6533b82efe1ef96bd12928dc
RESEARCH PRODUCT
CyaC, a redox-regulated adenylate cyclase of Sinorhizobium meliloti with a quinone responsive diheme-B membrane anchor domain.
Joachim E. SchultzThorsten FriedrichGottfried UndenJuliane WissigJens BasslerHeike BähreChristopher SchubertJulia Grischinsubject
Amino Acid Transport SystemsAdenylate kinasemedicine.disease_causeMicrobiologyCyclase03 medical and health sciencesmedicineBenzoquinonesNucleotideHistidineAmino Acid SequenceMolecular BiologyEscherichia coliHistidine030304 developmental biologychemistry.chemical_classification0303 health sciencesSinorhizobium melilotibiology030306 microbiologyEscherichia coli ProteinsGuanylate cyclase activityQuinonesMembrane Proteinsbiology.organism_classificationchemistryBiochemistryGenes BacterialHeterologous expressionOxidation-ReductionAdenylyl CyclasesSinorhizobium melilotidescription
The nucleotide cyclase CyaC of Sinorhizobium meliloti is a member of class III adenylate cyclases (AC), a diverse group present in all forms of life. CyaC is membrane-integral by a hexahelical membrane domain (6TM) with the basic topology of mammalian ACs. The 6TM domain of CyaC contains a tetra-histidine signature that is universally present in the membrane anchors of bacterial diheme-B succinate-quinone oxidoreductases. Heterologous expression of cyaC imparted activity for cAMP formation from ATP to Escherichia coli, whereas guanylate cyclase activity was not detectable. Detergent solubilized and purified CyaC was a diheme-B protein and carried a binuclear iron-sulfur cluster. Single point mutations in the signature histidine residues caused loss of heme-B in the membrane and loss of AC activity. Heme-B of purified CyaC could be oxidized or reduced by ubiquinone analogs (Q0 or Q0 H2 ). The activity of CyaC in bacterial membranes responded to oxidation or reduction by Q0 and O2 , or NADH and Q0 H2 respectively. We conclude that CyaC-like membrane anchors of bacterial ACs can serve as the input site for chemical stimuli which are translated by the AC into an intracellular second messenger response.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-04-10 | Molecular microbiology |