Dual Antifungal and Antiproliferative Activities of a Novel Protein Fraction from a Medicinally Important Herb Trillium govanianum Wall. ex. D. Don.

Antimicrobial resistance of microorganisms and the unwanted side effects of chemoradiation therapy in cancer are major issues in healthcare. In recent times, protein-based drugs have emerged as promising candidates due to their high specificity, less side effects, etc. In this context, the rhizome of Trillium govanianum was first explored for biologically active proteins/peptides. For this, three protein fractions namely Aqueous protein fraction (APF), Hexane-Methanol-treated aqueous protein fraction (HMAPF), and Methanol-treated aqueous protein fraction (MAPF) were prepared and evaluated for antimicrobial and antiproliferative activities. In antifungal activity, HMAPF showed the lowest MIC90 values of 1.56 µg/ml against Candida parapsilosis and Candida glabrata and 3.12 µg/ml against Candida albicans and Candida auris. The antifungal activity was further confirmed by a chitinase assay, a growth kinetics and a proteinase inhibitory assay. Surprisingly, none of the three protein fractions exhibited antibacterial activity against Escherichia coli and Staphylococcus aureus. Moreover, APF exhibited potent antiproliferative and antioxidant activities with IC50 values of 18 µg/ml and 227 µg /ml, respectively. For HMAPF, an IC50 value of 70 µg/ml against the MDA-MB-231 cell line was observed. The present results demonstrate that the protein fractions, particularly HMAPF and APF, might serve as potential sources of a dual antifungal and antiproliferative protein-based drug.

Novel Strategies to Combat the Emerging Drug Resistance in Human Pathogenic Microbes.

The major health-care burden for the developing world are infectious diseases where antimicrobial agents prove to be the magical drugs to combat this. But the phenomenon of antimicrobial resistance (AMR) represents a challenging global issue, which requires to be addressed effectively. The antimicrobial treatment for the emerging multidrug-resistant bacterial (e.g. TB, Cholera) and fungal (e.g. Candidiasis) infections is very limited, and there are multiple causes and reasons responsible for the evolution of such resistance. Considering the critical issues of increasing AMR, there is an urgent requirement of the identification, development, validation, and progression of novel strategies and approaches that can easily be utilized for overcoming this serious issue. Immunotherapy represents a significant way to improve host defenses and combat the issue of antimicrobial drug resistance. Similarly, drug combination therapy represents another promising approach for reducing the evolution of resistance and enhancing the longevity of the antimicrobial agents. Bacteriophage therapy also acts as a novel therapeutic option to control the development of the multidrug resistance (MDR) phenomenon. Besides, CRISPR, an innovative genome editing technology, offers multiple applications to safeguard host defenses to overcome different resistance challenges. The novel approaches/ strategies like combination therapy, bacteriophage therapy, immunotherapy, and CRISPR/Cas discussed here presents an overview of some of the novel strategies/approaches to be adopted against the pathogenic microbes/microbial invasions along with advanced knowledge of different drug resistance mechanisms adopted by the microbial pathogens to gain resistance against different antimicrobial agents. Therefore, understanding the novel control plans/approaches and different drug resistance mechanisms will help achieve the goals of the successful development of potential antimicrobial drugs and their respective targets and eventually help curtail the problem of increasing antimicrobial drug resistance menace in various human pathogenic microbes.

MFS transporters of Candida species and their role in clinical drug resistance.

ABC (ATP-binding cassette) and MFS (major facilitator superfamily) exporters, belonging to two different superfamilies, are one of the most prominent contributors of multidrug resistance (MDR) in yeast. While the role of ABC efflux pump proteins in the development of MDR is well documented, the MFS transporters which are also implicated in clinical drug resistance have not received due attention. The MFS superfamily is the largest known family of secondary active membrane carriers, and MFS exporters are capable of transporting a host of substrates ranging from small molecules, including organic and inorganic ions, to complex biomolecules, such as peptide and lipid moieties. A few of the members of the drug/H(+) antiporter family of the MFS superfamily function as multidrug transporters and employ downhill transport of protons to efflux their respective substrates. This review focuses on the recent developments in MFS of Candida and highlights their role in drug transport by using the example of the relatively well characterized promiscuous Mdr1 efflux pump of the pathogenic yeast C. albicans.