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Antimicrobial Agents and Chemotherapy, October 2001, p. 2676-2684, Vol. 45, No. 10
0066-4804/01/$04.00+0 DOI: 10.1128/AAC.45.10.2676-2684.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Prevalence of Molecular Mechanisms of Resistance to
Azole Antifungal Agents in Candida albicans Strains
Displaying High-Level Fluconazole Resistance Isolated from Human
Immunodeficiency Virus-Infected Patients
Sofia
Perea,1
José L.
López-Ribot,1,*
William
R.
Kirkpatrick,1
Robert K.
McAtee,1
Rebecca A.
Santillán,1
Marcos
Martínez,1
David
Calabrese,2
Dominique
Sanglard,2 and
Thomas F.
Patterson1,3
Department of Medicine, Division of Infectious Diseases,
The University of Texas Health Science Center at San
Antonio,1 and Audie L. Murphy
Division, South Texas Veterans Health Care
System,3 San Antonio, Texas, and
Centre Hospitalier Universitaire Vaudois, Lausanne,
Switzerland2
Received 28 March 2001/Returned for modification 22 May
2001/Accepted 18 June 2001
 |
ABSTRACT |
Molecular mechanisms of azole resistance in Candida
albicans, including alterations in the target enzyme and
increased efflux of drug, have been described, but the epidemiology of
the resistance mechanisms has not been established. We have
investigated the molecular mechanisms of resistance to azoles in
C. albicans strains displaying high-level fluconazole
resistance (MICs, 
64 µg/ml) isolated from human immunodeficiency
virus (HIV)-infected patients with oropharyngeal candidiasis. The
levels of expression of genes encoding lanosterol 14
-demethylase
(ERG11) and efflux transporters (MDR1 and
CDR) implicated in azole resistance were monitored in matched
sets of susceptible and resistant isolates. In addition, ERG11 genes were amplified by PCR, and their nucleotide
sequences were determined in order to detect point mutations with a
possible effect in the affinity for azoles. The analysis confirmed the multifactorial nature of azole resistance and the prevalence of these
mechanisms of resistance in C. albicans clinical
isolates exhibiting frank fluconazole resistance, with a predominance
of overexpression of genes encoding efflux pumps, detected in 85% of
all resistant isolates, being found. Alterations in the target enzyme,
including functional amino acid substitutions and overexpression of the
gene that encodes the enzyme, were detected in 65 and 35% of the
isolates, respectively. Overall, multiple mechanisms of resistance were
combined in 75% of the isolates displaying high-level fluconazole
resistance. These results may help in the development of new strategies
to overcome the problem of resistance as well as new treatments for
this condition.
| |
INTRODUCTION |
In Candida
albicans fluconazole resistance is a multifactorial process
mediated through multiple underlying mechanisms (4, 7, 8, 18, 34,
36, 42). Resistance can be the result of an alteration of the
target enzyme, the cytochrome P-450 lanosterol 14-demethylase
(Erg11p), either by overexpression or as a result of point mutations in
the gene that encodes it (ERG11) (3, 6, 7, 12, 14, 15,
16, 20, 33, 37, 41). The former creates the need for a higher
intracellular azole concentration to complex all the enzyme molecules
present in the cells, and the latter leads to amino acid substitutions,
resulting in a decreased affinity for azole derivatives. A second major
mechanism is failure of azole antifungal agents to accumulate inside
the yeast cell as a consequence of enhanced drug efflux. This mechanism
is mediated by two types of multidrug efflux transporters, the major
facilitators (encoded by multidrug resistance genes) and those
belonging to the ATP-binding cassette superfamily (ABC transporters,
encoded by CDR genes). Upregulation of the CDR genes appears to
confer resistance to multiple azoles, whereas upregulation of the
MDR1 gene alone leads to fluconazole resistance exclusively
(1, 18, 19, 22, 26, 30-32, 38-40).
These different molecular mechanisms implicated in the development of
resistance to fluconazole have previously been described for a limited
number of isolates by us and others by analyzing serial isolates from
the same patient with decreasing susceptibility to the drug (18,
30, 40, 41; D. C. Calabrese, J. Bille, and D. Sanglard,
Abstr. 5th Int. Meeting Candida Candidiasis, abstr. C55, p. 63, 1999).
However, the relative prevalence of these mechanisms in clinical
isolates displaying high-level fluconazole resistance is not known. In
the study described here, we have evaluated the molecular mechanisms
responsible for azole resistance in 20 C. albicans clinical
isolates displaying high-level fluconazole resistance (MICs, 64
µg/ml) obtained from 12 different human immunodeficiency virus
(HIV)-infected patients with oropharyngeal candidiasis (OPC).
(This work was partially presented at the 39th Interscience Conference
on Antimicrobial Agents and Chemotherapy, San Francisco, Calif., 26 to
29 September 1999.)
| |
MATERIALS AND METHODS |
Isolates.
Clinical samples were obtained from HIV-infected
patients enrolled in a prospective clinical study of OPC at the
University of Texas Health Science Center at San Antonio and the Audie
L. Murphy Division, South Texas Veterans Health Care System, San Antonio (27, 28). At the time of initial isolation, oral
samples were plated on RPMI and CHROMagar Candida (CHROMagar Company, Paris, France) media with fluconazole (8 and 16 µg/ml) and without fluconazole to maximize detection of resistant yeasts, as described previously (24, 25). The identities of the clinical
isolates were confirmed by standard biochemical and microbiological
procedures, including assessment of carbohydrate assimilation patterns
(API 20 C; Biomerieux, Marcy l'Etoile, France), germ
tube formation in serum-containing medium, and the colors of the
colonies in chromogenic medium (CHROMagar Candida). Initial fluconazole
susceptibility testing was performed by an NCCLS methodology, and
C. albicans isolates were considered resistant if the
fluconazole MIC was 64 µg/ml (23, 29). Isolates
were stored at room temperature as suspensions in sterile water and
were subcultured onto plates containing Sabouraud dextrose agar 48 h prior to propagation in YEPD medium (2% yeast extract, 1% peptone,
2% glucose).
DNA-typing techniques for strain identification.
Strain
identity was established by karyotyping, restriction fragment length
polymorphism analysis, and fingerprinting analysis with the moderately
repetitive Ca3 probe, as described before (17-19). The
resulting banding patterns were analyzed visually and by using
computer-assisted methods (Dendrom; Solltech Inc., Oakdale, Iowa)
(35).
Antifungal drug susceptibility testing.
Testing of
susceptibility to fluconazole (Pfizer Inc., Sandwich, United Kingdom),
itraconazole (Janssen Pharmaceutica, Beerse, Belgium), voriconazole
(Pfizer Inc.), posaconazole (SCH56592; Schering Plough, Kenilworth,
N.J.), and amphotericin B (Bristol-Myers Squibb, Princeton, N.J.) was
performed by an NCCLS methodology by a broth microdilution method
(23, 29).
Northern blot analysis.
The different isolates were
propagated in YEPD medium and harvested while growing in antifungal
drug-free medium at the logarithmic phase at an approximate cell
density of 7.5 × 107 cells/ml. Total RNA
was obtained with the RNAeasy mini kit (Qiagen Inc., Valencia, Calif.)
following the manufacturer's instructions. Equal amounts
(approximately 5 µg) of RNA, as determined by
A260 measurements, were separated by
electrophoresis and subsequently transferred to nylon membranes
(Nytran; Schleicher & Schuell, Keene, N.H.). Probes specific for the
ERG11, MDR1, and CDR genes were purified from
plasmids containing inserts of the respective genes, as described
before (18). Probes specific for the CDR1 and
CDR2 genes were prepared as described by Sanglard and
colleagues by PCR amplification from plasmids containing these
sequences (18, 32). All probes were labeled by random
priming (Random Primers DNA Labeling System; Gibco-BRL, Gaithersburg,
Md.), and hybridizations were performed with Rapid-hyb buffer (Amersham Life Science Inc., Arlington Heights, Ill.). After hybridization, the
blots were washed by using high-stringency conditions and were exposed
to autoradiography film (Kodak, Rochester, N.Y.) overnight at room
temperature. The nylon membranes were probed sequentially with the
different probes following stripping of the previously bound probe. For
densitometric analysis, autoradiograms were scanned with the Adobe
Photoshop program (Adobe Systems Inc., Mountain View, Calif.), and the
signals were quantified with Dendron software (Solltech Inc.). Relative
values were adjusted for differences in sample loading on the basis of
quantification of 18S rRNA levels. A twofold increase in the
densitometric values compared to the values obtained for the
corresponding matched susceptible isolate was arbitrarily considered
significant (upregulation).
PCR amplification and sequencing.
The ERG11 genes
encoding lanosterol l4-demethylase from all isolates were amplified
by PCR. Briefly, genomic DNA was extracted with YeaStar Genomic DNA
(Zymo Research, Orange, Calif.) and was used as a template for
amplification of ERG11 genes. PCR was carried out with
high-fidelity Pwo DNA polymerase (Boehringer Mannheim, GmbH,
Mannheim, Germany) with the following primers: 5'-GTT GAA ACT GTC
ATT GAT GG (forward) and 5'-TCA GAA CAC TGA ATC GAA AG (reverse). Amplicons were purified with a QIAquick PCR
purification kit (Qiagen Inc., Valencia, Calif.), and the nucleotide
sequences for both strands were determined by primer elongation with an automated DNA sequencer (Applied Biosystems, Foster City, Calif.). Sequence data were compared to a published ERG11 sequence by
using the BLAST program (2, 13).
Functional expression of C. albicans PCR-amplified
ERG11 alleles in S. cerevisiae
Saccharomyces cerevisiae YKKB-13 (MAT
ura3-52
lys2-801amber
ade-101ochreI
trp1-
63his3-200
leu2-1pdr5::TRP1),
which is defective in the ATP-binding cassette transporter and which is
therefore hypersusceptible to azole derivatives, was used for the
expression of C. albicans ERG11 genes in YEp51 plasmids.
YEp51 is a 2µm-based vector that contains a GAL10
promoter for inducible heterologous gene expression. S.
cerevisiae YKKB-13 cannot grow on galactose, which is required for GAL10 induction, but it can grow on raffinose;
therefore, both carbon sources were added to the same medium to ensure
the simultaneous occurrence of growth of S. cerevisiae
and induction of the GAL10 promoter. For the cloning of
ERG11 genes from C. albicans isolates,
the strategy developed by Sanglard et al. was followed
(33). Briefly, the ERG11 genes were cloned
from the genomic DNAs of the C. albicans isolates by PCR
as described above. DNA was first extracted and used as a
template for amplification of ERG11 alleles. PCR was
carried out with high-fidelity Pwo DNA polymerase
(Boehringer Mannheim) by using primers that span the entire
ERG11 open reading frame flanked with
BamHI and SalI restriction sites to allow
the subcloning of amplified ERG11 fragments into YEp51
precut by the same enzymes (33). For each PCR with genomic DNA of a C. albicans isolate, at least 10 ERG11 expression plasmids were obtained. Plasmids were
then transformed into S. cerevisiae YKKB-13 by a lithium
acetate method in noninducing yeast nitrogen broth (YNB) medium
with glucose as a carbon source. The expression of Erg11p was verified
by growth of the Leu+ transformant in inducing YNB
selective medium with galactose and raffinose as carbon sources. Then,
disk diffusion assays with fluconazole were performed with S.
cerevisiae transformants in raffinose-galactose YNB
selective medium. The following considerations were taken into
account when comparing the diameters of matched susceptible-resistant
isolates with the controls: if in the disk assays the diameters between
the isogenic susceptible and resistant isolates are similar between the
isolates as well similar to that for the susceptible control strain,
the mutation(s) present in the ERG11 genes from
azole-resistant or azole-susceptible isolates do not alter the affinity
of the target to fluconazole. If, on the contrary, the diameters are
dissimilar compared to that for the susceptible control strain, the
mutations found in both susceptible and resistant isolates play a role
in the affinity of Erg11p for the azoles. When the diameters between
the isogenic susceptible and resistant isolates are not identical in
the disk assays, mutations in the ERG11 genes from
azole-resistant isolates can be expected, and these could result in a
difference of affinity of the target to azoles. The nucleotide
sequences of the cloned C. albicans ERG11 alleles of
interest were determined as described above. The mean disk diameters
among resistant and susceptible isolates and a susceptible control were
compared by a one-way analysis of variance. Differences were considered
statistically significant when the P value was less than
0.05. The analyses were performed with SPSS software (version
6.12; SPSS, Chicago, Ill.).
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RESULTS |
Strain identification.
Since evaluation of molecular
mechanisms of resistance requires the use of matched sets of
susceptible and resistant isolates, DNA-typing techniques were used to
assess strain isogenicity among a total of 20 highly resistant isolates
(fluconazole MICs, 64 µg/ml) selected for analysis and their
corresponding susceptible isolates recovered from 12 different
HIV-infected patients. The high degree of relatedness among susceptible
and resistant isolates obtained from the same patient was confirmed by
all typing methods used (karyotyping, restriction fragment length
polymorphism analysis, and Ca3 probe-based fingerprinting). Thus,
susceptible and resistant isolates obtained from the same patient
represented the same strain. Also, these experiments revealed that
different patients harbored different C. albicans strains
(data not shown).
Antifungal susceptibility testing.
The MICs of fluconazole,
itraconazole, voriconazole, posaconazole, and amphotericin B for the
different isolates are summarized in Table
1. Except for the isolate from patient
51, the initial isolate of the series for each patient was fluconazole
susceptible (fluconazole MICs, 
8 µg/ml); for the isolates from
patient 51, the fluconazole MIC for the most susceptible isogenic
isolate that was found was 16 µg/ml (susceptible, dose dependent).
For each patient, the resistant isolates included in this study were selected on the basis of their high-level fluconazole resistance (fluconazole MICs, 64 µg/ml) and also after determination of their
isogenicities with the corresponding susceptible isolates obtained from
the same patient. By following the criteria established by Rex et al.
(29) for the interpretive breakpoints for antifungal susceptibility testing for fluconazole and itraconazole against C. albicans, all the fluconazole-resistant isolates remained
susceptible to itraconazole (itraconazole MICs, 1 µg/ml), although
increases in the MICs were also observed compared to those for the
susceptible isolates. Decreased susceptibility to itraconazole was
detected in fluconazole-resistant isolates from patients 7, 9, 30, 43, 51, 59, and 64, with a 1 to 5 twofold dilution increase in the itraconazole MICs. In the case of voriconazole, elevated MICs were
detected for fluconazole-resistant isolates from patients 7, 9, 14, 30, 42, 43, 51, 59, and 64, with up to a 6 twofold dilution increase in
resistance. In the case of posaconazole, decreased susceptibility was
also noted in fluconazole-resistant isolates from patients 7, 15, 43, 51, and 64, with up to 1 to 5 twofold dilution increases in resistance.
Isolates with decreased susceptibilities to all four azole derivatives
tested were detected in patients 7, 42, 43, 51, and 64. Considering the
isolates that presented large decreases in their susceptibilities to
the new azoles (isolates 2307, 3731, 2257, and 4380, for which MICs
were 3 or more twofold dilutions higher than those for their
susceptible counterparts), we could observe that the most frequent
mechanism of resistance in these isolates was the overexpression of
efflux pumps (predominantly, CDR-encoded pumps; see below). The
differences in the amphotericin B MICs for the susceptible and the
resistant isolates were small (in all cases they were within 1 twofold dilution), and all isolates remained susceptible to this
agent.
Levels of expression of ERG11,
MDR1, and CDR genes in matched sets of
susceptible and resistant C. albicans clinical
isolates.
Total RNA extracted from the different isolates growing
in YEPD medium in the absence of an antifungal drug was analyzed by a
Northern blot technique with probes specific for the ERG11, MDR1, CDR1, and CDR2 genes and a probe
that detects different members of the CDR gene family (18, 19,
22, 40). As shown in Fig. 1,
overexpression of CDR genes was detected in 11 isolates (55%) from 10 patients (83%). In most instances, concomitant overexpression of
CDR1 and CDR2 was observed. Upregulation of
MDR1 was also observed in a total of 11 isolates (55%) from
eight patients (67%). Upregulation of ERG11 genes was
detected in seven isolates (35%) from five patients (42%).
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FIG. 1.
Northern blots of total RNA from clinical C.
albicans isolates analyzed with radiolabeled probes specific
for ERG11, MDR1, CDR,
CDR1, and CDR2. Hybridizations were
performed as described in Materials and Methods. The bottom rows
show the amounts of 18S rRNA used to standardize and calibrate
signal levels according to lane loading parameters. Flu, fluconazole.
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Mutations in ERG11 genes from C.
albicans isolates resistant to azole antifungal agents.
ERG11 genes obtained from the genomic DNAs of all C. albicans isolates were amplified by PCR with high-fidelity
Pwo DNA polymerase. Fragments of the expected length (1.6 kb) were obtained in each case. In order to identify the point
mutations present in the ERG11 genes of the resistant
isolates, we obtained their sequences. All the sequences contained at
least one cryptic nucleotide variation compared to the published
sequence of ERG11 (13; data not shown). No
variation that led to an amino acid substitution was found in three
resistant isolates. In addition, all ERG11 genes from the
other 17 azole-resistant isolates contained one or more nucleotide variations that led to amino acid substitutions in the protein sequence. Point mutations in ERG11 genes that resulted in 13 different amino acid substitutions were detected (Table
2). To demonstrate that the identified
amino acid substitutions in ERG11 from fluconazole-resistant strains could confer resistance to antifungal drugs in an intact yeast
cell, the ERG11 genes from fluconazole-resistant and matched susceptible isolates were expressed in S. cerevisiae. Disk
diffusion assays with fluconazole were performed with 10 S. cerevisiae transformants obtained from each C. albicans
clinical isolate. Each transformant was subjected to a fluconazole disk
diffusion assay on raffinose- and galactose-containing YNB agar.
Diameters of inhibition were recorded for each transformant, and the
results are presented in Table 3. The
decrease in the diameter of inhibition reflects the fact that
alterations in ERG11 proteins, which translate into a lower
level of susceptibility, had occurred. In two cases (isolate 2307 from
patient 7 and isolate 2500 from patient 14), no differences in
diameters of inhibition were observed compared to those for the
isogenic susceptible strain as well as fluconazole-susceptible S. cerevisiae transformant YKKB-13 used as a control. Two different point mutations that led to amino acid substitutions K128T and V437I
were found in these isolates. In the case of the K128T amino acid
substitution, it appeared to be present in both the susceptible and the
resistant isolate. Neither amino acid substitution (K128T or V437I)
altered the affinity of Erg11p for fluconazole, and therefore, these
substitutions are not associated with azole resistance. Other
investigators have previously indicated that neither point mutation is
linked to the azole antifungal agent resistance phenotype. In one case
(isolate 5108 from patient 30), a decrease in the diameter of
inhibition was observed in fluconazole-resistant transformant YKKB-13
compared to that for the fluconazole-susceptible transformant. The
G464S substitution not present in the susceptible transformant was
detected. In other cases (isolates 3107 and 3119 from patient 16;
isolates 2274, 2257, and 2339 from patient 51; and isolates 5044 and
5052 from patient 28), no differences in diameters of inhibition were
recorded for yeasts expressing ERG11 genes compared with
those for the fluconazole-susceptible and -resistant isolates from a
given patient, although a decrease in the diameter of inhibition was
observed compared to that for fluconazole-susceptible S. cerevisiae YKKB-13 transformed with a susceptible control. In
these isolates, three amino acid substitutions linked to a phenotype of
less susceptibility were found: Y132F, S405F, and D446N. In two other
cases (isolate 1619 from patient 15 and isolate 3731 from patient 42),
two distinct diameters of inhibition were measured for YKKB-13
transformants expressing the ERG11 alleles. This fact is
consistent with the diploidy of C. albicans; each allele of
the genomic ERG11 loci of these two isolates was amplified
by PCR, and one of these alleles encodes an altered protein that
decreases the susceptibility of the S. cerevisiae strain
expressing the corresponding allele. In these isolates, five amino acid
substitutions were found: D116E, G450E, G307S, F126L, and K143R. For
three other isolates (isolates 3917, 4617, and 4639 from patient
59), two distinct diameters of inhibition were measured for YKKB-13
expressing the ERG11 alleles from the susceptible isolate
(in one case, no mutation was observed and the other transformant
presented the F449S amino acid substitution). In the case of the
resistant isolates, two substitutions were detected: F449S and T229A.
Globally, 11 amino acid substitutions were found to be associated with
a resistance phenotype: D116E, G450E, G307S, Y132F, D446N, G464S,
F126L, K143R, S405F, F449S, and T229A. Of these, G307S and D446N have
not been yet reported by other laboratories (3, 6, 11, 12, 16,
20, 33). On the other hand, two amino acid substitutions, K128T
and V437I, were confirmed to not participate in azole resistance, in
agreement with previous reports (6, 33).
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TABLE 3.
Fluconazole susceptibilities of S. cerevisiae
strains expressing C. albicans ERG11 genes, as determined by
zone of inhibition
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Multifactorial nature of resistance: combinations of different
molecular mechanisms are responsible for azole resistance in a majority
of isolates displaying high-level fluconazole resistance.
In five
isolates (25%) from five patients (41.6%), concomitant upregulation
of the CDR and multidrug resistance genes was noted. In three isolates
(15%) from two patients (10%), upregulation of ERG11
appeared to be associated with upregulation of MDR1; and in
three isolates (15%) from two patients, (10%) they were detected together with CDR gene upregulation. Point
mutations in ERG11 genes with an effect on the affinity of
the enzyme for the azoles were observed in 13 isolates (65%) from
seven patients (58.3%). In two isolates (10%) from two patients
(16.6%), ERG11 upregulation was detected simultaneously
with point mutations in their ERG11 genes. In 11 isolates
(55%), point mutations in ERG11 genes appeared to be
combined with the upregulation of efflux pumps; more precisely, in 7 isolates it appeared to be associated with upregulation of
MDR1 genes and in another 7 isolates it appeared to be
associated with upregulation of CDR genes, with both efflux pumps
combined appearing in 3 isolates. See Table
4 for a compendium of the amino acid
substitutions and gene overexpression in each of the isolates
displaying high-level fluconazole resistance compared to matched
susceptible isolates.
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TABLE 4.
Summary of amino acid substitutions in Erg11p and gene
overexpression in fluconazole-resistant C. albicans
isolates compared to matched susceptible isolates
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DISCUSSION |
The multiplicity of mechanisms of resistance to azole antifungal
agents represents a set of biological tools that enables yeast cells to
develop resistance by using different combinations of mechanisms. A
limited number of studies support the role of these mechanisms in the
development of C. albicans resistance in a small number of
clinical isolates (34, 42). The aim of the present study
was to assess the prevalence of specific mechanisms of resistance in
matched sets of susceptible and resistant C. albicans
isolates recovered from HIV-infected patients with OPC monitored
longitudinally while under treatment with fluconazole.
The majority of the fluconazole-resistant isolates also showed
decreased levels of susceptibility to the various azole compounds tested: itraconazole, voriconazole, and posaconazole. In the case of
voriconazole, this could be explained by the fact that voriconazole shows properties similar to those of fluconazole with respect to its
capacity to be a substrate for multidrug efflux transporters and to
respond to ERG11 mutations, as has recently been shown by
Sanglard et al. (D. Sanglard, F. Ischer, and J. Bille, Abstr. 40th
Intersci. Conf. Antimicrob. Agents Chemother., abstr. 1711, p. 393, 2000). Confirming previous results, decreased susceptibility to
multiple azole derivatives was mainly associated with overexpression of
CDR genes (18, 30, 40), but it was also associated with the presence of specific point mutations in the ERG11 gene.
Importantly, all isolates remained susceptible to amphotericin B,
indicating the lack of cross-resistance to polyene antifungal agents.
The most frequent molecular mechanism of azole resistance was the
upregulation of efflux pumps. Thus, overexpression of the CDR and
MDR1 genes was detected in isolates from 83 and 67% of the
patients, respectively. Upregulation of ERG11 genes was
detected in isolates from 42% of the patients. In 86% of the
isolates it to be appeared associated with the upregulation of
MDR1 and CDR genes, and in 28% of the isolates it appeared
to be associated with point mutations in their ERG11 genes.
PCR amplification and sequencing of the ERG11 genes encoding
lanosterol 14-demethylase showed 13 nucleotide changes that led to amino acid substitutions in the enzymes of the resistant isolates. Using the technique developed by Sanglard et al.
(33), we could demonstrate that 11 of these point
mutations were linked to increases in the MICs of fluconazole when the
alleles carrying these mutations were expressed in S. cerevisiae. Overall, point mutations in ERG11 genes
with an effect on the affinity of the enzyme for the azoles were
observed in the isolates from 58% of the patients. In 55% of the
isolates it appeared to be combined with upregulation of efflux pumps.
While nine mutations were described previously, two were novel (G307S
and D446N). The fact that many of the mutations described here were
also found independently by others in the ERG11 genes from
other isolates obtained in different geographic locations illustrates
that there may be preferential amino acid positions able to confer a
phenotype of resistance to fluconazole and other azole derivatives.
These mutations repeatedly identified by different groups may represent
"hot spots" for the development of azole resistance (3, 6,
16, 21, 33, 37). Remarkably, most of these substitutions are
present in domains that are highly conserved in lanosterol
14-demethylases across fungi, suggesting the importance of these
residues for the maintenance of function through evolution. According
to molecular modeling of the C. albicans lanosterol
14-demethylase, these regions correspond to important functional
domains of the enzyme in its interaction with the heme moiety at its
active site and at another region believed to play a role in the entry
of the substrate in the substrate pocket (5, 10). Three
other conclusions can be drawn from the nucleotide sequences
obtained: (i) allelic differences are present in the
ERG11 gene for some of the substitutions identified; (ii)
multiple isolates obtained from the same patient at different intervals
exhibited the same or very similar polymorphisms, indicating a high
degree of relatedness; and (iii) differences in nucleotide sequences
among strains obtained from different patients indicate heterogeneity
in the C. albicans population.
In summary, we have performed a study to evaluate the prevalence of
molecular mechanisms of azole resistance in C. albicans strains displaying high-level fluconazole resistance isolated from a
cohort of HIV-infected patients who presented with OPC while on
treatment with fluconazole. The results obtained showed that the
resistance to fluconazole and other azoles is the result of a
combination of different molecular mechanisms, with the predominating mechanism being the overexpression of efflux transporters (ABC transporters and major facilitators), alone or in combination with
overexpression of the target enzyme and the presence of point mutations
in such enzymes that alter the interaction between the azole antifungal
agents and the enzyme. These results may help in the development of new
strategies to overcome the problem of resistance as well as new
treatments for this condition (9, 34).
| |
ACKNOWLEDGMENTS |
This work was supported by a grant from Pfizer Inc. and Public
Health Service grants 5 R01 DE11381 (to T.F.P.), 1 R29 AI42401 (to
J.L.L.-R.), and M01-RR-01346 for the Frederic C. Bartter General Clinical Research Center. S.P. acknowledges the receipt of a NATO postdoctoral fellowship. M.M. was supported by a research supplement to
support underrepresented minorities (grant 3 R01 DE11381-04A2S2, to
T.F.P.). R.A.S. was supported by the Prematriculation Program, Medical
Hispanic Center of Excellence, UTHSCSA. D.S. was supported by
grant 3100-055901.98/1 from the Swiss National Foundation. Chromogenic
medium was provided by the CHROMagar Company.
We thank the Fungus Testing Laboratory at UTHSCSA for performing
antifungal susceptibility testing.
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FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Medicine, Division of Infectious Diseases, The University of Texas
Health Science Center at San Antonio, South Texas Centers for Biology in Medicine, Texas Research Park, 15355 Lambda Dr., San Antonio, TX
78245. Phone: (210) 562-5017. Fax: (210) 562-5016. E-mail: RIBOT{at}UTHSCSA.EDU.
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Antimicrobial Agents and Chemotherapy, October 2001, p. 2676-2684, Vol. 45, No. 10
0066-4804/01/$04.00+0 DOI: 10.1128/AAC.45.10.2676-2684.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
