Temporal expression of an H2-linked locus in host response to mouse malaria

 The action of host genes in response to malarial infection is complex. Two mouse loci, Char1, and Char2, have previously been shown to control peak parasitemia and host survival. Recent analysis of host response to mouse malaria has demonstrated that the action of several loci is time dependent. Char1 and Char2 act prior to peak parasitemia. Analysis of additional crosses revealed significant linkage to Chromosome 17 on the day following peak parasitemia. This H2-linked locus acts late in infection and is therefore crucial in clearing parasites from the circulation. The cloning of this gene will lead to a greater understanding of the host-parasite interaction, and the kinetics of host gene expression during an immune response. Received: 20 May 1999 / Revised: 9 August 1999     

Mosquito mortality and the evolution of malaria virulence

Abstract Several laboratory studies of malaria parasites (Plasmodium sp.) and some field observations suggest that parasite virulence, defined as the harm a parasite causes to its vertebrate host, is positively correlated with transmission. Given this advantage, what limits the continual evolution of higher parasite virulence? One possibility is that while more virulent strains are more infectious, they are also more lethal to mosquitoes. In this study, we tested whether the virulence of the rodent malaria parasite P. chabaudi in the laboratory mouse was correlated with the fitness of mosquitoes it subsequently infected. Mice were infected with one of seven genetically distinct clones of P. chabaudi that differ in virulence. Weight loss and anemia in infected mice were monitored for 16–17 days before Anopheles stephensi mosquitoes were allowed to take a blood meal from them. Infection virulence in mice was positively correlated with transmission to mosquitoes (infection rate) and weakly associated with parasite burden (number of oocysts). Mosquito survival fell with increasing oocyst burden, but there was no overall statistically significant relationship between virulence in mice and mosquito mortality. Thus, there was no evidence that more virulent strains are more lethal to mosquitoes. Both vector survival and fecundity depended on parasite clone, and contrary to expectations, mosquitoes fed on infections more virulent to mice were more fecund. The strong parasite genetic effects associated with both fecundity and survival suggests that vector fitness could be an important selective agent shaping malaria population genetics and the evolution of phenotypes such as virulence in the vector.     

Expression profiles of peroxiredoxin proteins of the rodent malaria parasite Plasmodium yoelii

Patterns of expression of the 2-Cys and 1-Cys peroxiredoxin (Prx) proteins of the rodent malaria parasite Plasmodium yoelii during its life cycle were observed by immunofluorescent antibody staining and confocal laser scanning microscopy. 2-Cys Prx was expressed in the parasite cytoplasm throughout the life cycle, and the thioredoxin (Trx)-peroxidase activity of 2-Cys Prx revealed with the recombinant protein suggested that the Prx is constitutively expressed and, thus, likely plays a housekeeping role in the parasite's intracellular redox control. In contrast, 1-Cys Prx showed stage-specific expression in blood-stage parasites. The limited expression of 1-Cys Prx in the trophozoite cytoplasm suggests that 1-Cys Prx may be involved in haemoglobin metabolism by the parasite, which generates a prooxidative haem iron and increases intracellular oxidative stress. The antioxidant activity of 1-Cys Prx was tested for its ability to protect yeast enolase against inactivation of the mixed-function oxidation system. Differential expression of the two Prx proteins during the erythrocytic and insect stages suggests the importance of these proteins in protecting parasites against oxidative stress, which is generated by the parasite's metabolism and also from the environment.     

IgG1 and IgG2 antibody responses to Plasmodium falciparum exoantigens correlate inversely and positively, respectively, to the number of malaria attacks

Abstract In Manarintsoa, near Antananarivo, Madagascar, two groups of patients were defined in terms of malaria clinical immune status: Group MA⁺ consisted of 36 patients who suffered from between one to four malaria attacks (MA) during the 20-week study, and Group MA⁻ who comprised of 48 persons who did not have any malaria attacks during this time. In group MA⁺, IgM and IgG antibody levels to Plasmodium falciparum exoantigens (E-Ag) were inversely related to the number of malaria attacks. The level of IgM antibodies were significantly higher in group MA⁺. In contrast, IgG, IgG1, IgG2, IgG3 and IgG4 antibodies to E-Ag were significantly higher in group MA⁻. The level of IgG1 antibodies was inversely correlated, and IgG2 antibodies were positively correlated to the number of malaria attacks.     

Dynamic regulation of single- and mixed-species malaria infection: insights to specific and non-specific mechanisms of control

Our increasing appreciation of the high prevalence of mixed-species Plasmodium infection in malaria-endemic regions has resulted in controversy regarding the likely mechanism(s) of regulation for mixed parasite burden within an individual human host. In the present study, we examined dynamic models of Plasmodium spp. regulation by fever and by non-specific (NS) and species-specific (SS) immunity (including the influence of their variable time-delays, duration, and efficacy) in order to assess the likely role of these factors in regulating detectable parasitemia and clinical disease. Our models suggest that in order to observe the irregular waves of fever and parasitemia that are often found in multiply infected subjects, there must be a differential SS immune effect (beyond the regulatory effects of the species-transcendent density-dependent factors previously posited to control mixed-species parasitemia), and time-dependent variation in immunity to the dominant species. By implementation of individual SS immune controls of non-permanent duration, the resulting multi-dimensional model can be viewed as multiple single-species oscillators coupled via a NS species-transcendent controller. This extended model exhibits the essential patterns of long-term mixed infections. Although this 'circuit-immunity' model gives only a qualitative estimate of the complex web of participating agents and reaction pathways, it provides a starting point for future studies of the specific and NS within-host mechanisms that regulate mixed-species malaria infection.     

Merozoite surface proteins of the malaria parasite: The MSP1 complex and the MSP7 family

The first interaction between the malaria merozoite and the red blood cell it will invade is mediated by molecules on the surface of the two cells. The Plasmodium falciparum merozoite surface protein (MSP)1 complex that contains MSP1 and two other parasite proteins, MSP6 and MSP7, is likely to be an important component in this process. This article reviews the role of the MSP1 complex in the biology of the host parasite interface with a focus on MSP7 and related proteins that are coded by gene families in each of the different Plasmodium spp.     

The fitness of drug-resistant malaria parasites in a rodent model: multiplicity of infection

Malaria infections normally consist of more than one clonally replicating lineage. Within-host interactions between sensitive and resistant parasites can have profound effects on the evolution of drug resistance. Here, using the Plasmodium chabaudi mouse malaria model, we ask whether the costs and benefits of resistance are affected by the number of co-infecting strains competing with a resistant clone. We found strong competitive suppression of resistant parasites in untreated infections and marked competitive release following treatment. The magnitude of competitive suppression depended on competitor identity. However, there was no overall effect of the diversity of susceptible parasites on the extent of competitive suppression or release. If these findings generalize, then transmission intensity will impact on resistance evolution because of its effect on the frequency of mixed infections, not because of its effect on the distribution of clones per host. This would greatly simplify the computational problems of adequately capturing within-host ecology in models of drug resistance evolution in malaria.     

Partial molar volumes of acyl carrier proteins are related to their states of acylation

Acyl carrier protein (ACP), an abundant protein in every cell, plays a central role in a number of metabolic processes requiring acyl group transfer. Conformational flexibility while crucial for its function remains substantially unaddressed. By dual polarization interferometry we establish correlation between the chain length of aliphatic groups covalently linked to Escherichia coli and Plasmodium falciparum ACP and their respective partial molar volumes in solution which helps to subserve the aforesaid goal.     

Prediction of mitochondrial proteins of malaria parasite using bi-profile Bayes feature extraction

Mitochondrial proteins of Plasmodium falciparum are considered as attractive targets for anti-malarial drugs, but the experimental identification of these proteins is a difficult and time-consuming task. Computational prediction of mitochondrial proteins offers an alternative approach. However, the commonly used subcellular location prediction methods are unsuited for P. falciparum mitochondrial proteins whereas the organism and organelle-specific methods were constructed on the basis of a rather small dataset. In this study, a novel dataset termed PfM233, which included 108 mitochondrial and 125 non-mitochondrial proteins with sequence similarity below 25%, was established and the methods for predicting mitochondrial proteins of P. falciparum were described. Both bi-profile Bayes and split amino acid composition were applied to extract the features from the N- and C-terminal sequences of these proteins, which were then used to construct two SVM based classifiers (PfMP-N25 and PfMP-30). Using PfM233 as the dataset, PfMP-N25 and PfMP-30 achieved accuracies (MCCs) of 90.13% (0.80) and 90.99% (0.82). When tested with the commonly used 40 mitochondrial proteins in PfM175 and the 108 mitochondrial proteins in PfM233, these two methods obviously outperformed the existing general, organelle-specific and organism and organelle-specific methods.     

Comparative study of Helicobacter pylori infection in guinea pigs and mice - elevation of acute-phase protein C3 in infected guinea pigs

Eighteen Dunkin-Hartley guinea pigs and 50 NMRI mice were inoculated with Helicobacter pylori and the infection followed by culture, histopathology, antibody response, and plasma levels of the acute-phase proteins albumin, C3, and transferrin for up to 7 weeks. The immune response to H. pylori surface proteins was studied by an enzyme immunoassay (EIA) and Western immunoblot and the plasma levels of albumin, C3, and transferrin were analyzed by single radial immunodiffusion. Guinea pigs had a more severe gastritis and a higher EIA immune response than NMRI mice. Serum C3 levels were elevated in infected guinea pigs after 3 and 7 weeks indicating a systemic inflammatory response and a possible link between H. pylori infection and extragastric manifestations such as vasculitis associated with atherosclerosis. Serum cholesterol levels were analyzed in guinea pigs at 7 weeks and indicated a higher level in H. pylori-infected than in control animals, but this difference was not statistically significant.     

Sequence analysis of the Rhop-3 gene of Plasmodium yoelii

The 110 kDa/Rhop-3 rhoptry protein of Plasmodium falciparum is non-covalently associated with two other proteins, the 140 kDa Rhop-1 and the 130 kDa Rhop-2. cDNAs encoding Rhop-3 from Plasmodium yoelii were isolated using rhoptry-specific antisera from Plasmodium falciparum, P. yoelii, and Plasmodium chabaudi. The cDNAs encoded peptides with partial homology to the C-terminal region (residues 541-861) of P. falciparum Rhop-3. Core regions of homology to the P. falciparum gene will be useful in determining the biological role of Rhop-3 and its potential as a vaccine candidate for malaria.     

冈比亚按蚊嗅觉结合蛋白候选基因cDNA的克隆、鉴定及其表达型分析

疟蚊主要依靠嗅觉发现寄主。非洲疟蚊冈比亚按蚊Anopheles gambiae是一种嗜吸人血的疟疾传播媒介昆虫。该文作者基于其全基因组序列,采用RT-PCR和标准分子克隆技术获得2个嗅觉结合蛋白候选基因agLZ3788和agLZ9988。测序分析结果表明,它们具有嗅觉结合蛋白的标志性结构域。进一步采用半定量RT-PCR技术研究了它们的空间表达型,结果发现它们不但在雌蚊触角中表达,也在其他部位(尤其是蚊虫足部)有强的表达。这一发现说明疟蚊嗅觉结合蛋白可能具有更广的功能,也为进一步重组表达和功能研究提供了重要依据。     

Murine malaria. I. Measurement of the mean rate of increase in vivo of Plasmodium berghei

Swiss mice were inoculated intraperitoneally with RBC infected with Plasmodium berghei. The moment a certain parasitemia was reached in each individual mouse was estimated by means of linear interpolation. The relationship between latent period and log inoculum was investigated by means of simple linear regression. The slopes of the latent period per log inoculum curves were significantly different using different donor mice inoculated with serial 10-fold dilution of infected RBC and exsanguinated in the same phase of the infection. It could not be demonstrated that the slopes of the regression lines depended on the stage of the disease of the donor mouse.     

PlasmoSEP: Predicting surface‐exposed proteins on the malaria parasite using semisupervised self‐training and expert‐annotated data

Accurate and comprehensive identification of surface‐exposed proteins (SEPs) in parasites is a key step in developing novel subunit vaccines. However, the reliability of MS‐based high‐throughput methods for proteome‐wide mapping of SEPs continues to be limited due to high rates of false positives (i.e., proteins mistakenly identified as surface exposed) as well as false negatives (i.e., SEPs not detected due to low expression or other technical limitations). We propose a framework called PlasmoSEP for the reliable identification of SEPs using a novel semisupervised learning algorithm that combines SEPs identified by high‐throughput experiments and expert annotation of high‐throughput data to augment labeled data for training a predictive model. Our experiments using high‐throughput data from the Plasmodium falciparum surface‐exposed proteome provide several novel high‐confidence predictions of SEPs in P. falciparum and also confirm expert annotations for several others. Furthermore, PlasmoSEP predicts that 25 of 37 experimentally identified SEPs in Plasmodium yoelii salivary gland sporozoites are likely to be SEPs. Finally, PlasmoSEP predicts several novel SEPs in P. yoelii and Plasmodium vivax malaria parasites that can be validated for further vaccine studies. Our computational framework can be easily adapted to improve the interpretation of data from high‐throughput studies.     

中国海南岛人恶性疟原虫基因文库的构建及环子孢子蛋白基因的筛选

本文介绍了以噬菌体λEMBL3为载体的中国海南岛人恶性疟原虫FCC1/HN分离株基因文库的构建。所得重组体的数目为3.3×10~4pfu,其相当于构建完整基因库理论计算值的6倍。作者以人工合成的巴西株恶性疟环子孢子蛋白基因重复序列区的24-mer寡核苷酸(AATGCAAACCCAAATGCAAACCCA)作探针,进行噬斑原位杂交,筛得三株阳性克隆。对其一重组体进行酶谱分析和Southern印迹实验,环子孢子蛋白基因被定位于HindⅢ和BamHI联合降解后所得的的4kb大小的片段上。     

Failure to respond to the surface of Plasmodium falciparum infected erythrocytes predicts susceptibility to clinical malaria amongst African children

Following infection with Plasmodium falciparum malaria, children in endemic areas develop antibodies specific to antigens on the parasite-infected red cell surface of the infecting isolate, antibodies associated with protection against subsequent infection with that isolate. In some circumstances induction of antibodies to heterologous parasite isolates also occurs and this has been suggested as evidence for cross-reactivity of responses against the erythrocyte surface. The role of these relatively cross-reactive antibodies in protection from clinical malaria is currently unknown. We studied the incidence of clinical malaria amongst children living on the coast of Kenya through one high transmission season. By categorising individuals according to their pre-season parasite status and antibody response to the surface of erythrocytes infected with four parasite isolates we were able to identify a group of children, those who failed to make a concomitant antibody response in the presence of an asymptomatic parasitaemia, at increased susceptibility to clinical malaria in the subsequent 6 months. The fact that this susceptible group was identified regardless of the parasite isolate tested infers a cross-reactive or conserved target is present on the surface of infected erythrocytes. Identification of this target will significantly aid understanding of naturally acquired immunity to clinical malaria amongst children in endemic areas.