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. 2010 Apr 27;15(5):2935-48.
doi: 10.3390/molecules15052935.

Artificial self-sufficient P450 in reversed micelles

Hidehiko Hirakawa  1 Noriho KamiyaYutaka KawarabayasiTeruyuki Nagamune
Affiliations

Artificial self-sufficient P450 in reversed micelles

Hidehiko Hirakawa et al. Molecules. .

Abstract

Cytochrome P450s are heme-containing monooxygenases that require electron transfer proteins for their catalytic activities. They prefer hydrophobic compounds as substrates and it is, therefore, desirable to perform their reactions in non-aqueous media. Reversed micelles can stably encapsulate proteins in nano-scaled water pools in organic solvents. However, in the reversed micellar system, when multiple proteins are involved in a reaction they can be separated into different micelles and it is then difficult to transfer electrons between proteins. We show here that an artificial self-sufficient cytochrome P450, which is an enzymatically crosslinked fusion protein composed of P450 and electron transfer proteins, showed micelle-size dependent catalytic activity in a reversed micellar system. Furthermore, the presence of thermostable alcohol dehydrogenase promoted the P450-catalyzed reaction due to cofactor regeneration.

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Figures

Figure 1
Figure 1
Reaction scheme for d-camphor hydroxylation by branched P450cam with cofactor regeneration in a reversed micellar system.
Figure 2
Figure 2
(a) Relationship between the initial rate of NADH oxidation and the concentration of branched P450cam at a water content (W0) of 16.7. The reaction mixture contained 5 mM d-camphor and 80 μM NADH. (b) Effect of W0 on the initial activities of branched P450cam (open circles) and an equimolar mixture of PdR, PdX and P450cam (closed circles). The reaction mixtures contained 0.05 μM protein, 5 mM d-camphor and 80 μM NADH. The reversed micelle solution containing PdR, PdX and P450cam was prepared by adding a mixture of PdR, PdX and P450cam to a starter reversed micelle solution (see experimental section).
Figure 3
Figure 3
Relationship between initial rate of NADH oxidation and the concentration of d-camphor at a W0 of 17. The reaction mixture contained 0.05 μM branched P450cam and 80 μM NADH.
Figure 4
Figure 4
UV-Vis spectrum of 2 μM branched P450cam with 5 mM d-camphor in the reversed micellar system at a W0 of 17.
Figure 5
Figure 5
(a) Relationship between the initial activity and the concentration of A. pernix ADH with 70 μM NAD+ at a W0 of 16.7. (b) Effect of W0 on the initial activity of A. pernix ADH at 1.2 μM.
Figure 6
Figure 6
Relationship between the initial reaction rate of A. pernix ADH and the concentration of 2-pentanol in 50 mM potassium phosphate buffer, pH 7.4, containing 150 mM KCl. The reaction mixture contained 1.2 μM A. pernix ADH and 70 μM NAD+.
Figure 7
Figure 7
(a) The consumption of d-camphor by branched P450cam (1 μM) in the reversed micellar system after 24 h in the presence (37 μM) and absence of A. pernix ADH with 1 mM NADH and at a W0 of 16.7. (b) Effect of W0 on the consumption of d-camphor after 24 h in the coupled reaction containing 1 μM branched P450cam and 37 μM A. pernix ADH with 1 mM NADH. (c) Effect of d-camphor concentration on the consumption of d-camphor after 24 h in the coupled reaction containing 1 mM NADH and at a W0 of 16.7. (d) Effect of initial NADH concentration on the consumption of d-camphor (open circles) and on the TTN of NADH (closed circles) after 24 h in the coupled reaction containing 20 mM d-camphor and at a W0 of 16.7.
Figure 7
Figure 7
(a) The consumption of d-camphor by branched P450cam (1 μM) in the reversed micellar system after 24 h in the presence (37 μM) and absence of A. pernix ADH with 1 mM NADH and at a W0 of 16.7. (b) Effect of W0 on the consumption of d-camphor after 24 h in the coupled reaction containing 1 μM branched P450cam and 37 μM A. pernix ADH with 1 mM NADH. (c) Effect of d-camphor concentration on the consumption of d-camphor after 24 h in the coupled reaction containing 1 mM NADH and at a W0 of 16.7. (d) Effect of initial NADH concentration on the consumption of d-camphor (open circles) and on the TTN of NADH (closed circles) after 24 h in the coupled reaction containing 20 mM d-camphor and at a W0 of 16.7.
Figure 8
Figure 8
(a) Time course of d-camphor consumption by branched P450cam (open circles) and by an equimolar mixture of P450cam, PdX and PdR (closed circles) in the presence of A. pernix ADH at a W0 of 16.7. (b) The stability of branched P450cam (open symbols) and of A. pernix ADH (closed symbols) in the reversed micellar system at a W0 of 16.7 (circles) and in an aqueous solution (squares).
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