Macrophages are the determinant of resistance to and outcome of nonlethal Babesia microti infection in mice.

In the present study, we examined the contributions of macrophages to the outcome of infection with Babesia microti, the etiological agent of human and rodent babesiosis, in BALB/c mice. Mice were treated with clodronate liposome at different times during the course of B. microti infection in order to deplete the macrophages. Notably, a depletion of host macrophages at the early and acute phases of infection caused a significant elevation of parasitemia associated with remarkable mortality in the mice. The depletion of macrophages at the resolving and latent phases of infection resulted in an immediate and temporal exacerbation of parasitemia coupled with mortality in mice. Reconstituting clodronate liposome-treated mice at the acute phase of infection with macrophages from naive mice resulted in a slight reduction in parasitemia with improved survival compared to that of mice that received the drug alone. These results indicate that macrophages play a crucial role in the control of and resistance to B. microti infection in mice. Moreover, analyses of host immune responses revealed that macrophage-depleted mice diminished their production of Th1 cell cytokines, including gamma interferon (IFN-γ) and tumor necrosis factor alpha (TNF-α). Furthermore, depletion of macrophages at different times exaggerated the pathogenesis of the infection in deficient IFN-γ(-/-) and severe combined immunodeficiency (SCID) mice. Collectively, our data provide important clues about the role of macrophages in the resistance and control of B. microti and imply that the severity of the infection in immunocompromised patients might be due to impairment of macrophage function.

Expression of erythropoietic cytokines in α-tocopherol transfer protein knockout mice with murine malaria infection.

Malaria infection leads to anemia in humans which generally occurs during the chronic phase of the infection. The role that erythropoietic molecules play for anemia during malaria at low parasitemia levels is still controversial due to the lack of suitable animal models which might mimic this condition. In this regard, α-tocopherol transfer protein knockout mice, with undetectable levels of vitamin E in circulation, were possibly used as a model to investigate the role that erythropoietic molecules such as erythropoietin (EPO), erythropoietin receptor (EPOR), and macrophage migration inhibitory factor (MIF) play on the outcome of anemia during uncomplicated malaria infection at low parasitemias. The results indicate that the degree of parasitemia unlikely plays any important effect on mRNA expression of EPO and EPOR in different organs. Moreover, even though EPO and EPOR productions are impaired in the kidney and bone marrow, respectively, other organs such as the liver and spleen intend to compensate production of these cytokines to prevent anemia in the infected animals.

Alpha-tocopherol transfer protein disruption confers resistance to malarial infection in mice.

BACKGROUND: Various factors impact the severity of malaria, including the nutritional status of the host. Vitamin E, an intra and extracellular anti-oxidant, is one such nutrient whose absence was shown previously to negatively affect Plasmodium development. However, mechanisms of this Plasmodium inhibition, in addition to means by which to exploit this finding as a therapeutic strategy, remain unclear. METHODS: alpha-TTP knockout mice were infected with Plasmodium berghei NK65 or Plasmodium yoelii XL-17, parasitaemia, survival rate were monitored. In one part of the experiments mice were fed with a supplemented diet of vitamin E and then infected. In addition, parasite DNA damage was monitored by means of comet assay and 8-OHdG test. Moreover, infected mice were treated with chloroquine and parasitaemia and survival rate were monitored. RESULTS: Inhibition of alpha-tocopherol transfer protein (alpha-TTP), a determinant of vitamin E concentration in circulation, confers resistance to malarial infection as a result of oxidative damage to the parasites. Furthermore, in combination with the anti-malarial drug chloroquine results were even more dramatic. CONCLUSION: Considering that these knockout mice lack observable negative impacts typical of vitamin E deficiency, these results suggest that inhibition of alpha-TTP activity in the liver may be a useful strategy in the prevention and treatment of malaria infection. Moreover, a combined strategy of alpha-TTP inhibition and chloroquine treatment might be effective against drug resistant parasites.

alpha-Tocopherol transfer protein inhibition is effective in the prevention of cerebral malaria in mice.

BACKGROUND: Nutritional status likely plays an important role in determining the outcome of protozoan infections. Despite the evidence of Plasmodium sensitivity to oxidative stress, the potential role of vitamin E, a free radical scavenger, on the outcome of cerebral malaria (CM) has yet to be elucidated. OBJECTIVE: To determine the influence of vitamin E on Plasmodium parasite development and murine CM outcome, alpha-tocopherol transfer protein (alpha-TTP), a regulator of vitamin E in the host circulation, was abrogated. DESIGN: alpha-TTP knockout mice were infected with Plasmodium berghei ANKA, and survival rate, parasitemia, brain histologic alterations, and brain barrier permeability were assessed. In addition, mRNA expression of the cytokines and adhesion molecules involved in this neurologic pathology were monitored. RESULTS: alpha-TTP knockout mice infected with P. berghei ANKA did not exhibit any clinical or pathologic signs of CM, and a histologic analysis of the brain tissues in these animals showed no alteration of blood-brain barrier integrity compared with that in control mice. Interestingly, protection of the blood-brain barrier in these infected alpha-TTP knockout mice was lost when dietary supplementation with vitamin E was added to their diet. Moreover, interleukins and adhesion molecule transcripts in the brain of control mice were significantly up-regulated compared with those in the alpha-TTP knockout mice. CONCLUSION: It appears that a deficiency of alpha-tocopherol in the circulation prevents CM and suggests that alpha-TTP is a putative target for the early prevention of CM.