The active site of bacteriorhodopsin. Two‐photon spectroscopic evidence for a positively charged chromophore binding site mediated by calcium

Stuart, Jeffrey A.; Vought, Bryan W.; Zhang, Chian‐Fan; Birge, Robert R.

doi:10.1002/bspy.350010104

Cited by 40 publications

(96 citation statements)

References 81 publications

(25 reference statements)

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“…The PSB group is now close to Glu-181 to establish the electrostatic interaction (green dashed line) with the new counterion. In the Meta intermediates, it is possible that the counterion environment about Glu-181 is complex as has been observed and discussed in the case of bacteriorhodopsin (30,31).…”

Section: Discussionmentioning

confidence: 96%

“…In addition to the known anion effects (29), these interactions could be a determining factor controlling the deprotonation of the SB in native Meta II. This suggests that, as indicated by the structure, Glu-181 and Glu-113 are not interacting independently with the chromophore in the later intermediates such that the possibility of a complex counterion as observed in bacteriorhodopsin must be considered (30,31).…”

Section: Discussionmentioning

confidence: 99%

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Retinal counterion switch in the photoactivation of the G protein-coupled receptor rhodopsin

Yan

Kazmi²,

Ganim³

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

205

279

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The biological function of Glu-181 in the photoactivation process of rhodopsin is explored through spectroscopic studies of site-specific mutants. Preresonance Raman vibrational spectra of the unphotolyzed E181Q mutant are nearly identical to spectra of the native pigment, supporting the view that Glu-181 is uncharged (protonated) in the dark state. The pH dependence of the absorption of the metarhodopsin I (Meta I)-like photoproduct of E181Q is investigated, revealing a dramatic shift of its Schiff base pKa compared with the native pigment. This result is most consistent with the assignment of Glu-181 as the primary counterion of the retinylidene protonated Schiff base in the Meta I state, implying that there is a counterion switch from Glu-113 in the dark state to Glu-181 in Meta I. We propose a model where the counterion switch occurs by transferring a proton from Glu-181 to Glu-113 through an H-bond network formed primarily with residues on extracellular loop II (EII). The resulting reorganization of EII is then coupled to movements of helix III through a conserved disulfide bond (Cys110 -Cys187); this process may be a general element of G proteincoupled receptor activation.

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Section: Discussionmentioning

confidence: 96%

Section: Discussionmentioning

confidence: 99%

Retinal counterion switch in the photoactivation of the G protein-coupled receptor rhodopsin

Yan

Kazmi²,

Ganim³

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

205

279

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“…A number of spectroscopic (26,27) and potentiometric titration (21,22) studies of bR and some of its mutants lead to the conclusion that Ca 2ϩ binds to amino acid residues not far from the retinal. Furthermore, Ca 2ϩ in the second highaffinity site (7,8,22) is responsible for the color change in regenerated bR.…”

Section: Discussionmentioning

confidence: 99%

“…This suggests the presence of Ca 2ϩ near D85, which is the active site of bR. Most recently, Stuart et al (27) could calculate the two photon spectrum of the retinal in bR only if the Ca 2ϩ is placed near D85 and D212 within the active site.…”

mentioning

confidence: 99%

Detection of a Yb ³⁺ binding site in regenerated bacteriorhodopsin that is coordinated with the protein and phospholipid head groups

Roselli¹,

Boussac²,

Mattioli³

et al. 1996

Proc. Natl. Acad. Sci. U.S.A.

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Near infrared Yb 3؉ vibronic sideband spectroscopy was used to characterize specific lanthanide binding sites in bacteriorhodopsin (bR) and retinal free bacteriorhodopsin (bO). The VSB spectra for deionized bO regenerated with a ratio of 1:1 and 2:1 ion to bO are identical. Application of a two-dimensional anti-correlation technique suggests that only a single Yb 3؉ site is observed. The Yb 3؉ binding site in bO is observed to consist of PO 2 ؊ groups and carboxylic acid groups, both of which are bound in a bidentate manner. An additional contribution most likely arising from a phenolic group is also observed. This implies that the ligands for the observed single binding site are the lipid head groups and amino acid residues. The vibronic sidebands of Yb 3؉ in deionized bR regenerated at a ratio of 2:1 ion to bR are essentially identical to those in bO. The other high-affinity binding site is thus either not evident or its f luorescence is quenched. A discussion is given on the difference in binding of Ca 2؉ (or Mg 2؉ ) and lanthanides in phospholipid membrane proteins.Bacteriorhodopsin (bR) is the only protein in the purple membrane of the halophilic archaebacterium Halobacterium salinarium. This protein is capable of light-driven transmembrane-proton translocation during a specific photochemical cycle (1-3) involving a retinal chromophore in a protonated Schiff base linkage with the lysine residue Lys-216 (4-6).The binding of metal cations, specifically Ca 2ϩ and Mg 2ϩ , is now recognized as essential for the proper functioning of the proton pumping mechanism of bR (7,8). Removal of the cations by deionization or acidification shifts the absorption maximum of purple membrane to 604 nm (blue bR) (9, 10). The absorption maximum of native bR (560-570 nm) returns upon the addition of different metal cations (9, 10). The initial step in the bR photocycle involves the excitation of the retinal by absorption of a photon (11-15). This step is followed by isomerization of the initially all-trans retinal to form the 13-cis retinal (11-15). Thermal relaxation leads to several intermediates, the net result being translocation of a proton from the cytoplasmic to the extracellular side of the membrane. Eventually, bR returns to its ground state from which it can undergo another photocycle (11-15). While retinal photoisomerization takes place in blue bR, the M 412 intermediate is not formed and, thus, proton pumping does not occur (9, 10).The locations of the cation binding sites are still not well known. Stroud and colleagues (16,17) have observed several Pb 2ϩ binding sites in bR via x-ray diffraction. The ligands that bind the cations cannot be identified from such studies due to the present inability to form three-dimensional crystals of bR. To understand the role that these metal cations play in the function of bR, it is necessary to know the location of the cations in the protein and the chemical nature of the ligands that bind them. For Ca 2ϩ binding proteins, such as bR, the latter is difficult to probe becau...

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“…Some authors claim a nonspecific location of the cations in the double layer (18,21,22) or in the lipid phase (26). However, the majority of works argue for the existence of specific binding sites in the purple membrane, including a site near Asp 85 (24,27,28), or a more external location (29,30). Among the most outstanding results pointing toward specific cation locations in the protein moiety are: (i) the evidence for carboxyl participation in cation binding from studies using specific reagents (13,17); (ii) the presence of fewer cation-binding sites and with lower affinity in the bleached and pink membranes as compared with purple membranes (14,16,19), even that the electric surface potential of bleached membrane remains unchanged (31); (iii) extended x-ray absorption fine structure data describing a different environment for the bound Mn 2ϩ with respect to free Mn 2ϩ in water and ruling out the interaction of Mn 2ϩ with P or S atoms (32); (iv) Fourier transform infrared studies showing that binding of Mn 2ϩ to deionized membrane induces changes in the reverse turns, located in the loops (33); and (v) 13 C NMR studies detecting changes in the Ala 196 environment upon divalent cation binding (25).…”

mentioning

confidence: 99%

Contribution of Extracellular Glu Residues to the Structure and Function of Bacteriorhodopsin

Sanz

Márquez

Perálvarez

et al. 2001

Journal of Biological Chemistry

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The active site of bacteriorhodopsin. Two‐photon spectroscopic evidence for a positively charged chromophore binding site mediated by calcium

Cited by 40 publications

References 81 publications

Retinal counterion switch in the photoactivation of the G protein-coupled receptor rhodopsin

Retinal counterion switch in the photoactivation of the G protein-coupled receptor rhodopsin

Detection of a Yb ³⁺ binding site in regenerated bacteriorhodopsin that is coordinated with the protein and phospholipid head groups

Contribution of Extracellular Glu Residues to the Structure and Function of Bacteriorhodopsin

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The active site of bacteriorhodopsin. Two‐photon spectroscopic evidence for a positively charged chromophore binding site mediated by calcium

Cited by 40 publications

References 81 publications

Retinal counterion switch in the photoactivation of the G protein-coupled receptor rhodopsin

Retinal counterion switch in the photoactivation of the G protein-coupled receptor rhodopsin

Detection of a Yb 3+ binding site in regenerated bacteriorhodopsin that is coordinated with the protein and phospholipid head groups

Contribution of Extracellular Glu Residues to the Structure and Function of Bacteriorhodopsin

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Detection of a Yb ³⁺ binding site in regenerated bacteriorhodopsin that is coordinated with the protein and phospholipid head groups