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Influence of the g- conformation of Ser and Thr on the structure of transmembrane helices.

In order to study the influence of Ser and Thr on the structure of transmembrane helices we have analyzed a database of helix stretches extracted from crystal structures of membrane proteins and an ensemble of model helices generated by molecular dynamics simulations. Both complementary analyses show that Ser and Thr in the g- conformation induce and/or stabilize a structural distortion in the helix backbone. Using quantum mechanical calculations, we have attributed this effect to the electrostatic repulsion between the side chain Ogamma atom of Ser and Thr and the backbone carbonyl oxygen at position i-3. In order to minimize the repulsive force between these negatively charged oxygens, there is a modest increase of the helix bend angle as well as a local opening of the helix turn preceding Ser/Thr. This small distortion can be amplified through the helix, resulting in a significant displacement of the residues located at the other side of the helix. The crystal structures of aquaporin Z and the beta(2)-adrenergic receptor are used to illustrate these effects. Ser/Thr-induced structural distortions can be implicated in processes as diverse as ligand recognition, protein function and protein folding.

Activation of the mu opioid receptor involves conformational rearrangements of multiple transmembrane domains.

We previously demonstrated that D3.49(164)Y or T6.34(279)K mutation in the rat mu opioid receptor (MOPR) resulted in agonist-independent activation. Here, we identified the cysteine(s) within the transmembrane domains (TMs) of the D3.49(164)Y mutant that became accessible in the binding-site crevice by use of methanethiosulfonate ethylammonium (MTSEA) and inferred conformational changes associated with receptor activation. While the C7.38(321)S mutant was insensitive to MTSEA, the D3.49(164)Y/C7.38(321)S mutant showed similar sensitivity as the D3.49(164)Y, suggesting that, in the D3.49(164)Y mutant, C7.38(321) becomes inaccessible while other cysteines are accessible in the binding-site crevice. Each of the other seven cysteines in the TMs was mutated to serine on the background of D3.49(164)Y/C7.38(321)S, and the resulting triple mutants were evaluated for [3H]diprenorphine and [d-Ala2,NMe-Phe4,Gly5-ol]-enkephalin (DAMGO) binding and effect of MTSEA on [3H]diprenorphine binding. The D3.49(164)Y/C7.38(321)S mutant and the triple mutants, except the C6.47(292)S triple mutant, retained similar affinities for [3H]diprenorphine and DAMGO as the D3.49(164)Y mutant. The second-order rate constants for MTSEA reactions showed that C3.44(159)S, C4.48(190)S, C5.41(235)S, and C7.47(330)S significantly reduced sensitivity to MTSEA, compared with the D3.49(164)Y/C7.38(321)S. These results suggest that the four cysteines may be rotated and/or tilted to become accessible. While the D3.49(164)Y/C7.38(321)S was similarly sensitive to MTSEA as the D3.49(164)Y mutant, the T6.34(279)K/C7.38(321)S was much less sensitive to MTSEA than the T6.34(279)K mutant, suggesting that the two constitutively active mutants assume different conformations and/or possess different dynamic properties. Molecular models of the MOPR monomer and homodimer, using the crystal structures of rhodopsin, the beta2-adrenergic receptor, and the ligand-free opsin, which contains several features characteristic of the active state, were employed to analyze these experimental results in a structural context.

A three-dimensional pharmacophore model for 5-hydroxytryptamine6 (5-HT6) receptor antagonists.

Forty-five structurally diverse 5-hydroxytryptamine(6) receptor (5-HT(6)R) antagonists were selected to develop a 3D pharmacophore model with the Catalyst software. The structural features for antagonism at this receptor are a positive ionizable atom interacting with Asp(3.32), a hydrogen bond acceptor group interacting with Ser(5.43) and Asn(6.55), a hydrophobic site interacting with residues in a hydrophobic pocket between transmembranes 3, 4, and 5, and an aromatic-ring hydrophobic site interacting with Phe(6.52).