Nitrile hydratases (NHase) are non-heme Fe(III)-containing, or noncorrinoid Co(III)-containing, microbial enzymes that catalyze nitrile hydration. 1 The iron form has been studied most extensively. The Fe(III) active site is low spin (S ) 1 / 2 ), and ligated by three cysteinates, two peptide amide nitrogens and either a hydroxide or an NO. [2][3][4] Given the high amount of sequence homology in the active site region, it is likely that the Co-NHase active site is virtually identical to Fe-NHase. 1,5 In one of two recent Fe NHase crystal structures 2,4 two of the metal-bound sulfurs appear to be oxidized, one to a sulfenate ( 114 S cys dO) and the other to a sulfinate ( 112 S cys (dO) 2 ). 4 The sulfenate is not observed by mass spectrometry. 6 Sulfenic acids are usually unstable, 7 and metal-sulfenates are readily oxidized to metalsulfinates. 8,9 A few synthetic NHase models containing oxidized sulfurs have been reported; 10-12 however, none of these incorporate a sulfenate, and only one 12 has an open coordination site.Our group has shown that the spin-state and spectroscopic properties of Fe-NHase can be nicely reproduced by six-coordinate Fe(III) model complexes containing two cis-thiolates and imines. 3,13-15 These models lack oxidized sulfurs, yet their spectroscopic properties are remarkably similar to the enzyme, suggesting that two, of the three, cysteinate NHase sulfurs remain unmodified. To understand how the sulfinate and, possibly, the sulfenate sulfur influences the electronic and reactivity properties of NHase, we have synthesized a series of sulfur-ligated, fivecoordinate Co(III) model complexes containing progressively more oxidized sulfurs.Five-coordinate [Co(III)(S 2 Me2 N 3 (Pr,Pr))] + (1) was synthesized in the same manner as its iron analogue. 15 Complex 1 is intermediate spin (S ) 1) over the temperature range 50-300 K (supplemental Figure S-1), and is reversibly reduced at E 1/2 ) -460 mV vs SCE. The average Co-S distance (2.16(2) Å) in 1 (Figure 1) 16 is shorter than most Co(III) thiolates (average ) 2.24 Å). [17][18][19] Azide and SCN -bind quantitatively to 1 at room temperature trans to one of the thiolate sulfurs. 20 Trigonal bipyramidal 1 (τ ) 0.87) 21 is converted to a more square pyramidal (τ ) 0.48) sulfinate/thiolate-ligated complex, [Co(III)(S Me2 (S O2 )N 3 (Pr,Pr))] + (2; Figure 2), 22 upon stirring in air for 3 days. Only one of the two thiolate sulfurs (S(2)) is oxidized, even upon prolonged stirring. Oxidation of S(2) causes the spinstate to change, from S ) 1 (in 1) to 0 (in 2), and the reduction potential to shift cathodically to E 1/2 ) -380 mV vs SCE. The mean S(2)-O(1,2) distance (1.453(2) Å) in 2 falls in the usual range (1.42-1.48 Å). 17,23,24 The Co-S(2) distance in 2 is indistinguishable from Co-S(1) (Figure 2). Both of the Co-S bonds in 2 are slightly shorter than the Co-S bonds in 1, because (1) Kobayashi, M.; Shimizu, S. Nature Biotechnol. 1998, 16, 733-36. (2) Huang, W.; Jia, J.; Cummings, J.; Nelson, M.; Schneider, G.; Lindqvist, Y. Structure 1997, 5, 691-6...
