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Journal of Clinical Microbiology, November 1998, p. 3255-3259, Vol. 36, No. 11
Istituto di Parassitologia,
Received 8 April 1998/Accepted 20 July 1998
The genetic analysis of oocysts recovered from the stools of humans
and animals infected with Cryptosporidium parvum has
consistently shown the existence of two distinct genotypes. One of the
genotypes is found exclusively in some human infections, whereas the
other genotype is found in human as well as in animal infections. On the basis of these observations and the results of published
epidemiological studies with single polymorphic markers, the existence
of two separate transmission cycles has been postulated, one
exclusively anthroponotic and the other involving both animals and
humans. To test this hypothesis, C. parvum isolates of
different geographic and host origins were analyzed by using unlinked
genetic polymorphisms. A total of 28 isolates originating from Europe,
North and South America, and Australia were examined. Isolates
clustered into two groups, one comprising both human and animal
isolates and the other comprising isolates only of human origin. The
absence of recombinant genotypes is consistent with two reproductively isolated populations within the species C. parvum.
Apicomplexan parasites of the genus
Cryptosporidium infect the gastrointestinal or respiratory
tracts of a wide range of mammals, birds, reptiles, and fish.
Cryptosporidium parvum, a major cause of diarrhea in young
livestock, has recently emerged as a widespread enteric pathogen in
humans (6, 21). In immunocompetent adults the infection is
generally acute and self-limiting, whereas immunocompromised individuals can develop chronic and potentially life-threatening diarrhea. The significant prevalence of C. parvum in
patients with opportunistic infections and recent reports of major
outbreaks of cryptosporidiosis in the United States and the United
Kingdom due to contamination of drinking water supplies (10, 17,
18) indicate that C. parvum is a major public health
problem. The absence of effective treatment for cryptosporidiosis
highlights the need for preventive measures. To this aim, it is
essential to understand the epidemiology of the disease and to identify the transmission routes accounting for human exposure and infections.
Recent studies on the intraspecific genetic variation in C. parvum have shed new light on the population structure of this parasite. Using isoenzyme analysis (1) or different
DNA-based techniques (3-5, 11-14, 19), several
laboratories, including ours, have found that C. parvum
isolates can be divided into two genetically distinct groups, one
exclusively associated with human infections and the other associated
with both human and animal infections. We refer to these genotypes as H
and C, respectively (24). The existence of two genotypes and
the apparent lack of recombinants has taxonomical and epidemiological
relevance. It implies that C. parvum may not be a uniform
species; rather, it may comprise two genetically distinct parasite
subpopulations. It also suggests the existence of two independent human
transmission cycles.
Most of the C. parvum typing studies carried out to date are
based on the analysis of single polymorphisms. A multilocus approach has the potential to better define the structure of the C. parvum population and assess the degree of genetic isolation of
the H and C subpopulations. We report herein on the genotyping of 28 C. parvum isolates of various host and geographic origins
simultaneously analyzed at up to five polymorphic loci.
Parasites.
Isolates GCH1, GCH2, GCH3, GCH4, GCH5, H77, H78,
P9, P12, P16, P18, P27, P29, A1, S1, Moredun (MD), ICP, UCP, 58EF, 63H,
LL, and 740 were described previously (see Table 2). Isolate GCH6 originated from a laboratory worker accidentally infected with C. parvum. Isolates H83, H84, and H87 were isolated from human immunodeficiency virus-negative individuals from Perth, Western Australia, Australia. Isolate UCP has been maintained in calves for
more than 8 years at ImmuCell Corp. (Portland, Maine) and was kindly
provided by Joe Crabb. Isolate OH originated from a human with an acute
infection and was obtained from Lucy Ward, Ohio State University,
Wooster. Isolate PC1 was isolated from a captive macaque at the New
England Regional Primate Center in Southboro, Mass., and was kindly
provided by Keith Mansfield.
DNA isolation, PCR, and restriction fragment length polymorphism
(RFLP) analysis.
C. parvum genomic DNA (gDNA) was extracted
either from purified oocysts or from stool. Briefly, 100 to 200 µl of
stool was diluted with equal volume of water and incubated overnight in 0.2% sodium dodecyl sulfate (SDS) and 200 µg of proteinase K per ml.
After phenol-chloroform extraction, the gDNA was purified by binding to
glass milk (GeneClean; Bio 101). Alternatively, stools were processed
as described previously (19). DNA from purified oocysts was
released either by three cycles of freezing-thawing or by proteinase K
digestion.
Genotypic analysis.
Four of the polymorphic loci used in
this study were analyzed by PCR-RFLP assays. The PCR primers used are
listed in Table 1. Selected endonucleases
recognizing polymorphic cleavage sites within the amplified sequences
were used to digest the PCR products and discriminate between alleles
on the basis of alternative restriction profiles. PCR-RFLP analyses of
the polythreonine [poly(T)] and Cryptosporidium oocyst
wall protein (COWP) (16) loci were performed as described
previously (5, 19). The gene encoding the
thrombospondin-related adhesive protein of Cryptosporidium
(TRAP-C1) (20a) was recently found to consist of at least
two alleles, TRAP-C1R1 and
TRAP-C1R2, differentially associated with animal
or human C. parvum isolates (20b). Primers Cp.E
and Cp.W were used to amplify a 506-bp fragment from the TRAP-C1-coding
sequence. Subsequent digestion of the PCR products with endonuclease
RsaI yielded two alternative restriction profiles consisting
of two bands for TRAP-C1R1 (455 and 51 bp) and
three bands for TRAP-C1R2 (341, 114, and 51 bp).
The PCR-RFLP assay for the ribonucleotide reductase (RNR) locus was
based on the amplification of a 441-bp fragment of the RNR R1 subunit
located at positions 1364 to 1804 (GenBank accession no. AF043243)
(24). Digestion was performed with restriction endonuclease
Tsp509I in 1× PCR buffer (50 mM KCl, 10 mM Tris-HCl [pH
9.0], 2 mM MgCl2, 0.1% Triton X-100) at 65°C. Extensive
sequence polymorphism in the ribosomal internal transcribed spacer
region 1 (ITS1) (4) was exploited to design a
genotype-specific PCR assay with primers cry8 and cryITS1 (Table 1).
Because this polymorphism is based on the presence or absence of PCR
products, this assay was always run in parallel with a control PCR
amplification.
0095-1137/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Multilocus Genotypic Analysis of Cryptosporidium
parvum Isolates from Different Hosts and Geographical
Origins
ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
TABLE 1.
Polymorphic loci analyzed
Karyotype analysis. The chromosomal locations of the COWP, RNR, and TRAP-C1 loci were determined by contour-clamped homogeneous electrical field (CHEF) electrophoresis as follows. Agarose blocks containing an amount of C. parvum DNA equivalent to 2 × 107 oocysts of the MD strain or a DNA size marker (Saccharomyces cerevisiae DNA Size Standard; Bio-Rad) were loaded onto a 1% low-gelling-temperature agarose gel made in 0.5× TBE (Tris-borate-EDTA) buffer. Chromosomal DNA was electrophoresed with the CHEF-DR II Pulse Field Electrophoresis System (Bio-Rad) with recirculated 0.5× TBE buffer maintained at 14°C. Electrophoresis was carried out at 120 V with a switch interval of 240 s for 72 h. The gel was then stained with 0.5 µg of ethidium bromide per ml and destained in distilled water, and the chromosomal bands were visualized with a UV transilluminator. The poly(T) locus was mapped by pulsed-field gel electrophoresis (PFGE) with the KSU-1 isolate as described previously (9).
Chromosomal DNA was depurinated by soaking the gel in 0.25 M HCl for 15 min, transferred onto a nylon membrane by capillary absorption, and cross-linked by UV irradiation. The membrane was hybridized sequentially to the 441-bp DNA fragment from the RNR R1 sequence and to the 4,420-bp COWP probe cpMM1 (20). A second membrane was probed with a 1,782-bp DNA fragment spanning most of the coding region of the TRAP-C1 gene (positions 70 to 1851). The poly(T) gene was located by using as a probe the 515-bp PCR fragment defined by primers cry44 and cry37 (5). Probes were labelled by random priming with [32P]dATP. Hybridizations were carried out at 65°C in 4× SSC (1× SSC is 0.15 M NaCl plus 0.015 M sodium citrate)-5× Denhardt's solution-0.1% sodium dodecyl sulfate in the presence of 50 µg of salmon sperm DNA per ml. Washes were performed at 65°C in 0.1× SSC-0.1% sodium dodecyl sulfate. Southern analysis of the poly(T) locus was performed as described previously (8).| |
RESULTS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Recent studies that used PCR-based methods for the analysis of C. parvum genetic variation at single loci have coherently demonstrated the existence of two main parasite subpopulations characterized by distinct genotypes (3-5, 12-14, 19, 23). The aim of this study was a multilocus analysis of a broad and heterogeneous collection of C. parvum isolates. We chose for our study five genetic markers defined by the PCR primers listed in Table 1. These loci have been shown to consist of at least two alleles differentially associated with animal or human C. parvum isolates. The copy numbers of two markers, RNR and ITS1 (type A), were determined to be 1 and 4, respectively (data not shown; 9).
Chromosomal locations of polymorphic markers. The chromosomal locations of four RFLP markers were determined by Southern analysis of CHEF- or PFGE-separated oocyst DNA (Fig. 1). The chromosomal profiles obtained by these electrophoretic techniques with DNA from the MD and KSU-1 strains (Fig. 1a, c, and e) were analogous to each other and to the profile described by Blunt et al. (2). Accordingly, the five chromosomal bands are numbered from 1 to 5, where band 1 is the largest band (1.54 Mb) and band 5 is the smallest band, which is estimated to be 1.03 Mb. Bands 1 and 3 are thought to comprise multiple comigrating chromosomes (2). Southern blot analysis showed that the markers are located on different chromosomes, namely, COWP and RNR on band 2 (Fig. 1b; data not shown), TRAP-C1 on band 5 (Fig. 1d), and poly(T) on band 1 (Fig. 1f). This analysis demonstrates that our RFLP markers fall into at least three distinct linkage groups.
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Multilocus genotype analysis. By using the primers listed in Table 1, 28 C. parvum isolates of disparate geographic and host origins were genotyped. Seventeen isolates originated directly from humans, three isolates (GCH1, LL, and 740) were derived from humans and propagated in calves, and eight isolates were from various animals. Human isolates were both from patients with sporadic cases of infection (H77-87, P12, and GCH2 to GCH6) and from documented outbreaks (P9, P16, P18, P27, and P29). GCH2 and GCH3 were from AIDS patients. Animal isolates included the widely used MD and GCH1 isolates.
Consistent with previous reports, we observed for each locus two electrophoretic profiles (Fig. 2). The absence of reassorted genotypes is indicative of two reproductively separated subgroups in the species. With the exception of isolate PC1, which originated from a captive macaque, C. parvum of genotype H was exclusively associated with human infections. Genotype C was associated with isolates from animals and a minority of human isolates (LL, 740, H78, GCH6, and P9) (Table 2). The PCR and PCR-RFLP profiles obtained for three representative isolates, two from humans (H78 and P12) and one from an animal (MD), are shown in Fig. 2. For isolates GCH4 and GCH5, RFLP profiles indicative of mixed genotypes at the poly(T) locus were detected (5).
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Published studies on C. parvum genotypic heterogeneity rely on the analysis of single loci (3-5, 12, 14, 19, 22). Morgan et al. (13) recently applied two polymorphic markers. From that work, it appears that isolates of C. parvum segregate into two groups, designated H and C.
The use of multiple polymorphisms described in this report confirmed the occurrence of two genotypes. The absence of recombinant isolates indicates reproductive isolation between H and C isolates. This is surprising considering that both genotypes can be found simultaneously in the same host (5) and the fact that C. parvum undergoes an obligatory sexual cycle. With the notable exception of isolate PC1, the host specificities of C. parvum genotypes H and C were confirmed by the present study. PC1, identified as belonging to genotype H, is the first nonhuman H isolate described.
The genomic locations of the RFLP markers on three C. parvum chromosomal bands demonstrate that at least three independent linkage groups were sampled. Because COWP and RNR are both located on chromosomal band 2, and at least two of the five ribosomal genes colocalize with poly(T) and TRAP-C1 (9), the degree of linkage between these loci is unknown.
At first glance, the population structure of C. parvum emerging from this study is reminiscent of that observed in Toxoplasma gondii, in which three clonal lines were identified (7). In apparent contrast to C. parvum, rare mixed genotypes were observed in T. gondii. However, it cannot be excluded that recombinant genotypes will eventually be identified in C. parvum as more isolates are analyzed. Even if such mixed genotypes are identified in future studies, our data suggest that genetic exchange between genotypes is at best a rare event.
Further advances in our understanding of the population structure of C. parvum will come from the application of polymorphisms capable of differentiating among isolates belonging to the same genotypic group. Heterogeneity within each group has been observed. Peng et al. (14) described the presence of three TRAP-C2 alleles defined by five polymorphic nucleotide positions. Similarly, a total of four alleles, each defined by one or several point mutations, were identified within a 145-bp region of the poly(T) locus (23). These observations indicate that genetic fingerprints capable of differentiating among C. parvum isolates or groups of isolates will soon be available and allow us to improve the resolution of C. parvum genotypes. The relevance of this work lies in the potential for identifying clinically relevant markers. From an environmental point of view, high-resolution fingerprints could assist in identifying the source of oocysts found in surface water, facilitating the implementation of measures to reduce the access of oocysts to drinking water.
The potential for each C. parvum genotype to cause different clinical symptoms is unknown. Differences in infectivity for laboratory animals were reported (14, 15) and were also observed among isolates originating from people with AIDS in laboratory animals and in tissue culture (24). Characterization of larger numbers of isolates from humans with chronic and acute infections is in progress. Together with improved fingerprinting methods, this work will lead to a better understanding of cryptosporidiosis.
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ACKNOWLEDGMENTS |
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This work received financial support from USDA (grant 94-371020914), NIH (cooperative agreement U019AI33384 and grant AI26497 from the International Collaborative Infectious Disease Research Program), and the IX AIDS Research Program, Ministero della Sanità, Istituto Superiore di Sanità, Rome, Italy. P.S. is supported by EEC RTD Programme ERBIC 18CT970217 of the European Community.
We sincerely thank all our colleagues who donated samples.
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FOOTNOTES |
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* Corresponding author. Mailing address: Division of Infectious Diseases, Tufts University School of Veterinary Medicine, 200 Westboro Rd., North Grafton, MA 01536. Phone: (508) 839 7944. Fax: (508) 839 7977. E-mail: gwidmer{at}infonet.tufts.edu.
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Journal of Clinical Microbiology, November 1998, p. 3255-3259, Vol. 36, No. 11
0095-1137/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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