[Productive and non-productive complexes in cytochrome P450-containing system].

The equilibrium dissociation constants K(D), the complex association / dissociation rate constants (k(on)/ k(off)) and the lifetimes of redox partners' complexes were measured for three cytochrome P450-containing monooxygenase systems (P450cam, P450 2B4 and P450scc). To estimate the productivity of complexes formed within the systems studied, the Q parameter--i.e. the ratio of protein-protein complex lifetime (T(LT)) to the time required for a single hydroxylation cycle (tau(cat))--was determined. It was shown that Q was changed (albeit insignificantly) upon transition from the oxidation to hydroxylation conditions in all the three P450 monooxygenase systems studied. It was shown that the binary complexes formed within the P450cam and the P450scc systems requiring an intermediate electron-transfer protein between the reductase and cytochrome P450 were non-productive while the binary complexes formed within the P450 2B4 system, not requiring such an intermediate electron-transfer protein, proved to be productive. Formation of ternary complexes within the three systems was demonstrated under hydroxylation conditions. Analysis of Q values led to the conclusion that the ternary complexes formed within the P450cam and the P450scc systems were virtually 100% productive. Within the P450 2B4 system, more than half (about 60%) ternary complexes were also found to be productive.

[Value of a new thickened formula in infants with regurgitations]. / Intérêt d'une nouvelle préparation infantile dans la prise en charge des régurgitations du nourrisson.

OBJECTIVES: The purpose of this open multicenter study was to evaluate the value of a new starch-thickened formula in infants with regurgitations in ambulatory pediatric practice. POPULATION AND METHODS: The study population comprised full-term infants with an age at inclusion of 1-90 days, who were bottle-fed and presented regurgitations. The formula tested was an infant formula-thickened with starch (2g/100mL). The primary endpoint was the frequency of bottles regurgitated, expressed in percentage of meals per day after 15 days of feeding with the preparation studied. Secondary endpoints were the assessment of regurgitations using the Vandenplas' score, as well as the daily increase in weight, height, and cranial circumference, overall and gastrointestinal tolerance, and formula acceptability. RESULTS: Sixty-four infants presenting regurgitation were included. The frequency of bottles regurgitated estimated at 80.3% at inclusion significantly decreased at D3, D15, and D30 to 40.1, 40.2 and 37.2% (P<0.0001), respectively. Thirty percent of infants did not present regurgitations at all at D30. Similarly, a significant decrease in the Vandenplas' score was observed from 1.9 at D0 to 0.9 at D30 (P<0.0001). Infant growth was similar to the French and European growth curves. CONCLUSION: The results showed rapid and lasting improvement in decreasing the frequency of feeding-bottles regurgitated by 50% from the first 3 days of using this new starch-thickened formula (2g/100mL). These satisfying results encourage the use of the tested formula in cases of infant regurgitation, in line with the European Society of Gastroenterology, Hepatology and Nutrition (ESPGHAN) recommendations.

[Optical biosensor study and molecular modeling of interactions between cytochrome P450cam and cytochrome b5].

The formation of complexes of cytochrome P450cam (P450cam) with full-length cytochrome b5 (d-b5) and its tryptic water-soluble fragment (t-b5) was analyzed using a two-channel IAsys+ optical biosensor. It was found that t-b5 can form complexes with P450cam, while d-b5 does not interact with P450cam. The involvement of amine groups of P450cam in the complex formation was demonstrated. The temperature dependence of t-b5(im)/P450cam complex formation was measured. The association rate constant (k(on)) increased with temperature, while the dissociation rate constant (k(off)) practically remained unchanged. It was concluded that hydrophobic interactions play a key role in the complex formation, while electrostatic interactions are significant for complex stabilization. Based on temperature dependence the activation energy, enthalpy and entropy of complex formation were calculated. It was shown that the entropy component plays a key role in t-b5(im)/P450cam interaction. Computer modeling of P450cam/t-b5 and P450cam/d-b5 interactions was carried out. Using the method of molecular docking some hypotheses of protein-protein complexes were advanced and the best ones were selected based on geometric complementarity, calculated binding energy and probability of electron tunneling between proteins. The computer modeling has shown that only P450cam and t-b5 can form the stable complex. These results are in good agreement with the experimental data obtained with the optical biosensor.

Revelation of ternary complexes between redox partners in cytochrome P450-containing monooxygenase systems by the optical biosensor method.

Formation of binary and ternary complexes in the water-soluble cytochrome P450cam (P450cam)-containing as well as in the membrane P4502B4(2B4)- and the mixed P450scc-containing monooxygenase systems was investigated in real time by the 'resonant mirror' optical biosensor method. It was shown that the inter-protein electron transfer occurs not only during complex formation but also upon random collision--as was the case with the d-Fp/d-b5 pair (2B4 system). Binary complexes may be either facilitative to electron transfer (electron-transfer complexes) or prohibitive to it (non-productive complexes). Although the binary PdR/Pd and P450cam/Pd complex formation (within the P450cam-system) as well as the binary AdR/Ad and P450scc/Ad complex formation (within the P450scc-system) does occur, the lifetimes of these complexes formed are several orders of magnitude higher than the time required for realization of a complete hydroxylation cycle. At the same time, the lifetimes of the ternary PdR/Pd/P450cam and AdR/Ad/P450scc complexes are sufficient to permit the realization of a complete hydroxylation cycle in either of these systems. For the membrane P450 2B4 system, the formation of both the binary (Fp/2B4 and 2B4/b5) and ternary (Fp/2B4/b5) complexes was registered. The lifetimes of the binary Fp/2B4 and the ternary Fp/2B4/b5 complexes are sufficient for realization of a complete hydroxylation cycle in each of them.

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.

High yield purification and physico-chemical properties of full-length recombinant allelic variants of sheep prion protein linked to scrapie susceptibility.

Sheep susceptibility to scrapie is governed by polymorphisms at two major sites, codons 136 and 171, of the prp gene. To get more insight into the prion protein (PrP) sequence-linked basis of differential scrapie susceptibility, a high yield one-step method for the purification (over 99% final purity) of the full-length recombinant sheep PrP was developed, based on the affinity of the conserved octapeptide repeats for transition-metal cations. Thermal and chemical denaturation experiments and limited proteolysis studies were performed on the natural variants (A136R171, V136Q171 and A136Q171) and a recombinant PrP mutated at position 136 (V136R171). Results revealed the influence of mutations in positions 136 and 171 on the folding thermodynamic parameters and on the conformation of the C-terminal domain. Together, our results show that the VQ cellular protein linked to higher scrapie susceptibility is intrinsically more compact and/or stable than the resistance-linked AR counterpart. This might lead to a lower in vivo clearance rate of VQ and a consequently higher probability of occurrence of pathological events.

Proton nuclear magnetic resonance study of the binary complex of cytochrome P450cam and putidaredoxin: interaction and electron transfer rate analysis.

A 1H nuclear magnetic resonance study of the complex of cytochrome P450cam-putidaredoxin has been performed. Isocyanide is bound to cytochrome P450cam in order to increase the stability of the protein both in the reduced and the oxidized state. Diprotein complex formation was detected through variation of the heme methyl proton resonances which have been assigned in the two redox states. The electron transfer rate at equilibrium was determinated by magnetization transfer experiments. The observed rate of oxidation of reduced cytochrome P450 by the oxidized putidaredoxin is 27 (+/- 7) per s.

Pressure-sensitivity of endoplasmic reticulum membrane and nucleolus as revealed by electron microscopy.

Murine erythroleukemia cells submitted to high hydrostatic pressure (up to 110 MPa, 17 min. at room temperature) remain viable (Mentré et al., 1997) but present, at the ultrastructure level, perturbations which are documented in this work. In cells submitted to 50 MPa, endoplasmic reticulum membranes displayed a characteristic rigid aspect, whereas plasma membrane remained unaffected up to 110 MPa. This result is in agreement with: i) the liquid-crystalline --> gel state transition undergone by phospholipid bilayers under pressure, which involves the structuration of water at the polar-apolar interface; ii) the low concentration in cholesterol of endoplasmic reticulum membranes compared to plasma membrane, and iii) the ability of cholesterol to protect membranes against the effects of high hydrostatic pressure. Nucleoli displayed a remarkable compact aspect above 80 MPa, involving the disappearance of vacuoles and the diminution of fibrillar component, but the retention of granular component. Pressure inhibition of translation is advanced as a possible cause of this perturbation.

Dynamics of protein-bound water in the heme domain of P450BM3 studied by high-pressure spectroscopy: comparison with P450cam and P450 2B4.

Pressure-induced transitions in the heme domain of cytochrome P450BM3 (P450BMP) were studied versus the concentration of palmitic acid. An increase in hydrostatic pressure causes a high- to low-spin shift and subsequent P450 to P420 transition. Conversion of P450BMP to P420 is associated with important conformational and hydration changes of the protein. Treating the pressure-induced changes in the high-spin content in P450 in terms of the four-state model of spin transitions and substrate binding, we evaluated and compared the barotropic parameters of these transitions for P450MBP, P450cam, and P450 2B4 (2B4). In the current study, the pressure-induced transitions in P450cam were reinvestigated versus the concentration of camphor. The interactions of 2B4 and P450BMP with their substrates (benzphetamine and palmitic acid) were accompanied by larger changes in the partial volume of the proteins (+267 and +248 mL/mol, respectively) than the interactions of P450cam with camphor (+106 mL/mol). For 2B4 and P450BMP, substrate binding apparently requires hydration of regions outside the active site. The reaction volumes of the low- to high-spin transitions of the substrate-free cytochromes (20-23 mL/mol) are consistent with the displacement of one water molecule. The volume changes in the high- to low-spin transition of the substrate-bound P450cam, 2B4, and P450BMP (-90, -49, and -16 mL/mol correspondingly) reveal a linear relationship with DeltaG degrees of the spin transition, suggesting that modulation of the spin state by substrate binding is driven by a common mechanism in all three heme proteins.

Origin of the photoacoustic signal in cytochrome P-450cam: role of the Arg186-Asp251-Lys178 bifurcated salt bridge.

The origin of the photoacoustic signal in ferrous CO-camphor-cytochrome P-450cam was investigated. Recently, the Arg186-Asp251-Lys178 bifurcated salt bridge, located above the heme pocket, has been shown to play a key role in the control of the diffusion step of camphor binding [Deprez, E., Gerber, N. C., Di Primo, C., Douzou, P., Sligar, S. G., & Hui Bon Hoa, G. (1994) Biochemistry 33, 14464-14468]. We considered the hypothesis that electrostriction resulting from the transient exposure of these charged residues to the solvent could be responsible for part of the photoacoustic signal. We thus examined the effects of a site-directed mutation of these linkages and ionic strength increases. Upon replacement of the Asp251 residue by an asparagine residue, the overall enthalpy and volume change of the CO dissociation reaction decrease from -5 to -24 kcal/mol and from 11 to 5.4 mL/mol, respectively. The mutation has the same effect on the thermodynamic parameters as increasing the ionic strength of the medium over a range of potassium or sodium concentrations from 0 to 500 mM. For the D251N mutant, the overall enthalpy of the reaction does not change with the ionic strength whereas a small effect is observed on the volume change. The results indicate that electrostriction around the bifurcated salt bridge contributes to the photoacoustic signal and suggest a scheme in which, following photodissociation of CO and diffusion of the molecule through the protein matrix, the structure relaxes and the bifurcated salt bridge desolvates.

Thermodynamic studies of substrate binding and spin transitions in human cytochrome P-450 3A4 expressed in yeast microsomes.

An approach to the quantitative spectral analysis of substrate binding and inactivation of cytochrome P-450 in microsomes is described. The method is based on the application of the principal component analysis technique on the Soret-region spectra measured at different temperatures at various concentrations of substrate. This approach allowed us to study the thermodynamic parameters of substrate binding and spin transitions in human cytochrome P-450 3A4 expressed in yeast (Saccharomyces cerevisiae) microsomes. These parameters are discussed in comparison with the values reported earlier by Ristau et al. [(1979) Acta Biol. Med. Ger. 38, 177-185] for rabbit liver cytochrome P-450 2B4 in solution with benzphetamine as a substrate. Our analysis shows the substrate-free states of 2B4 and 3A4 to be very similar. However, substrate binding seems to perturb haem-protein interactions in 3A4 in contrast with 2B4, where the effect of substrate binding on the thermodynamic parameters of spin transitions was insignificant. The implication of the results for the mechanism of substrate-induced spin shift is discussed.

Improved binding of cytochrome P450cam substrate analogues designed to fill extra space in the substrate binding pocket.

Cytochrome P450cam catalyzes the 5-exo-hydroxylation of camphor. Camphor analogues were designed to fill an empty region of the substrate binding pocket with the expectation that they would bind more tightly than camphor itself due to increased van der Waals interactions with the protein and the displacement of any solvent occupying this site. A series of compounds (endo-borneol methyl ether, endo-borneol propyl ether, endo-borneol allyl ether and endo-borneol dimethyl allyl ether) were synthesized with substituents at the camphor carbonyl oxygen. The spin conversion and thermodynamic properties of this series of compounds were measured for wild type and Y96F mutant cytochrome P450cam and were interpreted in the context of molecular dynamics simulations of the camphor analogues in the P450 binding site and in solution. Compounds with a 3-carbon chain substituent were predicted to match the size of the unoccupied region most optimally and thus bind best. Consistent with this prediction, the borneol allyl ether binds to cytochrome P450cam with highest affinity with a Kd = 0.6 +/- 0.1 microM (compared to a Kd = 1.7 +/- 0.2 microM for camphor under the same experimental conditions). Binding of the camphor analogues to the Y96F mutant is much enhanced over the binding of camphor, indicating that hydrogen bonding plays a less important role in binding of these analogues. Binding enthalpies calculated from the simulations, taking all solvent contributions into account, agree very well with experimental binding enthalpies. Binding affinity is not however correlated with the calculated binding enthalpy because the binding of the substrate analogues is characterized by enthalpy-entropy compensation. The new compounds are useful probes for further studies of the mechanism of cytochrome P450cam due to their high binding affinities and high spin properties.

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.

Antigenic mapping of bacterial and animal cytochromes P-450.

A peptide scanning (PEPSCAN) approach was used for antigenic mapping of two hepatic microsomal cytochromes P450 (rab1A2 and rab2B4) and the microbial cytochrome from Pseudomonas putida (P450 101 or P450cam). This approach includes simultaneous synthesis of pin-linked overlapping hexapeptides covering the whole sequences of three P450s and testing them by ELISA with corresponding polyclonal antisera. Microsomal cytochrome P450 maps were shown to vary depending on an antiserum used for testing the peptides, however, the most active linear B-epitopes were revealed with antisera from two animal species used. P450 linear B-epitopes were classified into individual and group-specific epitopes. While almost all P450 101 linear antigenic determinants are unique for this protein, rab1A2 and rab2B4 contain epitopes both individual for each protein, and subfamily- or even family-specific epitopes. These results point out the possibility of producing both monospecific and group-specific antipeptide antibodies against different P450s. The antigenic map of P450 101 was superimposed on the structural-functional map of this protein. Its linear B-epitopes were shown to coincide with boundaries of secondary structure elements, with surface-located, water accessible regions and with sites responsible for intermolecular interactions in the Pseudomonas putida monooxygenase system. Several known or predicted functionally active sites in microsomal cytochrome P450 rab1A2 and rab2B4 were also shown to coincide with linear B-epitopes. The peculiarities of epitope locations in the protein tertiary structure will allow to predict antigenic regions starting from protein structural information and vice versa, to structural protein models in accordance with antigenic mapping results. Antigenic regions which coincide with sites responsible for intermolecular interactions in monooxygenase systems may be synthesized as separate peptides and used as blockers of such interactions.

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.

Electrostatic control of the substrate access channel in cytochrome P-450cam.

Camphor binding to ferric cytochrome P-450cam is a two-step process. The first step corresponds to the diffusion of camphor into the heme pocket, and the second one corresponds to an observable spin transition of the heme iron. In this paper, electrostatic interactions that may control the opening of the structure to allow substrate access to the buried and not solvent-exposed active site were examined. The electrostatic interactions occurring at the protein surface were weakened by increasing the ionic strength of the medium with sodium salts and strengthened by decreasing the dielectric constant of the medium with ethylene glycol as a cosolvent. The results obtained with the wild-type protein were compared to those obtained with the site-directed mutant of cytochrome P-450cam in which the Arg 186-Asp 251 and Lys 178-Asp 251 salt bridges, located at the entrance of the proposed access channel, were suppressed by replacing Asp 251 with an asparagine residue. Over a range of sodium chloride concentrations from 0 to 400 mM, camphor binding is favored, as seen in the variation in the first step dissociation equilibrium constant, K1d, which decreases from 49.5 to 24 microM, respectively. Addition of ethylene glycol favors the dissociation of the substrate-bound complex. The addition of sodium to the ethylene glycol-containing samples reverses the effect of the cosolvent. Removal of the Arg 186-Asp 251 and Lys 178-Asp 251 salt bridges results in an alteration in camphor binding in which K1d is equal to 34 microM without sodium.(ABSTRACT TRUNCATED AT 250 WORDS)

The role of water in the dissociation of enolase, a dimeric enzyme.

Exposure of enolase to hydrostatic pressure results in a reversible inactivation of the enzyme; increasing the osmotic pressure, by adding glycerol, glucose, or sucrose to the solutions stabilizes the enzyme against the effects of hydrostatic pressure. The effects of both hydrostatic and osmotic pressure on the rate of inactivation have been determined. As hydrostatic pressure increases, the rate of inactivation increases. As osmotic pressure increases, the rate of inactivation decreases. We have interpreted these results using the following model: hydrostatic pressure causes the active, dimeric enzyme to dissociate into inactive monomers; during the dissociation, the subunit interfaces become hydrated. As osmotic pressure increases, hydration becomes more difficult and dissociation is reduced. The combined effects of hydrostatic and osmotic pressure suggest that much of this hydration occurs during formation of the transition state.

Conformational dynamics of cytochrome P-450cam as monitored by photoacoustic calorimetry.

Conformational transitions of cytochrome P-450cam following the dissociation of CO from the ferrous heme were investigated by using photoacoustic calorimetry. The effect of substrate association on the acoustic signal was also examined. Results show that the conformational dynamics of cytochrome P-450cam substrate-free protein occur faster than 10 ns, which is the time scale of the instrument response. The enthalpy and volume change for the dissociation reaction are 2.2 kcal mol-1 and 1.8 mL mol-1, respectively. Upon addition of camphor, the reaction is markedly slowed. An intermediate is formed whose lifetime is 130 ns at 17 degrees C. The overall enthalpy and volume changes are -15.9 kcal mol-1 and 10.3 mL mol-1, respectively. These results, together with published transient Raman spectra [Wells, A. V., Pusheng, L., Champion, P. M., Martinis, S. A., & Sligar, S. G. (1992) Biochemistry 31, 4384-4393] suggest that camphor leaves the heme pocket concomitant with the photoinduced expulsion of CO into the solvent and induces a considerable conformational change in the protein.

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.

Effect of the tyrosine 96 hydrogen bond on the inactivation of cytochrome P-450cam induced by hydrostatic pressure.

The effects of removal of the tyrosine 96 hydrogen bond on the stability and conformational events of cytochrome P-450cam are presented in this communication. Hydrostatic pressure has been used as a tool to perturbe the structure leading to the formation of cytochrome P-420, an inactivated but soluble and undenatured form of the enzyme. We show that the spin transition of cytochrome P-450cam, which is known to be influenced by hydrostatic pressure, is affected by this single mutation. The free energy of stabilisation of native substrate-free cytochrome P-450cam is not affected by the removal of the tyrosine 96 hydrogen bond via mutagenesis to phenylalanine, whereas the substrate-bound protein shows a difference of 21 kJ/mol. These results, as well as an observed 110 ml/mol difference for the volume of the inactivation reaction between substrate-bound native and mutant proteins, have been interpreted in terms of a more hydrated heme pocket for the site-directed mutant at position 96 compared to the wild-type protein where camphor is tightly bound via the tyrosine 96 hydrogen bond and water excluded from the active site.