Immunological and nonimmunological control of severity of Trypanosoma musculi infections in C3H and C57BL/6 inbred mice

Infection of C57BL/6 mice by Trypanosoma musculi modulates host immune responses during Brucella abortus cocolonization

Brucellosis, which results in fetal abortions in domestic and wildlife animal populations, is of major concern in the US and throughout much of the world. The disease, caused by Brucella abortus, poses an economic threat to agriculture-based communities. A moderately efficacious live attenuated vaccine (B. abortus strain RB51) exists. However, even with vaccine use, outbreaks occur. Evidence suggests that elk (Cervus canadensis), a wild host reservoir, are the source of recent outbreaks in domestic cattle herds in Wyoming, USA. Brucella abortus establishes a chronic, persistent infection in elk. The molecular mechanisms allowing the establishment of this persistent infective state are currently unknown. A potential mechanism could be that concurrent pathogen burdens contribute to persistence. In Wyoming, elk are chronically infected with Trypanosoma cervi, which may modulate host responses in a similar manner to that documented for other trypanosomes. To identify any synergistic relationship between the two pathogens, we simulated coinfection in the well-established murine brucellosis model using Trypanosoma musculi and B. abortus S19. Groups of C57BL/6 mice (Mus musculus) were infected with either B. abortus strain 19 (S19) or T. musculi or both. Sera were collected weekly; spleens from euthanized mice were tested to determine bacterial load near the end of normal brucellosis infection. Although changes in bacterial load were observed during the later stages of brucellosis in those mice coinfected with T. musculi, the most significant finding was the suppression of gamma interferon early during the infection along with an increase in interleukin-10 secretion compared with mice infected with either pathogen alone. These results suggest that immune modulatory events occur in the mouse during coinfection and that further experiments are warranted to determine if T. cervi impacts Brucella infection in elk.

Rodent trypanosomes: their conflict with the immune system of the host

Rodent trypanosome infections provide the opportunity to study major phenomena that are displayed in many parasite-host combinations and, therefore, the chance to contribute to the elucidation of those phenomena. Here, Julia and Joseph Albright focus on the immune responses to rodent trypanosomes and on the tricks the parasites play to minimize the effects of those responses.

Trypanosoma cruzi: peripheral blood monocytes and heart macrophages in the resistance to acute experimental infection in rats

The contribution of mononuclear phagocytes to host resistance against acute Chagas disease has been studied in vivo in a rat model inoculated with Trypanosoma cruzi, Y strain. Acute T. cruzi infection triggered a dramatic increase (937%) in peripheral blood monocyte number at day 12 of infection. At this point, histological analysis of the heart showed high parasitism and diffuse and a moderate to intense mononuclear inflammatory process. Ultrastructural study revealed a large number of macrophages, in addition to lymphocytes and undiffer entiated cells. Clusters of macrophages exhibited different morphologi cal phenotypes, with evident signs of activation (increase in size, surface rufflings, and amount of cytoplasmic organelles). Cell-to-cell contacts involving macrophages and lymphocytes or macrophages and mono cytes were observed. Depletion of macrophages by treatment with silica, a selective cytotoxic agent for these cells, caused a significant increase in the number of amastigote nests in cardiomyocytes. The present findings indicate that the early phase of infection with T. cruzi induces rapid production, maturation, and activation of the monocyte/macrophage system so as to control T. cruzi replication, emphasizing the crucial role for macrophages in the rat resistance to Chagas disease.

Depletion of immune effector cells induces myocardial damage in the acute experimental Trypanosoma cruzi infection: ultrastructural study in rats

The contribution of radiosensitive cells and macrophages to myocardial immunopathology has been studied in rats inoculated with Trypanosoma cruzi, Y strain. Immunodepression was induced by gamma irradiation and depletion of radioresistant macrophages was achieved by silica, a selective cytotoxic agent for macrophages. Irradiated or silica treated rats and age-matched controls were sacrificed at day 12 of infection so as to study the heart by light and electron microscopy. In the infected controls, damaged cardiomyocytes were directly related to tissue parasitism; inflammatory cells, predominantly lymphocytes and macrophages, were present. The drastic depletion of radiosensitive cells (lymphocytes and granulocytes), as well as the depletion of macrophages by silica, induced cardiomyocytes damage during the acute infection, exacerbating the lesions seen in the infected controls. In the irradiated-infected and silica treated-infected animals, degenerating cardiomyocytes, parasitized or not, were frequently observed, displaying evident signs of cytoplasmic and nuclear damage. Some signs of cardiomyocyte damage (irregular distribution of glycogen particles and myofibrils with shrinkage and aggregation of Z bands) were present only in silica treated-infected animals. The findings suggest that immune effector cells may not play a major role in the cardiomyocyte damage induced by acute. Chagas disease, arguing against the autoimmune etiology of Chagasic cardiomyopathy.

Ageing alters the competence of the immune system to control parasitic infection

The elderly are more susceptible to infections with various pathogenic organisms that are young-adults or middle-aged individuals. Certain microorganisms that are non-pathogenic in adults may cause serious infections in the elderly. This heightened susceptibility of the elderly is most likely a reflection of the age-associated decline in the competence of the immune system. It appears that the population of T cells is altered with advanced age and, possibly, the efficiency of the monocyte/macrophage cells to destroy microbial invaders declines. There is a small, but compelling, body of literature which shows that the elderly are particularly susceptible to protozoan and metazoan parasites. We have studied the markedly increased severity of infections in aged mice with the mouse-specific Trypanosoma musculi; both the parasite burden and the duration of infection are substantially greater in old compared to young mice. It appears that this difference is due, to a large extent, to the relatively weak ability of aged animals to generate cytokines associated with the TH1 subset of CD4+ T cells; in particular, the weak ability to generate IL-2 and IFN gamma which are involved in the selective expression of curative, parasite-specific antibody of the IgG2a isotype. A striking difference between young and aged mice is in the response of IL-3 producing cells to the parasite infection; IL-3-producers decline during infection in young mice but increase markedly in aged animals. There are several advantages to using T. musculi as a prototype pathogen for studying age-related susceptibility to infection.(ABSTRACT TRUNCATED AT 250 WORDS)

Transfer of antibody against Borrelia duttonii from mother to young in ddY mice

The route of transfer of anti-Borrelia duttonii antibody subclasses from mother to young and their role in protection against borrelial challenge infection in ddY mice were investigated. Offspring from infected and noninfected mice were segregated and nursed by noninfected or infected mothers. Enzyme-linked immunosorbent assay analysis of antibodies of the cross-suckled offspring revealed that anti-B. duttonii immunoglobulin G1 (IgG1) is transferred exclusively in milk and that IgG2a is transferred mainly in milk but also slightly through the yolk sac route. On the other hand, IgG3 is transferred mainly through the yolk sac route but also slightly in milk, whereas IgG2b is transferred through both routes but to a lesser extent. Anti-borrelial IgM was not detected in any offspring. The protective role of transferred IgG subclasses was examined by challenge infection with B. duttonii. Offspring from noninfected mice fed by infected mothers had IgG1, IgG2a, and IgG3 at challenge and were completely protected against the challenge infection. On the other hand, offspring from infected mice fed by noninfected mothers had only IgG3, and 8 of 10 were completely protected from challenge infection whereas the other 2 contracted slight and transient spirochetemia. These findings suggested that anti-borrelial IgG3 alone has considerable protective activity and that IgG1, IgG2a, or both, either by themselves or together with IgG3, have a complete protective activity against borrelial infection.

Response of inbred mice to infection with a new isolate of Trypanosoma musculi

A new isolate of Trypanosoma musculi has been derived from organisms recovered from Mus spretus captured in Lisbon, Portugal. The time-course and profiles of infection with this isolate in inbred mice have been compared with those obtained with the existing Partinico II isolate. Infections with the Portuguese isolate are less intense, and controlled more quickly than those with the Partinico isolate. As with the latter, there are marked mouse strain-dependent influences on infection with the Portuguese isolate, but these strain-dependent characteristics differ considerably with each isolate. For example, NIH mice were the most susceptible to the Partinico II isolate, but virtually refractory to the Portuguese isolate. Mice exposed to infection with one isolate show complete immunity to both homologous and heterologous challenge infections. These striking interactions between host and parasite genotype are discussed in terms of immunological influences on infection.

Immune and nonimmune regulation of the population of Trypanosoma musculi in infected host mice

A clear understanding of the population dynamics of trypanosome infections is lacking. In the case of murine Trypanosoma musculi infections, there are no answers to questions concerning (i) the nature of the prolonged plateau phase during which the number of parasites present in the host remains nearly constant (is it a static or dynamic steady state?); (ii) the origin of new parasites, if the plateau is a dynamic steady state, given the relatively early disappearance of generative forms from the bloodstream; and (iii) the role, if any, of a putative ablastin (reproduction-restricting antibody) in regulating the population dynamics of T. musculi infections. We describe here the results of studies of the number and distribution of mature and reproductive forms (RF) in the blood and peritoneal space of both immunocompetent and cyclophosphamide-treated mice throughout the course of infection. While the RF disappeared from the blood within a few days after parasite inoculation, a high fraction (20 to 30%) of the parasites in the peritoneal space were RF throughout the course of infection and, thus, represented a source of new parasites. If an ablastin is responsible for inhibiting RF in the blood, it appeared to have no effect on RF in the peritoneal space. The results of this investigation support the conclusion that the control of the dynamics of T. musculi infections is largely nonimmunological (until cure of the infection) and probably is exercised by the supply of nutrients and reproduction-inhibiting (nonimmunological) and maturation-promoting factors that affect the generative fraction of the population.