Jens G. Mattsson

Redescription of Neospora caninum and its differentiation from related coccidia

Neospora caninum is a protozoan parasite of animals, which before 1984 was misidentified as Toxoplasma gondii. Infection by this parasite is a major cause of abortion in cattle and causes paralysis in dogs. Since the original description of N. caninum in 1988, considerable progress has been made in the understanding of its life cycle, biology, genetics and diagnosis. In this article, the authors redescribe the parasite, distinguish it from related coccidia, and provide accession numbers to its type specimens deposited in museums.

From mouse to moose: multilocus genotyping of Giardia isolates from various animal species.

Giardia intestinalis is a protozoan parasite that consists of seven genetically distinct assemblages (A to G). Assemblage A and B parasites have been detected in a wide range of animals including humans, while the other assemblages (C to G) appear to have a narrower host range. However, the knowledge about zoonotic transmission of G. intestinalis is limited. To address this question, 114 Giardia isolates from various animals in Sweden including pets, livestock, wildlife and captive non-human primates were investigated by a sequence-based analysis of three genes (beta-giardin, glutamate dehydrogenase and triose phosphate isomerase). Assemblage A infections were detected in nine ruminants, five cats and one dog, while three sheep were infected with both assemblages A and E. Multilocus genotypes (MLGs) were defined for assemblage A, and three of these MLGs have previously been detected in Giardia isolates from humans. The newly described sub-assemblage AIII, until now reported mainly in wild hoofed animals, was found in one cat isolate. Assemblage B occurred in three monkeys, one guinea pig and one rabbit. The rabbit isolate exhibited sequences at all three loci previously detected in human isolates. The non-zoonotic assemblages C, D, E, F or G were found in the remaining 83 G. intestinalis isolates, which were successfully amplified and genotyped, generating a wide variety of both novel and known sub-genotypes. Double peaks in chromatograms were seen in assemblage B, C, D and E isolates but were never observed in assemblage A, F and G isolates, which can reflect differences in allelic sequence divergence. No evidence of genetic exchange between assemblages was detected. The study shows that multilocus genotyping of G. intestinalis is a highly discriminatory and useful tool in the determination of zoonotic sub-groups within assemblage A, but less valuable for subtyping assemblages B, C, D and E due to the high frequency of double peaks in the chromatograms. The obtained data also suggest that zoonotic transmission of assemblages A and B might occur to a limited extent in Sweden.

Development of a diagnostic PCR assay for the detection and discrimination of four pathogenic .Eimeria species of the chicken

We describe a polymerase chain reaction (PCR)-based assay for the detection, identification and differentiation of pathogenic species of .Eimeria in poultry. The internal transcribed spacer 1 (ITS1) regions of ribosomal DNA (rDNA) from .Eimeria acervulina, E. brunetti, E. necatrix and .E. tenella were sequenced and regions of unique sequences identified. Four pairs of oligonucleotide primers, each designed to amplify the ITS1 region of a single .Eimeria species, were synthesised for use in the PCR assay. In tests on purified genomic DNA from all seven species of .Eimeria that infect the chicken, each of the four primer pairs amplified the ITS1 region from only their respective target species. The robustness of the approach was further demonstrated by the amplification of specific DNA fragments from tissues of experimentally infected animals and from oocysts recovered from field samples. We conclude that the ITS1 regions of .Eimeria species contain sufficient inter-specific sequence variation to enable the selection of primers that can be applied in PCR analyses to detect and differentiate between species. In future work they may provide excellent markers for epidemiological studies.

In vitro amplification of the 16S rRNA genes from Mycoplasma bovis and Mycoplasma agalactiae by PCR.

Mycoplasma bovis and Mycoplasma agalactiae are two very closely related species which cause mastitis in cows and goats, respectively. M. bovis can also cause arthritis and respiratory disease in cattle. It has recently been shown that the 16S rRNA sequences differ only in 8 nucleotide positions between the two species [J.G. Mattsson, B. Guss and K.-E. Johansson (1994) FEMS Microbiol. Lett., 115: 325-328]. These nucleotide differences are distributed over the molecule in such a way that it is difficult to design specific identification systems, based on PCR only, for M. bovis and M. agalactiae. Two different PCR systems based on 16S rRNA sequence data have, however, been designed for these two species. The forward primers were identical in the two systems and complementary to a segment of the evolutionarily variable region V2. The reverse primers were complementary to the variable region V6, in which there are two nucleotide differences between M. bovis and M. agalactiae. The size of the PCR products, generated with these primers, was 360 bp. Cross-amplification was obtained with the two species in the heterologous PCR systems, but with approximately a 100-fold lower efficiency. Cross-amplification was not obtained with any other bovine or caprine mycoplasma except for Mycoplasma sp. strain A1343 of the caprine group 7. The detection limit of the PCR system for M. bovis with a reference culture was 4 x 10(2) CFU/ml and of the PCR system for M. agalactiae 2 x 10(2) CFU/ml. The M. bovis-PCR system was used to analyze nasal samples of calves from a herd where an outbreak of pneumonia had occured and it proved possible to detect M. bovis in these samples.

Rapid and sensitive identification of Neospora caninum by in vitro amplification of the internal transcribed spacer 1.

Neospora caninum and N. caninum-like organisms are cyst-forming coccidian parasites known to cause neuromuscular disorders in dogs and abortion in cattle. In this article we report on the use of the polymerase chain reaction (PCR) for the detection of DNA from N. caninum. After determining the sequence of the internal transcribed spacer 1 (ITS1) of N. caninum and Toxoplasma gondii, and part of the sequences for 4 species of Sarcocystis, we designed a primer set for the amplification of a 279-base-pair fragment of ITS1 from N. caninum. The PCR system made possible the specific detection of 5 N. caninum organisms and no amplification was observed from any of the other cyst-forming coccidia tested, including the closely related T. gondii. Furthermore, we were also able to demonstrate the presence of N. caninum in brain and lung tissue samples from experimentally infected mice. Our data also link the 5.8S rRNA gene for T. gondii and N. caninum to the 16S-like rRNA gene, within the rDNA unit.

Molecular epidemiology and clinical manifestations of human cryptosporidiosis in Sweden.

This study describes the epidemiology and symptoms in 271 cryptosporidiosis patients in Stockholm County, Sweden. Species/genotypes were determined by polymerase chain reaction-restriction fragment-length polymorphism (PCR-RFLP) of the Cryptosporidium oocyst wall protein (COWP) and 18S rRNA genes. Species were C. parvum (n=111), C. hominis (n=65), C. meleagridis (n=11), C. felis (n=2), Cryptosporidium chipmunk genotype 1 (n=2), and a recently described species, C. viatorum (n=2). Analysis of the Gp60 gene revealed five C. hominis allele families (Ia, Ib, Id, Ie, If), and four C. parvum allele families (IIa, IIc, IId, IIe). Most C. parvum cases (51%) were infected in Sweden, as opposed to C. hominis cases (26%). Clinical manifestations differed slightly by species. Diarrhoea lasted longer in C. parvum cases compared to C. hominis and C. meleagridis cases. At follow-up 25-36 months after disease onset, 15% of the patients still reported intermittent diarrhoea. In four outbreaks and 13 family clusters, a single subtype was identified, indicating a common infection source, which emphasizes the value of genotyping for epidemiological investigations.

Molecular characterisation of Cryptosporidium isolates from Swedish dairy cattle in relation to age, diarrhoea and region.

Cryptosporidium positive samples from 176 preweaned calves, young stock and cows of 48 herds were subjected to molecular characterisation of the 18S rRNA gene to determine which species are present in Swedish dairy cattle. In addition, samples characterised as Cryptosporidium parvum were further analysed at the GP60 gene to investigate distribution and zoonotic potential of subtypes. The 18S rRNA gene was successfully sequenced in 110 samples, with Cryptosporidium bovis in 83, C. parvum in 15, Cryptosporidium ryanae in 10, and Cryptosporidium andersoni in two samples. C. bovis was the most common species, being identified in 74% of calf samples, in 77% of young stock samples and in 100% of cow samples. The youngest calves infected with C. bovis were 7 days old, showing that the prepatent period is shorter than the previously stated 10 days. C. parvum was detected in 15 calves from nine farms, and samples were clustered in the southern parts of Sweden. Diarrhoeic calf samples contained C. parvum, C. bovis or C. ryanae. Sequencing of the GP60 gene was successful in 13 of the C. parvum samples. Eight subtypes, including three novel ones, were detected. Four of the subtypes have previously been identified in humans. This indicates that there is a zoonotic potential in C. parvum infected Swedish dairy calves.

Coccidial infections in commercial broilers: epidemiological aspects and comparison of Eimeria species identification by morphometric and polymerase chain reaction techniques

The objective of this study was to add to existing knowledge of the epidemiology and the aetiology of coccidial infections in commercial broiler flocks. Polymerase chain reaction (PCR) and morphometric identification of the Eimeria species were compared as means of differentiation in the field samples of faeces and litter. For morphometry, the Eimeria species were categorized into three groups based on lengths of the oocysts. Two random samples of commercial broilers were studied, one during 2000/01 and the other during 2003/04. The prophylactic regime (in-feed narasin), husbandry and methods applied were broadly the same for both subpopulations. Coccidial infection prevalence increased from approximately 45% to approximately 75% during this period, but infection levels (oocysts per gram of faeces) did not significantly change. There were substantial geographical differences in both prevalence and infection levels. A change in Eimeria species profile occurred during the study period. Five Eimeria species were identified at slaughter, by PCR targeting the ITS-1 region of the genome; Eimeria acervulina (100%), Eimeria tenella (77%), Eimeria maxima (25%), Eimeria praecox (10%) and Eimeria necatrix (2%). PCR and morphometric tentative identification were in complete agreement in only 49% of the cases.

Zoonotic transmission of Cryptosporidium meleagridis on an organic Swedish farm.

We believe that we present the first evidence of zoonotic transmission of the bird parasite, Cryptosporidium meleagridis. Despite being the third most common cause of human cryptosporidiosis, an identified zoonotic source has not been reported to date. We found Cryptosporidium oocysts in pigs, sheep/goats, hens and broiler chickens on a farm with suspected zoonotic transmission. By DNA analysis we identified C. meleagridis in samples from one human, three chickens and one hen. Sequencing of the ssrRNA and 70kDa Heat Shock Protein (HSP) genes showed identical C. meleagridis sequences in the human and chicken samples, which is evidence of zoonotic transmission. The HSP70 sequence was unique.

Paramyosin from the parasitic mite Sarcoptes scabiei : cDNA cloning and heterologous expression

The burrowing mite Sarcoptes scabiei is the causative agent of the highly contagious disease sarcoptic mange or scabies. So far, there is no in vitro propagation system for S. scabiei available, and mites used for various purposes must be isolated from infected hosts. Lack of parasite-derived material has limited the possibilities to study several aspects of scabies, including pathogenesis and immunity. It has also hampered the development of high performance serological assays. We have now constructed an S. scabiei cDNA expression library with mRNA purified from mites isolated from red foxes. Immunoscreening of the library enabled us to clone a full-length cDNA coding for a 102.5 kDa protein. Sequence similarity searches identified the protein as a paramyosin. Recombinant S. scabiei paramyosin expressed in Escherichia coli was recognized by sera from dogs and swine infected with S. scabiei. We also designed a small paramyosin construct of about 17 kDa that included the N-terminal part, an evolutionary variable part of the helical core, and the C-terminal part of the molecule. The miniaturized protein was efficiently expressed in E. coli and was recognized by sera from immunized rabbits. These data demonstrate that the cDNA library can assist in the isolation of important S. scabiei antigens and that recombinant proteins can be useful for the study of scabies.