Effects on substrate reduction of substitution of histidine-195 by glutamine in the alpha-subunit of the MoFe protein of Azotobacter vinelandii nitrogenase
Mj. Dilworth et al., Effects on substrate reduction of substitution of histidine-195 by glutamine in the alpha-subunit of the MoFe protein of Azotobacter vinelandii nitrogenase, BIOCHEM, 37(50), 1998, pp. 17495-17505
Studies of the substrate-reducing capabilities of an altered nitrogenase Mo
Fe protein (alpha-195(Gln) instead of alpha-195(His)) from a mutant of Azot
obacter vinelandii show, contrary to an earlier report [Kim, C.-H., Newton,
W. E., and Dean, D. R. (1995) Biochemistry 34, 2798-2808], that the alpha-
195(Gln) MoFe protein can reduce N-2 to NH3 but at a rate that is <2% of th
at of the wild type. The extent of effective binding of N-2 by this altered
MoFe protein, as monitored by the inhibition of H-2 evolution, is markedly
increased as temperature is lowered but virtually eliminated at 45 degrees
C. This inhibition of H-2 evolution results in an increase in the ATP:2e(-
) ratio, i.e., the number of molecules of MgATP hydrolyzed for each electro
n pair transferred to substrate, from ca. 5 (the wild-type level) at 45 deg
rees C to nearly 25 at 13 degrees C. Like wild-type nitrogenase, the N-2 in
hibition of H-2 evolution reaches a maximum at an Fe protein:MoFe protein m
olar ratio of ca. 2.5, suggesting that a highly reduced enzyme may not be n
ecessary for N-2 binding. N-2 binding to the alpha-195(Gln) MoFe protein re
tains a hallmark of the wild type by producing HD under a mixed N-2/D-2 atm
osphere. The rate of HD production and the fraction of total electron flow
allocated to HD are similar to those for wild-type nitrogenase under the sa
me conditions. However, the electrons forming HD do not come from those nor
mally producing NH3 (as occurs in the wild type) but are equivalent to thos
e whose evolution as H-2 had been inhibited by N-2. N-2 also inhibits C2H2
reduction catalyzed by the alpha-195(Gln) nitrogenase. This inhibition is r
elieved by added H-2, resulting in a lowering of the elevated ATP:2e(-) rat
io to that found under Ar. With solutions of NaCN, which contain both the s
ubstrate, HCN, and the inhibitor CN-, reduction of HCN is not impaired with
the alpha-195(Gln) nitrogenase, but the inhibition by CN- of total electro
n flow to substrate, which is observed with the wild-type MoFe protein, is
completely absent. Unlike that of the catalyzed reduction of H+, HCN, or C2
H2, the extent of azide reduction to either N-2 or N2H4 is markedly decreas
ed (to 5-7% of that of the wild type) with the alpha-195(Gln) nitrogenase.
Azide, like N-2, inhibits H-2 evolution and increases the ATP:2e(-) ratio.
Both effects are freely reversible and abolished by CO. Added D-2 does not
relieve either effect, implying that N-2 produced from N-3(-) is not the in
hibitory species. The correlation between the extremely low rates of reduct
ion for both N-2 and azide by the alpha-195(Gln) nitrogenase and their comm
on ability to inhibit H-2 evolution suggests that alpha-histidine-195 may b
e an important proton conductor to the FeMo cofactor center and specificall
y required for reduction of these two substrates.