The MCV (mean corpuscular volume, volume per individual erythrocyte) was also reduced in these mice, confirming the successful induction of IDA characterized by microcytic anemia. Iron-deficient mice were infected with Plasmodium yoelii (Py) and the kinetics of infection assessed by evaluating the daily levels of parasitemia and survival rates.
Py has two substrains, PyL and PyNL, each with differing virulence. Infection of iron-sufficient mice with the virulent strain, PyL, resulted in a rapid increase in parasitemia that killed all mice within 10 days (Fig. 1A). Interestingly, IDA mice showed markedly lower levels of parasitemia throughout the period of infection and survived longer than iron-sufficient Opaganib ic50 control mice. They finally succumbed to infection with low levels of parasitemia, presumably due to severe anemia (Fig. 1A). Mice infected with LD50 of the PyNL strain (less virulent than PyL) experienced peak levels of parasitemia 3 wk after infection followed by complete eradication of the parasites. Mice cured of PyNL infection showed sterile immunity against otherwise-lethal infections by PyL 8. IDA mice had low levels of parasitemia and all of them survived (Fig. 1B). A detailed evaluation showed that the numbers of late trophozoites and shizonts were
significantly reduced (Fig. 1C). These results clearly demonstrated that IDA mice were protected from death caused by acute Py infection. This protection was STK38 not limited to infection with Py, as similar results were obtained when IDA mice were infected with the P. berghei NK65 strain (data not shown). To address CP-868596 the mechanisms underlying resistance to malaria in IDA, two possibilities were raised. One relates to the direct effects
on the parasites themselves; the development/growth of the parasites is suppressed in IDA erythrocytes. The other is that iron-deficiency modulates host immunity to enhance the eradication of parasites. We first focused on the intra-erythrocytic development of the malaria parasites. Erythrocytes isolated from IDA mice during the early phase of PyL infection were cultured in the presence of 10% normal mouse serum and periodically observed under a microscope. The purified infected cells were almost ring-infected and developed into late trophozoites within 3 h. They developed into mature schizonts after nuclear division within 6 h. PyL parasites grew equally well in IDA erythrocytes and control erythrocytes (Fig. 2A). To further mimic the in vivo situation, we used serum from IDA mice. Under these conditions the parasites still grew in the presence of IDA serum (Fig. 2A). Furthermore, we did not observe any differences in the number of merozoites within the individual mature schizonts in vivo (Fig. 2B). These results seem to exclude the possibility that IDA adversely affects the development/growth of malaria parasites. We next analyzed the effects of IDA on host immunity.