Five mutations of rhodopsin have been produced, each of which contains a unique cysteine residue at positions 62, 65, 140, 240, or 316 in the cytoplasmic domain. The single reactive cysteines were derivatized with a sulfhydryl-specific nitroxide spin-label, and the electron paramagnetic resonance (EPR) spectra were analyzed in both lauryl maltoside and digitonin in the dark and after photobleaching. The collision rate of the attached nitroxides with polar and nonpolar paramagnetic agents indicated that they were all exposed to the aqueous environment. Photobleaching of the mutants in digitonin, which arrests the protein at the meta I intermediate, produced little change in mobility of the attached nitroxide. On the other hand, photobleaching in lauryl maltoside produced the meta II intermediate and significant changes in the EPR spectra of the nitroxides attached to positions 140 and 316. These data directly reveal a light-induced conformational change in the cytoplasmic loops that accompanies meta II formation.
Structure-function studies of rhodopsin indicate that both intradiscal and transmembrane (TM) domains are required for retinal binding and subsequent light-induced structural changes in the cytoplasmic domain. Further, a hypothesis involving a common mechanism for activation of G-protein-coupled receptor (GPCR) has been proposed. To test this hypothesis, chimeric receptors were required in which the cytoplasmic domains of rhodopsin were replaced with those of the beta(2)-adrenergic receptor (beta(2)-AR). Their preparation required identification of the boundaries between the TM domain of rhodopsin and the cytoplasmic domain of the beta(2)-AR necessary for formation of the rhodopsin chromophore and its activation by light and subsequent optimal activation of beta(2)-AR signaling. Chimeric receptors were constructed in which the cytoplasmic loops of rhodopsin were replaced one at a time and in combination. In these replacements, size of the third cytoplasmic (EF) loop critically determined the extent of chromophore formation, its stability, and subsequent signal transduction specificity. All the EF loop replacements showed significant decreases in transducin activation, while only minor effects were observed by replacements of the CD and AB loops. Light-dependent activation of beta(2)-AR leading to Galphas signaling was observed only for the EF2 chimera, and its activation was further enhanced by replacements of the other loops. The results demonstrate coupling between light-induced conformational changes occurring in the transmembrane domain of rhodopsin and the cytoplasmic domain of the beta(2)-AR.
FTIR-difference spectroscopy in combination with site-directed mutagenesis has been used to investigate the role of water during the photocycle of bacteriorhodopsin. At least one water molecule is detected which undergoes an increase in H-bonding during the primary bR-->K phototransition. Bands due to water appear in the OH stretch region of the bR-->K FTIR-difference spectrum which downshift by approximately 12 cm-1 when the sample is hydrated with H2(18)O. In contrast to 2H2O, the H2(18)O-induced shift is not complete, even after 24 h of hydration. This indicates that even though water is still able to exchange protons with the outside medium, it is partially trapped in the interior of the protein. In the mutant Y57D, these bands are absent while a new set of bands appear at much lower frequencies which undergo H2(18)O-induced shifts. It is concluded that the water molecule we detect is located inside the bR active-site and may interact with Tyr-57. The change in its hydrogen-bonding strength is most likely due to the photoinduced all-trans-->13-cis isomerization of the retinal chromophore and the associated movement of the positively charged Schiff base during the bR-->K transition. In contrast, a second water molecule, whose infrared difference bands are not affected by the Y57D mutation, appears to undergo a decrease in hydrogen bonding during the K-->L and L-->M transitions.
Sixteen single-cysteine substitution mutants of rhodopsin were prepared in the sequence 306-321 which begins in transmembrane helix VII and ends at the palmitoylation sites at 322C and 323C. The substituted cysteine residues were modified with a selective reagent to generate a nitroxide side chain, and the electron paramagnetic resonance spectrum of each spin-labeled mutant was analyzed in terms of residue accessibility and mobility. The periodic behavior of these parameters along the sequence indicated that residues 306-314 were in a regular alpha-helical conformation representing the end of helix VII. This helix apparently extends about 1.5 turns above the surface of the membrane, with one face in strong tertiary interaction with the core of the protein. For the segment 315-321, substituted cysteine residues at 317, 318, 320, and 321 had low reactivity with the spin-label reagent. This segment has the most extensive tertiary interactions yet observed in the rhodopsin extra-membrane sequences at the cytoplasmic surface. Previous studies showed the spontaneous formation of a disulfide bond between cysteine residues at 65 and 316. This result indicates that at least some of the tertiary contacts made in the 315-321 segment are with the sequence connecting transmembrane helices I and II. Photoactivation of rhodopsin produces changes in structure detected by spin labels at 306, 313, and 316. The changes at 313 can be accounted for by movements in the adjacent helix VI.
The cytoplasmic interhelical E-F loop in rhodopsin is a part of the region that interacts with the G-protein transducin and rhodopsin kinase during signal transduction. In extending the previous work on systematic single cysteine substitutions of the amino acids in the cytoplasmic C-D loop, we have now replaced, one at a time, the amino acids Q225-I256 in the E-F loop region by cysteines. All the mutants formed the characteristic rhodopsin chromophore with 11-cis-retinal. While most of the mutants bleached normally, L226C, showed abnormal bleaching behavior. A study of the alkylation of the mutants by N-ethylmaleimide in dark showed low reactivity by some mutants, especially L226C. The rates of transducin activation (GT(alpha)-GTP gamma S complex formation) were measured for all the mutants. While these were normal for the bulk of the mutants, some (L226C, T229C, V230C, A233C, A234C, T242C, T243C, and Q244C) showed strikingly reduced transducin activation. The results suggest a specific structure in the E-F loop that interacts with transducin.
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