P450-containing systems

Any enzyme system that includes cytochrome P450 protein or domain can be called a P450-containing system.

Overview

P450 enzymes usually act as terminal oxidase in multicomponent electron-transfer chains, called P450-containing monooxygenase systems, although self-sufficient non-monooxygenase P450s are also described. All known P450-containing monooxygenase systems share common structural and functional domain architecture. Apart from P450 itself, these systems contain one or more fundamental redox domains: FAD-containing flavoprotein or domain, FMN domain, ferredoxin and cytochrome b₅. These ubiquitous redox domains, in various combinations, are widely distributed in biological systems. FMN domain, ferredoxin or cytochrome b₅ transfer electrons between the flavin reductase (protein or domain) and P450. While P450-containing systems are found throughout all kingdoms of life, some organisms lack one or more of these redox domains.

FR/Fd/P450 systems

Mitochondrial and some bacterial P450 systems employ soluble Fe₂S₂ ferredoxins (Fd) that act as single electron carriers between FAD-containing ferredoxin reductase (FR) and P450. In mitochondrial monooxygenase systems, adrenodoxin functions as a soluble electron carrier between NADPH:adrenodoxin reductase and several membrane-bound P450s (CYP11A, CYP11B, CYP27). In bacteria, putidaredoxin, terpredoxin, and rhodocoxin serve as electron carriers between corresponding NADH-dependent ferredoxin reductases and soluble P450s (CYP101, CYP108, CYP116).

The general scheme of electron flow in the P450 systems containing adrenodoxin-type ferredoxins is:

CPR/P450 systems

Eukaryotic microsomal P450 enzymes and some bacterial P450s receive electrons from a FAD- and FMN-containing enzyme known as cytochrome P450 reductase (CPR; EC 1.6.2.4). Microsomal CPR is membrane-bound protein that interacts with different P450s. In Bacillus megaterium and Bacillus subtilis, CPR is a C-terminal domain of CYP102, a single polypeptide self-sufficient soluble P450 system (P450 is an N-terminal domain). The general scheme of electron flow in the CPR/P450 system is:

CBR/b5/P450 systems

The ubiquitous electron-transport protein cytochrome b₅ can serve as an effector (activator or inhibitor) of P450s. It was hypothesized that cytochrome b₅ is involved in the transfer of the second electron to P450, either from CPR or from NADH:cytochrome b₅ reductase (CBR; EC 1.6.2.2):

The ability of the CBR/cytochrome b₅ system to support P450 catalysis has been demonstrated in vitro using purified CBR and cytochrome b₅ from Saccharomyces cerevisiae and CYP51 enzyme from Candida albicans. In this system, both the first and second electrons are donated by CBR.

FMN/Fd/P450 systems

An unusual one-component P450 system was originally found in Rhodococcus sp. NCIMB 9784 (CYP116B2). In this system, the N-terminal P450 domain is fused to the reductase domain that shows sequence similarity to phthalate dioxygenase reductase and consists, in its turn, of FMN-binding domain and C-terminal plant-type ferredoxin domain. Similar systems have been identified in the heavy-metal-tolerant bacterium Ralstonia metallidurans (CYP116A1) and in several species of Burkolderia. The general scheme of electron flow in this system appears to be:

P450-only systems

Nitric oxide reductase (P450nor) is a P450 enzyme involved in denitrification in several fungal species. The best-characterized P450nor is CYP55 from Fusarium oxysporum. This enzyme does not have monooxygenase activity but is able to reduce nitric oxide (NO^·) to form nitrous oxide (N₂O) directly using NAD(P)H as electron donor:

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Fatty acid β-hydroxylase P450_BSβ from Bacillus subtilis (CYP152A1) and fatty acid α-hydroxylase P450_SPα from Pseudomonas paucimobilis (CYP152B1) catalyse the hydroxylation reaction of long-chain fatty acids using hydrogen peroxide (H₂O₂) as an oxidant. These enzymes do not require any reduction system for catalysis.

Allene oxide synthase (CYP74A; EC 4.2.1.92), fatty acid hydroperoxide lyase (CYP74B), prostacyclin synthase (CYP8; EC 5.3.99.4) and thromboxane synthase (CYP5; EC 5.3.99.5) are examples of P450 enzymes that do not require a reductase or molecular oxygen for their catalytic activity. Substrates for all these enzymes are fatty acid derivatives containing partially reduced dioxygen (either hydroperoxy or epidioxy groups).

References

• Degtyarenko, K.N. and Kulikova, T.A. (2001). "Evolution of bioinorganic motifs in P450-containing systems". Biochem. Soc. Trans. 29: 139–147. doi:10.1042/BST0290139. PMID 11356142. 
• Hanukoglu, I. (1996). "Electron transfer proteins of cytochrome P450 systems". Adv. Mol. Cell Biol. 14: 29–55. http://www.science.co.il/hi/pub/1996-P450-Review.asp. 
• McLean, K.J., Sabri, M., Marshall, K.R., Lawson, R.J., Lewis, D.G., Clift, D., Balding, P.R., Dunford, A.J., Warman, A.J., McVey, J.P., Quinn, A.-M., Sutcliffe, M.J., Scrutton, N.S. and Munro, A.W. (2005). "Biodiversity of cytochrome P450 redox systems". Biochem. Soc. Trans. 33: 796–801. doi:10.1042/BST0330796. PMID 16042601. 
• Ohta, D. and Mizutani, M. (2004). "Redundancy or flexibility: molecular diversity of the electron transfer components for P450 monooxygenases in higher plants". Front. Biosci. 9: 1587–1597. doi:10.2741/1356. PMID 14977570. 
• Roberts, G.A., Çelik, A., Hunter, D.J.B., Ost, T.W.B., White, J.H., Chapman, S.K., Turner, N.J. and Flitsch, S.L. (2003). "A self-sufficient cytochrome P450 with a primary structural organisation that includes a flavin domain and a [2Fe-2S] redox center". J. Biol. Chem. 278: 48914–48920. doi:10.1074/jbc.M309630200. PMID 14514666. 

External links

• Directory of P450-containing Systems