Abstract
BackgroundTreatment of parasitic diseases has been challenging due to evolution of drug resistant parasites, and thus there is need to identify new class of drugs and drug targets. Protein translation is important for survival of malarial parasite, Plasmodium, and the pathway is present in all of its life cycle stages. Aminoacyl tRNA synthetases are primary enzymes in protein translation as they catalyse amino acid addition to the cognate tRNA. This study sought to understand differences between Plasmodium and human aminoacyl tRNA synthetases through bioinformatics analysis.MethodsPlasmodium berghei, Plasmodium falciparum, Plasmodium fragile, Plasmodium knowlesi, Plasmodium malariae, Plasmodium ovale, Plasmodium vivax, Plasmodium yoelii and human aminoacyl tRNA synthetase sequences were retrieved from UniProt database and grouped into 20 families based on amino acid specificity. These families were further divided into two classes. Both families and classes were analysed. Motif discovery was carried out using the MEME software, sequence identity calculation was done using an in-house Python script, multiple sequence alignments were performed using PROMALS3D and TCOFFEE tools, and phylogenetic tree calculations were performed using MEGA vs 7.0 tool. Possible alternative binding sites were predicted using FTMap webserver and SiteMap tool.ResultsMotif discovery revealed Plasmodium-specific motifs while phylogenetic tree calculations showed that Plasmodium proteins have different evolutionary history to the human homologues. Human aaRSs sequences showed low sequence identity (below 40%) compared to Plasmodium sequences. Prediction of alternative binding sites revealed potential druggable sites in PfArgRS, PfMetRS and PfProRS at regions that are weakly conserved when compared to the human homologues. Multiple sequence analysis, motif discovery, pairwise sequence identity calculations and phylogenetic tree analysis showed significant differences between parasite and human aaRSs proteins despite functional and structural conservation. These differences may provide a basis for further exploration of Plasmodium aminoacyl tRNA synthetases as potential drug targets.ConclusionThis study showed that, despite, functional and structural conservation, Plasmodium aaRSs have key differences from the human homologues. These differences in Plasmodium aaRSs can be targeted to develop anti-malarial drugs with less toxicity to the host.
Highlights
Treatment of parasitic diseases has been challenging due to evolution of drug resistant parasites, and there is need to identify new class of drugs and drug targets
The data set consisted of the five Plasmodium species that infect human, P. berghei, P. yoelii, P. fragile and human homologues
More mammalian sequences were included for multiple sequence alignment (MSA) and motif search within each aminoacyl tRNA synthetases (aaRS) family to avoid bias
Summary
Treatment of parasitic diseases has been challenging due to evolution of drug resistant parasites, and there is need to identify new class of drugs and drug targets. Malaria, leishmaniasis and filariasis affect millions of people in the world yearly [1,2,3,4]. These diseases cause a remarkable burden in economic development and health of affected countries and the need to devise control and prevention strategies. There is need to develop new classes of drugs and to identify drug targets to solve the shortcoming of drug resistance Targeting housekeeping pathways such as protein translation may help deal with drug resistance as they are important for the survival of most parasites [11,12,13]
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