An EPR and VTVH MCD spectroscopic investigation of the nitrogenase assembly protein NifB.

NifB, a radical SAM enzyme, catalyzes the biosynthesis of the L cluster (Fe8S9C), a structural homolog and precursor to the nitrogenase active-site M cluster ([MoFe7S9C·R-homocitrate]). Sequence analysis shows that NifB contains the CxxCxxxC motif that is typically associated with the radical SAM cluster ([Fe4S4]SAM) involved in the binding of S-adenosylmethionine (SAM). In addition, NifB houses two transient [Fe4S4] clusters (K cluster) that can be fused into an 8Fe L cluster concomitant with the incorporation of an interstitial carbide ion, which is achieved through radical SAM chemistry initiated at the [Fe4S4]SAM cluster upon its interaction with SAM. Here, we report a VTVH MCD/EPR spectroscopic study of the L cluster biosynthesis on NifB, which focuses on the initial interaction of SAM with [Fe4S4]SAM in a variant NifB protein (MaNifBSAM) containing only the [Fe4S4]SAM cluster and no K cluster. Titration of MaNifBSAM with SAM reveals that [Fe4S4]SAM exists in two forms, labeled [Formula: see text] and [Formula: see text]. It is proposed that these forms are involved in the synthesis of the L cluster. Of the two cluster types, only [Formula: see text] initially interacts with SAM, resulting in the generation of Z, an S = ½ paramagnetic [Fe4S4]SAM/SAM complex.

Electron Paramagnetic Resonance and Magnetic Circular Dichroism Spectra of the Nitrogenase M Cluster Precursor Suggest Sulfur Migration upon Oxidation: A Proposal for Substrate and Inhibitor Binding.

The active site of the nitrogen-fixing enzyme Mo-nitrogenase is the M cluster ([MoFe7 S9 C⋅R-homocitrate]), also known as the FeMo cofactor or FeMoco. The biosynthesis of this highly complex metallocluster involves a series of proteins. Among them, NifB, a radical-SAM enzyme, is instrumental in the assembly of the L cluster ([Fe8 S9 C]), a precursor and all-iron core of the M cluster. In the absence of sulfite, NifB assembles a precursor form of the L cluster called the L* cluster ([Fe8 S8 C]), which lacks the final ninth sulfur. EPR and MCD spectroscopies are used to probe the electronic structures of the paramagnetic, oxidized forms of both the L and L* clusters, labeled LOx and [L*]Ox . This study shows that both LOx and [L*]Ox have nearly identical EPR and MCD spectra, thus suggesting that the two clusters have identical structures upon oxidation; in other words, a sulfur migrates away from LOx following oxidation, thereby rendering the cluster identical to [L*]Ox . It is proposed that a similar migration could occur to the M cluster upon oxidation, and that this is an instrumental part of both M cluster formation and nitrogenase substrate/inhibitor binding.

Magnetic Circular Dichroism Spectroscopy of Metalloproteins.

Metals and metal clusters in proteins typically serve as important structural/functional motifs. Because of this reason, there is a wide range of techniques that specifically probe the structure and energy levels of metals in metalloproteins. One technique, magnetic circular dichroism (MCD) spectroscopy, is the focus of this chapter. MCD spectroscopy monitors the circular dichroism spectrum induced by a magnetic field and is an effective way of obtaining electronic and structural information of paramagnetic metal ions or clusters. The basic methodology of this technique is discussed along with examples of how MCD spectroscopy can be used to elucidate typical metal clusters in proteins. Special emphasis is placed on iron-sulfur (FeS) clusters.

A VTVH MCD and EPR Spectroscopic Study of the Maturation of the "Second" Nitrogenase P-Cluster.

The P-cluster of the nitrogenase MoFe protein is a [ Fe8 S7] cluster that mediates efficient transfer of electrons to the active site for substrate reduction. Arguably the most complex homometallic FeS cluster found in nature, the biosynthetic mechanism of the P-cluster is of considerable theoretical and synthetic interest to chemists and biochemists alike. Previous studies have revealed a biphasic assembly mechanism of the two P-clusters in the MoFe protein upon incubation with Fe protein and ATP, in which the first P-cluster is formed through fast fusion of a pair of [ Fe4 S4]+ clusters within 5 min and the second P-cluster is formed through slow fusion of the second pair of [ Fe4 S4]+ clusters in a period of 2 h. Here we report a VTVH MCD and EPR spectroscopic study of the biosynthesis of the slow-forming, second P-cluster within the MoFe protein. Our results show that the first major step in the formation of the second P-cluster is the conversion of one of the precursor [ Fe4 S4]+ clusters into the integer spin cluster [ Fe4 S3-4]α, a process aided by the assembly protein NifZ, whereas the second major biosynthetic step appears to be the formation of a diamagnetic cluster with a possible structure of [ Fe8 S7-8]ß, which is eventually converted into the P-cluster.

Ethylene Glycol Quenching of Nitrogenase Catalysis: An Electron Paramagnetic Resonance Spectroscopic Study of Nitrogenase Turnover States and CO Bonding.

Most hydrophilic organic solvents inhibit enzymatic activity. Nitrogenase is shown to be approximately 3 times more sensitive to organic inhibition than most other soluble enzymes. Ethylene glycol (EG) is demonstrated to rapidly inhibit nitrogenase activity without uncoupling ATP hydrolysis. Our data suggest the mechanism of inhibition is EG's blocking of binding of MgATP to the nitrogenase Fe protein. EG quenching allows, for the first time, the observation of the relaxation of the intermediate reaction states at room temperature. Electron paramagnetic resonance (EPR) spectroscopy is used to monitor the room-temperature decay of the nitrogenase turnover states following EG quenching of catalytic activity. The return of the intermediate states to the resting state occurs in multiple phases over 2 h. During the initial stage, nitrogenase still possesses the ability to generate CO-induced EPR signals even though catalytic activity has ceased. During the last phase of relaxation, the one-electron reduced state of the MoFe protein (E1) relaxes to the resting state (E0) in a slow first-order reaction.

Nonenzymatic synthesis of the P-cluster in the nitrogenase MoFe protein: evidence of the involvement of all-ferrous [Fe4S4](0) intermediates.

The P-cluster in the nitrogenase MoFe protein is a [Fe8S7] cluster and represents the most complex FeS cluster found in Nature. To date, the exact mechanism of the in vivo synthesis of the P-cluster remains unclear. What is known is that the precursor to the P-cluster is a pair of neighboring [Fe4S4]-like clusters found on the ΔnifH MoFe protein, a protein expressed in the absence of the nitrogenase Fe protein (NifH). Moreover, incubation of the ΔnifH MoFe protein with NifH and MgATP results in the synthesis of the MoFe protein P-clusters. To improve our understanding of the mechanism of this reaction, we conducted a magnetic circular dichroism (MCD) spectroscopic study of the [Fe4S4]-like clusters on the ΔnifH MoFe protein. Reducing the ΔnifH MoFe protein with Ti(III) citrate results in the quenching of the S = (1)/2 electron paramagnetic resonance signal associated with the [Fe4S4](+) state of the clusters. MCD spectroscopy reveals this reduction results in all four 4Fe clusters being converted into the unusual, all-ferrous [Fe4S4](0) state. Subsequent increases of the redox potential generate new clusters. Most significantly, one of these newly formed clusters is the P-cluster, which represents approximately 20-25% of the converted Fe concentration. The other two clusters are an X cluster, of unknown structure, and a classic [Fe4S4] cluster, which represents approximately 30-35% of the Fe concentration. Diamagnetic FeS clusters may also have been generated but, because of their low spectral intensity, would not have been identified. These results demonstrate that the nitrogenase P-cluster can be generated in the absence of NifH and MgATP.

P+ state of nitrogenase p-cluster exhibits electronic structure of a [Fe4S4]+ cluster.

Mo nitrogenase consists of two component proteins: the Fe protein, which contains a [Fe(4)S(4)] cluster, and the MoFe protein, which contains two different classes of metal cluster: P-cluster ([Fe(8)S(7)]) and FeMoco ([MoFe(7)S(9)C·homocitrate]). The P-cluster is believed to mediate the electron transfer between the Fe protein and the MoFe protein via interconversions between its various oxidation states, such as the all-ferrous state (P(N)) and the one- (P(+)) and two-electron (P(2+)) oxidized states. While the structural and electronic properties of P(N) and P(2+) states have been well characterized, little is known about the electronic structure of the P(+) state. Here, a mutant strain of Azotobacter vinelandii (DJ1193) was used to facilitate the characterization of the P(+) state of P-cluster. This strain expresses a MoFe protein variant (designated ΔnifB ß-188(Cys) MoFe protein) that accumulates the P(+) form of P-cluster in the resting state. Magnetic circular dichroism (MCD) spectrum of the P-cluster in the oxidized ΔnifB ß-188(Cys) MoFe protein closely resembles that of the P(2+) state in the oxidized wild-type MoFe protein, except for the absence of a major charge-transfer band centered at 823 nm. Moreover, magnetization curves of ΔnifB ß-188(Cys) and wild-type MoFe proteins suggest that the P(2+) species in both proteins have the same spin state. MCD spectrum of the P(+) state in the ΔnifB ß-188(Cys) MoFe protein, on the other hand, is associated with a classic [Fe(4)S(4)](+) cluster, suggesting that the P-cluster could be viewed as two coupled 4Fe clusters and that it could donate either one or two electrons to FeMoco by using one or both of its 4Fe halves. Such a mode of action of P-cluster could provide energetic and kinetic advantages to nitrogenase in the complex mechanism of N(2) reduction.

Magnetic circular dichroism spectroscopy.

Being able to probe the structure and energy levels of metal ions in biological systems is an important goal of bioinorganic scientists. Several of the techniques used rely on the paramagnetic property of certain oxidation states of metal ions. MCD spectroscopy is one of those techniques and represents an effective way of obtaining structure/electronic information of paramagnetic metal ions. The basics of this technique are discussed along with examples of how MCD spectroscopy has been successfully used to elucidate the metal clusters of Nif proteins from nitrogen-fixing bacteria.

[4Fe4S]2+ clusters exhibit ground-state paramagnetism.

Two proteins involved in nitrogen fixation contain ferredoxin-type [4Fe4S] clusters that exist in paramagnetic ground state upon oxidation, a property never observed since the discovery of ferredoxins 50 years ago. This unique characteristic suggests a specific coupling in these clusters necessary for nitrogen fixation and implies an evolutionary connection between the clusters in the two proteins.

Variable-temperature, variable-field magnetic circular dichroism spectroscopic study of NifEN-bound precursor and "FeMoco".

NifEN plays a key role in the biosynthesis of the iron-molybdenum cofactor (FeMoco) of nitrogenase. A scaffold protein that hosts the conversion of a FeMoco precursor to a mature cofactor, NifEN can assume three conformations during the process of FeMoco maturation. One, designated ΔnifB NifEN, contains only two permanent [Fe(4)S(4)]-like clusters. The second, designated NifEN(Precursor), contains the permanent clusters and a precursor form of FeMoco. The third, designated NifEN("FeMoco"), contains the permanent [Fe(4)S(4)]-like clusters and a fully complemented, "FeMoco"-like structure. Here, we report a variable-temperature, variable-field magnetic circular dichroism spectroscopic investigation of the electronic structure of the metal clusters in the three forms of dithionite-reduced NifEN. Our data indicate that the permanent [Fe(4)S(4)]-like clusters are structurally and electronically conserved in all three NifEN species and exhibit spectral features of classic [Fe(4)S(4)](+) clusters; however, they are present in a mixed spin state with a small contribution from the S > ½ spin state. Our results also suggest that both the precursor and "FeMoco" have a conserved Fe/S electronic structure that is similar to the electronic structure of FeMoco in the MoFe protein, and that the "FeMoco" in NifEN("FeMoco") exists, predominantly, in an S = 3/2 spin state with spectral parameters identical to those of FeMoco in the MoFe protein. These observations provide strong support to the outcome of our previous EPR and X-ray absorption spectroscopy/extended X-ray absorption fine structure analysis of the three NifEN species while providing significant new insights into the unique electronic properties of the precursor and "FeMoco" in NifEN.

VTVH-MCD study of the Delta nifB Delta nifZ MoFe protein from Azotobacter vinelandii.

NifZ is a member of a series of proteins associated with the maturation of the nitrogenase MoFe protein. An MCD spectroscopic study was undertaken on the Delta nifB Delta nifZ MoFe protein generated in the absence of both NifZ and NifB (deletion of NifB generates an apo-MoFe protein lacking the FeMo cofactor). Results presented here show that, in the absence of NifZ, only one of the two P-clusters of the MoFe protein is matured to the ultimate [8Fe-7S] structure. The other P-cluster site in the protein contains a [4Fe-4S] cluster pair, representing a P-cluster precursor that is electronically identical to the analogous clusters observed in the Delta nifH MoFe protein. These results suggest that the MoFe protein is synthesized in a stepwise fashion where NifZ is specifically required for the formation of the second P-cluster.

Variable-temperature, variable-field magnetic circular dichroism spectroscopic study of the metal clusters in the DeltanifB and DeltanifH mofe proteins of nitrogenase from Azotobacter vinelandii.

Deletion of nifB results in the formation of a variant nitrogenase MoFe protein (DeltanifB MoFe protein) that appears to contain two normal [8Fe-7S] P clusters. This protein can be reactivated to form the holo MoFe protein upon addition of isolated FeMo cofactor. In contrast, deletion of nifH results in a variant protein (DeltanifH MoFe protein) that appears to contain FeS clusters different from the normal P cluster, presumably representing precursors of the normal P cluster. The DeltanifH MoFe protein is not reconstituted to the holo MoFe protein with isolated FeMo cofactor. The EPR and EXAFS spectroscopic properties of FeS clusters in the DeltanifH MoFe protein clearly differ from those of the normal P cluster found in the DeltanifB MoFe protein and suggest the presence of [4Fe-4S]-like clusters. To further characterize the metal cluster structures in the DeltanifH MoFe protein, a variable-temperature, variable-field magnetic circular dichroism (VTVH-MCD) spectroscopic study has been undertaken on both the DeltanifB MoFe protein and the DeltanifH MoFe protein in both the dithionite-reduced and oxidized states. This study clearly shows that each half of the dithionite-reduced DeltanifH MoFe protein contains a [4Fe-4S]+ cluster paired with a diamagnetic [4Fe-4S]-like cluster. Upon oxidation, the VTVH-MCD spectrum of the DeltanifH MoFe protein reveals a paramagnetic, albeit EPR-silent system, suggesting an integer spin state. These results suggest that the DeltanifH MoFe protein contains a pair of neighboring, unusual [4Fe-4S]-like clusters, which are paramagnetic in their oxidized state.

Electron inventory, kinetic assignment (E(n)), structure, and bonding of nitrogenase turnover intermediates with C2H2 and CO.

Improved 1H ENDOR data from the S(EPR1) intermediate formed during turnover of the nitrogenase alpha-195Gln MoFe protein with C2(1,2)H2 in (1,2)H2O buffers, taken in context with the recent study of the intermediate formed from propargyl alcohol, indicate that S(EPR1) is a product complex, likely with C2H4 bound as a ferracycle to a single Fe of the FeMo-cofactor active site. 35 GHz CW and Mims pulsed 57Fe ENDOR of 57Fe-enriched S(EPR1) cofactor indicates that it exhibits the same valencies as those of the CO-bound cofactor of the lo-CO intermediate formed during turnover with CO, [Mo4+, Fe3+, Fe6(2+), S9(2-)(d43)](+1), reduced by m = 2 electrons relative to the resting-state cofactor. Consideration of 57Fe hyperfine coupling in S(EPR1) and lo-CO leads to a picture in which CO bridges two Fe of lo-CO, while the C2H4 of S(EPR1) binds to one of these. To correlate these and other intermediates with Lowe-Thorneley (LT) kinetic schemes for substrate reduction, we introduce the concept of an "electron inventory". It partitions the number of electrons a MoFe protein intermediate has accepted from the Fe protein (n) into the number transmitted to the substrate (s), the number that remain on the intermediate cofactor (m), and the additional number delivered to the cofactor from the P clusters (p): n = m + s - p (with p = 0 here). The cofactors of lo-CO and S(EPR1) both are reduced by m = 2 electrons, but the intermediates are not at the same LT reduction stage (E(n)): (n = 2; m = 2, s = 0) for lo-CO; (n = 4; s = 2, m = 2) for S(EPR1). This is the first proposed correlation of an LT E(n) kinetic state with a well-defined chemical state of the enzyme.

Variant MoFe proteins of Azotobacter vinelandii: effects of carbon monoxide on electron paramagnetic resonance spectra generated during enzyme turnover.

The resting state of wild-type nitrogenase MoFe protein exhibits an S=3/2 electron paramagnetic resonance (EPR) signal originating from the FeMo cofactor, the enzyme's active site. When nitrogenase turns over under CO, this signal disappears and one (sometimes two) of three new EPR signals, which also arise from the FeMo cofactor, appears, depending on the CO concentration. The appearance and properties of these CO-inducible EPR signals, which were also generated with variant MoFe proteins (alphaR96Q, alphaR96K, alphaQ191K, alphaR359K, alphaR96K/alphaR359K, alphaR277C, alphaR277H, and DeltanifV) that are impacted around the FeMo cofactor, have been investigated. No new CO-induced EPR signals arise from any variant, suggesting that no new CO-binding sites are produced by the substitutions. All variant proteins, except alphaR277H, produce the lo-CO signal; all, except alphaQ191K, produce the hi(5)-CO signal; but only two (alphaR96Q and DeltanifV) exhibit the hi-CO signal. FeMo cofactor's environment clearly dictates which CO-induced EPR signals are generated; however, none of these EPR signals correlate with CO inhibition of H(2) evolution observed with some of these variants. CO inhibition of H(2) evolution is, therefore, due to CO binding to a different site(s) from those responsible for the CO-induced EPR signals. Some resting-state variants have overlapping S=3/2 EPR signals, whose intensities simultaneously decrease under turnover conditions, indicating that all FeMo cofactor conformations are catalytically active. Moreover, these variants produce a similar number of hi(5)-CO signals after turnover under CO to the number of resting-state S=3/2 signals. The FeMo cofactor associated with the hi(5)-CO signal likely contains two bridging CO molecules.

Observation of Fe-H/D modes by nuclear resonant vibrational spectroscopy.

Metal-hydrogen bonding is important in chemistry and catalysis, but H atoms are often difficult to observe, especially in metalloproteins. In this work we show that Fe-H interactions can be probed by nuclear resonance vibrational spectroscopy at the 14.4 keV 57Fe nuclear resonance. An important advantage of this method, compared to Raman and IR spectroscopy, is the selectivity for modes that involve 57Fe motion. We present data on the FeS4 site in rubredoxin and the [FeH(D)6]2- ion. Prospects for studying more complex systems are discussed.

Photo-lability of CO bound to Mo-nitrogenase from Azotobacter vinelandii.

In the presence of CO and under turnover conditions, Mo-nitrogenase generates three different electron paramagnetic resonance (EPR) signals. One of the signals, lo-CO, is an S=1/2 signal and occurs under low CO concentrations. The other two signals, hi-CO (S=1/2) and hi(5)-CO (S=3/2) displace the lo-CO as the CO concentration is raised above 0.05 atm. Irradiation of hi-CO with visible light at 12 K converts it into lo-CO. Using a series of color filters, the corrected action spectrum is determined and shown to contain 2-3 broad maxima in the region 350-730 nm. The conversion of lo-CO back into hi-CO is accomplished by warming the sample to 77 K for 5 min. Using this temperature cycle, the rate constant for the re-association of CO with lo-CO to form hi-CO is determined in the range 12-90 K. From these data, the activation energy for this reaction is calculated to be 3.9 kJ/mol. Identical irradiation of either lo-CO or hi(5)-CO induces no spectral change, showing that both of these states are photo-stable. The photo-stability of hi(5)-CO demonstrates that it is structurally different from hi-CO.