Thematic Minireview Series: Metals in Biology 2010

Metals are present in nearly one-half of protein structures analyzed to date and play important roles in many of these enzymes. This prologue introduces the third of the Thematic Minireview Series on Metals in Biology, which is focused on iron homeostasis. The four minireviews in the current series deal with redox cycling in iron metabolism, the biogenesis and assembly of iron-sulfur centers (two articles), and the assembly of iron into heme.     

Heterologous expression, purification, and properties of human cytochrome P450 27C1

Cytochrome P450 (P450) 27C1 is one of the "orphan" P450 enzymes without a known biological function. A human P450 27C1 cDNA with a nucleotide sequence modified for Escherichia coli usage was prepared and modified at the N-terminus, based on the expected mitochondrial localization. A derivative with residues 3-60 deleted was expressed at a level of 1350nmol/L E. coli culture and had the characteristic P450 spectra. The identity of the expressed protein was confirmed by mass spectrometry of proteolytic fragments. The purified P450 was in the low-spin iron state, and the spin equilibrium was not perturbed by any of the potential substrates vitamin D(3), 1alpha- or 25-hydroxy vitamin D(3), or cholesterol. P450s 27A1 and 27B1 are known to catalyze the 25-hydroxylation of vitamin D(3) and the 1alpha-hydroxylation of 25-hydroxy vitamin D(3), respectively. In the presence of recombinant human adrenodoxin and adrenodoxin reductase, recombinant P450 27C1 did not catalyze the oxidation of vitamin D(3), 1alpha- or 25-hydroxy vitamin D(3), or cholesterol at detectable rates. P450 27C1 mRNA was determined to be expressed in liver, kidney, pancreas, and several other human tissues.     

Three-dimensional structure of steroid 21-hydroxylase (cytochrome P450 21A2) with two substrates reveals locations of disease-associated variants

Steroid 21-hydroxylase (cytochrome P450 21A2, CYP21A2) deficiency accounts for ∼95% of individuals with congenital adrenal hyperplasia, a common autosomal recessive metabolic disorder of adrenal steroidogenesis. The effects of amino acid mutations on CYP21A2 activity lead to impairment of the synthesis of cortisol and aldosterone and the excessive production of androgens. In order to understand the structural and molecular basis of this group of diseases, the bovine CYP21A2 crystal structure complexed with the substrate 17-hydroxyprogesterone (17OHP) was determined to 3.0 Å resolution. An intriguing result from this structure is that there are two molecules of 17OHP bound to the enzyme, the distal one being located at the entrance of the substrate access channel and the proximal one bound in the active site. The substrate binding features locate the key substrate recognition residues not only around the heme but also along the substrate access channel. In addition, orientation of the skeleton of the proximal molecule is toward the interior of the enzyme away from the substrate access channel. The 17OHP complex of CYP21A2 provides a good relationship between the crystal structure, clinical data, and genetic mutants documented in the literature, thereby enhancing our understanding of congenital adrenal hyperplasia. In addition, the location of certain CYP21A2 mutations provides general understanding of structure/function relationships in P450s.     

Cooperativity in oxidation reactions catalyzed by cytochrome P450 1A2: highly cooperative pyrene hydroxylation and multiphasic kinetics of ligand binding

Rabbit liver cytochrome P450 (P450) 1A2 was found to catalyze the 5,6-epoxidation of alpha-naphthoflavone (alphaNF), 1-hydroxylation of pyrene, and the subsequent 6-, 8-, and other hydroxylations of 1-hydroxy (OH) pyrene. Plots of steady-state rates of product formation versus substrate concentration were hyperbolic for alphaNF epoxidation but highly cooperative (Hill n coefficients of 2-4) for pyrene and 1-OH pyrene hydroxylation. When any of the three substrates (alphaNF, pyrene, 1-OH pyrene) were mixed with ferric P450 1A2 using stopped-flow methods, the changes in the heme Soret spectra were relatively slow and multiphasic. Changes in the fluorescence of all of the substrates were much faster, consistent with rapid initial binding to P450 1A2 in a manner that does not change the heme spectrum. For binding of pyrene to ferrous P450 1A2, the course of the spectra revealed sequential changes in opposite directions, consistent with P450 1A2 being involved in a series of transitions to explain the kinetic multiphasicity as opposed to multiple, slowly interconverting populations of enzyme undergoing the same event at different rates. Models of rabbit P450 1A2 based on a published crystal structure of a human P450 1A2-alphaNF complex show active site space for only one alphaNF or for two pyrenes. The spectral changes observed for binding and hydroxylation of pyrene and 1-OH pyrene could be fit to a kinetic model in which hydroxylation occurs only when two substrates are bound. Elements of this mechanism may be relevant to other cases of P450 cooperativity.     

Immunohistochemical localization of epoxide hydratase in rat liver

An antibody produced against epoxide hydratase (EC 4.2.1.63) which had been purified to apparent homogeneity from hepatic microsomes of phenobarbital pretreated rats was employed in an unlabeled antibody peroxidase-antiperoxidase technique to localize the enzyme at the light microscopic level in the livers of untreated rats. Immunohistochemical staining for epoxide hydratase was detected in parenchymal cells throughout the liver lobule. Cells within the centrilobular regions, however, were observed to be stained more intensely than were those within the midzonal and periportal regions of the lobule. The results of this immunohistochemical study thus demonstrate that epoxide hydratase does not exhibit a uniform pattern of distribution within the liver lobule in untreated rats.     

Synthesis and insertion, both in vivo and in vitro, of rat-liver cytochrome P-450 and epoxide hydratase into Xenopus laevis membranes

We described whole cell and cell-free systems capable of inserting into membranes cytochrome P-450 and epoxide hydratase made under the direction of rat liver RNA. The systems have been used to study the pathways followed by newly made secretory and integral membrane proteins. The cell-free system contains Xenopus laevis embryo membranes, and demonstrates competition for a common receptor between cytochrome P-450 and epoxide hydratase, and normal secretory proteins: evidence is provided for differential membrane receptor affinity. Thus, synthesis of secretory and membrane proteins appears to involve a common initial pathway. Microinjection of rat liver RNA into whole oocytes suggests that membrane insertion is neither cell type nor species specific, because functional rat liver enzymes are found inserted in the endoplasmic reticulum of the frog cell. Nonetheless, insertion is highly selective since albumin and several other proteins made under the direction of the injected liver RNA are sequestered within membrane vesicles and are then secreted by the oocyte, whilst epoxide hydratase and cytochrome P-450 are inserted into membranes but are not secreted.     

Testosterone 1 beta-hydroxylation by human cytochrome P450 3A4.

Human cytochrome P450 3A4 forms a series of minor testosterone hydroxylation products in addition to 6 beta-hydroxytestosterone, the major product. One of these, formed at the next highest rate after the 6 beta- and 2 beta-hydroxy products, was identified as 1 beta-hydroxytestosterone. This product was characterized from a mixture of testosterone oxidation products using an HPLC-solid phase extraction-cryoprobe NMR/time-of-flight mass spectrometry system, with an estimated total of approximately 6 microg of this product. Mass spectrometry established the formula as C(19)H(29)O(3) (MH(+) 305.2080). The 1-position of the added hydroxyl group was established by correlated spectroscopy and heteronuclear spin quantum correlation experiments, and the beta-stereochemistry of the added hydroxyl group was assigned with a nuclear Overhauser correlated spectroscopy experiment (1 alpha-H). Of several human P450s examined, only P450 3A4 formed this product. The product was also formed in human liver microsomes.     

Complex reactions catalyzed by cytochrome P450 enzymes

Cytochrome P450 (P450) enzymes are some of the most versatile redox proteins known. The basic P450 reactions include C-hydroxylation, heteroatom oxygenation, heteroatom release (dealkylation), and epoxide formation. Mechanistic explanations for these reactions have been advanced. A number of more complex P450 reactions also occur, and these can be understood largely in the context of the basic chemical mechanisms and subsequent rearrangements. The list discussed here updates a 2001 review and includes chlorine oxygenation, aromatic dehalogenation, formation of diindole products, dimer formation via Diels-Alder reactions of products, ring coupling and also ring formation, reductive activation (e.g., aristolochic acid), ring contraction (piperidine nitroxide radical), oxidation of troglitazone, cleavage of amino oxazoles and a 1,2,4-oxadiazole ring, bioactivation of a dihydrobenzoxathiin, and oxidative aryl migration.     

Oxidations of p-alkoxyacylanilides catalyzed by human cytochrome P450 1A2: structure-activity relationships and simulation of rate constants of individual steps in catalysis

Human cytochrome P450 (P450) 1A2 is involved in the oxidation of many important drugs and carcinogens. The prototype substrate phenacetin is oxidized to an acetol as well as the O-dealkylation product [Yun, C.-H., Miller, G. P., and Guengerich, F. P. (2000) Biochemistry 39, 11319-11329]. In an effort to improve rates of catalysis of P450 1A2 enzymes, we considered a set of p-alkoxyacylanilide analogues of phenacetin and found that variations in the O-alkyl and N-acyl substituents altered the rates of the two oxidation reactions and the ratio of acetol/phenol products. Moving one methylene group of phenacetin from the O-alkyl group to the N-acyl moiety increased rates of both oxidations approximately 5-fold and improved the coupling efficiency (oxidation products formed/NADPH consumed) from 6% to 38%. Noncompetitive kinetic deuterium isotope effects of 2-3 were measured for all O-dealkylation reactions examined with wild-type P450 1A2 and the E225I mutant, which has 6-fold higher activity. A trend of decreasing kinetic deuterium isotope effect for E225I > wild-type > mutant D320A was observed for O-demethylation of p-methoxyacetanilide, which follows the trend for k(cat). The set of O-dealkylation and acetol formation results for wild-type P450 1A2 and the E225I mutant with several of the protiated and deuterated substrates were fit to a model developed for the basic catalytic cycle and a set of microscopic rate constants in which the only variable was the rate of product formation (substrate oxygenation, including hydrogen abstraction). In this model, k(cat) is considerably less than any of the microscopic rate constants and is affected by several individual rate constants, including the rate of formation of the oxygenating species, the rate of substrate oxidation by the oxygenating species, and the rates of generation of reduced oxygen species (H(2)O(2), H(2)O). This analysis of the effects of the individual rate constants provides a framework for consideration of other P450 reactions and rate-limiting steps.