CiteULike: neils's nitrite

Transcriptional analysis of the nirS gene, encoding cytochrome cd1 nitrite reductase, of Paracoccus pantotrophus LMD 92.63.

NF Saunders — 2008-05-11T09:22:17-00:00

Microbiology (Reading, England), Vol. 146 ( Pt 2) (February 2000), pp. 509-516.

The gene for cytochrome cd1 nitrite reductase of Paracoccus pantotrophus, a protein of known crystal structure, is nirS. This gene is shown to be flanked by genes previously recognized in other organisms to encode proteins involved in the control of its transcription (nirI) and the biosynthesis of the d1 cofactor (nirE). Northern blot analysis has established under anaerobic conditions that a monocistronic transcript is produced from nirS, in contrast to observations with other denitrifying bacteria in which arrangement of flanking genes is different and the messages produced are polycistronic. The lack of a transcript under aerobic conditions argues against a role for cytochrome cd1 in the previously proposed aerobic denitrification pathway in Pa. pantotrophus. A putative rho-independent transcription termination sequence immediately following nirS, and preceding nirE, can be identified. The independent transcription of nirS and nirE indicates that it should be possible to produce site-directed mutants of nirS borne on a plasmid in a nirS deletion mutant. The transcript start point for nirS has been determined by two complementary techniques, 5'-RACE (Rapid amplification of cDNA 5' ends) and primer extension. It is 29 bp upstream of the AUG of nirS. An anaerobox, which presumably binds Nnr, is centred a further 41.5 bp upstream of the transcript start. No standard sigma70 DNA sequence motifs can be identified, but a conserved sequence (T-T-GIC-C-G/C-G/C) can be found in approximately the same position (-16) upstream of the transcript starts of nirS and nirI, whose products are both involved in the conversion of nitrite to nitric oxide.

Transcription regulation of the nir gene cluster encoding nitrite reductase of Paracoccus denitrificans involves NNR and NirI, a novel type of membrane protein.

NF Saunders — 2008-05-11T09:20:58-00:00

Molecular microbiology, Vol. 34, No. 1. (October 1999), pp. 24-36.

The nirIX gene cluster of Paracoccus denitrificans is located between the nir and nor gene clusters encoding nitrite and nitric oxide reductases respectively. The NirI sequence corresponds to that of a membrane-bound protein with six transmembrane helices, a large periplasmic domain and cysteine-rich cytoplasmic domains that resemble the binding sites of [4Fe-4S] clusters in many ferredoxin-like proteins. NirX is soluble and apparently located in the periplasm, as judged by the predicted signal sequence. NirI and NirX are homologues of NosR and NosX, proteins involved in regulation of the expression of the nos gene cluster encoding nitrous oxide reductase in Pseudomonas stutzeri and Sinorhizobium meliloti. Analysis of a NirI-deficient mutant strain revealed that NirI is involved in transcription activation of the nir gene cluster in response to oxygen limitation and the presence of N-oxides. The NirX-deficient mutant transiently accumulated nitrite in the growth medium, but it had a final growth yield similar to that of the wild type. Transcription of the nirIX gene cluster itself was controlled by NNR, a member of the family of FNR-like transcriptional activators. An NNR binding sequence is located in the middle of the intergenic region between the nirI and nirS genes with its centre located at position -41.5 relative to the transcription start sites of both genes. Attempts to complement the NirI mutation via cloning of the nirIX gene cluster on a broad-host-range vector were unsuccessful, the ability to express nitrite reductase being restored only when the nirIX gene cluster was reintegrated into the chromosome of the NirI-deficient mutant via homologous recombination in such a way that the wild-type nirI gene was present directly upstream of the nir operon.

Cytochrome cd1 structure: unusual haem environments in a nitrite reductase and analysis of factors contributing to beta-propeller folds.

SC Baker — 2008-05-11T09:19:15-00:00

Journal of molecular biology, Vol. 269, No. 3. (13 June 1997), pp. 440-455.

The central tunnel of the eight-bladed beta-propeller domain of cytochrome cd1 (nitrite reductase) is seen, from a 1.28 A resolution structure, to contain hydrogen donors and acceptors that are satisfied by interaction either with water or the d1 haem. The d1 haem, although bound by an extensive network of hydrogen bonds, is not distorted in its binding pocket and is confirmed to have exactly the dioxoisobacteriochlorin structure proposed from chemical studies. A biological rationale is advanced for the undistorted structure of the d1 haem and the large number of hydrogen bonds it makes. The beta-propeller domain can be closely superimposed on that of methanol dehydrogenase despite the enzymes sharing no common sequence motifs and using a different set of interactions to "Velcro" close the propeller. The sequence and likely structural relationships between cytochrome cd1 or methanol dehydrogenase and other predicted eight-bladed beta-propeller domains in proteins, such as the pyrolloquinoline quinone-dependent alcohol dehydrogenase, are discussed and compared with other propeller proteins. From sequencing the nirS gene of Thiosphaera pantotropha, it is established that the amino acid sequence deduced previously in part from X-ray diffraction data at lower resolution was largely correct, as was the proposal that eight N-terminal amino acid residues were not seen in the structure. The unusual haem iron environments in both the c-type cytochrome domain, with His/His coordination, and the d1-type cytochrome domain with Tyr/His coordination are related to the functions of the redox centres.

Haem-ligand switching during catalysis in crystals of a nitrogen-cycle enzyme.

PA Williams — 2008-05-11T09:17:32-00:00

Nature, Vol. 389, No. 6649. (25 September 1997), pp. 406-412.

Cytochrome cd1 nitrite reductase catalyses the conversion of nitrite to nitric oxide in the nitrogen cycle. The crystal structure of the oxidized enzyme shows that the d1 haem iron of the active site is ligated by His/Tyr side chains, and the c haem iron is ligated by a His/His ligand pair. Here we show that both haems undergo re-ligation during catalysis. Upon reduction, the tyrosine ligand of the d1 haem is released to allow substrate binding. Concomitantly, a refolding of the cytochrome c domain takes place, resulting in an unexpected change of the c haem iron coordination from His 17/His 69 to Met106/His69. This step is similar to the last steps in the folding of cytochrome c. The changes must affect the redox potential of the haems, and suggest a mechanism by which internal electron transfer is regulated. Structures of reaction intermediates show how nitric oxide is formed and expelled from the active-site iron, as well as how both haems return to their starting coordination. These results show how redox energy can be switched into conformational energy within a haem protein.