Assignment of segments of the bacteriorhodopsin sequence to positions in the structural map

Structural studies of bacteriorhodopsin in BC era

It marked half a century since the discovery of bacteriorhodopsin two years ago. On this occasion, I have revisited historically important diffraction studies of this membrane protein, based on my recollections. X-ray diffraction and electron diffraction, and electron microscopy, described the low-resolution structure of bacteriorhodopsin within the purple membrane. Neutron diffraction was effective to assign the helical regions in the primary structure with 7 rods revealed by low-resolution structure as well as to describe the retinal position. Substantial conformational changes upon light illumination were clarified by the structures of various photointermediates. Early trials of time-resolved studies were also introduced. Models for the mechanism of light-driven proton pump based on the low-resolution structural studies are also described. Significantly, they are not far from the today's understanding. I believe that the spirit of the early research scientists in this field and the essence of their studies, which constitute the foundations of the field, still actively fertilizes current membrane protein research.

Low resolution structure and dynamics of a colicin-receptor complex determined by neutron scattering

Proteins that translocate across cell membranes need to overcome a significant hydrophobic barrier. This is usually accomplished via specialized protein complexes, which provide a polar transmembrane pore. Exceptions to this include bacterial toxins, which insert into and cross the lipid bilayer itself. We are studying the mechanism by which large antibacterial proteins enter Escherichia coli via specific outer membrane proteins. Here we describe the use of neutron scattering to investigate the interaction of colicin N with its outer membrane receptor protein OmpF. The positions of lipids, colicin N, and OmpF were separately resolved within complex structures by the use of selective deuteration. Neutron reflectivity showed, in real time, that OmpF mediates the insertion of colicin N into lipid monolayers. This data were complemented by Brewster Angle Microscopy images, which showed a lateral association of OmpF in the presence of colicin N. Small angle neutron scattering experiments then defined the three-dimensional structure of the colicin N-OmpF complex. This revealed that colicin N unfolds and binds to the OmpF-lipid interface. The implications of this unfolding step for colicin translocation across membranes are discussed.

Location of the cyclohexene ring of the chromophore of bacteriorhodopsin by neutron diffraction with selectively deuterated retinal

We report on the location of the cyclohexene ring of the retinylidene chromophore of bacteriorhodopsin projected onto the plane of the membrane. For this purpose, partially deuterated retinal was synthesized containing 11 deuterons at the following positions of the cyclohexene ring: one at C-2, two at C-4, three at C-16, three at C-17, and two at C-18. The partially deuterated retinal was incorporated biosynthetically during growth of the bacteria by using the mutant JW5, which is deficient in the synthesis of retinal. Undeuterated samples were prepared in the same way. Characterization by x-ray diffraction and absorption spectroscopy showed that these samples are identical to native purple membranes as judged by these criteria. A Fourier difference map was calculated from the differences in in-plane diffraction intensities between the deuterated and undeuterated dark-adapted membrane samples. Model calculations showed that the observed difference density had the amplitude expected for a label containing 11 deuterons. At 8.7 A resolution, the map shows one major peak with the center of mass of the deuterated ring in the interior of the molecule between helices 3, 4, 5, and 6. Based on this result and on our previous work on the location of the middle of the polyene chain, we conclude that the COOH-terminal helix G, to which retinal is attached at lysine-216, is either helix 2 or helix 6.

Location of chemically modified lysine 41 in the structure of bacteriorhodopsin by neutron diffraction

Purple membranes were prepared in which bacteriorhodopsin was labeled at lysine 41 with phenylisothiocyanate (PITC) and with perdeuterated PITC. The in-plane position of this small label containing only five deuterons was determined from the differences between the neutron diffraction intensities of the two samples. At 8.7-A resolution the Fourier difference map revealed a well-defined site between helices 3 and 4. This position was confirmed by a refinement procedure in reciprocal space. Model calculations showed that the observed difference density had the right amplitude for the label. Thus it is possible to locate a small group in a large protein structure by replacing as few as five hydrogens by deuterium. The observed location of PITC restricts the number of possibilities for the assignment of helix B in the sequence (to which lysine 41 is attached) to one of the seven helices of the structure. Taking into account the size of the label and the length of the lysine side chain our result excludes helices 1, 2, and 7 as candidates for B.

Determination of the absolute orientation of the retinylidene chromophore in purple membrane by a second-harmonic interference technique

The absolute direction of the retinal chromophore of bacterio-rhodopsin relative to the membrane plane is investigated by using an optical second-harmonic interference technique. Compared with the known adsorbed geometry of free retinylidene Schiff base on a glass substrate, our data indicate the beta-ionone ring of the chromophore of bacteriorhodopsin points away from the cytoplasmic surface of the purple membrane. The implication of this finding is discussed in light of other chemical and structural results on bacteriorhodopsin.

Further characterization of protein secondary structures in purple membrane by circular dichroism and polarized infrared spectroscopies

The conformation and the orientation of the protein secondary structures in purple membrane was analyzed by infrared absorption and linear dichroism of oriented membranes as well as by UV circular dichroism of bacteriorhodopsin in intact purple membrane and in lipid vesicles. A large amount (74 +/- 5%) of transmembrane alpha-helices is detected with no significant contribution of beta-sheet strands running perpendicular to the membrane plane. Thus, these data do not support the recent structural model proposed by Jap et al. (Biophys. J. 1983, 43:81-89).

Bacteriorhodopsin: the functional details of a molecular machine are being resolved

The photon-driven proton translocator bacteriorhodopsin is considered to be the best understood membrane protein so far. It is nowadays regarded as a model system for photosynthesis, ion pumps and seven transmembrane receptors. The profound knowledge came from the applicability of a variety of modern biophysical techniques which have often been further developed with research on bacteriorhodopsin and have delivered major contributions also to other areas. Most prominent examples are electron crystallography, solid-state NMR spectroscopy and time-resolved vibrational spectroscopy. The recently introduced method of crystallising a membrane protein in the lipidic cubic phase led to high-resolution structures of ground state bacteriorhodopsin and some of the photocycle intermediates. This achievement in combination with spectroscopic results will strongly advance our understanding of the functional mechanism of bacteriorhodopsin on the atomic level. We present here the current knowledge on specific aspects of the structural and functional dynamics of the photoreaction of bacteriorhodopsin with a focus on techniques established in our institute.

Bioenergetics of the Archaea

In the late 1970s, on the basis of rRNA phylogeny, Archaea (archaebacteria) was identified as a distinct domain of life besides Bacteria (eubacteria) and Eucarya. Though forming a separate domain, Archaea display an enormous diversity of lifestyles and metabolic capabilities. Many archaeal species are adapted to extreme environments with respect to salinity, temperatures around the boiling point of water, and/or extremely alkaline or acidic pH. This has posed the challenge of studying the molecular and mechanistic bases on which these organisms can cope with such adverse conditions. This review considers our cumulative knowledge on archaeal mechanisms of primary energy conservation, in relationship to those of bacteria and eucarya. Although the universal principle of chemiosmotic energy conservation also holds for Archaea, distinct features have been discovered with respect to novel ion-transducing, membrane-residing protein complexes and the use of novel cofactors in bioenergetics of methanogenesis. From aerobically respiring Archaea, unusual electron-transporting supercomplexes could be isolated and functionally resolved, and a proposal on the organization of archaeal electron transport chains has been presented. The unique functions of archaeal rhodopsins as sensory systems and as proton or chloride pumps have been elucidated on the basis of recent structural information on the atomic scale. Whereas components of methanogenesis and of phototrophic energy transduction in halobacteria appear to be unique to Archaea, respiratory complexes and the ATP synthase exhibit some chimeric features with respect to their evolutionary origin. Nevertheless, archaeal ATP synthases are to be considered distinct members of this family of secondary energy transducers. A major challenge to future investigations is the development of archaeal genetic transformation systems, in order to gain access to the regulation of bioenergetic systems and to overproducers of archaeal membrane proteins as a prerequisite for their crystallization.

Solid-state 13C-NMR of [(3-13C)Pro]bacteriorhodopsin and [(4-13C)Pro]bacteriorhodopsin: evidence for a flexible segment of the C-terminal tail

The configuration of an Xaa-Pro bond can be determined by solid-state magic-angle-sample-spinning (MASS)-13C-NMR spectroscopy since the chemical shifts of C beta and Cgamma of the proline ring are sensitive to the isomerization state of the preceding peptide bond. (3-13C)Pro and (4-13C)Pro have been chemically synthesized; the former by means of an asymmetric synthesis. The 13C-labeled Pro residues were biosynthetically incorporated into bacteriorhodopsin with a yield of 80%. The solid-state-MASS-13C-NMR spectra of [(3-13C)Pro]bacteriorhodopsin and [(4-13C)Pro]bacteriorhodopsin revealed isotropic chemical shifts at 29.8 ppm and 25.5 ppm, respectively. From the chemical-shift values we conclude that all Xaa Pro peptide bonds are in the trans configuration confirming previous results from solution-NMR studies on solubilized bacteriorhodopsin in organic solvents [Deber, M.C., Sorrell, B.J. & Xu, G.Y. (1990) Biochem. Biophys. Res. Commun. 172, 862-869]. Inversion-recovery experiments could differentiate between three classes of Pro residues distinguished by their relaxation time t1. Tentatively, these three distinct groups of Pro residues could be assigned to the helical, the loop, and the C-terminal parts of the protein. The resonances of the two C-terminal Pro could be identified by removing the C-terminus by proteolysis. Although they are separated by only one Glu they occupy different chemical environments and possess different flexibilities. These results indicate that the first part of the C-terminal tail is constrained. Pro238 marks the position where the tail becomes freely mobile. It is proposed that the C-terminus is fixed to the membrane via salt bridges between divalent cations and negative charges of the C-terminus as well as interhelical loops.

Retinal Schiff base chromophore in the surfactant solubilised water pools in CCl4

All-trans-N-retinylidene-n-butylamine Schiff base has been incorporated into AOT/CCl4 reverse micelles of various water pool sizes (omega = 0-20). The nature of interaction between retinal Schiff base and its surroundings in the micellar microenvironment has been investigated by NMR (1H-NMR and T1 studies). The Schiff base is found to undergo hydrogen bond interactions with bound water molecules. The results are discussed in terms of the implication of hydrogen bond interactions in retinal proteins, particularly, bacteriorhodopsin.

Rotational orientation of transmembrane alpha-helices in bacteriorhodopsin. A neutron diffraction study

The rotational orientation of the seven transmembrane alpha-helices (A-G) in bacteriorhodopsin has been investigated by neutron diffraction. The current model of bacteriorhodopsin is based on an electron density map obtained by high-resolution electron microscopy (EM). Assigning helix rotational positions in the EM model depended on fitting large side-chains, mainly aromatic residues, into bulges in the electron density map. For helix D, which contains no aromatic residues, the EM map is more difficult to interpret. For helices A and B, whose position and orientation had been determined previously by neutron diffraction, the positions defined by EM agree within experimental error with these earlier conclusions. The orientation of all seven helices has been examined by using neutron diffraction on bacteriorhodopsin samples with specifically deuterated valine, leucine and tryptophan residues. Experimental peak intensities were compared to those predicted for an extensive set of structural models. The models were generated by (1) rotating all helices around their axis; (2) moving deuterated residues in the extramembrane loops about their probable positions and changing the weight of their contribution to the neutron diffraction pattern; (3) allowing deuterated side-chains to change their conformation. The analysis confirmed exactly the positions previously determined for helices A and B. For an optimal fit to the data to be obtained, the other five helices, including helix D, must lie either at or within 20 degrees of their position in the current EM model. The complementarity of medium-resolution EM, neutron diffraction and model building for the structural study of integral membrane proteins is discussed.

Imaging the membrane protein bacteriorhodopsin with the atomic force microscope

The membrane protein bacteriorhodopsin was imaged in buffer solution at room temperature with the atomic force microscope. Three different substrates were used: mica, silanized glass and lipid bilayers. Single bacteriorhodopsin molecules could be imaged in purple membranes adsorbed to mica. A depression was observed between the bacteriorhodopsin molecules. The two dimensional Fourier transform showed the hexagonal lattice with a lattice constant of 6.21 +/- 0.20 nm which is in agreement with results of electron diffraction experiments. Spots at a resolution of approximately 1.1 nm could be resolved. A protein, cationic ferritin, could be imaged bound to the purple membranes on glass which was silanized with aminopropyltriethoxysilane. This opens the possibility of studying receptor/ligand binding under native conditions. In addition, purple membranes bound to a lipid bilayer were imaged. These images may help in interpreting results of functional studies done with purple membranes adsorbed to black lipid membranes.

High resolution 13C-solid state NMR of bacteriorhodopsin: assignment of specific aspartic acids and structural implications of single site mutations

Three mutant strains of Halobacterium sp. GRB with the site of mutation in the bacterioopsin gene (PM 326: Asp96----Asn; PM 374: Asp96----Gly; PM 384: Asp85----Glu) were grown in a synthetic medium containing (4-13C)-Asp. The mutant bacteriorhodopsins labeled with (4-13C)-Asp (37%-45%), and owing to the metabolism of Halobacteria also with (11-13C)-Trp (50%-100%), were isolated as purple membranes and 13C Solid State Magic Angle Sample Spinning (MASS) Nuclear Magnetic Resonance (NMR) spectra of the samples were taken. The Asp96 mutants lacked the signal at 171.3 ppm which was previously assigned to a protonated internal Asp (Engelhard et al. 1989a). This observation supports the conclusion that Asp96 is protonated in the ground state. PM 384 (Asp85----Glu) has an absorption maximum at 610 nm. It can be converted into a purple form (lambda max = 540 nm) by treatment with a detergent (CHAPSO). The NMR-spectra of these two species differ from each other and from the wild type. The intensity of the resonance at 173 ppm in the wild type spectrum is reduced in both forms of the mutant protein. It is probable that this signal is caused by Asp85. The amino acid changes result not only in a perturbation of their direct environment but also effects on Trp residues and the chromophore protein interaction can be observed.

Tertiary structure of bacteriorhodopsin. Positions and orientations of helices A and B in the structural map determined by neutron diffraction

Positions and rotations of two helices in the tertiary structure of bacteriorhodopsin have been studied by neutron diffraction using reconstituted, hybrid purple membrane samples. Purple membrane was biosynthetically 2H-labeled at non-exchangeable hydrogen positions of leucine and tryptophan residues. Two chymotryptic fragments were purified, encompassing either the first two or the last five of the seven putative transmembrane segments identified in the amino acid sequence of bacteriorhodopsin. The 2H-labeled fragments, diluted to variable extents with the identical, unlabeled fragment, were mixed with their unlabeled counterpart; bacteriorhodopsin was then renatured and reconstituted. The crystalline purple membrane samples thus obtained contained hybrid bacteriorhodopsin molecules in which certain transmembrane segments had been selectively 2H-labeled to various degrees. Neutron diffraction powder patterns were recorded and analyzed both by calculating difference Fourier maps and by model building. The two analyses yielded consistent results. The first and second transmembrane segments in the sequence correspond to helices 1 and 7 of the three-dimensional structure, respectively. Rotational orientations of these two helices were identified using best fits to the observed diffraction intensities. The data also put restrictions on the position of the third transmembrane segment. These observations are discussed in the context of folding models for bacteriorhodopsin, the environment of the retinal Schiff base, and site-directed mutagenesis experiments.

The transverse location of the retinal chromophore in the purple membrane by diffusion-enhanced energy transfer

We have used fluorescence energy transfer in the rapid-diffusion limit (RDL) to estimate the trans-membrane depth of retinal in the purple membrane (PM). Chelates of Tb(III) are excellent energy donors for the retinal chromophore of PM, having a maximum Ro value for Förster energy transfer of approximately 62 A (assuming a donor quantum yield of 1). Energy transfer rates were measured from the time-resolved emission kinetics of the donor. The distance of closest approach between chelates and the chromophore was estimated by simulating RDL energy-transfer rate constants according to geometric models of either PM sheets or membrane vesicles. The apparent rate constant for RDL energy transfer between Tb(III)HED3A and retinal in PM sheets is 1.5(+/- 0.1) x 10(6) M-1 s-1, corresponding to a depth of approximately 10 +/- 2 A for the retinal chromophore. Cell envelope vesicles (CEVs) from Halobacterium halobium were studied by using RDL energy transfer to assess the proximity of retinal to either the extracellular or intracellular face of the PM. The estimated depth of retinal from the extravesicular face of the PM is 10 +/- 3 A, based on the RDL energy-transfer rate constant. Energy-transfer levels to retinal in the PM were estimated by an indirect method with energy donors trapped in the inner-aqueous space of CEVs. The rate constants derived for this arrangement are too low to be consistent with the shortest depth of retinal deduced for PM sheets. Thus, the intravesticular face of CEVs, corresponding to the cytoplasmic face of cells, is the more distant surface from the chromophore of bacteriorhodopsin.

Atomic force microscopy of purple membranes

The surface structure of purple membranes was imaged using an atomic force probe mounted in a scanning tunnelling microscope. One of the two different membrane surfaces showed protruding, disc-shaped features forming an hexagonal lattice with about 6 nm centre to centre spacing. These are identified as the cytoplasmic surfaces of trimers of bacteriorhodopsin molecules and are correlated with the structural information on bacteriorhodopsin obtained from numerous earlier electron microscope and diffraction studies.

Aspartic acid substitutions affect proton translocation by bacteriorhodopsin

We have substituted each of the aspartic acid residues in bacteriorhodopsin to determine their possible role in proton translocation by this protein. The aspartic acid residues were replaced by asparagines; in addition, Asp-85, -96, -115, and -112 were changed to glutamic acid and Asp-212 was also replaced by alanine. The mutant bacteriorhodopsin genes were expressed in Escherichia coli and the proteins were purified. The mutant proteins all regenerated bacteriorhodopsin-like chromophores when treated with a detergent-phospholipid mixture and retinal. However, the rates of regeneration of the chromophores and their lambda max varied widely. No support was obtained for the external point charge model for the opsin shift. The Asp-85----Asn mutant showed not detectable proton pumping, the Asp-96----Asn and Asp-212----Glu mutants showed less than 10% and the Asp-115----Glu mutant showed approximately equal to 30% of the normal proton pumping. The implications of these findings for possible mechanisms of proton translocation by bacteriorhodopsin are discussed.

Fluorescent labeling of bacteriorhodopsin: implications for helix connections

Purple membrane from Halobacterium halobium was reacted with dansyl (5-dimethylamino-1-naphthalenyl fluorescent labels that have specificity for different protein side chains of bacteriorhodopsin. Dansyl chloride was found to react primarily with Lys-41. Dansyl hydrazine was coupled, with water-soluble carbodiimide, to Glu-74 and/or Asp-85, which was the major modified site after papain-cleavage of the carboxyl-terminal 17 amino acids. Fluorescence energy transfer was used to probe the proximity of the modified sites to the retinal chromophore of bacteriorhodopsin. The dansyl group on Lys-41 was greater than 2.99 nm from retinal, while the dansyl group on Glu-74/Asp-85 was greater than 2.10 nm from retinal. Information available on the location of retinal in the transmembrane profile and probable surface locations of the fluorescent labels was combined with the energy transfer results to calculate distances projected in the plane of the membrane. The projected distances to retinal were 1.64 nm (Lys-41) and 1.65 nm (Gly-74). These measurements, combined with many other labeling experiments that have been reported, restrict the number of likely helix-connection models to only three: EDCABGF, FEDCBAG and FGEABDC (in the nomenclature of Engelman et al. (1980) Proc. Natl. Acad. Sci. USA 77, 2023-2027).

The opsin family of proteins

Images

A conformational preference parameter to predict helices in integral membrane proteins

Assignments were made for helical regions in several integral membrane proteins using an algorithm devised to delineate the transmembrane helices in bacteriorhodopsin (Eur. J. Biochem. 182 (1982) 565-575). A new conformational preference parameter for membrane-buried helices was obtained. The use of this parameter to predict helices in membrane proteins is discussed. When applied to the L and M subunits of Rhodopseudomonas sphaeroides, five helices were predicted, which is consistent with the three-dimensional X-ray crystal structure. Data on signal sequences and amino acid exchanges in membrane proteins are also analysed and discussed

Structural comparison of native and deoxycholate-treated purple membrane

Lipid-depleted purple membrane prepared by extraction with deoxycholate has been compared with the native structure. X-ray and electron diffraction photographs show a reduction in cell dimension from 62.4 to 57.3 A, and a substantial change in the distribution of diffraction intensity compared with the native specimens. Low-dose electron microscopy has been used to obtain a projected density map of lipid-depleted membranes. The projected structure shows that the deoxycholate treatment removes a boundary layer of lipid, which in the native form separates adjacent trimers of bacteriorhodopsin. The map also provides an improved estimate of the molecular envelope of the protein. A plausible arrangement for the lipid molecules in both the native and the lipid-depleted membranes is proposed, but the precise positions of individual molecules cannot yet be specified.

Stability of transmembrane regions in bacteriorhodopsin studied by progressive proteolysis

Proteinase K digestions of bacteriorhodopsin were carried out with the aim of characterizing the membrane-embedded regions of the protein. Products of digestions for two, eight or 24 hours were separated by high-pressure liquid chromotography. A computerized search procedure was used to compare the amino acid analyses of peptide-containing peaks with segments of the bacteriorhodopsin sequence. Molecular weight distributions of the products were determined by sodium dodecylsulfate-urea polyacrylamide gel electrophoresis. The structural integrity of the protein after digestion was monitored through the visible absorption spectrum, by X-ray diffraction of partially dried membranes, and by following release of biosynthetically-incorporated 3H leucine from the digested membranes. During mild proteolysis, bacteriorhodopsin was cleaved near the amino and carboxyl termini and at two internal regions previously identified as being accessible to the aqueous medium. Longer digestion resulted in cleavage at new sites. Under conditions where no fragments of bacteriorhodopsin larger than 9000 mol wt were observed, a significant proportion of the digested membranes retained diffraction patterns similar to those of native purple membranes. The harshest digestion conditions led to complete loss of the X-ray diffraction patterns and optical absorption and to release of half the hydrophobic segments of the protein from the membrane in the form of small soluble peptides. Upon cleavage of aqueous loop regions of the protein, isolated transmembrane segments may experience motion in a direction perpendicular to the plane of the membrane, allowing them access to protease.

A neutron diffraction study on the location of the polyene chain of retinal in bacteriorhodopsin

We report on the location of the chain part of the retinylidene chromophore in the projected density of bacteriorhodopsin as determined by neutron diffraction from the two-dimensional purple membrane lattice. For this purpose, partially deuterated retinal was synthesized containing 10 deuterons at positions C-8, C-10, C-12, C-14, C-19(3), and C-20(3) of the polyene chain. Two sets of dark-adapted samples were prepared in entirely different ways: (i) Deuterated retinal was incorporated biosynthetically during growth of the bacteria by using the mutant JW5, which is deficient in the synthesis of retinal. (ii) The chromophore was converted to retinal oxime, the resulting colorless apomembrane was regenerated with deuterated retinal, and the residual retinal oxime was removed by washing with bovine serum albumin. Characterization of these samples by x-ray diffraction, absorption, and flash spectroscopy showed that they were identical to native purple membrane samples as judged by these criteria. Fourier difference maps were calculated from the differences in inplane diffraction from the deuterated membranes and from protonated samples that were prepared in exactly the same way. At 8.7 A resolution, both maps show a single major peak at the same position with the center of mass of the labeled part of the chain (C-11) between helices 6 and 3 but closer to helix 6. It appears likely that the COOH-terminal helix G, to which retinal is attached at lysine-216, is either helix 2 or 6.

Light-driven protonation changes of internal aspartic acids of bacteriorhodopsin: an investigation by static and time-resolved infrared difference spectroscopy using [4-13C]aspartic acid labeled purple membrane

The molecular events during the photocycle of bacteriorhodopsin have been studied by the method of time-resolved and static infrared difference spectroscopy. Characteristic spectral changes involving the C=O stretching vibration of protonated carboxylic groups were detected. To identify the corresponding groups with either glutamic or aspartic acid, BR was selectively labeled with [4-13C]aspartic acid. An incorporation of ca. 70% was obtained. The comparison of the difference spectra in the region of the CO2- stretching vibrations of labeled and unlabeled BR indicates that ionized aspartic acids are influenced during the photocycle, the earliest effect being observed already at the K610 intermediate. Taken together, the results provide evidence that four internal aspartic acids undergo protonation changes and that one glutamic acid, remaining protonated, is disturbed. The results are discussed in relation to the various aspects of the proton pumping mechanism, such as retinal isomerization, charge separation, pK changes, and proton pathway.

The C-terminus of bacteriorhodopsin is a random coil

The 21 amino acids which can be selectively removed from the carboxyl terminus of bacteriorhodopsin by proteolytic treatment are disordered in 2-dimensional arrays of the protein present in purple membranes. This C-terminal portion of the molecule may be involved in the efficiency and rate of light-driven proton uptake, although its presence is not required for pumping activity. In this study, the secondary structure of the C-terminus of bacteriorhodopsin has been determined by examining circular dichroism (CD) difference spectra derived from native and digested samples. In low ionic strength media, this part of the molecule appears to form a random coil-like structure. To examine if this structure is related to the structure found under the high ionic strength condition present in halobacteria, the CD spectra of native purple membranes in water and in 4 M salt solutions were compared. They were found to be identical, suggesting the conformation of the C-terminus in vivo may also be a random coil.

Location of an extrinsic label in the primary and tertiary structure of bacteriorhodopsin

We located a heavy metal label, mercurilated phenylglyoxal, in both the primary sequence and in the tertiary structure of bacteriorhodopsin. This label modified arginines 225 and 227, which are on the COOH-terminal helix (G). In the projected electron potential difference map, the major site is close to the central inner helix. From this result we conclude that helix 1 could not be the COOH-terminal helix G. We tested the multiple isomorphous replacement method for obtaining phases for purple membrane by electron diffraction.

Solid-state 13C NMR studies of retinal in bacteriorhodopsin

Solid-state 13C magic-angle sample spinning (MASS) NMR has been used to study lyophilized dark-adapted purple membrane containing 13C-labeled retinals. C-10-, C-11-, and C-12-labeled derivatives each showed two lines, assigned to the coexisting 13-cis and all-trans isomers. The isotropic chemical shifts, particularly of C-11, indicate that the Schiff base is protonated. Shift anisotropies are also similar to those of model compounds, indicating that this part of the chromophore is rigid and immobile and possesses the same degree of in-plane bending as crystalline retinal derivatives. Purple membrane samples labeled on the C-19- and C-20-methyl groups both give single lines from the retinal, upfield shifted by 2.1 and 1.0 ppm, respectively, from model compounds. In all cases, high-quality spectra were obtained from approximately 50-mg samples in modest signal-averaging times. These results suggest that it is now practical to exploit the enormous potential of MASS NMR for structural studies of 13C-labeled membrane proteins.

Light activates rotations of bacteriorhodopsin in the purple membrane

To investigate how a photoactivated chromophore drives the proton pump mechanism of bacteriorhodopsin, we have observed how the chromophore rotates during the photocyle. To do this, we examined the dichroism induced in aqueous suspensions of purple membrane fragments by flashes of linearly polarized light. We find that the flash stimulates both the photocycling chromophores and their noncycling neighbors to undergo large (greater than 10 degrees - 20 degrees) rotations within the membrane during the photocycle, and that these two chromophore populations undergo distinctly different sequences of rotations. All these rotations could be eliminated by glutaraldehyde fixation as well as by embedding unfixed fragments in polyacrylamide or agarose gels. Thus, in these immbolizing preparations the chromophore can photocycle without rotating inside a bacteriorhodopsin monomer by more than our detection limit of 2 degrees - 5 degrees. The large rotations we observed in aqueous suspensions of purple membranes were probably due to rotations of entire protein monomers. The process by which a photocycling monomer causes its noncycling neighbors to rotate may help explain the highly cooperative behavior bacteriorhodopsin exhibits when it is aggregated into crystalline arrays of trimers.