The crystal structure and spectroscopic properties of the periplasmic penta-heme cytochrome c nitrite reductase (NrfA) of Escherichia coli are presented. The structure is the first for a member of the NrfA subgroup that utilize a soluble penta-heme cytochrome, NrfB, as a redox partner. Comparison to the structures of Wolinella succinogenes NrfA and Sulfospirillum deleyianum NrfA, which accept electrons from a membrane-anchored tetra-heme cytochrome (NrfH), reveals notable differences in the protein surface around heme 2, which may be the docking site for the redox partner. The structure shows that four of the NrfA hemes (hemes 2-5) have bis-histidine axial heme-Fe ligation. The catalytic heme-Fe (heme 1) has a lysine distal ligand and an oxygen atom proximal ligand. Analysis of NrfA in solution by magnetic circular dichroism (MCD) suggested that the oxygen ligand arose from water. Electron paramagnetic resonance (EPR) spectra were collected from electrochemically poised NrfA samples. Broad perpendicular mode signals at g similar 10.8 and 3.5, characteristic of weakly spin-coupled S = 5/2, S = 1/2 paramagnets, titrated with E(m) = -107 mV. A possible origin for these are the active site Lys-OH(2) coordinated heme (heme 1) and a nearby bis-His coordinated heme (heme 3). A rhombic heme Fe(III) EPR signal at g(z) = 2.91, g(y) = 2.3, g(x) = 1.5 titrated with E(m) = -37 mV and is likely to arise from bis-His coordinated heme (heme 2) in which the interplanar angle of the imidazole rings is 21.2. The final two bis-His coordinated hemes (hemes 4 and 5) have imidazole interplanar angles of 64.4 and 71.8. Either, or both, of these hemes could give rise to a "Large g max" EPR signal at g(z)() = 3.17 that titrated at potentials between -250 and -400 mV. Previous spectroscopic studies on NrfA from a number of bacterial species are considered in the light of the structure-based spectro-potentiometric analysis presented for the E. coli NrfA.
Mycobacterium tuberculosis (Mtb) cytochrome P450 gene CYP121 is shown to be essential for viability of the bacterium in vitro by gene knock-out with complementation. Production of CYP121 protein in Mtb cells is demonstrated. Minimum inhibitory concentration values for azole drugs against Mtb H37Rv were determined, the rank order of which correlated well with K d values for their binding to CYP121. Solution-state spectroscopic, kinetic, and thermodynamic studies and crystal structure determination for a series of CYP121 active site mutants provide further insights into structure and biophysical features of the enzyme. Pro 346 was shown to control heme cofactor conformation, whereas Arg 386 is a critical determinant of heme potential, with an unprecedented 280-mV increase in heme iron redox potential in a R386L mutant. A homologous Mtb redox partner system was reconstituted and transported electrons faster to CYP121 R386L than to wild type CYP121. Heme potential was not perturbed in a F338H mutant, suggesting that a proposed P450 superfamily-wide role for the phylogenetically conserved phenylalanine in heme thermodynamic regulation is unlikely. Collectively, data point to an important cellular role for CYP121 and highlight its potential as a novel Mtb drug target.
Crystal Structure of the Mycobacterium tuberculosis P450 CYP121-Fluconazole Complex Reveals New Azole Drug-P450 Binding Mode
Azole and triazole drugs are cytochrome P450 inhibitors widely used as fungal antibiotics and possessing potent antimycobacterial activity. We present here the crystal structure of Mycobacterium tuberculosis cytochrome P450 CYP121 in complex with the triazole drug fluconazole, revealing a new azole heme ligation mode. In contrast to other structurally characterized cytochrome P450 azole complexes, where the azole nitrogen directly coordinates the heme iron, in CYP121 fluconazole does not displace the aqua sixth heme ligand but occupies a position that allows formation of a direct hydrogen bond to the aqua sixth heme ligand. Direct ligation of fluconazole to the heme iron is observed in a minority of CYP121 molecules, albeit with severe deviations from ideal geometry due to close contacts with active site residues. Analysis of both ligand-on and -off structures reveals the relative position of active site residues derived from the I-helix is a key determinant in the relative ratio of on and off states. Regardless, both ligand-bound states lead to P450 inactivation by active site occlusion. This previously unrecognized means of P450 inactivation is consistent with spectroscopic analyses in both solution and in the crystalline form and raises important questions relating to interaction of azoles with both pathogen and human P450s.Fungal infections are successfully treated with azole and triazole drugs that inhibit fungal cytochromes P450 (P450s).5 A major target is the sterol demethylase (CYP51) and inhibition prevents synthesis of the membrane sterol ergosterol from lanosterol (1). This compromises membrane integrity and induces fungal cell lysis. Newer generation azoles and triazoles (e.g. fluconazole and voriconazole) have less severe interactions with human P450s and are used systemically as well as topically (2). Moreover, azoles are potent inhibitors of cell growth in mycobacteria and other actinobacteria (3). Furthermore, recent studies indicate that azole drugs have antitubercular activity in mice (4, 5). These genera have in common a high proportion of P450s, suggesting that azoles exert effects by inhibiting one or more P450 isoforms critical to viability or efficient growth (6). In the pathogen Mycobacterium tuberculosis (Mtb), several azoles have been shown to bind the CYP51 and (more tightly) to the CYP121 P450 (7, 8). Currently, structures of three P450-antifungal azole complexes are available, showing direct coordination of heme iron by azole nitrogen in the case of Mtb CYP51 with fluconazole, Saccharopolyspora erythrae P450 eryF (CYP107A1) with ketoconazole, and rabbit microsomal CYP2B4 with bifonazole (9 -11). Understanding molecular interactions of azoles in P450 active sites provides a route for designing more specific azole-based inhibitors and for rationalizing (and avoiding) development of drug resistance (12). However, if assuming a similar azole-nitrogen heme iron ligation occurs in Mtb CYP121, the tight binding of various azoles to Mtb CYP121 cannot easily be explained on the basis of the l...
Mycobacterium tuberculosis encodes a P450 of the sterol demethylase family (CYP51) chromosomally located adjacent to a ferredoxin (Fdx). CYP51 and Fdx were purified to homogeneity and characterized. Spectroscopic analyses were consistent with cysteinate- and aqua-ligated heme iron in CYP51. An epsilon419 of 134 mM(-1) cm(-1) was determined for oxidized CYP51. Analysis of interactions of 1-, 2-, and 4-phenylimidazoles with CYP51 showed that the 1- and 4-forms were heme iron-coordinating inhibitors, while 2-phenylimidazole induced a substrate-like optical shift. The 2-phenyimidazole-bound CYP51 demonstrated unusual decreases in high-spin heme iron content at elevated temperatures and an almost complete absence of high-spin heme iron by low-temperature EPR. These data suggest thermally induced alterations in CYP51 active site structure and/or binding modes for the small ligand. Reduction of CYP51 in the presence of carbon monoxide leads to formation of an Fe(II)-CO complex with a Soret absorption maximum at 448.5 nm, which collapses (at 0.246 min(-1) at pH 7.0) forming a species with a Soret maximum at 421.5 nm (the inactive P420 form). The rate of P420 formation is accelerated at lower pH, consistent with protonation of the cysteinate (Cys 394) to a thiol underlying the P450-P420 transition. The P450 form is stabilized by estriol, which induces a type I spectral shift on binding CYP51 (Kd = 21.7 microM). Nonstandard spectral changes occur on CYP51 reduction (using either dithionite or natural redox partners), including a blue-shifted Soret band and development of a strong feature at approximately 558.5 nm, suggestive of cysteine thiol ligation. Thus, ligand-free ferrous CYP51 is prone to thiolate ligand protonation even in the absence of carbon monoxide. Analysis of reoxidized CYP51 demonstrates that the enzyme re-forms P450, indicating that Cys 394 thiol is readily deprotonated to thiolate in the ferric form. Spectroscopic analysis of Fdx by EPR (resonance at g = 2.03) and magnetic CD (intensity for oxidized and reduced forms and signal intensity dependence on field strength and temperature) demonstrated that Fdx binds a [3Fe-4S] iron-sulfur cluster. Potentiometric studies show that the midpoint potential for ligand-free CYP51 is -375 mV, increasing to -225 mV in the estriol-bound form. The Fdx potential is -31 mV. Fdx forms a productive electron transfer complex with CYP51 and reduces it at a rate of 3.0 min(-1) in the ligand-free form and 4.3 min(-1) in the estriol-bound form, despite a thermodynamic barrier. Steady-state analysis of a M. tuberculosis class I redox system comprising flavoprotein reductase A (FprA), Fdx, and estriol-bound CYP51 indicates heme iron reduction as a rate-limiting step.
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