Molecular dynamics simulation of the Staphylococcus aureus YsxC protein: molecular insights into ribosome assembly and allosteric inhibition of the protein.

YsxC from Staphylococcus aureus is a member of the GTPase protein family, and is involved in the ribosomal assembly and stability of this microorganism through its interactions with the L17, S2 and S10 ribosomal proteins. Inhibition of its interactions with L17, S2, S10 and the ß' subunit of RNA polymerase influences ribosomal assembly, which may affect the growth of the microorganism. This makes YsxC a novel target for the design of inhibitors to treat the disease caused by S. aureus. Understanding the interaction mechanism between YsxC and its partners would aid in the identification of potential catalytic residues, which could then be targeted to inhibit its function. Accordingly, in the present study, an in silico analysis of the interactions between YsxC and L17, S2 and S10 was performed, and the potential residues involved in these interactions were identified. Based on the simulation results, a possible mechanism for the interactions between these proteins was also proposed. Finally, six ligands from among a library of 81,000 chemical molecules were found to interact with parts of the G2 and switch II regions of the YsxC protein. Moreover, their interactions with the YsxC protein were observed to provoke changes at its GTP-binding site, which suggests that the binding of these ligands leads to a reduction in GTPase activity, and they were also found to affect the interactions of YsxC with its partners. This observation indicates that the proposed interacting site of YsxC may act as an allosteric site, and disrupting interactions at this site might lead to novel allosteric inhibition of the YsxC protein.

Uneven spread of cis- and trans-editing aminoacyl-tRNA synthetase domains within translational compartments of P. falciparum.

Accuracy of aminoacylation is dependent on maintaining fidelity during attachment of amino acids to cognate tRNAs. Cis- and trans-editing protein factors impose quality control during protein translation, and 8 of 36 Plasmodium falciparum aminoacyl-tRNA synthetase (aaRS) assemblies contain canonical putative editing modules. Based on expression and localization profiles of these 8 aaRSs, we propose an asymmetric distribution between the parasite cytoplasm and its apicoplast of putative editing-domain containing aaRSs. We also show that the single copy alanyl- and threonyl-tRNA synthetases are dually targeted to parasite cytoplasm and apicoplast. This bipolar presence of two unique synthetases presents opportunity for inhibitor targeting their aminoacylation and editing activities in twin parasite compartments. We used this approach to identify specific inhibitors against the alanyl- and threonyl-tRNA synthetases. Further development of such inhibitors may lead to anti-parasitics which simultaneously block protein translation in two key parasite organelles, a strategy of wider applicability for pathogen control.