PfeIF4E and PfeIF4A colocalize and their double-stranded RNA inhibits Plasmodium falciparum proliferation

Identification of mRNA 5' cap-associated proteins in the human malaria parasite Plasmodium falciparum

Eukaryotic messenger RNA is translated via a 5' cap-dependent initiation mechanism. Experimental evidence for proteins involved with translation initiation among eukaryotic parasites is lacking, including Plasmodium falciparum, the human malaria parasite. Native P. falciparum proteins from asexual stage parasites were enriched using a 5' cap affinity matrix. Proteomic analysis of enriched protein eluates revealed proteins putatively associated with the 5' cap. The canonical 5' cap-binding protein eIF4E (PF3D7_0315100) was the most reproducibly enriched protein. The eIF4A and eIF4G proteins hypothesized to form the eIF4F initiation complex with eIF4E were also detected as 5' cap enriched, albeit with low reproducibility. Surprisingly, enolase (ENO) was the second most enriched protein after eIF4E. Recombinant ENO protein did not demonstrate 5' cap activity, suggesting an indirect association of the native ENO with the 5' cap.

ATPase activity of Plasmodium falciparum MLH is inhibited by DNA-interacting ligands and dsRNAs of MLH along with UvrD curtail malaria parasite growth

Malaria caused by Plasmodium falciparum is the major disease burden all over the world. Recently, the situation has deteriorated because the malarial parasites are becoming progressively more resistant to numerous commonly used antimalarial drugs. Thus, there is a critical requirement to find other means to restrict and eliminate malaria. The mismatch repair (MMR) machinery of parasite is quite unique in several ways, and it can be exploited for finding new drug targets. MutL homolog (MLH) is one of the major components of MMR machinery, and along with UvrD, it helps in unwinding the DNA. We have screened several DNA-interacting ligands for their effect on intrinsic ATPase activity of PfMLH protein. This screening suggested that several ligands such as daunorubicin, etoposide, ethidium bromide, netropsin, and nogalamycin are inhibitors of the ATPase activity of PfMLH, and their apparent IC₅₀ values range from 2.1 to 9.35 μM. In the presence of nogalamycin and netropsin, the effect was significant because in their presence, the V _max value dropped from 1.024 μM of hydrolyzed ATP/min to 0.596 and 0.643 μM of hydrolyzed ATP/min, respectively. The effect of double-stranded RNAs of PfMLH and PfUvrD on growth of P. falciparum 3D7 strain was studied. The parasite growth was significantly inhibited suggesting that these components belonging to MMR pathway are crucial for the survival of the parasite.

Translational regulation in blood stages of the malaria parasite Plasmodium spp.: systems-wide studies pave the way

The malaria parasite Plasmodium spp. varies the expression profile of its genes depending on the host it resides in and its developmental stage. Virtually all messenger RNA (mRNA) is expressed in a monocistronic manner, with transcriptional activation regulated at the epigenetic level and by specialized transcription factors. Furthermore, recent systems-wide studies have identified distinct mechanisms of post-transcriptional and translational control at various points of the parasite lifecycle. Taken together, it is evident that 'just-in-time' transcription and translation strategies coexist and coordinate protein expression during Plasmodium development, some of which we review here. In particular, we discuss global and specific mechanisms that control protein translation in blood stages of the human malaria parasite Plasmodium falciparum, once a cytoplasmic mRNA has been generated, and its crosstalk with mRNA decay and storage. We also focus on the widespread translational delay observed during the 48-hour blood stage lifecycle of P. falciparum-for over 30% of transcribed genes, including virulence factors required to invade erythrocytes-and its regulation by cis-elements in the mRNA, RNA-processing enzymes and RNA-binding proteins; the first-characterized amongst these are the DNA- and RNA-binding Alba proteins. More generally, we conclude that translational regulation is an emerging research field in malaria parasites and propose that its elucidation will not only shed light on the complex developmental program of this parasite, but may also reveal mechanisms contributing to drug resistance and define new targets for malaria intervention strategies. WIREs RNA 2016, 7:772-792. doi: 10.1002/wrna.1365 For further resources related to this article, please visit the WIREs website.

Challenges of drug-resistant malaria

Over the past six decades, the drug resistance of Plasmodium falciparum has become an issue of utmost concern. Despite the remarkable progress that has been made in recent years in reducing the mortality rate to about 30% with the scaling-up of vector control, introduction of artemisinin-based combination therapies and other malaria control strategies, the confirmation of artemisinin resistance on the Cambodia–Thailand border threatened all the previous success. This review addresses the global scenario of antimalarial resistance and factors associated with it, with the main emphasis on futuristic approaches like nanotechnology and stem cell therapy that may impede resistant malaria, along with novel medications which are preparing to enter the global antimalarial market. These novel studies are likely to escalate over the coming years and will hopefully help to reduce the burden of malaria.

Protective immunity induced by a DNA vaccine expressing eIF4A of Toxoplasma gondii against acute toxoplasmosis in mice

Toxoplasma gondii is an obligate intracellular protozoan parasite infecting humans, mammals and birds. Eukaryotic translation initiation factor (eIF4A) is a newly identified protein associated with tachyzoite virulence. To evaluate the protective efficacy of T. gondii eIF4A, a DNA vaccine (pVAX-eIF4A) encoding T. gondii eIF4A (Tg-eIF4A) gene was constructed. The expression ability of this recombinant DNA plasmid was examined in Marc145 cells by IFA. Then, Kunming mice were intramuscularly immunized with pVAX-eIF4A and followed by challenge infection with the highly virulent T. gondii RH strain. The results showed that vaccination with pVAX-eIF4A elicited specific humoral responses, with high IgG antibody titers and specific lymphocyte proliferative responses. The cellular immune response was associated with significant production of IFN-γ, IL-2 in Kunming mice, and a mixed IgG1/IgG2a response with predominance of IgG2a production, indicating that a Th1 type response was elicited after immunization with pVAX-eIF4A. In addition, the increase of the percentage of CD8+ T cells in lymphoid in mice suggested the activation of MHC class I restricted antigen presentation pathways. After lethal challenge, the mice vaccinated with the pVAX-eIF4A showed a significantly prolonged survival time (23.0±5.5 days) compared with control mice which died within 7 days of challenge (P<0.05). These results demonstrate that pVAX-eIF4A could elicit strong humoral, Th1-type cellular immune responses and increase survival time of immunized mice, suggesting that eIF4A is a promising vaccine candidate against acute T. gondii infection in mice.

Enhanced purification and characterization of the PfeIF4A (PfH45) helicase from Plasmodium falciparum using a codon-optimised clone

With the intention of investigating the DNA strand displacement properties of Plasmodium falciparum helicase PfeIF4A (formerly known as PfH45) a codon-optimized gene for expression in Escherichia coli has been produced. Several histidine-containing proteins with intrinsic helicase activity were captured from the bacterial sonicate by initial Ni(2+)-chromatography. Heparin and size-exclusion steps were subsequently required for unambiguous PfeIF4A purification. This strategy generated an active recombinant protein of significantly improved yield in comparison to previously published studies (~4.2 mg/g wet weight of cells). Helicase unwinding assays confirmed a bipolar activity, but revealed a preference for unwinding a free 3'-end, with a rate of displacement in the 3'-5' direction 2-fold higher than that in the 5'-3' direction. DNA constructs with two, three or four blunt ends were not unwound. Studies confirmed the enzyme to be Mg(2+)-dependent, optimally active at 37°C and had a background ATP turnover rate of 23.16±1.74 pmol/min, which in the presence of single- or double-stranded DNA doubled to 42.92±3.21 pmol/min.

A Synthetic Biology Project - Developing a single-molecule device for screening drug-target interactions

This review describes a European-funded project in the area of Synthetic Biology. The project seeks to demonstrate the application of engineering techniques and methodologies to the design and construction of a biosensor for detecting drug-target interactions at the single-molecule level. Production of the proteins required for the system followed the principle of previously described "bioparts" concepts (a system where a database of biological parts - promoters, genes, terminators, linking tags and cleavage sequences - is used to construct novel gene assemblies) and cassette-type assembly of gene expression systems (the concept of linking different "bioparts" to produce functional "cassettes"), but problems were quickly identified with these approaches. DNA substrates for the device were also constructed using a cassette-system. Finally, micro-engineering was used to build a magnetoresistive Magnetic Tweezer device for detection of single molecule DNA modifying enzymes (motors), while the possibility of constructing a Hall Effect version of this device was explored. The device is currently being used to study helicases from Plasmodium as potential targets for anti-malarial drugs, but we also suggest other potential uses for the device.

Gene silencing in parasites: current status and future prospects

Parasitic diseases cause important losses in public and veterinary health worldwide. Novel drugs, more reliable diagnostic techniques and vaccine candidates are urgently needed. Due to the complexity of parasites and the intricate relationship with their hosts, development of successful tools to fight parasites has been very limited to date. The growing information on individual parasite genomes is now allowing the use of a broader range of potential strategies to gain deeper insights into the host-parasite relationship and has increased the possibilities to develop molecular-based tools in the field of parasitology. Nevertheless, functional studies of respective genes are still scarce. The RNA interference phenomenon resulting in the regulation of protein expression through the specific degradation of defined mRNAs, and more specifically the possibility of artificially induce it, has shown to be a powerful tool for the investigation of proteins function in many organisms. Recent advances in the design and delivery of targeting molecules allow efficient and highly specific gene silencing in different types of parasites, pointing out this technology as a powerful tool for the identification of novel vaccine candidates or drug targets at the high-throughput level in the near future, and could enable researchers to functionally annotate parasite genomes. The aim of this review is to provide a comprehensive overview on the current advances and pitfalls in gene silencing mechanisms, techniques, applications and prospects in animal parasites.