Differences in erythrocyte receptor specificity of different parts of the Plasmodium falciparum reticulocyte binding protein homologue 2a.

The Plasmodium falciparum reticulocyte-binding-like protein homologue (RH) and erythrocyte binding-like (EBL) protein families play important roles during invasion, though their exact roles are not clear. Both EBL and RH proteins are thought to directly bind different receptors on the surface of the erythrocyte, and the binding properties for a number of EBLs and RHs have been described. While P. falciparum RH1 (PfRH1) and PfRH4 have been shown to act directly in two alternative invasion pathways used by merozoites, the functions of PfRH2a and PfRH2b during invasion are less defined. Here, using monoclonal antibodies raised against a unique region of PfRH2a, we show that PfRH2a moves from the rhoptry neck to the moving junction during merozoite invasion. The movement of PfRH2a to the junction is independent of the invasion pathway used by the merozoite, suggesting an additional function of the protein that is independent of receptor binding. We further show that PfRH2a is processed both in the schizont and during invasion, resulting in proteins with different erythrocyte binding properties. Our findings suggest that PfRH2a and, most likely, the other members of the RH family, depending on their processing stage, can engage different receptors at different stages of the invasion process.

Defining species specific genome differences in malaria parasites.

BACKGROUND: In recent years a number of genome sequences for different plasmodium species have become available. This has allowed the identification of numerous conserved genes across the different species and has significantly enhanced our understanding of parasite biology. In contrast little is known about species specific differences between the different genomes partly due to the lower sequence coverage and therefore relatively poor annotation of some of the draft genomes particularly the rodent malarias parasite species. RESULTS: To improve the current annotation and gene identification status of the draft genomes of P. berghei, P. chabaudi and P. yoelii, we performed genome-wide comparisons between these three species. Through analyses via comparative genome hybridizations using a newly designed pan-rodent array as well as in depth bioinformatics analysis, we were able to improve on the coverage of the draft rodent parasite genomes by detecting orthologous genes between these related rodent parasite species. More than 1,000 orthologs for P. yoelii were now newly associated with a P. falciparum gene. In addition to extending the current core gene set for all plasmodium species this analysis also for the first time identifies a relatively small number of genes that are unique to the primate malaria parasites while a larger gene set is uniquely conserved amongst the rodent malaria parasites. CONCLUSIONS: These findings allow a more thorough investigation of the genes that are important for host specificity in malaria.

Microarray and real-time RT-PCR analyses of a novel set of differentially expressed human genes in ECV304 endothelial-like cells infected with dengue virus type 2.

The cellular and molecular pathways of dengue infection have not been as intensively studied compared to the host immunological responses. Changes in mRNA expression levels of ECV304 human endothelial-like cells following infection with the virulent New Guinea C strain of dengue virus type 2 were analyzed by a microarray system comprising 7600 oligonucleotide cDNAs. After normalization against the uninfected control using two independent software programs, 111 genes exhibited at least a 1.5-fold difference in expression level. Out of these, 21 mRNAs were upregulated while 90mRNAs were downregulated. Quantitative real-time RT-PCR was then performed to determine the expression patterns of 15 selected genes of interest involved in the cell cycle (MAD3), apoptosis (RIPK3, PDCD8), cellular receptors (H963, CCR7, KLRC3), transcriptional regulation (RUNX3, HNF4G, MIZ1), signal transduction (HSP27, TRIP, MAP4K4), enzymes (angiotensinogen), protein transport (AP4M1), and cytoskeleton (ACTA2). Dengue virus infection resulted in the downregulation of the C-terminal alternatively spliced p53 variant, the pro-apoptotic IG20 and IG20-SV2 isoforms, and the Fas apoptosis inhibitory molecule (FAIM). Most of the real-time RT-PCR data showed concordance with the normalized microarray data. Hence, real-time RT-PCR validation of high-throughput gene microarray screening is important and necessary before further conclusions on gene expression can be drawn. This study elucidated novel information on the complex responses at the transcriptional level in susceptible human endothelial-like cells induced by a virulent dengue virus strain implicated in the pathogenesis of dengue and/or its complications.

Differential display RT-PCR analysis of ECV304 endothelial-like cells infected with dengue virus type 2 reveals messenger RNA expression profiles of multiple human genes involved in known and novel roles.

Differential display (DD)-RT-PCR was employed to analyze mRNAs from ECV304 human endothelial-like cells undergoing apoptosis following infection with the virulent New Guinea C strain of dengue virus type 2 in order to elucidate the cellular gene responses to dengue viral infection at the transcriptional level. We isolated, sequenced, and identified 203 differentially expressed and overlapping cDNA fragments, all of which were of human origin except 1 that was of viral origin. Out of these, 78 were individual distinct clones comprising 46 and 32 expressed sequence tags (ESTs) that exhibited upregulated and downregulated trends, respectively. Of the 78 differentially expressed mRNAs, 16 did not match any characterized genes or ESTs. The remaining 62 mRNAs modified by dengue virus infection matched known genes, including those encoding components of the cell cycle (Anillin, CDC27), cytoskeleton (epsilon-tubulin), signal transduction (OPHN1, PPP2R2A, TIRAP), protein translation and modification (EIF3S10, IF2, TMEM1), transcriptional regulation (alpha-NAC, C20orf104, EGR1, ELP2), apoptotic cell death (RICK), membrane (BPAG1), and mitochondrial-related proteins. Semiquantitative RT-PCR and real-time RT-PCR authenticated further the altered expression patterns of selected genes of interest. These data demonstrate the feasibility of mRNA DD in providing insights into the complex responses of the transcriptional machinery of permissive and apoptotic human endothelial-like cells in the pathogenesis of dengue and/or its complications induced by the virulent dengue virus type 2.