IRON-SULFUR CLUSTER DISASSEMBLY IN THE FNR PROTEIN OF ESCHERICHIA-COLI BY O-2 - [4FE-4S] TO [2FE-2S] CONVERSION WITH LOSS OF BIOLOGICAL-ACTIVITY

The transcription factor FNR (fumarate nitrate reduction) requires the presence of an iron-sulfur (Fe-S) cluster for its function as a globa l transcription regulator in Escherichia coli when oxygen becomes scar ce, To define the oxidation state and type of Fe-S cluster present in the active form of FNR, we have studied anaerobically purified FNR wit h Mossbauer spectroscopy, Our data showed that this form of FNR contai ned a [4Fe-4S](2+) cluster (delta = 0.45 mm/s; Delta E-Q = 1.22 mm/s) and that the [4Fe-4S](2+) cluster was rapidly destroyed on exposure of FNR to air. Under these conditions, the yellow-green active form of F NR turned deep red; analysis of sulfide indicated that 70% of the labi le sulfide was still present, suggesting that the Fe-S cluster had bee n converted into a different form, Little [3Fe-4S] cluster was, howeve r, detected by EPR. According to Mossbauer spectroscopy, the [4Fe-4S]( 2+) cluster was converted in about 60% yield to a [2Fe-2S](2+) cluster (delta = 0.28 mm/s; Delta E-Q = 0.58 mm/s) following 17 min of exposu re to air, The [2Fe-2S](2+) cluster form of FNR was much more stable t o oxygen, but was unable to sustain biological activity (e.g., DNA bin ding), IIowever, DNA binding and the absorption spectrum characteristi c of the [4Fe-4S](2+) cluster could be largely restored from the [2Fe- 2S](2+) form when Cys, Fe, DTT, and the NifS protein were added. It ha s yet to be determined whether the form of FNR containing the [ZFe-2S] (2+) cluster has any biological significance, e.g., as an ill vivo int ermediate that is more rapidly converted to the active form than the a poprotein.