2013
DOI: 10.1002/ange.201302137
|View full text |Cite
|
Sign up to set email alerts
|

Driving Force for Oxygen‐Atom Transfer by Heme‐Thiolate Enzymes

Abstract: The heme-thiolate peroxygenase from Agrocybe aegerita (AaeAPO, EC 1.11.2.1) is a versatile biocatalyst and cytochrome P450 analogue which catalyzes a variety of oxygenation reactions with high efficiency and selectivity.[1] Our recent kinetic characterization of AaeAPO-catalyzed reactions has shown that AaeAPO compound I is an oxo-Fe IV porphyrin radical cation.[2] The reactivity of AaeAPO-I toward a panel of substrates showed very fast C À H hydroxylation rates, similar to those of cytochrome P450 (CYP119-I),… Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
2
1
1

Citation Types

2
25
0

Year Published

2014
2014
2017
2017

Publication Types

Select...
7
2

Relationship

4
5

Authors

Journals

citations
Cited by 19 publications
(27 citation statements)
references
References 49 publications
2
25
0
Order By: Relevance
“…We assign this spectrum to APO-II based on the characteristic split Soret band (370 nm and 428 nm) and two Q bands centered at 535 nm and 567 nm, slightly blue shifted from those of the ferric state (18). APO-I is the dominant intermediate by reacting ferric APO with an oxidant only, such as mCPBA (29,30). However, with the presence of nitroxyl radical, the accumulation of APO-I was not apparent.…”
Section: Significancementioning
confidence: 98%
See 1 more Smart Citation
“…We assign this spectrum to APO-II based on the characteristic split Soret band (370 nm and 428 nm) and two Q bands centered at 535 nm and 567 nm, slightly blue shifted from those of the ferric state (18). APO-I is the dominant intermediate by reacting ferric APO with an oxidant only, such as mCPBA (29,30). However, with the presence of nitroxyl radical, the accumulation of APO-I was not apparent.…”
Section: Significancementioning
confidence: 98%
“…This intermediate was shown to be highly competent for the hydroxylation of even strong C−H bonds. Further, APO-I reacts with chloride and bromide ions rapidly and reversibly, allowing a direct determination of the thermodynamics of oxygen transfer by APO-I (E' = 1.2 V) (30). Here, we report a previously unidentified method of generating the elusive ferryl state, APO-II, directly from APO-I over a wide range of pH.…”
mentioning
confidence: 98%
“…S8), would lead to generation of a carbocation poised for C−Cα cleavage to liberate CO 2 . Although the intrinsic reactivity of Ole-II is most likely undervalued here, largely due to limitations that stem from its method of preparation, the estimated reduction potential (51) and oxidative prowess of APO-II (46) serve as a useful guide. As olefin and alcohol products result from the metabolism of chemically similar substrates, both rigid and precise positioning of a carbon-centered radical would seem necessary to inhibit oxygen rebound.…”
Section: Significancementioning
confidence: 99%
“…Despite the great variety of chemical transformations catalyzed by cytochromes P450, the vast majority of them are undoubtedly driven by Compound I This ferryl-oxo intermediate with a π-cation radical delocalized on the porphyrin is a very reactive species All attempts to observe this species in a P450 system using atmospheric dioxygen have so far failed However, important spectroscopic characterization and reactivity measurements have been obtained by using the [227][228][229][230] or by analogy to other closely related thiolate-ligated heme enzymes such as CPO [231][232][233] and peroxygenases [234,235], for which Comopund I is much more stable This situation changed with the work of Rittle and Green who achieved a breakthrough on the peroxide pathway by radically improving the purification protocol for thermostable CYP119 from the extremophile archae Sulfolobus acidocaldarius [236][237][238] Careful multistep removal of endogenous substrate analogs from the purified, heterologously expressed protein, which hampered earlier studies [222], allowed them to dramatically increase the yield of Compound I in a stopped-flow reaction with m-CPBA, reach-ing a conversion of greater than 75 % [236] This made possible high-precision UV-vis spectra to quantitate the reaction kinetics, which in turn provided the necessary information for the preparation of highly concentrated samples for EPR and Mössbauer spectroscopy The UV-vis spectra of Compound I confirmed the main features of the ferryl-oxo π-cation radical known from the earlier experiments: a broad Soret band at 367 nm and a pronounced charge-transfer band at 690 nm The EPR spectrum of CYP119 Compound I [236] had a different shape as compared to that previously reported for CPO, another thiolate-ligated heme protein [239] Fitting of both spectra to the S = 1 Fe(IV)-oxo unit coupled with S = 1/2 porphyrin radical resulted in a higher ratio of the exchange coupling ( J) to zero-field splitting ( D) for CYP119 ( J/D = 1.3) than in CPO ( J/D = 1.02) [236] The higher J value in CYP119 was tentatively attributed to either a higher spin density on the thiolate sulfur atom or a shortened Fe-S bond The Mössbauer parameters measured for the CYP119 Compound I were more similar to those of CPO [239], with the isomer shift δ = 0.11 mm/s (0.13 mm/s for CPO) and quadrupole splitting ΔE Q = 0.96 mm/s (0.90 mm/s for CPO) These parameters also correspond to the ferryl-oxo S = 1 unit exchange coupled to the porphyrin radical (S = 1/2).…”
Section: Compound I As the "Active Oxygen" In Alkane Hydroxylationsmentioning
confidence: 98%