Molybdenum-independent nitrogenases of Azotobacter vinelandii: a functional species of alternative nitrogenase-3 isolated from a molybdenum-tolerant strain contains an iron-molybdenum cofactor.

Nitrogenase-3 of Azotobacter vinelandii is synthesized under conditions of molybdenum and vanadium deficiency. The minimal metal requirement for its synthesis, and its metal content, indicated that the only transition metal in nitrogenase-3 was iron [Chisnell, Premakumar and Bishop (1988) J. Bacteriol. 170, 27-33; Pau, Mitchenall and Robson (1989) J. Bacteriol. 171, 124-129]. A new species of nitrogenase-3 has been purified from a strain of A. vinelandii (RP306) lacking structural genes for the Mo- and V-nitrogenases and containing a mutation which enables nitrogenase-3 to be synthesized in the presence of molybdenum. SDS/PAGE showed that component 1 contained a 15 kDa polypeptide which N-terminal amino acid sequence determination showed to be encoded by anfG. This confirms that nitrogenase-3, like V-nitrogenase, comprises three subunits. Preparations of the nitrogenase-3 from strain RP306 contained 24 Fe atoms and 1 Mo atom per molecule. Characterization of the cofactor centre of the enzyme by e.p.r. spectroscopy and an enzymic cofactor assay, together with stimulation of the growth of strain RP306 by Mo, showed that nitrogenase-3 can incorporate the Mo-nitrogenase cofactor (FeMoco) to form a functional enzyme. The specific activities (nmol of product produced/min per mg of protein) determined from activity titration curves were: under N2, NH3 formation 110, with concomitant H2 evolution of 220; under argon, H2 evolution 350; under 10% acetylene (C2H2) in argon, ethylene (C2H4) 58, ethane (C2H6) 26, and concomitant H2 evolution 226. The rate of formation of C2H6 was non-linear, and the C2H6/C2H4 ratio strongly dependent on the ratio of nitrogenase components.

The molybdenum and vanadium nitrogenases of Azotobacter chroococcum: effect of elevated temperature on N2 reduction.

During the reduction of N2 by V-nitrogenase at 30 degrees C, some hydrazine (N2H4) is formed as a product in addition to NH3 [Dilworth and Eady (1991) Biochem. J. 277, 465-468]. We show here the following. (1) That over the temperature range 30-45 degrees C the apparent Km for the reduction of N2 to yield these products is the same, but increases from 30 to 58 kPa of N2. On increasing the temperature from 45 degrees C to 50 degrees C, little change occurred in the rate of reduction of protons to H2; the rate of N2H4 production increased, but the rate of NH3 formation decreased 7-fold. (2) Temperature-shift experiments from 42 to 50 degrees C or from 50 to 42 degrees C showed that this selective loss of the ability to reduce N2 to NH3 was reversible. The effects we observe are consistent with the existence of different conformers of the VFe-protein at the two temperatures, that predominating at 50 degrees C being largely unable to reduce N2 to ammonia. (3) Measurement of the ratio between H2 evolution and N2 reduced to NH3 at N2 pressures up to 339 kPa for both Mo- and V-nitrogenases gave limiting H2/N2 values of 1.13 +/- 0.13 for Mo-nitrogenase and 3.50 +/- 0.03 for V-nitrogenase. Since for Mo-nitrogenase our measured value for the ratio at 339 kPa is the same as that derived by Simpson and Burris [(1984) Science 224, 1095-1097] at 5650 kPa, there appears to be little or no divergence from the predictions based on the apparent Km for N2. These data then suggest that there may be a fundamentally different mechanism for N2 binding to V-nitrogenase compared with Mo-nitrogenase. (4) We did not detect any N2H4 as a product of N2 reduction by Mo-nitrogenase over the temperature range investigated; however, at 50 degrees C this system reduced acetylene (C2H2) to yield some ethane (C2H6), in addition to ethylene (C2H4), a reaction normally associated with Mo-independent nitrogenases.

Correction for creatine interference with the direct indophenol measurement of NH3 in steady-state nitrogenase assays.

Creatine was identified as a major source of interference with the direct phenol/hypochlorite colorimetric determination of ammonia in nitrogenase reaction mixtures. A method is described for removing other compounds which inhibit color development and for compensating for the interference produced by creatine. This method avoids time-consuming microdiffusion and also routinely makes available the efficiency of ATP hydrolysis coupled to substrate reduction (ATP/2e ratio) with N2 as a reducible substrate. Using this method we determined values for this ratio at 30 degrees C of 4.87 +/- 0.03 during the reduction of protons to H2 and 7.16 +/- 0.14 during the reduction of N2 by the vanadium-containing nitrogenase of Azotobacter chroococcum.

The vanadium nitrogenase of Azotobacter chroococcum. Reduction of acetylene and ethylene to ethane.

1. The vanadium (V-) nitrogenase of Azobacter chroococcum transfers up to 7.4% of the electrons used in acetylene (C2H2) reduction for the formation of ethane (C2H6). The apparent Km for C2H2 (6 kPa) is the same for either ethylene (C2H4) or ethane (C2H6) formation and much higher than the reported Km values for C2H2 reduction to C2H4 by molybdenum (Mo-) nitrogenases. Reduction of C2H2 in 2H2O yields predominantly [cis-2H2]ethylene. 2. The ratio of electron flux yielding C2H6 to that yielding C2H4 (the C2H6/C2H4 ratio) is increased by raising the ratio of Fe protein to VFe protein and by increasing the assay temperature up to at least 40 degrees C. pH values above 7.5 decrease the C2H6/C2H4 ratio. 3. C2H4 and C2H6 formation from C2H2 by V-nitrogenase are not inhibited by H2. CO inhibits both processes much less strongly than it inhibits C2H4 formation from C2H2 with Mo-nitrogenase. 4. Although V-nitrogenase also catalyses the slow CO-sensitive reduction of C2H4 to C2H6, free C2H4 is not an intermediate in C2H6 formation from C2H2. 5. Propyne (CH3C identical to CH) is not reduced by the V-nitrogenase. 6. Some implications of these results for the mechanism of C2H6 formation by the V-nitrogenase are discussed.