A cornucopia of research resources for the fourth rodent malaria parasite species

The study of human malaria caused by species of Plasmodium has undoubtedly been enriched by the use of model systems, such as the rodent malaria parasites originally isolated from African thicket rats. A significant gap in the arsenal of resources of the species that make up the rodent malaria parasites has been the lack of any such tools for the fourth of the species, Plasmodium vinckei. This has recently been rectified by Abhinay Ramaprasad and colleagues, whose pivotal paper published in BMC Biology describes a cornucopia of new P. vinckei ‘omics datasets, mosquito transmission experiments, transfection protocols, and virulence phenotypes, to propel this species firmly into the twenty-first century.

Plasmodium vinckei genomes provide insights into the pan-genome and evolution of rodent malaria parasites

Background Rodent malaria parasites (RMPs) serve as tractable tools to study malaria parasite biology and host-parasite-vector interactions. Among the four RMPs originally collected from wild thicket rats in sub-Saharan Central Africa and adapted to laboratory mice, Plasmodium vinckei is the most geographically widespread with isolates collected from five separate locations. However, there is a lack of extensive phenotype and genotype data associated with this species, thus hindering its use in experimental studies. Results We have generated a comprehensive genetic resource for P. vinckei comprising of five reference-quality genomes, one for each of its subspecies, blood-stage RNA sequencing data for five P. vinckei isolates, and genotypes and growth phenotypes for ten isolates. Additionally, we sequenced seven isolates of the RMP species Plasmodium chabaudi and Plasmodium yoelii, thus extending genotypic information for four additional subspecies enabling a re-evaluation of the genotypic diversity and evolutionary history of RMPs. The five subspecies of P. vinckei have diverged widely from their common ancestor and have undergone large-scale genome rearrangements. Comparing P. vinckei genotypes reveals region-specific selection pressures particularly on genes involved in mosquito transmission. Using phylogenetic analyses, we show that RMP multigene families have evolved differently across the vinckei and berghei groups of RMPs and that family-specific expansions in P. chabaudi and P. vinckei occurred in the common vinckei group ancestor prior to speciation. The erythrocyte membrane antigen 1 and fam-c families in particular show considerable expansions among the lowland forest-dwelling P. vinckei parasites. The subspecies from the highland forests of Katanga, P. v. vinckei, has a uniquely smaller genome, a reduced multigene family repertoire and is also amenable to transfection making it an ideal parasite for reverse genetics. We also show that P. vinckei parasites are amenable to genetic crosses. Conclusions Plasmodium vinckei isolates display a large degree of phenotypic and genotypic diversity and could serve as a resource to study parasite virulence and immunogenicity. Inclusion of P. vinckei genomes provide new insights into the evolution of RMPs and their multigene families. Amenability to genetic crossing and transfection make them also suitable for classical and functional genetics to study Plasmodium biology.

Plasmodium vinckei genomes provide insights into the pan-genome and evolution of rodent malaria parasites

BackgroundRodent malaria parasites (RMPs) serve as tractable tools to study malaria parasite biology and host-parasite-vector interactions. Plasmodium vinckei is the most geographically widespread of the four RMP species collected in sub-Saharan Central Africa. Several P. vinckei isolates are available but relatively less characterized than other RMPs, thus hindering their use in experimental studies. We have generated a comprehensive resource for P. vinckei comprising of high-quality reference genomes, genotypes, gene expression profiles and growth phenotypes for ten P. vinckei isolates.ResultsThe P. vinckei subspecies have diverged widely from their common ancestor and have undergone genomic structural variations. The subspecies from Katanga, P. v. vinckei, has a uniquely smaller genome, a reduced multigene family repertoire and is also amenable to genetic manipulation making it an ideal parasite for reverse genetics. Comparing P. vinckei genotypes reveals region-specific selection pressures particularly on genes involved in mosquito transmission. The erythrocyte membrane antigen 1 and fam-c families have expanded considerably among the lowland forest-dwelling P. vinckei parasites. Genetic crosses can be established in P. vinckei but are limited at present by low transmission success under the experimental conditions tested in this study.ConclusionsPlasmodium vinckei isolates display a large degree of phenotypic and genotypic diversity and could serve as a resource to study parasite virulence and immunogenicity. Inclusion of P. vinckei genomes provide new insights into the evolution of RMPs and their multigene families. Amenability to genetic crossing and genetic manipulation make them also suitable for classical and functional genetics to study Plasmodium biology.

Splenohepatomegaly in Protein-Malourished Mice Infected with Plasmodium Vinckei

Cellular and histopathological observations were made with light microscopy during the Plasmodium vinckeiinfection in protein-malnourished mice (fed on 2% casein diet and para-aminobenzoic acid deficient diet (PABA-DD).In the infected spleen, hyperplasia of the red as well as the white pulp was evident; active erythropoiesis and lymphopoiesis. Hyperemia and deposition of malarial pigments inside the macrophages. Cloudy swelling was noticed in the swollen hepatic cells of the uninfected liver due to protein deficiency. This lesion had developed to fatty infiltration in the infected protein-malnourished mice. These new and interesting changes represent the combined deleterious effect upon the host of infection and protein-malnutrition. Hypertrophy of the kupffer cells due to progressive phagocytosis of malarial pigments. In addition, focal necrosis surrounded by inflammatory cells was seen.