Sequence divergence analysis for the prediction of seven-helix membrane protein structures: I. Comparison with bacteriorhodopsin

A method using protein sequence divergence to predict the three-dimensionalstructure of the transmembrane domain of seven-helix membraneproteins is described. The key component in the multistep procedureis the calculation of a hydrophilic and lipophilic variabilityindex for each amino acid in an alignment of a family of homologousproteins. The variability profile, a plot of the calculatedvariability index versus alignment position, can be used topredict a tertiary model of the backbone conformation of thetransmembrane domain. This method was applied to bacteriorhodopsin(BR) and the model obtained was compared with the known structureof this protein. Using an alignment of the amino acid sequencesof BR and closely related (20% identity) proteins, the boundariesof the transmembrane regions, their secondary structures andorientations inside the membrane bilayer were predicted basedon the variability profile. Additional information about theshape of the helix bundle was also obtained from the averagevariability of each transmembrane helix with the assumptionthat the helices are packed sequentially and form a closed helixbundle. Correct features of the known structure of BR were foundin the model structure, suggesting that a similar strategy canbe used to predict transmembrane helices and the packing shapeof other membrane proteins with seven transmembrane helices,such as the opsins and other G-protein coupled receptors.