optimization of carbocyclic analogues to a specific pharmaceutical enzyme target via discovery...

Optimization of Carbocyclic Analogues to a Specific Pharmaceutical Enzyme Target via Discovery Studio TM Douglas Harris Department of Chemistry and Biochemistry, Utah State University, 0300 Old Main Hill, Logan, UT 83422-0300, USA [email protected] Abstract: The following teaching organic chemistry and biochemistry laboratory experiments introduce students to principles of structure-based drug design and the important role that molecular modeling plays in optimizing drug leads. The discovery and development of the potent influenza antivirals oseltamivir (Tamiflu), Tamiphosphor, and Peramivir are highlighted. The user-friendly graphical interface of the Discovery Studio molecular modeling software provides an excellent environment for introducing students to the techniques of molecular minimization and calculation of relative enzyme/inhibitor interaction energies. A strong correlation between the experimentally determined inhibition constant values of various carbocyclic analogues and calculated relative interaction energies is obtained. References [1] Mayo S, Olafson B, Goddard W, J. of Phys. Chem. 94, 8897 – 8909 (1990) [2] Russell et al., Nature 443, 45-49 (2006) [3] Lew et al., Curr. Med.. Chem. 7, 663 – 672 (2000) [4] Shie J J et al., JACS 129, 11892-11893 (2007) [5] Cheng TJ et al., J. Med. Chem. 55, 8657-8670 (2012) [6] Nair et al., J. Mol. Graph. Modelling 21, 171-179 (2002) Figure 3 Left – Compound 17 [3] minimized within the active site of influenza neuraminidase type 1. Right – Compound 13b [4] minimized within the active site of influenza neuramindase type 1. Presented Topics: Molecular mechanics Force field E = E B + E A + E T + E I + E VDW + E Q + E HB (Dreiding) [1] Energy Minimizations Local potential energy minimum and global minimum ation of Relative Interaction Energies of Inhibitors to a Receptor Enzyme tion Energy E i = E[Enz:I] - E[I] - E[Enz] e Interaction Energy E i = E i,analogue – E i,reference ation of Relative Interaction Energies of Various Carbocyclic Inhibitor Analogues to idase of Influenza Virus and Drug Lead Optimization nidase subtype 1/oseltamivir carboxylate complex crystal structure 2HU4.pdb [2] Sciences Structure activity relationship [3] a Sinica Tamiphosphor development [4 and 5] nce of Correlation Between Experimental and Theoretical Results Similar established method [6] Compound Ki (nM) [4] E i (kcal/mole) Oseltamivir carboxylate (OC) 2.90 0 13a (Guanidine-OC) 2.02 -2.23 Tamiphosphor 0.15 -3.39 13b 0.06 -5.16 Combined 13b and 17 -7.78 Drug lead optimization -8.40 Figure 2 “Reduced” oseltamivir carboxylate/neuraminidase active site. The active site system includes the inhibitor (pink) and all atoms (light blue) of the neuraminidase structure within 8 angstroms of the inhibito remaining atoms (element colors) are within 16 angstroms of the inhibitor. Figure 1 Left - Minimized water system depicting optimized hydrogen bonds. Middle – Local cyclohexane minimized structure – 34 kcal/mole. Right – Global cyclohexane minimized structure – 11 kcal/mole.

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Optimization of Carbocyclic Analogues to a Specific Pharmaceutical Enzyme Target via Discovery StudioTM

Douglas HarrisDepartment of Chemistry and Biochemistry, Utah State University, 0300 Old Main Hill, Logan, UT 83422-0300, USA

[email protected]

Abstract:The following teaching organic chemistry and biochemistry laboratory experiments introduce students to principles of structure-based drug design and the important role that molecular modeling plays in optimizing drug leads. The discovery and development of the potent influenza antivirals oseltamivir (Tamiflu), Tamiphosphor, and Peramivir are highlighted. The user-friendly graphical interface of the Discovery Studio molecular modeling software provides an excellent environment for introducing students to the techniques of molecular minimization and calculation of relative enzyme/inhibitor interaction energies. A strong correlation between the experimentally determined inhibition constant values of various carbocyclic analogues and calculated relative interaction energies is obtained.

References[1] Mayo S, Olafson B, Goddard W, J. of Phys. Chem. 94, 8897 – 8909 (1990)[2] Russell et al., Nature 443, 45-49 (2006)[3] Lew et al., Curr. Med.. Chem. 7, 663 – 672 (2000)

[4] Shie J J et al., JACS 129, 11892-11893 (2007)[5] Cheng TJ et al., J. Med. Chem. 55, 8657-8670 (2012)[6] Nair et al., J. Mol. Graph. Modelling 21, 171-179 (2002)

Figure 3 Left – Compound 17 [3] minimized within the active site of influenza neuraminidase type 1. Right – Compound 13b [4] minimized within the active site of influenza neuramindase type 1.

Presented Topics:Molecular mechanicsForce field

E = EB + EA + ET + EI + EVDW + EQ + EHB (Dreiding) [1] Energy Minimizations

Local potential energy minimum and global minimum

Determination of Relative Interaction Energies of Inhibitors to a Receptor EnzymeInteraction Energy

Ei = E[Enz:I] - E[I] - E[Enz] Relative Interaction Energy

Ei = Ei,analogue – Ei,reference

Determination of Relative Interaction Energies of Various Carbocyclic Inhibitor Analogues to Neuraminidase of Influenza Virus and Drug Lead OptimizationNeuraminidase subtype 1/oseltamivir carboxylate complex crystal structure

2HU4.pdb [2]Gilead Sciences

Structure activity relationship [3]Academia Sinica

Tamiphosphor development [4 and 5]Importance of Correlation Between Experimental and Theoretical Results

Similar established method [6]

Compound Ki (nM) [4] Ei (kcal/mole)

Oseltamivir carboxylate (OC) 2.90 0

13a (Guanidine-OC) 2.02 -2.23

Tamiphosphor 0.15 -3.39

13b 0.06 -5.16

Combined 13b and 17 -7.78

Drug lead optimization -8.40

Figure 2 “Reduced” oseltamivir carboxylate/neuraminidase active site. The active site system includes the inhibitor (pink) and all atoms (light blue) of the neuraminidase structure within 8 angstroms of the inhibitor. The remaining atoms (element colors) are within 16 angstroms of the inhibitor.

Figure 1 Left - Minimized water system depicting optimized hydrogen bonds. Middle – Local cyclohexane minimized structure – 34 kcal/mole. Right – Global cyclohexane minimized structure – 11 kcal/mole.

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