Cooperativity between Plasmodium falciparum adhesive proteins for invasion into erythrocytes.

Plasmodium falciparum is the most virulent of the Plasmodium species infective to humans. Different P. falciparum strains vary in their dependence on erythrocyte receptors for invasion and their ability to switch in their utilization of different receptor repertoires. Members of the reticulocyte-binding protein-like (RBL) family of invasion ligands are postulated to play a central role in defining ligand-receptor interactions, known as invasion pathways. Here we report the targeted gene disruption of PfRh2b and PfRh2a in W2mef, a parasite strain that is heavily dependent on sialic-acid receptors for invasion, and show that the PfRh2b ligand is functional in this parasite background. Like the parental line, parasites lacking either PfRh2a or PfR2b can switch to a sialic acid-independent invasion pathway. However, both of the switched lines exhibit a reduced efficiency for invasion into sialic acid-depleted cells, suggesting a role for both PfRh2b and PfRh2a in invasion via sialic acid-independent receptors. We also find a strong selective pressure for the reconstitution of PfRh2b expression at the expense of PfRh2a. Our results reveal the importance of genetic background in ligand-receptor usage by P. falciparum parasites, and suggest that the co-ordinate expression of PfRh2a, PfRh2b together mediate efficient sialic acid-independent erythrocyte invasion.

Antisense RNA and RNAi in protozoan parasites: working hard or hardly working?

The complex life cycles of many protozoan parasites require the ability to respond to environmental and developmental cues through regulated gene expression. Traditionally, parasitologists have investigated these mechanisms by identifying and characterizing proteins that are necessary for the regulated expression of the genetic material. Although often successful, it is clear that protein-mediated gene regulation is only part of a complex story in which RNA itself is endowed with regulatory functions. Herein, we review both the known and potential regulatory roles of two types of RNA pathways within protozoan parasites: the RNA interference pathway and natural antisense transcripts. A better understanding of the native role of these pathways will not only enhance our understanding of the biology of these organisms but also aid in the development of more robust tools for reverse genetic analysis in this post-genomic era.

Multiple drug resistance genes in malaria -- from epistasis to epidemiology.

A decline in our ability to successfully treat patients with malaria infections of the parasitic protozoan Plasmodium falciparum with cheap quinoline drugs has led to a huge escalation in morbidity and mortality in recent years. Many approaches have been taken, including classical genetics, reverse genetics and molecular epidemiology, to identify the molecular determinants underlying this resistance. The contribution of the P. falciparum multidrug resistance gene, pfmdr1, to antimalarial resistance has been a source of controversy for over a decade since it was first identified. In the current issue of Molecular Microbiology, Sidhu and colleagues use powerful reverse genetics to demonstrate the importance of commonly occurring alleles of pfmdr1 in conferring resistance to the second-line drugs quinine and sensitivity to the new alternatives mefloquine and artemisinin. They also elegantly highlight the importance of genetic background and epistasis between pfmdr1 and other potential modulators of drug resistance. Such molecular knowledge will facilitate surveillance/monitoring and aid the development of strategies for the reversal of resistance.

PfMyb1, a Plasmodium falciparum transcription factor, is required for intra-erythrocytic growth and controls key genes for cell cycle regulation.

During the complex life cycle of Plasmodium falciparum, divided between mosquito and human hosts, the regulation of morphologic changes implies a fine control of transcriptional regulation. Transcriptional control, however, and in particular its molecular actors, transcription factors and regulatory motifs, are as yet poorly described in Plasmodium. In order to decipher the molecular mechanisms implicated in transcriptional regulation, a transcription factor belonging to the tryptophan cluster family was studied. In a previous work, the PfMyb1 protein, contained in nuclear extracts, was shown to have DNA binding activity and to interact specifically with myb regulatory elements. We used long pfmyb1 double-stranded RNA (dsRNA) to interfere with the cognate messenger expression. Parasite cultures treated with pfmyb1 dsRNA exhibited a 40% growth inhibition when compared with either untreated cultures or cultures treated with unrelated dsRNA, and parasite mortality occurred during trophozoite to schizont transition. In addition, the pfmyb1 transcript and protein decreased by as much as 80% in treated trophozoite cultures at the time of their maximum expression. The global effect of this partial loss of transcript and protein was investigated using a thematic DNA microarray encompassing genes involved in signal transduction, cell cycle and transcriptional regulation. SAM software enabled us to identify several genes that were differentially expressed and probably directly or indirectly under the control of PfMyb1. Using chromatin immuno-precipitation, we demonstrated that PfMyb1 binds, within the parasite nuclei, to several promoters and therefore participates directly in the transcriptional regulation of the corresponding genes. This study provides the first evidence of a regulation network involving a Plasmodium transcription factor.

Transcriptome of 3D7 and its gametocyte-less derivative F12 Plasmodium falciparum clones during erythrocytic development using a gene-specific microarray assigned to gene regulation, cell cycle and transcription factors.

During the complex life cycle of Plasmodium falciparum, through mosquito and human, the erythrocytic cycle is responsible for malarial disease and transmission. The regulation of events that occur during parasite development, such as proliferation and differentiation, implies a fine control of transcriptional activities that in turn governs the expression profiles of sets of genes. Pathways that underline gametocyte commitment are yet poorly understood even though kinases and transcription factors have been assumed to play a crucial role in this event. In order to understand the molecular mechanisms controlling the variation of gene expression profiles that might participate in early gametocytogenesis, the transcriptome of two clones, 3D7 and its gametocyte-less derivative F12, was compared at five time points of the erythrocytic asexual development. We have used a thematic DNA microarray containing 150 PCR fragments, representative of P. falciparum genes involved in signal transduction, cell cycle and transcriptional regulation. We identified several genes eliciting different expression profiles among which some implicated in gene regulation or encoding putative transcription factors. The differential expression of transcription factor and kinase transcripts observed in the two clones may enlighten genes that might have a role in impairment of the early gametocytogenesis of the F12 clone.

Transcription status of vaccine candidate genes of Plasmodium falciparum during the hepatic phase of its life cycle.

The CSP, EMP2/MESA, MSP2, MSP3, MSP5, RAP1, RAP2, RESA1, SERA1 and SSP2/TRAP genes of Plasmodium falciparum are vaccine candidates. The hepatic phase of the infection is of major interest due to the protection induced by immunization with radiation-attenuated sporozoites. We therefore performed RT-PCR experiments to determine whether these genes are transcribed during this phase. Whereas transcripts of the CSP gene were detectable only in sporozoites, transcripts of the MSP2, MSP5, RAP1, RAP2, SERA1 and SSP2/TRAP genes were present in both sporozoites and infected hepatocytes. Transcripts of the EMP2/MESA gene were detectable only in infected hepatocytes. Transcripts of the MSP3 and RESA1 genes were not detectable in sporozoites or in infected hepatocytes. Genes presently identified as being transcribed during the hepatic phase may be of interest with respect to the design of preventative vaccination strategies.