Sex differences in (-)-pentazocine antinociception: comparison to morphine and spiradoline in four rat strains using a thermal nociceptive assay.

The present study examined the influence of sex on the antinociceptive effects of (-)-pentazocine, morphine and spiradoline in four rat strains, using a warm-water (50, 52 and 55 degrees C) tail-withdrawal procedure. In F344, Lewis, Sprague-Dawley (SD) and Wistar rats, baseline latencies decreased with increases in water temperature, and at each water temperature latencies were longer in males than in their female counterparts. Morphine and spiradoline produced maximal or near maximal antinociceptive effects in males and females of each strain. Whereas morphine was generally more potent in males, sex differences were not consistently observed with spiradoline. In contrast, there were marked sex differences with (-)-pentazocine, and in each strain (-)-pentazocine was more potent and produced a greater maximal effect in males. The magnitude of the sex differences varied markedly across strains, with (-)-pentazocine being 2.5-fold more potent in males of the F344 strain, but 11-fold more potent in males of the Wistar strain. When collapsed across nociceptive stimulus intensities, sex differences were largest in the Wistar and Lewis strains and smallest in the SD and F344 strains. The present findings indicate that there are marked sex differences in (-)-pentazocine antinociception, and that the magnitude of this effect is genotype dependent.

Spectroscopic studies of peroxyacetic acid reaction intermediates of cytochrome P450cam and chloroperoxidase.

It is generally assumed that the putative compound I (cpd I) in cytochrome P450 should contain the same electron and spin distribution as is observed for cpd I of peroxidases and catalases and many synthetic cpd I analogues. In these systems one oxidation equivalent resides on the Fe(IV)=O unit (d(4), S=1) and one is located on the porphyrin (S'=1/2), constituting a magnetically coupled ferryl iron-oxo porphyrin pi-cation radical system. However, this laboratory has recently reported detection of a ferryl iron (S=1) and a tyrosyl radical (S'=1/2), via Mössbauer and EPR studies of 8 ms-reaction intermediates of substrate-free P450cam from Pseudomonas putida, prepared by a freeze-quench method using peroxyacetic acid as the oxidizing agent [Schünemann et al., FEBS Lett. 479 (2000) 149]. In the present study we show that under the same reaction conditions, but in the presence of the substrate camphor, only trace amounts of the tyrosine radical are formed and no Fe(IV) is detectable. We conclude that camphor restricts the access of the heme pocket by peroxyacetic acid. This conclusion is supported by the additional finding that binding of camphor and metyrapone inhibit heme bleaching at room temperature and longer reaction times, forming only trace amounts of 5-hydroxy-camphor, the hydroxylation product of camphor, during peroxyacetic acid oxidation. As a control we performed freeze-quench experiments with chloroperoxidase from Caldariomyces fumago using peroxyacetic acid under the identical conditions used for the substrate-free P450cam oxidations. We were able to confirm earlier findings [Rutter et al., Biochemistry 23 (1984) 6809], that an antiferromagnetically coupled Fe(IV)=O porphyrin pi-cation radical system is formed. We conclude that CPO and P450 behave differently when reacting with peracids during an 8-ms reaction time. In P450cam the formation of Fe(IV) is accompanied by the formation of a tyrosine radical, whereas in CPO Fe(IV) formation is accompanied by the formation of a porphyrin radical.

Relative reinforcing effects of three opioids with different durations of action.

The role of duration of action on the relative reinforcing effects of three opioid drugs (fentanyl, alfentanil, and remifentanil) was evaluated. Duration and onset of action were determined using measures of respiratory depression and antinociception after i.v. administration. Effects on minute volume of respiration indicated that each of the three opioids had immediate onsets of action after i.v. administration. Fentanyl's duration of suppression of respiration and antinociception was longer than that of alfentanil, which was longer than that of remifentanil. Reinforcing strength was measured in i.v. self-administration studies in which the fixed ratio resulting in drug administration was increased from one session to the next. Comparisons were made of the behavioral economic variables P(max) and area under the demand curve (O(max)). Remifentanil maintained higher rates of responding than did alfentanil, and alfentanil maintained higher rates of responding than did fentanyl. When normalized demand functions were compared, however, the drugs did not differ significantly from each other in terms of P(max) or O(max). These data agree with those of others who have suggested that duration of action is not an important contributor to drugs' reinforcing strength.

Valence-tautomerism in high-valent iron and manganese porphyrins.

Iron and manganese hemes are "high-valent" when the valence state of the metal exceeds III. Redox chemistry of the high valent metal complexes involves redistribution of holes and electrons over the metal ion and the porphyrin and axial ligands, defined as valence tautomerism. Thus, catalytic pathways of heme-containing biomolecules such as peroxidases, catalases and cytochromes P450 involve valence tautomerism, as do pathways of biomimetic oxygen transfer catalysis by manganese porphyrins, robust catalysts with potential commercial value. Determinants of the site of electron abstraction are key to understanding valence tautomerism. In model systems, metal-centered oxidation is supported by hard anionic axial ligands that are also strongly pi-donating, such as oxo, aryl, bix-methoxy and bis-fluoro groups. Manganese(IV) is more stable than iron(IV) and metal-centered one-electron oxidations occur with weaker pi-donating axial ligands such as bisazido, -isocyanato, -hypochlorito and bis chloro groups. Virtually all known high-valent iron porphyrin complexes oxidized by two-electrons above the ferric state are coordinated by the strongly pi-donating oxo or nitrido ligands. In all well-characterized oxo complexes, iron is in the ferryl state and the second oxidizing equivalent resides on the porphyrin. Complexes with iron(V) have not been definitively characterized. One-electron oxidation of oxomanganese(IV) porphyrin complexes gives the oxomanganese(IV) porphyrin pi-cation redicals. In aqueous solution, oxidation of Mn(III) complexes of tetra cationic N-methylpyridiniumylporphyrin isomers by monooxygen donors yields a transient oxomanganese(V) species.

Importance of sex and relative efficacy at the mu opioid receptor in the development of tolerance and cross-tolerance to the antinociceptive effects of opioids.

RATIONALE: Recent studies indicate that mu opioids are generally more potent and effective as antinociceptive agents in male than female rodents. OBJECTIVES: To evaluate the influence of sex on the development of tolerance to the antinociceptive effects of morphine and cross-tolerance to the lower efficacy mu opioids buprenorphine and dezocine in F344 and Lewis rats. METHODS: Using a warm-water tail-withdrawal procedure, the antinociceptive effects of morphine, buprenorphine and dezocine were determined before and during chronic morphine (5, 10 and 20 mg/kg, b.i.d., for 7 and 14 days) administration. RESULTS: Under acute conditions, morphine was more potent in males and during chronic morphine administration tolerance development was generally greater in males. As males were more sensitive to the acute effects of morphine, the functional chronic morphine dose (i.e., chronic morphine dose/acute morphine ED50) administered to males was larger than in females. Analyses of the relationship between the functional chronic morphine dose and tolerance indicated that morphine tolerance development was comparable in males and females. Under acute conditions, buprenorphine and dezocine were more potent and effective in males. During chronic morphine administration, cross-tolerance was conferred to these opioids as evidenced by rightward, and in some cases downward, shifts in their dose-effect curves. Decreases in the maximal effects produced by buprenorphine and dezocine were more frequently observed in females. CONCLUSIONS: That comparable levels of morphine tolerance were obtained in males and females when the functional chronic morphine dose was taken into consideration suggests that the mechanism underlying tolerance is not sex-dependent. Sex differences in the effectiveness of buprenorphine and dezocine when administered acutely and during chronic morphine administration further suggest that these opioids have lower efficacy at the mu opioid receptor in females.

Stereochemistry of the chloroperoxidase active site: crystallographic and molecular-modeling studies.

BACKGROUND: Chloroperoxidase (CPO) is the most versatile of the known heme enzymes. It catalyzes chlorination of activated C-H bonds, as well as peroxidase, catalase and cytochrome P450 reactions, including enantioselective epoxidation. CPO contains a proximal heme-thiolate ligand, like P450, and polar distal pocket, like peroxidase. The substrate-binding site is formed by an opening above the heme that enables organic substrates to approach the activated oxoferryl oxygen atom. CPO, unlike other peroxidases, utilizes a glutamate acid-base catalyst, rather than a histidine residue. RESULTS: The crystal structures of CPO complexed with exogenous ligands, carbon monoxide, nitric oxide, cyanide and thiocyanate, have been determined. The distal pocket discriminates ligands on the basis of size and pKa. The refined CPO-ligand structures indicate a rigid active-site architecture with an immobile glutamate acid-base catalyst. Molecular modeling and dynamics simulations of CPO with the substrate cis-beta methylstyrene and the corresponding epoxide products provide a structural and energetic basis for understanding the enantioselectivity of CPO-catalyzed epoxidation reactions. CONCLUSIONS: The various CPO-ligand structures provide the basis for a detailed stereochemical mechanism of the formation of the intermediate compound I, in which Glu183 acts as an acid-base catalyst. The observed rigidity in the active site also explains the relative instability of CPO compound I and the formation of the HOCI chlorinating species. Energetics of CPO-substrate/ product molecular modeling provides a theoretical basis for the P450-type enantioselective epoxidation activities of CPO.

Compound I and Compound II Analogues from Porpholactones.

The tetraaza macrocycles 2-oxa-3-oxotetramesitylporphine (|H(2) 1|) and 2-oxa-3-oxotetrakis(2,6-dichlorophenyl)porphine (|H(2) 2|) and the corresponding iron complexes (|Fe(III)(X) 1| and |Fe(III)(X) 2|; X= Cl(-), OH(-), or SO(3)CF(3)(-)) have been synthesized. These macrocycles are derived from porphyrins by transformation of one pyrrole ring to an oxazolone ring. The resulting lactone functionality serves to restrict but not completely block pi-conjugation around the periphery. These complexes thus share properties with both porphyrins and chlorins. The ferric and high-valent iron complexes have been characterized by a variety of spectroscopic techniques. The molecular structure of |Fe(III)(Cl) 2| has been obtained by X-ray crystallography and shows that the structural changes at the macrocycle periphery do not perturb the coordination sphere of iron relative to the corresponding porphyrin complexes. This is illustrated by the observation that Fe-O frequencies in the resonance Raman spectra of the porpholactone analogues of compounds I and II are not substantially different from those of porphyrins and by the axial appearance of the EPR signals of the high-spin ferric complexes. This is consistent with reports that the Fe=O unit of oxidized porphyrins and chlorins is relatively insensitive to alteration of macrocycle symmetry. Nevertheless, probes of properties of the porpholactone macrocycle ((1)H NMR, resonance Raman skeletal modes) show effects of the asymmetry induced by the oxazolone ring. On the basis of (1)H NMR, EPR, Mössbauer, and resonance Raman data, the singly occupied molecular orbital of oxoferryl porpholactone pi-cation radicals correlates with the a(1u) molecular orbital of porphyrins under D(4)(h)() symmetry. Moreover, the paramagnetic properties and the intramolecular exchange interaction of ferryl iron and the porpholactone pi-radical have been characterized by EPR and magnetic Mössbauer measurements and spin-Hamiltonian analyses. The values J(0) = 17 cm(-)(1) and J(0) = 11 cm(-)(1) obtained for the exchange coupling constants of the oxoferryl porpholactone pi-cation radical complexes |Fe(IV)=O 1|(+) and |Fe(IV)=O 2|(+), respectively, are among the lowest found for synthetic compound I analogues.

Influence of Meso Substituents on Electronic States of (Oxoferryl)porphyrin pi-Cation Radicals.

A series of (oxoferryl)porphyrin pi-cation radicals generated from porphyrins substituted at the meso positions with highly electron-withdrawing aryl groups has been characterized: tetrakis-5,10,15,20-(2,6-dichlorophenyl)-, 5-(2-chloro-6-nitrophenyl)-10,15,20-tris(2,6-dichlorophenyl)-, and 5-(2,6-dinitrophenyl)-10,15,20-tris(2,6-dichlorophenyl)porphyrins (porphyrins 1-3, respectively). The physical-chemical properties of the oxidized complexes of 1-3 are compared to those of two (oxoferryl)porphyrin pi-cation radical complexes substituted with electron-releasing aryl groups: tetramesitylporphyrin (TMP) and 2-iodotetramesitylporphyrin (2-iodoTMP). While all of the complexes examined show close correspondance in a number of spectroscopic parameters, some significant differences were observed. In contrast to observations for the oxidized complexes of TMP and 2-iodoTMP, the resonance Raman marker bands nu(2) and nu(11), which are indicators of symmetry state of porphyrin pi-cation radicals of 1-3, do not show the expected downfrequency shifts for oxidation to compound I analogs in a(2u) symmetry states. The upfield hyperfine NMR shifts of the pyrrole beta-proton signals of the compound I analogs of 1-3 are much larger than those for TMP and 2-iodoTMP. These data may be explained by admixture of some a(1u) character into the ground state of radical cations of 1-3, consistent with the hypothesis that electron-withdrawing meso substituents lower the energy of the a(2u) molecular orbital, favoring an a(1u) admixture.

The crystal structure of chloroperoxidase: a heme peroxidase--cytochrome P450 functional hybrid.

BACKGROUND: Chloroperoxidase (CPO) is a versatile heme-containing enzyme that exhibits peroxidase, catalase and cytochrome P450-like activities in addition to catalyzing halogenation reactions. The structure determination of CPO was undertaken to help elucidate those structural features that enable the enzyme to exhibit these multiple activities. RESULTS: Despite functional similarities with other heme enzymes, CPO folds into a novel tertiary structure dominated by eight helical segments. The catalytic base, required to cleave the peroxide O-O bond, is glutamic acid rather than histidine as in other peroxidases. CPO contains a hydrophobic patch above the heme that could be the binding site for substrates that undergo P450-like reactions. The crystal structure also shows extensive glycosylation with both N- and O-linked glycosyl chains. CONCLUSIONS: The proximal side of the heme in CPO resembles cytochrome P450 because a cysteine residue serves as an axial heme ligand, whereas the distal side of the heme is 'peroxidase-like' in that polar residues form the peroxide-binding site. Access to the heme pocket is restricted to the distal face such that small organic substrates can interact with the iron-linked oxygen atom which accounts for the P450-like reactions catalyzed by chloroperoxidase.

Preliminary crystallographic analysis of chloroperoxidase from Caldariomyces fumago.

Chloroperoxidase from the fungus Caldariomyces fumago has been crystallized in two space groups, C222(1) and P2(1)2(1)2(1) both of which are suitable for high-resolution X-ray studies. Parent data sets have been obtained to 2.16 A in space group C222(1) and 2.00 A in space group P2(1)2(1)2(1). Heavy-atom derivatives have been obtained with both forms and electron-density maps calculated. The heme has been located and continuous electron density between the heme and protein clearly indicates the location of the proximal ligand.

Design of remote control units for seniors.

HumRRO International, Inc. conducted a project to improve the human factors aspects of remote control unit (RCU) design. Although the research was oriented toward RCUs for future telerobots that older adults may use, the RCUs examined were currently available models. An observational study found that a sample of 18 persons aged 65-88 years made errors in performing a simple arithmetic task with four different handheld calculators and that 13 participants made errors operating 11 VCR remotes. Better human-machine designs in RCUs appear to be needed to reduce errors that might cause accidents in the future use of mobile telerobots and their manipulators. In addition, manufacturers of RCUs, gerontologists, and members of SeniorNet, a network of older adults interested in computers, were queried regarding the design of RCUs. The responses of these individuals and the participants in the observational study, together with human factors engineering analyses, suggested numerous design improvements that may be systematically examined.

Resonance Raman spectroscopy of the catalytic intermediates and derivatives of chloroperoxidase from Caldariomyces fumago.

Near-ultraviolet resonance Raman spectra of chloroperoxidase derivatives and high valent intermediates show frequencies that can be systematically assigned. In accord with previous observations of low v4 frequencies for the ferric enzyme, and quite low v4 frequencies for the ferrous enzyme, low v4 frequencies are observed for ferryl compound II and several ferric derivatives. Resonance Raman spectra of chloroperoxidase compound I feature upshifted v2, v11, and v37 frequencies and other characteristics that argue for a 2A1u in preference to a 2A2u ground state for the porphyrin phi-cation radical. A moderately intense anomalously polarized band is observed at a frequency typical for octaethylporphyrin phi-cation radicals, which have been previously assigned as the 2A1u radical type. Similar resonance Raman spectral attributes are observed for horseradish peroxidase compound I, supporting a 2A1u symmetry state assignment for this species also. A 2A1u symmetry state assignment for chloroperoxidase and horseradish peroxidase compounds I is consistent with the beta-pyrrole substituent pattern of the protoporphyrin hemes found in these enzymes.

Resonance Raman spectroscopy of horseradish peroxidase derivatives and intermediates with excitation in the near ultraviolet.

Resonance Raman enhancement of derivatives and intermediates of horseradish peroxidase in the near ultraviolet (N-band excitation) results in intensity and enhancement patterns that are different from those normally observed within the porphyrin Soret (B-band) and alpha-beta (Q-band) absorptions. In particular it allows the resolution of resonance Raman spectra of horseradish peroxidase compound I. The bands above 1300 cm-1 can be assigned to porphyrin vibrational modes that are characteristically shifted in frequency due to removal of an electron from the porphyrin ring. The resonance Raman frequency shifts follow normal mode compositions. Relative to resonance Raman spectra of compound II, the v4 frequency (primarily Ca-N) exhibits a 20 cm-1 downshift. The v2, v11, and v37 vibrational frequencies whose mode compositions are primarily porphyrin Cb-Cb, exhibit 10-20 cm-1 upshifts. The v3, v10, and v28 frequencies, whose mode compositions are primarily Ca-Cm, exhibit downshifts. The downshifts for v3 and v10 are small, 3-5 cm-1; however, the downshift for v28 is 14 cm-1. These frequency shifts are consistent with those of previously published resonance Raman studies of model compounds. In contrast to reports from other laboratories, the data presented here for horseradish peroxidase compound I can be attributed unambiguously to resonance Raman scattering from a porphyrin pi-cation radical.

Comparative spectral analysis of mammalian, fungal, and bacterial catalases. Resonance Raman evidence for iron-tyrosinate coordination.

Resonance Raman spectra are reported for catalases from bovine liver, the ascomycete fungus Aspergillus niger, and the bacterium Micrococcus luteus. The vibrational frequencies of the oxidation-, spin-, and coordination number-sensitive spectral bands are indicative of high spin pentacoordinate hemes in the resting ferric enzymes of each of these organisms. This result is in accord with the crystal structure of bovine catalase (Fita, I., and Rossmann, M.G. (1985) J. Mol. Biol. 185, 21-37). In contrast, the crystallographic study of catalase from the ascomycete Penicillium vitale (Vainshtein, B. K., Melik-Adamyan, W. R., Barynin, V. V., Vagin, A.A., Grebenko, A. I., Borisov, V. V., Bartels, K. S., Fita, I., and Rossmann, M. G. (1986) J. Mol. Biol. 188, 49-61) showed electron density on the distal side of the heme which could imply the presence of a sixth ligand, possibly a water molecule. However, both of these crystallographic studies showed the proximal ligand in catalase to be a tyrosine. The present study confirms tyrosinate coordination in each of the three catalases from the appearance of selected resonance-enhanced tyrosine vibrational modes. The most characteristic band is the tyrosinate ring mode at approximately 1612 cm-1 which is maximally enhanced with 488.0 nm excitation. The appearance of tyrosinate modes at 1607 and 1245 cm-1 in the resonance Raman spectra of M. luteus cyano catalase serves to identify tyrosine as an axial ligand in bacterial as well as eukaryotic catalases. Unlike non-heme iron tyrosinate proteins, whose resonance Raman spectra are dominated by several intense bands diagnostic of tyrosine ligation, the heme-linked tyrosine modes are not easily distinguished from the large number of porphyrin vibrations.

Resonance Raman spectroscopic evidence for heme iron-hydroxide ligation in peroxidase alkaline forms.

Horseradish peroxidase will convert from a five-coordinate high-spin heme at neutral pH to a six-coordinate low-spin heme at alkaline pH. Though alkaline forms of other heme proteins such as hemoglobin and myoglobin are known to contain a heme-ligated hydroxide, alkaline horseradish peroxidase has been considered not to contain a ligated hydroxide. Several alternatives have been proposed which would be stronger field ligands than a hydroxide ion. In this report we provide resonance Raman evidence, using Soret excitation, that alkaline horseradish peroxidase does in fact contain a heme iron-ligated hydroxyl group. The band was located for isoenzymes C and A-1 by its sensitivity to 18O substitution and confirmed with 54Fe, 57Fe, and 2H. An isoenzyme of turnip peroxidase was investigated and found to also contain a ligated hydroxide at alkaline pH. The observed peroxidase Fe(III)-OH frequencies are 15-25 cm-1 higher than the corresponding frequencies of alkaline methemoglobin and metmyoglobin and correlate with changes in spin-state distribution. This is explained in the context of hydrogen bonding to a distal histidine which results in increased ligand field strength facilitating the formation of low-spin hemes. It has been demonstrated that the ferryl/ferric redox potential of horseradish peroxidase is markedly lowered at alkaline pH (Hayashi, Y., and Yamazaki, I. (1979) J. Biol. Chem. 254, 9101-9106). These observations are rationalized in terms of oxidation of a ligated ferric hydroxyl group facilitated through base catalysis by a distal histidine.

Comparison of the heme structures of horseradish peroxidase compounds X and II by resonance Raman spectroscopy.

Horseradish peroxidase will catalyze the chlorination of certain substrates by sodium chlorite through an intermediate known as compound X. A chlorite-derived chlorine atom is known to be retained by compound X and has been proposed to be located at the heme active site. Although several heme structures have been proposed for compound X, including an Fe(IV)-OCl group, preliminary data previously reported by our laboratory suggested that compound X contained a heme Fe(IV) = O group, based on the similarity of a compound X resonance Raman band at 788 cm-1 to resonance Raman Fe(IV) = O stretching vibrations recently identified for horseradish peroxidase compound II and ferryl myoglobin. Isotopic studies now confirm that the 788 cm-1 resonance Raman band of compound X is, in fact, due to a heme Fe(IV) = O group, with the oxygen atom derived from chlorite. The Fe(IV) = O frequency of compound X, of horseradish peroxidase isoenzymes B and C, undergoes a pH-induced frequency shift, with behavior which appears to be the same as that previously reported for compound II, formed from the same isoenzymes. These observations strongly suggest that compounds II and X have very similar, if not identical, heme structures. The chlorine atom thus appears not to be heme-bound and may rather be located on an amino acid residue. The studies on compound X reported here were done in a pH region above pH 8, where compound X is moderately stable. The present results do not necessarily apply to compound X below pH 8.

Heme-linked ionization of horseradish peroxidase compound II monitored by the resonance Raman Fe(IV)=O stretching vibration.

Fe(IV)=O resonance Raman stretching vibrations were recently identified by this laboratory for horseradish peroxidase compound II and ferryl myoglobin. In the present report it is shown that Fe(IV)=O stretching frequency for horseradish peroxidase compound II will switch between two values depending on pH, with pKa values corresponding to the previously reported compound II heme-linked ionizations of pKa = 6.9 for isoenzyme A-2 and pKa = 8.5 for isoenzyme C. Similar pH-dependent shifts of the Fe(IV)=O frequency of ferryl myoglobin were not detected above pH 6. The Fe(IV)=O stretching frequencies of compound II of the horseradish peroxidase isoenzymes at pH values above the transition points were at a high value approaching the Fe(IV)=O stretching frequency of ferryl myoglobin. Below the transition points the horseradish peroxidase frequencies were found to be 10 cm-1 lower. Frequencies of the Fe(IV)=O stretching vibrations of horseradish peroxidase compound II for one set of isoenzymes were found to be sensitive to deuterium exchange below the transition point but not above. These results were interpreted to be indicative of an alkaline deprotonation of a distal amino acid group, probably histidine, which is hydrogen bonded to the oxyferryl group below the transition point. Deprotonation of this group at pH values above the pKa disrupts hydrogen bonding, raising the Fe(IV)=O stretching frequency, and is proposed to account for the lowering of compound II reactivity at alkaline pH. The high value of the Fe(IV)=O vibration of compound II above the transition point appears to be identical in frequency to what is believed to be the Fe(IV)=O vibration of compound X.

Observation of the FeIV=O stretching vibration of ferryl myoglobin by resonance Raman spectroscopy.

We have directly observed the oxyferryl group of ferryl myoglobin by resonance Raman spectroscopy. The FeIV = O stretching vibration is observed at 797 cm-1 and confirmed by an 18O-induced isotopic shift to 771 cm-1. The porphyrin center-to-nitrogen distance of ferryl myoglobin is significantly less than that previously observed for horseradish peroxidase compound II, which also contains an FeIV = O heme. The FeIII-CN- stretch of myoglobin (FeIII) cyanide is observed at 454 cm-1, which shifts to 449 cm-1 upon substitution with [13C]cyanide.

Picosecond resonance Raman spectroscopic evidence for excited-state spin conversion in carbonmonoxy-hemoglobin photolysis.

The structure of the carbonmonoxy-hemoglobin (COHb) photoproduct has been studied on the picosecond time scale with resonance Raman spectroscopy, by tightly focusing the 30-ps pulses of a synchronously pumped mode-locked cavitydumped dye laser on a jet stream of COHb solution. The spectrum of the photoproduct is similar to that of deoxy Hb, but the frequencies 1603 cm(-1) (depolarized), 1552 cm(-1) (anomalously polarized), and 1542 cm(-1) (depolarized) are 2-4 cm(-1) lower than those of deoxy Hb. Similar low frequencies are observed for a species believed to be the bis-tetrahydrofuran adduct of Fe(II) octaethylporphyrin, containing in-plane high-spin Fe(II). These results indicate that in the COHb photoproduct the Fe(II) is already high-spin but is closer to the heme plane than in deoxy Hb. Photodissociation from a quintet ligand-field excited state of COHb is suggested. The frequency shifts relative to deoxy Hb persist when the laser pulses are lengthened to 20 ns. The apparently slow relaxation to the fully out-of-plane heme conformation of deoxy Hb is suggested to be associated with change of the globin tertiary structure.

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.