Construction and Use of a Recyclable Marker To Examine the Role of Major Facilitator Superfamily Protein Members in Candida glabrata Drug Resistance Phenotypes.

Aaron P. Mitchell,Bao G. Vu,W. Scott Moye-Rowley

doi:10.1128/msphere.00099-18

Abstract

Candida glabrata is the second most common species causing candidiasis. C.glabrata can also readily acquire resistance to azole drugs, complicating its treatment. Here we add to the collection of disruption markers to aid in genetic analysis of this yeast. This new construct is marked with a nourseothricin resistance cassette that produces an estrogen-activated form of Cre recombinase in a methionine-regulated manner. This allows eviction and reuse of this cassette in a facile manner. Using this new disruption marker, we have constructed a series of strains lacking different members of the major facilitator superfamily (MFS) of membrane transporter proteins. The presence of 15 MFS proteins that may contribute to drug resistance in C.glabrata placed a premium on development of a marker that could easily be reused to construct multiple gene-disrupted strains. Employing this recyclable marker, we found that loss of the MFS transporter-encoding gene FLR1 caused a dramatic increase in diamide resistance (as seen before), and deletion of two other MFS-encoding genes did not influence this phenotype. Interestingly, loss of FLR1 led to an increase in levels of oxidized glutathione, suggesting a possible molecular explanation for this enhanced oxidant sensitivity. We also found that while overproduction of the transcription factor Yap1 could suppress the fluconazole sensitivity caused by loss of the important ATP-binding cassette transporter protein Cdr1, this required the presence of FLR1. IMPORTANCE Export of drugs is a problem for chemotherapy of infectious organisms. A class of membrane proteins called the major facilitator superfamily contains a large number of proteins that often elevate drug resistance when overproduced but do not impact this phenotype when the gene is removed. We wondered if this absence of a phenotype for a disruption allele might be due to the redundancy of this group of membrane proteins. We describe the production of an easy-to-use recyclable marker cassette that will allow construction of strains lacking multiple members of the MFS family of transporter proteins.

Highlights

IMPORTANCE Export of drugs is a problem for chemotherapy of infectious organisms
Studies from many laboratories have demonstrated that the elevated transcription of ABC transporter-encoding genes like CDR1 is the cause of the enhanced azole resistance of strains containing GOF variants of PDR1 [4,5,6,7]
Further applying our new loxPcre-estradiol-binding domain (EBD) recyclable system into C. glabrata genetics, we found that C. glabrata CAGL0H06017g, a homolog of S. cerevisiae FLR1, has a significant role in oxidative stress and fluconazole resistance of the organism

Summary

Introduction

A class of membrane proteins called the major facilitator superfamily contains a large number of proteins that often elevate drug resistance when overproduced but do not impact this phenotype when the gene is removed. C. glabrata typically acquires azole resistance primary through gain-of-function (GOF) mutations in gene encoding a zinc cluster-containing transcription factor called Pdr1 [3,4,5]. Data exist that argue these GOF forms of Pdr enhance virulence of strains containing these mutant transcription factors [8] Another class of membrane transporter protein found to be involved in drug resistance includes members of the major facilitator superfamily (MFS) class of proteins (reviewed in reference 9). One possible explanation for this phenotypic difference is the presence of multiple MFS proteins with redundant physiological roles

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