Animal infectivity of Encephalitozoon cuniculi.

Rabbits, mice, rats and Rhesus monkeys were infected experimentally with a rabbit isolate of the mammalian microsporidan Encephalitozoon cuniculi. The lesions produced were typical of those occurring in spontaneous encephalitozoonosis in rabbits, mice, and rats, respectively. Viable E. cuniculi were recovered from tissues of injected animals with and without lesions. Titration of rabbit, mouse, and hamster isolates of E. cuniculi in mice and in rabbit choroid plexus cell cultures showed that the rabbit isolate was equally infectious for mice and cell cultures. Mouse and hamster isolates were less infectious for cell cultures than for mice. The results provide further evidence that the mouse, hamster, and rabbit isolates of E. cuniculi are identical.     

Effect of fumagillin on in vitro multiplication of Encephalitozoon cuniculi

Encephalitozoon cuniculi (Levaditi, Nicolau & Schoen) is an obligate intracellular pathogenic parasite of rabbits, carnivores, laboratory rodents, and a variety of other mammals. Cell cultures of rabbit and canine cells were infected with rabbit and dog isolates of E. cuniculi. Four days later 5 microgram/ml of fumagillin was introduced into the culture medium. The multiplication of the parasite was inhibited within 48 h and this effect was maintained as long as the antibiotic remained in the medium. There was no effect when spores and proliferative forms of the parasite were incubated with fumagillin before being used for infecting host cells. No infection occurred, however, if the antibiotic was added to the culture medium before introduction of E. cuniculi. On electron-microscopic examination, the treated parasites were found to have severe cytoplasmic swelling, vesicular distortion of the plasma membrane, and marked reduction in cytoplasmic ribosomes. it was concluded that fumagillin blocks multipliation of E. cuniculi in vitro. The drug may be useful for the treatment or prevention of spontaneous encephalitozoonosis.     

Application of immunofluorescence to the establishment of an Encephalitozoon cuniculi-free rabbit colony.

Serologic screening of a rabbit breeding colony over a 9-month period showed that all 9-week-old rabbits with Encephalitozoon cuniculi infection were born of E cuniculi-infected does. This observation, obtained from studies on 395 young rabbits, suggested that transmission of infection is either transplacental or the result of close contact soon after birth. On this basis, 16 young healthy rabbits, seronegative to E cuniculi, were isolated and tested at 2-week intervals for antibodies to E cuniculi. In the first 2 months, seven rabbits showed indications of developing antibodies to E cuniculi and were immediately removed from the colony. The remaining rabbits along with their 52 offspring were tested for serum antibodies for a further 16 months and no rabbit became seropositive. Eight months after establishment of the colony, three does, one buck and six 12-week-old rabbits were killed. Macroscopic and extensive histologic and immunofluorescence examinations failed to reveal any evidence of infection with E cuniculi. These results showed that serological screening for E cuniculi infection by immunofluorescence is a simple yet adequate procedure for establishing a rabbit colony free of encephalitozoonosis.     

An investigation of the route and progression of Encephalitozoon cuniculi infection in adult rabbits.

Rabbits infected either orally or intratracheally with cell culture-grown Encephalitozoon cuniculi were monitored regularly for serum antibody levels and E. cuniculi in the urine. Their responses were compared with intravenously inoculated and uninoculated control rabbits. All rabbits receiving E. cuniculi developed serum antibodies, generally within 3 weeks, and excreted E. cuniculi by 6 weeks. In the acute stage of infection, the organs most affected were lung, kidney and liver; the brain and gut were unaffected. However, during chronic infection, the brain, kidney, and heart were the only organs found to be involved. Antibody levels were very high at this stage. Thus both the oral and tracheal routes may be normal routes of infection with E. cuniculi in adult rabbits.     

应用不同代次兔肾细胞培养风疹病毒松叶株的研究

目的为提高兔肾细胞产量用于增加风疹病毒生产。方法 SPF级家兔肾细胞经传代培养10代,对不同代次兔肾细胞进行遗传稳定性、外源因子及兔脑原虫检测后接种风疹病毒松叶株(Matsuba strain)的试验。结果兔肾细胞产量得到提高,由1对兔肾平均生产1瓶细胞增加为8瓶,细胞核型检查传至第10代的细胞染色体数目与初代细胞一致,细胞培养物均一性提高。第0～第3代细胞病毒培养物滴度间无显著性差异,χ2检验返回相关性的P值均大于0.95。结论第1～第3代细胞培养风疹病毒与第0代相比,可获得相同滴度的病毒培养物,p3代兔肾细胞应用于疫苗生产可显著提高细胞及病毒产量。     

Effects of gamma radiation on viability of Encephalitozoon spores

Spores of Encephalitozoon cuniculi, E. hellem, and E. intestinalis harvested from cultured mammalian cells were suspended in deionized water, exposed to gamma irradiation at doses of 0-3.0 kGy, and then tested for infectivity by inoculating spores into monolayer cultures of Madin-Darby bovine kidney cells. The cultures were examined for developing microsporidia 4 days later. As the dosage level of radiation increased, corresponding decreases were observed in the number of developing microsporidia for all 3 species. For E. cuniculi and E. intestinalis, 100% inhibition of development was observed after exposure to 1.5 and 2.0 kGy, respectively. Although development of E. hellem was greatly inhibited (97.6% inhibition) after exposure to 3.0 kGy, complete inhibition was not obtained. These findings provide a baseline for investigating the dose levels required to render food products safe when kept under varying temperature, moisture, and other storage conditions.     

Mechanisms of resistance to the intracellular protozoan Encephalitozoon cuniculi in mice

Mechanisms of resistance to the obligate intracellular protozoan Encephalitozoon cuniculi were studied in BALB/c mice. Resistance to lethal disease was T cell-dependent because transfer of T-enriched, but not T-depleted, spleen cells from sensitized BALB/c donors would protect infected BALB/c-nu mice. A modified focus-forming assay was utilized to measure effects on E. cuniculi infectivity in vitro. The results show that antibodies exert an opsonization effect and may block parasite entry into nonphagocytic cells. No cytotoxic T cells were demonstrated. Supernatants from E. cuniculi-sensitized spleen cells incubated with E. cuniculi in vitro could induce adherent PEC to kill E. cuniculi.     

Sensitivity of Encephalitozoon cuniculi to various temperatures, disinfectants and drugs.

Spores of Encephalitozoon cuniculi were exposed to various temperature or to disinfectants, and their infectivity was then tested on monolayer cultures of canine kidney cells. The maximum survival time for spores suspended in medium 199 was 1 day at -20 degrees C, 98 days at 4 degrees C, 6 days at 22 degrees C, and 2 days at 37 degrees C. Only 2.5% survived 30 min at 56 degrees C. Boiling for 5 min or autoclaving at 120 degrees C for 10 min killed all spores. Dry spores survived less than a week at 4 degrees C but at least 4 weeks at 22 degrees C. Exposure for 30 min to recommended working concentrations of 9 of the 11 disinfectants tested killed all spores. The growth-inhibition effect of 7 antibiotics and chemotherapeutics was studied on canine kidney cell culture inoculated with E. cuniculi. None could completely inhibit growth. The most effective was chloroquine phosphate which, at a concentration of 12.5 mg per 1000 ml culture medium and during a test period of 8 weeks, reduced the harvest of E. cuniculi to 31% of that from inoculated, untreated cultures.     

Rabbit intestinal xenograft model for human Encephalitozoon infections in mice.

BACKGROUND AND PURPOSE: The gastrointestinal tract is a common portal of entry for Encephalitozoon cuniculi, one of several microsporidial organisms emerging as opportunistic pathogens in immunocompromised humans. Although most human microsporidial pathogens can be propagated in vitro and in a variety of laboratory animals, an experimental animal system to specifically study intestinal uptake and systemic spread of these organisms does not exist. METHODS: Paired segments of near-term fetal rabbit small intestine were implanted subcutaneously into 25 athymic nude or 10 severe combined immune deficient mice. Five weeks after surgery, 65 xenografts were inoculated intraluminally with E. cuniculi (n = 14), E. intestinalis (n = 27), E. hellem (n = 20), or RK-13 cells (n = 2), or were left uninoculated (n = 2). RESULTS: Intestinal xenograft infection with E. cuniculi (n = 11), E. intestinalis (n = 17), and E. hellem (n = 18) was determined by light microscopy; control xenografts remained uninfected. Extraintestinal infection with E. cuniculi developed in host mouse brain, respiratory tract, spleen, salivary glands, and gastrointestinal tract (3 of 3 mice), and infection with E. intestinalis developed in the liver (8 of 15 mice). CONCLUSION: Intestinal xenografts provide a unique, sterile, and biologically relevant animal model system for studying host enterocyte/parasite interactions, mechanisms of microsporidial pathogenicity, antimicrosporidial chemotherapeutic agents, and immune effector mechanisms. This model provides evidence for persistent graft infection with three Encephalitozoon spp., and for intestinal spread of E. cuniculi and E. intestinalis from infected enterocytes in immunoincompetent mice.     

Encephalitozoonosis in pharmacologically immunosuppressed mice

Encephalitozoon cuniculi is a parasite that has been identified as a cause of opportunistic infections in immunocompromised individuals. This study was performed to evaluate E. cuniculi infection in pharmacologically immunosuppressed mice. Mice were immunosuppressed with cyclophosphamide (100mg/kg twice a week, IP) or cyclosporin (10mg/kg daily, IP) and inoculated with 10(7)E. cuniculi spores IP. The E. cuniculi spores were cultivated in MDCK cells. E. cuniculi identification was performed by light microscopy studies using Gram-Chromotrope, Hematoxylin-Eosin and Toluidine blue-fuchsin staining techniques, as well as by PCR at 15, 30 and 45 days post-inoculation (DPI). Cyclophosphamide-immunosuppressed mice have greatly reduced amounts of CD8(+), CD4(+) and CD3(+) T cells and CD19(+) B cells. The cells from these mice were analyzed by FACS and showed acute disseminated and fatal encephalitozoonosis. Mice treated with ciclosporin, which is both antiparasitic and immunosuppressive, have a milder, chronic, non-lethal infection and showed a significant reduction only in CD3(+) and CD4(+) T cell numbers. Our results support the role of CD8(+) T cells in controlling infection by E. cuniculi and show that preventive measures are essential for preventing this zoonosis in individuals undergoing chemotherapy for cancer or other immunosuppressive therapies.     

Infectivity of microsporidia spores stored in water at environmental temperatures

To determine how long waterborne spores of Encephalitozoon cuniculi, E. hellem, and E. intestinalis could survive at environmental temperatures, culture-derived spores were stored in water at 10, 15, 20, 25, and 30 C and tested for infectivity in monolayer cultures of Madin Darby bovine kidney (MDBK) cells. At 10 C, spores of E. intestinalis were still infective after 12 mo, whereas those of E. hellem and E. cuniculi were infective for 9 and 3 mo, respectively. At 15 C, spores of the same species remained infective for 10, 6, and 2 mo, and at 20 C, for 7, 5, and 1 mo, respectively. At 25 C, spores of E. intestinalis and E. hellem were infective for 3 mo, but those of E. cuniculi were infective for only 3 wk. At 30 C, the former 2 species were infective for 3 wk and 1 mo, respectively, and the latter species for only 1 wk. These findings indicate that spores of different species of Encephalitozoon differ in their longevity and temperature tolerance, but at temperatures from 10 to 30 C, all 3 have the potential to remain infective in the environment long enough to become widely dispersed.     

Experimental Encephalitozoonosis in the Blue Fox

Newborn and young pups up to the age of 15 days were exposed to E. cuniculi, either by keeping the pups in cages together with orally inoculated foster-mothers and their offspring, or by oral inoculation with E. cuniculi spores. A majority of pups appeared sero-positive to E. cuniculi with the india-ink immuno-reaction from 35 to 87 days post exposure; spores of E. cuniculi were detected in organs of some of the animals. The non-inoculated pups kept together with the orally inoculated pups became seropositive from 49 to 129 days after the oral inoculations. However, the exposure of newborn and young pups failed to induce clinical encephalitozoo-nosis, and when killed at the time of pelting the body weights and fur quality appeared to be within the normal range in all exposed foxes. No macroscopic lesions were detected in the various organs. Histologically focal interstitial nephritis occurred in the great majority of the seropositive animals. Meningoencephalitis was seen in some of the foxes, whereas slightly thickened walls of some arteries, mainly in the myocardium, were found in a few animals. The lesions of the brain and kidneys seem to be very similar to those seen in chronic cases of rabbit encephalitozoonosis. Polyarteritis nodosa and severe encephalitis and interstitial nephritis with extensive proliferations of plasma cells, which are almost constant findings in cases of clinically diseased foxes, were not detected in any of the subclinically infected animals. Various factors that might be of significance in the pathogenesis of the disease are discussed, and it is concluded that intrauterine infection of the pups via the transplacental route appears to be an essential supposition for the establishment of clinical fox encephalitozoonosis.     

Rabbit encephalitozoonosis in Kenya.

Encephalitozoon cuniculi infection was diagnosed in a laboratory rabbit breeding colony at Muguga, Kenya. This is the first report of the disease in rabbits in Kenya. Post-mortem examination showed gross renal lesions and the presence of the parasite in histological sections of the cerebrum and cerebellum. On Gram stain, spores were observed in the kidney sections.     

Fine structure of a new human microsporidian, Encephalitozoon hellem, in culture

Encephalitozoon hellem is a new human microsporidian isolated from corneal biopsies and conjunctival scrapings of three AIDS patients and cultured in Madin Darby canine kidney (MDCK) cells. Encephalitozoon hellem and Encephalitozoon cuniculi display different protein profiles with sodium dodecyl sulfate-polyacrylamide gel electrophoresis and unique antibody binding patterns with murine antisera against Western blots of each organism. Developmental stages of E. hellem in culture are similar to E. cuniculi. Meronts are 1.3-2.7 microns in diameter, develop within a parasitophorous vacuole adjacent to the vacuolar membrane, divide by binary fission, and contain one or two discrete nuclei. Sporonts measure 2 x 3 microns, separate from the vacuolar membrane, and have a thickened outer membrane. Sporoblasts display a tri-layered wall and possess the earliest recognized polar filaments. Mature spores measure 1 x 1.5 microns and are more electron-dense than other stages. Each spore contains a single nucleus, a polar tubule with four to nine coils, thin electron-dense exospore and thick, electron-lucent endospore. Although E. hellem and E. cuniculi differ biochemically and immunologically, their fine structure and development are indistinguishable.     

Fine Structure of a New Human Microsporidian, Encephalitozoon hellem, in Culture

Encephalitozoon hellem is a new human microsporidian isolated from corneal biopsies and conjunctival scrapings of three AIDS patients and cultured in Madin Darby canine kidney (MDCK) cells. Encephalitozoon hellem and Encephalitozoon cuniculi display different protein profiles with sodium dodecyl sulfate-polyacrylamide gel electrophoresis and unique antibody binding patterns with murine antisera against Western blots of each organism. Developmental stages of E. hellem in culture are similar to E. cuniculi. Meronts are 1.3–2.7 μm in diameter, develop within a parasitophorous vacuole adjacent to the vacuolar membrane, divide by binary fission, and contain one or two discrete nuclei. Sporonts measure 2 × 3 μm, separate from the vacuolar membrane, and have a thickened outer membrane. Sporoblasts display a tri-layered wall and possess the earliest recognized polar filaments. Mature spores measure 1 × 1.5 μm and are more electron-dense than other stages. Each spore contains a single nucleus, a polar tubule with four to nine coils, thin electron-dense exospore and thick, electron-lucent endospore. Although E. hellem and E. cuniculi differ biochemically and immunologically, their fine structure and development are indistinguishable.     

Gamma delta T cell-deficient mice have a down-regulated CD8+ T cell immune response against Encephalitozoon cuniculi infection

Gamma(delta) T cells have been reported to play an essential effector role during the early immune response against a wide variety of infectious agents. Recent studies have suggested that the gamma(delta) T cell subtype may also be important for the induction of adaptive immune response against certain microbial pathogens. In the present study, an early increase of gamma(delta) T cells during murine infection with Encephalitozoon cuniculi, an intracellular parasite, was observed. The role of gamma(delta) T cells against E. cuniculi infection was further evaluated by using gene-knockout mice. Mice lacking gamma(delta) T cells were susceptible to E. cuniculi infection at high challenge doses. The reduced resistance of delta(-/-) mice was attributed to a down-regulated CD8+ immune response. Compared with parental wild-type animals, suboptimal Ag-specific CD8+ T cell immunity against E. cuniculi infection was noted in delta(-/-) mice. The splenocytes from infected knockout mice exhibited a lower frequency of Ag-specific CD8+ T cells. Moreover, adoptive transfer of immune TCR(alpha)beta+ CD8+ cells from the delta(-/-) mice failed to protect naive CD8(-/-) mice against a lethal E. cuniculi challenge. Our studies suggest that gamma(delta) T cells, due to their ability to produce cytokines, are important for the optimal priming of CD8+ T cell immunity against E. cuniculi infection. This is the first evidence of a parasitic infection in which down-regulation of CD8+ T cell immune response in the absence of gamma(delta) T cells has been demonstrated.     

Polar tube proteins of microsporidia of the family encephalitozoonidae

Encephalitozoonidae are microsporidia associated with human infections including hepatitis, encephalitis, conjunctivitis, and disseminated disease. Microsporidia produce a small resistant spore containing a polar tube which serves as a unique vehicle of infection. Polar tube proteins (PTPs) from Encephalitozoon hellem. Encephalitozoon (Septata) intestinalis, and Encephalitozoon cuniculi were purified to homogeneity by HPLC. By SDS-PAGE, the Mr of E. hellem PTP was 55 kDa, while the Mr of E. intestinalis and E. cuniculi PTP was 45 kDa. Polyclonal rabbit antiserum to these purified PTPs localized to polar filaments by immunogold electron microscopy and immunofluorescence, and demonstrated cross-reactivity by both immunoblotting and immunogold electron microscopy. These PTPs have similar solubility properties, hydrophobicity, and proline content to a 43-kDa PTP we have previously purified from Glugea americanus, a fish microsporidium. As the polar tube is critical in the transmission of this organism, further study of PTPs may lead to the development of new therapeutic strategies and diagnostic tests.     

Infectivity of microsporidia spores stored in seawater at environmental temperatures

To determine how long spores of Encephalitozoon cuniculi, E. hellem, and E. intestinalis remain viable in seawater at environmental temperatures, culture-derived spores were stored in 10, 20, and 30 ppt artificial seawater at 10 and 20 C. At intervals of 1, 2, 4, 8, and 12 wk, spores were tested for infectivity in monolayer cultures of Madin Darby bovine kidney cells. Spores of E. hellem appeared the most robust, some remaining infectious in 30 ppt seawater at 10 C for 12 wk and in 30 ppt seawater at 20 C for 2 wk. Those of E. intestinalis were slightly less robust, remaining infectious in 30 ppt seawater at 10 and 20 C for 1 and 2 wk, respectively. Spores of E. cuniculi remained infectious in 10 ppt seawater at 10 and 20 C for 2 wk but not at higher salinities. These findings indicate that the spores of the 3 species of Encephalitozoon vary in their ability to remain viable when exposed to a conservative range of salinities and temperatures found in nature but, based strictly on salinity and temperature, can potentially remain infectious long enough to become widely dispersed in estuarine and coastal waters.     

Serological survey of Encephalitozoon cuniculi infection in Japanese dogs

Antibodies to Encephalitozoon cuniculi were examined by enzyme-linked immunosorbent assay using E. cuniculi PTP2 recombinant protein and by Western blot analysis on a total of 472 dog serum samples that had been collected in Japan. Of these samples, 21.8% (103/472) had antibodies against E. cuniculi. Each of 5 serum samples that showed high (>1.0) or low (<0.1) OD value was selected randomly and further examined by Western blot using E. cuniculi-native antigens. All samples with high OD values reacted with specific E. cuniculi proteins, including an antigen of approximately 35 kDa corresponding with PTP2; sera with low OD values did not recognize this E. cuniculi band. This study is the first to demonstrate the prevalence of E. cuniculi infection in dogs in Japan.     

Isolation and Characterization of a Herpes-like Virus from New Zealand Albino Rabbit Kidney Cell Cultures: a Probable Reisolation of Virus III of Rivers

An agent which possesses the physical, chemical, cytopathic, histological, and electron microscopic attributes of a herpes group virus was isolated from an uninoculated batch of primary rabbit kidney cell cultures. Preliminary evidence indicates that antibodies against the agent are found in some sera of other "normal" New Zealand albino rabbits. In cell cultures, the virus grew best and almost exclusively in cells of rabbit origin. On the basis of these facts, the name herpesvirus cuniculi (HC) is suggested for the isolate. A batch of anti-herpesvirus bovis antiserum prepared in rabbits was found to be "contaminated" with unsuspected neutralizing antibodies against HC. Caution is mandatory when using rabbits, rabbit tissues, or rabbit sera for work with any herpes group virus unless precautions are taken to rule out unsuspected infection with or antibodies against HC. This agent may well represent a reisolation of virus III, a rabbit herpes virus, described by Rivers in 1923; the isolation of this virus has not been reported since 1940. It is important to reemphasize the existence of this agent in an animal which is commonly used for laboratory investigation of herpes group viruses.