The aconitase family: three structural variations on a common theme

Citrate synthase and 2-methylcitrate synthase: structural, functional and evolutionary relationships

Following the complete sequencing of the Escherichia coli genome, it has been shown that the proposed second citrate synthase of this organism, recently described by the authors, is in fact a 2-methylcitrate synthase that possesses citrate synthase activity as a minor component. Whereas the hexameric citrate synthase is constitutively produced, the 2-methylcitrate synthase is induced during growth on propionate, and the catabolism of propionate to succinate and pyruvate via 2-methylcitrate is proposed. The citrate synthases of the psychrotolerant eubacterium DS2-3R, and of the thermophilic archaea Thermoplasma acidophilum and Pyrococcus furiosus, are approximately 40% identical in sequence to the Escherichia coli 2-methylcitrate synthase and also possess 2-methylcitrate synthase activity. The data are discussed with respect to the structure, function and evolution of citrate synthase and 2-methylcitrate synthase.

Determination of a 15437 bp nucleotide sequence around the inhA gene of Mycobacterium avium and similarity analysis of the products of putative ORFs

A 15437 bp region encompassing the inhA locus from the Mycobacterium avium chromosome was cloned and sequenced. From the sequencing data generated and the results of homology searches, the primary structure of this region was determined. This region contains four known genes (acnA, fabG, inhA and hemH) and two genes, invA and invB, whose products display homology with p60 invasion protein of Listeria monocytogenes. Six proteins encoded by putative ORFs contained an RGD motif (often involved in binding to macrophage integrins), while ORF1 and MoxR are probably transcriptional regulators. The rest of the putative products encoded by ORFs in the sequenced region showed little homology with the proteins contained in the databases and were considered to be unknown proteins.

Transcriptional regulation of the aconitase genes (acnA and acnB) of Escherichia coli

Escherichia coli contains two differentially regulated aconitase genes, acnA and acnB. Two acnA promoters transcribing from start points located 407 bp (P1acnA) and 50 bp (P2acnA) upstream of the acnA coding region, and one acnB promoter (PacnB) with a start point 95 bp upstream of the acnB coding region, were identified by primer extension analysis. A 2.8 kb acnA monocistronic transcript was detected by Northern blot hybridization, but only in redox-stressed (methyl-viologen-treated) cultures, and a 2.5 kb acnB monocistronic transcript was detected in exponential- but not stationary-phase cultures. These findings are consistent with previous observations that acnA is specifically subject to SoxRS-mediated activation, whereas acnB encodes the major aconitase that is synthesized earlier in the growth cycle than AcnA. Further studies with acn-lacZ gene fusions and a wider range of transcription regulators indicated that acnA expression is initiated by sigma 38 from P1acnA, and from P2acnA it is activated directly or indirectly by CRP, FruR, Fur and SoxRS, and repressed by ArcA and FNR. In contrast, acnB expression is activated by CRP and repressed by ArcA, FruR and Fis from PacnB. Comparable studies with fum-lacZ fusions indicated that transcription of fumC, but not of fumA or fumB, is initiated by RNA polymerase containing sigma 38. It is concluded that AcnB is the major citric acid cycle enzyme, whereas AcnA is an aerobic stationary-phase enzyme that is specifically induced by iron and redox-stress.

An EPR investigation of the products of the reaction of cytosolic and mitochondrial aconitases with nitric oxide

Cellular studies have indicated that some Fe-S proteins, and the aconitases in particular, are targets for nitric oxide. Specifically, NO has been implicated in the intracellular process of the conversion of active cytosolic aconitase containing a [4Fe-4S] cluster, to its apo-form which functions as an iron-regulatory protein. We have undertaken the in vitro study of the reaction of NO with purified forms of both mitochondrial and cytosolic aconitases by following enzyme activity and by observing the formation of EPR signals not shown by the original reactants. Inactivation by either NO solutions or NO-producing NONOates under anaerobic conditions is seen for both enzyme isoforms. This inactivation, which occurs in the presence or absence of substrate, is accompanied by the appearance of the g = 2.02 signals of the [3Fe-4S] clusters and the g approximately 2.04 signal of a protein-bound dinitrosyl-iron-dithiol complex in the d7 state. In addition, in the reaction of cytosolic aconitase, the transient formation of a thiyl radical, g parallel = 2.11 and g perpendicular = 2.03, is observed. Disassembly of the [3Fe-4S] clusters of the inactive forms of the enzymes upon the anaerobic addition of NO is also accompanied by the formation of the g approximately 2.04 species and in the case of mitochondrial aconitase, a transient signal at g approximately 2. 032 appeared. This signal is tentatively assigned to the d9 form of an iron-nitrosyl-histidyl complex of the mitochondrial protein. Inactivation of the [4Fe-4S] forms of both aconitases by either superoxide anion or peroxynitrite produces the g = 2.02 [3Fe-4S] proteins.

Construction and properties of aconitase mutants of Escherichia coli

Escherichia coli contains two genes (acnA and acnB) encoding aconitase activities. An acnB mutant was engineered by replacing the chromosomal acnB gene by an internally deleted derivative containing a tetR cassette. An acnB double mutant was then made by transducing a previously constructed acnA::kanR mutation into the acnB::tetR strain. Western blotting confirmed that the AcnA and AcnB proteins were no longer produced by the corresponding mutants and PCR analysis showed that the chromosomal acnB gene had been replaced by the disrupted gene. Aerobic and anaerobic growth in glucose minimal medium were impaired but not abolished by the acnB mutation, indicating that the lesion is partially complemented by the acnA+ gene, and growth was enhanced by glutamate. The acnAB double mutant would not grow on unsupplemented glucose minimal medium and although it responded to glutamate like a typical auxotroph under anaerobic conditions, under aerobic conditions no response to glutamate was observed before it was over-grown by 'revertants' lacking citrate synthase (acnAB gltA). The acnAB double mutant retained a low but significant aconitase activity (< or = 5% of wild-type), designated AcnC. Enzymological and regulatory studies with acn-lacZ fusions indicated that AcnB is the major aconitase, which is synthesized earlier in the growth cycle than AcnA, and subject to catabolite and anaerobic repression.