Neospora caninum detected in feral rodents

The role of rodents in the epidemiology of neosporosis was investigated by assaying brain tissue of feral mice (Mus musculus) and rats (Rattus norvegicus) for Neospora caninum. Both mouse and rat brain tissue were extracted for total DNA, and subjected to two different N. caninum-specific nested polymerase chain reaction (PCR) assays. A portion of brain tissue from the mice and rats were also assayed for N. caninum in gerbils or gamma-interferon gene knockout (KO) mice. Of the 105 feral mice tested, 10% were positive in the N. caninum-specific PCR assays. Of the 242 rats tested, 30% were positive in both assays. Although mice and rats had N. caninum by PCR testing, clinical signs of N. caninum infection were not observed nor were N. caninum parasites observed in gerbils or KO mice inoculated with the rodent brain tissue.     

Finding of Neospora caninum in the wild brown rat (Rattus norvegicus)

Nine rats (16.4%) out of 55 (Rattus norvegicus) from cattle farms were seropositive to Neospora caninum. Two of the seropositive rats were also PCR positive but all were negative by immunohistochemistry and PAS staining. The brains of all the captured rats were homogenized and initially inoculated intraperitoneally into nude mice or into SPF ICR mice, which had been immunosuppressed with prednisolone. One mouse that was inoculated with brain material from a seropositive rat became infected with N. caninum, as demonstrated by the presence of a tissue cyst in the brain and confirmed by immunohistochemistry and PCR. This is the first finding of N. caninum in naturally infected farm rats. The findings show that natural N. caninum infection occurs in wild brown rats and thus rats may serve as a reservoir for the protozoan on the cattle farm.     

Comparison of two PCR protocols for the detection of Neospora caninum DNA in rodents

The objective of the present study was, due to increasing interest in the epidemiological role of small mammals as potential reservoir of Neospora caninum, to compare two different PCR protocols for the diagnosis of N. caninum in rodents. We tested tissue samples from 50 house mice (Mus musculus), 50 rats (Rattus norvegicus) and 35 field mice (Apodemus sylvaticus). Two different PCR protocols based on primer pairs, Np4-Np7 and Np6plus-Np21plus, were used for diagnosis on these samples. While there were not mismatches between the results of both PCR from rats or field mice, 49 out of 50 samples from house mice gave positive results with Np4-Np7 primer set. However after cloning and sequencing the PCR products, only six of these were confirmed to be N. caninum, while all the other 43 amplicons matched with house mice DNA sequence from clone RP23-14F5 on chromosome 11 sequence. Our results evidence that Np4-Np7 PCR could not be reliable in diagnosis of N. caninum in rodents.     

Neospora caninum and Toxoplasma gondii in brain tissue of feral rodents and insectivores caught on farms in the Netherlands

We investigated the presence of both Neospora caninum and Toxoplasma gondii in 250 brain tissue samples from 9 species of feral rodents and insectivores caught on 10 organic farms in the Netherlands in 2004. Collected samples were conserved in 4% paraformaldehyde solution and analysed by real-time PCR. For N. caninum, 31 samples originating from 6 species tested positive (12.4%): common shrews (33.3%), wood mice (17.6%), harvest mice (16.7%), house mice (15.4%), white-toothed shrews (10.8%) and common voles (4.2%). For T. gondii, the overall contamination level was 4%, and only three species were found to be positive: house mice (9.0%), common voles (4.2%) and white-toothed shrews (2.0%). Most N. caninum infected samples (27/31; 87%) were found on farms where dogs were present. Due to the observation that rodents and insectivores can contract both parasites, they might function as indicator species for the parasitic load on farms.     

Optimization of the use of C57BL/6 mice as a laboratory animal model for Neospora caninum vaccine studies

The development and testing of vaccines for Neospora caninum in mice require challenge studies to demonstrate a reduction in clinical signs or prevention of vertical transmission of the parasite after vaccination. Genetic susceptibility to N. caninum varies with the strain of mice. In this study, C57BL/6 mice were evaluated as a model for Neospora vaccine studies. A lethal challenge model was developed and the LD(50) was determined to be 1.5 x 10(7)N. caninum tachyzoites/mouse, delivered intraperitoneally. Brain lesions encountered in sections from sub-lethally challenged mice were scored on the basis of severity and total number of lesions to develop a histopathological scoring system for vaccine efficacy. A vertical transmission model for N. caninum vaccine studies was developed by studying mice that were infected either 2 weeks prior to mating or between days 12 and 14 of pregnancy. It was found that infection prior to mating reduced the average number of pups per litter. DNA extracted from fetal tissue was examined by a N. caninum specific polymerase chain reaction (PCR). The rate of vertical transmission was 0, 100 and 90.5% for the uninfected controls, mice infected during pregnancy and mice infected before mating, respectively. This study demonstrates that the C57BL/6 strain of mice is a good model for N. caninum vaccine studies because it is possible to establish a clear-cut lethal challenge model in C57BL/6 mice and they transmit the disease to their offspring efficiently.     

Isolation of Neospora caninum from naturally infected white-tailed deer (Odocoileus virginianus)

Attempts were made to isolate Neospora caninum from naturally infected white-tailed deer (Odocoileus virginianus). A total of 110 deer killed during the 2003 hunting season in Virginia region were used for the isolation of N. caninum. Of these, brains from 28 deer that had NAT titer of 1:200 were inoculated into interferon-gamma gene knock out (KO) mice. N. caninum was isolated from the tissues of three deer and all three isolates were mildly virulent to KO mice. Only one of the isolates could be adapted to in vitro growth. Protozoa in the tissues of KO mice reacted with N. caninum-specific polyclonal antibodies and N. caninum DNA was demonstrated in infected tissues by PCR assays; sequences of portions of the ITS-1 and gene 5 loci were identical to those in the public database. This is the first record of in vitro isolation of N. caninum from white-tailed deer and lends credence to the white-tailed deer as an intermediate host for this parasite.     

Immunohistochemical and polymerase chain reaction studies in Neospora caninum experimentally infected broiler chicken embryonated eggs

The diagnostic characteristics of immunohistochemistry (IHC) and polymerase chain reaction (PCR) methods were studied in the tissues of broiler chicken embryos experimentally infected by Neospora caninum. An infection with N. caninum NC-1 isolate was conducted in 70 broiler chicken embryonated eggs randomly divided into seven equal groups. After 8 days of incubation, six groups were inoculated with 10, 10(2), 10(3), 10(4), 10(5), and 10(6) doses of tachyzoites/embryonated egg. The 7th group was considered as control. The mortality rate and pathological changes of the dead embryos and hatched chickens up to 60 days old were noticed. Consecutive sections to those used for histopathological examination including the liver, heart, brain, and chorioalantoic (CA) membrane were subjected to IHC. The intensity and distribution of the immunostaining was graded as highly to mildly positive. For PCR procedure, DNA was extracted from 50mg of the tissues and primer pair Np21/Np6 was used for amplification of the Nc-5 gene. The results of the immunosignaling ranged from variable degrees of mild to moderate staining as dark-brown to brown and coarsely to finely granular, mostly within the cytoplasm of infected cells such as the endothelial cells of blood vessels. The parasite aggregation was more predominant in the heart than other tissues. Immunoreactivity for N. caninum antigen was multifocally moderate positive in the heart, liver and CA of the 10(3) dose, and also heart, liver, brain and CA of the 10(4) dose. IHC showed mildly positive in the liver and heart of the chicken embryos infected with 10 and 10(2) tachyzoites, as well. The results of the PCR confirmed the existence of the parasite in all of the examined tissues from the 10(3) and 10(4) doses. In conclusion, the results indicate a good agreement between IHC and PCR in diagnosis of neospora antigen in the infected tissues.     

Isolation and molecular detection of Neospora caninum from naturally infected sheep from Brazil

Neospora caninum was isolated from a naturally infected sheep from Brazil by bioassay in dogs. Approximately 70g of brain from each of two 4-month-old sheep with indirect fluorescent antibodies (>or=1:50) to N. caninum was offered to a different IFAT negative dog (Sheep n. 302, IFAT 1:400-Dog 1 and Sheep n. 342, IFAT 1:50-Dog 2). Parasite DNA was detected in both sheep brains using a PCR targeting the Nc-5 gene of N. caninum. Shedding of Neospora-like oocysts was noticed only in Dog 1, from 10 days post-inoculation (PI) to 25 days PI (a total of approximately 27,600 oocysts). Seventy days after infection, Dog 1 was euthanized and brain/cerebellum and medulla were collected and submitted to molecular methods, as were the oocysts, to confirm the identity of the isolate. Serum samples collected weekly from both dogs from the infection to the end of the experimental period had no antibodies anti-N. caninum by IFAT (<1:50). Oocysts, brain/cerebellum and medulla specimens of Dog 1 proved positive by a PCR assay targeting the Nc-5 gene of N. caninum. In addition, the oocysts have the DNA amplified by a PCR based on primers directed to the common toxoplasmatiid ITS1 sequence. The PCR products of ITS1 were sequenced, confirming again the isolate as N. caninum. Oocysts were also orally inoculated in two Swiss white mice two Mongolian gerbils (Meriones ungulatus) and two large vesper mice (Calomys callosus) (10(3)oocysts/animal). The rodents were sacrificed 2 months PI, and fresh preparations of brains showed Neospora thick-walled cysts in gerbil brains, but molecular detection using the Nc-5 PCR assay revealed DNA parasite in gerbil and also C. callosus brains. This is the first report of isolation and sequencing of N. caninum from a Brazilian sheep and the first report of molecular detection of N. caninum from C. callosus.     

Multimammate rat (Mastomys natalensis), Tristram's jird (Meriones tristrami) and Wagner's gerbil (Gerbillus dasyurus) as laboratory models of acute neosporosis

To test the different sensitivity of rodents of the subfamily Murinae and Gerbillinae, Wagner's gerbils (Gerbillus dasyurus), Tristram's jirds (Meriones tristrami) and multimammate rats (Mastomys natalensis) were inoculated with Neospora caninum tachyzoites. Clinical signs of neosporosis appeared in all inoculated animals. Histopathological examination confirmed the presence of tachyzoites in brains, lungs, skeletal muscle, myocardium, liver, in serosa of stomach and intestines, and in vesicular accessory genital glands. An examination of brains by PCR revealed presence of N. caninum DNA in all experimentally N. caninum infected rodents. The susceptibility of Wagner's gerbils and Tristram's jirds further proved the high sensitivity of gerbiline rodents to the N. caninum infection. The finding of N. caninum tachyzoites in the vesicular accessory genital glands of the infected gerbils suggests the usefulness of the rodent model for demonstration of N. caninum in the male reproductive system. Moreover, the multimammate rat was a susceptible experimental host to be the first immunocompetent rodent of the subfamily Murinae.     

Isolation of Neospora caninum from the brain of a naturally infected adult dairy cow

Neospora caninum was isolated from the brain of a 2-year-old dairy cow that had aborted confirmed N. caninum-infected fetuses on two occasions. The cow had an indirect fluorescent antibody titer of 1:1600 to N. caninum. The cow was killed 24 days after its second abortion and the brain was bioassayed for N. caninum in nude mice. Multifocal areas of perivascular cuffing and glial nodules were observed in the cerebrum and mesencephalon of the cow, but N. caninum was not identified in histological sections of the brain. All three nude mice inoculated with brain homogenate of the cow, developed emaciation and paralysis. Microscopical examination of the nude mice revealed systemic N. caninum infection with demonstrable tachyzoites in various organs. The parasites isolated from fresh mouse brain were transferred successfully into Vero cell cultures. PCR procedure on the purified tachyzoites obtained from the Vero cell cultures amplified the specific DNA sequence for N. caninum.     

牛源犬新孢子虫孕鼠感染模型的建立

为建立牛源犬新孢子虫孕鼠感染模型,深入研究牛源犬新孢子虫对孕鼠的致病作用,本试验以雌性BALB/c小鼠为试验动物,分离Vero细胞中培养的牛源犬新孢子虫速殖子,分不同剂量组腹腔接种雌性BALB/c小鼠后,与雄性BALB/c小鼠合笼,每天观察小鼠临床症状和发病情况,观察主要脏器组织的病理变化,应用PCR方法检测孕鼠脑、肝脏、脾脏等脏器组织及胎盘中犬新孢子虫Nc5基因,并测定孕鼠胎盘湿重和胎盘系数。结果显示,感染模型小鼠的最佳攻虫剂量为10⁵个虫体;感染犬新孢子虫孕鼠先后出现精神不振、共济失调等临床症状,并有不同程度死亡;病理学观察模型小鼠脑、肝脏、脾脏等脏器组织出现充血、出血、肿大等病理变化;在模型小鼠脑、肝脏、脾脏等脏器组织及胎盘中检测到犬新孢子虫Nc5基因;随攻虫天数的增加,模型小鼠胎盘重量和胎鼠重量均不断增加,胎盘系数逐步降低,在第12、14、16天时,模型组与对照组相比,胎盘重量和胎盘系数均差异显著（P < 0.05）。本试验成功建立了牛源犬新孢子虫孕鼠感染模型,为犬新孢子虫致病机制研究奠定了基础。     

Isolation and molecular characterisation of Neospora caninum in cattle in New Zealand

AIM: To isolate Neospora caninum from the brains of naturally infected cattle and use molecular techniques to characterise the isolates. METHODS: Neospora caninum tachyzoites were isolated in Vero cell culture from the brains of a cow and two calves. The isolates were characterised using polymerase chain reaction (PCR) methods, DNA sequencing, an immunofluorescent antibody test (IFAT), transmission electron microscopy (TEM), and immunohistochemistry (IHC). The brains of the three cattle were subjected to histopathological examination. A pathogenicity study was conducted in 120 BALB/c mice. RESULTS: Neospora caninum tachyzoites were isolated from all three cases and first observed in vitro between 14 and 17 days post-inoculation. Parasites were sub-cultured and maintained in Vero cell culture for more than 6 months. PCR products were generated for all three isolates, using two different primers. Sequencing of the PCR products and a subsequent BLAST search identified the isolates as N. caninum. In addition, the isolates tested positive using IFAT and IHC, and ultrastructure revealed by TEM was characteristic of N. caninum. Histopathological examination revealed lesions characteristic of N. caninum in 1/3 brains. In the pathogenicity study using BALB/c mice, the mortality rate was 3-7%. CONCLUSION: This was the first successful isolation of N. caninum in New Zealand confirmed using molecular characterisation tests.     

Experimental infection of dogs (Canis familiaris) with sporulated oocysts of Neospora caninum

Neospora caninum is widely distributed in the world and this parasite is one of the major causes of abortion in cattle. Dogs and coyotes are definitive hosts of N. caninum and several species of domestic and wild animals are intermediate hosts. Dogs can become infected by the ingestion of tissues containing cysts and then excrete oocysts. It is not yet known whether sporulated oocysts are able to induce a patent infection in dogs, i.e. a shedding of N. caninum oocysts in feces. The objective of this study was to experimentally examine the infection of dogs by sporulated oocysts. The oocysts used in the experiment were obtained by feeding dogs with brain of buffaloes (Bubalus bubalis) positive for anti-N. caninum antibodies by indirect fluorescent antibody test (IFAT ≥200). Oocysts shed by these dogs were confirmed to be N. caninum by molecular methods and by bioassay in gerbils, and sporulated N. caninum oocysts were used for the oral infection of four dogs. The dogs were 8 weeks old and negative for antibodies to N. caninum and Toxoplasma gondii. Dogs 1 and 4 received an inoculum of 10,000 sporulated oocysts each; dog 2 an inoculum of 5000 sporulated oocysts and dog 3 received 1000 sporulated oocysts of N. caninum. The total feces excreted by these dogs were collected and examined daily for a period of 30 days. No oocysts were found in their feces. The dogs were monitored monthly for a 6-month period to observe a possible seroconversion and when this occurred the animals were eliminated from the experiment. Dogs 1 and 4 seroconverted 1 month after the infection with titer, in the IFAT, of 1600 and 800, respectively; the other two dogs presented no seroconvertion during the 6-month period. Dogs 1 and 2 were euthanized 180 days after infection and were examined for the detection of N. caninum in tissues (brain, muscle, lymph node, liver, lung, heart and bone marrow) by immunohistochemistry and PCR with negative results in both techniques. Bioassay in gerbils with brain of these dogs was also performed and again the results were negative. In conclusion, dogs infected with sporulated oocysts of N. caninum were not able to shed oocysts in feces. However, a higher dose of infection stimulated the production of antibodies against N. caninum in the dogs.     

The use of PCR to detect Neospora caninum DNA in the blood of naturally infected cows

Twelve 2-year old heifers in their fifth month of gestation when pregnancy tested were used in this study. Six heifers aborted at approximately 4 months of gestation and had blood samples drawn less than 6 weeks after the abortions were identified. Blood samples were also drawn from three sero-positive pregnant and three sero-negative pregnant heifers. DNA was isolated from the samples and a 350 bp fragment of the Nc-5 gene was PCR amplified using primer pair Np21+ and Np6+. Also, the Internal Transcribed Spacer 1 (ITS1) was PCR amplified using Tim 3 and Tim 11 primer pair. The Nc-5 gene fragment was cloned, sequenced and the sequence BLAST-tested. Similarly, the ITS1 product was sequenced and BLAST-tested. The BLAST test results revealed that Neospora caninum DNA was present in these blood samples indicating that polymerase chain reaction can be used in the detection of N. caninum DNA in the blood of sero-positive cows.     

Red foxes (Vulpes vulpes) are a natural intermediate host of Neospora caninum

The present study was undertaken to determine if red foxes are natural intermediate and/or definitive host for Neospora caninum and to study the importance of infection of N. caninum in this species in North-eastern Spain. Faecal samples and brain tissues were obtained from 122 foxes from 21 rural areas of Catalonia. Faeces collected were examined for parasite eggs and coccidian oocysts using sucrose flotation. For PCR-based diagnosis of N. caninum in brain tissues, the specific genomic Nc5 region was selected as the target sequence for DNA amplification. To control for PCR failure and facilitate identification of truly negative samples, the competitor pNc5C molecule was added to all negative samples in a second round of PCR reactions. Of the 122 foxes analysed, 13 (10.7%) were positive by PCR for N. caninum. Signal intensities of all positive samples were relatively weak with the exception of one sample from a 3-month male animal, that also showed the highest repeatability. No differences were observed by sex, age or area of sampling analysis. Detection of stages of N. caninum in brain from naturally infected red foxes demonstrated that red foxes are a natural intermediate host for N. caninum. Faecal samples were analysed for the presence of N. caninum oocysts, however, no oocysts compatible with N. caninum were found. A widespread latent infection of red foxes in North-eastern Spain found in the present study indicates that red foxes could have a very important role in the epidemiology of neosporosis in our area.     

Gray wolf (Canis lupus) is a natural definitive host for Neospora caninum

The gray wolf (Canis lupus) was found to be a new natural definitive host for Neospora caninum. Neospora-like oocysts were found microscopically in the feces of three of 73 wolves from Minnesota examined at necropsy. N. caninum-specific DNA was amplified from the oocysts of all three wolves. Oocysts from one wolf were infective for the gamma interferon gene knock out (KO) mice. Viable N. caninum (designated NcWolfUS1) was isolated in cell cultures seeded with tissue homogenate from the infected mouse. Typical thick walled tissue cysts were found in outbred mice inoculated with the parasite from the KO mouse. Tissue stages in mice stained positively with N. caninum-specific polyclonal antibodies. Our observation suggests that wolves may be an important link in the sylvatic cycle of N. caninum.     

Isolation of Neospora caninum from dairy zero grazing cattle in Israel

First Israeli Neospora caninum isolates were obtained from brain tissues of aborted fetuses (NcIs491 and NcIs580) from dairy farms endemic for neosporosis and maintaining cattle on zero grazing. Tissues from different parts of the fetus brains were used to infect Vero cells. Tachyzoites of N. caninum were first observed in cultures from days 30 and 32 after infection. To confirm the identity of the isolated parasites, DNA extracts from brains and cultures were tested by PCR with specific primers based on the Nc5 gene. Specific fragments were amplified by PCR from infected cultures of both fetuses on day 25. Susceptible seronegative gerbils (Meriones tristrami) were inoculated intraperitoneally with 10(3) to 10(5) tenfold dilutions of subculture tachyzoites. The inoculated gerbils developed specific antibodies to N. caninum, with end-point serum dilution of 1:4096 in the IFA assay, whereas no neurological signs or deaths were seen during 4 months of observation.     

Studies on Neospora caninum DNA detection in the oocytes and embryos collected from infected cows

Neosporosis is a major cause of abortion in cattle over the world. One of the methods of preventing vertical transmission within the herd is to avoid breeding replacement heifers from infected dams. Another procedure suggested and recommended by the International Embryo Transfer Society (IETS) is embryo transfer (ET) from infected dams into uninfected recipients. Oocytes and embryos taken from seropositive cows were examined for the presence of Neospora caninum DNA. A modified PCR protocol using Np21 and Np6 primers was applied to detect parasite DNA in the samples. The expected 328 bp product was not obtained in oocytes and/or embryos collected from seropositive dams. The results confirmed that transfer of the embryos from seropositive donors into seronegative recipients is an appropriate method to eliminate vertical transmission of neosporosis in a herd. The present study demonstrated that oocytes and embryos are not exposed to N. caninum in the uterine cavity of seropositive dams.     

Serodiagnosis of Neospora caninum infection in cattle by enzyme-linked immunosorbent assay with recombinant truncated NcSAG1

Neospora caninum is a veterinary medically important pathogen capable of causing abortion in cattle and neuromuscular paralysis in dogs. The surface antigen 1 of N. caninum (NcSAG1) is an important candidate for the development of a diagnostic reagent for neosporosis. In order to establish an effective diagnostic method, the gene encoding truncated NcSAG1 (NcSAG1t) lacking a signal peptide and C-terminal hydrophobic regions was cloned and expressed in Escherichia coli as a fusion protein with glutathione S-transferase (GST). The purified GST-NcSAG1t was tested in an enzyme-linked immunosorbent assay (ELISA) for the detection of N. caninum antibodies in cattle. The ELISA with GST-NcSAG1t clearly differentiated between immunofluorescent antibody test (IFAT)-positive and -negative sera from cattle. In addition, the ELISA detected no cross-reactivity with sera from mice experimentally infected with the closely related parasite Toxoplasma gondii. Field serum samples collected from cattle in Brazil were examined for the diagnosis of neosporosis by using the ELISA. Of the 197 samples analyzed, 66 (33.5%) samples were positive for antibodies to N. caninum. Of the 66 ELISA-positive samples, 60 (90%) samples were confirmed as positive by Western blot analysis with whole parasite antigens. These results suggest that the recombinant NcSAG1t could be a reliable reagent for use as an antigen in ELISA for the serodiagnosis of N. caninum infection in cattle.     

Neospora hughesi: experimental infections in mice, gerbils, and dogs

Neospora hughesi is a recently described cause of equine protozoal myeloencephalitis (EPM). A rodent model for pathogenicity would facilitate development of therapies to be used in horses. In the present study, we examined the susceptibility of BALB/c gamma-interferon gene knockout (gamma-INFKO), BALB/c, CD-1, and C57BL/6 strains of mice and gerbils to infection with tachyzoites of the Nh-A1 strain of N. hughesi isolated from a horse from AL, USA. Only the gamma-IFNKO mice developed severe clinical disease following infection with N. hughesi and died 19-25 days after infection and exhibited severe cardiac lesions. In contrast, experimental infection of gamma-INFKO mice with tachyzoites of the NC-1 or NC-Liverpool strains of Neospora caninum resulted in deaths 8-10 days after infection. The most severe lesions were in the livers, spleens, and lungs of these mice. Gerbils inoculated with N. hughesi did not develop clinical disease, had few microscopic lesions, but did seroconvert. Two dogs fed the brains of mice, shown to contain N. hughesi tissue stages by cell culture and gamma-IFNKO mouse bioassay, did not shed N. caninum-like oocysts over a 23 days observation period. The marked difference in pathogenicity between the two species of Neospora in gamma-IFNKO mice, and lack of oocyst excretion by dogs fed N. hughesi infected mice provide additional evidence that the species distinction between N. caninum and N. hughesi is valid.