Miner Kyle D, Pfister Thomas D, Hosseinzadeh Parisa, Karaduman Nadime, Donald Lynda J, Loewen Peter C, Lu Yi, Ivancich Anabella
CNRS, Unité de Recherche Mixte CNRS/CEA/Université Paris-Sud (UMR 8221), Laboratoire de Bioénergétique, Métalloprotéines et Stress. Centre d'Etudes de Saclay, iBiTec-S, 91191 Gif-sur-Yvette, France.
Biochemistry. 2014 Jun 17;53(23):3781-9. doi: 10.1021/bi500353p. Epub 2014 Jun 5.
The location of the Trp radical and the catalytic function of the [Fe(IV)═O Trp₁₉₁(•+)] intermediate in cytochrome c peroxidase (CcP) are well-established; however, the unambiguous identification of the site(s) for the formation of tyrosyl radical(s) and their possible biological roles remain elusive. We have now performed a systematic investigation of the location and reactivity of the Tyr radical(s) using multifrequency Electron Paramagnetic Resonance (EPR) spectroscopy combined with multiple-site Trp/Tyr mutations in CcP. Two tyrosines, Tyr71 and Tyr236, were identified as those contributing primarily to the EPR spectrum of the tyrosyl radical, recorded at 9 and 285 GHz. The EPR characterization also showed that the heme distal-side Trp51 is involved in the intramolecular electron transfer between Tyr71 and the heme and that formation of Tyr₇₁(•) and Tyr₂₃₆(•) is independent of the [Fe(IV)═O Trp₁₉₁(•+)] intermediate. Tyr71 is located in an optimal position to mediate the oxidation of substrates binding at a site, more than 20 Å from the heme, which has been reported recently in the crystal structures of CcP with bound guaicol and phenol [Murphy, E. J., et al. (2012) FEBS J. 279, 1632-1639]. The possibility of discriminating the radical intermediates by their EPR spectra allowed us to identify Tyr₇₁(•) as the reactive species with the guaiacol substrate. Our assignment of the surface-exposed Tyr236 as the other radical site agrees well with previous studies based on MNP labeling and protein cross-linking [Tsaprailis, G., and English, A. M. (2003) JBIC, J. Biol. Inorg. Chem. 8, 248-255] and on its covalent modification upon reaction of W191G CcP with 2-aminotriazole [Musah, R. A., and Goodin, D. B. (1997) Biochemistry 36, 11665-11674]. Accordingly, while Tyr71 acts as a true reactive intermediate for the oxidation of certain small substrates that bind at a site remote from the heme, the surface-exposed Tyr236 would be more likely related to oxidative stress signaling, as previously proposed. Our findings reinforce the view that CcP is the monofunctional peroxidase that most closely resembles its ancestor enzymes, the catalase-peroxidases, in terms of the higher complexity of the peroxidase reaction [Colin, J., et al. (2009) J. Am. Chem. Soc. 131, 8557-8563]. The strategy used to identify the elusive Tyr radical sites in CcP may be applied to other heme enzymes containing a large number of Tyr and Trp residues and for which Tyr (or Trp) radicals have been proposed to be involved in their peroxidase or peroxidase-like reaction.
色氨酸自由基在细胞色素c过氧化物酶(CcP)中的位置以及[Fe(IV)═O Trp₁₉₁(•+)]中间体的催化功能已得到充分证实;然而,酪氨酸自由基形成位点的明确鉴定及其可能的生物学作用仍然难以捉摸。我们现在使用多频电子顺磁共振(EPR)光谱结合CcP中的多位点色氨酸/酪氨酸突变,对酪氨酸自由基的位置和反应性进行了系统研究。在9和285 GHz记录的EPR光谱中,确定了两个酪氨酸Tyr71和Tyr236是主要贡献酪氨酸自由基EPR光谱的位点。EPR表征还表明,血红素远端的色氨酸Trp51参与了Tyr71与血红素之间的分子内电子转移,并且Tyr₇₁(•)和Tyr₂₃₆(•)的形成与[Fe(IV)═O Trp₁₉₁(•+)]中间体无关。Tyr71位于一个最佳位置,可介导在距血红素超过20 Å的位点结合的底物的氧化,这在最近报道的结合愈创木酚和苯酚的CcP晶体结构中已有体现[Murphy, E. J.,等人(2012年)《FEBS杂志》279卷,1632 - 1639页]。通过EPR光谱区分自由基中间体的可能性使我们能够确定Tyr₇₁(•)是与愈创木酚底物反应的活性物种。我们将表面暴露的Tyr236指定为另一个自由基位点,这与之前基于MNP标记和蛋白质交联的研究[Tsaprailis, G.和English, A. M.(2003年)《JBIC,生物无机化学杂志》8卷,248 - 255页]以及W191G CcP与2 - 氨基三唑反应后的共价修饰研究[Musah, R. A.和Goodin, D. B.(1997年)《生物化学》36卷,11665 - 1167页]非常吻合。因此,虽然Tyr71作为某些在远离血红素的位点结合的小底物氧化的真正活性中间体,但如先前提出的那样,表面暴露的Tyr236更可能与氧化应激信号传导有关。我们的发现强化了这样一种观点,即就过氧化物酶反应的更高复杂性而言,CcP是最类似于其祖先酶过氧化氢酶 - 过氧化物酶的单功能过氧化物酶[Colin, J.,等人(2009年)《美国化学会志》131卷,8557 - 8563页]。用于鉴定CcP中难以捉摸的酪氨酸自由基位点的策略可应用于其他含有大量酪氨酸和色氨酸残基且已提出酪氨酸(或色氨酸)自由基参与其过氧化物酶或类过氧化物酶反应的血红素酶。
