The First Evidence of Cryptosporidium meleagridis Infection in a Colon Adenocarcinoma From an Immunocompetent Patient

Molecular diagnostic tools have been used increasingly in the characterization of the transmission of cryptosporidiosis and microsporidiosis in developing countries. However, few studies have examined the distribution of Cryptosporidium species and Enterocytozoon bieneusi genotypes in AIDS patients receiving antiretroviral therapy. In the present study, 683 HIV-positive patients in the National Free Antiretroviral Therapy Program in China and 683 matched HIV-negative controls were enrolled. Cryptosporidium species and subtypes and Enterocytozoon bieneusi genotypes were detected and differentiated by PCR and DNA sequencing. The infection rates were 1.5% and 0.15% for Cryptosporidium and 5.7% and 4.2% for E. bieneusi in HIV-positive and HIV-negative participants, respectively. The majority (8/11) of Cryptosporidium cases were infections by zoonotic species, including Cryptosporidium meleagridis (5), Cryptosporidium parvum (2), and Cryptosporidium suis (1). Prevalent E. bieneusi genotypes detected, including EbpC (39), D (12), and type IV (7), were also potentially zoonotic. The common occurrence of EbpC was a feature of E. bieneusi transmission not seen in other areas. Contact with animals was a risk factor for both cryptosporidiosis and microsporidiosis. The results suggest that zoonotic transmission was significant in the epidemiology of both diseases in rural AIDS patients in China.

Cryptosporidiosis is often observed as a pediatric disease in areas where Cryptosporidium spp. are endemic. Children 40 unnamed genotypes that are potentially different species. At least 8 of them have been reported in humans: C. hominis, C. parvum, C. meleagridis, C. felis, C. canis, C. muris, and C. suis, and the Cryptosporidium cervine genotype. Molecular characterization of the 60-kDa glycoprotein (GP60) gene of C. hominis and C. parvum has enabled further division into subtype families and subtypes ( 11 ). Humans are most frequently infected with C. hominis and C. parvum ( 7 , 11 , 12 ); recent reports indicate possible associations between these 2 organisms and different clinical manifestations. In Brazil, children infected with C. hominis had increased parasite shedding, more frequent presence of fecal lactoferrin, and delayed growth when compared with those infected with C. parvum ( 13 ). In a study of sporadic cryptosporidiosis in the United Kingdom, illness was more severe in persons infected with C. hominis than in those infected with C. parvum ( 14 , 15 ). A recent study reported different clinical manifestations among Cryptosporidium spp. in HIV-positive persons, and C. hominis was linked to more severe symptoms. The high virulence of C. hominis was evident within its subtype family Id, while absent in subtype families Ia and Ie ( 16 ). In this study, we analyzed the diversity of Cryptosporidium at the species, subtype family, and subtype levels in children living in an area with endemic cryptosporidiosis. We also analyzed the association between clinical manifestations and infections with specific Cryptosporidium spp. and C. hominis subtype families. Methods Study Design Specimens and data were obtained from a longitudinal birth cohort study of diarrheal diseases conducted during 1995–1998 in Pampas de San Juan de Miraflores, Lima, Peru. This community was initially settled in the 1980s by immigrants from rural areas. It is located in the outskirts of Lima and had at the time of the study ≈40,000 inhabitants. In this community, the prevalence of HIV infection was 150 oocysts. Genotyping and Subtyping Cryptosporidium spp. were identified by using a small subunit rRNA-based PCR–restriction fragment length polymorphism genotyping tool ( 7 , 12 , 17 ). Subtyping of C. hominis and C. parvum was based on sequence analysis of GP60 genes ( 18 ). Each specimen was analyzed by either method at least twice. Subtype families within C. hominis and C. parvum were determined on the basis of sequence differences in the nonrepeat region of the gene. Within each subtype family, subtypes differed from each other, mostly in the number of serine-coding trinucleotide repeats (TCA, TCG, or TCT microsatellite) located in the 5′ region of the gene. The previously established nomenclature system was used to differentiate subtypes within each subtype family ( 11 , 16 , 17 ). For C. parvum subtype family IIc, the original GP60 sequence for C. parvum subtype family IIc (GenBank accession no. AF164491) was assigned as IIcA5G3a. Subtypes that diverged from this sequence were assigned subsequent alphabetical extensions. Associated Clinical Manifestations and Risk Factors Daily information on clinical manifestations was gathered by using structured questionnaires. These data were collected by study personnel during interviews of adult caregivers of the participants. Data included relevant gastrointestinal symptoms such as abdominal pain, fever, general malaise, nausea, vomiting, number and consistency of bowel movements, and blood in stools. Study of potential risk factors for infections was based on sanitation and socioeconomic data obtained at study enrollment. These factors included hygiene parameters (water piped inside the house and presence of flush toilets), presence of animals (dogs, chicken, ducks, guinea pigs, rabbits, parrots, and sheep), house infrastructure (sturdy walls and roof), and indirect economic indicators (house infrastructure and possession of electronic appliances). Definitions For the epidemiologic and statistical analyses, we included data from eligible children who had >6 months of participation in the study and 3 liquid or semiliquid bowel movements on any day and the mother’s assessment that the child had diarrhea. Diarrhea was considered associated with an episode if it occurred within 7 days of a positive result for Cryptosporidium spp. Statistical Analysis Statistical analyses included data from participants infected with 1 species of Cryptosporidium and compared children with a specific Cryptosporidium sp. or C. hominis subtype family with all other participants not infected with that species or subtype family. Subtype families were compared because of the extensive sequence polymorphism in the nonrepeat regions of GP60, and subtypes within families primarily differed from each other in the length of the serine stretch at the beginning of the protein. Data from the few children infected with >1 species or subtype determinations that were conflicting with genotype categorizations were excluded from that particular comparison. Because all C. parvum in this population belonged to 1 subtype family, results were presented at the species level. Few participants were infected with C. canis and C. felis and these species are genetically divergent from C. hominis, C. parvum, and C. meleagridis. Therefore, the data for these persons were pooled. Poisson regression was used to compare incidence rates of gastrointestinal symptoms (dependent variables) and infections with Cryptosporidium spp. or subtype families (independent variables) detected in each infection episode. This model was used to incorporate individual incidence rates of infections and the duration that each person participated in the study. These regression analyses were conducted by using SAS Proc Genmod (SAS Institute, Cary, NC, USA) for linear models. The generalized estimating equations procedure was implemented to adjust for correlation among multiple infections for the same child. Statistical significance for a priori tests was set at α = 0.05. Whenever multiple subtypes were compared, a separate Bonferroni adjustment was used to maintain an overall experiment-wide α of 0.05. The χ2 or Fisher exact tests were used to analyze any association between Cryptosporidium spp. or subtypes and animal contacts or socioeconomic risk factors. Pooled t test was used to investigate the differences in age at first infection episode among Cryptosporidium spp. and subtype families. All statistical analyses were performed by using SAS version 9.1 (SAS Institute). Results A total of 533 children were enrolled, and their median age at enrollment was 14 days. They contributed 44,042 stool specimens for detection of enteric parasites and 324,067 child-days of clinical manifestation surveillance. Prevalence of Cryptosporidiosis Data from 368 participants who met the evaluable criteria were included in the epidemiologic analyses. Cryptosporidiosis was detected by microscopy for 109 participants, for a total of 156 infection episodes. Among them, 71 children had 1 infection, 30 had 2 infections, 7 had 3 infections, and 1 had 4 infections. Cryptosporidium spp. Genotypes and Subtypes Genotype data for Cryptosporidium spp. were obtained from 127 (81%) of 156 infection episodes. Among those genotyped, C. hominis (70%) was the species most frequently detected, followed by C. parvum (13%) and C. meleagridis (8%). In contrast, C. canis and C. felis were detected in 2% and 5% of cases, respectively (Table 1). Among 106 infection episodes with either C. hominis (89) or C. parvum (17), subtype analysis was successfully accomplished for 78 of 89 infections with C. hominis and 14 of 17 infections with C. parvum. Four subtype families were identified within C. hominis: Ia, Ib, Id, and Ie, the least frequent was Id. All infections with C. parvum belonged to subtype family IIc. Novel subtype sequences were deposited in GenBank under accession nos. EU095258–EU095267 (Table 2). Table 1 Frequency of infections with Cryptosporidium spp. in 533 children, Peru Species No. (%) infection episodes First Overall C. hominis 61 (64.9) 89 (70.1) C. parvum 15 (16.0) 17 (13.4) C. meleagridis 9 (9.6) 10 (7.9) C. canis 2 (2.1) 2 (1.6) C. felis 4 (4.3) 6 (4.7) C. hominis and C. parvum 2 (2.1) 2 (1.6) C. canis and C. meleagridis 1 (1.1) 1 (0.8) No. genotyped 94 127 Total episodes 109 156 Table 2 Distribution of subtype families and subtypes of Cryptosporidium hominis and C. parvum in 533 children, Peru Species Subtype families No. episodes (%) Subtype: no. (%) 
within subtype family GenBank accession no. At first infection All C. hominis Ia 15 (24.6) 21 (26.9) IaA11R4: 3 (14) EU095258* IaA12R4: 7 (33) EU095259* IaA13R4: 1 (5) EU095260* IaA13R7: 1 (5) EU095261* IaA14R6: 5 (24) EU095262* IaA15R3: 3 (14) EU095263* Ib 16 (26.2) 23 (29.5) IbA10G2: 23 (100) AY262031 Id 7 (11.5) 12 (15.4) IdA10: 9 (75) EU095264* IdA15: 1 (8) DQ280498 IdA20: 2 (16) EU095265* Ie 15 (24.6) 19 (24.4) IeA11G3T3:19 (100) DQ665689 lb + le 1 (1.6) 1 (1.3) 1 (1.3) Ib + id 1 (1.6) 1 (1.3) 1 (1.3) Id + ie 1 (1.6) 1 (1.3) 1 (1.3) C. hominis and C. parvum Id + IIc 1 C. parvum IIc 14 (100) 14 (100) IIcA5G3a: 12 (86) AY738195 IIcA5G3b: 1 (7) EU095266* IIcA5G3c: 1 (7) EU095267* *From this study. Several subtypes were found within subtype families Ia and Id of C. hominis and IIc of C. parvum. Subtype family Ia was the most diverse with 6 subtypes, followed by subtype families Id and IIc, each with 3 subtypes. In contrast, subtype families Ib and Ie each had only 1 subtype: IbA10G2 was the only subtype in subtype family Ib and IeA11G3T3 was the only subtype in subtype family Ie (Table 2). Cryptosporidium spp. and Oocyst Shedding The mean age for first infections was 1.6 years of age (median 1.4 years, range 0.2–4.7 years). Infections with C. parvum occurred at a younger age than those with other genotypes, and infections with C. canis or C. felis occurred in older children. However, these differences were not statistically significant after the Bonferroni correction (Table 3). Table 3 Age at first infection by Cryptosporidium spp. and subtype family in 533 children, Peru Species or subtype family No. episodes Age, y, mean (range) p value C. hominis 61* 1.93 (0.19–9.51) 0.026† Subtype family Ia 15 2.13 (0.67–8.05) 0.113 Subtype family Ib 16 1.38 (0.60–2.82) 0.176 Subtype family Id 7 1.41 (0.19–3.34) 0.645 Subtype family Ie 15 1.81 (0.25–9.51) 0.723 C. parvum 15 1.22 (0.44–2.49) 0.034† C. meleagridis 9 1.43 (0.78–2.75) 0.615 C. canis or C. felis‡ 6 2.26 (0.68–3.74) 0.039† Mixed infections 2 1.62 (1.44–1.79) Not done *Eight C. hominis infections did not have subtype family data.
†Not significant after Bonferroni adjusted α = 0.05/5 = 0.01.
‡Includes 1 mixed infection with C. meleagridis and C. canis. The mean duration of the first infection episode was 8.1 days (median 5.5 days, range 1–40 days). Infections with C. hominis (mean 10.3 days) lasted longer than infections with other species of Cryptosporidium (mean 5.8 days; p = 0.001). The length of the infection episodes among children infected with different subtype families of C. hominis was not significantly different (9.3, 13.1, 7.7, and 12.8 days for Ia, Ib, Id, and Ie, respectively). Similar patterns were observed for intensity of parasite excretion. Children infected with C. hominis had higher parasite excretion scores (mean 1.93) than those infected with other species of Cryptosporidium (mean 1.42; p = 0.021). Among children infected with different subtype families of C. hominis, the intensity of parasite shedding was similar. Sequential Cryptosporidium spp. Infections Among children with complete genotyping data, sequential infections were detected in 17 children: 15 had 2 episodes of Cryptosporidium spp. infection and 2 had 3 episodes (total of 19 reinfection events). The median interval between infections was 10 months (range 2.1–26 months). The same Cryptosporidium sp. was detected in 6 of 15 children with 2 episodes and 1 of 2 children with 3 infections, all involving C. hominis (Table 4). When analysis of reinfections included C. hominis subtype family data, only 2 sequential infections occurred with the same subtype family: child 5395 had C. hominis subtype family Id in the first and second infections, and child 5076 had C. hominis subtype family Ie in the second and third episodes of cryptosporidiosis. Table 4 Cryptosporidium spp. and subtype families of C. hominis detected in reinfection events in 533 children, Peru Event Infection First Second Third 5444 C. parvum (IIc) C. hominis (Id and Ie) C. hominis (Ib) 5076 C. hominis (Id) C. hominis (Ie) C. hominis (Ie)* E392 C. hominis (Ib) C. hominis (Ie) K283 C. hominis (Ib) C. hominis (Id) 5395 C. hominis (Id) C. hominis (Id)* 5125 C. hominis C. hominis (Ia) D037 C. hominis C. hominis (Ia) 5492 C. hominis C. hominis (Id) 5471 C. hominis (Ib) C. parvum 5399 C. hominis (Ie) C. felis 5370 C. parvum C. hominis (Id) 5266 C. meleagridis C. hominis (Ib) H131 C. meleagridis C. hominis (Ia) 5082 C. meleagridis C. hominis 5300 C. felis C. hominis 5085 C. canis C. hominis 5049 C. hominis and C. parvum C. felis *Reinfections with the same subtype family. Cryptosporidium spp. and Subtypes and Associated Clinical Manifestations Distribution of species and subtype families at first infection among 109 Cryptosporidium spp.–infected children was similar to the distribution in all infection episodes. A second model analyzed the data from all infection episodes (Table 5). Table 5 Associations between infections with Cryptosporidium spp. or C. hominis subtype families and clinical manifestations expressed as incidence rate ratios in 533 children, Peru* Clinical manifestation First infection All infections IRR p value IRR p value Children infected with C. hominis vs. those with cryptosporidiosis but not infected with C. hominis Nausea 5.469 1 of the manifestations assessed in the study. Associated clinical manifestations at first infection varied among different Cryptosporidium spp. First infections with C. hominis were associated with nausea, vomiting, general malaise, and diarrhea (Table 5). In contrast, infections with other species were associated with diarrhea only. Patterns of clinical manifestations also varied among C. hominis subtype families. Infections with subtype family Ib were associated with nausea, vomiting, general malaise, and diarrhea. Infections with other subtype families (Ia, Id, and Ie) were generally associated with diarrhea only. A similar trend was also seen in the cumulative analysis of all infection episodes at the species and subtype family levels. A possible exception was C. hominis subtype family Ia, which showed an association with nausea and vomiting at first infections but did not show such an association in the cumulative analysis of all infection episodes (Table 5). Discussion Rates of clinical manifestations in our study were lower than rates reported for a birth cohort in Brazil, where 81% of 42 participants infected with C. hominis or C. parvum had diarrhea ( 13 ). This difference can be attributed to differences in study designs. Our study analyzed weekly stool samples for the presence of Cryptosporidium spp. and other parasites in a cohort of healthy children. In contrast, the cohort study in Brazil was designed to identify causes of diarrhea, and the specimens were collected within 2 weeks of clinical identification of diarrhea. C. hominis was the predominant species in this community-based longitudinal study, followed by C. parvum ( 7 ). This predominance of C. hominis has been observed in persons in other developing countries, such as pediatric populations from Malawi ( 19 ), Kenya ( 20 ), India ( 21 ), Haiti ( 22 ), and Brazil ( 13 ), children and elderly persons from South Africa ( 23 ), and hospitalized HIV-infected children from South Africa and Uganda ( 24 , 25 ). As reported in previous studies ( 21 , 24 , 26 , 27 ), we also detected few concurrent infections with multiple Cryptosporidium spp. or C. hominis subtype families. We observed a comparatively large proportion of participants infected with C. meleagridis, a finding that was also reported at a high frequency in HIV-infected adults in Lima, Peru ( 12 , 16 ). This species has been rarely reported for studies from other locations such as Portugal ( 28 ), India ( 21 , 26 , 29 ), Taiwan ( 30 ), or Iran ( 31 ) that included either children or adults with or without HIV infections. It should be noted that the diversity of Cryptosporidium spp. is also affected by the methods used. We used a genotyping tool proven to distinguish several dozen species and genotypes. However, methods based on genes coding for a 70-kDa heat-shock protein ( 32 ), Cryptosporidium spp. oocyst wall protein ( 33 ), or a smaller fragment of the small subunit rRNA gene ( 34 ) discriminate fewer Cryptosporidium spp. and genotypes. Overall, distribution of species and C. hominis subtype families in our study was similar to that found in an HIV study in Lima, Peru ( 12 , 16 ). These 2 studies were conducted in the same area but in different study populations. In both studies, all C. parvum specimens belonged to subtype family IIc, which is considered anthroponotic in origin ( 17 ). The normally zoonotic subtype family IIa was not seen in our study population. This finding is also supported by our risk factor data, which showed the lack of bovines in the study households and the absence of cattle farms in or near the community of Pampas de San Juan. The similarity of the species and subtype distribution in both studies is highly suggestive that the prevalence of Cryptosporidium spp. and subtypes in a specific location is independent of the immune status of the study population. The role of parasite genetics in clinical manifestations of cryptosporidiosis is not clear. Studies of human volunteers showed that exposure provided some degree of protection against infection and illness; the infection rates and frequencies of infection-associated clinical manifestations were lower for subsequent infections ( 35 ). Thus, clinical manifestations caused by parasite differences would be better observed in primary infections. Our longitudinal birth cohort study enrolled children at an early age (median 14 days), which enabled us to study genotypes and subtypes present at first infections and their associations with different clinical manifestations. First infections with all species and C. hominis subtype families were associated with diarrhea. However, only C. hominis subtype family Ib was also associated with nausea, vomiting, and general malaise, but C. hominis subtype families Ia, Id, and Ie, and other Cryptosporidium spp. were not. Previously, other studies had suggested that C. hominis might be more pathogenic than other species or might induce different clinical manifestations ( 13 , 15 , 21 ). Our results indicate that within C. hominis, subtype family Ib may be more pathogenic than Ia, Id, and Ie. Subtype family Ib of C. hominis is the most frequently detected Cryptosporidium spp. in waterborne outbreaks of cryptosporidiosis in industrialized nations ( 36 ). A previous study of cryptosporidiosis in HIV-infected persons in Peru showed that infections with different species or subtype families were associated with different clinical manifestations. Patients infected with subtype families Ib and Id of C. hominis, C. parvum, or C. canis/C. felis were more likely to have chronic diarrhea, and patients infected with C. parvum were more likely to have infection-associated vomiting ( 16 ). Overall, subtype family Id was the most virulent in the HIV study and was strongly associated with diarrhea in general and chronic diarrhea in particular. Subtype family Ib was also marginally associated with diarrhea and vomiting but not with chronic diarrhea. In this study, however, Id was only associated with diarrhea. This difference may be caused by the fact that chronic cryptosporidiosis, the life-threatening manifestation of the disease in AIDS patients, was never detected in this study of pediatric patients, and few children in this study were infected with subtype family Id, which might have prevented us from assessing its clinical manifestations fully. Nevertheless, our study corroborated the previous observation of defined patterns of clinical manifestations associated with different Cryptosporidium spp. and C. hominis subtype families. We also conducted a risk factor analysis for predictors of infection, including age at first infection, in which we did not identify statistically significant associations between any Cryptosporidium spp. or subtype families and any of the variables analyzed, although they covered basic aspects of sanitation and zoonotic, foodborne, and waterborne transmission. One possible explanation is that our questionnaires did not obtain data on factors that were relevant. However, the same questionnaire successfully identified infection risk factors for other organisms in the same community ( 2 ). A more likely explanation is that because most Cryptosporidium spp. in this study were anthroponotic in origin, children may be constantly exposed to these ubiquitous parasites through different transmission routes. Therefore, single exposure variables were not identified as risk factors. This constant exposure may also fit the age distribution pattern of cryptosporidiosis in the community, in which most cases are found in children <2 years of age, occasionally found in older children, and almost never found in immunocompetent adults. This finding is in contrast to transmission of Cryptosporidium spp. in industrialized nations, where infections have been frequently associated with waterborne transmission from either drinking water ( 37 ) or recreational water ( 38 ). In conclusion, clinical manifestations of cryptosporidiosis in healthy populations in disease-endemic areas are likely diverse, and the spectrum of these clinical manifestations can be attributed in part to the different species of Cryptosporidium and subtype families of C. hominis. Although further laboratory and longitudinal cohort studies in other disease-endemic areas are needed to validate our observations, these results demonstrate that parasite genetics may play an important role in the clinical manifestations of human cryptosporidiosis. Future studies should be conducted in different geographic settings; they should overcome some potential limitations of this study, such as lack of data on other gastrointestinal pathogens, which might have confounded the clinical findings, and small sample sizes, which had limited the power of the statistical analyses.

To assess the source and public health significance of Cryptosporidium oocyst contamination in storm runoff, a PCR-restriction fragment length polymorphism technique based on the small-subunit rRNA gene was used in the analysis of 94 storm water samples collected from the Malcolm Brook and N5 stream basins in New York over a 3-year period. The distribution of Cryptosporidium in this study was compared with the data obtained from 27 storm water samples from the Ashokan Brook in a previous study. These three watersheds represented different levels of human activity. Among the total of 121 samples analyzed from the three watersheds, 107 were PCR positive, 101 of which (94.4%) were linked to animal sources. In addition, C. hominis (W14) was detected in six samples collected from the Malcolm Brook over a 2-week period. Altogether, 22 Cryptosporidium species or genotypes were found in storm water samples from these three watersheds, only 11 of which could be attributed to known species/groups of animals. Several Cryptosporidium spp. were commonly found in these three watersheds, including the W1 genotype from an unknown animal source, the W4 genotype from deer, and the W7 genotype from muskrats. Some genotypes were found only in a particular watershed. Aliquots of 113 samples were also analyzed by the Environmental Protection Agency (EPA) Method 1623; 63 samples (55.7%) were positive for Cryptosporidium by microscopy, and 39 (78%) of the 50 microscopy-negative samples were positive by PCR. Results of this study demonstrate that molecular techniques can complement traditional detection methods by providing information on the source of contamination and the human-infective potential of Cryptosporidium oocysts found in water.