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Antimicrobial Agents and Chemotherapy, September 2003, p. 2725-2731, Vol. 47, No. 9
0066-4804/03/$08.00+0     DOI: 10.1128/AAC.47.9.2725-2731.2003
Copyright © 2003, American Society for Microbiology. All Rights Reserved.

Recapitulation in Saccharomyces cerevisiae of Cytochrome b Mutations Conferring Resistance to Atovaquone in Pneumocystis jiroveci

Wolfson Institute for Biomedical Research, University College London, London, United Kingdom,¹ Department of Biochemistry, Dartmouth Medical School, Hanover, New Hampshire,² Department of Microbiology and Immunology, University of North Carolina, Chapel Hill, North Carolina³

Received 31 March 2003/ Returned for modification 12 May 2003/ Accepted 19 June 2003

	ABSTRACT

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Pneumocystis jiroveci (human-derived P. carinii) is an opportunistic pathogenic fungus which causes pneumonia and is life-threatening in immunocompromised individuals. Spontaneously acquired resistance to atovaquone, a hydroxynaphthoquinone that is used to treat P. jiroveci infections, was linked to mutations in the mitochondrially encoded cytochrome b gene. Because P. jiroveci cannot be easily cultivated, we have developed Saccharomyces cerevisiae as an alternative system to study atovaquone resistance mutations. In this work, we introduced seven mutations linked with atovaquone resistance in P. jiroveci into the S. cerevisiae cytochrome b gene. The effects of the mutations on the respiratory function and on the sensitivity to the inhibitor were then characterized. Six of the reported mutations lowered the sensitivity of the S. cerevisiae bc₁ complex to atovaquone, while one mutation had no effect on the drug resistance. These results were confirmed by monitoring the in vivo resistance of S. cerevisiae mutants which carried both the cytochrome b mutations and a deletion of the ABC transporter genes, allowing the drug to bypass the weakened efflux pump system. S. cerevisiae thus provides an easy-to-use system to characterize in vivo and in vitro cytochrome b mutations reported in pathogens and to assess their role in drug resistance.

	INTRODUCTION

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The mitochondrial bc₁ complex is a membrane-bound enzyme that catalyzes the transfer of electrons from ubiquinol to cytochrome c and couples this electron transfer to the vectorial translocation of proton across the inner mitochondrial membrane. The enzyme consists of 10 or 11 different polypeptides. Cytochrome b, cytochrome c₁, and the Rieske iron-sulfur protein form the catalytic core of the enzyme. The catalytic mechanism, called the Q cycle, requires two distinct quinone-binding sites (Q_o, quinol oxidation site, and Q_i, quinone reduction site) which are located on opposite sides of the membrane and linked by a transmembrane electron transfer pathway. The mitochondrially encoded cytochrome b provides the quinol and quinone binding pockets and the transmembrane electron pathway.

A number of quinol antagonists that inhibit bc₁ activity are known. They are specific for either the Q_o site, such as myxothiazol, stigmatellin, and strobilurin, or the Qi site, such as antimycin, funiculosin, and diuron. Some bc₁ inhibitors are widely used in agriculture and medicine as antiparasitic drugs. The hydroxynaphthoquinone atovaquone, for instance, is a broad-spectrum drug active against various parasitic infections, such as malaria, Pneumocystis jiroveci (human-derived P. carinii) pneumonia, and toxoplasmosis. Resistance to the drug was reported in Plasmodium spp. and Toxoplasma gondii isolated from patients who experienced a recrudescence of parasitemia after treatment with atovaquone, in parasites cultivated in vitro on selective medium, and in animals treated with the drug (8, 10, 13). Mutations in the cytochrome b gene of the pathogens were observed. These mutations were located in the Q_o binding site pocket and correlated with an increased resistance to atovaquone.

Several mutations in the cytochrome b gene of P. jiroveci from AIDS patients have also been observed. P. jiroveci pneumonia is a common severe opportunistic infection in AIDS patients and a significant cause of mortality. A cohort study on AIDS patients with P. jiroveci infection suggested that exposure to atovaquone increased the frequency of cytochrome b mutations in the fungus (7). However, it is not possible to demonstrate a direct relationship between these cytochrome b mutations and the acquired resistance to atovaquone because P. jiroveci cannot be cultivated in medium or isolated in sufficient quantities for enzyme assay. Therefore, we developed Saccharomyces cerevisiae as a model organism to study the effects of the mutations observed in the fungus.

In this work, seven P. jiroveci mutations of conserved residues located in the Q_o site of cytochrome b, T127I, I147V, T148I, L150F, S152A, P266L, and L275F (Fig. 1 and 2), were introduced into S. cerevisiae cytochrome b. The S. cerevisiae mutants were then used to assess the effect of these mutations on atovaquone resistance.

View larger version (72K): [in this window] [in a new window]   FIG. 1. Sequence alignment of S. cerevisiae (Sc), P. jiroveci, and human-derived P. carinii (Pc) mitochondrial cytochrome b. Point mutations discussed in this paper are boxed in bold lines. Residues in close contact with stigmatellin in the S. cerevisiae bc1 complex crystal structure 1EZV (defining the Qo site) are indicated by a grey line above the sequence data. Residues corresponding to the tester mutations A144F and L263stop are circled.

View larger version (47K): [in this window] [in a new window]   FIG. 2. Location of atovaquone resistance mutations in the bc1 structure. The structure was drawn with the coordinates of the S. cerevisiae enzyme (accession number PDB 1EZV) (6). The bound inhibitor stigmatellin is in green.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results and Discussion References

The following S. cerevisiae strains were used for transformation and screening: the recipient strain for biolistic transformation was W303-1B/rho⁰ (MAT ura3 his3 leu2 ade2 trp1); the mit^- tester strains CKB78 (CYTB A144F) and CKL57 (CYTB L263Stop) were MATa leu1 kar1-1 with a rho⁺ intronless mitochondrial DNA. JC8/56 (MATa leu1 kar1-1 rho⁰) was used for cytoduction. Strains carrying single deletions of YOR1, SNQ2, PDR5, PDR10, PDR11, YCF1, PDR3, PDR15, and PDR1 were obtained from Euroscarf (http://www.uni-frankfurt.de/fb15/mikro/euroscarf/). The strain AD1-9, harboring multiple deletions (MATa ura3 his1 yor1::hisG snq2::hisG pdr5::hisG pdr10::hisG pdr11::hisG ycf1::hisG pdr3::hisG pdr15::hisG pdr1::hisG) (4) was kindly given by M. Ghislain (UCL, Belgium). These strains were used to monitor atovaquone sensitivity in vivo. AD1-9/rho0 was obtained by ethidium bromide treatment.

2,3-Dimethoxy-5-methyl-n-decyl-1,4-benzoquinol and myxothiazol were purchased from Sigma. Stigmatellin was purchased from Fluka. Atovaquone was obtained from Glaxo-Wellcome.

Site-directed mutagenesis, biolistic transformation, and selection of mitochondrial mutants. Plasmid pBM5 carrying the wild-type intronless sequence of the CYTB gene was constructed by blunt-end cloning of a PCR product of CYTB into the pCRscript vector (Stratagene). The mutagenesis was performed with the Quickchange site-directed mutagenesis kit (Stratagene) according to the manufacturer's recommendations. After verification of the sequence, the plasmids carrying the mutated genes were used for biolistic transformation.

Mitochondrial transformation by microprojectile bombardment was adapted from reference 1. Approximately 3 µg of the plasmids carrying the mutated CYTB genes and 0.5 µg of plasmid YEP352 (which contains the URA3 gene, allowing the selection of Ura⁺ nuclear transformants) were mixed with 50 µl of 0.7-µm tungsten particles (at a concentration of 60 mg/ml). The particles (supplied by Bio-Rad) were prepared and coated with DNA according to the manufacturer's protocol. Aliquots of the coated particles were used for transformation of the recipient strain W303-1B/rho⁰. Around 10⁷ cells of the recipient strain were evenly spread on transformation medium (selective for Ura⁺ transformants). The particle bombardments were performed with a Biolistic PDS-1000/He particle delivery system (Bio-Rad) according to the manufacturer's recommendations.

Colonies of Ura⁺ transformants (which have received plasmid YEP352) appeared after 4 to 5 days of incubation. The Ura⁺ colonies were crossed with respiratory-deficient (mit^-) tester strains CKB78(A144F) and CKL57(L263Stop), which carry mutations located near the atovaquone resistance mutations (Fig. 1). CKB78(A144F) was used for mutations in residues 127 to 152, whereas CKL57(L263Stop) was used for mutations in residues 266 and 275. The diploids were replica-plated on respiratory medium (YPG). Since the tester deficiency mutations could be corrected by recombination with the plasmid-derived mitochondrial sequence, mitochondrial transformants were identified by their ability to form respiration-competent diploids when crossed with the tester strains. Respiration-competent diploids that issued from the crossing were selected and subcloned. Their sequencing showed that the new mutations were incorporated while the tester mutations were replaced by the wild-type codon.

Construction of S. cerevisiae strains with combined atovaquone resistance mutations and deletion of membrane transporters. The mitochondrial genome carrying the atovaquone resistance mutations was transferred into strain AD1-9 as follows. The mitochondrial transformants which carried the atovaquone resistance mutations were sporulated. The haploid clones were used for cytoduction of the mitochondrial genome into the recipient strain JC8/56 (rho⁰). This strain carries the mutation kar1-1, which is required for cytoduction (3). These cytoductants were then used to transfer the mitochondrial genome into AD1-9/rho⁰. The resulting strains combined atovaquone mutations and multiple deletions in the membrane transporters and were used to monitor atovaquone resistance in vivo.

Preparation of mitochondrial membrane, cytochrome c reductase activity, and inhibitor titrations. Mitochondrial membranes were isolated as described before (12). Cytochrome c reductase activity measurements were assayed in 50 mM potassium phosphate (pH 7.0), 250 mM sucrose, 0.2 mM EDTA, 1 mM NaN₃, 2.5 mM KCN, 0.01% Tween 20, and 40 µM cytochrome c (assay buffer) at 23°C. Membranes were diluted to 2.5 nM cytochrome bc₁ complex. The reaction was started by adding 50 µM 2,3-dimethoxy-5-methyl-n-decyl-1,4-benzoquinol, an analogue of ubiquinol. Reduction of cytochrome c was monitored in an Aminco DW-2a spectrophotometer at 550 versus 539 nm in dual-wavelength mode. Data were collected and analyzed with an Online Instrument Systems Inc. computer interface and software. Activities of the bc₁ complex in membranes were measured in duplicate, and turnover numbers were calculated on the basis of cytochrome b concentration. The cytochrome b content was estimated from reduced minus oxidized spectra, with the extinction coefficient 25 mM^-1 cm^-1 at 562 to 572 nm.

Spectroscopic analysis of cytochromes in whole cells. Spectra were generated by scanning cell suspensions with a single-beam spectrophotometer built in-house. The cells, grown on YPG plates for 48 h, were resuspended in 5% Ficoll at a concentration of around 200 mg of cells per ml and reduced with dithionite. A quadratic baseline compensation was carried out on the data as described before (2) to remove the distortion of the baseline.

	RESULTS AND DISCUSSION

Top Abstract Introduction Materials and Methods Results and Discussion References

 
Generation of S. cerevisiae mutants harboring cytochrome b mutations observed in P. jiroveci. Several mutations in the cytochrome b gene of P. jiroveci were reported following exposure to atovaquone. The mutations T127I, I147V, T148I, L150F, S152A, P266L, and L275F (S. cerevisiae numbering) are located in the Q_o binding site (Fig. 1 and 2). Because P. jiroveci cannot be cultivated in medium, a model organism is needed to assess the role of the mutations in atovaquone resistance. S. cerevisiae is the obvious choice. S. cerevisiae is amenable to mitochondrial transformation, so that designed mutations can be introduced in the mitochondrially encoded cytochrome b. In addition, the sequences of cytochrome b from S. cerevisiae and P. jiroveci are highly similar (63% identity), as shown in Fig. 1. The P. jiroveci mutations were therefore introduced into S. cerevisiae by the biolistic technique as described in Materials and Methods. The effects of the mutations on respiratory competence and resistance to inhibitor were then monitored.

Effect of mutations on respiratory competence. The growth rate of the wild-type and mutant strains in respiratory medium (YPG) was monitored. The mutations had no effect on the respiratory competence of the cells, since the doubling times on a nonfermentable carbon source of the control and mutant strains were identical (5 h). Similarly, no significant decrease in oxygen consumption was observed in the mutant cells (data not shown). Analysis of the optical signal of the cytochromes in whole cells showed a slight decrease in the cytochrome b content in the mutants compared with the wild-type strain. The cytochrome b level was decreased by approximately 15% in all the mutants except T148I, where the cytochrome b content was decreased by approximately 30%. Figure 3 shows the optical spectra of the wild-type strain and two mutants: T148I, which had a low cytochrome b content, and I147V. The optical spectra of the remaining mutants were almost identical to that of I147V. Thus, it seems that the introduction of the mutations slightly affect the folding of cytochrome b and/or the assembly of acomplex.

View larger version (29K): [in this window] [in a new window]   FIG. 3. Optical spectra of wild-type, L148I, and L147V cells. Optical spectra of reduced cell suspensions were obtained as described in Materials and Methods. c, cytochrome c (heme c); b, cytochrome bc1 (hemes b); a, cytochrome oxidase (hemes aa3).

The decrease in both cytochrome b content and bc₁ activity in the mutant cells was not enough to affect the respiratory growth of the mutants. The introduction of these mutations had little or no effect on the overall fitness of these strains. It is likely that the mutations do not have severely deleterious effects in P. jiroveci, because a major decrease in respiratory competence would be lethal for the fungus.

Effect of mutations on sensitivity of bc₁ complex to atovaquone. In order to assess the role of the mutations on atovaquone resistance, mitochondrial membranes were prepared from the wild-type and mutant strains, as described above, and the cytochrome c reductase activity was monitored in the presence of increasing concentrations of atovaquone (Fig. 4). Atovaquone is an efficient inhibitor of the S. cerevisiae bc₁ complex because the inhibitor concentration required for 50% inhibition of the activity (I₅₀) was around 50 nM. This was in agreement with data obtained with other organisms and with other methods: the concentration required for a 50% decrease in the membrane potential in Plasmodium yoelii was 15 nM (13), and a 50% decrease in nucleic acid synthesis activity was observed in the presence of 20 and 50 nM atovaquone in Plasmodium berghei and Toxoplasma gondii, respectively (14, 10).

View larger version (21K): [in this window] [in a new window]   FIG. 4. Effect of atovaquone on bc1 activity of wild-type (wt) parental and mutant strains. The cytochrome c reductase activity of mitochondrial membranes was measured as described in Materials and Methods in the presence of increasing concentrations of inhibitor. The assays were performed in duplicate, and the results are shown as averages, with less then 10% variation in individual rates. Activities are expressed as a percentage of the turnover number of each strain in the absence of atovaquone.

It is interesting that the P. jiroveci mutations studied here are located in or close to the inhibitor binding regions (Fig. 1). It was therefore expected that they might modify the sensitivity of the bc₁ complex to atovaquone. In addition, mutations of residues L275 and I147, conferring resistance to other Q_o inhibitors in S. cerevisiae, were reported previously (5). As shown in Fig. 4, three mutants, T148I, I147V, and L150F, showed a slight decrease in sensitivity to atovaquone. The I₅₀ increased to approximately 100 to 150 nM. Three mutants, P266L, L275F, and S152A, showed a marked resistance, with I₅₀s higher than 350 nM. Surprisingly, T127I did not show any increased resistance to atovaquone.

The threefold increase in resistance observed with the L150F mutant is undoubtedly due to steric hindrance arising from the bulky aromatic side chain of the introduced phenyl group. Similarly, P266L and L275F, which confer high atovaquone resistance, result in the introduction of bulkier nonpolar side chains, which may sterically hinder antagonist binding. I147V represents a conservative structural change. The loss of a side chain methylene moiety may remove a potentially stabilizing hydrophobic interaction with atovaquone bound at the Q_o site or may subtly affect the packing of the protein around this region, which forms a tunnel for access to the lipid phase. The mutations S152A and T148I both result in replacement of a residue with a polar, hydroxylated side chain by a nonpolar, aliphatic species, although the resistance of S152A is much higher than that of T148I. It is possible that the mutations abolish hydrogen bond interactions involving S152 or T148 and result in slight structural rearrangement of components within the Q_o site. Molecular modeling studies with minimum energy calculations to assess structural changes in the protein resulting from the resistance mutations are currently in progress.

Because of the high similarity between S. cerevisiae and P. jiroveci cytochrome b, it is expected that the mutations have similar effects on the pathogen's bc₁ complex. The mutation T127I probably has little effect on the bc₁ sensitivity to atovaquone in P. jiroveci. As shown above, this mutation also had little effect on the activity of the complex. It is tempting to suggest that the change is a silent mutation. The mutations I147V, T148I, and L150F would confer a slight advantage to the mutant fungi when exposed to atovaquone, whereas the mutations P266L, L275F, and S152A would cause a marked resistance to treatment with the drug.

Sensitivity of S. cerevisiae cells to atovaquone treatment. As shown in Fig. 4, the molecular target of atovaquone, the bc₁ complex, is inhibited by submicromolar concentrations of atovaquone. However, S. cerevisiae is naturally resistant to the drug. At 50 µM atovaquone, no decrease in respiratory growth was observed for the control strain (Fig. 5). Since it was likely that the resistance of the S. cerevisiae cells to atovaquone treatment was due to efficient efflux pumps, we monitored the sensitivity of strains harboring deletions of genes involved in drug resistance, namely YOR1, SNQ2, PDR5, PDR10, PDR11, YCF1, PDR3, PDR15, and PDR1. These genes are members of gene families which, in mammalian cells, are involved in the resistance of tumor cells to anticancer treatment. Similar mechanisms exist in pathogenic fungi, such as Candida and Aspergillus spp. (11, 15). PDR1 and PDR3 code for transcriptional regulators. Yor1p, Snq2p, Pdr5p, Pdr10p, Pdr11p, Ycf1p, and Pdr15p are ABC transporters (reviewed in reference 16). These plasma membrane transporters, especially Pdr5p and Snq2p, mediate the ATP-dependent efflux of a large number of unrelated compounds.

View larger version (83K): [in this window] [in a new window]   FIG. 5. Sensitivity of S. cerevisiae cells to atovaquone exposure. The name and position of the strains tested are shown above the plates. YOR1, YCF1, PDR3, SNQ2, PDR15, PDR10, PDR1, PDR5, and PDR11 are strains carrying single deletions of genes of the ABC transporter family; AD1-9 carries deletions of all these genes (left-hand panels). The right-hand panels show the growth of AD1-9 and the seven strains derived from AD1-9 which carry cytochrome b mutations. WT, wild type.

The multiple deletion of genes involved in multidrug resistance resulted in an increased sensitivity to atovaquone. The AD1-9 strain, which combines the inactivation of the ABC transporters and a wild-type cytochrome b, was indeed unable to grow in the presence of atovaquone. This hypersensitive strain could then be used to monitor in vivo the drug resistance caused by cytochrome b mutations. For this purpose, the seven mutant strains and a parental (wild-type) strain were constructed as described in Materials and Methods. They derived from AD1-9 but harbored the P. jiroveci cytochrome b mutations mentioned above. As shown in Fig. 5, T127I did not confer any resistance to the drug, whereas the other mutations resulted in clear resistance to the inhibitor. These data are in agreement with the results obtained in our in vitro studies. Such S. cerevisiae strains could be useful tools to screen new compounds and to test the cross-resistance of existing mutants.

In conclusion, we have shown here that S. cerevisiae provides an easy-to-use system to characterize cytochrome b mutations observed in pathogens and to assess their role in drug resistance. Since S. cerevisiae is amenable to mitochondrial transformation, mutations found in cytochrome b in pathogens can be introduced into the S. cerevisiae mitochondrial gene. In addition, the availability of strains with multiple deletions of membrane transporters allows the in vivo study of drug resistance. The characterization of the resistance mutations in the pathogens and in model organisms such as S. cerevisiae could provide molecular markers to monitor the potential resistance of pathogens and screening tools for new inhibitors.

	ACKNOWLEDGMENTS

 
This work was supported by a Medical Research Fellowship and a BBSRC grant to B.M. and by National Institutes of Health grants AI46966 to S.M. and GM20379 to B.L.T. P.H. has a BBSRC Studentship.

	FOOTNOTES

 
* Corresponding authors. Mailing address for B. Meunier: Wolfson Institute for Biomedical Research, University College London, London, United Kingdom. Phone: 44 20 7679 6860. Fax: 44 20 7679 6860. E-mail: b.meunier{at}ucl.ac.uk. Mailing address for B. L. Trumpower: Department of Biochemistry, Dartmouth Medical School, Hanover, N.H. E-mail: Trumpower{at}Dartmouth.edu.

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