Vladislav B. Bergo

His-75 in Proteorhodopsin, a Novel Component in Light-driven Proton Translocation by Primary Pumps

Proteorhodopsins (PRs), photoactive retinylidene membrane proteins ubiquitous in marine eubacteria, exhibit light-driven proton transport activity similar to that of the well studied bacteriorhodopsin from halophilic archaea. However, unlike bacteriorhodopsin, PRs have a single highly conserved histidine located near the photoactive site of the protein. Time-resolved Fourier transform IR difference spectroscopy combined with visible absorption spectroscopy, isotope labeling, and electrical measurements of light-induced charge movements reveal participation of His-75 in the proton translocation mechanism of PR. Substitution of His-75 with Ala or Glu perturbed the structure of the photoactive site and resulted in significantly shifted visible absorption spectra. In contrast, His-75 substitution with a positively charged Arg did not shift the visible absorption spectrum of PR. The mutation to Arg also blocks the light-induced proton transfer from the Schiff base to its counterion Asp-97 during the photocycle and the acid-induced protonation of Asp-97 in the dark state of the protein. Isotope labeling of histidine revealed that His-75 undergoes deprotonation during the photocycle in the proton-pumping (high pH) form of PR, a reaction further supported by results from H75E. Finally, all His-75 mutations greatly affect charge movements within the PR and shift its pH dependence to acidic values. A model of the proteorhodopsin proton transport process is proposed as follows: (i) in the dark state His-75 is positively charged (protonated) over a wide pH range and interacts directly with the Schiff base counterion Asp-97; and (ii) photoisomerization-induced transfer of the Schiff base proton to the Asp-97 counterion disrupts its interaction with His-75 and triggers a histidine deprotonation.

Conformational changes in the photocycle of Anabaena sensory rhodopsin : Absence of the schiff base counterion protonation signal

Anabaena sensory rhodopsin (ASR) is a novel microbial rhodopsin recently discovered in the freshwater cyanobacterium Anabaena sp. PCC7120. This protein most likely functions as a photosensory receptor as do the related haloarchaeal sensory rhodopsins. However, unlike the archaeal pigments, which are tightly bound to their cognate membrane-embedded transducers, ASR interacts with a soluble cytoplasmic protein analogous to transducers of animal vertebrate rhodopsins. In this study, infrared spectroscopy was used to examine the molecular mechanism of photoactivation in ASR. Light adaptation of the pigment leads to a phototransformation of an all-trans/15-anti to 13-cis/15-syn retinylidene-containing species very similar in chromophore structural changes to those caused by dark adaptation in bacteriorhodopsin. Following 532 nm laser-pulsed excitation, the protein exhibits predominantly an all-trans retinylidene photocycle containing a deprotonated Schiff base species similar to those of other microbial rhodopsins such as bacteriorhodopsin, sensory rhodopsin II, and Neurospora rhodopsin. However, no changes are observed in the Schiff base counterion Asp-75, which remains unprotonated throughout the photocycle. This result along with other evidence indicates that the Schiff base proton release mechanism differs significantly from that of other known microbial rhodopsins, possibly because of the absence of a second carboxylate group at the ASR photoactive site. Several conformational changes are detected during the ASR photocycle including in the transmembrane helices E and G as indicated by hydrogen-bonding alterations of their native cysteine residues. In addition, similarly to animal vertebrate rhodopsin, perturbations of the polar head groups of lipid molecules are detected.

A Fourier Transform Infrared Study of Neurospora Rhodopsin: Similarities with Archaeal Rhodopsins¶,†

The NOP‐1 gene from the eukaryote Neurospora crassa, a filamentous fungus, has recently been shown to encode an archaeal rhodopsin–like protein NOP‐1. To explore the functional mechanism of NOP‐1 and its possible similarities to archaeal and visual rhodopsins, static and time‐resolved Fourier transform infrared difference spectra were measured from wild‐type NOP‐1 and from a mutant containing an Asp→Glu substitution in the Schiff base (SB) counterion, Asp131 (D131E). Several conclusions could be drawn about the molecular mechanism of NOP‐1: ( 1 ) the NOP‐1 retinylidene chromophore undergoes an all‐trans to 13‐cis isomerization, which is typical of archaeal rhodopsins, and closely resembles structural changes of the chromophore in sensory rhodopsin II; ( 2 ) the NOP‐1 SB counterion, Asp131, has a very similar environment and behavior compared with the SB counterions in bacteriorhodopsin (BR) and sensory rhodopsin II; ( 3 ) the O–H stretching of a structurally active water molecule(s) in NOP‐1 is similar to water detected in BR and is most likely located near the SB and SB counterion in these proteins; and ( 4 ) one or more cysteine residues undergo structural changes during the NOP‐1 photocycle. Overall, these results indicate that many features of the active sites of the archaeal rhodopsins are conserved in NOP‐1, despite its eukaryotic origin.

Protonation State of Glu142 Differs in the Green-and Blue-Absorbing Variants of Proteorhodopsin

Proteorhodopsins are a recently discovered class of microbial rhodopsins, ubiquitous in marine bacteria. Over 4000 variants have thus far been discovered, distributed throughout the oceans of the world. Most variants fall into one of two major groups, green- or blue-absorbing proteorhodopsin (GPR and BPR, respectively), on the basis of both the visible absorption maxima (530 versus 490 nm) and photocycle kinetics ( approximately 20 versus approximately 200 ms). For a well-studied pair, these differences appear to be largely determined by the identity of a single residue at position 105 (leucine/GPR and glutamine/BPR). We find using a combination of visible and infrared spectroscopy that a second difference is the protonation state of a glutamic acid residue located at position 142 on the extracellular side of helix D. In BPR, Glu142 (the GPR numbering system is used) is deprotonated and can act as an alternate proton acceptor, thus explaining the earlier observations that neutralization of the Schiff base counterion, Asp97, does not block the formation of the M intermediate. In contrast, Glu142 in GPR is protonated and cannot act in this state as an alternate proton acceptor for the Schiff base. On the basis of these findings, a mechanism is proposed for proton pumping in BPR. Because the pKa of Glu142 is near the pH of its native marine environment, changes in pH may act to modulate its function in the cell.

Different structural changes occur in blue- and green-proteorhodopsins during the primary photoreaction.

We examine the structural changes during the primary photoreaction in blue-absorbing proteorhodopsin (BPR), a light-driven retinylidene proton pump, using low-temperature FTIR difference spectroscopy. Comparison of the light-induced BPR difference spectrum recorded at 80 K to that of green-absorbing proteorhodopsin (GPR) reveals that there are several differences in the BPR and GPR primary photoreactions despite the similar structure of the retinal chromophore and all-trans --> 13-cis isomerization. Strong bands near 1700 cm(-1) assigned previously to a change in hydrogen bonding of Asn230 in GPR are still present in BPR. However, additional bands in the same region are assigned on the basis of site-directed mutagenesis to changes occurring in Gln105. In the amide II region, bands are assigned on the basis of total (15)N labeling to structural changes of the protein backbone, although no such bands were previously observed for GPR. A band at 3642 cm(-1) in BPR, assigned to the OH stretching mode of a water molecule on the basis of H2(18)O substitution, appears at a different frequency than a band at 3626 cm(-1) previously assigned to a water molecule in GPR. However, the substitution of Gln105 for Leu105 in BPR leads to the appearance of both bands at 3642 and 3626 cm(-1), indicating the waters assigned in BPR and GPR exist in separate distinct locations and can coexist in the GPR-like Q105L mutant of BPR. These results indicate that there exist significant differences in the conformational changes occurring in these two types proteorhodopsin during the initial photoreaction despite their similar chromophore structures, which might reflect a different arrangement of water in the active site as well as substitution of a hydrophilic for hydrophobic residue at residue 105.

Methionine Changes in Bacteriorhodopsin Detected by FTIR and Cell-Free Selenomethionine Substitution

Bacteriorhodopsin (BR) is an integral membrane protein, which functions as a light-driven proton pump in Halobacterium salinarum. We report evidence that one or more methionine residues undergo a structural change during the BR-->M portion of the BR photocycle. Selenomethionine was incorporated into BR using a cell-free protein translation system containing an amino acid mixture with selenomethionine substituted for methionine. BR-->M FTIR difference spectra recorded for unlabeled and selenomethionine-labeled cell-free expressed BR closely resemble the spectra of in vivo expressed BR. However, reproducible changes occur in two regions near 1,284 and 900 cm(-1) due to selenomethionine incorporation. Isotope labeled tyrosine was also co-incorporated with selenomethionine in order to confirm these assignments. Based on recent x-ray crystallographic studies, likely methionines which give rise to the FTIR difference bands are Met-118 and Met-145, which are located inside the retinal binding pocket and in a position to constrain the motion of retinal during photoisomerization. The assignment of methionine bands in the FTIR difference spectrum of BR provides a means to study methionine-chromophore interaction under physiological conditions. More generally, combining cell-free incorporations of selenomethionine into proteins with FTIR difference spectroscopy provides a useful method for investigating the role of methionines in protein structure and function.

Active Water in Protein-Protein Communication within the Membrane: the Case of SRII-HtrII Signal Relay

We detect internal water molecules in a membrane-embedded receptor-transducer complex and demonstrate water structure changes during formation of the signaling state. Time-resolved FTIR spectroscopy reveals stimulus-induced repositioning of one or more structurally active water molecules to a significantly more hydrophobic environment in the signaling state of the sensory rhodopsin II (SRII)-transducer (HtrII) complex. These waters, distinct from bound water molecules within the SRII receptor, appear to be in the middle of the transmembrane interface region near the Tyr199(SRII)-Asn74(HtrII) hydrogen bond. We conclude that water potentially plays an important role in the SRII --> HtrII signal transfer mechanism in the membranes hydrophobic core.

His75 in Proteorhodopsin, a Novel Component in Light-Driven Proton Translocation by Primary Pumps

Proteorhodopsins (PRs), photoactive retinylidene membrane proteins ubiquitous in marine eubacteria, exhibit light-driven proton transport activity similar to that of the well-studied bacteriorhodopsin from halophilic archaea. However, unlike bacteriorhodopsin, PRs have a single highly conserved histidine located near the proteins photoactive site. Time-resolved FTIR difference spectroscopy combined with visible absorption spectroscopy, isotope labeling, and electrical measurements of light-induced charge movements reveal participation of His75 in the proton translocation mechanism of PR. Substitution of His75 with Ala or Glu perturbed the structure of the photoactive site and resulted in significantly shifted visible absorption spectra. In contrast, His75 substitution with a positively charged Arg did not shift the visible absorption spectrum of PR. The mutation to Arg also blocks the light-induced proton transfer from the Schiff base to its counterion Asp97 during the photocycle and the acid-induced protonation of Asp97 in the proteins dark state. Isotope labeling of histidine revealed that His75 undergoes deprotonation during the photocycle in the proton-pumping (high pH) form of PR, a reaction further supported by results from H75E. Finally, all His75 mutations greatly affect charge movements within the PR and shift its pH dependence to acidic values. A model of the proteorhodopsin proton transport process is proposed whereby (i) in the dark state His75 is positively charged (protonated) over a wide pH range and interacts directly with the Schiff base counterion Asp97; and (ii) photoisomerization-induced transfer of the Schiff base proton to the Asp97 counterion disrupts its interaction with His75 and triggers a histidine deprotonation.