Abstract
In previous work, we identified a triple mutant of the castor (Ricinus communis) stearoyl-Acyl Carrier Protein desaturase (T117R/G188L/D280K) that, in addition to introducing a double bond into stearate to produce oleate, performed an additional round of oxidation to convert oleate to a trans allylic alcohol acid. To determine the contributions of each mutation, in this work we generated individual castor desaturase mutants carrying residue changes corresponding to those in the triple mutant and investigated their catalytic activities. We observed that T117R, and to a lesser extent D280K, accumulated a novel product, namely erythro-9,10-dihydroxystearate, that we identified via its methyl ester through gas chromatography-mass spectrometry and comparison with authentic standards. The use of 18O2 labeling showed that the oxygens of both hydroxyl moieties originate from molecular oxygen rather than water. Incubation with an equimolar mixture of 18O2 and 16O2 demonstrated that both hydroxyl oxygens originate from a single molecule of O2, proving the product is the result of dioxygenase catalysis. Using prolonged incubation, we discovered that wild-type castor desaturase is also capable of forming erythro-9,10-dihydroxystearate, which presents a likely explanation for its accumulation to ∼0.7% in castor oil, the biosynthetic origin of which had remained enigmatic for decades. In summary, the findings presented here expand the documented constellation of di-iron enzyme catalysis to include a dioxygenase reactivity in which an unactivated alkene is converted to a vicinal diol.
Highlights
Diiron clusters within the active sites of enzymes facilitate the binding of molecular oxygen and its derivatives and are able to perform redox chemistry, which results in a range of chemical outcomes (Edmondson and Juynh, 1996)
All diiron enzymes characterized to date belong to one of two separate classes, one soluble and the other membrane bound (Shanklin and Somerville, 1991)
We showed that the conversion of (Z)-9-18:1 substrate to (E)-10-18:1-9-OH product by castor desaturase T117R/G188L/D280K proceeds via hydrogen abstraction at C-11 and highly regioselective hydroxylation (>97%) at C-9 (Whittle et al, 2008). 18O
Summary
Diiron clusters within the active sites of enzymes facilitate the binding of molecular oxygen and its derivatives and are able to perform redox chemistry, which results in a range of chemical outcomes (Edmondson and Juynh, 1996). All diiron enzymes characterized to date belong to one of two separate classes, one soluble and the other membrane bound (Shanklin and Somerville, 1991) Both classes have the ability to catalyze the oxidation of unactivated C-H bonds to give a range of chemical outcomes (Shanklin and Cahoon, 1998; Fox et al, 2004). Both soluble and membrane diiron enzyme classes contain desaturase enzymes that perform the stereo- and regioselective introduction of Z- (cis) double bonds into unactivated lipid acyl chains. As predicted by Bloch (Bloch, 1969) and subsequently confirmed by X-ray crystallography (Lindqvist et al, 1996; Bai et al, 2015), the boomerang shape of the substrate binding channel within the desaturase drives the formation of the (Z)-olefinic fatty acids
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