Journal of Bacteriology, February 1999, p. 1369-1373, Vol. 181, No. 4
Department of Microbiology, Duke University
Medical Center, Durham, North Carolina
27710,1 and
Department of Botany,
Duke University, Durham, North Carolina 277082
Received 22 July 1998/Accepted 30 November 1998
The patterns of genetic variation of samples of Candida
albicans isolated from patients infected with human
immunodeficiency virus in Durham, N.C., and Vitória, Brazil, were
compared. Genotypes for 126 strains were obtained at 16 polymorphic
restriction sites distributed on nine PCR fragments. The results
indicated evidence of clonality both within and between these two
geographically diverse samples. The samples are genetically very
similar, with little evidence of genetic differentiation.
Previous studies on the population
structure of the human pathogen Candida albicans (Robin)
Berkhout (1923) revealed its diploid nature and predominantly clonal
mode of reproduction (3, 7, 8, 19). However, little is known
about the geographic structure of this species. Clemons et al. showed
that strains from the United States and Europe were on average more
similar to each other than they were to strains from Singapore
(2). Since their genotyping methods did not allow the
unambiguous assignment of alleles to individual loci, the population
gene frequencies and genetic distances cannot be calculated to
determine whether geographically diverse samples of C. albicans are statistically differentiated. Codominant markers are
best able to address these issues.
As an initial attempt to understand the geographic structure of
C. albicans, we applied codominant markers to examine the patterns of genetic variation between different geographic samples of
C. albicans. Sixty-two and sixty-four isolates of C. albicans were obtained by oral swabs of patients at Infectious
Diseases Clinics at Duke University Medical Center (Durham, N.C.) and
Vitória Hospital (Vitória, Brazil). There was one isolate
per patient, and all patients had AIDS at the time of sampling. Genomic
DNA was isolated as previously described (10).
The molecular markers were described in a previous study; an additional
polymorphic restriction site (around 350 bp) in primer pair E15n7 was
present in the Vitória sample but absent in the Durham samples
(19). Altogether, 16 polymorphic restriction sites were
analyzed for the two samples. The protocols for PCR amplification,
digestion with restriction endonucleases, agarose gel electrophoresis,
and scoring were performed as previously described (19).
A total of 45 multilocus genotypes were found among the 126 strains.
Six genotypes were shared between the two samples, representing a total
of 80 isolates, 43 from Durham and 37 from Vitória. The most
common genotype was found in both samples, 35 isolates from Durham and
15 from Vitória.
To compare genetic variation between samples, the following genetic
parameters were analyzed: (i) observed heterozygosity (4),
(ii) gene diversity (4), and (iii) Stoddart's genotypic diversity (12, 13). The statistical significance between
the samples for the three measures was assessed by the t
test (1, 11). The results indicated that the samples have
similar observed heterozygosities, gene diversities, and genotypic
diversities (Table 1).
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Lack of Genetic Differentiation between Two
Geographically Diverse Samples of Candida albicans Isolated
from Patients Infected with Human Immunodeficiency Virus
ABSTRACT
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TABLE 1.
Comparisons of heterozygosity, gene diversity, and
genotypic diversity between two geographically diverse samples of
C. albicans isolated from patients with AIDS
To examine whether the samples showed similar evidence of clonality and recombination, we used three common tests: (i) the Hardy-Weinberg (HW) equilibrium test, which examines the associations of alleles within each locus (4, 11, 15); (ii) the composite genotypic equilibrium test, which examines the associations of alleles between pairs of loci (6, 15, 20); and (iii) a t test between observed and expected genotypic diversities (13).
The results of the first two tests are presented in Table
2. In both samples, about half of the
loci showed genotypic frequencies not significantly different from
those expected from random recombination, and in both samples, all but
one of the loci in HW disequilibrium showed an excess of homozygotes. A
similar pattern of allelic association between loci was found for the
two samples, with more than half the pairs of loci in composite
genotypic disequilibrium (Table 2). The third test (13) also
showed evidence for significant departure from panmixia in both samples
(P < 0.001 for both samples). Therefore, consistent
with previous studies based on codominant molecular markers (3, 8,
19), these geographically diverse samples showed a significant
clonal component, with some evidence for recombination (Table 2). The
possible mechanisms and implications of this pattern of genetic
variation within a population have been discussed elsewhere (3, 8,
19).
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Genetic differentiation between the two samples was quantified with traditional F statistics (4-6, 15-17). The F statistics were calculated by an analysis of variance approach, implemented in the program GDA1d32, and the 95% confidence limits were estimated by jackknifing (6, 16). Probability testing for genetic differences between samples was performed by chi-square contingency table tests of gene frequencies at each individual locus and summed across all loci (5, 11, 18, 19).
The overall FST value between the two samples was 0.017, with 95% confidence limits of 0.001 to 0.035. Hence, the large geographic separation of the two sampling locations contributed only about 1.7% to the overall levels of genetic variation of the total sample. Furthermore, there was no significant difference in allele frequencies for 13 of the 16 loci (data not shown). The summed chi-square values for the 16 loci was 25.561 (df = 16, P > 0.05). Both tests provide strong evidence for genetic homogeneity between these two samples.
Because C. albicans and many other microbes are known to reproduce clonally via mitosis, the use of clone correction has been proposed as a means of reducing overrepresentation of individual genotypes derived from locale-specific clonality (1, 19). In the clone-corrected sample analyses, only one isolate of each multilocus genotype was taken from each sample. The patterns of genetic variation within and between clone-corrected samples were similar to the results that included all the isolates (Tables 1 and 2). The overall FST value between the two clone-corrected samples was 0.002, lower than between the total samples. None of the 16 loci showed any significant difference in gene frequency between the two geographically diverse samples in the clone-corrected data analysis (data not shown), with a summed chi-square value of 23.257 (df = 16, P > 0.05).
We tested whether the high genetic similarity between the two samples is related to the AIDS patients. Two additional samples from Durham (one sample from human immunodeficiency virus [HIV]-negative patients and the other from healthy student volunteers [19]) were included in the genetic distance analysis (9). The genetic similarities among samples are presented in Fig. 1. In Fig. 1A, the two patient samples from Durham are seen to be most similar to each other. Surprisingly, these two samples were more similar to the sample from AIDS patients in Vitória than to the sample from healthy students in Durham. The analysis of clone-corrected samples (Fig. 1B) produced strong support for potential association of AIDS with genetic similarity of C. albicans isolates. In this analysis, the two samples from HIV-infected patients were more similar to each other than either was to any of the other samples (Fig. 1B).
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The similarity analysis among individual multilocus genotypes, assessed with the unweighted pair-group method using arithmetic means (UPGMA) algorithm of PAUP4d64 (14), generated a phenogram for all 45 multilocus genotypes (Fig. 2). This phenogram indicated no evidence that a single cluster contained all the strains from one geographic origin. The genotypes shared by isolates from the two geographic areas were also dispersed in the phenogram.
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In summary, this is the first study to apply population genetic approaches to compare geographically separated samples of C. albicans from AIDS patients. The results showed evidence for clonality both within and between geographically diverse samples. Even though the two samples, one from North America and the other from South America, are genetically indistinguishable, many questions remain. For example, is this pattern of genetic structure typical for other host groups in the two regions? Will other geographic regions show similar patterns of clonality and genetic homogeneity? The approaches presented here should contribute to the understanding of these and other questions relating to the epidemiology and pathogenesis of candidiasis.
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ACKNOWLEDGMENTS |
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We thank Wiley Schell, Kieren Marr, Preston Klassen, Barbara Alexander, and Cynthia Boyd for helping to collect strains. We appreciate the extensive comments of one anonymous reviewer. We gratefully acknowledge the collaboration of Reynaldo Dietze of the Federal University of Espirito Santo, Brazil, whose contributions made this research possible.
This work was supported by Public Health Service grant AI 28836 from the National Institutes of Health.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Microbiology, Box 3020, Duke University Medical Center, Durham, NC 27710. Phone: (919) 684-9096. Fax: (919) 681-8911. E-mail: jpxu{at}acpub.duke.edu.
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Journal of Bacteriology, February 1999, p. 1369-1373, Vol. 181, No. 4
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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