The 3-dimensional quantitative structure-activity relationship (3D-QSAR) molecular modeling technique or comparative molecular field analysis (CoMFA) has been used to design analogs of the natural product cryptolepine (1). Twenty-three compounds with their in vitro biological activities (IC50 values) against Crytococcus neoformans were used to generate the training set database of compounds for the CoMFA studies. The cross-validated q(2), noncross-validated r(2), and partial least squares (PLS) analysis results were used to predict the biological activity of 11 newly designed test set compounds. The best CoMFA model produced a q(2) of 0.815 and an r(2) of 0.976 indicating high statistical significance as a predictive model. The steric and electrostatic contributions from the contour map were interpreted from the color-coded contour plots generated from the PLS model and the active structural components for potency against C. neoformans were determined and validated in the test set compounds. The 3-substituted benzylthio quinolinium salts (4) that make up the test set were synthesized and evaluated based on the predicted activity from the CoMFA model and the results produced a good correlation between the predicted and experimental activity (R=0.82). Thus, CoMFA has served as an effective tool to aid the design of new analogs and in this case, it has aided the identification of compounds equipotent with amphotericin B, the gold standard in antifungal drug design.
The 3-dimensional quantitative structure-activity relationship (3D-QSAR) molecular modeling technique or comparative molecular field analysis (CoMFA) has been used to design analogs of the natural product cryptolepine (1). Twenty-three compounds with their in vitro biological activities (IC50 values) against Crytococcus n class="Species">neoformans were used to generate the training set database of compounds for the CoMFA studies. The cross-validated q(2), noncross-validated r(2), and partial least squares (PLS) analysis results were used to predict the biological activity of 11 newly designed test set compounds. The best CoMFA model produced a q(2) of 0.815 and an r(2) of 0.976 indicating high statistical significance as a predictive model. The steric and electrostatic contributions from the contour map were interpreted from the color-coded contour plots generated from the PLS model and the active structural components for potency against C. neoformans were determined and validated in the test set compounds. The 3-substituted benzylthio quinolinium salts (4) that make up the test set were synthesized and evaluated based on the predicted activity from the CoMFA model and the results produced a good correlation between the predicted and experimental activity (R=0.82). Thus, CoMFA has served as an effective tool to aid the design of new analogs and in this case, it has aided the identification of compounds equipotent with amphotericin B, the gold standard in antifungal drug design.
Authors: Comfort A Boateng; Suresh V K Eyunni; Xue Y Zhu; Jagan R Etukala; Barbara A Bricker; M K Ashfaq; Melissa R Jacob; Shabana I Khan; Larry A Walker; Seth Y Ablordeppey Journal: Bioorg Med Chem Date: 2010-11-10 Impact factor: 3.641
Authors: Leroy G Mardenborough; Xue Y Zhu; Pincheng Fan; Melissa R Jacob; Shabana I Khan; Larry A Walker; Seth Y Ablordeppey Journal: Bioorg Med Chem Date: 2005-06-02 Impact factor: 3.641
Authors: Volodymyr Samoylenko; Melissa R Jacob; Shabana I Khan; Jianping Zhao; Babu L Tekwani; Jacob O Midiwo; Larry A Walker; Ilias Muhammad Journal: Nat Prod Commun Date: 2009-06 Impact factor: 0.986
Authors: Sidney Bolden; Xue Y Zhu; Jagan R Etukala; Comfort Boateng; Tryphon Mazu; Hernan Flores-Rozas; Melissa R Jacob; Shabana I Khan; Larry A Walker; Seth Y Ablordeppey Journal: Eur J Med Chem Date: 2013-10-05 Impact factor: 6.514