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- Enoyl-acyl-carrier-protein-Reductase <Enoyl-[acyl-carrier-protein]-Reductase> (1) (entfernen)
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The high infection rates and recent emergence of extremely drug resistant forms of
Mycobacterium tuberculosis pose a significant challenge for global health. The NADH-
dependent enoyl-ACP-reductase InhA of the type II mycobacterial fatty acid biosynthesis
pathway is a well-validated target for inhibiting mycobacterial growth. InhA has been
shown to be inhibited by a variety of compound series. Prominent classes of InhA
inhibitors from literature include diaryl ethers, pyrrolidine carboxamides and arylamides
which can be subjected to further development. Despite the progress in this area, very
few compounds are in clinical development phase. The present work involves a detailed
computational investigation of the binding modes and structure-based optimisation of
pyrrolidine carboxamides as InhA inhibitors.
With substituents of widely varying bulkiness, the pyrrolidine carboxamide dataset
presented a challenge for prediction of binding mode as well as affinity. Using advanced
docking protocols and in-house developed pose selection procedures, the binding modes
of 44 compounds were predicted. The poses from docking were used in short molecular
dynamics (MD) simulations to ascertain the dominant binding conformations for the
bulkier members of the series. Subsequently, an activity-based classification strategy
could be developed to circumvent the affinity prediction problems observed with this
dataset. The prominent motions of the bound ligand and the active site residues were
then ascertained using Essential Dynamics (ED). The information from ED and literature
was subsequently used to design a total of 20 compounds that were subjected to extensive
in-silico evaluations. Finally, the molecular determinants of rapid-reversible binding of
pyrrolidine carboxamides were investigated using long MD simulations.