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Allosteric drugs: thinking outside the active-site box

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Presentation on theme: "Allosteric drugs: thinking outside the active-site box"— Presentation transcript:

1 Allosteric drugs: thinking outside the active-site box
Brian S DeDecker  Chemistry & Biology  Volume 7, Issue 5, Pages R103-R107 (May 2000) DOI: /S (00)

2 Figure 1 Stereochemical basis of trp repressor activation. Trp repressor in an inactive DNA binding state on the left and an active conformation bound to DNA and tryptophan to the right. Tryptophan (blue) binds to and stabilizes the DNA-binding conformation of the trp repressor; with both helix–turn–helix motifs (red) spread apart and aligned properly for interaction with the DNA major groove. Adapted from Zhang et al. [1]. Chemistry & Biology 2000 7, R103-R107DOI: ( /S (00) )

3 Figure 2 Selection strategy for p53 stabilizers used by Foster et al. [10]. (a) The wild-type p53 core domain loses the mAb 1620 epitope and gains mAb 240 reactivity upon heat denaturation. (b) Immobilized p53 core domain has no remaining mAb 1620 reactivity after 30 min at 45°C. Addition of compounds CP or CP stabilize the p53 fold, preserving mAb 1620 reactivity under the heat-denaturing conditions in a concentration-dependent fashion. (c) The two compounds that were selected to stabilize wild-type core domain also stabilize various p53 point mutants. The stability of various p53 mutants ia compared between the proteins alone (red) and in the presence of compound (blue) incubated at 37°C for 30 min. (d) Structures of two active compounds (CP and CP ): both show a polycyclic moiety attached to an amine. Chemistry & Biology 2000 7, R103-R107DOI: ( /S (00) )

4 Figure 3 Ribbon diagram of the p53 core domain bound to a DNA half site [4,21]. Sites of representative mutations are shown: Arg273→His primarily reduces affinity for DNA, Val143→Ala mainly decreases the stability of protein folding, and Arg249→Ser affects both equilibria. Chemistry & Biology 2000 7, R103-R107DOI: ( /S (00) )

5 Figure 4 (a) The iNOS active homodimer complex with the active site and part of the dimer interface of one NOS molecule (green) shown bound to the dimer interface of the other (blue). (b) The compound binds the arginine-binding site (near the heme) and displaces helix 7a, causing the region from the beginning of helix 7a to the middle half of helix 8 to be disordered (inferred by lack of electron density) and possibly disrupts the dimer interface by an allosteric mechanism. Helix 9 also shifts in position between the two structures. Adapted from McMillan et al. [18]. Chemistry & Biology 2000 7, R103-R107DOI: ( /S (00) )

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