Structural Evolution of a Retinal Chromophore in the Photocycle of Halorhodopsin from Natronobacterium pharaonis.

We revealed the chloride ion pumping mechanism in halorhodopsin from Natronobacterium pharaonis ( pHR) by exploring sequential structural changes in the retinal chromophore during its photocycle using time-resolved resonance Raman (RR) spectroscopy on the nanosecond to millisecond time scales. A series of RR spectra of the retinal chromophore in the unphotolyzed state and of the three intermediates of pHR were obtained. Using singular value decomposition analysis of the C═C and C-C stretch bands in the time-resolved RR spectra, we identified the spectra of the K, L, and N intermediates. We focused on structural markers of the RR bands to explore the structure of the retinal chromophore. In the unphotolyzed state, the retinal chromophore is in the planar all- trans, 15- anti geometry. The bound ion affects the polyene chain but does not interact with the protonated Schiff base. In the observed intermediates, the chromophore is in the 13- cis configuration. The chromophore in the K intermediate is distorted due to the photoisomerization of retinal. The hydrogen bond is weak in the unphotolyzed state and in the K intermediate, resulting in exchange of the hydrogen-bond acceptor to a water molecule in the K-to-L transition, relaxation of the polyene chain distortion, and generation of an alternative distortion near the Schiff base. The bound halide ion interacts with the protonated Schiff base through the water molecule bound to the protonated Schiff base. In the L-to-N transition, the hydrogen acceptor of the protonated Schiff base switches from the water molecule to another species, although the strong hydrogen bond of the protonated Schiff base remains. This paper reports the first observation of sequential changes in the RR spectra in the pHR photocycle, provides information on the structural evolution of the retinal chromophore, and proposes a model for chloride ion translocation in pHR.

Cation binding to halorhodopsin.

A member of the retinal protein family, halorhodopsin, acts as an inward light-driven Cl(-) pump. It was recently demonstrated that the Natronomonas pharaonis halorhodopsin-overproducing mutant strain KM-1 contains, in addition to the retinal chromophore, a lipid soluble chromophore, bacterioruberin, which binds to crevices between adjacent protein subunits. It is established that halorhodopsin has several chloride binding sites, with binding site I, located in the retinal protonated Schiff base vicinity, affecting retinal absorption. However, it remained unclear whether cations also bind to this protein. Our electron paramagnetic resonance spectroscopy examination of cation binding to the halorhodopsin mutant KM-1 reveals that divalent cations like Mn(2+) and Ca(2+) bind to the protein. Halorhodopsin has a high affinity for Mn(2+) ions, which bind initially to several strong binding sites and then to binding sites that exhibit positive cooperativity. The binding behavior is pH-dependent, and its strength is influenced by the nature of counterions. Furthermore, the binding strength of Mn(2+) ions decreases upon removal of the retinal chromophore from the protein or following bacterioruberin oxidation. Our results also indicate that Mn(2+) ions, as well as Cl(-) ions, first occupy binding sites other than site I. The observed synergetic effect between cation and anion binding suggests that while Cl(-) anions bind to halorhodopsin at low concentrations, the occupancy of site I requires a high concentration.

Comparative simulations of the ground state and the M-intermediate state of the sensory rhodopsin II-transducer complex with a HAMP domain model.

The complex of sensory rhodopsin II (SRII) and its cognate transducer HtrII (2:2 SRII-HtrII complex) consists of a photoreceptor and its signal transducer, respectively, associated with negative phototaxis in extreme halophiles. In this study to investigate how photoexcitation in SRII affects the structures of the complex, we conducted two series of molecular dynamics simulations of the complex of SRII and truncated HtrII (residues 1-136) of Natronomonas pharaonis linked with a modeled HAMP domain in the lipid bilayer using the two crystal structures of the ground state and the M-intermediate state as the starting structures. The simulation results showed significant enhancements of the structural differences observed between the two crystal structures. Helix F of SRII showed an outward motion, and the C-terminal end of transmembrane domain 2 (TM2) in HtrII rotated by ∼10°. The most significant structural changes were observed in the overall orientations of the two SRII molecules, closed in the ground state and open in the M-state. This change was attributed to substantial differences in the structure of the four-helix bundle of the HtrII dimer causing the apparent rotation of TM2. These simulation results established the structural basis for the various experimental observations explaining the structural differences between the ground state and the M-intermediate state.

Color Tuning in rhodopsins: the origin of the spectral shift between the chloride-bound and anion-free forms of halorhodopsin.

Detailed knowledge of the molecular mechanisms that control the spectral properties in the rhodopsin protein family is important for understanding the functions of these photoreceptors and for the rational design of artificial photosensitive proteins. Here we used a high-level ab initio QM/MM method to investigate the mechanism of spectral tuning in the chloride-bound and anion-free forms of halorhodopsin from Natronobacterium pharaonis (phR) and the interprotein spectral shift between them. We demonstrate that the chloride ion tunes the spectral properties of phR via two distinct mechanisms: (i) electrostatic interaction with the chromophore, which results in a 95 nm difference between the absorption maxima of the two forms, and (ii) induction of a structural reorganization in the protein, which changes the positions of charged and polar residues and reduces this difference to 29 nm. The present study expands our knowledge concerning the role of the reorganization of the internal H-bond network for color tuning in general and provides a detailed investigation of the tuning mechanism in phR in particular.

Active state of sensory rhodopsin II: structural determinants for signal transfer and proton pumping.

The molecular mechanism of transmembrane signal transduction is still a pertinent question in cellular biology. Generally, a receptor can transfer an external signal via its cytoplasmic surface, as found for G-protein-coupled receptors such as rhodopsin, or via the membrane domain, such as that in sensory rhodopsin II (SRII) in complex with its transducer, HtrII. In the absence of HtrII, SRII functions as a proton pump. Here, we report on the crystal structure of the active state of uncomplexed SRII from Natronomonas pharaonis, NpSRII. The problem with a dramatic loss of diffraction quality upon loading of the active state was overcome by growing better crystals and by reducing the occupancy of the state. The conformational changes in the region comprising helices F and G are similar to those observed for the NpSRII-transducer complex but are much more pronounced. The meaning of these differences for the understanding of proton pumping and signal transduction by NpSRII is discussed.

Deciphering excited state evolution in halorhodopsin with stimulated emission pumping.

The primary photochemical dynamics of Hb. pharaonis Halorhodopsin (pHR) are investigated by femtosecond visible pump-near IR dump-hyperspectral probe spectroscopy. The efficiency of excited state depletion is deduced from transient changes in absorption, recorded with and without stimulated emission pumping (SEP), as a function of the dump delay. The concomitant reduction of photocycle population is assessed by probing the "K" intermediate difference spectrum. Results show that the cross section for stimulating emission is nearly constant throughout the fluorescent state lifetime. Probing "K" demonstrates that dumping produces a proportionate reduction in photocycle yields. We conclude that, despite its nonexponential internal conversion (IC) kinetics, the fluorescent state in pHR constitutes a single intermediate in the photocycle. This contrasts with conclusions drawn from the study of primary events in the related chloride pump from Hb. salinarum (sHR), believed to produce the "K" intermediate from a distinct short-lived subpopulation in the excited state. Our discoveries concerning internal conversion dynamics in pHR are discussed in light of recent expectations for similar excited state dynamics in both proteins.

The retinal structure of channelrhodopsin-2 assessed by resonance Raman spectroscopy.

Channelrhodopsin-2 mediates phototaxis in green algae by acting as a light-gated cation channel. As a result of this property, it is used as a novel optogenetic tool in neurophysiological applications. Structural information is still scant and we present here the first resonance Raman spectra of channelrhodopsin-2. Spectra of detergent solubilized and lipid-reconstituted protein were recorded under pre-resonant conditions to exclusively probe retinal in its electronic ground state. All-trans retinal was identified to be the favoured configuration of the chromophore but significant contributions of 13-cis were detected. Pre-illumination hardly changed the isomeric composition but small amounts of presumably 9-cis retinal were found in the light-adapted state. Spectral analysis suggested that the Schiff base proton is strongly hydrogen-bonded to a nearby water molecule.

Single-molecule force spectroscopy measures structural changes induced by light activation and transducer binding in sensory rhodopsin II.

Microbial rhodopsins are a family of seven-helical transmembrane proteins containing retinal as chromophore. Sensory rhodopsin II (SRII) triggers two very different responses upon light excitation, depending on the presence or the absence of its cognate transducer HtrII: Whereas light activation of the NpSRII/NpHtrII complex activates a signalling cascade that initiates the photophobic response, NpSRII alone acts as a proton pump. Using single-molecule force spectroscopy, we analysed the stability of NpSRII and its complex with the transducer in the dark and under illumination. By improving force spectroscopic data analysis, we were able to reveal the localisation of occurring forces within the protein chain with a resolution of about six amino acids. Distinct regions in helices G and F were affected differently, depending on the experimental conditions. The results are generally in line with previous data on the molecular stability of NpSRII. Interestingly, new interaction sites were identified upon light activation, whose functional importance is discussed in detail.

The lifetimes of Pharaonis phoborhodopsin signaling states depend on the rates of proton transfers--effects of hydrostatic pressure and stopped flow experiments.

Pharaonis phoborhodopsin (ppR), a negative phototaxis receptor of Natronomonas pharaonis, undergoes photocycle similar to the light-driven proton pump bacteriorhodopsin (BR), but the turnover rate is much slower due to much longer lifetimes of the M and O intermediates. The M decay was shown to become as fast as it is in BR in the L40T/F86D mutant. We examined the effects of hydrostatic pressure on the decay of these intermediates. For BR, pressure decelerated M decay but slightly affected O decay. In contrast, with ppR and with its L40T/F86D mutant, pressure slightly affected M decay but accelerated O decay. Clearly, the pressure-dependent factors for M and O decay are different in BR and ppR. In order to examine the deprotonation of Asp75 in unphotolyzed ppR we performed stopped flow experiments. The pH jump-induced deprotonation of Asp75 occurred with 60 ms, which is at least 20 times slower than deprotonation of the equivalent Asp85 in BR and about 10-fold faster than the O decay of ppR. These data suggest that proton transfer is slowed not only in the cytoplasmic channel but also in the extracellular channel of ppR and that the light-induced structural changes in the O intermediate of ppR additionally decrease this rate.

Protein-protein interaction of a Pharaonis halorhodopsin mutant forming a complex with Pharaonis halobacterial transducer protein II detected by Fourier-transform infrared spectroscopy.

Pharaonis halorhodopsin (pHR) functions as a light-driven inward chloride ion pump in Natoronomonas pharaonis, while pharaonis phoborhodopsin (ppR; also called pharaonis sensory rhodopsin II, pSRII), is a light sensor for negative phototaxis. ppR forms a 2:2 complex with its cognate transducer protein (pHtrII) through intramembranous hydrogen bonds: Tyr199(ppR)-Asn74(pHtrII) and Thr189(ppR)-Glu43 (pHtrII), Ser62(pHtrII). It was reported that a pHR mutant (P240T/F250Y), which possesses the hydrogen-bonding sites, impairs its pumping activity upon complexation with pHtrII. In this study, effect of the complexation with pHtrII on the structural changes upon formation of the K, L(1) and L(2) intermediates of pHR was investigated by use of Fourier-transform infrared spectroscopy. The vibrational changes of Tyr250(pHR) and Asn74(pHtrII) were detected for the L(1) and L(2) intermediates, supporting that Tyr250(pHR) forms a hydrogen bond with Asn74(pHtrII) as similarly to Tyr199(ppR). The conformational changes of the retinal chromophore were never affected by complexation with pHtrII, but amide-I vibrations were clearly different in the absence and presence of pHtrII. The molecular environment around Asp156(pHR) in helix D is also slightly affected. These additional structural changes are probably related to blocking of translocation of a chloride ion from the extracellular to the cytoplasmic side during the photocycle.

Signal transmission through the HtrII transducer alters the interaction of two alpha-helices in the HAMP domain.

A conformational change of the transducer HtrII upon photoexcitation of the associated photoreceptor sensory rhodopsin II (SRII) was investigated by monitoring the kinetics of volume changes and the diffusion coefficient (D) of the complex during the photochemical reaction cycle. To localize the region of the transducer responsible, we truncated it at various positions in the cytoplasmic HAMP (histidine kinases, adenylyl cyclases, methyl-accepting chemotaxis proteins, and phosphatases) domain. The truncations do not alter receptor binding, which is dependent primarily on membrane-embedded domain interactions. We found that the light-induced reduction in D occurs in transducers of lengths 120 and 157 residues (Tr120 and Tr157), which are both predicted to contain a HAMP domain consisting of two amphipathic alpha-helices (AS-1 and AS-2). In contrast, the change in D was abolished in a transducer of 114 amino acid residues (Tr114), which lacks a distal portion of the second alpha-helix AS-2. The volume changes in SRII-Tr114 are comparable in amplitude and kinetics with those in SRII-Tr120 and SRII-Tr157, confirming the integrity of the complex, which was previously concluded from the similar SRII binding affinity and similar blocking of SRII proton transport by full-length HtrII and Tr114. Our results indicate that a substantial conformational change occurs in the HAMP domain during SRII-HtrII signaling. The data presented here are the first demonstration of stimulus-induced conformational changes of a HAMP domain and provide evidence that the presence of AS-2 is crucial for the conformational alterations. The reduction in diffusion coefficient is likely to due to structural changes in the AS-1 and AS-2 helices such that hydrogen bonding with the surrounding water molecules is increased, thereby increasing friction with the solvent. Similar structural changes may be a general feature in HAMP domain switching, which occurs in diverse signaling proteins, including sensor kinases, taxis receptors/transducers, adenylyl cyclases, and phosphatases.

Shape and oligomerization state of the cytoplasmic domain of the phototaxis transducer II from Natronobacterium pharaonis.

Phototaxis allows archaea to adjust flagellar motion in response to light. In the photophobic response of Natronobacterium pharaonis, light-activated sensory rhodopsin II causes conformational changes in the transducer II protein (pHtrII), initiating the two-component signaling system analogous to bacterial chemotaxis. pHtrII's cytoplasmic domain (pHtrII-cyt) is homologous to the cytoplasmic domains of eubacterial chemotaxis receptors. Chemotaxis receptors require dimerization for activity and are in vivo-organized in large clusters. In this study we investigated the oligomerization and aggregation states of pHtrII-cyt by using chemical cross-linking, analytical gel-filtration chromatography, and small-angle neutron scattering. We show that pHtrII-cyt is monomeric in dilute buffers, but forms dimers in 4 M KCl, the physiological salt concentration for halophilic archaea. At high ammonium sulfate concentration, the protein forms higher-order aggregates. The monomeric protein has a rod-like shape, 202 A in length and 14.4 A in diameter; upon dimerization the length increases to 248 A and the diameter to 18.2 A. These results suggest that under high salt concentration the shape and oligomerization state of pHtrII-cyt are comparable to those of chemotaxis receptors.

All-optical switching in Pharaonis phoborhodopsin protein molecules.

Low-power all-optical switching with pharaonis phoborhodopsin (ppR) protein is demonstrated based on nonlinear excited-state absorption at different wavelengths. A modulating pulsed 532-nm laser beam is shown to switch the transmission of a continuous-wave signal light beam at: 1) 390 nm; 2) 500 nm; 3) 560 nm; and 4) 600 nm, respectively. Simulations based on the rate equation approach considering all seven states in the ppR photocycle are in good agreement with experimental results. It is shown that the switching characteristics at 560 and 600 nm, respectively, can exhibit negative to positive switching. The switching characteristics at 500 nm can be inverted by increasing the signal beam intensity. The profile of switched signal beam is also sensitive to the modulating pulse frequency and signal beam intensity and wavelength. The switching characteristics are also shown to be sensitive to the lifetimes of ppR(M) and ppR(O) intermediates. The results show the applicability of ppR as a low-power wavelength tunable all-optical switch.

Internal water molecules of the proton-pumping halorhodopsin in the presence of azide.

In the FTIR study of rhodopsins, we have so far found that strongly hydrogen-bonded water molecules (O-D stretch at <2400 cm-1) are only present in the proteins exhibiting proton-pumping activity. Halorhodopsin (HR) is a light-driven chloride pump in haloarchaea, which does not possess such water molecules. On the other hand, it is known that addition of azide converts HR into a proton pump. Although the mechanism has not been understood, we observed strongly hydrogen-bonded water molecules in the azide-bound HR of Natronobacterium pharaonis (pHR). This finding is consistent with the previous results, implying that the presence of strongly hydrogen-bonded water molecules is requested for the proton-pumping function of rhodopsins.

The protonated Schiff base of halorhodopsin from Natronobacterium pharaonis is hydrolyzed at elevated temperatures.

Halorhodopsin from Natronobacterium pharaonis (pHR) is a light-driven chloride pump in which photoisomerzation of a retinal chromophore triggers a photocycle which leads to a chloride anion transport across the plasma membrane. Similarly to other retinal proteins the protonated Schiff base (PSB), which covalently links the retinal to the protein, does not experience hydrolysis reaction at room temperature even though several water molecules are located in the protonated Schiff base (PSB) vicinity. In the present studies we have revealed that in contrast to other studied archaeal rhodopsins, temperature increase to about 70 degrees C hydrolyses the PSB linkage of pHR. The rate of the reaction is affected by Cl-concentration and reveals an anion binding site (in addition to the Cl- in the SB vicinity) with a binding constant of 100mM (measured at 70 degrees C). We suggest that this binding site is located on the extracellular side and its possible role in the Cl-pumping mechanism is discussed. The rate of the hydrolysis reaction is affected by the nature of the anion bound to pHR. Substitution of the Cl- anion by Br-, I- and SCN- exhibits similar behavior to that of CI- in the region of 100mM but higher concentrations are needed for N3-, HCOO- and NO2-to achieve similar behavior. Steady state pigment illumination accelerates the reaction and reduces the energy of activation and the frequency factor. Adjusting the sample temperature to 25 degrees C following the hydrolysis reaction led to about 80% pigment recovery. However, the newly reformed pigment is different from the mother pigment and has different characteristics. It is concluded that the apo-membrane adopts a modified conformation and/or aggregated state which rebinds the retinal to give a new conformation of the pHR pigment.

Spin labeling of Natronomonas pharaonis halorhodopsin: probing the cysteine residues environment.

Halorhodopsin from Natronomonas pharaonis (pHR) is a light-driven chloride pump that transports a chloride anion across the plasma membrane following light absorption by a retinal chromophore which initiates a photocycle. Analysis of the amino acid sequence of pHR reveals three cysteine residues (Cys160, Cys184, and Cys186) in helices D and E. Here we have labeled the cysteine residues with nitroxide spin labels and studied using electron paramagnetic resonance (EPR) spectroscopy their mobility, accessibility to various reagents, and the distance between the labels. It was revealed by following the d(1)/d parameter that the distance between the spin labels is ca. 13-15 Angstrom. The EPR spectrum suggests that one label has a restricted mobility while the other two are more mobile. Only one label is accessible to hydrophilic paramagnetic broadening reagents leading to the conclusion that this label is exposed to the water phase. All three labels are reduced by ascorbic acid and reoxidized by molecular oxygen. The rate of the oxidation is accelerated following retinal irradiation indicating that the protein experiences conformation alterations in the vicinity of the labels during the pigment photocycle. It is suggested that Cys186 is exposed to the bulk medium while Cys184, located close to the retinal ionone ring, exhibits an immobilized EPR signal and is characterized by a hydrophobic environment.

The trans-cis isomerization reaction dynamics in sensory rhodopsin II by femtosecond time-resolved midinfrared spectroscopy: chromophore and protein dynamics.

Transient infrared (IR) vibrational spectroscopy at subpicosecond time resolution on sensory rhodopsin II from Natronomonas pharaonis, NpSRII, has been performed for the first time. The experiments yield three time constants for the description of the primary photoinduced reaction dynamics, i.e. 0.5, 3.7-4.4, and 11 ps. The data are consistent with a sequential reaction scheme, with the isomerization taking place within 0.5 ps, succeeded by an electronic ground state relaxation. The 11 ps component, observed at 1550 and 1530 cm(-1), is attributed to dynamics of protein vibrational bands, possibly amide II bands of the protein backbone, perturbed by the ultrafast retinal photoisomerization. Similar observations, yet not as strongly expressed, have been made earlier in bacteriorhodopsin and halorhodopsin.

Effects of solubilization on the structure and function of the sensory rhodopsin II/transducer complex.

Lipid-protein interactions are known to play a crucial role in structure and physiological activity of integral membrane proteins. However, current technology for membrane protein purification necessitates extraction from the membrane into detergent micelles. Also, due to experimental protocols, most of the data available for membrane proteins is obtained using detergent-solubilized samples. Stable solubilization of membrane proteins is therefore an important issue in biotechnology as well as in biochemistry and structural biology. An understanding of solubilization effects on structural and functional properties of specific proteins is of utmost relevance for the evaluation and interpretation of experimental results. In this study, a comparison of structural and kinetic data obtained for the archaebacterial photoreceptor/transducer complex from Natronomonas pharaonis (NpSRII/NpHtrII) in detergent-solubilized and lipid-reconstituted states is presented. Laser flash photolysis, fluorescence spectroscopy, and electron paramagnetic resonance spectroscopy data reveal considerable influence of solubilization on the photocycle kinetics of the receptor protein and on the structure of the transducer protein. Especially the protein-membrane proximal region and the protein-protein interfacial domains are sensitive towards non-native conditions. These data demonstrate that relevance of biochemical and structural information obtained from solubilized membrane proteins or membrane protein complexes has to be evaluated carefully.

Effect of anions on the photocycle of halorhodopsin. Substitution of chloride with formate anion.

Halorhodopsin from Natronomonas pharaonis is a light-driven chloride pump which transports a chloride anion across the plasma membrane following light absorption by a retinal chromophore which initiates a photocycle. It was shown that the chloride anion bound in the vicinity of retinal PSB can be replaced by several inorganic anions, including azide which converts the chloride pump into a proton pump and induces formation of an M-like intermediate detected in the bR photocycle but not in native halorhodopsin. Here we have studied the possibility of replacing the chloride anion with organic anions and have followed the photocycle under several conditions. It is revealed that the chloride can be replaced with a formate anion but not with larger organic anions such as acetate. Flash photolysis experiments detected in the formate pigment an M-like intermediate characterized by a lifetime much longer than that of the O intermediate. The lifetime of the M-like intermediate depends on the pH, and its decay is significantly accelerated at low pH. The decay rate exhibited a titration-like curve, suggesting that the protonation of a protein residue controls the rate of M decay. Similar behavior was detected in N. pharaonis pigments in which the chloride anion was replaced with NO(2)(-) and OCN(-) anions. It is suggested that the formation of the M-like intermediate indicates branching pathways from the L intermediate or basic heterogeneity in the original pigment.

Disassembling and bleaching of chloride-free pharaonis halorhodopsin by octyl-beta-glucoside.

Natronomonas (Natronobacterium) pharaonis halorhodopsin (NpHR) is a transmembrane, seven-helix retinal protein of the archaeal bacterium and acts as an inward light-driven chloride ion pump in the membrane. The denaturation process of NpHR solubilized with n-octyl-beta-d-glucopyranoside (OG) was investigated to clarify the effects of the chloride ion and pH on the stability and bleaching of the NpHR chromophore. Initially, active NpHR solubilized with n-dodecyl-beta-d-maltopyranoside (DM) was obtained from the recombinant halo-opsin (NpHO), which was expressed in Escherichia coli cells, by adding all-trans retinal to the medium. Apparent molecular weight of the active NpHR solubilized with DM, which was determined by gel-filtration chromatography and dynamic light scattering, indicated the oligomeric state. The bleaching of NpHR in the dark by the addition of 50 mM OG in the presence and absence of chloride was investigated. In the presence of 256 mM NaCl, the bleaching of NpHR was strongly inhibited. On the other hand, in the absence of NaCl, an immediate decrease of absorbance at 600 nm was observed. Stopped-flow rapid-mixing analysis clarified the bleaching process in the absence of chloride as DM-NpHR (oligomeric) <--> OG-NpHR (disassembled) <--> intermediate --> NpHO and free retinal, and each rate constant were determined. The formation of an intermediate (450 nm) in the dark was found to be strongly dependent on pH, as well as anion and detergent concentrations. The disassembling and protonation of a Schiff base corresponding to the bleaching intermediate is also discussed.