Molybdenum cofactor nitrogenase complexes

A large number of studies devoted to metal-sulfur centers are motivated by the occurrence of such arrangements at the active site of various metalloenzymes [1-13]. Mononuclear complexes with Mo=0 func-tion(s) and possessing sulfur ligands in their coordination sphere have been extensively investigated since they can be seen as models of the active site of enzymes such as nitrate- and DM SO reductases or sulfite- and xanthine oxidases [1-4]. On the other hand, a large variety of mono-, di-, and polynuclear Mo—S centers have been synthesized in order to produce functional models of the Mo-nitrogenase since the exact nature (mono-, di- or polynuclear) of the metal center, where N2 interacts within the iron-molybdenum cofactor (FeMo—co) of the enzyme is still unknown [4-8]. 

A large part of the research involving metal-sulfur complexes (metal = molybdenum or iron) is aimed at designing functional models of the active site of nitrogenase, the iron-molybdenum cofactor, EeMo—CO [4-8, 12, 13]. Only a very... 

More complex iron-sulfur clusters are also known to exist. These include the iron-molybdenum cofactor of nitrogenase (Thornely and Lowe, 1984) and probably larger clusters in which the only metal is iron (Hagen, 1987). They are characterized by highly anisotropic EPR spectra from S > ground states the nitrogenase cluster, for example is S = j and has EPR features near g = 4 and g = 2. 

The enzyme system responsible for N2 reduction, called the nitrogenase complex, consists of two separate proteins. As outlined in Figure 20.4, one protein-called component I, nitrogenase, or molybdenumiron protein-catalyzes the reduction of N2, and the other-called component II, nitrogenase reductase, or iron protein-transfers electrons from ferredoxin or flavodoxin to component I. Both component I and component II contain Fe4S4 iron-sulfur clusters, and component I also contains molybdenum, in the form of a tightly bound iron-molybdenum cofactor (FeMoCo). 

Both proteins contain iron-sulfur clusters. Nitrogenase also contains a tightly bound iron-molybdenum cofactor. Some variations on this theme are known. Some bacteria, such as Azotobacter, contain more than one nitrogenase complex. Of the three systems in Azotobacter, one uses vanadium instead of molybdenum and another uses only iron. 

Nitrogenase, as must now become clear, is a complex enzyme of two component proteins which requires ATP, a reductant, a reducible substrate, Mg " " as an activator, and an anaerobic environment to function. To this complexity must be added the difficulty that the component proteins have no enzymatic half reactions . There are, perhaps, four main questions to decide about the mechanism (1) the role(s) of the two component proteins (2) the role(s) of ATP (3) the nature of the active site(s) and (4) the mechanism of N2 reduction. Despite the complexities and difficulties mentioned above, progress in the last 15 years has partly answered all these questions. The Fe protein mediates an ATP-dependent electron transfer from the donor to the MoFe protein which contains the active site. MgATP binds and induces a conformational change in the Fe protein which lowers its redox potential. FeMoco, the molybdenum cofactor, which may be part of the active site of N2 reduction, has been isolated and partly characterized, while an intermediate in N2 reduction has recently been discovered (Thorneley ct al., 1978). The next part of this chapter describes the evidence for these claims. This evidence involves the noncatalytic reactions of the individual proteins, their... 

The iron-molybdenum cofactor of nitrogenase is one of the more complex inorganic cofactors. It consists of seven iron, one molybdenum, and nine sulfur atoms. The cofactor is held in place through an iron-cysteine interaction on one end and a molybdenum-histidine interaetion... 

Corbett and co-workers compared both the structural and Mo-localized electronic features of the iron-molybdenum co-factor (FeMoco) in isolated MoFe protein and in the ADP AIF4 stabilized complex of the MoFe protein with the Fe protein. The local metal structure of the iron-molybdenum cofactor of nitrogenase in isolated MoFe protein has been determined by XAS. 

---