magnitude of serum albumin and drug interactions have a tremendous impact on the pharmacological behavior and toxicity of that drug. Binding of drug to serum albumin not only controls its free and active concentration, but also provides a reservoir for a long duration of action. This ultimately affects drug absorption, distribution, metabolism, and excretion. Such interaction determines the actual drug efficacy as the drug action can be correlated with the amount of unbound drug. With the advancement in spectroscopic techniques and simulation studies, binding studies play an increasingly important role in biophysical and biomedical science, especially in the field of drug delivery and development. This review assesses the insight we have gained so far to improve drug delivery and discovery of antimalarials on the basis of a plethora of drug-serum protein interaction studies done so far.

A multi-spectroscopic and computational simulations study to delineate the interaction between antimalarial drug hydroxychloroquine and human serum albumin.

Hydroxychloroquine (HCQ), a quinoline based medicine is commonly used to treat malaria and autoimmune diseases such as rheumatoid arthritis. Since, human serum albumin (HSA) serves as excipient for vaccines or therapeutic protein drugs, it is important to understand the effect of HCQ on the structural stability of HSA. In this study, the binding mechanism of HCQ and their effect on stability of HSA have been studied using various spectroscopic techniques and molecular dynamic simulation. The UV-VIS results confirmed the strong binding of HCQ with HSA. The calculated thermodynamics parameters confirmed that binding is spontaneous in nature and van der Waals forces and hydrogen bonding are involved in the binding system which is also confirmed by molecular docking results. The steady-state fluorescence confirms the static quenching mechanism in the interaction system, which was further validated by time-resolved fluorescence. The synchronous fluorescence confirmed the more abrupt binding of HCQ with tryptophan residue of HSA compared to Tyr residue of HSA. Isothermal titration calorimetry (ITC) was done to validate the thermodynamics parameters of HSA-HCQ complex in one experiment, supporting the values obtained from the spectroscopic techniques. The circular dichroism (CD) demonstrated that the HCQ affected the secondary structure of HSA protein by reducing their α-helical content. The docking and molecular dynamic simulation results further helped in understanding the effect of HCQ on conformational changes of HSA. Overall, present work defined the physicochemical properties and interaction mechanism of HCQ with HSA that have extensively been elucidated by both in vitro and in silico approaches.Communicated by Ramaswamy H. Sarma.

Mechanistic Understanding of Candida albicans Biofilm Formation and Approaches for Its Inhibition.

In recent years, the demand for novel antifungal therapies has increased several- folds due to its potential to treat severe biofilm-associated infections. Biofilms are made by the sessile microorganisms attached to the abiotic or biotic surfaces, enclosed in a matrix of exopolymeric substances. This results in new phenotypic characteristics and intrinsic resistance from both host immune response and antimicrobial drugs. Candida albicans biofilm is a complex association of hyphal cells that are associated with both abiotic and animal tissues. It is an invasive fungal infection and acts as an important virulent factor. The challenges linked with biofilm-associated diseases have urged scientists to uncover the factors responsible for the formation and maturation of biofilm. Several strategies have been developed that could be adopted to eradicate biofilm-associated infections. This article presents an overview of the role of C. albicans biofilm in its pathogenicity, challenges it poses and threats associated with its formation. Further, it discusses strategies that are currently available or under development targeting prostaglandins, quorum-sensing, changing surface properties of biomedical devices, natural scaffolds, and small molecule-based chemical approaches to combat the threat of C. albicans biofilm. This review also highlights the recent developments in finding ways to increase the penetration of drugs into the extracellular matrix of biofilm using different nanomaterials against C. albicans.