Molecular modeling,in silico screening and molecular dynamics of PfPRL-PTP of P. falciparum for identification of potential anti-malarials

Millions of deaths occur every year due to malaria. Growing resistance against existing drugs for treatment of malaria has exaggerated the problem further. There is an intense demand of identifying drug targets in malaria parasite. PfPRL-PTP protein is PRL group of phosphatase, and one of the interesting drug targets being involved in three important pathways of malaria parasite (secretion, phosphorylation, and prenylation). Therefore, in this study, we have modeled three-dimensional structure of PfPRL-PTP followed by validation of 3D structure using RAMPAGE, verify3D, and other structure validation tools. We could identify 12 potential inhibitory compounds using in silico screening of NCI library against PfPRL-PTP with Glide. The molecular dynamics simulation was also performed using GROMACS on PfPRL-PTP model alone and PfPRL-PTP-inhibitor complex. This study of identifying potential drug-like molecules would add up to the process of drug discovery against malaria parasite.     

Mutagenic exploration of the active site of lactate dehydrogenase from Plasmodium falciparum

Several site-directed mutations of residues around the active site of the lactate dehydrogenase from Plasmodium falciparum are described. These include changes to three highly, but not completely, conserved residues in the pocket of the active site and also three changes (including deletions) to the active site loop. Changes to residues in the active-site pocket resulted in little or no over-production of protein and no enzymic activity. Likewise, a five residue deletion from the active site loop gave no over-produced protein, while a two residue deletion and changes of residue type in this loop were tolerated. The results are discussed in the light of this protein being a suitable target for novel anti-malarials.     

Structure-based binding between protein farnesyl transferase and PRL-PTP of malaria parasite: an interaction study of prenylation process in Plasmodium

Protein prenylation is a post-translational modification critical for many cellular processes such as DNA replication, signaling, and trafficking. It is mediated by protein farnesyltransferase by recognizing ‘CAAX’ motif on protein substrate. Plasmodium falciparum also possesses many such proteins with ‘CAAX’ motif, involved in various pathways of the parasite. The interaction studies of PfPFT with its substrate were carried out using synthetic peptides but not with full protein. Therefore, in this study, we have modeled both PfPFT and its substrate protein tyrosine phosphatase (PfPRL-PTP) followed by interaction studies using protein–protein docking and molecular dynamics simulation. Our findings provided a clear picture of interactions at atomic level between prenyltransferase and its protein substrate. We are assured that this piece of information can be extended to many other proteins of parasite containing ‘CAAX’ motif and that it may also lead to the development of anti-malarials based on the inhibition of prenylation-dependent pathways of parasite..