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ARTICLE in PRESS ZRT YJMBI-60577; No ARTICLE IN PRESS ZRT YJMBI-60577; No. of pages: 12; 4C: 5, 7 doi:10.1016/j.jmb.2008.06.060 J. Mol. Biol. (2008) xx, xxx–xxx Available online at www.sciencedirect.com Evolutionary History of a Specialized P450 Propane Monooxygenase Rudi Fasan1, Yergalem T. Meharenna2, Christopher D. Snow1, Thomas L. Poulos2 and Frances H. Arnold1⁎ 1Division of Chemistry and The evolutionary pressures that shaped the specificity and catalytic effi- Chemical Engineering, California ciency of enzymes can only be speculated. While directed evolution expe- Institute of Technology, 1200 riments show that new functions can be acquired under positive selection E. California Blvd., MC 210-41, with few mutations, the role of negative selection in eliminating undesired Pasadena, CA 91125, USA activities and achieving high specificity remains unclear. Here we examine intermediates along the ‘lineage’ from a naturally occurring C –C fatty 2Department of Molecular 12 20 acid hydroxylase (P450 ) to a laboratory-evolved P450 propane mono- Biology & Biochemistry, BM3 oxygenase (P450 ) having 20 heme domain substitutions compared to Chemistry, and Pharmaceutical PMO P450 . Biochemical, crystallographic, and computational analyses Sciences, University of BM3 show that a minimal perturbation of the P450 fold and substrate- California, Irvine, Irvine, BM3 binding pocket accompanies a significant broadening of enzyme substrate CA 92697, USA range and the emergence of propane activity. In contrast, refinement of the Received 22 April 2008; enzyme catalytic efficiency for propane oxidation (∼9000-fold increase in received in revised form kcat/Km) involves profound reshaping and partitioning of the substrate 13 June 2008; access pathway. Remodeling of the substrate-recognition mechanisms accepted 19 June 2008 ultimately results in remarkable narrowing of the substrate profile around propane and enables the acquisition of a basal iodomethane dehalogenase activity as yet unknown in natural alkane monooxygenases. A highly de- stabilizing L188P substitution in a region of the enzyme that undergoes a large conformational change during catalysis plays an important role in adaptation to the gaseous alkane. This work demonstrates that positive selection alone is sufficient to completely respecialize the cytochrome P450 for function on a nonnative substrate. Published by Elsevier Ltd. Keywords: alkane oxidation; protein evolution; directed evolution; propane Edited by F. Schmid monooxygenase; cytochrome P450 BM3 Introduction forces driving the diversification and specialization of enzymes to occupy new functional niches remains Organisms can adapt to changing environments limited. by acquiring alternative biosynthetic pathways Directed evolution experiments have demons- or detoxification mechanisms upon discovery and trated that a small number of mutations can alter subsequent optimization of new enzyme catalysts. enzyme specificity and enhance activity toward 3–8 Despite fundamental contributions from genetic and poor substrates. Catalytic promiscuity and the structural analyses,1,2 our understanding of the ease with which these side activities can be im- proved provide a mechanism for enzyme diversifi- cation in nature.9,10 Although there are cases in *Corresponding author. E-mail address: which having a broad substrate range is linked to [email protected]. the physiological role of the enzyme (e.g., the ability Abbreviations used: PMO, propane monooxygenase; of certain P450s to metabolize a wide array of – MMO, methane monooxygenase; TTN, total turnover xenobiotics),11 14 many enzymes show exceptional number; NPG, N-palmitoylglycine; sMMO, soluble power to discriminate among similar substrates. non-heme diiron methane monooxygenase; GC–ECD, gas How this specialization occurs is largely unknown. chromatography–electron capture detector; FID, flame In the laboratory, newly specialized enzyme var- ionization detector; CRS, cofactor regeneration system. iants have been obtained by applying positive and 0022-2836/$ - see front matter. Published by Elsevier Ltd. Please cite this article as: Fasan, R. et al., Evolutionary History of a Specialized P450 Propane Monooxygenase, J. Mol. Biol. (2008), doi:10.1016/j.jmb.2008.06.060 ARTICLE IN PRESS 2 Evolutionary History of a Specialized P450 Propane Monoxygenase Table 1. Summary of directed evolution steps and amino acid substitutions accumulated in P450BM3 variants Variant Target substrate Mutagenesis method Heme domain substitutionsa 139-3b Octane Random/recombination V78A, H138Y, T175I, V178I, A184V, H236Q, E252G, R255S, A290V, A295T, L353V Jc Propane DNA shuffling Y138H, I178V, F205C, S226R, T295A 35E11d Propane Site saturation–recombination R47C, A78F, A82S, K94I, P142S, A328F ETS8e Stability/propane Site directed L52I, I366V 19A12e Propane Random L188P 11-3e Propane Site saturation A74S 1-3e Propane Recombination V184A – P450PMO Propane Saturation recombination/site directed A74E, S82G, A184V, G443A a Substitutions are given with respect to the preceding variant. b From Ref. 29. c From Ref. 31. d From Ref. 30. This and subsequent variants carry also two mutations in the reductase domain (E464G, I710T). While important for ethane oxidation, these mutations have only a small effect on propane oxidation. e From Ref. 27. negative selection pressures that reinforce the de- improved activity toward octane.29 Further evolution sired phenotype while removing unfavorable side of this variant was directed to improving activity on activities.15,16 Negative selection may guide natural propane.27,30,31 enzyme evolution in those cases where a promis- The entire ‘fossil record’—sequences and biochem- cuous activity has a negative impact on viability, ical properties of all mutants in the lineage, selection leading, for example, to accumulation of toxic inter- pressure, and even the mutational process—is know- mediates or the waste of cellular resources. How- able for laboratory evolution experiments.32 Here, we ever, negative selection may not be required to examine intermediates along the pathway to the achieve high specificity. It has been postulated that P450 propane monooxygenase to investigate how ‘generalist’ enzymes may have to trade off high the applied evolutionary pressure affected the enzy- activity on any one substrate for the ability to recog- me's structure and biochemical properties and to nize and react with a wide range of substrates.17 elucidate the mechanisms by which this novel, ‘Specialist’ enzymes could thus be the natural re- nonnative activity emerged and was refined. sult of maximizing activity on one particular subs- trate and not require negative selection to remove other activities. Specialization under positive selec- Results tion alone, however, has not yet been demonstrated ‘ ’ experimentally. The evolutionary lineage connecting P450BM3 to A large family of heme-containing monooxyge- P450PMO was reconstructed through eight variants. nases comprising more than 7000 known members†, The series begins with the octane-hydroxylating the cytochrome P450s provide an extraordinary variant 139-3 and includes subsequent variants that example of how a conserved structural fold diversi- show at least a twofold increase in propane total fied over millions of years to catalyze oxygenation turnover number (TTN) and/or N10% improvement reactions on widely different substrates.18–20 In addi- in coupling efficiency for propane oxidation compared 27,30,31 tion to their key roles in the breakdown of xeno- to their predecessors. P450PMOR2 carries a biotics, cytochrome P450s catalyze important steps reductase domain mutation (D698G) beneficial to in the biosynthesis of flavonoids,21 alkaloids,22 propane oxidation.27 To facilitate comparison with 23 24 terpenes, sterols, and other natural products. wild-type P450BM3 and other variants, we generated Unlike the xenobiotic-oxidizing P450s, these latter, P450PMO, where Gly698 was reverted to Asp by site- anabolic enzymes tend to display narrow substrate directed mutagenesis. P450PMO is highly active, preference.25,26 We have recently reported the engi- supporting 33,400 turnovers on propane (versus neering of a proficient P450 propane monooxygenase 45,800 for P450PMOR2) with a coupling efficiency of (P450PMOR2) that catalyzes the subterminal hydro- 93% (versus 98% for P450PMOR2). The mutagenesis/ xylation of propane with in vivo activities compar- screening methods used for the isolation of the able to those of naturally occurring alkane mono- selected variants together with their amino acid oxygenases from alkanotrophic organisms.27 This substitutions are summarized in Table 1. enzyme was obtained through multiple rounds of laboratory evolution starting from P450BM3, a long- – Biochemical analysis of P450PMO and its chain (C12 C20) fatty acid hydroxylase from Bacillus evolutionary precursors megaterium that has no measurable activity on 28 propane. Propane activity was first identified in a Changes in the catalytic parameters and stabi- P450BM3 variant (139-3) that was selected for lities of the variants are reported in Fig. 1. Kinetic constants (Km, kcat) for propane oxidation were † http://drnelson.utmem.edu/P450.statsfile.html determined from Michaelis–Menten plots of initial Please cite this article as: Fasan, R. et al., Evolutionary History of a Specialized P450 Propane Monooxygenase, J. Mol. Biol. (2008), doi:10.1016/j.jmb.2008.06.060 ARTICLE IN PRESS Evolutionary History of a Specialized P450 Propane Monoxygenase 3 propanol formation rates at different propane con- centrations.
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