Folic acid utilisation related to sulfa drug resistance in Saccharomyces cerevisiae.

Saccharomyces cerevisiae mutants deficient in folate synthesis have been constructed and employed to study the utilisation of exogenous folates in yeast. One mutant specifically lacked dihydropteroate synthase while the second lacked dihydrofolate synthase. Exogenous folinic acid restored optimal growth to both strains. Folic acid did not generally rescue growth but spontaneous isolates capable of utilising folic acid were selected. The folic acid synthesis pathway in the folate utilising isolates was restored via transformation with FOL1 or FOL3 expression plasmids and transformants were tested for resistance to sulfamethoxazole (SMX). The presence of elevated levels of folic acid led to greatly reduced SMX sensitivity regardless of whether strains were folate utilisers or not.

Novel alleles of the Plasmodium falciparum dhfr highly resistant to pyrimethamine and chlorcycloguanil, but not WR99210.

We have expressed dhfr alleles of Plasmodium falciparum in the budding yeast, Saccharomyces cerevisiae, and used this yeast model to identify single amino acid substitutions that confer high level pyrimethamine resistance on the background of the triple mutant dhfr (I51+R59+N108). Mutations in three clusters were identified: codons 50-57, 187-193, and 213-214. Several mutations previously identified in field samples were also isolated, including codons 50 and 164. The I164L mutation is of particular interest, because the quadruple mutant genotype (N51I+C59R+S108N+I164L) encodes an enzyme that is no longer inhibited by pyrimethamine, rendering sulfadoxine/pyrimethamine (SP; Fansidar) clinically ineffective. Thirty-six novel alleles were tested to determine their sensitivity to chlorcycloguanil and WR99210, two DHFR inhibitors that are in clinical and pre-clinical development, respectively. Chlorcycloguanil is effective against parasites that carry the triple mutant allele, but in vitro analysis has suggested that chlorcycloguanil will be clinically ineffective against parasites that carry the quadruple mutant allele of dhfr. In our screen, 23 of 36 novel strains were as resistant to chlorcycloguanil as the quadruple mutant, and one strain was 10-fold more resistant. WR99210 is still effective in the nM range against parasites that carry the quadruple mutant allele. In the preliminary screen, 31 of 36 novel alleles were as sensitive to WR99210 as the quadruple mutant. Detailed analysis of the remaining five showed that four of the five had IC(50) values in the same range as the quadruple mutant, and one, N51I+C59R+S108N+E192G, had an IC(50) value about fivefold higher. This result suggests that WR99210 and related compounds will be clinically effective against quadruple mutants currently found in Southeast Asia and South America and against most novel alleles that could be selected on the background of the triple mutant genotype now prevalent in East Africa.

Yeast as a model system to study drugs effective against apicomplexan proteins.

Biochemical and genetic analyses are required to identify potential drug targets in apicomplexan parasites, but these studies have proved difficult in most parasite systems. We have developed methods based on expression of parasite proteins in the budding yeast, Saccharomyces cerevisiae, to rapidly screen drugs directed against particular parasite targets, to study the structure and function of these target molecules, and to identify mutations in the parasite genes that alter enzyme specificity or drug sensitivity. In this paper we outline the parameters that need to be considered to design yeast strains that function efficiently to assay function of parasite proteins. Basic protocols and methods are included. We detail some problems that might be encountered in the engineering of these yeast strains and suggest possible solutions.