N. Gupta et al., RECOMBINANT DESULFOVIBRIO-VULGARIS RUBRERYTHRIN - ISOLATION AND CHARACTERIZATION OF THE DIIRON DOMAIN, Biochemistry, 34(10), 1995, pp. 3310-3318
The gene encoding Desulfovibrio (D.) vulgaris rubrerythrin (Prickril,
B. C,, Kurtz, D. M., Jr., LeGall, J., and Voordouw, G. (1991) Biochemi
stry 30, 1118), a protein of unknown function containing both FeS4 and
(mu-oxo)diiron sites, was cloned and overexpressed in Escherichia col
i. Upon cell lysis, the overexpressed protein was found in an insolubl
e form deficient in iron. Iron was incorporated in vitro by dissolving
the protein in 3 M guanidinium chloride, adding Fe(II) anaerobically
and diluting the denaturant. This recombinant rubrerythrin was found t
o have properties very similar to those of rubrerythrin isolated from
D. vulgaris, except that the recombinant rubrerythrin contained six ra
ther than four (or five) iron atoms per 44 kDa homodimer. Analyses of
UV-vis, Mossbauer, and EPR spectra showed that the six iron atoms in r
ecombinant rubrerythrin are organized as two FeS4 and two (mu-oxo/hydr
oxo)diiron sites. In order to allow examination of the diiron sites in
the absence of the FeS4 sites, a truncated gene encoding the N-termin
al 152 residues of D. vulgaris rubrerythrin was also cloned and overex
pressed as an insoluble protein in E. coil, and iron was incorporated
by a procedure analogous to that for recombinant rubrerythrin. This so
-called ''chopped'' rubrerythrin (CRr) was found to consist of an appr
oximate to 35 kDa homodimer containing four iron atoms. Spectroscopic
characterization indicated that the four iron atoms in CRr are organiz
ed as two diiron sites, the majority of which closely resemble the (mu
-oxo)diiron(III) sites in E. coil ribonucleotide reductase R2 protein,
and a minor fraction of which resemble the mixed-valent diiron(II,III
) site in methane monooxygenase hydroxylase. Both the diiron(III) and
diiron(II) sites of CRr were shown by UV-vis and Mossbauer spectroscop
ies to form complexes with azide. The diiron(II)CRr azide adduct could
be detected by a parallel-mode EPR signal at g approximate to 17.5. A
similar parallel-mode EPR signal at g approximate to 19.8 was detecte
d when excess azide was added to the reduced recombinant rubrerythrin.
EPR-based redox titrations of CRr gave diiron(III)-to-mixed-valent an
d mixed-valent-to-diiron(II) reduction potentials of 215 +/- 5 and 154
+/- 5 mV, respectively, vs NHE. These potentials were approximately 7
0 mV more negative than those measured for the corresponding redox cou
ples in recombinant rubrerythrin. Possible activities for rubrerythrin
are discussed.