Site-Directed Mutagenesis of the Anabaena sp. Strain PCC 7120 Nitrogenase Active Site To Increase Photobiological Hydrogen Production

Cyanobacteria use sunlight and water to produce hydrogen gas (H₂), which is potentially useful as a clean and renewable biofuel. Photobiological H₂ arises primarily as an inevitable by-product of N₂ fixation by nitrogenase, an oxygen-labile enzyme typically containing an iron-molybdenum cofactor (FeMo-co) active site. In Anabaena sp. strain 7120, the enzyme is localized to the microaerobic environment of heterocysts, a highly differentiated subset of the filamentous cells. In an effort to increase H₂ production by this strain, six nitrogenase amino acid residues predicted to reside within 5 Å of the FeMo-co were mutated in an attempt to direct electron flow selectively toward proton reduction in the presence of N₂. Most of the 49 variants examined were deficient in N₂-fixing growth and exhibited decreases in their in vivo rates of acetylene reduction. Of greater interest, several variants examined under an N₂ atmosphere significantly increased their in vivo rates of H₂ production, approximating rates equivalent to those under an Ar atmosphere, and accumulated high levels of H₂ compared to the reference strains. These results demonstrate the feasibility of engineering cyanobacterial strains for enhanced photobiological production of H₂ in an aerobic, nitrogen-containing environment.Photobiologically produced hydrogen gas (H₂) is a clean energy source with the potential to greatly supplement our use of fossil fuels (39). Whereas coal and oil are limited, cyanobacteria and eukaryotic microalgae can use inexhaustible sunlight as the energy source and water as the electron donor to produce H₂ (42). This gas is generated either by hydrogenases (52) or as an inevitable by-product of N₂ fixation by nitrogenases (49). In contrast to the reaction of hydrogenases which is reversible, nitrogenases catalyze the unidirectional production of H₂, although with substantial energy input in the form of ATP (47). Under optimal N₂-fixing conditions: N₂ + 8 e⁻ + 8 H⁺ + 16 ATP → H₂ + 2 NH₃ + 16 (ADP + P_i), whereas, in the absence of N₂ (e.g., under Ar), all electrons are allocated to proton reduction: 2 e⁻ + 2 H⁺ + 4 ATP → H₂ + 4 (ADP + P_i). Thus, one expects to be able to increase the H₂ production activity of nitrogenase by decreasing the electron allocation to N₂ fixation.Nitrogenases are sensitive to inactivation by O₂; however, N₂-fixing cyanobacteria have developed mechanisms to protect these enzymes from photosynthetically generated oxygen (5). Of particular interest, Anabaena (also known as Nostoc) sp. strain PCC 7120 and some other filamentous cyanobacteria respond to combined-nitrogen deprivation by undergoing differentiation in which a subset of cells become heterocysts that provide a microaerobic environment, allowing nitrogenase to function in aerobic culture conditions. The nitrogenase-related (nif) genes are specifically expressed in heterocysts which lack O₂-evolving photosystem II activity and are surrounded by a thick cell envelope composed of glycolipids and polysaccharides that impede the entry of O₂ (56). Vegetative cells perform oxygenic photosynthesis and fix CO₂. Heterocysts obtain carbohydrates from those cells and, in turn, provide them with fixed nitrogen.The molybdenum-containing nitrogenase of Anabaena sp. strain PCC 7120 consists of the Fe protein (encoded by nifH) and the MoFe protein (encoded by nifD and nifK). As in other organisms, the Fe protein is a homodimer containing a single 4Fe-4S] cluster and functions as an ATP-dependent electron donor to the MoFe protein. The latter is an α₂β₂ heterotetramer with each nifD-encoded α subunit coordinating the FeMo cofactor (FeMo-co; MoFe₇S₉X-homocitrate) that binds and reduces substrate, while α plus the nifK-encoded β subunits coordinate the 8Fe-7S] P-cluster (14). Additional nif genes are required for the biosynthesis of the metal clusters and maturation of the enzyme (40). The major nif gene cluster of Anabaena sp. strain PCC 7120 undergoes two rearrangements in the heterocyst to yield nifB-fdxN-nifSUHDK-(1 ORF)-nifENX-(2 ORFs)-nifW-hesAB-fdxH (19).One approach to increase H₂ production by nitrogenase is to enhance the electron flux to proton reduction and away from N₂ reduction. Although replacement of N₂ by Ar is effective for increasing H₂ production, this approach increases the operational cost for large-scale generation of H₂. Mutagenesis offers an alternative mechanism to overcome N₂ competition. The amino acid sequences of the MoFe α subunit are highly conserved among different phyla (18). The V75I substitution in the suspected gas channel of NifD2 of Anabaena variabilis (equivalent to V70 in A. vinelandii) resulted in greatly diminished N₂ fixation, while allowing for H₂ production rates (under N₂) that were similar to those of wild-type cells under Ar (55). Significantly, however, the nonheterocyst nitrogenase of this strain, which is expressed mainly in vegetative cells under anaerobic conditions, is incompatible with O₂-evolving photosynthesis and thus requires continuous anaerobic conditions along with a supply of exogenous reducing sugars for H₂ production. Substitutions of selected amino acids in the vicinity of the FeMo-co active site within Azotobacter vinelandii nitrogenase were shown to eliminate or greatly diminish N₂ fixation while, in some cases, allowing for effective proton reduction (2, 10, 17, 27, 36, 44, 45, 48). Therefore, certain amino acid exchanges near FeMo-co might produce variant MoFe proteins in heterocyst-forming Anabaena that redirect the electron flux through the enzyme preferentially to proton reduction so as to synthesize more H₂ in the presence of N₂ in an aerobic environment.To examine whether Anabaena sp. strain PCC 7120 nitrogenase can be modified to increase photobiological H₂ production by effecting such a redirection, we evaluated in vivo H₂ production and acetylene reduction rates of a series of cyanobacterial nifD site-directed mutants. We mutated six NifD residues (Fig. ​(Fig.1)1) predicted to lie within 5 Å of FeMo-co to create 49 variants using an Anabaena ΔNifΔHup (previously denoted ΔhupL) parental strain that lacks both an intact nifD and an uptake hydrogenase (34). In an atmosphere containing N₂ and O₂, several mutants exhibited significantly enhanced rates of in vivo H₂ production and accumulated high levels of H₂ compared to the reference strains.Open in a separate windowFIG. 1.Side-on (left) and Mo end-on (right) views of the predicted active site for nitrogenase of Anabaena sp. strain PCC 7120. The FeMo-co cluster, a 7Fe-8S-Mo-X-homocitrate] complex, where X is a central unidentified light atom (N, C, or O), and its two coordinating residues (C282 and H449) are shown in a ball-and-stick representation. Water molecules near the FeMo-co are indicated by isolated spheres in red. The side chains of the residues targeted for mutagenesis—Q193, H197, Y236, R284, S285, and F388—are shown in stick representation. Residues V362 through P367 are represented by lines. The Anabaena residues were mapped onto the corresponding residues from the crystal structure of the A. vinelandii enzyme (PDB file 1M1N). The figure was generated by using PyMOL (www.pymol.org/), with the following color scheme: Fe, orange; S, yellow; C, gray; N and central atom X, blue; O, red; and Mo, pink.