Time-resolved resonance Raman characterization of the bO640 intermediate of bacteriorhodopsin. Reprotonation of the Schiff base.

The resonance Raman spectrum of photolyzed bacteriorhodopsin under conditions known to increase the concentration of the bO640 intermediate in both H2O and D2O is presented. By use of computer subtraction techniques and a knowledge of the Raman spectra of the unphotolyzed bacteriorhodopsin as well as the other intermediates in the cycle, a qualitative spectrum of bO640 is determined. The shift of a band at 1630 cm-1 in H2O to 1616 cm-1 in D2O suggests that the Schiff base of bO640 is protonated. Additional bands at 947, 965, and 992 cm-1 that appear only in D2O suspensions confirm that a proton is coupled to the retinal chromophore of bO640. The reprotonation of the Schiff base thus occurs during the bM412 to bO640 step. The fingerprint region, sensitive to the isomeric configuration of the retinal chromophore of bO640, is dissimilar to the fingerprint regions of published model compounds and other forms of bacteriorhodopsin.     

Time-resolved ultraviolet resonance Raman studies of protein structure: application to bacteriorhodopsin.

Time-resolved ultraviolet resonance Raman spectra of bacteriorhodopsin are used to study protein structural changes on the nanosecond and millisecond time scales. Excitation at 240 nm is used to selectively enhance vibrational scattering from tyrosine so that changes in its hydrogen bonding and protonation state can be examined. Both nanosecond and millisecond UV Raman difference spectra indicate that none of the tyrosine residues change ionization state during the BR----K and BR----M transitions. However, intensity changes are observed at 1172 and 1615 cm-1 in the BR----M UV Raman difference spectra. The 1615-cm-1 feature shifts down 25 cm-1 in tyrosine-d4-labeled BR, consistent with its assignment as a tyrosine vibration. The intensity changes in the BR----M UV Raman difference spectra most likely reflect an increase in resonance enhancement that occurs when one or more tyrosine residues interact more strongly with a hydrogen-bond acceptor in M412. The frequency of the v7a feature (1172 cm-1) in the BR----M UV Raman difference spectra supports this interpretation. The proximity of Tyr-185 and Asp-212 in the retinal binding pocket suggests that deprotonation of the Schiff base in M412 causes Tyr-185 to stabilize ionized Asp-212 by forming a stronger hydrogen bond.     

Resonance raman spectroscopy of chemically modified and isotopically labelled purple membranes. II. Kinetic studies

Kinetic resonance Raman spectra of native and isotopically labelled purple membranes are compared. Using these data and the assignments of the previous paper in this sequence, we have confirmed that the Schiff base is deprotonated at times that are short in comparison to M₄₁₂ evolution. In addition, by monitoring the kinetic resonance Raman spectra in ²H₂O with 488.0 nm excitation we have been able to characterize in more detail the vibrational features associated with this unprotonated intermediate that precedes M₄₁₂. Furthermore, the kinetic spectra of fully deuterated purple membranes in H₂O have allowed us to assign the 1465 cm⁻¹ band in these spectra to the C=C stretching frequency of BR₅₇₀ and the 1512 cm⁻¹ band to the C=C stretching frequency of M₄₁₂. These spectra have also provided an indication of a Raman spectral feature associated with O₆₄₀ and, finally, our kinetic spectra have provided evidence that there is a significant alteration in the rate constants for the evolution of the various intermediates when the non-exchangeable protons on the membrane are replaced by deuterons.     

Bacteriorhodopsin's M412 intermediate contains a 13-cis, 14-s-trans, 15-anti-retinal Schiff base chromophore

The structure of the retinal chromophore about the C = N and C14-C15 bonds in bacteriorhodopsin's M412 intermediate has been determined by analyzing resonance Raman spectra of 2H and 13C isotopic derivatives. Normal mode calculations on 13-cis-retinal Schiff bases demonstrate that the C15-D rock and N-CLys stretch are strongly coupled for C = N-syn chromophores and weakly coupled for C = N-anti chromophores. When the Schiff base geometry is anti, the C15-D rock appears as a localized resonance Raman active mode at approximately 980 cm-1, which is moderately sensitive to 13C substitution at positions 14 and 15 (approximately 7 cm-1) and insensitive to 13C substitution at the epsilon position of lysine. When the Schiff base geometry is syn, in-phase and out-of-phase combinations of the C15-D rock and N-CLys stretch are predicted at approximately 1060 and approximately 910 cm-1, respectively. The in-phase mode is more sensitive to 13C substitution at positions 14 and 15 (approximately 15 cm-1) and at the epsilon position of lysine (approximately 4 cm-1). Calculations and comparison with experimental data on dark-adapted bacteriorhodopsin indicate that the in-phase mode at approximately 1060 cm-1 carries the majority of the resonance Raman intensity. M412 exhibits a C15-D rock at 968 cm-1 that shifts 8 cm-1 when 13C is added at positions 14 and 15 and is insensitive to 13C substitution at the epsilon-position of lysine. This demonstrates that M412 contains a C = N-anti Schiff base.(ABSTRACT TRUNCATED AT 250 WORDS)     

Photochemical cycle of bacteriorhodopsin studied by resonance Raman spectroscopy

Individual species of the photochemical cycle of bacteriorhodopsin, a retinal-protein complex of Halobacteria, were studied in aqueous suspensions of the "purple membrane" at room temperature by resonance Raman (RR) spectroscopy with flow systems. Two pronounced deuterium shifts were found in the RR spectra of the all-trans complex BR-570 in H2O-D2O suspensions. The first is ascribed to C=NH+ (C=ND+) stretching vibrations of the protonated Schiff base which links retinal to opsin. The second is assigned tentatively to an "X-H" ("X-D") bending mode, where "X" is an atom which carries an exchangeable proton. A RR spectrum of the 13-cis-retinal complex "BR-548" could be deduced from spectra of the dark-adapted purple membrane. The RR spectrum of the M-412 intermediate was monitored in a double-beam pump-probe experiment. The main vibrational features of the intermediate M' in the reaction M-412 in equilibrium hv M' leads to delta BR-570 could be deduced from a photostationary mixture of M-412 and M'. Difference procedures were applied to obtain RR spectra of the L-550 intermediate and of two new long-lived species, R1'-590 and R2-550. From kinetic data it is suggested that T1'-590 links the proton-translocating cycle to the "13-cis" cycle of BR-548. The protonation and isomeric states of the different species are discussed in light of the new spectroscopic and kinetic data. It is found that conformational changes during the photochemical cycle play an important role.     

Chromophore structure in bacteriorhodopsin's N intermediate: implications for the proton-pumping mechanism

By elevating the pH to 9.5 in 3 M KCl, the concentration of the N intermediate in the bacteriorhodopsin photocycle has been enhanced, and time-resolved resonance Raman spectra of this intermediate have been obtained. Kinetic Raman measurements show that N appears with a half-time of 4 +/- 2 ms, which agrees satisfactorily with our measured decay time of the M412 intermediate (2 +/- 1 ms). This argues that M412 decays directly to N in the light-adapted photocycle. The configuration of the chromophore about the C13 = C14 bond was examined by regenerating the protein with [12,14-2H]retinal. The coupled C12-2H + C14-2H rock at 946 cm-1 demonstrates that the chromophore in N is 13-cis. The shift of the 1642-cm-1 Schiff base stretching mode to 1618 cm-1 in D2O indicates that the Schiff base linkage to the protein is protonated. The insensitivity of the 1168-cm-1 C14-C15 stretching mode to N-deuteriation establishes a C = N anti (trans) Schiff base configuration. The high frequency of the C14-C15 stretching mode as well as the frequency of the 966-cm-1 C14-2H-C15-2H rocking mode shows that the chromophore is 14-s-trans. Thus, N contains a 13-cis, 14-s-trans, 15-anti protonated retinal Schiff base.(ABSTRACT TRUNCATED AT 250 WORDS)     

Resonance Raman microspectroscopy of myeloperoxidase and cytochrome b558 in human neutrophilic granulocytes.

With (resonance) Raman microscospectroscopy, it is possible to investigate the chemical constitution of a very small volume (0.5 fl) in a living cell. We have measured resonance Raman spectra in the cytoplasm of living normal, myeloperoxidase (MPO)-deficient, and cytochrome b558-deficient neutrophils and in isolated specific and azurophilic granule fractions, using an excitation wavelength of 413.1 nm. Similar experiments were performed after reduction of the redox centers by the addition of sodium dithionite. The specific and azurophilic granules in both redox states appeared to have clearly distinguishable Raman spectra when exciting at a wavelength of 413.1 nm. The azurophilic granules and the cytochrome b558-deficient neutrophils showed Raman spectra similar to that of the isolated MPO. The spectra of the specific granules and the MPO-deficient neutrophils corresponded very well to published cytochrome b558 spectra. The resonance Raman spectrum of the cytoplasmic region of normal neutrophilic granulocytes could be fitted with a combination of the spectra of the specific and azurophilic granules, which shows that the Raman signal of neutrophilic granulocytes mainly originates from MPO and cytochrome b558, at an excitation wavelength of 413.1 nm.     

The role of back-reactions and proton uptake during the N----O transition in bacteriorhodopsin's photocycle: a kinetic resonance Raman study

The kinetics of bacteriorhodopsin's photocycle have been analyzed at pH 5, 6, 7, 8, and 8.6 by using time-resolved resonance Raman spectroscopy. The concentrations of the various intermediates as a function of time were determined by following their resonance Raman intensities using 502-nm (L550, N550, BR568), 458-nm (M412), and 752-nm (O640) excitation. The spectral contributions to the pump + probe data from each intermediate were quantitatively separated by least-squares decomposition. These relative concentrations were then converted to absolute concentrations by using a conservation of molecules constraint. This enabled the unambiguous refinement of a variety of kinetic models to find the simplest one that accurately describes the data. The kinetic data, including the biphasic decay of L550 and M412, are best reproduced by a sequential scheme including back-reactions (BR----L----M----N----O----BR). In addition, the kinetics of the L----M and N----O steps are found to be pH-dependent. Both the forward and reverse rate constants connecting L550 and M412 increase with pH, confirming earlier proposals of catalyzed Schiff base deprotonation at alkaline pH. Below pH 7, the N550----O640 rate constant is independent of pH, but it decreases linearly with pH above 7. This indicates that the protein must pick up a proton during the N550----O640 transition and that this process becomes rate determining above pH 7. There must, therefore, be an intermediate between N550 and O640 which we denote as N+550. A molecular graphics model is presented which incorporates these observations into a mechanism for proton pumping.     

Haem-rotational disorder in monomeric allosteric cyano-Met insect haemoglobins monitored by resonance Raman spectroscopy

The haem-rotational disorder (insertion of haem into globin rotated about the alpha, gamma-meso axis by 180 degrees) has been investigated in the cyano-Met form of the monomeric allosteric insect haemoglobins, CTT III and CTT IV, by resonance Raman spectroscopy. The effect of haem disorder on the resonance Raman spectra has been observed in proto-IX, deutero-IX, and meso-IX CTTs. Most importantly, in the absence of overlapping vinyl vibrations, we have identified two Fe-C-N bending vibrations at 401 cm-1 and 422 cm-1 (pH 9.5) for 57Fe deutero-IX CTT IV ligated with 13C15N-, which are attributed to the two haem-rotational components. One Fe-C-N bending mode at 422 cm-1 shows a pH-induced shift to 424 cm-1 (pH 5.5) indicating the t----r conformational transition, whereas the other bending mode is pH-insensitive, representing a non-allosteric component. By replacing the unsymmetrical porphyrins with the "symmetrical" protoporphyrin-III we eliminate the haem disorder. Then, sharpening of the Fe-N epsilon(His) (at 313 cm-1) and Fe-CN (at 453 cm-1) stretching modes is observed and a single Fe-C-N bending mode (at 412 cm-1) appears. In cyano-Met proto-IX CTT III two vinyl bending vibrations at 412 cm-1 and 591 cm-1 assigned by deuteration of the vinyl groups also reflect the haem disorder. The 412 cm-1 vinyl vibration is intensity-enhanced via through-space coupling with one of the Fe-C-N bending modes (at 412 cm-1). In the cyano-Met form of proto-III CTT III this vinyl vibration is shifted to 430 cm-1 resulting in a dramatic drop in intensity. It is most likely that the specific vinyl-protein interaction at position 4 in one of the haem-rotational components is the origin of the coupling between the Fe-C-N and vinyl bending modes. The Fe-N epsilon(proximal His) and the Fe-CN stretching vibrations as well as the Fe-C-N bending vibration have been identified by 54Fe/57Fe and 13C15N/12C15N/13C14N/12C14N isotope exchange.     

Identification of enzyme coupling sites with aromatic diazonium salts-a resonance raman study.

The coupling reaction of diazonium salts of aromatic compounds with the aromatic residues of proteins results in chromophoric covalent derivatives which yield strong resonance enhanced Raman spectra. The protein residues modified by these coupling reactions have been identified using the ν(NN) and ν(N-φ) vibrational bands in the resonance Raman spectra. Previous studies have established that diazoarsanilic acid couples with carboxypeptidase at tyrosine 248. The resonance Raman spectrum of arsanilazocarboxypeptidase was compared with spectra of arsanilazotyrosine and arsanilazohistidine model compounds; the results are consistent only with coupling at a tyrosine residue. This confirmation of the previously established site of modification establishes the utility of resonance Raman spectroscopy as a tool for identification of the site of covalent modification. To further investigate this approach, the diazonium salt of sulfanilamide (a site-specific reagent) was used to prepare a covalent coupling derivative of bovine carbonic anhydrase. The coupling reaction appears to have a stoichiometry of 1:1 and results in nearly complete loss of sulfanilamide binding capability and esterase activity. Comparison of the pH dependence of the resonance Raman spectra of sulfanilazocarbonic anhydrase with the spectra of sulfanilazotyrosine, sulfanilazohistidine, and sulfanilazotryptophan suggests that histidine is the site of modification of this new carbonic anhydrase derivative.     

In situ mapping of nitrifiers and anammox bacteria in microbial aggregates by means of confocal resonance Raman microscopy

In the present work the exploration of microbial communities by confocal resonance Raman microscopy (CRRM) is reported. Using the resonance Raman effect of cytochrome c (Cyt c) we were able to record the microbial distribution of nitrifiers and anammox bacteria directly in their natural environment without the need of sample preparation. For this new non-invasive investigation a reference database of bacteria assumed to be found in microbial aggregates obtained from biological wastewater treatment was created. Reference spectra of enriched cultures of the interesting bacteria were taken by means of optical tweezers. Significant spectra were achieved in less than 1 s (excitation wavelength 532 nm, laser power 9 mW) due to the resonance Raman effect. In addition, the impact of different parameters on the reference spectra, such as integration time and culture conditions, was analysed. We successfully demonstrate the grouping of bacteria down to strain level based on the heterogeneity of the resonance Raman spectra of the heme protein Cyt c.     

Resonance Raman assignment and evidence for noncoupling of individual 2- and 4-vinyl vibrational modes in a monomeric cyanomethemoglobin

We have investigated the resonance Raman spectra of monomeric insect cyanomethemoglobins (CTT III and CTT IV) reconstituted with (1) protohemes IX selectively deuterated at the 4-vinyl as well as the 2,4-divinyls, (2) monovinyl-truncated hemes such as pemptoheme (2-hydrogen, 4-vinyl) and isopemptoheme (2-vinyl, 4-hydrogen), (3) symmetric hemes such as protoheme III (with 2- and 3-vinyls) and protoheme XIII (with 1- and 4-vinyls), and (4) hemes without 2- and 4-vinyls such as mesoheme IX, deuteroheme IX, 2,4-dimethyldeuteroheme IX, and 2,4-dibromodeuteroheme IX. Evidence is presented that the highly localized vinyl C = C stretching vibrations at the 2- and 4-positions of the heme in these cyanomet CTT hemoglobins are noncoupled and inequivalent; i.e., the 1631- and 1624-cm-1 lines have been assigned to 2-vinyl and 4-vinyl, respectively. The elimination of the 2-vinyl (in pemptoheme) or the 4-vinyl (in isopemptoheme) does not affect the C = C stretching frequency of the remaining vinyl. Furthermore, two low-frequency vinyl bending modes at 412 and 591 cm-1 exhibit greatly different resonance Raman intensities between 2-vinyl and 4-vinyl. The observed intensity at 412 cm-1 is primarily derived from 4-vinyl, whereas the 591-cm-1 line results exclusively from the 2-vinyl. Again, there is no significant coupling between 2-vinyl and 4-vinyl for these two bending modes.     

Determination of retinal chromophore structure in bacteriorhodopsin with resonance Raman spectroscopy

The analysis of the vibrational spectrum of the retinal chromophore in bacteriorhodopsin with isotopic derivatives provides a powerful "structural dictionary" for the translation of vibrational frequencies and intensities into structural information. Of importance for the proton-pumping mechanism is the unambiguous determination of the configuration about the C13=C14 and C=N bonds, and the protonation state of the Schiff base nitrogen. Vibrational studies have shown that in light-adapted BR568 the Schiff base nitrogen is protonated and both the C13=C14 and C=N bonds are in a trans geometry. The formation of K625 involves the photochemical isomerization about only the C13=C14 bond which displaces the Schiff base proton into a different protein environment. Subsequent Schiff base deprotonation produces the M412 intermediate. Thermal reisomerization of the C13=C14 bond and reprotonation of the Schiff base occur in the M412------O640 transition, resetting the proton-pumping mechanism. The vibrational spectra can also be used to examine the conformation about the C--C single bonds. The frequency of the C14--C15 stretching vibration in BR568, K625, L550 and O640 argues that the C14--C15 conformation in these intermediates is s-trans. Conformational distortions of the chromophore have been identified in K625 and O640 through the observation of intense hydrogen out-of-plane wagging vibrations in the Raman spectra (see Fig. 2). These two intermediates are the direct products of chromophore isomerization. Thus it appears that following isomerization in a tight protein binding pocket, the chromophore cannot easily relax to a planar geometry. The analogous observation of intense hydrogen out-of-plane modes in the primary photoproduct in vision (Eyring et al., 1982) suggests that this may be a general phenomenon in protein-bound isomerizations. Future resonance Raman studies should provide even more details on how bacterio-opsin and retinal act in concert to produce an efficient light-energy convertor. Important unresolved questions involve the mechanism by which the protein catalyzes deprotonation of the L550 intermediate and the mechanism of the thermal conversion of M412 back to BR568. Also, it has been shown that under conditions of high ionic strength and/or low light intensity two protons are pumped per photocycle (Kuschmitz & Hess, 1981). How might this be accomplished?(ABSTRACT TRUNCATED AT 400 WORDS)     

Resonance Raman investigations of cytochrome c conformational change upon interaction with the membranes of intact and Ca2+-exposed mitochondria

The conformational states of cytochrome c inside intact and Ca(2+)-exposed mitochondria have been investigated using resonance Raman spectroscopy. Intact and swelling bovine heart and rat liver mitochondria were examined with an excitation wavelength (413.1 nm) in resonance with the Soret transition of ferrous cytochrome c. The different b- to c-type cytochrome concentration ratio in mitochondria from two different tissues was used to help assign the Raman spectral components. Resonance Raman spectra were also recorded for mitochondria fractions (supernatants and pellets) obtained from swollen (Ca(2+)-exposed) mitochondria after differential centrifugation. The results illustrate that cytochrome c has an altered vibrational spectrum in solution, in intact, and in swollen mitochondria. When cytochrome c is released from mitochondria, its Raman spectrum becomes identical to that of ferrous cytochrome c in solution. The spectra of mitochondrial pellets indicate that a small amount of structurally modified cytochrome c remains associated with the heavy membrane fraction. Indeed, spectroscopic shifts in the low-frequency fingerprint and the high-frequency marker-band regions suggest that membrane binding leads to a partial opening of the heme pocket and an alteration of the heme thioether bonds. The results support the conclusion that most cytochrome c molecules in mitochondria are membrane-bound and that the cytochrome c structure changes upon binding. Furthermore, changes in the resonance Raman active mode located at 675 cm(-)(1) in the spectra of intact, swollen, and fractionated mitochondria indicate that b-type cytochromes may also undergo structural alterations during mitochondrial swelling and disruption.     

Surface-enhanced resonance Raman spectroscopy of phycocyanin and allophycocyanin

High quality surface-enhanced resonance Raman (SERR) spectra were recorded from native and denatured phycocyanin and allophycocyanin on ascorbic acid treated silver hydrosols. The visible-excited SERR and resonance Raman (RR) spectra of the phycobiliproteins were very similar, indicating a predominantly electromagnetic surface enhancement mechanism. Investigation of pH-induced denaturation ofx allophycocyanin has shown that even small differences in protein/chromophore conformational are sensitively reflected by the SERR spectra. Concerning the adsorption of the protein to the metal surface, the experiments have shown that: (i) there is limited possibility for changing protein conformation during the adsorption process, (ii) there are no changes after the protein has been adsorbed onto the silver surface and (iii) for each protein an optimal activation of the silver sol has to be found for recording proper SERR spectra. The results obtained on phycobiliproteins are also discussed in connection with the interpretation of phytochrome Raman spectra.     

Resonance Raman study of intermediates of the halorhodopsin photocycle

The resonance Raman (RR) study of the retinal protein halorhodopsin (HR₅₇₈) was extended to two of its photoproducts: HR and HR^L₄₁₀ RR spectra of both species were recorded in H₂O and D₂O and compared with the RR spectra of the intermediates L₅₅₀ and M₄₁₂ from the bacteriorhodopsin photocycle. HR₅₂₀ was found to be a protonated Schiff base in the 13-cis configuration and HR^L₄₁₀ a deprotonated Schiff base in the 13-cis configuration.     

Investigation of higher order structures of proteins by ultraviolet resonance Raman spectroscopy.

Progress in laser technology and light detection devices have enabled us to explore protein structures and their dynamics by using time-resolved resonance Raman spectroscopy. It is in the last decade that Raman spectra of proteins excited at 200-240 nm have brought about rich structural information. The technological developments in deep UV resonance Raman spectroscopy are reviewed first, and the unique information on proteins obtainable from such spectra are summarized. As an application of this technique to investigations of the higher order structures of proteins, studies on the quaternary structure transition of haemoglobin are described.     

Comparison of the substrate conformations in the active sites of papain, chymopapain, ficin and bromelain by resonance Raman spectroscopy

The resonance Raman spectra of several enzyme-substrate intermediates of papain, chymopapain, ficin and bromelain are reported. The intermediates are dithioacyl enzymes formed during the catalyzed hydrolysis of N-acylglycine thionoester substrates. Interpretation of the resonance Raman spectra allows us to compare, for the first time, the substrate geometries in a series of functioning intermediates from different enzymes. The substrates assume essentially identical conformations for papain, chymopapain and ficin and a similar, but not identical, conformation in the active site of bromelain. Each dithioacyl enzyme population appears to be made up of a single homogeneous conformational state. This state has been characterised in earlier studies of dithioacyl papains. It is designated as conformer B and is characterized by an attractive contact between the substrate's glycinic N atom and the active site cysteine S atom. It is now apparent that conformer B is of general significance in the mechanism of cysteine proteases.     

Resonance raman spectroscopy of iron (3)--ovotransferrin and iron (3)--human serum transferrin

We report the resonance Raman spectra in the frequency range 300–1800 cm^?1 of Fe (III)-ovotransferrin and Fe (III)-human serum transferrin in aqueous solution at about 10^?4M protein concentration. This is the first observation of resonance Raman scattering ascribable to amino acid ligand vibrational modes of a nonheme iron protein. The resonance Raman spectra of the transferrins are similar except that the resonance band near 1270 cm^?1 is shifted to a higher frequency for Fe(III)-human serum transferrin than that for Fe(III)-ovotransferrin. The resonance Raman bands observed near 1170, 1270, 1500 and 1600 cm^?1 may reflect resonance enhancement of p-hydroxy-phenyl frequencies of tyrosine residues and/or imidazolium frequencies of histidine residues.