Stig Milan Thamsborg

Cryptosporidium andersoni from a Danish cattle herd: identification and preliminary characterisation

In November 1997, Cryptosporidium andersoni, for the first time, was isolated from a Danish heifer. The isolate was characterised morphologically, molecularly, and furthermore inoculated into mice and one calf. Data on the distribution of cryptosporidia in the herd of origin were obtained at two separate visits in December 1997 and April 1998. C. andersoni was detected in 27 (19.0%) of 142 cattle examined at the first visit, whereas C. parvum was found in six (4.2%). At the following visit 42 (28.0%) of 150 cattle excreted C. andersoni, while 25 (16.7%) were positive for C. parvum. Oocysts of the Danish C. andersoni isolate were ovoid, 7.3(6.5-8.0) x 5.7(5.0-7.0) microm(2) (n=25), with smooth, colourless, single layer oocyst wall and distinct oocyst residuum. The length to width ratio was 1.27 (1.14-1.40, n=25). The identification was verified by sequencing of a 246bp fragment of the rDNA, which was identical to Cryptosporidium muris, the calf genotype (AF093496). The Danish C. andersoni isolate was not transmissible to mice, whereas oocysts were detected in the faeces of one experimentally infected calf from 25 days post-infection (DPI) and shed intermittently at low numbers until 165 DPI, the day of euthanasia. No macroscopic or microscopic changes that could be attributed to infection with C. andersoni were seen in the gastro-intestinal tract of the experimentally infected calf following necropsy and histological examination. This is to our knowledge the first report of C. andersoni in Scandinavia.

Molecular characterization of Danish Cryptosporidium parvum isolates.

The genetic polymorphism among 271 Danish Cryptosporidium isolates of human and animal origin was studied by partial amplification and sequencing of the Cryptosporidium oocyst wall protein (COWP) gene, the 1 8S rDNA, and a microsatellite locus. Furthermore, the microsatellite locus was studied directly using fragment analysis. A comparative analysis of DNA sequences showed the presence of 3 different subgenotypes (Cl, C2 and C3) in C. parvum isolates from Danish cattle, with prevalences of 16.7, 17.2 and 73.1% including 13 (7.0%) mixed infections. Subgenotype Cl was significantly more prevalent (P < 0.001) in the southern part of Denmark. In Cryptosporidium isolates of human origin the anthroponotic subgenotype H1 was identified, in addition to the zoonotic subgenotypes C1, C2, and C3. Of 44 human samples, 56.8% were anthroponotic, whereas 40.9% were zoonotic genotypes. One human isolate was characterized as C. meleagridis. The porcine Cryptosporidium isolates (N = 4) revealed a pattern which was genetically distinct from human and bovine isolates. Cryptosporidium in a hedgehog (Erinaceus europaeus L.) was identified for the first time. By microsatellite sequencing the hedgehog isolate showed a subgenotype distinct from the previously detected types. The assignment to subgenotype by microsatellite sequencing and fragment typing was 100% identical in samples where results were achieved by both methods. In addition, the fragment analysis proved more sensitive, easier, faster, and less expensive compared to sequencing.

Pathogenicity of Cryptosporidium parvum—evaluation of an animal infection model

Abstract With the intention of developing a standardised method for assessment of pathogenicity of Cryptosporidium parvum, the CPB-0 isolate was studied by propagation in 1-day-old calves followed by inoculation into specific pathogen free (SPF) piglets. The experiment was repeated. Diarrhoea and shedding of oocysts were seen in all animals infected with the CPB-0 isolate. Clinical signs included depression, inappetence, vomiting (exclusively in the piglets), and death. Histological examination at 17 and 19 days post-infection revealed parasitic stages and microscopic changes primarily restricted to colon and rectum. The unintended presence of rotavirus in some of the experimental animals revealed an additive or synergistic effect between rotavirus and C. parvum as indicated by prolonged diarrhoea, increased oocyst shedding, decreased weight gain and elevated levels of serum haptoglobin and serum amyloid A (SAA) in piglets infected simultaneously with both pathogens. The difference in daily weight gain between infected and control animals was significant only for piglets co-infected with rotavirus. The acute phase response of haptoglobin and SAA was characterised by a large individual variation. In piglets, co-infected with rotavirus, the levels of serum haptoglobin were 3.5 and 4.6 times higher in the infected versus the controls 6 and 9dpi, respectively (mean values: 2411 μg/ml±S.D. 2023 and 1840 μg/ml±S.D. 1697). In the controls infected with rotavirus, peak haptoglobin concentration was seen 3dpi (mean: 1022 μg/ml±S.D. 425). Elevated levels of SAA were seen in 1 of 6 piglets infected with C. parvum, and in 5 of 6 piglets co-infected with rotavirus. Tumour necrosis factor alpha (TNFα) was undetectable in all serum samples from piglets. The obvious advantages of the SPF pig model are the naturally acquired intestinal microflora, the development of distinct clinical signs similar to cryptosporidiosis in humans and calves, the size of the animals, and the accessibility of individuals born within a short time span. This makes the model ideal for dose–response studies, evaluation of therapeutic agents as well as for assessment of differences in the clinical response to isolates of diverse genetic background. In conclusion, it was shown that the CPB-0 isolate was pathogenic to calves and piglets at a dose of 2.5×105 oocysts, and that the clinical signs could be replicated during separate experiments. Moreover, diarrhoea, oocyst shedding, body weight changes, histological alterations, and the acute phase response of haptoglobin and SAA were identified as useful parameters for discrimination of isolate-specific differences of pathogenicity.