Binding of CO at the Pro2 side is crucial for the activation of CO-sensing transcriptional activator CooA. (1)H NMR spectroscopic studies.

CooA is a heme-containing transcriptional activator that anaerobically binds to DNA at CO atmosphere. To obtain information on the conformational transition of CooA induced by CO binding to the heme, we assigned ring current-shifted (1)H NMR signals of CooA using two mutants whose axial ligands of the heme were replaced. In the absence of CO, the NMR spectral pattern of H77Y CooA, in which the axial histidine (His(77)) was replaced with tyrosine, was similar to that of wild-type CooA. In contrast, the spectra of CooADeltaN5, in which the NH(2) termini including the other axial ligand (Pro(2)) were deleted, were drastically modulated. We assigned three signals of wild-type CooA at -4.5, -3.6, and -2.8 ppm to delta(1)-, alpha-, and delta(2)-protons of Pro(2), respectively. The Pro(2) signals were undetectable in the upfield region of the spectrum of the CO-bound state, which confirms that CO displaces Pro(2). Interestingly, the Pro(2) signals were observed for CO-bound H77Y CooA, implying that CO binds to the trans position of Pro(2) in H77Y CooA. The abolished CO-dependent transcriptional activity of H77Y CooA is therefore the consequence of Pro(2) ligation. These observations are consistent with the view that the movement of the NH(2) terminus triggers the conformational transition to the DNA binding form.

Ligand migration in human myoglobin: steric effects of isoleucine 107(G8) on O(2) and CO binding.

To investigate the ligand pathway in myoglobin, some mutant myoglobins, in which one of the amino acid residues constituting a putative ligand-docking site, Ile107, is replaced by Ala, Val, Leu, or Phe, were prepared and their structural and ligand binding properties were characterized. The kinetic barrier for the ligand entry to protein inside was lowered by decreasing the side-chain volume at position 107, indicating that the bulky side chain interferes with the formation of the activation state for the ligand migration and the free space near position 107 would be filled with the ligand in the activation state. Another prominent effect of the reduced side-chain volume at position 107 is to stabilize the ligand-binding intermediate state. Because the stabilization can be ascribed to decrease of the positive enthalpy, the enlarged free space near position 107 would relieve unfavorable steric interactions between the ligand and nearby amino acid residues. The side-chain volume at position 107, therefore, is crucial for the kinetic barrier for the ligand migration and free energy of the ligand-binding intermediate state, which allows us to propose that some photodissociated O(2) moves toward position 107 to be trapped and then expelled to the solvent.

Proximal cysteine residue is essential for the enzymatic activities of cytochrome P450cam.

To investigate the functional and structural roles of the proximal thiolate ligand in cytochrome P450cam, we prepared the C357H mutant of the enzyme in which the axial cysteine residue (Cys357) was replaced with a histidine residue. We obtained the unstable C357H mutant by developing a new preparation procedure involving in vitro folding of P450cam from the inclusion bodies. The C357H mutant in the ferrous-CO form exhibited the Soret peak at 420 nm and the Fe-CO stretching line at 498 cm-1, indicating a neutral histidine residue as the axial ligand. However, another internal ligand is coordinated to the heme iron as the sixth ligand in the ferric and ferrous forms of the C357H mutant, suggesting the collapse of the substrate-binding site. The C357H mutant showed no catalytic activity for camphor hydroxylation and the reduced heterolytic/homolytic ratio of the O-O bond scission in the reaction with cumene hydroperoxide. The present observations indicate that the thiolate coordination in P450cam is important for the construction of the heme pocket and the heterolysis of the O-O bond.

Identification of histidine 77 as the axial heme ligand of carbonmonoxy CooA by picosecond time-resolved resonance Raman spectroscopy.

The heme proximal ligand of carbonmonoxy CooA, a CO-sensing transcriptional activator, in the CO-bound form was identified to be His77 by using picosecond time-resolved resonance Raman spectroscopy. On the basis of the inverse correlation between Fe-CO and C-O stretching frequencies, we proposed previously that His77 is the axial ligand trans to CO [Uchida et al. (1998) J. Biol. Chem. 273, 19988-19992], whereas later a possibility of displacement of His77 by CO with retention of another unidentified axial ligand was reported [Vogel et al. (1999) Biochemistry 38, 2679-2687]. Although our previous resonance Raman study failed to detect the Fe-His stretching [nu(Fe-His)] mode of CO-photodissociated CooA of the carbonmonoxy adduct due to the rapid recombination, application of the picosecond time-resolved resonance Raman technique enabled us to observe a new intense line assignable to nu(Fe-His) at 211 cm(-)(1) immediately after photolysis, while it became nondiscernible after 100-ps delay. The low nu(Fe-His) frequency of photodissociated CooA indicates the presence of some strain in the Fe-His bond in CO-bound CooA. This and the rapid recombination of CO characterize the heme pocket of CooA. The 211 cm(-)(1) band was completely absent in the spectrum of the CO-photodissociated form of the His77-substituted mutant but the Fe-Im stretching band was observed in the presence of exogenous imidazole (Im). Thus, we conclude that His77 is the axial ligand of CO-bound CooA and CO displaces the axial ligand trans to His77 with retention of ligated His77 to activate CooA as the transcriptional activator.

Roles of the axial push effect in cytochrome P450cam studied with the site-directed mutagenesis at the heme proximal site.

To examine the roles of the axial thiolate in cytochrome P450-catalyzed reactions, a mutant of cytochrome P450cam, L358P, was prepared to remove one of the conserved amide protons that are proposed to neutralize the negative charge of the thiolate sulfur. The increased push effect of the thiolate in L358P was evidenced by the reduced reduction potential of the heme. The 15N-NMR and resonance Raman spectra of the mutant in the ferric-CN and in the ferrous-CO forms, respectively, also supported the increased push effect. The maintenance of stereo- and regioselectivities for d-camphor hydroxylation by the mutant suggests the minimum structural change at the distal site. The heterolysis/homolysis ratios of cumene hydroperoxide were the same for wild-type and L358P. However, we observed the enhanced monooxygenations of the unnatural substrates using dioxygen and electrons supplied from the reconstituted system, which indicate the significant role of the push effect in dioxygen activation. We interpret that the enhanced push effect inhibits the protonation of the inner oxygen atom and/or promotes the protonation of the outer oxygen atom in the putative iron-hydroperoxo intermediate (Fe3+ -O-OH) of P450cam. This work is the first experimental indication of the significance of the axial cysteine for the P450 reactivity.

Electron transfer reactions in Zn-substituted cytochrome P450cam.

We have investigated photoinduced electron transfer (ET) reactions between zinc-substituted cytochrome P450cam (ZnP450) and several inorganic reagents by using the laser flash photolysis method, to reveal roles of the electrostatic interactions in the regulation of the ET reactions. The laser pulse irradiation to ZnP450 yielded a strong reductant, the triplet excited state of ZnP450, (3)ZnP450, which was able to transfer one electron to anionic redox partners, OsCl(6)(2-) and Fe(CN)(6)(3-), with formation of the porphyrin pi-cation radical, ZnP450(+). In contrast, the ET reactions from (3)ZnP450 to cationic redox partners, such as Ru(NH(3))(6)(3+) and Co(phen)(3)(3+), were not observed even in the presence of 100-fold excess of the oxidant. One of the possible interpretations for the preferential ET to the anionic redox partner is that the cationic patch on the P450cam surface, a putative interaction site for the anionic reagents, is located near the heme (less than 10 A from the heme edge), while the anionic surface is far from the heme moiety (more than 16 A from the heme edge), which would yield 8000-fold faster ET rates through the cationic patch. The ET rate through the anionic patch to the cationic partner would be substantially slower than that of the phosphorescence process in (3)ZnP450, resulting in no ET reactions to the cationic reagents. These results demonstrate that the asymmetrical charge distribution on the protein surface is critical for the ET reaction in P450cam.

Unusual pressure effects on ligand rebinding to the human myoglobin Leucine 29 mutants.

Using high pressure flash photolysis, we revealed that the side chain of Leu(29) controls the reaction volume of the ligand migration process in myoglobin, which is the primary factor for the unusual activation volume of ligand binding in some Leu(29) mutants. As we previously reported (Adachi, S., Sunohara, N., Ishimori, K., and Morishima, I. (1992) J. Biol. Chem. 267, 12614-12621), CO bimolecular rebinding in the L29A mutant was unexpectedly decelerated by pressurization, suggesting that the rate-determining step is switched to ligand migration. However, very slow CO bimolecular rebinding of the mutants implies that bond formation is still the rate-determining step. To gain further insights into effects of the side chain on ligand binding, we prepared some new Leu(29) mutants to measure the CO and O(2) rebinding reaction rates under high hydrostatic pressure. CO bimolecular rebinding in the mutants bearing Gly or Ser at position 29 was also decelerated upon pressurization, resulting in apparent positive activation volumes (DeltaV), as observed for O(2) binding. Based on the three-state model, we concluded that the increased space available to ligands in these mutants enhances the volume difference between the geminate and deoxy states (DeltaV(32)), which shifts the apparent activation volume to the positive side, and that the apparent positive activation volume is not due to contribution of the ligand migration process to the rate-determining step.

Stepwise formation of alpha-helices during cytochrome c folding.

Two models have been proposed to describe the folding pathways of proteins. The framework model assumes the initial formation of the secondary structures whereas the hydrophobic collapse model supposes their formation after the collapse of backbone structures. To differentiate between these models for real proteins, we have developed a novel CD spectrometer that enables us to observe the submillisecond time frame of protein folding and have characterized the timing of secondary structure formation in the folding process of cytochrome c (cyt c). We found that approximately 20% of the native helical content was organized in the first phase of folding, which is completed within milliseconds. Furthermore, we suggest the presence of a second intermediate, which has alpha-helical content resembling that of the molten globule state. Our results indicate that many of the alpha-helices are organized after collapse in the folding mechanism of cyt c.

Functions of fluctuation in the heme-binding loops of cytochrome b5 revealed in the process of heme incorporation.

Cytochrome b(5) (cyt b(5)) holds heme using two axial histidines, His63 and His39, that are located in the centers of the two heme-binding loops. The previous NMR study on the apo form of cyt b(5) (apocyt b(5)) revealed that the loop including His63 exhibits a larger fluctuation compared to the other loop including His39 [Falzone, C. J., Mayer, M. R., Whiteman, E. L., Moore, C. D., and Lecomte, J. T. (1996) Biochemistry 35, 6519-6526]. To understand the significance of the fluctuation, the heme association and dissociation rates of the two loops were compared using two mutants of cyt b(5) in which one of the axial histidines was replaced with leucine. It was demonstrated that the fluctuating loop possesses a significantly slower heme dissociation rate and a faster heme association rate than the other loop. To further verify the importance of the fluctuating loop, the heme association process of wild-type apocyt b(5) was investigated using optical absorption and CD spectroscopies. It was indicated that the process proceeds through the two pathways, and that the dominant pathway involves the initial coordination of His63 located in the fluctuating loop. The urea concentration dependency of the rate constants revealed that the folding of the fluctuating loop is associated with the coordination of His63. It was suggested that the fluctuation enables the loop to have a larger heme-loop contact in the heme-bound conformation. The fluctuating heme-binding loops might be useful for the artificial design of heme-binding proteins.

Substitution of the heme binding module in hemoglobin alpha- and beta-subunits. Implication for different regulation mechanisms of the heme proximal structure between hemoglobin and myoglobin.

In our previous work, we demonstrated that the replacement of the "heme binding module," a segment from F1 to G5 site, in myoglobin with that of hemoglobin alpha-subunit converted the heme proximal structure of myoglobin into the alpha-subunit type (Inaba, K., Ishimori, K. and Morishima, I. (1998) J. Mol. Biol. 283, 311-327). To further examine the structural regulation by the heme binding module in hemoglobin, we synthesized the betaalpha(HBM)-subunit, in which the heme binding module (HBM) of hemoglobin beta-subunit was replaced by that of hemoglobin alpha-subunit. Based on the gel chromatography, the betaalpha(HBM)-subunit was preferentially associated with the alpha-subunit to form a heterotetramer, alpha(2)[betaalpha(HBM)(2)], just as is native beta-subunit. Deoxy-alpha(2)[betaalpha(HBM)(2)] tetramer exhibited the hyperfine-shifted NMR resonance from the proximal histidyl N(delta)H proton and the resonance Raman band from the Fe-His vibrational mode at the same positions as native hemoglobin. Also, NMR spectra of carbonmonoxy and cyanomet alpha(2)[betaalpha(HBM)(2)] tetramer were quite similar to those of native hemoglobin. Consequently, the heme environmental structure of the betaalpha(HBM)-subunit in tetrameric alpha(2)[betaalpha(HBM)(2)] was similar to that of the beta-subunit in native tetrameric Hb A, and the structural conversion by the module substitution was not clear in the hemoglobin subunits. The contrastive structural effects of the module substitution on myoglobin and hemoglobin subunits strongly suggest different regulation mechanisms of the heme proximal structure between these two globins. Whereas the heme proximal structure of monomeric myoglobin is simply determined by the amino acid sequence of the heme binding module, that of tetrameric hemoglobin appears to be closely coupled to the subunit interactions.

Luminol activity of horseradish peroxidase mutants mimicking a proposed binding site for luminol in Arthromyces ramosus peroxidase.

To enhance the oxidation activity for luminol in horseradish peroxidase (HRP), we have prepared three HRP mutants by mimicking a possible binding site for luminol in Arthromyces ramosus peroxidase (ARP) which shows 500-fold higher oxidation activity for luminol than native HRP. Spectroscopic studies by (1)H NMR revealed that the chemical shifts of 7-propionate and 8-methyl protons of the heme in cyanide-ligated ARP were deviated upon addition of luminol (4 mM), suggesting that the charged residues, Lys49 and Glu190, which are located near the 7-propionate and 8-methyl groups of the heme, are involved in the specific binding to luminol. The positively charged Lys and negatively charged Glu were introduced into the corresponding positions of Ser35 (S35K) and Gln176 (Q176E) in HRP, respectively, to build the putative binding site for luminol. A double mutant, S35K/Q176E, in which both Ser35 and Gln176 were replaced, was also prepared. Addition of luminol to the HRP mutants induced more pronounced effects on the resonances from the heme substituents and heme environmental residues in the (1)H NMR spectra than that to the wild-type enzyme, indicating that the mutations in this study induced interactions with luminol in the vicinity of the heme. The catalytic efficiencies (V(max)/K(m)) for luminol oxidation of the S35K and S35K/Q176E mutants were 1.5- and 2-fold improved, whereas that of the Q176E mutant was slightly depressed. The increase in luminol activity of the S35K and S35K/Q176E mutants was rather small but significant, suggesting that the electrostatic interactions between the positive charge of Lys35 and the negative charge of luminol can contribute to the effective binding for the luminol oxidation. On the other hand, the negatively charged residue would not be so crucial for the luminol oxidation. The absence of drastic improvement in the luminol activity suggests that introduction of the charged residues into the heme vicinity is not enough to enhance the oxidation activity for luminol as observed for ARP.

Crystal structure of a protein with an artificial exon-shuffling, module M4-substituted chimera hemoglobin beta alpha, at 2.5 A resolution.

The crystal structure of the homotetramer of a chimera beta alpha-subunit of human hemoglobin was refined at 2.5 A resolution. The chimera subunit was constructed by replacing an exon-encoded module M4 of the beta-subunit with that of the alpha-subunit, simulating an exon-shuffling event. The implanted module M4 retained the native alpha-subunit structure, while module M3 was disturbed around the site where a new type of intron was recently found. Some of the residues were found in alternative conformations that avoid steric hindrance at the subunit interface. The modules are modestly rigid in their backbone structures by using side-chains to compensate for interface incompatibility.

Structural and functional roles of heme binding module in globin proteins: identification of the segment regulating the heme binding structure.

To investigate structural and functional significance of a newly proposed structural unit in globins, the "heme binding module", we synthesized a "heme binding module"-substituted chimeric globin and characterized its function and structure. In our previous study we proposed that the heme binding module, corresponding to the segment from Leu(F1) to Phe(G5) in hemoglobin alpha-subunit, plays a key role in constructing the heme proximal structure in globins. The replacement of the heme binding module in myoglobin with that of hemoglobin alpha-subunit converted the absorption spectra into that of the alpha-subunit, and, in the resonance Raman spectra, the vibration mode characteristic of myoglobin completely disappeared after the module replacement. The hyperfine-shifted NMR resonances for the cyanide-bound form of the module-substituted myoglobin also revealed that the orientation of the axial histidine is close to that of the alpha-subunit rather than that of myoglobin, while the deviations of the resonance positions of the NMR signals from the amino acid residues located in the distal site were subtle, supporting the preferential structural alterations in the heme proximal site. The present finding for the structural alterations in the module-substituted myoglobin confirms that the heme binding module can be a segment regulating the heme proximal structure in globin proteins.

Heme environmental structure of CooA is modulated by the target DNA binding. Evidence from resonance Raman spectroscopy and CO rebinding kinetics.

In order to investigate the gene activation mechanism triggered by the CO binding to CooA, a heme-containing transcriptional activator, the heme environmental structure and the dynamics of the CO rebinding and dissociation have been examined in the absence and presence of its target DNA. In the absence of DNA, the Fe-CO and C=O stretching Raman lines of the CO-bound CooA were observed at 487 and 1969 cm-1, respectively, suggesting that a neutral histidine is an axial ligand trans to CO. The frequency of nu(Fe-CO) implies an open conformation of the distal heme pocket, indicating that the ligand replaced by CO is located away from the bound CO. When the target DNA was added to CO-bound CooA, an appearance of a new nu(Fe-CO) line at 519 cm-1 and narrowing of the main line at 486 cm-1 were observed. Although the rate of the CO dissociation was insensitive to the additions of DNA, the CO rebinding was decelerated in the presence of the target DNA, but not in the presence of nonsense DNA. These observations demonstrate the structural alterations in the heme distal site in response to binding of the target DNA and support the activation mechanism proposed for CooA, which is triggered by the movement of the heme distal ligand to modify the conformation of the DNA binding domain.

Design, construction, crystallization, and preliminary X-ray studies of a fine-tuning mutant (F133V) of module-substituted chimera hemoglobin.

A chimera betaalpha-subunit of human hemoglobin was crystallized into a carbonmonoxy form. The protein was assembled by substituting the structural portion of a beta-subunit of hemoglobin (M4 module of the subunit) for its counterpart in the alpha-subunit. In order to overcome the inherent instability in the crystallization of the chimera subunit, a site-directed mutagenesis (F133V) technique was employed based on a computer model. The crystal was used for an X-ray diffraction study yielding a data set with a resolution of 2.5 A. The crystal belongs to the monoclinic space group P21, with cell dimensions of a = 62.9, b = 81.3, c = 55.1 A, and beta = 91.0 degrees . These dimensions are similar to the crystallographic parameters of the native beta-subunit tetramers in three different ligand states, one of which is a cyanide form that was also crystallized in this study.

Roles of negatively charged surface residues of putidaredoxin in interactions with redox partners in p450cam monooxygenase system.

To investigate the interaction of putidaredoxin (Pdx) with its redox partners in the cytochrome P450cam system, we focused on the role of negatively charged surface amino acid residues. The amino acid residues we examined in this mutational study are Asp-58, Glu-65, Glu-72, and Glu-77, which are located on the alpha-helical segment to form a negatively charged region on the surface of Pdx and have been supposed to play key roles in the association with the redox partners, NADH-putidaredoxin reductase (PdR) and P450cam. The neutralization of the single negative charge on these amino acid residues did not significantly inhibit the electron-transfer reaction with the redox partners, except for the mutation at Glu-72. Together with the previous results, we can conclude that the negatively charged cluster on the alpha-helical segment is not so crucial for the electron transfer of the Pdx/PdR complex, and, instead of the negative charges, the steric hindrance is essential for the binding of Pdx with PdR. In the electron transfer from Pdx to P450cam, the alpha-helical region would not be included in the binding site with P450cam and some specific hydrogen bonds on the surface loop near the Fe-S center contribute to the electron transfer to P450cam. Such different binding sites and interactions for Pdx will shed light on the electron-transfer mechanism mediated by Pdx, the shuttle mechanism.

NMR studies of putidaredoxin: associations of putidaredoxin with NADH-putidaredoxin reductase and cytochrome p450cam.

To characterize the electron-transfer reaction in the P450cam monooxygenation system, the binding regions of putidaredoxin (Pdx) to NADH-putidaredoxin reductase (PdR) and P450cam were investigated using isotope-filtered NMR experiments in which uniformly 15N-labeled Pdx ([U-15N]Pdx) is mixed with unlabeled PdR and P450cam. By addition of PdR to Pdx, site specific signal broadening was observed for the N-H correlation peaks from Val-28, Glu-72, Ile-88, and Gln-105. Although previous studies have suggested the contribution from acidic amino acid residues on the G-helix of Pdx to the binding with PdR, no site specific broadening was observed for the resonances from these residues except for Glu-72. The lesser contribution of electrostatic interactions to the Pdx/PdR complex formation was also suggested by our previous study (M. Aoki, K. Ishimori, H. Fukada, K. Takahashi, I. Morishima, Biochim. Biophys. Acta 1384 (1998) 180-188), which is in sharp contrast to the complex formation between adrenodoxin and adrenodoxin reductase. Upon the complex formation between Pdx and P450cam, the site specific NMR line broadening was observed for several amino acid residues distributed near the iron-sulfur cluster, corresponding to the large binding site in the complex formation with P450cam. Since some of the amino acid residues included in the binding site are not conserved for the electron-transfer iron-sulfur proteins such as ferredoxin and adrenodoxin, the interactions formed by these amino acid residues would be highly specific to the binding with P450cam, consistent with very low cross-reactivity to other iron-sulfur proteins in the P450cam monooxygenation system.

Detection of a tryptophan radical as an intermediate species in the reaction of horseradish peroxidase mutant (Phe-221 --> Trp) and hydrogen peroxide.

The crucial reaction intermediate in the reaction of peroxidase with hydrogen peroxide (H2O2), compound I, contains a porphyrin pi-cation radical in horseradish peroxidase (HRP), which catalyzes oxidation of small organic and inorganic compounds, whereas cytochrome c peroxidase (CcP) has a radical center on the tryptophan residue (Trp-191) and oxidizes the redox partner, cytochrome c. To investigate the roles of the amino acid residue near the heme active center in discriminating the function of the peroxidases in these two enzymes, we prepared a CcP-like HRP mutant, F221W (Phe-221 --> Trp). Although the rapid spectral scanning and stopped-flow experiments confirmed that the F221W mutant reacts with H2O2 to form the porphyrin pi-cation radical at the same rate as for the wild-type enzyme, the characteristic spectral features of the porphyrin pi-cation radical disappeared rapidly, and were converted to the compound II-type spectrum. The EPR spectrum of the resultant species produced by reduction of the porphyrin pi-cation radical, however, was quite different from that of compound II in HRP, showing typical signals from a Trp radical as found for CcP. The sequential radical formation from the porphyrin ring to the Trp residue implies that the proximal Trp is a key residue in the process of the radical transfer from the porphyrin ring, which differentiates the function of peroxidases.

Structural and functional effects of pseudo-module substitution in hemoglobin subunits. New structural and functional units in globin structure.

Functional and structural significance of the "module" in proteins has been investigated for globin proteins. Our previous studies have revealed that some modules in globins are responsible for regulating the subunit association and heme environmental structures, whereas the module substitution often induces fatal structural destabilization, resulting in failure of functional regulation. In this paper, to gain further insight into functional and structural significance of the modular structure in globins, we focused upon the "pseudo-module" in globin structure where boundaries are located at the center of modules. Although the pseudo-module has been supposed not to retain a compactness, the betaalpha(PM3)-subunit, in which one of the pseudo-modules, the F1-H6 region, of the alpha-subunit is implanted into the beta-subunit, conserved stable globin structure, and its association property was converted into that of the alpha-subunit, as the case for the module substituted globin, the betaalpha(M4)-subunit. These results suggest that modules are not unique structural and functional units for globins. Interestingly, however, the recent reconsideration of the module boundary indicates that the modules in globins can be further divided into two small modules, and one of the boundaries for the new small modules coincides with that of the pseudo-module we substituted in this study. Although it would be premature to conclude the significance of the modular structure in globins, it can be safely said that we have found new structural units in globin structure, probably new modules.

Isothermal titration calorimetric studies on the associations of putidaredoxin to NADH-putidaredoxin reductase and P450cam.

Putidaredoxin (Pdx), an iron-sulfur protein containing a 2Fe-2S cluster, serves as a physiological electron mediator from NADH-putidaredoxin reductase (PdR) to P450cam in the P450cam monooxygenation reaction cycle. Previous studies have revealed that the associations of Pdx with P450cam and PdR are not strongly dominated by electrostatic interactions, although such interactions stabilize most electron-transfer complexes [A.R. De Pascalis, I. Jelesarov, F. Ackermann, W.H. Koppenol, M. Hiroasawa, D.B. Knaff, H.R. Bosshard, Protein Sci. 2 (1993) 1126-1135]. In the present study, to elucidate the interactions dominating the specific associations in the electron-transfer reaction mediated by Pdx, the thermodynamic properties--entropy (delta S), enthalpy (delta H), and heat capacity changes (delta Cp)--for PdR/Pdx and P450cam/Pdx association reactions have been examined by isothermal titration calorimetry (ITC). Although the binding enthalpy change, delta Hbind, for the PdR/Pdx association is positive at 10 degrees C, it declines linearly with temperature in the range 10-22 degrees C and becomes negative above 11 degrees C. On the other hand, the binding entropy change, delta Sbind, is positive at all temperatures examined in this study, indicating that the association of Pdx to PdR is entropically driven. On the basis of the temperature dependence of delta Hbind, delta Cpbind for the association of Pdx to PdR was estimated as -1.24 kJ mol-1 K-1. This value is larger than those reported for other electron-transfer protein systems (e.g., -0.68 kJ mol-1 K-1 for ferredoxin/ferredoxin: NADP+ reductase), suggesting that the PdR/Pdx association may be dominated by hydrophobic rather than electrostatic components. For the P450cam/Pdx association, the negative delta Sbind and highly favorable delta Hbind were observed, behavior that stands in sharp contrast to the association reactions in other electron-transfer proteins. The energetics of the P450cam/Pdx association are similar to those of binding reaction of antibody to antigen in which van der Waals and hydrogen bonding interactions are dominant, resulting in high specificity in the association of Pdx with P450cam.