The impact of immunization on competition within Plasmodium infections.

Evolutionary theory argues that ecological interactions between pathogens within an infection can be a potent source of selection shaping traits such as virulence, drug resistance, and infectiousness. In humans, malaria infections are frequently genetically diverse, with mixed genotype infections the norm. A wide variety of evidence shows that crowding occurs within infections, with the population densities of individual genotypes suppressed by the presence of others. Public health interventions are expected to impact on levels of immunity experienced by pathogens, indirectly by reducing the rate of acquisition of natural immunity by reducing the force of infection, and directly in the case of vaccination programs. Here we ask how enhanced host immunity affects competitive interactions between malaria parasites within hosts and thus the strength of in-host selection on traits such as virulence. We used a model malaria system, Plasmodium chabaudi in laboratory mice, where it has been previously shown that less virulent parasites are competitively suppressed by more virulent strains, generating within-host selection for increased virulence. We found that immunization with either a recombinant antigen or with live parasites suppressed parasite densities, but that there was no evidence that immunization relieved or exacerbated competitive suppression, or affected the relative frequency of clones within infections. There is thus no reason to think that immunization strengthens or alleviates the potentially very potent selection on parasite traits arising from interactions between pathogen genotypes within infections.

The effect of parental rearing conditions on offspring life history in Anopheles stephensi.

BACKGROUND: The environmental conditions experienced by parents are increasingly recognized to impact the success of offspring. Little is known on the presence of such parental effects in Anopheles. If present, parental effects could influence mosquito breeding programmes, some malaria control measures and have epidemiological and evolutionary consequences. METHODS: The presence of parental effects on offspring emergence time, size, survival, blood meal size and fecundity in laboratory reared An. stephensi were tested. RESULTS: Parental rearing conditions did not influence the time taken for offspring to emerge, or their size or survival as adults. However, parental effects were influential in determining the fecundity of daughters. Counter-intuitively, daughters of parents reared in low food conditions produced larger egg clutches than daughters of parents reared in high food conditions. Offspring reared in low food conditions took larger blood meals if their parents had also experienced a low food environment. CONCLUSION: So far as we are aware, this is the first evidence of parental effects on progeny in Anopheles.

Numerous, robust genetic markers for Plasmodium chabaudi by the method of amplified fragment length polymorphism.

We have used the method of amplified fragment length polymorphism (AFLP) to identify genetic polymorphisms between two cloned isolates of the rodent malaria parasite Plasmodium chabaudi chabaudi. The method employs polymerase chain reaction (PCR)-amplification of genomic DNA fragments cut with specific combinations of restriction endonucleases; we used EcoRI and Tru1I (isoschizomer of MseI). We have identified 819 parasite clone-specific AFLPs between P. c. chabaudi clones AS and AJ. Of these, 403 fragments were specific to AS and 416 to AJ. In preparing blood stage parasites for DNA, nucleated host cells were removed by successive filtration of infected blood through powdered cellulose and Plasmodipur filters. This reduced nucleated host cell contamination to around 1-10 per million parasite nuclei and reduced host DNA to below the limit of detection by the AFLP method. Analysis of our results showed that the total number of PCR-amplified fragments of parasite DNA was consistent with the predicted number of EcoRI sites in the parasite genome. 19.4% of all amplified fragments were P. c. chabaudi clone-specific. From this figure we estimated that the diversity between clones AS and AJ, measured as the probability of a sequence difference, was between about 8 x 10(-3) and 4.6 x 10(-4) per base pair. This is consistent with the sequence diversity found between alleles of candidate drug resistance genes from P. c. chabaudi clones AS and AJ identified and sequenced in this laboratory.