Improved Secondary Structure Predictions for a Nicotinic Receptor Subunit: Incorporation of Solvent Accessibility and Experimental Data into a Two-Dimensional Representation

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Improved Secondary Structure Predictions for a Nicotinic Receptor Subunit: Incorporation of Solvent Accessibility and Experimental Data into a Two-Dimensional Representation

Nicolas Le Novère, Pierre-Jean Corringer, and Jean-Pierre Changeux

Centre National de la Recherche Scientifique URA D1284 Neurobiologie Moléculaire, Institut Pasteur, 75015 Paris, France

Abstract A refined prediction of the nicotinic acetylcholine receptor (nAChR) subunits' secondary structure was computed withthird-generation algorithms. The four selected programs, PHD,Predator, DSC, and NNSSP, based on different prediction approaches,were applied to each sequence of an alignment of nAChR and 5-HT₃receptor subunits, as well as a larger alignment with relatedsubunit sequences from glycine and GABA receptors. A consensusprediction was computed for the nAChR subunits through a "winnertakes all" method. By integrating the probabilities obtained withPHD, DSC, and NNSSP, this prediction was filtered in order toeliminate the singletons and to more precisely establish the structurelimits (only 4% of the residues were modified). The final consensussecondary structure includes nine $alpha$ -helices (24.2% of the residues,with an average length of 13.9 residues) and 17 $beta$ -strands (22.5%of the residues, with an average length of 6.6 residues). Thelarge extracellular domain is predicted to be mainly composedof $beta$ -strands, with only two helices at the amino-terminal end.The transmembrane segments are predicted to be in a mixed $alpha$ / $beta$ topology (with a predominance of $alpha$ -helices), with no known equivalentin the current protein database. The cytoplasmic domain is predictedto consist of two well-conserved amphipathic helices joined togetherby an unfolded stretch of variable length and sequence. In general,the segments predicted to occur in a periodic structure correspondto the more conserved regions, as defined by an analysis of sequenceconservation per position performed on 152 superfamily members.The solvent accessibility of each residue was predicted from themultiple alignments with PHDacc. Each segment with more than threeexposed residues was assumed to be external to the core protein.Overall, these data constitute an envelope of structural constraints.In a subsequent step, experimental data relative to the extracellularportion of the complete receptor were incorporated into the model.This led to a proposed two-dimensional representation of the secondarystructure in which the peptide chain of the extracellular domainwinds alternatively between the two interfaces of the subunit.Although this representation is not a tertiary structure and doesnot lead to predictions of specific $beta$ - $beta$ interaction, it shouldprovide a basic framework for further mutagenesis investigationsand for fold recognition (threading)searches.

Biophys J, May 1999, p. 2329-2345, Vol. 76, No. 5
© 1999 by the Biophysical Society 0006-3495/99/05/2329/17 $2.00

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