Assembly of iron-sulfur clusters. Identification of an iscSUA-hscBA-fdx gene cluster from Azotobacter vinelandii.

An enzyme having the same L-cysteine desulfurization activity previously described for the NifS protein was purified from a strain of Azotobacter vinelandii deleted for the nifS gene. This protein was designated IscS to indicate its proposed role in iron-sulfur cluster assembly. Like NifS, IscS is a pyridoxal-phosphate containing homodimer. Information gained from microsequencing of oligopeptides obtained by tryptic digestion of purified IscS was used to design a strategy for isolation and DNA sequence analysis of a 7,886-base pair A. vinelandii genomic segment that includes the iscS gene. The iscS gene is contained within a gene cluster that includes homologs to nifU and another gene contained within the major nif cluster of A. vinelandii previously designated orf6. These genes have been designated iscU and iscA, respectively. Information available from complete genome sequences of Escherichia coli and Hemophilus influenzae reveals that they also encode iscSUA gene clusters. A wide conservation of iscSUA genes in nature and evidence that NifU and NifS participate in the mobilization of iron and sulfur for nitrogenase-specific iron-sulfur cluster formation suggest that the products of the iscSUA genes could play a general role in the formation or repair of iron-sulfur clusters. The proposal that IscS is involved in mobilization of sulfur for iron-sulfur cluster formation in A. vinelandii is supported by the presence of a cysE-like homolog in another gene cluster located immediately upstream from the one containing the iscSUA genes. O-Acetylserine synthase is the product of the cysE gene, and it catalyzes the rate-limiting step in cysteine biosynthesis. A similar cysE-like gene is also located within the nif gene cluster of A. vinelandii. The likely role of such cysE-like gene products is to increase the cysteine pool needed for iron-sulfur cluster formation. Another feature of the iscSUA gene cluster region from A. vinelandii is that E. coli genes previously designated as hscB, hscA, and fdx are located immediately downstream from, and are probably co-transcribed with, the iscSUA genes. The hscB, hscA, and fdx genes are also located adjacent to the iscSUA genes in both E. coli and H. influenzae. The E. coli hscA and hscB gene products have previously been shown to bear primary sequence identity when respectively compared with the dnaK and dnaJ gene products and have been proposed to be members of a heat-shock-cognate molecular chaperone system of unknown function. The close proximity and apparent co-expression of iscSUA and hscBA in A. vinelandii indicate that the proposed chaperone function of the hscBA gene products could be related to the maturation of iron-sulfur cluster-containing proteins. Attempts to place non-polar insertion mutations within either A. vinelandii iscS or hscA revealed that such mutations could not be stably maintained in the absence of the corresponding wild-type allele. These results reveal a very strong selective pressure against the maintenance of A. vinelandii iscS or hscA knock-out mutations and suggest that such mutations are either lethal or highly deleterious. In contrast to iscS or hscA, a strain having a polar insertion mutation within the cysE-like gene was readily isolated and could be stably maintained. These results show that the cysE-like gene located upstream from iscS is not essential for cell growth and that the cysE-like gene and the iscSUA-hscBA-fdx genes are contained within separate transcription units.