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.

High-pressure-induced transitions in microsomal cytochrome P450 2B4 in solution: evidence for conformational inhomogeneity in the oligomers.

Pressure-induced changes in ferric P450 2B4 (LM2) were studied as a function of benzphetamine concentration (0.05 divided by 2 mM) and state of aggregation of the hemoprotein in solution. Application of factor analysis to the spectral changes in the Soret region allowed us to resolve two particular pressure-induced processes in 2B4 oligomers. The first process was identified as the conversion of the low-spin P450 into the P420 state. At 25 degrees C it was followed by decay (bleaching) of about 50% of the newly formed P420. The second process was a pressure-induced high- to low-spin shift. Both transitions were reversible, except the hemoprotein bleaching. The amplitude of the P450-->P420 transition accounted for 67 +/- 5% of the total hemoprotein content. Furthermore, the fraction of the hemoprotein exposed to spin equilibrium was not affected by the P450-->P420 conversion and was estimated to be only about 31 +/- 5% of the total hemoprotein content. After the dissociation of the oligomers by 0.2% Triton N-101, the inhomogeneity vanished: 95% of the monomers were involved in the P450-->P420 transition (delta V degrees = -86 ml/mol) followed by intense bleaching of the hemoprotein. This agrees with our earlier observations on the reduced carbonyl complex of P450 2B4 and suggests some conformational difference between subunits in P450 LM2 oligomers. The parameters of the P450-->P420 conversion (delta V degrees = -32 ml/mol, P1/2 = 1560 bar) show no dependency on the substrate concentration. Analysis of the pressure-induced spin shift versus benzphetamine concentration shows this transition to be caused mainly by changes in the spin equilibrium of both substrate-bound (delta V degrees = -49 ml/mol) and substrate-free (delta V degrees = -21 ml/mol) hemoprotein, whereas the substrate binding step itself has a very weak pressure dependency (delta V degrees = -8 ml/mol).

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.