A boosted unbiased molecular dynamics method for predicting ligands binding mechanisms: Probing the binding pathway of dasatinib to Src-kinase

Aryapour

2021

Preprint

Self Cite

Retroviruses are a growing concern for the health of human beings, and one of the dangerous members of this family is the Human T-cell Leukemia Virus 1 (HTLV-1) virus. It has affected more than 20 million people so far, and since there are no registered treatments against it yet, urgent treatment solutions are needed. One of the most promising drug targets to fight this virus is the protease enzyme of the virus's protein machinery. In this study, by utilizing a computational method called Unaggregated Unbiased Molecular Dynamics (UUMD), we reconstructed the binding pathway of a HTLV-1 protease inhibitor, Indinavir, to find the details of the binding pathway, the influential residues, and also the stable states of the binding pathway. We achieved the native conformation of the inhibitor in 6 rounds, 360 replicas by performing over 4 micro-seconds of UMD simulations. We found 3 Intermediate states between the solvated state and the native conformation state in the binding pathway. We also discovered that aromatic residues such as Trp98 and Trp98′, catalytic residues Asp32 and Asp32′, and the flap region's residues have the most influential roles in the binding pathway and also have the most contribution to the total interaction energies. We believe that the details found in this study would be a great guide for developing new treatment solutions against the HTLV-1 virus by inhibiting the HTLV-1 protease.

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Reconstruction of the binding pathway of an anti-HIV drug, Indinavir, in complex with the HTLV-1 protease by Unaggregated Unbiased Molecular Dynamics simulation

Aryapour

2021

Preprint

Self Cite

Complete reconstruction of the unbinding pathway of an anticancer drug by conventional unbiased molecular dynamics simulation

Moghadam

Aliyar

et al. 2020

Preprint

Self Cite

11Understanding the details of unbinding mechanism of small molecule drugs is an 12 inseparable part of rational drug design. Reconstruction of the unbinding pathway of small 13 molecule drugs, todays, can be achieved through molecular dynamics simulations. Nonetheless, 14 simulating a process in which a drug unbinds from its receptor demands lots of time, mostly up 15 to several milliseconds. This amount of time is neither reasonable nor affordable; therefore, 16 many researchers utilize various biases that there are still many doubts about their 17 trustworthiness. In this work we have utilized short-run simulations, replicas, to make such time-18 consuming process cost effective. By replicating those snapshots of the trajectories which, after 19 careful analyses, were selected as potential candidates we increased our system's efficiency 20 considerably. As a matter of fact, we have implemented a sort of human bias, inspecting 21 trajectories visually, to achieve multiple unbinding events. We would like to call this stratagem, 22 replicating of potent snapshots, "rational sampling" as it is, in fact, benefiting from human logic. 23In our case, an anticancer drug, the dasatinib, completely unbounded from its target protein, c-24 Src kinase, in only 392.6 ns, and this was gained without applying any internal biases and 25 potentials which can increase error level. Thus, we achieved important structural details that can 26 alter our viewpoint as well as assist drug designers. 27 2

Comparative analysis of the unbinding pathways of antiviral drug Indinavir from HIV and HTLV1 proteases by Supervised Molecular Dynamics simulation

Aryapour

2021

Preprint

Self Cite

Determining the unbinding pathways of potential small molecule compounds from their target proteins is of great significance for designing efficacious treatment solutions. One of these potential compounds is the approved HIV-1 protease inhibitor, indinavir, which has a weak effect on the HTLV-1 protease. In this work, by employing SuMD method, we reconstructed the unbinding pathways of indinavir from HIV and HTLV-1 proteases in order to compare and to understand the mechanism of the unbinding, and also to discover the reasons for the lack of inhibitory activity of indinavir against the HTLV-1 protease. We achieved multiple unbinding events from both HIV and HTLV-1 proteases in which the RMSD values of indinavir reached over 4 nm. Also, we found that the mobility and the fluctuations of the flap region is higher in the HTLV-1 protease which makes the drug less stable. We realized that critically positioned aromatic residues such as Trp98/Trp98' and Phe67/Phe67' in the HTLV-1 protease can make strong pi-Stacking interactions with indinavir in the unbinding pathway which are unfavorable for the stability of indinavir in the active site. The details found in this study can make a good explanation for the lack of inhibitory activity of this drug against HTLV-1 protease. We believe the details discovered in this work can be a great assist for designing more effective and more selective inhibitors for the HTLV-1 protease.