Studium účinku antimikrobiálních peptidů na Saccharomyces cerevisiae a další druhy kvasinek / The effect of antimicrobial peptides on Saccharomyces cerevisiae and other yeast species

Makarova, Anna-Marie

January 2018

The increased use of antibiotics, antifungal agents and disinfectants in the last decades has resulted in development of microbial resistance to these drugs. Candida species are the fourth most common cause of hospital-acquired bloodstream infection and kill 40% of those patients. Natural antimicrobial peptides are promising candidates for the development of new agents to treat yeast and bacterial infections, as their presumed mechanism of action differs significantly from the mechanism of action of current drugs. This work is focused on several peptides isolated from the venom of wild bees and their synthetic analogues and the identification of the most effective ones against non-pathogenic Saccharomyces cerevisiae and several pathogenic Candida species. Antifungal activity of eight cationic antimicrobial peptides was tested and compared under various conditions. The overall susceptibility of pathogenic yeast species to currently used antifungal drugs and the antimicrobial peptides was screened with the aim to identify potential synergistic and species-specific effects. The effect of antimicrobial peptides on membrane potential was measured by a fluorescent probe (diS-C3(3)), and the relative hyperpolarization of plasma membrane was shown for each peptide. The effect of antimicrobial peptides on...

THE ROLE OF SET1 MEDIATED HISTONE H3K4 METHYLATION IN ANTIFUNGAL DRUG RESISTANCE AND FUNGAL PATHOGENESIS IN CANDIDA SPECIES

Kortany M. Baker (13775098)

14 September 2022

<p>  </p> <p>Fungal pathogens are an increasing threat to humans, plants, and animals worldwide. Death and disease caused by fungal pathogens results in the loss of over 1.5 million lives, 12 million tons of crops, and even entire species every year. <em>Candida </em>species are the leading cause of invasive fungal species lead by <em>Candida albicans, </em>and <em>Candida glabrata </em>in second. <em>Candida glabrata </em>intrinsically has a low susceptibility to azole treatment, and multidrug resistant isolates are becoming more common. Additionally, new emerging <em>Candida </em>species have been found, and most clinical isolates are resistant to one or more drugs. There is a critical need to better understand drug resistance and pathogenesis to generate new therapies. </p> <p>Drug resistance can be caused by several different genetic factors, but until recently epigenetic factors have been frequently overlooked. Epigenetic research has revolutionized the treatment and detection of many cancers. And now, early research has shown epigenetic mechanisms play a role in drug resistance and pathogenesis in fungal species. Limited resources exist to combat fungal infections and understanding the epigenetic mechanisms that contribute to drug resistance and pathogenicity will provide new drug targets for future treatment.</p> <p>Previous publications from the Briggs’ lab showed Set1-mediated histone H3K4 methylation was necessary for proper ergosterol homeostasis and Brefeldin A resistance. One of the three classes of antifungals, azoles, target the ergosterol pathway. The ergosterol connection resulted into this thesis project, investigating the role of Set1-mediated histone H3K4 methylation in drug resistance and pathogenicity in <em>Saccharomyces cerevisiae, Candida glabrata, Candida albicans, </em>and <em>Candida auris. </em>This research was the first to characterize the Set1 complex in <em>C. glabrata </em>and show it is the sole histone H3K4 methyltransferase in <em>C. glabrata </em>and <em>C. auris. </em>Additionally, it shows loss of <em>SET1 </em>in <em>C. glabrata </em>and <em>C. auris </em>reduces pathogenicity and alters drug efficacy. Interestingly, although the loss of <em>SET1</em> seems to cause a similar pathogenic defect in all three <em>Candida </em>species, the role Set1 plays in drug efficacy including which drug and severity varies amongst species and isolates. Altogether, this research project provides new possible drug targets for fungal treatment and knowledge added to the scientific community on the role of epigenetics in fungal pathogens. </p>

Microbial genetics

SET1

Ergosterol

Sterol

ERG11

Candida

Candida glabrata

Candida auris

Candida albicans

Galleria mellonella

Survival

Fungal pathogens

Drug Resistance

Azoles

Echinocandins

Saccharomyces cerevisiae Eukaryotes