ABSTRACT
BACKGROUND: The intestinal protozoan parasite Cryptosporidium is an important cause of diarrheal disease worldwide. A national microbiological surveillance programme was implemented in Sweden in 2018 in order to increase knowledge of the molecular epidemiology of human cryptosporidiosis to better understand transmission patterns and potential zoonotic sources. This article summarises the results of the first five years of the surveillance programme. METHODS: Cryptosporidium-positive faecal and DNA samples from domestically acquired infections were collected from clinical microbiological laboratories in Sweden. Species and subtype determination was performed using 60 kDa glycoprotein and/or small subunit ribosomal RNA gene analysis. RESULTS: Between 2018 and 2022, 1654 samples were analysed and 11 different species were identified: C. parvum (n = 1412), C. mortiferum (n = 59), C. hominis (n = 56), C. erinacei (n = 11), C. cuniculus (n = 5), C. meleagridis (n = 3), C. equi (n = 2), C. ubiquitum (n = 2), and one each of C. canis, C. ditrichi and C. felis. Subtyping revealed seven subtype families of C. parvum (new subtype families IIy and IIz) and 69 different subtypes (11 new subtypes). The most common C. parvum subtypes were IIdA22G1c, IIdA24G1, IIdA15G2R1 and IIaA16G1R1b. For C. hominis, four different subtype families and nine different subtypes (two new subtypes) were identified. For additional species, two new subtype families (IIIk and VId) and nine new subtypes were identified. All successfully subtyped C. mortiferum cases were subtype XIVaA20G2T1, confirming previous findings in Sweden. Several outbreaks were identified of which the majority were foodborne and a few were due to direct contact with infected animals. CONCLUSION: Infection with C. parvum is the leading cause of human cryptosporidiosis acquired in Sweden, where more than 90% of domestic cases are caused by this zoonotic species and only a small proportion of cases are due to infection with other species. The rodent-associated C. mortiferum is considered an emerging zoonotic species in Sweden and the number of domestically acquired human cases has surpassed that of infection with C. hominis. A high diversity of species and subtypes, as well as diversity within the same subtype, was detected. Also, cryptosporidiosis appears to affect adults to a great extent in Sweden.
Subject(s)
Cryptosporidiosis , Cryptosporidium , Animals , Adult , Humans , Cryptosporidium/genetics , Cryptosporidiosis/epidemiology , Cryptosporidiosis/parasitology , Sweden/epidemiology , Genotype , Sequence Analysis, DNA , DNA, Protozoan/genetics , Feces/parasitologyABSTRACT
Entamoebapolecki is a parasite of human and nonhuman primates, other mammals, and birds. Due to overlapping morphological features, cysts of E. polecki may be confused with those of other Entamoeba species commonly found in human fecal samples, including immature cysts of Entamoeba histolytica Although the presence of E. polecki in human Entamoeba-positive stool samples may be rare, its prevalence is likely underestimated due to such confusion. Here, we give examples of diagnostic approaches applied so far and summarize data on the molecular epidemiology of E. polecki, including host specificity and phylogeography. Moreover, we evaluate a novel diagnostic conventional PCR developed for the screening of fecal samples for E. polecki The assay was highly sensitive and specific when used on genomic DNA extracted directly from stool and Swedish wastewater samples. The PCR enabled the identification of all four subtypes (ST1 to ST4) of E. polecki by PCR product sequencing. Most (23/28) subtyped E. polecki-positive samples detected in patients in Sweden between 2002 and 2015 reflected colonization by ST4 and were seen in travelers/foreigners. Two and three human cases of ST2 and ST3, respectively, were also detected. Subtypes 1, 2, and 3 were detected in 3/21 wastewater samples, suggesting local endemicity of these E. polecki subtypes; interestingly, ST4 was not detected in wastewater. In conclusion, the current PCR assay enables simple and cost-effective screening of fecal and wastewater samples for E. polecki Human cases of E. polecki appear to involve primarily ST4, while E. polecki detected in wastewater may be primarily of animal origin.
Subject(s)
Entamoeba/classification , Entamoeba/isolation & purification , Entamoebiasis/epidemiology , Entamoebiasis/parasitology , Molecular Diagnostic Techniques/methods , Polymerase Chain Reaction/methods , Wastewater/parasitology , Entamoeba/genetics , Entamoebiasis/diagnosis , Humans , Molecular Epidemiology , Prevalence , Sensitivity and Specificity , Sweden/epidemiologyABSTRACT
Cryptosporidium hominis is considered a strictly human-adapted species, and it is only occasionally diagnosed in animals. However, two variants, C. hominis monkey genotype and C. hominis Ik, were originally described in non-human hosts, monkeys and horses, respectively. During a Swedish national Cryptosporidium study, where all samples were analyzed at the small subunit rRNA and the 60â¯kDa (gp60) glycoprotein loci, we identified two patients infected with C. hominis monkey genotype (subtype IiA17) and two infected with C. hominis subtype IkA18G1. The isolates were further analyzed at the actin and the 70â¯kDa heat shock protein loci, and these analyses showed that these two subtype families are closely related to each other and to human-adapted C. hominis as well as to Cryptosporidium cuniculus. The two patients with C. hominis monkey genotype infection (a father and son) had visited a monkey farm in Thailand prior to infection, while the two cases with C. hominis Ik were unrelated, both probably infected in Sweden. This is the first time that a monkey genotype infection in humans has been related to contact with monkeys and where the gp60 subtype was identified. It is also the first time that human infection caused by C. hominis subtype Ik is described. Even though we were not able to detect any parasites in the animal samples, zoonotic transmission cannot be ruled out in any of these cases because both subtype families are regarded as animal adapted.
Subject(s)
Cryptosporidiosis/parasitology , Cryptosporidium/genetics , Actins/genetics , Adult , Animals , Base Sequence , Child , Cryptosporidiosis/epidemiology , Cryptosporidium/classification , DNA, Protozoan/chemistry , Feces/parasitology , Female , Genotype , HSP70 Heat-Shock Proteins/genetics , Haplorhini , Horses , Humans , Infant , Male , Middle Aged , Phylogeny , Real-Time Polymerase Chain Reaction , Sequence Alignment , Sialoglycoproteins/genetics , Sweden/epidemiology , TravelABSTRACT
BACKGROUND: In the winter and spring of 2011 a large outbreak of cryptosporidiosis occurred in Skellefteå municipality, Sweden. This study summarizes the outbreak investigation in terms of outbreak size, duration, clinical characteristics, possible source(s) and the potential for earlier detection using calls to a health advice line. METHODS: The investigation included two epidemiological questionnaires and microbial analysis of samples from patients, water and other environmental sources. In addition, a retrospective study based on phone calls to a health advice line was performed by comparing patterns of phone calls between different water distribution areas. RESULTS: Our analyses showed that approximately 18,500 individuals were affected by a waterborne outbreak of cryptosporidiosis in Skellefteå in 2011. This makes it the second largest outbreak of cryptosporidiosis in Europe to date. Cryptosporidium hominis oocysts of subtype IbA10G2 were found in patient and sewage samples, but not in raw water or in drinking water, and the initial contamination source could not be determined. The outbreak went unnoticed to authorities for several months. The analysis of the calls to the health advice line provides strong indications early in the outbreak that it was linked to a particular water treatment plant. CONCLUSIONS: We conclude that an earlier detection of the outbreak by linking calls to a health advice line to water distribution areas could have limited the outbreak substantially.
Subject(s)
Cryptosporidiosis/diagnosis , Cryptosporidiosis/epidemiology , Disease Outbreaks , Early Diagnosis , Hotlines/statistics & numerical data , Population Surveillance/methods , Water Supply/statistics & numerical data , Adolescent , Adult , Aged , Child , Child, Preschool , Cryptosporidium/isolation & purification , Disease Outbreaks/prevention & control , Disease Outbreaks/statistics & numerical data , Female , Humans , Infant , Infant, Newborn , Male , Middle Aged , Retrospective Studies , Seasons , Sewage/microbiology , Surveys and Questionnaires , Sweden/epidemiology , Water Purification , Young AdultABSTRACT
BACKGROUND: The diarrhea-causing protozoan Giardia intestinalis makes up a species complex of eight different assemblages (A-H), where assemblage A and B infect humans. Comparative whole-genome analyses of three of these assemblages have shown that there is significant divergence at the inter-assemblage level, however little is currently known regarding variation at the intra-assemblage level. We have performed whole genome sequencing of two sub-assemblage AII isolates, recently axenized from symptomatic human patients, to study the biological and genetic diversity within assemblage A isolates. RESULTS: Several biological differences between the new and earlier characterized assemblage A isolates were identified, including a difference in growth medium preference. The two AII isolates were of different sub-assemblage types (AII-1 [AS175] and AII-2 [AS98]) and showed size differences in the smallest chromosomes. The amount of genetic diversity was characterized in relation to the genome of the Giardia reference isolate WB, an assemblage AI isolate. Our analyses indicate that the divergence between AI and AII is approximately 1 %, represented by ~100,000 single nucleotide polymorphisms (SNP) distributed over the chromosomes with enrichment in variable genomic regions containing surface antigens. The level of allelic sequence heterozygosity (ASH) in the two AII isolates was found to be 0.25-0.35 %, which is 25-30 fold higher than in the WB isolate and 10 fold higher than the assemblage AII isolate DH (0.037 %). 35 protein-encoding genes, not found in the WB genome, were identified in the two AII genomes. The large gene families of variant-specific surface proteins (VSPs) and high cysteine membrane proteins (HCMPs) showed isolate-specific divergences of the gene repertoires. Certain genes, often in small gene families with 2 to 8 members, localize to the variable regions of the genomes and show high sequence diversity between the assemblage A isolates. One of the families, Bactericidal/Permeability Increasing-like protein (BPIL), with eight members was characterized further and the proteins were shown to localize to the ER in trophozoites. CONCLUSIONS: Giardia genomes are modular with highly conserved core regions mixed up by variable regions containing high levels of ASH, SNPs and variable surface antigens. There are significant genomic variations in assemblage A isolates, in terms of chromosome size, gene content, surface protein repertoire and gene polymorphisms and these differences mainly localize to the variable regions of the genomes. The large genetic differences within one assemblage of G. intestinalis strengthen the argument that the assemblages represent different Giardia species.
Subject(s)
Genome, Protozoan , Genomics , Giardia lamblia/genetics , Alleles , Diarrhea/parasitology , Female , Genes, Protozoan , Genome-Wide Association Study , Genomics/methods , Genotype , Giardia lamblia/classification , Giardia lamblia/isolation & purification , Giardiasis/parasitology , Humans , Multigene Family , Phylogeny , Polymorphism, Single Nucleotide , Protein TransportABSTRACT
Cryptosporidium chipmunk genotype I is an emerging zoonotic pathogen in humans. The lack of subtyping tools makes it impossible to determine the role of zoonotic transmission in epidemiology. To identify potential subtyping markers, we sequenced the genome of a human chipmunk genotype I isolate. Altogether, 9,509,783 bp of assembled sequences in 853 contigs were obtained, with an N50 of 117,886 bp and >200-fold coverage. Based on the whole-genome sequence data, two genetic markers encoding the 60-kDa glycoprotein (gp60) and a mucin protein (ortholog of cgd1_470) were selected for the development of a subtyping tool. The tool was used for characterizing chipmunk genotype I in 25 human specimens from four U.S. states and Sweden, one specimen each from an eastern gray squirrel, a chipmunk, and a deer mouse, and 4 water samples from New York. At the gp60 locus, although different subtypes were seen among the animals, water, and humans, the 15 subtypes identified differed mostly in the numbers of trinucleotide repeats (TCA, TCG, or TCT) in the serine repeat region, with only two single nucleotide polymorphisms in the nonrepeat region. Some geographic differences were found in the subtype distribution of chipmunk genotype I from humans. In contrast, only two subtypes were found at the mucin locus, which differed from each other in the numbers of a 30-bp minisatellite repeat. Thus, Cryptosporidium chipmunk genotype I isolates from humans and wildlife are genetically similar, and zoonotic transmission might play a potential role in human infections.
Subject(s)
Cryptosporidium/classification , Cryptosporidium/genetics , Genetic Variation , Genotype , Genotyping Techniques/methods , Animals , Cryptosporidiosis/parasitology , Cryptosporidiosis/transmission , Cryptosporidium/isolation & purification , Environmental Microbiology , Genetic Markers , Genome, Protozoan , Humans , Molecular Sequence Data , New York , Peromyscus , Protozoan Proteins/genetics , Sciuridae , Sequence Analysis, DNA , Sweden , Zoonoses/parasitology , Zoonoses/transmissionABSTRACT
In November 2010, ≈27,000 (≈45%) inhabitants of Östersund, Sweden, were affected by a waterborne outbreak of cryptosporidiosis. The outbreak was characterized by a rapid onset and high attack rate, especially among young and middle-aged persons. Young age, number of infected family members, amount of water consumed daily, and gluten intolerance were identified as risk factors for acquiring cryptosporidiosis. Also, chronic intestinal disease and young age were significantly associated with prolonged diarrhea. Identification of Cryptosporidium hominis subtype IbA10G2 in human and environmental samples and consistently low numbers of oocysts in drinking water confirmed insufficient reduction of parasites by the municipal water treatment plant. The current outbreak shows that use of inadequate microbial barriers at water treatment plants can have serious consequences for public health. This risk can be minimized by optimizing control of raw water quality and employing multiple barriers that remove or inactivate all groups of pathogens.
Subject(s)
Cryptosporidiosis/epidemiology , Cryptosporidium/isolation & purification , Adolescent , Adult , Aged , Aged, 80 and over , Child , Child, Preschool , Cryptosporidiosis/microbiology , Disease Outbreaks , Female , Humans , Infant , Infant, Newborn , Male , Middle Aged , Sweden/epidemiology , Water , Water Microbiology , Water Purification/methods , Water Supply , Young AdultABSTRACT
Cryptosporidium meleagridis is a common cause of cryptosporidiosis in avian hosts and the third most common species involved in human cryptosporidiosis. Sequencing of the highly polymorphic 60-kDa glycoprotein (gp60) gene is a frequently used tool for investigation of the genetic diversity and transmission dynamics of Cryptosporidium. However, few studies have included gp60 sequencing of C. meleagridis. One explanation may be that the gp60 primers currently in use are based on Cryptosporidium hominis and Cryptosporidium parvum sequence data, potentially limiting successful amplification of the C. meleagridis gp60 gene. We therefore aimed to design primers for better gp60 subtyping of C. meleagridis. Initially, â¼1,440 bp of the gp60 locus of seven C. meleagridis isolates were amplified using primers flanking the open reading frame. The obtained sequence data (â¼1,250 bp) were used to design primers for a nested PCR targeting C. meleagridis. Twenty isolates (16 from human and 4 from poultry) previously identified as C. meleagridis by analysis of small subunit (SSU) rRNA genes were investigated. Amplicons of the expected size (â¼900 bp) were obtained from all 20 isolates. The subsequent sequence analysis identified 3 subtype families and 10 different subtypes. The most common subtype family, IIIb, was identified in 12 isolates, represented by 6 subtypes, 4 new and 2 previously reported. Subtype family IIIe was found in 3 isolates represented by 3 novel, distinct subtypes. Finally, IIIgA31G3R1 was found in 1 human isolate and 4 poultry isolates, all originating from a previously reported C. meleagridis outbreak at a Swedish organic farm.
Subject(s)
Cryptosporidiosis/diagnosis , Cryptosporidium/classification , Cryptosporidium/genetics , Genetic Variation , Genotyping Techniques/methods , Protozoan Proteins/genetics , Animals , Cryptosporidium/isolation & purification , DNA Primers/genetics , DNA, Protozoan/chemistry , DNA, Protozoan/genetics , Genotype , Glycoproteins/genetics , Humans , Molecular Sequence Data , Polymerase Chain Reaction , Poultry , Sequence Analysis, DNAABSTRACT
As data accumulate in GenBank, the difficulties of delineating species of Cryptosporidium based on nuclear small subunit ribosomal RNA (ssu rRNA) gene information alone becomes increasingly evident. Here, we summarize currently available evidence suggesting that several ssu rDNA sequences primarily referred to as Cryptosporidium suis (some of them from non-suid hosts) should be considered Cryptosporidium occultus.
Subject(s)
Cryptosporidiosis , Cryptosporidium , DNA, Ribosomal , Cryptosporidium/genetics , Cryptosporidium/classification , Cryptosporidium/isolation & purification , Cryptosporidiosis/parasitology , Animals , DNA, Ribosomal/genetics , DNA, Protozoan/genetics , Humans , Phylogeny , Sequence Analysis, DNA/methodsABSTRACT
Cases of cryptosporidiosis in humans have been reported with strong indication of transmission from rodents. Here, we report seven new human cases of cryptosporidiosis involving rodent-adapted species (Cryptosporidium ditrichi [n = 1], Cryptosporidium mortiferum [n = 4; previously known as Cryptosporidium chipmunk genotype I], Cryptosporidium tyzzeri [n = 1], and Cryptosporidium viatorum [n = 1]) and review cases of human infection caused by these four species published to date. The seven new cases were detected in Denmark within a period of twelve months from 2022 to 2023. Only the C. tyzzeri and C. viatorum cases were associated with travel outside Denmark. The total number of human cases of cryptosporidiosis due to C. ditrichi and C. tyzzeri documented to date globally are still limited (4 and 7, respectively), whereas cases involving C. viatorum and C. mortiferum have been detected to a larger extent (43 and 63 cases, respectively). The four new cases of C. mortiferum were all of the XIVaA20G2T1 subtype, which is the only subtype identified so far in Scandinavia, and which is a subtype not yet found outside of Scandinavia. The new C. viatorum case was identified as the XVaA3g subtype. The C. tyzzeri case was subtyped as IXbA6. No subtype data were produced for C. ditrichi due to lack of a subtype assay. Review of existing data suggests the presence of C. ditrichi and C. mortiferum primarily in northern countries and C. tyzzeri and C. viatorum primarily in warmer climates. While our data may further support the role of Cryptosporidium as a cause of zoonotic disease, case descriptions should be obtained where possible to determine if Cryptosporidium species primarily adapted to rodents are the likely cause of symptoms or just an incidental finding.
ABSTRACT
Cryptosporidiosis is an infectious enteric disease caused by species (some of them zoonotic) of the genus Cryptosporidium that in many countries are under surveillance. Typing assays critical to the surveillance of cryptosporidiosis typically involve characterization of Cryptosporidium glycoprotein 60 genes (gp60). Here, we characterized the gp60 of Cryptosporidium suis from two samples-a human and a porcine faecal sample-based on which a preliminary typing scheme was developed. A conspicuous feature of the C. suis gp60 was a novel type of tandem repeats located in the 5' end of the gene and that took up 777/1635 bp (48%) of the gene. The C. suis gp60 lacked the classical poly-serine repeats (TCA/TCG/TCT), which is usually subject to major genetic variation, and the length of the tandem repeat made a typing assay incorporating this region based on Sanger sequencing practically unfeasible. We therefore designed a typing assay based on the post-repeat region only and applied it to C. suis-positive samples from suid hosts from Norway, Denmark, and Spain. We were able to distinguish three different subtypes; XXVa-1, XXVa-2, and XXVa-3. Subtype XXVa-1 had a wider geographic distribution than the other subtypes and was also observed in the human sample. We think that the present data will inform future strategies to develop a C. suis typing assay that could be even more informative by including a greater part of the gene, including the tandem repeat region, e.g., by the use of long-read next-generation sequencing.
Subject(s)
Cryptosporidiosis , Cryptosporidium , Tandem Repeat Sequences , Animals , Cryptosporidiosis/parasitology , Cryptosporidiosis/epidemiology , Swine , Humans , Cryptosporidium/genetics , Cryptosporidium/classification , Phylogeny , Swine Diseases/parasitology , Protozoan Proteins/genetics , Feces/parasitologyABSTRACT
Iodamoeba is the last genus of obligately parasitic human protist whose phylogenetic position is unknown. Iodamoeba small subunit ribosomal DNA sequences were obtained using samples from three host species, and phylogenetic analyses convincingly placed Iodamoeba as a sister taxon to Endolimax. This clade in turn branches among free-living amoeboflagellates of the genus Mastigamoeba. Two Iodamoeba ribosomal lineages (RL1 and RL2) were detected whose sequences differ by 31%, each of which is found in both human and nonhuman hosts.
Subject(s)
Archamoebae/genetics , Evolution, Molecular , Amebiasis/parasitology , Animals , Archamoebae/classification , Cluster Analysis , Cysts , DNA/analysis , DNA/chemistry , Genetic Variation , Humans , Phylogeny , Ribosome Subunits, Small, Eukaryotic/genetics , SwineABSTRACT
Most human cases of cryptosporidiosis are caused by Cryptosporidium parvum or Cryptosporidium hominis, but the use of molecular diagnostic methods has revealed that several other less common species or genotypes can also be involved. Here, we describe two unusual causes of cryptosporidiosis, one being the recently described species Cryptosporidium viatorum and the other Cryptosporidium chipmunk genotype I. Two Swedish patients who were infected with C. viatorum had travelled to Kenya and Guatemala, respectively, and two others had been infected with Cryptosporidium chipmunk genotype I in Sweden. None of these four patients were immunocompromised, and all four showed classical symptoms of cryptosporidiosis. We performed extensive molecular characterization, including analysis of four loci. The two C. viatorum isolates were found to differ slightly at the 70-kDa heat shock protein locus, which may indicate a local geographical variation in this species that has previously been described exclusively on the Indian subcontinent.
Subject(s)
Cryptosporidiosis/parasitology , Cryptosporidium/classification , Cryptosporidium/genetics , Adult , Animals , Child, Preschool , Cryptosporidiosis/epidemiology , Female , Genotype , Humans , Male , Middle Aged , Phylogeny , Sweden/epidemiology , TravelABSTRACT
BACKGROUND: Genetic heterogeneity has become a major inconvenience in the genotyping and molecular epidemiology of the intestinal protozoan parasite Giardia intestinalis, in particular for the major human infecting genotype, assemblage B. Sequence-based genotyping of assemblage B Giardia from patient fecal samples, where one or several of the commonly used genotyping loci (beta-giardin, triosephosphate isomerase and glutamate dehydrogenase) are implemented, is often hampered due to the presence of sequence heterogeneity in the sequencing chromatograms. This can be due to allelic sequence heterozygosity (ASH) and /or co-infections with parasites of different assemblage B sub-genotypes. Thus, two important questions have arisen; i) does ASH occur at the single cell level, and/or ii) do multiple sub-genotype infections commonly occur in patients infected with assemblage B, G. intestinalis isolates? RESULTS: We used micromanipulation in order to isolate single Giardia intestinalis, assemblage B trophozoites (GS isolate) and cysts from human patients. Molecular analysis at the tpi loci of trophozoites from the GS lineage indicated that ASH is present at the single cell level. Analyses of assemblage B Giardia cysts from clinical samples at the bg and tpi loci also indicated ASH at the single cell level. Additionally, alignment of sequence data from several different cysts that originated from the same patient yielded different sequence patterns, thus suggesting the presence of multiple sub-assemblage infections in congruence with ASH within the same patient. CONCLUSIONS: Our results conclusively show that ASH does occur at the single cell level in assemblage B Giardia. Furthermore, sequence heterogeneity generated during sequence-based genotyping of assemblage B isolates may possess the complexity of single cell ASH in concurrence with co-infections of different assemblage B sub-genotypes. These findings explain the high abundance of sequence heterogeneity commonly found when performing sequence based genotyping of assemblage B Giardia, and illuminates the necessity of developing new G. intestinalis genotyping tools.
Subject(s)
Giardia lamblia/genetics , Heterozygote , Alleles , DNA, Protozoan/chemistry , DNA, Protozoan/genetics , Genetic Variation , Genotype , Giardia lamblia/isolation & purification , Giardiasis/parasitology , Humans , Molecular Sequence Data , Sequence Analysis, DNA , TrophozoitesABSTRACT
BACKGROUND: Frozen blood clots remaining after serum collection is an often disregarded source of host and pathogen DNA due to troublesome handling and suboptimal outcome. METHODS: High-speed shaking of clot samples in a cell disruptor manufactured for homogenization of tissue and faecal specimens was evaluated for processing frozen blood clots for DNA extraction. The method was compared to two commercial clot protocols based on a chemical kit and centrifugation through a plastic sieve, followed by the same DNA extraction protocol. Blood clots with different levels of parasitaemia (1-1,000 p/µl) were prepared from parasite cultures to assess sensitivity of PCR detection. In addition, clots retrieved from serum samples collected within two epidemiological studies in Kenya (n = 630) were processed by high speed shaking and analysed by PCR for detection of malaria parasites and the human α-thalassaemia gene. RESULTS: High speed shaking succeeded in fully dispersing the clots and the method generated the highest DNA yield. The level of PCR detection of P. falciparum parasites and the human thalassaemia gene was the same as samples optimally collected with an anticoagulant. The commercial clot protocol and centrifugation through a sieve failed to fully dissolve the clots and resulted in lower sensitivity of PCR detection. CONCLUSIONS: High speed shaking was a simple and efficacious method for homogenizing frozen blood clots before DNA purification and resulted in PCR templates of high quality both from humans and malaria parasites. This novel method enables genetic studies from stored blood clots.
Subject(s)
Blood/parasitology , DNA/isolation & purification , Hemoglobin H/genetics , Malaria/diagnosis , Plasmodium/genetics , Specimen Handling/methods , alpha-Thalassemia/diagnosis , Child, Preschool , DNA/genetics , Freezing , Humans , Infant , Kenya , Malaria/parasitology , Polymerase Chain Reaction/methods , Sensitivity and SpecificityABSTRACT
In this study we describe a novel protocol for rapid molecular analysis of patient samples using a combination of real-time polymerase chain reaction (PCR) and Sanger sequencing. This would normally take 2 working days in the diagnostic laboratory, but using this protocol the process can be completed within 3 h using equipment normally found in the laboratory. The innovative steps in this protocol are the sequencing of the product generated in the diagnostic real-time PCR, addition of a sequencing tail to the PCR primer, which increases the quality of the sequence without loss of sensitivity or specificity, and optimization of the hands-on and instrument steps using modern reagents. The read length of the sequencing step is routinely 250 nucleotides, which is substantially longer than existing rapid sequencing methods, increasing the chances of covering several genetic markers within 1 analysis. As proof of the concept, we used the detection and genotyping of the intestinal parasite Giardia lamblia, but the protocol can be applied to any PCR and sequence-based analysis.
Subject(s)
Clinical Laboratory Techniques/methods , Molecular Diagnostic Techniques/methods , Polymerase Chain Reaction/methods , Sequence Analysis, DNA/methods , DNA Primers/genetics , Humans , Sensitivity and Specificity , Time FactorsABSTRACT
The intestinal protozoan parasite Cryptosporidium is an important cause of diarrheal disease worldwide. The aim of this study was to expand the knowledge on the molecular epidemiology of human cryptosporidiosis in Sweden to better understand transmission patterns and potential zoonotic sources. Cryptosporidium-positive fecal samples were collected between January 2013 and December 2014 from 12 regional clinical microbiology laboratories in Sweden. Species and subtype determination was achieved using small subunit ribosomal RNA and 60 kDa glycoprotein gene analysis. Samples were available for 398 patients, of whom 250 (63%) and 138 (35%) had acquired the infection in Sweden and abroad, respectively. Species identification was successful for 95% (379/398) of the samples, revealing 12 species/genotypes: Cryptosporidium parvum (n = 299), C. hominis (n = 49), C. meleagridis (n = 8), C. cuniculus (n = 5), Cryptosporidium chipmunk genotype I (n = 5), C. felis (n = 4), C. erinacei (n = 2), C. ubiquitum (n = 2), and one each of C. suis, C. viatorum, C. ditrichi, and Cryptosporidium horse genotype. One patient was co-infected with C. parvum and C. hominis. Subtyping was successful for all species/genotypes, except for C. ditrichi, and revealed large diversity, with 29 subtype families (including 4 novel ones: C. parvum IIr, IIs, IIt, and Cryptosporidium horse genotype Vic) and 81 different subtypes. The most common subtype families were IIa (n = 164) and IId (n = 118) for C. parvum and Ib (n = 26) and Ia (n = 12) for C. hominis. Infections caused by the zoonotic C. parvum subtype families IIa and IId dominated both in patients infected in Sweden and abroad, while most C. hominis cases were travel-related. Infections caused by non-hominis and non-parvum species were quite common (8%) and equally represented in cases infected in Sweden and abroad.
ABSTRACT
Most cases of cryptosporidiosis in humans are caused by Cryptosporidium parvum or Cryptosporidium hominis. However, more uncommon species are increasingly being recognised to cause infection in humans. Here we report that Cryptosporidium chipmunk genotype I, which has various rodents as its natural host, is the third most common source of human cryptosporidiosis in Sweden. We also describe the first small outbreak of cryptosporidiosis caused by Cryptosporidium chipmunk genotype I and report the first case of zoonotic transmission of Cryptosporidium chipmunk genotype I from a red squirrel to a human. Cryptosporidium chipmunk genotype I was identified in 20 human cases, including 16 sporadic cases, three outbreak-related cases, and one zoonotic case, as well as in two squirrel samples. Gp60 subtyping which was successful for 19 human cases and two squirrel samples showed that all samples harboured the same subtype, XIVaA20G2T1. The work presented here suggests that red squirrel is a natural host of Cryptosporidium chipmunk genotype I and that infection with Cryptosporidium chipmunk genotype I is an emerging cause of domestic cryptosporidiosis in Sweden and a potential source of outbreaks.
Subject(s)
Cryptosporidiosis/epidemiology , Cryptosporidium/genetics , Disease Outbreaks , Genotype , Sciuridae , Zoonoses/epidemiology , Adolescent , Adult , Aged , Animals , Child, Preschool , Cryptosporidiosis/parasitology , Female , Humans , Infant , Male , Middle Aged , Sweden/epidemiologyABSTRACT
A method using a single-round PCR coupled to pyrosequencing was developed for the detection and differentiation of members of the Entamoeba complex. The technique was evaluated using DNA isolated directly from faecal specimens and compared with a duplex real-time PCR targeting Entamoeba histolytica and Entamoeba dispar, and a conventional single-round PCR for the detection of Entamoeba moshkovskii. Tetranucleate cysts from 102 faecal specimens from Swedish, Danish and Dutch patients test-positive for the Entamoeba complex by coproscopic examination were identified to species using each of the three methods. Although none of the patients were confirmed to be positive for E. moshkovskii, E. histolytica and E. dispar were identified in 17 and 86 of the samples, respectively, one of the samples containing both species. There was concordance in results between pyrosequencing and the two other methods used. This study showed that PCR and pyrosequencing could be used for the rapid and high throughput identification of Entamoeba species.
Subject(s)
Entamoeba/classification , Entamoeba/genetics , Sequence Analysis, DNA/methods , Temperature , Base Sequence , Entamoeba/isolation & purification , Humans , Molecular Sequence Data , RNA, Ribosomal/genetics , Ribosome Subunits, Small/geneticsABSTRACT
During May and June 2009 an outbreak of Cyclospora cayetanensis infection involving 12 laboratory-confirmed and 6 probable cases was detected in Stockholm County, Sweden. Imported sugar snap peas from Guatemala were the suspected vehicle, based on information obtained from patient questionnaires. This is the first reported outbreak of cyclosporiasis in Sweden and the second in Europe.