BackgroundThe metabolic capacity for nitrogen fixation is known to be present in several prokaryotic species scattered across taxonomic groups. Experimental detection of nitrogen fixation in microbes requires species-specific conditions, making it difficult to obtain a comprehensive census of this trait. The recent and rapid increase in the availability of microbial genome sequences affords novel opportunities to re-examine the occurrence and distribution of nitrogen fixation genes. The current practice for computational prediction of nitrogen fixation is to use the presence of the nifH and/or nifD genes.ResultsBased on a careful comparison of the repertoire of nitrogen fixation genes in known diazotroph species we propose a new criterion for computational prediction of nitrogen fixation: the presence of a minimum set of six genes coding for structural and biosynthetic components, namely NifHDK and NifENB. Using this criterion, we conducted a comprehensive search in fully sequenced genomes and identified 149 diazotrophic species, including 82 known diazotrophs and 67 species not known to fix nitrogen. The taxonomic distribution of nitrogen fixation in Archaea was limited to the Euryarchaeota phylum; within the Bacteria domain we predict that nitrogen fixation occurs in 13 different phyla. Of these, seven phyla had not hitherto been known to contain species capable of nitrogen fixation. Our analyses also identified protein sequences that are similar to nitrogenase in organisms that do not meet the minimum-gene-set criteria. The existence of nitrogenase-like proteins lacking conserved co-factor ligands in both diazotrophs and non-diazotrophs suggests their potential for performing other, as yet unidentified, metabolic functions.ConclusionsOur predictions expand the known phylogenetic diversity of nitrogen fixation, and suggest that this trait may be much more common in nature than it is currently thought. The diverse phylogenetic distribution of nitrogenase-like proteins indicates potential new roles for anciently duplicated and divergent members of this group of enzymes.
We here show that the iron-molybdenum (FeMo)-cofactor of the nitrogenase alpha-70(Ile) molybdenum-iron (MoFe) protein variant accumulates a novel S = (1)/(2) state that can be trapped during the reduction of protons to H(2). (1,2)H-ENDOR measurements disclose the presence of two protons/hydrides (H(+/)(-)) whose hyperfine tensors have been determined from two-dimensional field-frequency (1)H ENDOR plots. The two H(+/)(-) have large isotropic hyperfine couplings, A(iso)( )() approximately 23 MHz, which shows they are bound to the cofactor. The favored analysis for these plots indicates that the two H(+/)(-) have the same principal values, which indicates that they are chemically equivalent. The tensors are further related to each other by a permutation of the tensor components, which indicates an underlying symmetry of binding relative to the cofactor. At present, no model for the structure of the iron-molybdenum (FeMo)-cofactor in the S = (1)/(2) state trapped during the reduction of H(+) can be shown unequivocally to satisfy all of the constraints generated by the ENDOR analysis. The data disfavors any model that involves protonation of sulfides, and thus suggests that the intermediate instead contains two chemically equivalent bound hydrides; it appears unlikely that these are terminal monohydrides.
Azotobacter vinelandii is a soil bacterium related to the Pseudomonas genus that fixes nitrogen under aerobic conditions while simultaneously protecting nitrogenase from oxygen damage. In response to carbon availability, this organism undergoes a simple differentiation process to form cysts that are resistant to drought and other physical and chemical agents. Here we report the complete genome sequence of A. vinelandii DJ, which has a single circular genome of 5,365,318 bp. In order to reconcile an obligate aerobic lifestyle with exquisitely oxygen-sensitive processes, A. vinelandii is specialized in terms of its complement of respiratory proteins. It is able to produce alginate, a polymer that further protects the organism from excess exogenous oxygen, and it has multiple duplications of alginate modification genes, which may alter alginate composition in response to oxygen availability. The genome analysis identified the chromosomal locations of the genes coding for the three known oxygen-sensitive nitrogenases, as well as genes coding for other oxygen-sensitive enzymes, such as carbon monoxide dehydrogenase and formate dehydrogenase. These findings offer new prospects for the wider application of A. vinelandii as a host for the production and characterization of oxygen-sensitive proteins.
Nitrogenase is the metalloenzyme that catalyzes the nucleotide-dependent reduction of N(2), as well as reduction of a variety of other triply bonded substrates, including the alkyne, acetylene. Substitution of the alpha-70(Val) residue in the nitrogenase MoFe protein by alanine expands the range of substrates to include short-chain alkynes not reduced by the unaltered protein. Rapid freezing of the alpha-70(Ala) nitrogenase MoFe protein during reduction of the alkyne propargyl alcohol (HC triple bond CH(2)OH; PA) traps an S = (1)/(2) intermediate state of the active-site metal cluster, the FeMo-cofactor. We have combined CW and pulsed (13)C ENDOR (electron-nuclear double resonance) with two quantitative 35 GHz (1,2)H ENDOR techniques, Mims pulsed ENDOR and the newly devised "stochastic field-modulated" ENDOR, to study this intermediate prepared with isotopically substituted ((13)C, (1,2)H) propargyl alcohol in H(2)O and D(2)O buffers. These measurements allow the first description of a trapped nitrogenase reduction intermediate. The S = (1)/(2) turnover intermediate generated during the reduction of PA contains the 3-carbon chain of PA and exhibits resolved (1,2)H ENDOR signals from three protons, two strongly coupled (H(a)) and one weakly coupled (H(b)); H(a)(c) originates as the C3 proton of PA, while H(a)(s) and H(b) are solvent-derived. The two H(a) protons have identical hyperfine tensors, despite having different origins. The equality of the (H(a)(s), H(a)(c)) hyperfine tensors strongly constrains proposals for the structure of the cluster-bound reduced PA. Through consideration of model structures found in the Cambridge Structural Database, we propose that the intermediate contains a novel bio-organometallic complex in which a reduction product of propargyl alcohol binds as a metalla-cyclopropane ring to a single Fe atom of the Fe-S face of the FeMo-cofactor that is composed of Fe atoms 2, 3, 6, and 7. Of the two most attractive structures, one singly reduced at C3 (4), the other being the doubly reduced allyl alcohol product (6), we tentatively favor 6 because of the "natural" assignment it affords for H(b).
The chemical mechanism for biological cleavage of the N(2) triple bond at ambient pressure and temperature has been the subject of intense study for many years. The site of substrate activation and reduction has been localized to a complex cofactor, called FeMo cofactor, yet until now the complexity of the system has denied information concerning exactly where and how substrates interact with the metal-sulfur framework of the active site. In this Account, we describe a combined genetic, biophysical, and biochemical approach that was used to provide direct and detailed information concerning where alternative alkyne substrates interact with FeMo cofactor during catalysis. The relevance and limitations of this work with respect to N(2) binding and reduction also are discussed.
Nitrogenase catalyzes biological dinitrogen fixation, the reduction of N 2 to 2NH 3 . Recently, the binding site for a non-physiological alkyne substrate (propargyl alcohol, HC'C-CH 2 OH) was localized to a specific Fe-S face of the FeMo-cofactor approached by the MoFe protein amino acid ␣-70Val . Here we provide evidence to indicate that the smaller alkyne substrate acetylene (HC'CH), the physiological substrate dinitrogen, and its semi-reduced form hydrazine (H 2 N-NH 2 ) interact with the same Fe-S face of the FeMo-cofactor. Hydrazine is a relatively poor substrate for the wild-type (␣-70 Val ) MoFe protein. Substitution of the ␣-70Val residue by an amino acid having a smaller side chain (alanine) dramatically enhanced hydrazine reduction activity. Conversely, substitution of ␣-70Val by an amino acid having a larger side chain (isoleucine) significantly lowered the capacity of the MoFe protein to reduce dinitrogen, hydrazine, or acetylene.
A Proposed Role for the Azotobacter vinelandii NfuA Protein as an Intermediate Iron-Sulfur Cluster Carrier
Iron-sulfur clusters ([Fe-The in vivo maturation of simple [Fe-S] proteins is proposed to require preassembly of [Fe-S] species on molecular scaffolds. The first [Fe-S] cluster assembly system to be described is the NIF 2 system from Azotobacter vinelandii. This system consists of a cysteine desulfurase, encoded by nifS, which supplies the S for [Fe-S] cluster formation, and a proposed scaffold protein, encoded by nifU (1). The NIF system is specialized for the maturation of [Fe-S] proteins involved in nitrogen fixation.A. vinelandii also contains a second [Fe-S] protein maturation system designated ISC. The ISC system is required for the general maturation of cellular [Fe-S] proteins involved in intermediary metabolism, such as aconitase (2). The ISC system is more complicated than the NIF system as it includes the products of eight contiguous genes : iscR, iscS, iscU, iscA, hscB, hscA, fdx, and iscX (3). Although the NIF and ISC systems exhibit physiological target specificity, each can partially replace the function of the other, when expressed at high levels (4, 5).Even though the NIF and ISC systems are differentiated by their apparent target specificities, they share a number of common structural and functional features. For example, NifS and IscS have similar sequences, and they both exhibit cysteine desulfurase activity (2). IscU also shares considerable sequence identity when compared with the N-terminal domain of NifU, including conservation of three cysteine residues that are likely to provide the nucleation site(s) for [Fe-S] cluster assembly (2, 6).NifU is a modular protein that contains three distinct domains (Fig. 1). The central domain contains a stable redoxactive [2Fe-2S] cluster with an as-yet-unknown function (7). In vitro and in vivo experiments have established that labile [Fe-S] clusters can be assembled on both the N-terminal and C-terminal domains of NifU, and such cluster-loaded forms of NifU can be used for activation of the nitrogenase 9). Thus, NifU contains two different sites upon which labile [Fe-S] clusters can be assembled in vitro, but the functional relationship between these sites is not yet known.There are no genes within the ISC transcriptional unit that encode proteins with sequence similarity to the C-terminal domain of NifU. However, located elsewhere on the A. vinelandii genome is a gene, designated nfuA, whose product encodes a protein having a C-terminal sequence similar to the C-terminal domain of NifU (Fig. 1). The sequence conservation between NifU and NfuA includes two cysteine residues that are required for the in vitro assembly of [Fe-S] clusters within the NifU C-terminal domain. Like NifU, NfuA also appears to be a modular protein because the amino acid sequence within its N-terminal region shares some sequence similarity with another protein involved in [Fe-S] protein maturation designated IscA (Fig. 1). IscA is a nonessential protein encoded within the ISC transcriptional unit, and it has been proposed to serve as an alternative [Fe-S] cluster ass...
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