1 / 23

DE NOVO DESIGN OF A THYMIDYLATE KINASE INHIBITOR

DE NOVO DESIGN OF A THYMIDYLATE KINASE INHIBITOR. Thymidylate Synthase. Enzyme Reaction. Notes dTMP is one of the building blocks for DNA synthesis Enzyme inhibition inhibits DNA synthesis and cell division Enzyme inhibitors are potential anticancer agents

salome
Download Presentation

DE NOVO DESIGN OF A THYMIDYLATE KINASE INHIBITOR

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. DE NOVO DESIGN OF A THYMIDYLATE KINASE INHIBITOR

  2. ThymidylateSynthase EnzymeReaction • Notes • dTMP is one of the building blocks for DNA synthesis • Enzyme inhibition inhibits DNA synthesis and cell division • Enzyme inhibitors are potential anticancer agents • Inhibitors can be modelled on the substrate or cofactor

  3. 5,10-Methylenetetrahydrofolate Dihydrofolic acid ThymidylateSynthase Cofactor • Notes • Provides a 1-C unit for biosynthetic pathways • Inhibitors can be based on the cofactor structure • Difficult to gain selectivity between enzymes using the same cofactor

  4. De Novo Design • Notes • The design of a novel inhibitor based on the structure of the binding site • Crystallize target enzyme with known inhibitors • Establish structure by X-ray crystallography • Molecular modelling studies to carry out following • Identify binding site and binding regions • Design structure to fit the binding site • Incorporate functional groups to make binding interactions • Possibility of better selectivity between different targets

  5. 5-Fluorodeoxyuridylate CB 3717 De Novo Design Enzyme inhibitors • Notes • 5-Fluorodeoxyuridylate binds to the substrate binding site • CB 3717 binds to the cofactor binding site

  6. De Novo Design Binding interactions for CB 3717 • Notes • Identifies binding interactions of pteridine ring • Identifies available amino acids and bridging water molecule

  7. De Novo Design • Notes • Remove CB 3717 in silico • Set up a grid in the empty binding site • Place an aromatic CH probe at each grid point • Measure hydrophobic interactions • The binding pocket for the pteridine ring is hydrophobic • Identify a hydrophobic scaffold to fit the pocket • Scaffold must be smaller than binding pocket to allow introduction of functional groups • Add functional groups to make additional binding interactions

  8. De Novo Design • Notes • Hydrophobic naphthalene group forms van der Waals interactions with the binding site • Room for additional binding groups

  9. De Novo Design • Notes • Lactam introduced to allow additional hydrogen bond interactions with the binding site • Naphthostyryl scaffold

  10. De Novo Design • Notes • Amino substituent added to gain access to vacant region • Placed at 5-position for synthetic feasibility • Can vary N-alkyl groups without introducing an asymmetric centre

  11. De Novo Design Notes The benzyl group mimics the benzene ring of the cofactor

  12. De Novo Design • Notes • Phenylsulfonylpiperazine group is added for water solubility • Positioned to protrude from binding site • Makes contact with surrounding water • No desolvation penalty

  13. De Novo Design • Notes • De novo designed inhibitor is now synthesized and tested • Active inhibitor • Co-crystallized with enzyme • Crystal structure determined

  14. Bad interaction Shift Binding Interactions Intended Actual Water shifted • Notes • Inhibitor binds deeper into pocket than expected • Ala-263 shifted due to steric clash • Water molecule displaced to different position

  15. Structure-based Drug Design • Notes • Molecular modelling studies of actual binding interactions • Identifies 4 regions for modification • Possible analogues are overlaid with lead compound to test whether they fit the binding site • Synthesis of analogues

  16. Structure-based Drug Design • Region R1 • Substituent fits hydrophobic pocket • Pocket becomes hydrophilic with depth • Polar functional group at the end of the alkyl chain may be beneficial • CH2CH2OH has greater binding affinity • Methyl better than ethyl

  17. Structure-based Drug Design • Region R2 • Carbonyl oxygen replaced with amidine group • Capable of binding to Ala-263 instead of repelling it • More basic and protonated - allows ionic interaction and stronger hydrogen bonding interaction • Increased inhibition • Binding interactions identified from crystal structure

  18. H-Bonding Structure-based Drug Design Binding interactions Ionic and stronger H- bonding interactions • Notes • Binding interactions as expected • Ala-263 not displaced • Bridging water molecule not displaced

  19. Structure-based Drug Design • Region R3 • Small hydrophobic pocket available in the region • Methyl or chloro-substituent both beneficial for activity

  20. Structure-based Drug Design Region R4 Morpholine ring found to be beneficial for selectivity and pharmacokinetics

  21. Structure-based Drug Design • Notes • Structures are synthesized containing combinations of the optimum groups at each position • Amidine is the most important group for enhanced activity • Inclusion of all the optimum groups is not beneficial

  22. Structure-based Drug Design • Notes • Amidine, morpholine and methyl group are introduced • No change at R3 • Potent inhibitor (500 x more active) • Structure taken forward for clinical trials

  23. De Novo Design • Principles • De novo design isuseful in designing lead compounds for structure-based drug design • Designed structure should be ‘loose fitting’ and flexible • Allows possibility of different binding modes if binding does not take place as predicted • Allows scope for further modification and drug optimization • Compounds should be synthetically feasible • Compounds should be in a stable conformation • Desolvation penalties need to be considered

More Related