Nitrogen oxyanion-dependent dissociation of a two-component complex that regulates bacterial nitrate assimilation.

Nitrogen is an essential nutrient for growth and is readily available to microbes in many environments in the form of ammonium and nitrate. Both ions are of environmental significance due to sustained use of inorganic fertilizers on agricultural soils. Diverse species of bacteria that have an assimilatory nitrate/nitrite reductase system (NAS) can use nitrate or nitrite as the sole nitrogen source for growth when ammonium is limited. In Paracoccus denitrificans, the pathway-specific two-component regulator for NAS expression is encoded by the nasT and nasS genes. Here, we show that the putative RNA-binding protein NasT is a positive regulator essential for expression of the nas gene cluster (i.e. nasABGHC). By contrast, a nitrogen oxyanion-binding sensor (NasS) is required for nitrate/nitrite-responsive control of nas gene expression. The NasS and NasT proteins co-purify as a stable heterotetrameric regulatory complex, NasS-NasT. This protein-protein interaction is sensitive to nitrate and nitrite, which cause dissociation of the NasS-NasT complex into monomeric NasS and an oligomeric form of NasT. NasT has been shown to bind the leader RNA for nasA. Thus, upon liberation from the complex, the positive regulator NasT is free to up-regulate nas gene expression.

X-ray crystal structure of a mutant assimilatory nitrite reductase that shows sulfite reductase-like activity.

Assimilatory nitrite reductase (aNiR) reduces nitrite ions (NO(2)(-)) to ammonium ions (NH(4)(+)), whereas assimilatory sulfite reductase reduces sulfite (SO(3)(2-)) to hydrogen sulfide (HS(-)). Although aNiR can also reduce SO(3)(2-), its activity is much lower than when NO(2)(-) is reduced as the substrate. To increase the SO(3)(2-)-reduction activity of aNiR, we performed a N226K mutation of Nii3, a representative aNiR. The resulting Nii3-N226K variant could bind non-native targets, SO(3)(2-), and HCO(3)(-), in addition to its native target, i.e., NO(2)(-). We have determined the high-resolution structure of Nii3-N226K in its apo-state and in complex with SO(3)(2-), NO(2)(-), and HCO(3)(-). This analysis revealed conformational changes of Lys226 and the adjacent Lys224 upon binding of SO(3)(2-), but not NO(2)(-)In contrast, HCO(3)(-) binding induced a conformational change at Arg179. After replacing Asn226 with a positively charged Lys, aNiR showed affinity for several anions. A comparison of all ligand-bound structures for Nii3-N226K revealed that structural changes in the active site depend on the size of the substrate.

Structure-function relationship of assimilatory nitrite reductases from the leaf and root of tobacco based on high-resolution structures.

Tobacco expresses four isomers of assimilatory nitrite reductase (aNiR), leaf-type (Nii1 and Nii3), and root-type (Nii2 and Nii4). The high-resolution crystal structures of Nii3 and Nii4, determined at 1.25 and 2.3 Å resolutions, respectively, revealed that both proteins had very similar structures. The Nii3 structure provided detailed geometries for the [4Fe-4S] cluster and the siroheme prosthetic groups. We have generated two types of Nii3 variants: one set focuses on residue Met175 (Nii3-M175G, Nii3-M175E, and Nii3-M175K), a residue that is located on the substrate entrance pathway; the second set targets residue Gln448 (Nii3-Q448K), a residue near the prosthetic groups. Comparison of the structures and kinetics of the Nii3 wild-type (Nii3-WT) and the Met175 variants showed that the hydrophobic side-chain of Met175 facilitated enzyme efficiency (k(cat) /K(m) ). The Nii4-WT has Lys449 at the equivalent position of Gln448 in Nii3-WT. The enzyme activity assay revealed that the turnover number (k(cat) ) and Michaelis constant (K(m) ) of Nii4-WT were lower than those of Nii3-WT. However, the k(cat) /K(m) of Nii4-WT was about 1.4 times higher than that of Nii3-WT. A comparison of the kinetics of the Nii3-Q448K and Nii4-K449Q variants revealed that the change in k(cat) /K(m) was brought about by the difference in Residue 448 (defined as Gln448 in Nii3 and Lys449 in Nii4). By combining detailed crystal structures with enzyme kinetics, we have proposed that Nii3 is the low-affinity and Nii4 is the high-affinity aNiR.