The Biosynthesis and Function of Nitrogenase Metalloclusters

Dos Santos, Patricia C.

03 December 2004

Nitrogenase catalyzes the biological reduction of N2 to ammonia (nitrogen fixation). The metalloclusters associated with the nitrogenase components include the [4Fe-4S] cluster of the Fe protein, and the P-cluster [8Fe7S] and FeMo-cofactor [7Fe-9S-Mo-X-homocitrate], both contained within the MoFe protein. These metal-complexes play a vital role in enzyme activity during electron transport and substrate reduction. It is known that the FeMo-cofactor provides the site of substrate reduction, but the exact site of substrate binding remains a topic of intense debate. Some models for the substrate binding location favor the molybdenum atom, while other models favor one or more iron atoms within FeMo-cofactor. We have shown that the a-70 residue of the MoFe protein plays a significant role in defining substrate access to the active site: a-70 approaches one 4Fe-4S face of the FeMo-cofactor. Substitutions at this position alter enzyme specificity for reduction of alternative alkyne substrates. These altered MoFe proteins and alternative alkyne substrates, such as propargyl alcohol, were used to trap an intermediate during substrate reduction. Further studies involving the effect of pH on substrate reduction of these altered MoFe proteins pinpointed the location of the bound substrate-derived intermediate on the FeMo-cofactor to a specific Fe atom, designated Fe6. In addition to understanding how substrates are bound and reduced at the active site, understanding how these clusters are biologically assembled is a second point of interest. Inactivation of NifU or NifS has been shown to affect the activity of both nitrogenase components. NifS is a cysteine desulfurase that provides the sulfur for cluster formation and NifU serves as a molecular scaffold during [Fe-S] cluster assembly. Genetic and biochemical experiments involving amino acid substitutions within the N-terminal and C-terminal domains of NifU indicate that both domains can separately participate in nitrogenase-specific [Fe-S] cluster formation. Furthermore, the NifU and NifS protein appear to have specialized functions in the maturation of metalloclusters of nitrogenase and cannot functionally replace the isc [Fe-S] cluster system used for the maturation of other [Fe-S] proteins. These results indicate that, in certain cases, [Fe-S] cluster biosynthetic machineries have evolved to perform only specialized functions. / Ph. D.

FeMo-cofactor

nifS

nifU

nitrogenase

metalloclusters

Biosynthesis of Iron-Sulfur Clusters

Yuvaniyama, Pramvadee

11 April 1999

It is not known whether biosynthesis of [Fe-S] clusters occurs through a spontaneous self-assembly process or an enzymatic process. However, in the <I>Azotobacter</I> <I>vinelandii</I> nitrogenase system, it has been proposed that NifS and NifU are involved in the mobilization of sulfur and iron necessary for nitrogenase-specific [Fe-S] cluster assembly. The NifS protein has been shown to have cysteine desulfurase activity and can be used to supply sulfur for the <I>in</I> <I>vitro</I> catalytic formation of [Fe-S] clusters. The activity of the NifU protein has not yet been established, but NifU could have functions complementary to NifS by mobilizing iron or serving as an intermediate site necessary for nitrogenase-specific [Fe-S] cluster assembly. A second iron-binding site within NifU was predicted to serve these functions because two identical [2Fe-2S] clusters that had previously been identified within the homodimeric NifU are tightly bound, and the NifU primary sequence is rich in cysteine residues. In this dissertation, I examined the possibility that NifU might mobilize iron or serve as an intermediate site for [Fe-S] cluster assembly, as well as the possibility that NifU could work in concert with NifS. Primary sequence comparisons, amino acid substitution experiments, and biophysical characterization of recombinantly-produced NifU fragments were used to show that NifU has a modular structure. One module is contained in approximately the C-terminal half of NifU and provides the binding site for the [2Fe-2S] cluster previously identified (the permanent [2Fe-2S] cluster). Cysteine residues Cys¹³⁷, Cys¹³⁹, Cys¹⁷⁵, and Cys¹⁷⁵ serve as ligands to the [2Fe-2S] cluster. Another module (referred to as NifU-1) is contained in approximately the N-terminal third of NifU and provides a second iron-binding site (rubredoxin-like Fe(III)-binding site). Cysteine residues Cys³⁵, Cys⁶², Cys¹⁰⁶>, and a putative non-cysteine ligand of unknown origin provide coordination to the iron at this site. The significance of these iron-binding sites was also accessed by showing that cysteine residues involved in providing the rubredoxin-like Fe(III)-binding site and those that provide the [2Fe-2S] cluster binding site are all required for the full physiological function of NifU. The two other cysteine residues contained within NifU, Cys²⁷² and Cys²⁷⁵, are neither necessary for binding iron at either site nor are they required for the full physiological function of NifU. These results provide the basis for a model where iron bound at the rubredoxin-like sites within NifU-1 (one iron per monomer) is proposed to be destined for [Fe-S] cluster formation. It was possible to find in vitro evidence supporting this idea. First, it was demonstrated that NifU and NifS are able to form a transient complex. Second, in the presence of NifS as well as L-cysteine and a reducing agent, the Fe(III) contained at the rubredoxin-like sites within the NifU-1 or NifU homodimer can rearrange to form a transient [2Fe-2S] cluster between the two subunits. Finally, a mutant form of NifU-1 was isolated that appears to be trapped in the [2Fe-2S] cluster-containing form, and this [2Fe-2S] cluster (the transient [2Fe-2S] cluster) can be released from the polypeptide matrix upon reduction with dithionite. Previous work has shown that the permanent [2Fe-2S] clusters of as-isolated NifU are in the oxidized form but can be reduced chemically. The transient [2Fe-2S] cluster formed between rubredoxin-like sites, in contrast, is reductively labile. If the transient cluster serves as an intermediate [Fe-S] cluster to be destined for [Fe-S] cluster assembly, I propose that the permanent [2Fe-2S] clusters could have redox roles participating in either one or all of the following events. The permanent [2Fe-2S] clusters could have a redox function in the acquisition of iron for initial binding at the mononuclear sites. They could also provide reducing equivalents for releasing the transient [2Fe-2S] cluster. In addition, upon releasing the transient [2Fe-2S] cluster, the permanent [2Fe-2S] clusters could provide the appropriate oxidation state of the irons to be destined to nitrogenase metallocluster core formation. Finally, because proteins homologous to NifU and NifS are widely distributed in nature, it is suggested that the mechanism for NifU and NifS in the formation of nitrogenase-specific [Fe-S] clusters could represent a general mechanism for [Fe-S] cluster synthesis in other systems. / Ph. D.

NifS

Iron-sulfur clusters

Biosynthesis

NifU

Mechanism of Fe-S cluster biosynthesis: the [2Fe-2S] IscU as a model scaffold

Nuth, Manunya

29 September 2004

No description available.

Chemistry, Biochemistry

Fe-S

iron-sulfur

IscU

IscS

NifS

Characterization of human NFU and its interaction with the molecular chaperone system

Liu, Yushi

27 March 2007

No description available.

NFU

NifS

iron-sulfur cluster

molten globule

molecular chaperone

Expresión recombinante de proteínas relacionadas con el metabolismo del nitrógeno en Haloferax mediterranei

Zafrilla, Basilio

22 July 2011

No description available.

Archaea

Halófilo

Haloferax

Secuenciación

Caracterización

Expresión

Enzima recombinante

Cisteín desulfurasa

Metabolismo del nitrógeno

Proteína tipo NIFS

Nitrito reductasa

Asimilación de nitrato

Respiración de nitrato

Sistema TAT

Bioquímica y Biología Molecular