David M. Arciero

Enzymology of the oxidation of ammonia to nitrite by bacteria

The enzymes which catalyze the oxidation of ammonia to nitrite by autotrophic bacteria are reviewed. A comparison is made with enzymes which catalyze the same reactions in methylotrophs and organotrophic heterotrophic bacteria.

Electron transfer during the oxidation of ammonia by the chemolithotrophic bacterium Nitrosomonas europaea.

The combined action of ammonia monooxygenase, AMO, (NH(3)+2e(-)+O(2)-->NH(2)OH) and hydroxylamine oxidoreductase, HAO, (NH(2)OH+H(2)O-->HNO(2)+4e(-)+4H(+)) accounts for ammonia oxidation in Nitrosomonas europaea. Pathways for electrons from HAO to O(2), nitrite, NO, H(2)O(2) or AMO are reviewed and some recent advances described. The membrane cytochrome c(M)552 is proposed to participate in the path between HAO and ubiquinone. A bc(1) complex is shown to mediate between ubiquinol and the terminal oxidase and is shown to be downstream of HAO. A novel, red, low-potential, periplasmic copper protein, nitrosocyanin, is introduced. Possible mechanisms for the inhibition of ammonia oxidation in cells by protonophores are summarized. Genes for nitrite- and NO-reductase but not N(2)O or nitrate reductase are present in the genome of Nitrosomonas. Nitrite reductase is not repressed by growth on O(2); the flux of nitrite reduction is controlled at the substrate level.

Nitrite Reductase of Nitrosomonas europaea Is Not Essential for Production of Gaseous Nitrogen Oxides and Confers Tolerance to Nitrite

A gene that encodes a periplasmic copper-type nitrite reductase (NirK) was identified in Nitrosomonas europaea. Disruption of this gene resulted in the disappearance of Nir activity in cell extracts. The nitrite tolerance of NirK-deficient cells was lower than that of wild-type cells. Unexpectedly, NirK-deficient cells still produced nitric oxide (NO) and nitrous oxide (N(2)O), the latter in greater amounts than that of wild-type cells. This demonstrates that NirK is not essential for the production of NO and N(2)O by N. europaea. Inactivation of the putative fnr gene showed that Fnr is not essential for the expression of nirK.

Heme packing motifs revealed by the crystal structure of the tetra-heme cytochrome c554 from Nitrosomonas europaea.

Cytochrome c554 (cyt c554), a tetra-heme cytochrome from Nitrosomonas europaea, is an essential component in the biological nitrification pathway. In N. europaea, ammonia is converted to hydroxylamine, which is then oxidized to nitrite by hydroxylamine oxidoreductase (HAO). Cyt c554 functions in the latter process by accepting pairs of electrons from HAO and transferring them to a cytochrome acceptor. The crystal structure of cyt c554 at 2.6 Å resolution shows a predominantly α-helical protein with four covalently attached hemes. The four hemes are arranged in two pairs such that the planes of the porphyrin rings are almost parallel and overlapping at the edge; corresponding heme arrangements are observed in other multi-heme proteins. Striking structural similarities are evident between the tetra-heme core of cyt c554 and hemes 3–6 of HAO, which suggests an evolutionary relationship between these redox partners.

Evidence for an iron center in the ammonia monooxygenase from Nitrosomonas europaea

Binding of the ligand, nitric oxide, in the presence of reductant was used to identify a ferrous S=3/2 signal, characteristic of a ferrous nitrosyl complex, and a g=2.03 copper of iron signal in membranes of the ammonia‐oxidizing bacterium, Nitrosomonas europaea. The same ferrous S=3/2 signal is thought to be a component of the membrane‐associated methane monooxygenase (pMMO) of Methylococcus capsulatus Bath, since it is seen in the membrane fraction of cells expressing pMMO and in the purified enzyme, but not in the membrane fraction of cells expressing the soluble MMO [Zahn, J.A. and DiSpirito, A.A. (1996) J. Bacteriol. 178, 1018–1029]. Treatment of resting membranes or cells of N. europaea with nitrapyrin, 2‐chloro,6‐trichloromethylpyridine, resulted in the increase in magnitude of a g = 6, high‐spin ferric iron signal. In the presence of NO and reductant, nitrapyrin prevented the formation of the S=3/2 nitrosyl‐iron complex while increasing the intensity of the g=6 signal. Nitrapyrin is a specific inhibitor of, and is reduced by, the ammonia monoxygenase (AMO) [Bédard, C. and Knowles, R. (1989) Microbiol. Rev. 53, 38–83]. Taken together the data suggest that iron capable of forming the S=3/2 complex is a catalytic component of AMO of N. europaea, possibly a part of the oxygen‐activating center. Inactivation of the membrane‐associated AMO with acetylene did not diminish the S=3/2 nitrosyl‐iron signal, the g=6 signal, or the g=6 signal.

Cytochrome c peroxidase from Methylococcus capsulatus Bath.

Abstract A bacterial cytochrome c peroxidase was purified from the obligate methanotroph Methylococcus capsulatus Bath in either the fully oxidized or the half reduced form depending on the purification procedure. The cytochrome was a homo-dimer with a subunit mol mass of 35.8 kDa and an isoelectric point of 4.5. At physiological temperatures, the enzyme contained one high-spin, low-potential (Em7 = –254 mV) and one low-spin, high-potential (Em7 = +432 mM ) heme. The low-potential heme center exhibited a spin-state transition from the penta-coordinated, high-spin configuration to a low-spin configuration upon cooling the enzyme to cryogenic temperatures. Using M. capsulatus Bath ferrocytochrome c555 as the electron donor, the KM and Vmax for peroxide reduction were 510 ± 100 nM and 425 ± 22 mol ferrocytochrome c555 oxidized min–1 (mole cytochrome c peroxidase)–1, respectively.

High-resolution structures of the oxidized and reduced states of cytochrome c554 from Nitrosomonas europaea

Cytochrome c554 (cyt c554) is a tetra-heme cytochrome involved in the oxidation of NH3 by Nitrosomonas europaea. The X-ray crystal structures of both the oxidized and dithionite-reduced states of cyt c554 in a new, rhombohedral crystal form have been solved by molecular replacement, at 1.6 Å and 1.8 Å resolution, respectively. Upon reduction, the conformation of the polypeptide chain changes between residues 175 and 179, which are adjacent to hemes III and IV. Cyt c554 displays conserved heme-packing motifs that are present in other heme-containing proteins. Comparisons to hydroxylamine oxidoreductase, the electron donor to cyt c554, and cytochrome c nitrite reductase, an enzyme involved in nitrite ammonification, reveal substantial structural similarity in the polypeptide chain surrounding the heme core environment. The structural determinants of these heme-packing motifs extend to the buried water molecules that hydrogen bond to the histidine ligands to the heme iron. In the original structure determination of a tetragonal crystal form, a cis peptide bond between His129 and Phe130 was identified that appeared to be stabilized by crystal contacts. In the rhombohedral crystal form used in the present high-resolution structure determination, this peptide bond adopts the trans conformation, but with disallowed angles of φ and ψ.

Evidence for a crosslink between c-heme and a lysine residue in cytochrome P460 of Nitrosomonas europaea

Sequence analysis of a purified heme‐containing tryptic chromopeptide from cytochrome P460 revealed two predominant amino acid residues per cycle. Two peptides present in the chromopeptide with the sequences NLPTAEXAAXHK and DGTVTVXELVSV. Comparison of the data to the gene sequence for the protein revealed that the gaps in the first peptide (indicated by Xs) code for C residues, confirming the prediction of a c‐heme binding motif. The gap in the sequence in the second peptide at cycle 7 is predicted by the gene sequence to be a K. The results suggest that the lysine residue is crosslinked in some manner to the porphyrin macrocycle, possibly mimicking the tyrosine crosslink found for the heme P460 of HAO. While a common role for the crosslinked residues in HAO and cytochrome P460 is difficult to ascertain due to the dissimilarities in side chain structure, it may be related to the similar pK a values for lysine and tyrosine.

Primary sequence and solution conformation of ferrocytochrome c-552 from Nitrosomonas europaea.

Cytochrome c-552 from Nitrosomonas europaea is a 9.1-kDa monoheme protein that is a member of the bacterial cytochrome c-551 family. The gene encoding for c-552 has been cloned and sequenced and the primary sequence of the product deduced. Proton resonance assignments were made for all main-chain and most side-chain protons in the diamagnetic, reduced form by two-dimensional NMR techniques. Distance constraints (1056) were determined from nuclear Overhauser enhancements, and torsion angle constraints (88) were determined from scalar coupling estimates. Solution conformations for the protein were computed by the hybrid distance geometry-simulated annealing approach. For 20 computed structures, the root mean squared deviation from the average position of equivalent atoms was 0.84 A (sigma = 0.12) for backbone atoms over all residues. Analysis by residue revealed there were three regions clearly less well defined than the rest of the protein: the first two residues at the N-terminus, the last two at the C-terminus, and a loop region from residues 34 to 40. Omitting these regions from the comparison, the root mean squared deviation was 0.61 A (sigma = 0.13) for backbone atoms, 0.86 A (sigma = 0.12) for all associated heavy atoms, and 0. 43 A (sigma = 0.17) for the heme group. The global folding of the protein is consistent with others in the c-551 family. A deletion at the N-terminus relative to other family members had no impact on the global folding, whereas an insertion at residue 65 did affect the way the polypeptide packs against the methionine-ligated side of the heme. The effects of specific substitutions will be discussed. The structure of c-552 serves to delineate essential features of the c-551 family.

Identification of axial ligands of cytochrome c552 from Nitrosomonas europaea

Cytochrome c 552 from Nitrosomonas europaea was analyzed by visible, EPR and MCD spectroscopies. The visible and MCD data show that histidine and methionine are the axial ligands to the heme iron of the ferric protein. The EPR spectrum of the cytochrome shows an atypical highly axial low spin (HALS) type signal with g‐values that make it difficult to identify the axial ligands. These results reinforce the value of near‐infrared MCD spectroscopy for assigning ligands in ferric heme systems and point out the difficulties in using only EPR spectroscopy for the same purpose. The description of another c‐cytochrome exhibiting a HALS‐type EPR signal will eventually be helpful in explaining the physical basis for this unusual signal.