Isolation and genetic characterization of Neospora caninum from naturally infected sheep.

Neospora caninum is considered one of the main causes of abortion in cattle but can also cause abortion in sheep. There is limited knowledge of the N. caninum population infecting sheep, and only one N. caninum isolate from a pregnant sheep from Japan has been reported. This study describes the in vitro isolation and genetic characterization of two new sheep isolates of N. caninum implicated in ovine reproductive failure. We used IFN-γ-knockout mice inoculated with PCR-positive brain homogenates from two clinically healthy but congenitally infected lambs at 4.5 months of age for parasite isolation. The lambs were born to dams from a sheep farm that had experienced pregnancy failure caused by N. caninum in successive generations. Tachyzoites were microscopically visualized in peritoneal flushes from all inoculated mice and were also observed in MARC-145 cell cultures within one week after inoculation with peritoneal flushes. Two N. caninum isolates, Nc-Spain11 and Nc-Spain12, were obtained from each lamb. The genotyping of the Nc-Spain11 and Nc-Spain12 isolates based on 9 microsatellite markers showed identical multilocus genotype (MLG). Comparison between a previous N. caninum genotype dataset including 80 MLGs from Argentinean, Spanish, Mexican, German and Scottish bovine isolates and the Japanese sheep isolate showed that the Nc-Spain11 and Nc-Spain12 MLG was unique and differed from the other MLGs. eBURST analyses showed that the Nc-Spain11 and Nc-Spain12 MLG was genetically clustered with other bovine MLGs and one ovine MLG, and the nearest genetic relationship was with an MLG from a bovine abortion collected in the same geographical area of Galicia.

Validation of IMP dehydrogenase inhibitors in a mouse model of cryptosporidiosis.

Cryptosporidium parasites are a major cause of diarrhea and malnutrition in the developing world, a frequent cause of waterborne disease in the developed world, and a potential bioterrorism agent. Currently, available treatment is limited, and Cryptosporidium drug discovery remains largely unsuccessful. As a result, the pharmacokinetic properties required for in vivo efficacy have not been established. We have been engaged in a Cryptosporidium drug discovery program targeting IMP dehydrogenase (CpIMPDH). Here, we report the activity of eight potent and selective inhibitors of CpIMPDH in the interleukin-12 (IL-12) knockout mouse model, which mimics acute human cryptosporidiosis. Two compounds displayed significant antiparasitic activity, validating CpIMPDH as a drug target. The best compound, P131 (250 mg/kg of body weight/day), performed equivalently to paromomycin (2,000 mg/kg/day) when administered in a single dose and better than paromomycin when administered in three daily doses. One compound, A110, appeared to promote Cryptosporidium infection. The pharmacokinetic, uptake, and permeability properties of the eight compounds were measured. P131 had the lowest systemic distribution but accumulated to high concentrations within intestinal cells. A110 had the highest systemic distribution. These observations suggest that systemic distribution is not required, and may be a liability, for in vivo antiparasitic activity. Intriguingly, A110 caused specific alterations in fecal microbiota that were not observed with P131 or vehicle alone. Such changes may explain how A110 promotes parasitemia. Collectively, these observations suggest a blueprint for the development of anticryptosporidial therapy.

Leishmania spp. parasite isolation through inoculation of patient biopsy macerates in interferon gamma knockout mice.

Isolation of Leishmania parasite and species identification are important for confirmation and to help define the epidemiology of the leishmaniasis. Mice are often used to isolate pathogens, but the most common mouse strains are resistant to infection with parasites from the Leishmania (Viannia) subgenus. In this study we tested the inoculation of interferon gamma knockout (IFNgamma KO) mice with biopsy macerates from Leishmania-infected patients to increase the possibility of isolating parasites. Biopsies from twenty five patients with clinical signs of leishmaniasis were taken and tested for the presence of parasites. Immunohistochemical assay (IHC) and conventional histopathology detected the parasite in 88% and 83% of the patients, respectively. Leishmania sp. were isolated in biopsy macerates from 52% of the patients by culture in Grace's insect medium, but 13% of isolates were lost due to contamination. Inoculation of macerates in IFNgamma KO mice provides isolation of parasites in 31.8% of the biopsies. Most isolates belong to L. (Viannia) subgenus, as confirmed by PCR, except one that belongs to L. (Leishmania) subgenus. Our preliminary results support the use of IFNgamma KO mice to improve the possibility to isolate New World Leishmania species.

Leishmania spp. parasite isolation through inoculation of patient biopsy macerates in interferon gamma knockout mice / Leishmania spp.: isolamento de parasitos pela inoculação de macerados de biopsias de pacientes em camundongos deficientes em interferon gama

Isolation of Leishmania parasite and species identification are important for confirmation and to help define the epidemiology of the leishmaniasis. Mice are often used to isolate pathogens, but the most common mouse strains are resistant to infection with parasites from the Leishmania (Viannia) subgenus. In this study we tested the inoculation of interferon gamma knockout (IFNγ KO) mice with biopsy macerates from Leishmania-infected patients to increase the possibility of isolating parasites. Biopsies from twenty five patients with clinical signs of leishmaniasis were taken and tested for the presence of parasites. Immunohistochemical assay (IHC) and conventional histopathology detected the parasite in 88 percent and 83 percent of the patients, respectively. Leishmania sp. were isolated in biopsy macerates from 52 percent of the patients by culture in Grace's insect medium, but 13 percent of isolates were lost due to contamination. Inoculation of macerates in IFNγ KO mice provides isolation of parasites in 31.8 percent of the biopsies. Most isolates belong to L. (Viannia) subgenus, as confirmed by PCR, except one that belongs to L. (Leishmania) subgenus. Our preliminary results support the use of IFNγ KO mice to improve the possibility to isolate New World Leishmania species.

O isolamento e a identificação da espécie de parasito do gênero Leishmania são importantes para a confirmação e auxiliam na epidemiologia da leishmaniose. Os camundongos são freqüentemente utilizados para isolar patógenos, porém, as linhagens mais comuns de camundongos são resistentes à infecção por parasitos do subgênero Leishmania (Viannia). Neste estudo, avaliamos a inoculação de macerados de biópsias de pacientes infectados em camundongos deficientes do gene do interferon gama (IFNγ KO) como um método para aumentar a possibilidade de isolar Leishmania spp. Biópsias de 25 pacientes infectados com Leishmania sp. foram avaliadas para a presença de parasitos pelos métodos de imunohistoquímica (IHC) e histopatologia convencional. Os parasitos foram observados, respectivamente, em 88 por cento e 83 por cento das biópsias. Leishmania sp. foi isolada de macerados de biópsia de 52 por cento dos pacientes infectados, quando cultivados em meio Grace, porém, 13 por cento destes isolados foram perdidos devido a contaminações. Inoculação dos macerados em camundongos IFNγ KO proporcionou o isolamento de parasitos oriundos de 31,8 por cento dos pacientes. A maioria dos isolados pertence ao subgênero L. (Viannia), exceto um que pertence ao subgênero L. (Leishmania), como confirmado pela reação da polimerase em cadeia. Nossos resultados preliminares sugerem que o uso de camundongos IFNγ KO pode ser útil para aumentar a possibilidade de isolamento de leishmânias encontradas nas Américas.

The temperature-sensitive mutants of Toxoplasma gondii and ocular toxoplasmosis.

The risk of blindness caused by ocular toxoplasmosis supports efforts to improve our understanding for control of this disease. In this study, the involvement of CD8(+), CD4(+), B cell, and IL-10 gene in the immune response of primary ocular infection with the temperature-sensitive mutant (ts-4) of the RH Toxoplasma gondii strain, and in the protective immunity of ocular ts-4 vaccination and challenge with RH strain was investigated in murine models utilizing inbred C57BL/6 mice-deficient in CD4(+), CD8(+), B cells (microMT), or IL-10 gene. Compared to naive mice, all WT and mutant mice had different degree of ocular pathological changes after ts-4 ocular infection, in which both CD8 KO and IL-10 KO mice showed the most severe ocular lesions. Immunized by ts-4 intracameral (i.c.) inoculation, all mutant mice had partially decreased vaccine-induced resistance associated with increased ocular parasite burdens after RH strain challenge. A significant increase of the percentages of B cells and CD8(+) T cells in the draining lymph nodes were observed in WT and IL-10 KO mice after either infection or challenge. The levels of specific anti-toxoplasma IgG in both eye fluid and serum from all the mice were significantly increased after ts-4 i.c. immunization, except microMT mice. These results suggest that the avirulent ts-4 of T. gondii inoculated intracamerally can induce both ocular pathology and ocular protective immunity; CD4(+), CD8(+), B cell, and IL-10 gene are all necessary to the vaccine-induced resistance to ocular challenge by virulent RH strain, in which CD8(+) T cells are the most important component.

High-yield amplification of Cryptosporidium parvum in interferon gamma receptor knockout mice.

To date, large-scale production of Cryptosporidium parvum oocysts has only been achieved by amplification in neonatal calves and sheep. Many laboratories currently depend on supplies from external sources and store oocysts for prolonged periods which results in progressive loss of viability. Six to 8-week-old interferon gamma receptor knockout (IFN gamma R-KO) mice on a C57BL/6 background were inoculated by gavage (2000 oocysts/animal). Fecal pellets were collected daily from 7 days post-infection (p.i.) up to 2 weeks p.i. Intestinal oocyst yield was assessed at days 11, 12 and 14 p.i. by homogenization of intestinal tissues. Ether extraction and one or more NaCl flotations were used to purify oocysts. Total recoveries averaged 2.6 x 10(6) oocysts/mouse from fecal material and 3.8 x 10(7) oocysts/mouse from intestinal tissues. Overall, 2.3 x 10(9) purified oocysts were obtained from 60 mice. Recovered oocysts were capable of sporulation and were shown to be infectious both in vitro and in vivo. Oocyst amplification was achieved in only 11-14 days with minimal expense. The simplicity of this method presents a practical alternative for the routine passage, maintenance and storage of C. parvum in biomedical laboratories.

The chromosomes of Rodentolepis nana (Siebold, 1852) Spasskii, 1954 obtained from naturally infected mice conventionally maintained in a Braziuan laboratory animal house.

The karyotype of Rodentolepis nana obtained from mice in Rio de Janeiro, Brazil, was described. The diploid chromosome number obtained by the division of embryonic cells was 2n = 12. The first and the third pairs presented subterminal centromeres and the other pairs were all acrocentric. The studied species differed in chromosome morphology when compared to previous description by Mutafova and Gergova (1994) in Bulgaria, suggesting an intraspecific variation.

Evaluation of the effects of sulfamethoxazole on Toxoplasma gondii loads and stage conversion in IFN-gamma knockout mice using QC-PCR.

Toxoplasma gondii abundance with or without sulfamethoxazole treatment was evaluated by quantitative competitive polymerase chain reaction (QC-PCR) assay in various organs of IFN-gamma knockout BALB/c (B/c) mice after peroral infection with the cyst-forming Fukaya strain. T. gondii infection was observed in the brain, skin, tongue, heart, and skeletal muscle of the mice treated with sulfamethoxazole, although the parasite was not observed during the treatment in the mesenteric lymph node, spleen, small intestine or kidney. After discontinuing the therapy, T. gondii reappeared within five days in all organs. Reverse transcriptase (RT)-PCR showed that sulfamethoxazole treatment accelerated the stage conversion of T. gondii from tachyzoites into bradyzoites in the brain, lung, and heart. In contrast, after discontinuing sulfamethoxazole treatment, T. gondii underwent stage conversion from bradyzoites into tachyzoites in these organs. These results indicate that we successfully established an animal model for evaluating chemotherapy regimens in immunocompromised hosts infected with T. gondii.

Determinants for resistance and susceptibility to microfilaraemia in Litomosoides sigmodontis filariasis.

Filarial infections of humans are chronic diseases. Despite an ongoing immune response, adult filariae continuously produce their offspring, the microfilariae (Mf), which are able to persist in sufficient numbers to ensure transmission. In this study, host- and parasite-derived factors, which contribute to persistence of Mf, were investigated using the filariasis model of Litomosoides sigmodontis in mice. Different strains of mice were found to differ widely in their capability to eliminate circulating Mf. Studies of congenic mouse strains showed that early and rapid clearance of Mf was mediated by activation pathways relevant to innate immunity, whereas late or delayed clearance of Mf was pre-determined by MHC-related factors. Genetic knock-out of genes for the MHC class-II molecules totally abrogated resistance. Most interestingly, the presence of only I adult female, but not male worms, renders all mice susceptible, irrespective of the genetic background, enabling Mf to circulate for extended periods of time. Such prolonged microfilaraemia was also observed in L. sigmodontis-infected animals challenged with heterologous Mf of Acanthocheilonema viteae. The use of cytokine gene knock-out mice showed that persistence of L. sigmodontis Mf was facilitated by IL-10, but not by IL-4 or IFN-gamma. In conclusion, irrespective of a resistant or susceptible host genetic background, survival of Mf of L. sigmodontis in mice is decisively regulated by the presence of adult female L. sigmodontis which will skew and exploit immune responses to facilitate the survival and persistence of their offspring in the infected host.

Organ infectivity of Toxoplasma gondii in interferon-gamma knockout mice.

To determine the influence of interferon (IFN)-gamma on the organ infectivity and on the genetic susceptibility of susceptible (C57BL/6) and resistant (BALB/c) strains after peroral infection with cysts of Toxoplasma gondii. IFN-gamma knockout (KO) mice in C57BL/6 and BALB/c backgrounds were utilized. The kinetics of the changes in T. gondii abundance were evaluated with a quantitative competitive polymerase chain reaction assay in various organs at different times after peroral infection. In IFN-gamma KO mice, a T. gondii-specific gene, SAG1, was detected in all organs examined, and the protozoan proliferated much more actively than in wild-type mice. The abundance of T. gondii was much higher in mesenteric lymph nodes and the heart than in other organs. In contrast, in the nervous system organs and kidneys, only a weakly detectable reaction was observed. Toxoplasma gondii grew at a more rapid rate in the organs of IFN-gamma KO C57BL/6 mice than in the organs of IFN-gamma KO BALB/c mice during the course of infection. Destruction of the IFN-gamma gene showed remarkable effects on the infectivity in both susceptible and resistant mice.

Migration and development of Sarcocystis neurona in tissues of interferon gamma knockout mice fed sporocysts from a naturally infected opossum.

Migration and development of Sarcocystis neurona was studied in 50 gamma interferon knockout mice fed graded doses of S. neurona sporocysts from the intestine of a naturally infected opossum. Mice were examined at necropsy 1-62 days after feeding sporocysts (DAFS). All tissue sections were reacted with anti-S. neurona-specific polyclonal rabbit serum in an immunohistochemical (IHC) test. Between 1 and 3 DAFS, organisms were seen mainly in intestines. Between 4 and 11 DAFS, organisms were seen in several visceral tissues. Beginning with 13 DAFS, schizonts and merozoites were present in sections of brains of all infected mice. All regions of the brain were parasitized but the hind brain was most severely affected. S. neurona was found in the spinal cord of all 10 mice examined 22-30 DAFS. Of the 28 infected mice examined 20-62 DAFS, S. neurona was found in the brains of all 28, lungs of 14, hearts of 8 and eyes of 3. More organisms were seen in IHC-stained sections than in sections stained with hematoxylin and eosin. Treatment of tissues with glutaraldehyde, Karnovsky fixative, and ethylene diamino tetra acetic acid (EDTA, used for decalcification) did not affect staining of organisms by IHC.

[Regulation of the immune response to intestinal nematode infections in mice]. / Regulacja odpowiedzi immunologicznej na inwazje nicieni jelitowych u myszy.

Control of parasitic infections is dependent on mechanisms that limit invasion, reproduction or survival of the parasite, including elevated serum IgE, eosinophilia and intestinal mast cell hyperplasia. Studies with mice infected with Heligmosomoides polygyrus, Trichuris muris, Nippostrongylus brasiliensis and Trichinella spiralis have provided considerable information about immune mechanisms correlated with resistance and susceptibility. Activation and cytokine secretion of distinct Th cell subset leads to the generation of effective or ineffective responses resulting in clearance of the parasite load or maintenance of chronic infection. The induction of differential responses remains to be determined but is likely to be influenced at a number of levels including the host genetic background, involvement of accessory cells, activation of co-stimulatory molecules on antigen presenting cells. The regulation of responses to intestinal nematode infections is discussed.

gamma delta T-cells may interfere with a productive immune response in Plasmodium yoelii infections.

Mice lacking alpha beta T-cells or gamma delta T-cells were infected with Plasmodium yoelii 17X NL (non-lethal) and followed for parasitaemia and cytokine production. While the parasitaemia in wild type mice resolved after reaching a peak value of 30 to 50%, it persisted in the -alpha beta T-cell mice until death. However, in the -gamma delta T-cell mice the peak parasitaemia was 12.5% of the levels seen in the wild type and -alpha beta T-cell mice and resolved faster than in the wild type mice. Higher levels of IL-10 and IFN-gamma were consistently found in the wild type and -gamma delta T-cell mice but not in the -alpha beta T-cell mice.