High-pressure spectrometry at subzero temperatures

Unfolding under Pressure: An NMR Perspective

This review aims to analyse the role of solution nuclear magnetic resonance spectroscopy in pressure-induced in vitro studies of protein unfolding. Although this transition has been neglected for many years because of technical difficulties, it provides important information about the forces that keep protein structure together. We first analyse what pressure unfolding is, then provide a critical overview of how NMR spectroscopy has contributed to the field and evaluate the observables used in these studies. Finally, we discuss the commonalities and differences between pressure-, cold- and heat-induced unfolding. We conclude that, despite specific peculiarities, in both cold and pressure denaturation the important contribution of the state of hydration of nonpolar side chains is a major factor that determines the pressure dependence of the conformational stability of proteins.

The Protein Unfolded State: One, No One and One Hundred Thousand

Many in vitro studies, in which proteins have been unfolded by the action of a variety of physical or chemical agents, have led to the definition of a folded versus an unfolded state and to the question of what is the nature of the unfolded state. The unstructured nature of this state could suggest that "the" unfolded state is a unique entity which holds true for all kinds of unfolding processes. This assumption has to be questioned because the unfolding processes under different stress conditions are dictated by entirely different mechanisms. As a consequence, it can be easily understood that the final state, generically referred to as "the unfolded state", can be completely different for each of the unfolding processes. The present review examines recent data on the characteristics of the unfolded states emerging from experiments under different conditions, focusing specific attention to the level of compaction of the unfolded species.

Conformational Rearrangements in the Redox Cycling of NADPH-Cytochrome P450 Reductase from Sorghum bicolor Explored with FRET and Pressure-Perturbation Spectroscopy

Simple Summary

NADPH-cytochrome P450 reductase (CPR) enzymes are known to undergo an ample conformational transition between the closed and open states in the process of their redox cycling. To explore the conformational landscape of CPR from the potential biofuel crop Sorghum bicolor (SbCPR), we incorporated a FRET donor/acceptor pair into the enzyme and employed rapid scanning stop-flow and pressure perturbation spectroscopy to characterize the equilibrium between its open and closed states at different stages of the redox cycle. Our results suggest the presence of several open conformational sub-states differing in the system volume change associated with the opening transition (ΔV⁰). Although the closed conformation always predominates in the conformational landscape, the population of the open conformations increases by order of magnitude upon the two-electron reduction and the formation of the disemiquinone state of the enzyme. In addition to elucidating the functional choreography of plant CPRs, our study demonstrates the high exploratory potential of a combination of the pressure-perturbation approach with the FRET-based monitoring of protein conformational transitions.

Abstract

NADPH-cytochrome P450 reductase (CPR) from Sorghum bicolor (SbCPR) serves as an electron donor for cytochrome P450 essential for monolignol and lignin production in this biofuel crop. The CPR enzymes undergo an ample conformational transition between the closed and open states in their functioning. This transition is triggered by electron transfer between the FAD and FMN and provides access of the partner protein to the electron-donating FMN domain. To characterize the electron transfer mechanisms in the monolignol biosynthetic pathway better, we explore the conformational transitions in SbCPR with rapid scanning stop-flow and pressure-perturbation spectroscopy. We used FRET between a pair of donor and acceptor probes incorporated into the FAD and FMN domains of SbCPR, respectively, to characterize the equilibrium between the open and closed states and explore its modulation in connection with the redox state of the enzyme. We demonstrate that, although the closed conformation always predominates in the conformational landscape, the population of open state increases by order of magnitude upon the formation of the disemiquinone state. Our results are consistent with several open conformation sub-states differing in the volume change (ΔV⁰) of the opening transition. While the ΔV⁰ characteristic of the oxidized enzyme is as large as −88 mL/mol, the interaction of the enzyme with the nucleotide cofactor and the formation of the double-semiquinone state of CPR decrease this value to −34 and −18 mL/mol, respectively. This observation suggests that the interdomain electron transfer in CPR increases protein hydration, while promoting more open conformation. In addition to elucidating the functional choreography of plant CPRs, our study demonstrates the high exploratory potential of a combination of the pressure-perturbation approach with the FRET-based monitoring of protein conformational transitions.

Proteins in Wonderland: The Magical World of Pressure

Admitting the "Native", "Unfolded" and "Fibril" states as the three basic generic states of proteins in nature, each of which is characterized with its partial molar volume, here we predict that the interconversion among these generic states N, U, F may be performed simply by making a temporal excursion into the so called "the high-pressure regime", created artificially by putting the system under sufficiently high hydrostatic pressure, where we convert N to U and F to U, and then back to "the low-pressure regime" (the "Anfinsen regime"), where we convert U back to N (U→N). Provided that the solution conditions (temperature, pH, etc.) remain largely the same, the idea provides a general method for choosing N, U, or F of a protein, to a great extent at will, assisted by the proper use of the external perturbation pressure. A successful experiment is demonstrated for the case of hen lysozyme, for which the amyloid fibril state F prepared at 1 bar is turned almost fully back into its original native state N at 1 bar by going through the "the high-pressure regime". The outstanding simplicity and effectiveness of pressure in controlling the conformational state of a protein are expected to have a wide variety of applications both in basic and applied bioscience in the future.

Effect of Ligands on HP-Induced Unfolding and Oligomerization of β-Lactoglobulin

To probe intermediate states during unfolding and oligomerization of proteins remains a major challenge. High pressure (HP) is a powerful tool for studying these problems, revealing subtle structural changes in proteins not accessible by other means of denaturation. Bovine β-lactoglobulin (BLG), the main whey protein, has a strong propensity to bind various bioactive molecules such as retinol and resveratrol, two ligands with different affinity and binding sites. By combining in situ HP-small-angle neutron scattering (SANS) and HP-ultraviolet/visible absorption spectroscopy, we report the specific effects of these ligands on three-dimensional conformational and local changes in BLG induced by HP. Depending on BLG concentration, two different unfolding mechanisms are observed in situ under pressures up to ∼300 MPa: either a complete protein unfolding, from native dimers to Gaussian chains, or a partial unfolding with oligomerization in tetramers mediated by disulfide bridges. Retinol, which has a high affinity for the BLG hydrophobic cavity, significantly stabilizes BLG both in three-dimensional and local environments by shifting the onset of protein unfolding by ∼100 MPa. Increasing temperature from 30 to 37°C enhances the hydrophobic stabilization effects of retinol. In contrast, resveratrol, which has a low binding affinity for site(s) on the surface of the BLG, does not induce any significant effect on the structural changes of BLG due to pressure. HP treatment back and forth up to ∼300 MPa causes irreversible covalent oligomerization of BLG. Ab initio modeling of SANS shows that the oligomers formed from the BLG-retinol complex are smaller and more elongated compared to BLG without ligand or in the presence of resveratrol. By combining HP-SANS and HP-ultraviolet/visible absorption spectroscopy, our strategy highlights the crucial role of BLG hydrophobic cavity and opens up new possibilities for the structural determination of HP-induced protein folding intermediates and irreversible oligomerization.

Pressure tolerance of deep-sea enzymes can be evolved through increasing volume changes in protein transitions: a study with lactate dehydrogenases from abyssal and hadal fishes

We explore the principles of pressure tolerance in enzymes of deep-sea fishes using lactate dehydrogenases (LDH) as a case study. We compared the effects of pressure on the activities of LDH from hadal snailfishes Notoliparis kermadecensis and Pseudoliparis swirei with those from a shallow-adapted Liparis florae and an abyssal grenadier Coryphaenoides armatus. We then quantified the LDH content in muscle homogenates using mass-spectrometric determination of the LDH-specific conserved peptide LNLVQR. Existing theory suggests that adaptation to high pressure requires a decrease in volume changes in enzymatic catalysis. Accordingly, evolved pressure tolerance must be accompanied with an important reduction in the volume change associated with pressure-promoted alteration of enzymatic activity ( Δ V PP ∘ ). Our results suggest an important revision to this paradigm. Here, we describe an opposite effect of pressure adaptation-a substantial increase in the absolute value of Δ V PP ∘ in deep-living species compared to shallow-water counterparts. With this change, the enzyme activities in abyssal and hadal species do not substantially decrease their activity with pressure increasing up to 1-2 kbar, well beyond full-ocean depth pressures. In contrast, the activity of the enzyme from the tidepool snailfish, L. florae, decreases nearly linearly from 1 to 2500 bar. The increased tolerance of LDH activity to pressure comes at the expense of decreased catalytic efficiency, which is compensated with increased enzyme contents in high-pressure-adapted species. The newly discovered strategy is presumably used when the enzyme mechanism involves the formation of potentially unstable excited transient states associated with substantial changes in enzyme-solvent interactions.

High-Pressure Fluorescence Spectroscopy

The combination of fluorescence and pressure perturbation is a widely used technique to study the effect of pressure on a protein system to obtain thermodynamic, structural and kinetic information on proteins. However, we often encounter the situation where the available pressure range up to 400 MPa of most commercial high-pressure fluorescence spectrometers is insufficient for studying highly pressure-stable proteins like inhibitors and allergenic proteins. To overcome the difficulty, we have recently developed a new high-pressure fluorescence system that allows fluorescence measurements up to 700 MPa. Here we describe the basic design of the apparatus and its application to study structural and thermodynamic properties of a couple of highly stable allergenic proteins, hen lysozyme and ovomucoid, using Tryptophan and Tyrosine/Tyrosinate fluorescence, respectively. Finally, we discuss the utility and the limitation of Trp and Tyr fluorescence. We discuss pitfalls of fluorescence technique and importance of simultaneous use of other high-pressure spectroscopy, particularly high-pressure NMR spectroscopy.

Ligand-rebinding kinetics of 2/2 hemoglobin from the Antarctic bacterium Pseudoalteromonas haloplanktis TAC125

Kinetic studies were performed on ligand rebinding to a cold-adapted globin of the Antarctic bacterium Pseudoalteromonas haloplanktis TAC125 (Ph-2/2HbO). This 2/2 hemoglobin displays a rapid spectroscopic phase that is independent of CO concentration, followed by the standard bimolecular recombination. While the geminate recombination usually occurs on a ns timescale, Ph-2/2HbO displays a component of about 1μs that accounts for half of the geminate phase at 8°C, indicative of a relatively slow internal ligand binding. The O2 binding kinetics were measured in competition with CO to allow a short-time exposure of the deoxy hemes to O2 before CO replacement. Indeed Ph-2/2HbO is readily oxidised in the presence of O2, probably due to a superoxide character of the FeO2 bond induced by of a hydrogen-bond donor amino-acid residue. Upon O2 release or iron oxidation a distal residue (probably Tyr) is able to reversibly bind to the heme and as such to compete for binding with an external ligand. The transient hexacoordinated ferrous His-Fe-Tyr conformation after O2 dissociation could initiate the electron transfer from the iron toward its final acceptor, molecular O2 under our conditions. The hexacoordination via the distal Tyr is only partial, indicating a weak interaction between Tyr and the heme under atmospheric pressure. Hydrostatic high pressure enhances the hexacoordination indicating a flexible globin that allows structural changes. The O2 binding affinity for Ph-2/2HbO, poorly affected by the competition with Tyr, is about 1Torr at 8°C, pH7.0, which is compatible for an in vivo O2 binding function; however, this globin is more likely involved in a redox reaction associating diatomic ligands and their derived oxidative species. This article is part of a Special Issue entitled: Oxygen Binding and Sensing Proteins.

Constrained water access to the active site of cytochrome P450 from the piezophilic bacterium Photobacterium profundum

Living species inhabiting ocean deeps must adapt to high hydrostatic pressure. This adaptation, which must enable functioning under conditions of promoted protein hydration, is especially important for proteins such as cytochromes P450 that exhibit functionally important hydration-dehydration dynamics. Here we study the interactions of substrates with cytochrome P450-SS9, a putative fatty acid hydroxylase from the piezophilic bacterium Photobacterium profundum SS9, and characterize the protein's barotropic properties. Comparison of P450-SS9 with cytochrome P450BM-3, a mesophilic fatty acid hydroxylase, suggests that P450-SS9 is characterized by severely confined accessibility and low water occupancy of the active site. This feature may reveal a mechanism of structural adaptation of the piezophilic enzyme. We also demonstrate that saturated and unsaturated fatty acids exert opposite effects on solvent accessibility and hydration of the active site. Modulation of the protein conformation by fatty acids is hypothesized to have an important physiological function in the piezophile.

Effect of conformational dynamics on substrate recognition and specificity as probed by the introduction of a de novo disulfide bond into cytochrome P450 2B1

The conformational dynamics of cytochrome P450 2B1 (CYP2B1) were investigated through the introduction of a disulfide bond to link the I- and K-helices by generation of a double Cys variant, Y309C/S360C. The consequences of the disulfide bonding were examined both experimentally and in silico by molecular dynamics simulations. Under high hydrostatic pressures, the partial inactivation volume for the Y309C/S360C variant was determined to be -21 cm3mol(-1), which is more than twice as much as those of the wild type (WT) and single Cys variants (Y309C, S360C). This result indicates that the engineered disulfide bond has substantially reduced the protein plasticity of the Y309C/S360C variant. Under steady-state turnover conditions, the S360C variant catalyzed the N-demethylation of benzphetamine and O-deethylation of 7-ethoxy-trifluoromethylcoumarin as the WT did, whereas the Y309C variant retained only 39% of the N-demethylation activity and 66% of the O-deethylation activity compared with the WT. Interestingly, the Y309C/S360C variant restored the N-demethylation activity to the same level as that of the WT but decreased the O-deethylation activity to only 19% of the WT. Furthermore, the Y309C/S360C variant showed increased substrate specificity for testosterone over androstenedione. Molecular dynamics simulations revealed that the engineered disulfide bond altered substrate access channels. Taken together, these results suggest that protein dynamics play an important role in regulating substrate entry and recognition.

High‐Pressure Studies on Protein Aggregates and Amyloid Fibrils

High hydrostatic pressure (HHP) modulates protein-protein and protein-solvent interactions through volume changes and thereby affects the equilibrium of protein conformational species between native and denatured forms as well as monomeric, oligomeric, and aggregated forms without the addition of chemicals or use of high temperature. Because of this unique property, HHP has provided deep insights into the thermodynamics and kinetics of protein folding and aggregation, including amyloid fibril formation. In particular, HHP is a useful tool to stabilize and populate specific folding intermediates, the characterization of which provides thorough understanding of protein folding and aggregation pathways. Furthermore, recent application of HHP for dissociation of protein aggregates, such as inclusion bodies (IBs), into native proteins in a single step facilitates protein preparation for structural and functional studies. This chapter overviews recent HHP studies on the population and characterization of folding intermediates associated with protein aggregation and protein refolding from protein aggregates of amyloid fibrils and IBs. Finally, we describe overall experimental procedures of HHP-mediated protein refolding and provide a detailed discussion of each operating parameter to optimize the refolding.

Pressure dependence of the dual luminescence of twisting molecules. The case of substituted 2,3-naphthalimides

The effect of high pressure (up to 5 kbar) has been studied for triacetin solutions of 2-phenyl-2,3-dihydro-1H-benzo[f]isoindole-1,3dione 1 (N-phenyl-2,3-naphthalimide) and its 3-fluorophenyl- (2), 4-carbethoxyphenyl(4) and 4-methoxyphenyl (5) derivatives which all show dual fluorescence. When the N-phenyl group is unsubstituted (compound 1) or substituted with electron-attracting groups (2 and 4), the increase of pressure over the solution decreases slightly the emission at the long-wavelengths (LW) and increases dramatically the intensity of the short-wavelength (SW) fluorescence. Plotting the logarithm of the SW/LW fluorescence quantum yield ratio for compounds, 1,2 and 4 versus the logarithm of the viscosity of the medium shows a substantial increase of this ratio which corresponds mainly to the increase of the SW emission intensity, the effect on the LW emission being only moderate. As the pressure is increased, the rotation of the N-phenyl group of compound 1 is progressively hindered and the prevailing emission comes from a state which has the same geometry as the ground state (in which the planes of the two moieties of the molecule form an angle close to 60 degree). The effect is different when an electron-donating methoxy group is attached in the para position to the N-phenyl ring, compound 5, as mainly the LW fluorescence intensity increases with pressure. For this molecule which has an electron-donating p-substituent on the N-phenyl ring, the two moieties of the ground state molecule have a more planar geometry (43 degree angle) and the LW fluorescence appears to originate from an intramolecular charge transfer state the fluorescence of which increases with pressure. A three-level reaction scheme is proposed to account for the observed kinetics. In all cases, the viscosity of the medium is found to be the main factor which induces the changes in the fluorescence spectra, and the deceleration of the non-radiative deactivation from the SW* excited state is responsible for these modifications whether a reversible process between the two emitting SW* and LW* states is observed (as for compounds 2 and 4) or not (as for compound 1).

Cloning, expression and mutagenesis of a subunit contact of rabbit muscle-specific (betabeta) enolase

The cDNA for rabbit muscle-specific (betabeta) enolase was cloned, sequenced and expressed in Escherichia coli. This betabeta-enolase differs at eight positions from that sequenced by Chin (17). Site-directed mutagenesis was used to change residue 414 from glutamate to leucine, thereby abolishing a salt bridge involved in subunit contacts. Recombinant wild-type and mutant enolase were purified from E. coli and compared to enolase isolated from rabbit muscle. Molecular weights were determined by mass spectrometry. All three betabeta-enolases had similar kinetics, and UV and circular dichroism (CD) spectra. The mutant enolase was far more sensitive to inactivation by pressure, by KCl or EDTA, and by sodium perchlorate. We confirmed, by analytical ultracentrifugation, that the sodium perchlorate inactivation was due to dissociation. DeltaG(o) for dissociation of enolase was decreased from 49.7 kJ/mol for the wild-type enzyme to 42.3 kJ/mol for the mutant. In contrast to the wild-type enzyme, perchlorate inactivation of E414L was accompanied by a small loss of secondary structure.

UV-visible derivative spectroscopy under high pressure

High hydrostatic pressure affects proteins, changing their intra- or intermolecular interactions, conformation and solvation. How to detect these changes? In this paper, via some selected examples, we show the potentiality (but also the limits) of the ultraviolet derivative spectroscopy specially adapted to high pressure experiments.

High pressure, a tool for exploring heme protein active sites

High pressure is an interesting and suitable parameter in the study of the dynamics and stability of proteins. The effects of pressure on proteins delineates its volumic (deltaV degrees ) and energetic (deltaG degrees ) parameters. An enormous amount of effort has been invested by several laboratories in developing basic theory and high pressure techniques that allow the determination of barotropic parameters. Cytochrome P450s, one of the largest super families of heme proteins, are good models for high pressure studies. Two distinct pressure-induced spin transitions of the heme iron in the active site and a P450 to P420 inactivation process have been characterized. The obtained reaction volumes of these two processes for a series of analog-bound cytochrome P450s are compared. We have shown that both the spin volume and the inactivation volume are dependent on the substrate analogs which are known to modulate the polarity and hydration of the heme pocket. Several linear correlations were found between these reaction volumes and the physico-chemical properties of the heme protein such as the polarity-induced exposure of tyrosines, the hydration of the cytochrome CYP101 heme pocket, and the mobility and binding of the substrates indicate that they constitute the main contribution to the complex thermodynamic reaction volume parameters. This interpretation allows us to conclude that cytochrome CYP101, CYP2B4 and CYP102 possess a similar mechanism of substrate binding. Interestingly the barotropic behaviors of monomeric cytochrome P450s are quite different from those of oligomeric and hetorooligomeric cytochrome P450s. The interactions of heterooligomeric subunits influence the stability of individual cytochrome P450s and the asymmetric organization of subunits which can control and modulate the activity and the recognition with NADPH-cytochrome P450 reductase.

Reversible pressure deformation of a thermophilic cytochrome P450 enzyme (CYP119) and its active-site mutants

The pressure stability of the thermophilic CYP119 from Sulfolobus solfataricus and its active-site Thr213 and Thr214 mutants was investigated. At 20 degrees C and pH 6.5, the protein undergoes a reversible P450-to-P420 inactivation with a midpoint at 380 MPa and a reaction volume change of -28 mL/mol. The volume of activation of the process was -9.5 mL/mol. The inactivation transition was retarded, and the absolute reaction volume was decreased by increasing temperature or by mutations that decrease the size of the active-site cavity. High pressure affected the tryptophan fluorescence yield, which decreased by about 37% at 480 MPa. The effect was reversible and suggested considerable contraction of the protein. Aerobic decomposition of iron-aryl complexes of the CYP119 T213A mutant under increasing hydrostatic pressure resulted in variation of the N-arylprotoporphyrin-IX regioisomer (N(B):N(A):N(C):N(D)) adduct pattern from 39:47:07:07 at 0.1 MPa to 23:36:14:27 at 400 MPa. Preincubation of the protein at 400 MPa followed by complex formation and decomposition gave the same regioisomer distribution as untreated protein. The results indicate that the protein is reversibly inactivated by pressure, in contrast to the irreversible inactivation of P450(cam) and other P450 enzymes, and that this inactivation process is modulated by changes in the active-site cavity dimensions.

Structural and functional effects of hydrostatic pressure on centrosomes from vertebrate cells

In an attempt to better understand the role of centrioles in vertebrate centrosomes, hydrostatic pressure was applied to isolated centrosomes as a means to disassemble centriole microtubules. Treatments of the centrosomes were monitored by analyzing their protein composition, ultrastructure, their ability to nucleate microtubules from pure tubulin, and their capability to induce parthenogenetic development of Xenopus eggs. Moderate hydrostatic pressure (95 MPa) already affected the organization of centriole microtubules in isolated centrosomes, and also impaired microtubule nucleation. At higher pressure, the protein composition of the peri-centriolar matrix (PCM) was also altered and the capacity to nucleate microtubules severely impaired. Incubation of the treated centrosomes in Xenopus egg extract could restore their capacity to nucleate microtubules after treatment at 95 MPa, but not after higher pressure treatment. However, the centriole structure was in no case restored. It is noteworthy that centrosomes treated with mild pressure did not allow parthenogenetic development after injection into Xenopus eggs, even if they had recovered their capacity to nucleate microtubules. This suggested that, in agreement with previous results, centrosomes in which centriole architecture is impaired, could not direct the biogenesis of new centrioles in Xenopus eggs. Centriole structure could also be affected by applying mild hydrostatic pressure directly to living cells. Comparison of the effect of hydrostatic pressure on cells at the G1/S border or on the corresponding cytoplasts suggests that pro-centrioles are very sensitive to pressure. However, cells can regrow a centriole after pressure-induced disassembly. In that case, centrosomes eventually recover an apparently normal duplication cycle although with some delay.

Effects of high hydrostatic pressures on living cells: a consequence of the properties of macromolecules and macromolecule-associated water

Sixty percent of the Earth's biomass is found in the sea, at depths greater than 1000 m, i.e., at hydrostatic pressures higher than 100 atm. Still more surprising is the fact that living cells can reversibly withstand pressure shifts of 1000 atm. One explanation lies in the properties of cellular water. Water forms a very thin film around macromolecules, with a heterogeneous structure that is an image of the heterogeneity of the macromolecular surface. The density of water in contact with macromolecules reflects the physical properties of their different domains. Therefore, any macromolecular shape variations involving the reorganization of water and concomitant density changes are sensitive to pressure (Le Chatelier's principle). Most of the pressure-induced changes to macromolecules are reversible up to 2000 atm. Both the effects of pressure shifts on living cells and the characteristics of pressure-adapted species are opening new perspectives on fundamental problems such as regulation and adaptation.

Hydrostatic pressure and calcium-induced dissociation of calpains

The dissociation of mu- and m-calpains was studied by fluorescence spectroscopy under high hydrostatic pressure (up to 650 MPa). Increasing pressure induced a red shift of the tryptophan fluorescence of the calcium-free enzyme. The concentration dependence of the spectral transition was consistent with a pressure-induced dissociation of the subunits. Rising temperature increased the stability of calpain heterodimers and confirmed the predominance of hydrophobic interactions between monomers. At saturating calcium, the spectral transition was not observed for native or iodoacetamide-inactivated calpains, indicating that they were already dissociated by calcium. The reaction volume was about -150 ml mol-1 for both isoforms, and the dissociation constants at atmospheric pressure are approximately 10-12 M and 10-15 M for mu- and m-calpains, respectively. This result indicates a tighter interaction in the isoform that requires higher calcium concentration for activity.

Mobility of norbornane-type substrates and water accessibility in cytochrome P-450cam

The behaviour of norbornane-type substrates bound to oxidised cytochrome P-450cam (CYP 101) in 60% (w/w) glycerol-containing phosphate buffer was investigated using electronic absorption spectroscopy. The high-pressure dependence study revealed that the value of the spin-state reaction-volume change decreased from -70 to -22.8 cm3/mol with decreasing high-spin state content from 99 to 63%. Simultaneously, the values for the enthalpy and entropy determined from the low-temperature dependence of the spin-state transition decreased from 73.7 to 24.3 kJ/mol and from 310.4 to 88.9 J/mol K, respectively. Under our experimental conditions the pH-value of the buffer remained at low temperatures and high pressures in the range of pH 7-8, in which no pH-value-induced spin-state conversion occurred. Therefore, the secondary effect of the temperature and pressure-induced pH change can be disregarded as being responsible for the observed spin-state transition effects. Substrate dissociation constants were determined. From the temperature-jump experiments (297 K to 180 K) we found a higher mobility in the active site for the substrates in the sequence (1R)-camphor, (1S)-camphor, camphane, (1R)- and (1S)-camphorquinone, norcamphor, and norbornane. Our findings can be explained by the incomplete fit of the methyl groups of the norbornane-type substrate to the protein, in particular to the I-helix, predominantly determining the substrate mobility and water accessibility to the protein.

Interactions of cytochrome P450 2B4 with NADPH-cytochrome P450 reductase studied by fluorescent probe

A new method for monitoring the formation of the cytochrome P450 complexes with NADPH-cytochrome P450 reductase (NCPR) is introduced. The method is based on the quenching of fluorescence of NCPR labelled with 7-ethylamino-3-(4'-maleimidilphenyl)-4-methylcoumarin maleimide (CPM). In a monomerized soluble reconstituted system in the absence of phospholipid, cytochrome P450 2B4 and NCPRcpm were shown to form 1:1 complexes with a Kd of 0.038 microM. Formation of the complex follows the kinetics of reversible second order transition with k(on) = 6.5 10(5) M-1 s-1. Application of high hydrostatic pressure induces dissociation of the complex (delta V degrees = -65 mL/mol). Succinylation of the hemoprotein increases the value of Kd to 0.5 microM primarily by decreasing k(on). In contrast to what was shown for intact 2B4, rising pressure does not take apart succinylated hemoprotein and NCPRcpm molecules, but causes some internal transition in their complex that diminishes the quenching. This transition is characterised by a very large volume change (delta V degrees = -155 mL/mol). The following conclusions were drawn: 1) a molecule of 2B4 contains two distinct contact regions involved in the interactions with NCPR. Only one of these regions is polar and highly hydrated in unbound hemoprotein; 2) interactions of the polar regions of 2B4 and NCPR are necessary to bring CPM-labelled cysteine of NCPR in short distance of the heme of 2B4; and 3) some of the lysine residues located in the proximity of the polar binding regions are apparently involved in the formation of the internal salt bridges in the molecule of 2B4.

Compressibility of the heme pocket of substrate analogue complexes of cytochrome P-450cam-CO. The effect of hydrostatic pressure on the Soret band

The effect of hydrostatic pressure on the electronic absorption spectrum of the carbon monoxide complex of cytochrome P-450cam (CYP101) in the presence of various substrates was studied. With increasing pressure the wavenumber of the Soret band in the cytochrome P-450-CO complex shifts linearily to lower values (red-shift) and the half-width increases (broadening). The microscopic theory of solvent-solute interaction discussed by Laird and Skinner is used to explain the observed pressure effects. According to this theory, the slope of the red-shift of the Soret band is related to the compressibility of the chromophore environment, that is the heme moiety of the hemoproteins. It was found that the slope of the red-shift and the slope of the broadening of the Soret band for the CO complex in the presence of various substrate analogues increase with the decrease of the initial high-spin content at 0.1 MPa in the oxidized state. Variation of the high-spin content reflects the changes in the number of water molecules and/or changes in the polarity of the heme environment. The higher compressibility of the cytochrome P-450 complexes with the substrate analogues, which induce a lower degree of the high-spin content in the oxidized protein, is explained by the ability of the water molecules in the heme moiety to transmit the pressure effect on the protein structure to the heme chromophore. Therefore, a larger pressure-induced red-shift of the Soret band in the CO complex of cytochrome P-450cam might indicate a higher water content in the heme environment.

Antagonistic effects of hydrostatic pressure and osmotic pressure on cytochrome P-450cam spin transition

The combined effects of hydrostatic pressure and osmotic pressure, generated by polyols, on the spin equilibrium of fenchone-bound cytochrome P-450cam were investigated. Hydrostatic pressure indices a high spin to low spin transition, whereas polyols induce the reversed reaction. Of the four solutes used, glycerol, glucose, stachyose, and sucrose, only the last two would act on the spin transition by osmotic stress. The spin volume changes measured by both techniques are different, 29 and -350 ml/mol for hydrostatic pressure and osmotic pressure, respectively. It suggests that even if the two are perturbing water molecules, different properties are probed. From the volume change induced by osmotic stress, 19 water molecules are deduced that would be implicated in the spin transition of the fenchone-bound protein. This result suggests that water molecules other than the well defined ones located in the active site play a key role in modulating the spin equilibrium of cytochrome P-450cam.

High-pressure effects on beta-lactoglobulin interactions with ligands studied by fluorescence

The effects of pressure (0.1 MPa to 400 MPa) on intrinsic fluorescence of beta-lactoglobulin and on its binding of retinol and cis-parinaric acid have been studied at neutral and acid pHs. In neutral pH, fluorescence emission spectra of beta-lactoglobulin tryptophanes are characterized by an irreversible 14 nm red-shift indicating pressure-induced folding changes. The intensity of the fluorescence of retinol in beta-lactoglobulin-retinol complex is enhanced by a pressure increase up to 150 MPa. It decreases at higher pressures and disappears altogether at 300 MPa. beta-Lactoglobulin-retinol complex does not reassociate after decompression at neutral pH. At acid pH condition, the fluorescence quenching by pressure of beta-lactoglobulin tryptophans is coupled with a 2 nm spectral shift and is fully reversible demonstrating almost complete restoration of globulin folding. The evolution of retinol fluorescence in beta-lactoglobulin-retinol complex is also entirely reversible between 0.1 MPa and 400 MPa and the complex never dissociates in the studied pressure range. beta-lactoglobulin-cis-parinaric acid complexes at neutral and acid pH values dissociate irreversibly at 200 MPa and 350 MPa, respectively.

High pressure induced inactivation of ferrous cytochrome P-450 LM2 (IIB4) CO complex: evidence for the presence of two conformers in the oligomer

The effect of high pressure on the spectral properties of cytochrome P-450 LM2(Fe2+)-CO complex was studied. The application of high pressure was shown to induce the conversion of cytochrome P-450 to P-420. In the solution when P-450 was oligomeric only about 65% of the total converted to P-420. The remaining portion of cytochrome P-450 was stable at pressures up to 6 kbar. When P-450 was incorporated into membranes or when it was succinylated, the proportion of the pressure sensitive fraction was slightly higher (about 75%). Dissociation of P-450 oligomers into monomers was made by addition of 0.2% Triton N-101. Monomers were the most sensitive to pressure; they could be completely converted to P-420. These results have been interpreted as evidence for the existence of two different conformers of P-450 LM2, which differ in pressure stability. Splitting between these two states appears to be a result of the oligomeric organization of cytochrome P-450 in solution and in the membrane.

Heme-pocket-hydration change during the inactivation of cytochrome P-450camphor by hydrostatic pressure

Hydrostatic pressure has been used to convert cytochrome P-450camphor to cytochrome P-420. The latter is an inactivated but soluble and undenaturated form of cytochrome P-450camphor. Using camphor analogues as probes of the active site we show that the inactivation volume change is directly correlated to the initial degree of hydration of the heme pocket. The values range between -73 ml/mol and -197 ml/mol [Di Primo, C., Hui Bon Hoa, G., Douzou, P. & Sligar, S. G. (1990) Eur. J. Biochem. 193, 383-386] for a totally hydrated (substrate-free, low-spin, six coordinated heme iron) and a non-hydrated (camphor-bound, high-spin, five coordinated heme iron) heme pocket. These results suggest that the larger value, -197 ml/mol, for the inactivation volume change is due to a hydration change of the heme pocket resulting from the displacement of the substrate during the compression and the subsequent entrance of water molecules. Similarly, the stability of the protein against compression is correlated with water accessibility to the active site. Increase in substrate mobility by loss of specific interactions with both regions of well defined secondary structure of cytochrome P-450camphor results in an increase of water accessibility and decrease of stability. Thus for camphor and adamantanone which strongly interact with the protein and exclude water from the active site [Poulos, T. L., Finzel, B. C. & Howard, A. J. (1987) J. Mol. Biol. 195, 687-700; Raag, R. & Poulos, T. L. (1989) Biochemistry 28, 917-922] the increase in stability compared to the free protein is roughly 30 kJ/mol at 20 degrees C. With smaller substrates such as norcamphor, which loosely fits into the active site and does not completely exclude water [Raag, R. & Poulos, T. L. (1989) Biochemistry 28, 917-922], the increase in stability is only 7 kJ/mol. Finally these results suggest that cytochrome P-420 induced by hydrostatic pressure is a unique form where the active site is hydrated and camphor is displaced from its binding site.

Dissociation and unfolding of Pi-class glutathione transferase. Evidence for a monomeric inactive intermediate

The dissociation and unfolding of the homodimeric glutathione transferase (GST) Pi from human placenta, using different physicochemical denaturants, have been investigated at equilibrium. The protein transitions were followed by monitoring loss of activity, intrinsic fluorescence, tyrosine exposure, far-u.v. c.d. and gel-filtration retention time of the protein. At low denaturant concentration (less than 1 M for guanidinium chloride and less than 4.5 M for urea), a reversible dissociation step leading to inactivation of the enzyme was observed. At higher denaturant concentrations the monomer unfolds completely. The same unfolding behaviour was also observed with high hydrostatic pressure as denaturant. Our results indicate that the denaturation of GST Pi is a multistep process, i.e. dissociation of the active dimer into structured inactive monomers followed by unfolding.

A nontraditional role for water in the cytochrome c oxidase reaction

The passage of electrons through cytochrome c oxidase is directly related to the activity of water. Reducing the activity in a system containing reductant, oxygen, and cytochrome oxidase blocks electron transfer between reduced cytochrome a and oxidized cytochrome a3. The extent of the block is directly related to the osmotic pressure of the system, implying that the protein shell of the oxidase acts as a semipermeable membrane that excludes osmotic perturbants but not water. It appears that approximately 10 water molecules must enter and leave the oxidase in order for internal electron transfer to occur.

The formation of cytochrome P-450 from cytochrome P-420 is promoted by spermine

This paper is concerned with camphor-bound bacterial cytochrome P-450 and processes that alter its spin-state equilibrium and influence its transition to the nonactive form, cytochrome P-420, as well as its renaturation to the native camphor-bound cytochrome P-450. Spermine, a polycation carrying a charge of 4 +, and potassium, a monovalent cation, were shown to differently cause an increase of high-spin content of camphor-bound cytochrome P-450. The spermine-induced spin transition saturates around 75% of the high spin; a further addition of KCl to the spermine-containing sample shifted the spin state to 95% of the high spin. The volume change of these spin transitions as measured by the use of high pressure indicated an excess of -40 mL/mol for the sample containing potassium as compared to that containing spermine. These results suggest that the proposed privileged site for potassium has not been occupied by spermine and that pressure forces both the camphor and the potassium ion from its sites, allowing solvent movement into the protein as well as ordering of solvent by the excluded camphor and potassium. Cytochrome P-420 was produced from cytochrome P-450 by hydrostatic pressure in the presence of potassium, spermine, and cysteine. Potassium cation shows a bigger effect on the stability of cytochrome P-450 than spermine or cysteine, as revealed by a higher value of the pressure of half-inactivation, P1/2, and a bigger inactivation volume change. However, potassium cation did not promote renaturation of cytochrome P-420 to cytochrome P-450 while the presence of spermine did.(ABSTRACT TRUNCATED AT 250 WORDS)

Activation thermodynamics of the binding of carbon monoxide to horseradish peroxidase. Role of pressure, temperature and solvent

The kinetics at 423 nm of the binding of carbon monoxide to ferrous horseradish peroxidase were studied as a function of three parameters: pressure (1-1200 bar), temperature (34 to -20 degrees C) and solvent (water, 40% ethylene glycol, 50% methanol) using a high-pressure stopped-flow apparatus. By using transition state theory the thermodynamic quantities delta V, delta S and delta H were determined under these different experimental conditions and were found to be greatly modulated by the physico-chemical parameters of the media. The results suggest that the macroscopic thermodynamic response is mainly controlled by the solvent. By adjusting two variables (among T, P, solvent), it is possible either to amplify or to cancel out the effect of the third.

High-pressure stopped-flow fluorometry at subzero temperatures: application to kinetics of the binding of NADH to liver alcohol dehydrogenase

A stopped-flow apparatus operating in fluorescence mode over temperature and pressure ranges of +30 to -30 degrees C and 10(-3) to 2 kbar, respectively, is described. The system was interfaced on a special spectrofluorometer. Its general design is an improvement of the previous instrument (C. Balny, J. L. Saldana, and N. Dahan, (1984) Anal. Biochem. 139, 178-189) in that the observation chamber and the driving mechanism have been modified. The application of the method to kinetics of the binding of NADH to horse liver alcohol dehydrogenase at subzero temperatures and as a function of hydrostatic pressure is described.

The pressure-induced inactivation of mammalian enolases is accompanied by dissociation of the dimeric enzyme

The effects of exposure to pressure on both the activity and the quaternary structure of rabbit brain enolases, forms alpha alpha, alpha gamma, and gamma gamma were studied in the pressure range of 1 to 3400 bar. Effects on quaternary structure were determined by subunit scrambling (the formation of alpha alpha and gamma gamma from alpha gamma or vice versa). All three dimers are stable up to pressures of 1200 bar. The dissociation of gamma gamma begins at 1200 bar, yielding a stable monomer; inactivation of gamma gamma does not begin until the pressure is greater than 2000 bar. Dissociation of gamma gamma is not accompanied by changes in the tryptophan fluorescence of the protein. However, the fluorescence does decrease when the pressure is greater than 2000 bar, the point at which inactivation of gamma gamma starts. The alpha monomer, on the other hand, is unstable in the pressure range that produces dissociation of alpha alpha. This process, which also begins at 1200 bar, is paralleled by inactivation. Crosslinking the enzyme with glutaraldehyde demonstrated that the inactive form of the enzyme is monomeric. The pressure-induced inactivation of these forms of enolase is thus clearly a two-step process, with both dissociation and inactivation occurring. The difference in pressure sensitivity of rabbit brain alpha alpha and gamma gamma is due to a difference in stability of the alpha and gamma monomers and not due to a difference in the pressures required for dissociation.

The effects of pressure on yeast cytochrome c peroxidase

The effects of pressure on cytochrome c peroxidase [CcP(FeIII)], its cyano derivative (CcP X CN) and its enzyme-substrate complex (ES) have been studied. The effects of pressure on the binding of the substrate analog porphyrin cytochrome c (porphyrin c) to CcP X CN and ES have also been studied. High pressure causes CcP(FeIII) to undergo a high-spin to low-spin transition but has no detectable effect on either CcP X CN, which is already low spin, or on ES. The low-spin CcP(FeIII) structure at pressure is similar to the low-spin form at low temperature and the low-spin form of horseradish peroxidase at high pressure. delta V degree associated with the spin equilibrium is about 30 ml/mol and is independent of temperature. delta G degree is small, 4.7 kJ/mol at 0 degree C, while delta H degree is 14.2 kJ/mol at 1 bar (100 kPa). Pressure has no detectable effect on the binding equilibria of mixtures of CcP X CN plus porphyrin c or ES plus porphyrin c. This indicates that the interaction of CcP and porphyrin c results in little or no volume change; the same is true in the case of cytochrome c oxidase and porphyrin c.

Heme protein fluorescence versus pressure

Fluorescence spectra of several ferric heme proteins have been measured vs. pressure to 6,000 bars. Sperm whale myoglobin (SW Mb), Aplysia myoglobin, leghemoglobin (Lb), and cytochrome P450 all show excitation and emission spectra characteristic of tryptophan in proteins with peak emission at 330-340 nm. At one bar, the fluorescence is weak due to energy transfer to the heme group, which makes the yield a sensitive probe of protein unfolding at high pressure. After an initial decrease of a few percent per kbar, the protein shows a large increase in fluorescence at high pressure. The increase is pH dependent and the results indicate that several high pressure states occur. For SW Mb at 15 degrees C an increase of a factor of 20 occurs with midpoint at 2,000 bars at pH 5 and is only partially reversible, while the increase at pH 7 occurs at 4,000 bars and is only half as large and is completely reversible. Aplysia Mb and Lb show a similar effect, but unfold at a higher pressure than SW Mb. P450 also shows a transition to a state of higher fluorescence, but the transition in this case is irreversible as a stable form, P420, is formed. The fluorescence intensity measurements permit an estimation of the increase in the TRY-heme distance in the high pressure state.

High-pressure stopped-flow spectrometry at low temperatures

A stopped-flow instrument operating over temperature and pressure ranges of +30 to -20 degrees C and 10(-3) to 2 kbar , respectively, is described. The system has been designed so that it can be easily interfaced with many commercially available spectrophotometers of fast response time, with the aid of quartz fiber optics. The materials used for the construction are inert, metal free and the apparatus has proven to be leak free at temperatures as low as -20 degrees C under a pressure of 2 kbar . The performance of the instrument was tested by measuring the rate of reduction of cytochrome c with sodium dithionite and the 2,6-dichloroindophenol/ascorbate reaction. The dead time of the system has been evaluated to be 20, 50, and congruent to 100 ms in water at 20 degrees C, in 40% ethylene glycol/water, and at 20 degrees C and -15 degrees C, respectively. These values are rather pressure independent up to 2 kbar . Application of the bomb was demonstrated using the cytochrome c peroxidase/ethyl peroxide reaction. This process occurred in two phases and an increase in pressure decreased the rates of reactions indicating two positive volumes of activation (delta V not equal to app (fast) = 9.2 +/- 1.5 ml X mol-1; delta V not equal to app (slow) = 14 +/- 1.5 ml X mol-1, temperature 2 degrees C). The data suggest that the fast reaction could involve a hydrophobic bond, whereas the slow process could be associated with a stereochemical change of the protein. The problem of temperature equilibrium for high-pressure experiments is also discussed.

Developments in low-temperature biochemistry and biology

Though under most circumstances harmful changes are induced in cellular structures by subzero temperatures, conditions can be found under which such damage is avoided. Thus, in solution, biochemical reactions can be slowed and more easily analysed and many enzyme-substrate complexes can be stabilized and structurally analysed; in crystals, 'stop-action' pictures unveil the stereochemical changes along reaction pathways. The progressive 'solidification' of non-covalent bonds involved in protein structures should permit investigation of their dynamics. Studies at high pressures open the way to new investigations on 'activated' enzyme-substrate complexes and might permit the refinement of current concepts to a considerable degree, as a preliminary but decisive step towards a full description of enzyme mechanisms. The conditions of medium allowing such cryobiochemical studies fail to protect cellular structures against cold. Investigations of plasma membrane behaviour are now under way to determine processes leading to cryosensitivity or cryotolerance of cells.

Dynamics of the spin transition in camphor-bound ferric cytochrome P-450 versus temperature, pressure and viscosity

The kinetics and equilibrium of the low-spin (LS) to high-spin (HS) transition in camphor-bound ferric cytochrome P-450 have been measured versus temperature, pressure and viscosity at selected pH and KCl concentration. The results cannot be described by a single set of delta E degrees, delta V degrees and delta S degrees, since these parameters change with the solvent conditions. A three-state model can explain a large bulk of the data but it is clear that other substates are involved. The activation energy and volume are practically zero for the high to low spin transition, while the low to high spin transition parameters vary from 20 kJ/mol to 80 kJ/mol for delta E psi and from 5 cm3/mol to 80 cm3/mol for delta V psi. The observed relaxation time could be varied from about 10 ms to more than 1000 s by changing temperature, pressure and viscosity. Both kLH and kHL rate coefficients scale roughly as 1/eta, indicating that the slow spin change involves protein motions which are influenced by the solvent viscous forces.

The pressure-induced, reversible inactivation of mouse brain enolases

The three isozymes of mouse brain enolase (alpha alpha, alpha gamma and gamma gamma) were subjected to pressures between 160 MPa and 380 MPa. Enzymatic activity 2 min after the pressure exposure was used to monitor pressure-induced changes in the physical state of the protein. Pressure caused a reversible inactivation of all three forms; alpha alpha showed a continual inactivation with increasing pressure whereas the inactivation curves for alpha gamma and gamma gamma were biphasic. P1 2 for alpha alpha was 190 MPa, for alpha gamma 210 MPa and for gamma gamma 280 MPa. Volume changes associated with this inactivation were calculated for all three forms of the enzyme; delta V0 varied from -150 ml mol-1 to -170 ml mol-1, assuming a model in which there was no change in the aggregation state of the enzyme, or from -230 ml mol-1 to -250 ml mol-1 assuming that the enzyme dissociated on exposure to pressure. The half-time for reactivation was measured as a function of the concentration of enzyme; the results are consistent with an inactivation that is due to dissociation of the dimeric enzyme into monomers.

The pressure dependence of the spin equilibrium in camphor-bound ferric cytochrome P-450

The spin equilibrium of camphor-bound ferric cytochrome P-450 has been measured between 1-1000 bar (10(5)-10(8) Pa). Increasing pressure shifts the absorption spectrum from the high-spin form at 392 nm to the low-spin form at 417 nm. The molar volume change for the spin states delta V = -RT delta ln Ke/ delta P and the equilibrium coefficient Ke = [high spin]/[low spin] depend on the solvent conditions. At pH 5.6 the equilibrium coefficient at 1 bar, K1 = 0.5 and delta V = 312 cm3/mol. A sample with 10 mM KCl at pH 7 has K1 = 7.0 amd delta V = 52 cm3/mol. Solvent changes producing a larger K1 also result in a larger delta V which ranged over 16-74 cm3/mol. The correlation can be approximated as delta V = 36 + 18 log K1, which implies that there is a pressure, 3000 bar, for camphor-bound ferric cytochrome P-450 at 4 degrees C, at which the changes in delta V are compensated by the other thermodynamic parameters leaving Ke independent of the solvent conditions. Although the protein is not stable about 1000 bar for most sample conditions, the extrapolated log Ke versus pressure curves for all sample conditions intersect near 3000 bar. Camphor-bound cytochrome P-450 appears to be a rather flexible protein, having a low denaturing pressure, a large volume change, and a high sensitivity to the protein environment.