Mutation of L125R in trasmembrane helix III of rhodopsin, associated with the retinal degenerative disease retinitis pigmentosa, was previously shown to cause structural misfolding of the mutant protein. Also, conservative mutations at this position were found to cause partial misfolding of the mutant receptors. We report here on a series of mutations at position 125 to further investigate the role of Leu125 in the correct folding and function of rhodopsin. In particular, the effect of the size of the substituted amino-acid side chain in the functionality of the receptor, measured as the ability of the mutant rhodopsins to activate the G protein transducin, has been analysed. The following mutations have been studied: L125G, L125N, L125I, L125H, L125P, L125T, L125D, L125E, L125Y and L125W. Most of the mutant proteins, expressed in COS-1 cells, showed reduced 11-cis-retinal binding, red-shifts in the wavelength of the visible absorbance maximum, and increased reactivity towards hydroxylamine in the dark. Thermal stability in the dark was reduced, particularly for L125P, L125Y and L125W mutants. The ability of the mutant rhodopsins to activate the G protein transducin was significantly reduced in a size dependent manner, especially in the case of the bulkier L125Y and L125W substitutions, suggesting a steric effect of the substituted amino acid. On the basis of the present and previous results, Leu125 in transmembrane helix III of rhodopsin, in the vicinity of the b-ionone ring of 11-cis-retinal, is proposed to be an important residue in maintaining the correct structure of the chromophore binding pocket. Thus, bulky substitutions at this position may affect the structure and signallling of the receptor by altering the optimal conformation of the retinal binding pocket, rather than by direct interaction with the chromophore, as seen from the recent crystallographic structure of rhodopsin.Keywords: rhodopsin; retinitis pigmentosa; signal transduction; G-protein-coupled receptor; point mutations.Rhodopsin, the photoreceptor molecule of the vertebrate retina, belongs to the G-protein-coupled receptor (GPCR) superfamily, whose structural distinctive feature is the basic heptahelical transmembrane motif [1 -3]. The proposal made several years ago that rhodopsin would be a good example for an emerging pattern of structure/function relationships [4], has turned out to be remarkably accurate from the experimental data so far obtained. The protein consists of a single polypeptide chain of < 40 kDa, the opsin apoprotein, with 11-cis-retinal chromophore covalently bound to Lys296 in the seventh transmembrane helix through a protonated Schiff-base (PSB) linkage [5 -7]. In the past decade, a number of studies on recombinant mutant rhodopsins, obtained by site-directed mutagenesis, have allowed significant structural and functional information to be obtained [8], especially for the transmembrane domain. These experimental results, in combination with molecular modelling, have allowed the proposal of structural models for the re...
