Immunodepression in Babesia microti infections.

Infection with the avirulent piroplasm Babesia microti in mice is accompanied by a marked depression in the ability of the mice to mount an immune response to sheep red blood cells. The period of immunodepression begins 3 days after peak parasitaemia and is maximal 4 days later. Thereafter, there is a slow return to normal immune responsiveness, correlated with the gradual disappearance of the parasites from the blood. Both IgM and IgG responses are depressed. Cell-mediated responses as determined by contact sensitivity to oxazolone and allograft survival are apparently unaffected. Phagocytic activity was measured by carbon clearance tests is increased, and is correlated with the parasitaemia.     

Isoenzyme analysis of Babesia microti infections in humans

We used high-resolution polyacrylamide gradient gel electrophoresis (PGGE) to separate four babesial enzymes to aid in the identification of two Babesia microti isolates established in hamsters. The isolates were compared to two different hamsters passages of the "Gray" strain. All isoenzymes patterns from the two isolates and the "Gray" strain were similar except glucose phosphate isomerase (GPI) from one of the "Gray" strain passages. It showed a polymorphic GPI pattern as opposed to a monomorphic GPI pattern seen in the other "Gray" strain passage and the two isolates. The observed differences suggested that some population of B. microti are capable of having polymorphic GPI, that the "Gray" strain originally contained (and may still contain) a heterogeneous population of B. microti, and that the population possessing polymorphic GPI was selected over that with monomorphic GPI. This information was obtained by a PGGE method that eliminated hemoglobin from gels and allowed, for the first time, detection of babesial leucine amino peptidase (LAP) and isocitrate dehydrogenase (IDH). In addition, this method provided molecular weight estimations on babesial GPI, LAP, IDH, and glutamate dehydrogenase (GDH), and it proved useful in the identification and characterization of the B. microti isolates.     

Isoenzyme Analysis of Babesia microti Infections in Humans

ABSTRACT. We used high-resolution polyacrylamide gradient gel electrophoresis (PGGE) to separate four babesial enzymes to aid in the identification of two Babesia microti isolates established in hamsters. The isolates were compared to two different hamster passages of the "Gray" strain. All isoenzyme patterns from the two isolates and the "Gray" strain were similar except glucose phosphate isomerase (GPI) from one of the "Gray" strain passages. It showed a polymorphic GPI pattern as opposed to a monomorphic GPI pattern seen in the other "Gray" strain passage and the two isolates. The observed differences suggested (i) that some populations of B. microti are capable of having polymorphic GPI, (ii) that the "Gray" strain originally contained (and may still contain) a heterogenous population of B. microti , and (iii) that the population possessing polymorphic GPI was selected over that with monomorphic GPI. This information was obtained by a PGGE method that eliminated hemoglobin from gels and allowed, for the first time, detection of babesial leucine amino peptidase (LAP) and isocitrate dehydrogenase (IDH). In addition, this method provided molecular weight estimations on babesial GPI, LAP, IDH, and glutamate dehydrogenase (GDH), and it proved useful in the identification and characterization of the B. microti isolates.     

Experimental Babesia microti infections in non-splenectomized Macaca mulatta.

Eight non-splenectomized Macaca mulatta were inoculated intravenously with strains of Babesia microti that originally were isolated from 2 human cases of babesiosis and then were maintained in hamsters in the laboratory. Patent infections developed in 7 animals with peak parasitemias of 496 to 3,906 organisms/mm3 blood. Prepatent periods ranged from 15 to 46 days. Parasitemia persisted for at least 90 days in all animals and in one, organisms were still present 559 days after inoculation.     

Babesia bovis, Babesia bigemina, Babesia canis, Babesia microti and Babesia rodhaini: comparison of ribosomal RNA gene organization.

The three ribosomal DNA (rDNA) units have been cloned from an Australian isolate of Babesia bigemina. The organization of the units is very similar to that reported for a Mexican isolate of B. bigemina. In Babesia canis four rDNA units have been identified. Both Babesia rodhaini and Babesia microti contain two different rDNA units. A small number of different rDNA units appears to be a common feature of this group of Protozoa. Restriction enzyme analysis of the rDNA units form these species and B. bovis suggests that the genus Babesia as currently defined does indeed include two distinct groups of organisms namely, B. bovis, B. bigemina and B. canis and B. rodhaini and B. microti.     

Pathology of experimental Babesia microti infection in the Syrian hamster

Pathologic changes produced after 4 weeks of infection by Babesia microti in Syrian hamsters are described and compared to babesiosis of humans. Following intraperitoneal inoculation, both intravascular and extravascular hemolysis developed. Up to 70% of red blood cells were parasitized. The principal morphologic abnormalities were an increase in extramedullary hematopoiesis and hyperplasia of the mononuclear phagocytic cells of the red pulp manifested grossly as splenomegaly, marked renal tubular hemosiderosis and hypertrophy of Kupffer cells. The disease was not fatal to any hamsters during the 4 week study. The clinical signs and lesions were less severe than fatal babesiosis of asplenic humans and similar to severe, but nonfatal disease in spleen intact humans. The hamster may serve as an animal model for the studying the pathophysiology of human babesiosis and for studying potential chemotherapeutic agents.     

Macrophage mediated resistance to Babesia microti in Nematospiroides dubius--infected mice

Infection with the gastrointestinal nematode, Nematospiroides dubius, induced resistance to a concurrent infection with Babesia microti in mice. This enhanced resistance to B. microti occurred during infection with the larval, rather than the adult stages of N. dubius. Splenectomy or the injection of carrageenan or silica abrogated the protective effect against B. microti induced by infection with N. dubius. Peritoneal macrophages harvested from infected mice produced inhibition of the development of B. microti in vitro. This inhibition was greatest using macrophages harvested from mice recovered from infection with B. microti and from mice infected with the larval stages of N. dubius. Also, supernatants harvested from cultures of macrophages from N. dubius-infected mice suppressed B. microti development in vitro.     

Immunogenicity of recombinant Babesia microti hsp70 homologue in mice

A Babesia microti hsp70 homologue was cloned, expressed in a prokaryotic system and tested in a pilot study for protection against lethal challenge. Results showed that 30% of the mice inoculated with recombinant protein (rBm hsp70) survived challenge, while all of the controls died. Evidence of antibody response to the hsp homologue was detected by Western blot analysis, but no protection was imparted through passive transfer of convalescent serum. Passively transferred spleen cells, from mice which survived challenge, also failed to impart protection. The mechanism of partial immunity suggested by these observations remains to be elucidated.     

An electron microscopic study of Babesia microti invading erythrocytes

Summary Intracellular sporozoan parasites invade the host cell through the invagination of the plasma membrane of the host and a vacuole is formed which accommodates the entering parasite. The vacuole may disappear and the invaginated membrane of the host then becomes closely apposed to that of the parasite's own membrane. As a result the parasite is covered by two membranes. Members of the class Piroplasmea differ from other Sporozoa in that their trophozoites are covered by a single membrane. By screening numerous sections of intraerythrocytic Babesia microti belonging to the class Piroplasmea, it was found that merozoites of Babesia enter the erythrocytes of hamsters in the same way as those of other Sporozoa. When a merozoite touches the red blood cell with its anterior end it becomes attached to the membrane of the host, which starts to invaginate and a parasitophorous vacuole is formed. The vacuolar space disappears rapidly and the membrane of the vacuole and that of the parasite become closely adjacent. At this stage the parasite is surrounded by two plasma membranes. The outer membrane derived from the invaginated host membrane disintegrates quickly and the parasite is left with a single membrane throughout its life span.Supported by Grant AI 08989 from the U.S. Public Health Service. The excellent technical assistance of Ms. Renata Klatt is gratefully acknowledged     

Prevalence of Babesia microti in free-ranging baboons and African green monkeys

Babesia microti-like parasites have been reported to infect captive non-human primates (NHPs). However, studies on the prevalence of Babesia spp. in free-ranging NHPs are lacking. This investigation aimed at determining the prevalence of B. microti in wild-caught Kenyan NHPs. In total, 125 animals were studied, including 65 olive baboons (Papio cynocephalus anubis) and 60 African green monkeys ([AGMs] Chlorocebus aethiops). Nested polymerase chain reaction targeting Babesia β-tubulin genes was used to diagnose infection prevalence. Results indicated a prevalence of 22% (27/125) B. microti infection in free-ranging NHPs in Kenya. There was no statistically significant difference in B. microti infection prevalence between baboons and AGMs or male and female animals. This is the first report of the presence and prevalence of B. microti in free-ranging Kenyan NHPs.     

The proliferative response of mouse lymphoid tissues during infections with Babesia microti or Babesia rodhaini

Inchley C. J., Grieve E. M. and Preston P. M. 1987. The proliferative response of mouse lymphoid tissues during infections with Babesia microti or Babesia rodhaini. International Journal for Parasitology17: 945–950. Proliferative responses induced by the lethal protozoan parasite, Babesia rodhaini, or the non-lethal species, B. microti were measured in the lymphoid tissues of infected mice. Both stimulated equally rapid DNA synthesis in the spleen, but spleen enlargement during the first week was more pronounced after infection with B. rodhaini, suggesting an earlier influx of cirulating cells than during B. microti infections. Termination of B. rodhaini infections by chemotherapy revealed that the recruitment of cells, but not the proliferative response, was dependent on the presence of live parasites. The spleen enlargement typical of B. microti-infected mice developed during the second week, but up to half of this response could be attributed to compensatory erythropoiesis. Babesia microti, but not B. rodhaini, induced a proliferative response in peripheral lymph nodes, and transiently depressed cell division in the thymus.     

Babesia microti: Pathogenesis of parasite of human origin in the hamster

The pathogenesis of the disease in hamsters caused by the first human Babesia isolant, tentatively named Babesia microti, and the immunologic relationship of the organism to Babesia canis were studied. The patent phase of the disease was characterized by severe anemia and marked parasitemia which occurred between the 6th and 41st day following infection. An increase in total white cell count with a neutrophilia, eosinophilia, monocytosis, and lymphocytosis was observed during the patent phase. The patent phase was followed by development of a carrier state. This was demonstrated by relapse following splenectomy 113 days after infection. No statistically significant differences were observed between the serum profiles of infected and noninfected animals during the period monitored. A serologic relationship between B. microti and B. canis was revealed by the use of gel diffusion and indirect fluorescent antibody (IFA) tests. The IFA test was used to monitor serum antibody responses during the patent and carrier phases of the disease. Crossabsorption studies between B. canis and B. microti revealed that the two organisms possess common and specific antigens.     

Babesia microti: prolonged survival of salavarian piroplasms in nymphal Ixodes dammini

We determined how long Babesia microti survive in the salivary glands of nymphal Ixodes dammini. Of those ticks held at 21 C, the proportion with demonstrable piroplasms decreased from 95%, prior to 20 weeks post-larval-feeding (p-l-f), to less than 80% at 42 weeks p-l-f. Similarly, the number of infected acini decreased significantly. Nymphal I. dammini were kept alive for as long as 1 year, by transferring them to 4 C, at 20 weeks p-l-f. The proportion of infected ticks at 52 weeks p-l-f was less than half of the proportion of infected nymphs examined prior to 20 weeks p-l-f, and only 1/6 as many acini were infected. Ultrastructural observations of salivary glands from ticks at 44 weeks p-l-f revealed that B. microti parasites in older ticks remain in the sporoblast meshwork phase; such parasites rarely differentiated into sporozoites. Degenerating parasites containing autophagic vacuoles were also observed in older ticks.     

Fay and Rausch 1969 revisited: Babesia microti in Alaskan small mammals

The Holarctic distribution of Babesia microti within small rodents implies an ancient association. A seminal report of piroplasms in Alaskan voles suggested to us the possibility that B. microti entered North America within Eurasian microtine rodents dispersing through Beringian corridors. To test this hypothesis, we analyzed samples from Alaskan rodents by polymerase chain reaction for evidence of infection with B. microti; one-third of the rodents were found to be infected. Sequence analysis of the 18S rDNA gene demonstrates that Alaskan B. microti comprises a clade that infects microtines in several sites across North America and is distinct from a clade that is zoonotic.     

Penetration of the peritrophic membrane of the tick by Babesia microti

Summary A peritrophic membrane (PM) has been demonstrated in the gut of feeding larvae, nymphs, and adults of the tick Ixodes dammini. This is the first report of a PM in ticks. This temporary structure divides the lumen of the gut into two compartments, an endoperitrophic space, the lumen proper, and an ectoperitrophic space located between the PM and the epithelial cells of the gut wall. The PM is a mechanical barrier and even such small particles as ribosomes derived from ingested reticulocytes are retained in the lumen proper; they are never found in the ectoperitrophic compartment. In Ixodes dammini fed on hamsters infected with Babesia microti some of the parasites are found in the ectoperitrophic space. This passage is accomplished by a highly specialized organelle, the arrowhead, which develops in some Babesia during their metamorphosis in the gut of the vector. The arrowhead, while passing through the PM, changes its fine structure and loses its internal organization as if releasing some of its contents. Its disintegration continues and it disappears shortly after the Babesia have entered the epithelial cells. Only Babesia equipped with the arrowhead structure are able to cross the PM. This is the first documented case of a parasite traversing a solidified PM.Supported by Research Grant AI-15886 from the United States Public Health ServiceIt is a great pleasure to acknowledge the excellent technical assistance of Mrs. Ellen Lanners. Special thanks are extended to Dr. Alex S. Raikhel for the courtesy of translating from Russian to English his Chapter 3, Intestine, from the book, An Atlas of Electron Microscopical Anatomy of Ixodid Ticks. We are indebted to Mrs. Liubov Lyandvert for the translation from Russian of selected other parts of the same book     

Vertical Transmission of Babesia microti in BALB/c Mice: Preliminary Report

Babesia spp. (Apicomplexa, Piroplasmida) are obligate parasites of many species of mammals, causing a malaria-like infection- babesiosis. Three routes of Babesia infection have been recognized to date. The main route is by a tick bite, the second is via blood transfusion. The third, vertical route of infection is poorly recognized and understood. Our study focused on vertical transmission of B. microti in a well-established mouse model. We assessed the success of this route of infection in BALB/c mice with acute and chronic infections of B. microti. In experimental groups, females were mated on the 1^st day of Babesia infection (Group G0); on the 28^th day post infection (dpi) in the post- acute phase of the parasite infection (G28); and on the 90^th and 150^th dpi (G90 and G150 group, respectively), in the chronic phase of the parasite infection. Pups were obtained from 58% of females mated in the post-acute phase (G28) and from 33% of females in groups G90 and G150. Mice mated in the pre-acute phase of infection (G0) did not deliver pups. Congenital B. microti infections were detected by PCR amplification of Babesia 18S rDNA in almost all pups (96%) from the experimental groups G28, G90 and G150. Parasitaemia in the F1 generation was low and varied between 0.01–0.001%. Vertical transmission of B. microti was demonstrated for the first time in BALB/c mice.