Previous Article | Next Article 
Journal of Bacteriology, March 2000, p. 1442-1447, Vol. 182, No. 5
Department of Molecular Biology and
Biotechnology, University of Sheffield, Sheffield S10 2TN, United
Kingdom
Received 14 September 1999/Accepted 5 December 1999
We report the cloning and sequencing of the gene containing
cytochrome c' (cycP) from the photosynthetic
purple bacterium Rhodobacter capsulatus and the regions
flanking that gene. Mutant strains unable to synthesize cytochrome
c' had increased sensitivity to nitrosothiols and to nitric
oxide (which binds to the heme moiety of cytochrome c').
The physiological function of
periplasmic bacterial cytochrome c' has eluded definition
for over 40 years since its first discovery (27), despite
extensive biochemical and biophysical analysis. The amino acid
sequences of cytochromes c' from metabolically diverse
proteobacteria reveal these cytochromes to be entirely distinct from
the class I c-type cytochromes that include the mitochondrial cytochrome c (1). Most striking is
that the motif CXXCH, at which the heme is covalently bound, is located
toward the C terminus of the polypeptide. Three-dimensional structures of cytochromes c' from a number of different bacteria
(9, 11, 22, 25, 29) show that the heme iron lacks an amino
acid ligand at its sixth coordination site, consistent with the
high-spin-intermediate-spin state of the heme iron and unusual optical
spectral features (17). The hydrophobic environment in this
unoccupied pocket explains why the binding of ligands to cytochrome
c' is limited to small, predominantly uncharged ligands,
particularly nitric oxide (NO) and carbon monoxide (CO).
There are some data available which indicate that the physiological
function of cytochrome c' involves binding NO in vivo. Electron paramagnetic resonance spectroscopy of intact cells of denitrifying bacteria which produce cytochrome c' has shown
that these organisms contain a heme-nitrosyl after growth under
denitrifying conditions, whereas organisms that do not synthesize
cytochrome c' do not give rise to a spectral feature due to
a heme-nitrosyl (30, 31). The possibility cannot be
excluded, however, that the spectral feature is due to some chromophore
other than cytochrome c'. Work in our laboratory has shown
that cytochrome c' added to a suspension of denitrifying
bacteria binds to NO which is produced as a freely diffusible
intermediate during denitrification, indicating that the cytochrome is
indeed capable of binding NO at the concentrations it achieves in vivo
during denitrification (20). NO is a free radical that is
capable of damaging cellular material, particularly by reaction with
thiols and transition metals in proteins, and hence inhibiting normal
metabolism. Furthermore, under aerobic conditions, NO reacts with the
superoxide anion to form peroxynitrite (ONOO Cloning and sequencing of cycP.
To investigate the
function of cytochrome c', we amplified the gene encoding
cytochrome c', cycP, from the photosynthetic bacterium Rhodobacter capsulatus PAS100 by PCR using primers
which had been designed to the cytochrome c' amino acid
sequence from R. capsulatus SP7 (1). Degeneracy
in the oligonucleotide primers was biased according to the probable
codon usage as determined for R. capsulatus by Armstrong et
al. (3). Primer 1 was designed to an amino acid sequence
toward the N terminus (VLEAREA), 5'-GTSCTKGARGCSCGSGARGC-3'; primer 2 was designed to be complementary to sequence toward the C terminus (CKACHDD), 5'-TCRTCRTGGCASGCYTTGCA-3' (where
S = G/C, K = G/T, R = G/A, and Y = C/T). Thermal
cycling using these oligonucleotide primers with R. capsulatus chromosomal DNA as a template (35 cycles of 30 s
of denaturation at 94°C, 60 s of annealing at 60°C, and 90 s of extension at 72°C) gave a 350-bp product which was
confirmed as cycP by DNA sequencing using an ABI 373A DNA
sequencer (Applied Biosystems). Digoxigenin-labeled deoxynucleoside
triphosphate mix was used to amplify a labeled cycP product
which was used as a hybridization probe. To identify a suitable
fragment of R. capsulatus PAS100 chromosomal DNA which
contained cycP, a Southern hybridization of DNA digested
with a range of restriction enzymes was undertaken. A SalI
fragment of 6 kb hybridized with the digoxigenin-labeled cycP probe. A library was constructed by cloning R. capsulatus PAS100 DNA SalI fragments of around 6 kb
into the vector pZErO and maintaining the clones in Escherichia
coli TOP10F'. A colony blot identified those transformants which
contained the cloned cycP fragment. The plasmid was purified
from a culture of one of these colonies and designated pCP101. The
insert of pCP101 was sequenced using a primer walking approach,
starting with primers designed to the central region of
cycP, identified by sequencing of the initial 350-bp
amplification product. Sequence was compiled using Staden, and further
analysis of the sequence utilized the Wisconsin GCG package available
from the SEQNET facility at the Daresbury Laboratory and sequence
analysis program available on the Internet at
http://www.expasy.hcuge.ch.
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Cytochrome c' from Rhodobacter
capsulatus Confers Increased Resistance to Nitric Oxide
ABSTRACT
Top
Abstract
Text
References
TEXT
Top
Abstract
Text
References
), which may
also be a potent agent of oxidative damage. Cytochrome c'
may function to prevent the accumulation of NO and hence protect the
bacterial cell against the harmful effects of NO and nitrosative stress.
View larger version (19K):
[in a new window]
FIG. 1.
Map of cycP and flanking regions. Physical
map of the R. capsulatus region containing cycP
(encoding cytochrome c'), cybP (encoding a
putative membrane-bound b-type cytochrome), and three open
reading frames with no homology to genes of known function. Constructs
were generated in this work containing a Kmr cassette
inserted in the XhoI site within cycP in the
opposite direction from cycP transcription (plasmids pCP201
and pCP301 and R. capsulatus strain MC101) (i) and in the
same direction as cycP transcription (plasmids pCP202 and
pCP302 and R. capsulatus strain MC111) (ii).
G = 
19.7 kcal, as calculated using GCG program
Mfold) followed by a T-rich region which may together constitute the
elements necessary to stop transcription. There is a purine-rich
putative ribosome binding site just upstream from the predicted start
site of cybP but no obvious promoter features. It is likely
therefore that the expression of cybP relies upon
read-through from cycP, and therefore the level of
expression of the membrane cytochrome is low compared to that of
cytochrome c'.
In order to gauge the distribution of cytochrome c', a
TBLASTN search was executed against a National Center for Biotechnology Information database containing all complete and partially complete eubacterial and archaeal genome sequences
(http://www.ncbi.nlm.nih.gov/BLAST/unfinishedgenome.html). Genes with significant homology to cycP were identified in
the genomes of Pseudomonas aeruginosa, Bordetella
pertussis, and Neisseria meningitidis. Part of the gene
for cytochrome c' from N. meningitidis had
previously been identified in a project to identify its neighboring gene lst, which encodes lipopolysaccharide
-2,3-sialyltransferase (13). In each case, the gene
consists of an open reading frame whose predicted amino acid sequence
bears significant similarity to the mature cytochrome c'
(including the conservation of the c-heme covalent
attachment motif CXXCH toward the C terminus) and an N-terminal
predicted periplasmic leader sequence. Although organisms of
significantly variable metabolic diversity which contain cytochrome
c' have been identified, all those so far identified are
members of the -, 
-, or 
-Proteobacteria.
Our analysis showing that the pathogen N. meningitidis is
capable of synthesizing a cytochrome c' is of interest,
since this organism needs to withstand environments in which NO is
produced specifically as a toxic agent, during its pathogenic life
cycle. Macrophages produce NO as a consequence of bacterial infection causing induction of inducible NO synthase. The capacity of the organisms to withstand NO may be an important virulence factor. A
further twist is that the production of NO may damage the blood-brain barrier, thus allowing N. meningitidis to enter the meninges
and cause the disease state of meningitis (6).
Insertional mutagenesis of cycP. Mutant strains in which cycP was disrupted were generated by inserting the kanamycin resistance gene derived from Tn903 into the XhoI site located within cycP. The kanamycin resistance gene was inserted in both orientations in order to ensure that polar effects of the insertion could be discounted. (The kanamycin resistance gene lacks transcriptional terminators [21], and therefore read-through into cybP should occur in mutant strains in which the resistance cassette is oriented in the same direction as transcription of cycP and cybP, but not when the cassette is oriented oppositely.)
The insert from pCP101 was excised with NsiI and ligated into pGEM-3Zf(+), which had been digested with PstI, to produce a plasmid with a unique XhoI site within cycP. A SalI restriction fragment containing the Tn903-derived kanamycin resistance cartridge from pUC4-K was inserted into the XhoI site, yielding plasmids pCP201 and pCP202 (Fig. 1 and Table 1). pCP201 and pCP202 were digested with KpnI, and the sticky ends were rendered blunt with T4 polymerase. The resultant 7-kb fragments containing disrupted copies of cycP were ligated into the vector pRVS1 (26) (a mobilizable vector capable of replicating within an E. coli host but not within R. capsulatus), which had been linearized with SmaI, to produce pCP301 and pCP302. These plasmids were transformed into E. coli S17-1 (24). E. coli S17-1(pCP301) and E. coli S17-1(pCP302) were allowed to undergo a conjugative mating with R. capsulatus PAS100. For the mating, bacterial strains were grown to mid-log phase, harvested and washed, mixed in a 2:1 ratio of R. capsulatus to E. coli, and maintained on 0.22-µm-pore-size nitrocellulose filters on RCV (28) agar plates for 6 h. R. capsulatus transconjugants in which the kanamycin resistance encoded within plasmids pCP301 and pCP302 had become incorporated into the chromosome by homologous recombination were selected on RCV-malate plates containing kanamycin and rifampin (R. capsulatus PAS100 is resistant to rifampin, the antibiotic being included to counterselect against the E. coli donor strain). Of the resultant transconjugants, 5% were spectinomycin sensitive, indicating that the plasmid DNA containing the spectinomycin resistance gene had become lost. Southern analysis confirmed that double crossovers had occurred such that R. capsulatus MC111 and MC101 each contained a single, disrupted copy of cycP with the kanamycin resistance cassette inserted so as to be transcribed in the same orientation as (MC111) and opposite orientation from (MC101) cycP.
|
|
Growth rates of R. capsulatus strains.
R.
capsulatus PAS100 (wild type) and MC101 and MC111 (cycP
mutant strains) were grown under anaerobic photoheterotrophic
conditions, chemoheterotrophic aerobic conditions, and
chemoheterotrophic anaerobic conditions with 60 mM dimethyl sulfoxide
(DMSO) as respiratory electron acceptor in the dark in RCV medium
(28) supplemented with 25 mM malate. Under aerobic
conditions, the wild-type and mutant strains grew at similar rates, as
would be expected given that cytochrome c' is expressed
mainly under anaerobic conditions (4). A more unexpected
finding was that the mutant strains grew slightly faster than the
wild-type strain under anaerobic conditions. This was particularly
notable during growth in the dark with DMSO as respiratory electron
acceptor (growth rate, µPAS100 = 0.0117 ± 0.0011 h1, µMC111 = 0.0176 ± 0.0022 h1, and µMC101 = 0.0200 ± 0.0006 h1). Cytochrome c' is a highly
expressed protein and represents ca. 5 to 10% of the total periplasmic
protein in the wild type after anaerobic growth. The absence of
cytochrome c' may allow a subsequently higher concentration
of other proteins in the periplasm (e.g., binding proteins necessary
for transport processes and other electron transport proteins),
enabling more rapid metabolism and hence growth. This metabolic burden
imposed by synthesis of the cytochrome is most noticeable under
anaerobic conditions in the dark with DMSO, presumably because the
bacteria grow exceedingly slowly under these conditions, and hence the
metabolic burden is exaggerated.
Disk diffusion susceptibility assays.
The toxicity of various
compounds to strains of R. capsulatus was assessed on agar
plates spread with a lawn of the bacteria. Whatman 3MM paper disks
(4-mm diameter) soaked in a solution of test substance were carefully
laid onto the center of the plates, and the plates were then incubated
at 30°C overnight. A circular zone of clearing, within which there
was no bacterial growth, occurred on the plates surrounding the filter
disk which had been soaked in toxic chemical. The concentration of
toxic compound decreases with distance from the disk since the
concentration is dependent upon diffusion. The diameter of the
clearance zone is a measure of the toxicity of the substance to a given
R. capsulatus strain. Filters which were soaked with
hydrogen peroxide (H2O2) or with methyl
viologen or benzyl viologen, which are superoxide (O2) releasers, gave similar clearance zones
for mutant and wild-type strains (data not shown). On the other hand,
soaking filter disks with S-nitrosoglutathione (GSNO) and
S-nitrosopenicillamine (SNAP) (both of which can release NO
on homolysis or act as nitrosating agents, transferring
NO+) gave rise to a larger zone of clearance for the
cycP mutant than for the wild type, indicating that the
mutant is sensitive to NO or nitrosative stress (Fig.
3A).
|
Effect of NO gas on growth rate. The finding that the NO releasers and nitrosating agents GSNO and SNAP were less toxic to a strain of R. capsulatus expressing cytochrome c' than to strains which could not express the cytochrome suggests that the cytochrome serves to detoxify NO in vivo. However, given the possibility that the effect of these chemicals is independent of NO, we devised a method to directly test the toxicity of NO. Growth of R. capsulatus strains was carried out in agar, in glass tubes with a 9-mm internal diameter. Suspensions of R. capsulatus were mixed with RCV-malate containing either 0.3 or 1.0% agar at 42°C, poured into glass tubes, and allowed to set. The tubes were fitted with gastight Suba-Seals, and the headspace was sparged with nitrogen gas. Subsequently, known volumes of NO gas (obtained from Aldrich) were injected into the headspace using a Hamilton syringe in order to assess the effect of the gas on growth of R. capsulatus strains. During the subsequent incubation, NO diffused from the headspace through the agar, and a zone of clearance formed at the top of the tubes due to the toxicity of NO gas. The depth of the clearance zone is a measure of the toxicity of NO to a given strain. Figure 3B shows typical NO tubes and demonstrates clearly that the wild type is significantly less susceptible to the toxicity of NO than is either of the cycP mutant strains. In order to exclude the possibility that the clearance toward the top of the tube was due to NO acting as a chemorepellant and that the bacteria were moving down the tubes by chemotaxis, the experiments were repeated with suspensions of bacteria maintained in 1% agar (in which motility is inhibited), yielding results similar to those shown in Fig. 3B.
Effect of NO on oxygen uptake.
In R. capsulatus,
oxygen utilization is performed by heme-copper oxidases, enzymes which
are sensitive to NO (7). To test whether the presence of
cytochrome c' confers NO resistance by binding the ligand,
the rates of oxygen uptake by R. capsulatus wild-type and
cycP mutant strains were monitored in a Clark-type O2 electrode (Rank Brothers, Bottisham, Cambridge, United
Kingdom). The inhibitory effect of NO was assessed by injecting volumes of an NO-saturated solution into the vessel containing the respiring cells. Figure 4 shows that NO has a
greater inhibitory effect on oxygen respiration in the cycP
mutant strains than in the wild type.
|
Cytochrome c' confers increased resistance to NO. Since cytochrome c' is known to bind NO, and it has been speculated that its physiological function is related to this property (20, 30, 31), the influence of NO on the growth of wild-type and cycP mutant R. capsulatus was examined by a number of methods. The introduction of NO into cultures of R. capsulatus as a bolus had no noticeably differential effect on growth rates of wild-type versus mutant strains (see above). However, convincing effects on wild-type and cycP mutant R. capsulatus were achieved either indirectly via NO releasers SNAP and GSNO or directly by supplying NO to the headspace above immobilized R. capsulatus. Clearly, the mutant is more susceptible to toxicity caused by NO than is the wild-type strain (Fig. 3). Other heme proteins have been found to function in detoxification, notably, flavohemoglobin from E. coli and Salmonella enterica serovar Typhimurium (12, 18) and hemoglobin from the nematode Ascaris lumbricoides (19).
Natural environments contain detectable levels of NO, which are generated as a result of disproportionation of nitrite under acidic conditions (8) and biologically via nitrification and denitrification (2). The synthesis of cytochrome c' presumably protects R. capsulatus (and other organisms possessing the cytochrome) from the damaging effects of the radical in these environments. Bulk [NO] in soils has been measured at concentrations of up to 107 M
(23), which is sufficient to cause potent inhibition of
heme-copper oxidases (7). The capacity of cytochrome
c' to bind NO and hence allow oxygen respiratory metabolism
to continue may be a key factor in the selection of bacteria that
synthesize cytochrome c'. This latter supposition is
clearly supported by the finding that oxygen consumption is
significantly impaired in mutant strains unable to synthesize
cytochrome c' compared to wild-type strains (Fig. 4).
In conclusion, we have been able to demonstrate for the first time that
cytochrome c' has a physiological function and that this is
to alleviate the toxic effects caused by a constant supply of NO to
bacterial cultures.
Nucleotide sequence accession number. The nucleotide sequence of the gene for cytochrome c' and flanking genes has been deposited in the GenBank database under GenBank accession no. AF147705.
| |
ACKNOWLEDGMENTS |
|---|
This work was supported by Biotechnology and Biological Sciences Research Council (BBSRC) grant P08290, awarded to J.W.B.M. and R.K.P.
| |
FOOTNOTES |
|---|
* Corresponding author. Mailing address: Department of Molecular Biology and Biotechnology, University of Sheffield, Firth Court, Western Bank, Sheffield S10 2TN, United Kingdom. Phone: 44 (0) 114 2224409. Fax: 44 (0) 114 2728697. E-mail: j.moir{at}sheffield.ac.uk.
| |
REFERENCES |
|---|
|
Top
Abstract
Text
References
|
|---|
| 1. |
Ambler, R. P.,
R. G. Bartsch,
M. Daniel,
M. D. Kamen,
L. McLellan,
T. E. Meyer, and J. Vanbeeumen.
1981.
Amino-acid sequences of bacterial cytochromes c' and c556.
Proc. Natl. Acad. Sci. USA
78:6854-6857 |
| 2. |
Anderson, I. C., and J. S. Levine.
1986.
Relative rates of nitric oxide and nitrous oxide production by nitrifiers, denitrifiers, and nitrate respirers.
Appl. Environ. Microbiol.
51:938-945 |
| 3. | Armstrong, G. A., M. Alberti, F. Leach, and J. E. Hearst. 1989. Nucleotide sequence, organization, and nature of the protein products of the carotenoid biosynthesis gene cluster of Rhodobacter capsulatus. Mol. Gen. Genet. 216:254-268[CrossRef][Medline]. |
| 4. | Bartsch, R. G., R. P. Ambler, T. E. Meyer, and M. A. Cusanovich. 1989. Effect of aerobic growth-conditions on the soluble cytochrome content of the purple phototrophic bacterium Rhodobacter sphaeroides: induction of cytochrome c554. Arch. Biochem. Biophys. 271:433-440[CrossRef][Medline]. |
| 5. |
Bell, L. C.,
D. J. Richardson, and S. J. Ferguson.
1992.
Identification of nitric oxide reductase activity in Rhodobacter capsulatus: the electron transport pathway can either use or bypass both cytochrome c2 and the cytochrome bc1 complex.
J. Gen. Microbiol.
138:437-443 |
| 6. | Boje, K. M. K. 1996. Inhibition of nitric oxide synthase attenuates blood-brain barrier disruption during experimental meningitis. Brain Res. 720:75-83[CrossRef][Medline]. |
| 7. | Brown, G. C., and C. E. Cooper. 1994. Nanomolar concentrations of nitric oxide reversibly inhibit synaptosomal respiration by competing with oxygen at cytochrome oxidase. FEBS Lett. 356:295-298[CrossRef][Medline]. |
| 8. | Chalk, P. M., and C. J. Smith. 1983. Chemodenitrification. Dev. Plant Soil Sci. 9:65-89. |
| 9. | Dobbs, A. J., B. F. Anderson, H. R. Faber, and E. N. Baker. 1996. Three-dimensional structure of cytochrome c' from two Alcaligenes species and the implications for four-helix bundle structures. Acta Crystallogr. D52:356-368. |
| 10. | Even, M. T., R. J. Kassner, M. Dolata, T. E. Meyer, and M. A. Cusanovich. 1995. Molecular-cloning and sequencing of cytochrome c' from the phototrophic purple sulfur bacterium Chromatium vinosum. Biochim. Biophys. Acta 1231:220-222[Medline]. |
| 11. | Finzel, B. C., P. C. Weber, K. D. Hardman, and F. R. Salemme. 1985. Structure of ferricytochrome c' from Rhodospirillum molischianum at 1.67 Å resolution. J. Mol. Biol. 186:627-643[CrossRef][Medline]. |
| 12. |
Gardner, P. R.,
A. M. Gardner,
L. A. Martin, and A. L. Salzman.
1998.
Nitric oxide dioxygenase: an enzymic function for flavohemoglobin.
Proc. Natl. Acad. Sci. USA
95:10378-10383 |
| 13. |
Gilbert, M.,
D. C. Watson,
A. M. Cunningham,
M. P. Jennings,
N. M. Young, and W. W. Wakarchuk.
1996.
Cloning of the lipooligosaccharide alpha-2,3-sialyltransferase from the bacterial pathogens Neisseria meningitidis and Neisseria gonorrhoeae.
J. Biol. Chem.
271:28271-28276 |
| 14. | Gilmour, R., C. F. Goodhew, and G. W. Pettigrew. 1991. Cytochrome c' of Paracoccus denitrificans. Biochim. Biophys. Acta 1059:233-238[Medline]. |
| 15. | Gross, R., J. Simon, C. R. D. Lancaster, and A. Kroger. 1998. Identification of histidine residues in Wolinella succinogenes hydrogenase that are essential for menaquinone reduction by H2. Mol. Microbiol. 30:639-646[CrossRef][Medline]. |
| 16. | Keen, N. T., S. Tamaki, D. Kobayashi, and D. Trollinger. 1988. Improved broad-host-range plasmids for DNA cloning in Gram-negative bacteria. Gene 70:191-197[CrossRef][Medline]. |
| 17. | Maltempo, M. M., and T. H. Moss. 1976. The spin 3/2 state and quantum spin mixtures in haem proteins. Q. Rev. Biophys. 9:181-215[Medline]. |
| 18. | Membrillo-Hernandez, J., M. D. Coopamah, A. Channa, M. N. Hughes, and R. K. Poole. 1998. A novel mechanism for upregulation of the Escherichia coli K-12 hmp (flavohaemoglobin) gene by the 'NO releaser,` S-nitrosoglutathione: nitrosation of homocysteine and modulation of MetR binding to the glyA-hmp intergenic region. Mol. Microbiol. 29:1101-1112[CrossRef][Medline]. |
| 19. | Minning, D. M., A. J. Gow, J. Bonaventura, R. Braun, M. Dewhirst, D. E. Goldberg, and J. S. Stamler. 1999. Ascaris haemoglobin is a nitric oxide-activated `deoxygenase.' Nature 401:497-502[CrossRef][Medline]. |
| 20. | Moir, J. W. B. 1999. Cytochrome c' from Paracoccus denitrificans: spectroscopic studies consistent with a role for the protein in nitric oxide metabolism. Biochim. Biophys. Acta 1430:65-72[CrossRef][Medline]. |
| 21. | Oka, A., H. Sugisaki, and M. Takanami. 1981. Nucleotide sequence of the kanamycin resistance transposon Tn903. J. Mol. Biol. 147:217-226[CrossRef][Medline]. |
| 22. | Ren, Z., T. Meyer, and D. E. McRee. 1993. Atomic-structure of a cytochrome c' with an unusual ligand-controlled dimer dissociation at 1.8 Å resolution. J. Mol. Biol. 234:433-445[CrossRef][Medline]. |
| 23. | Rudolph, J., and R. Conrad. 1996. Flux between soil and atmosphere, vertical concentration profiles in soil, and turnover of nitric oxide. 2. Experiments with naturally layered soil cores. J. Atmos. Chem. 23:275-300[CrossRef]. |
| 24. | Simon, R., U. Priefer, and A. Puhler. 1983. A broad host range mobilization system for in vivo genetic engineering: transposon mutagenesis in Gram-negative bacteria. Bio/Technology 1:784-791[CrossRef]. |
| 25. | Tahirov, T. H., S. Misaki, T. E. Meyer, M. A. Cusanovich, Y. Higuchi, and N. Yasuoka. 1996. High-resolution crystal structures of two polymorphs of cytochrome c' from the purple phototrophic bacterium Rhodobacter capsulatus. J. Mol. Biol. 259:467-479[CrossRef][Medline]. |
| 26. |
VanSpanning, R. J. M.,
C. W. Wansell,
W. N. M. Reijnders,
N. Harms,
J. Ras,
L. F. Oltmann, and A. H. Stouthamer.
1991.
A method for introduction of unmarked mutations in the genome of Paracoccus denitrificans: construction of strains with multiple mutations in the genes encoding periplasmic cytochrome c550, cytochrome c551i, and cytochrome c553i.
J. Bacteriol.
173:6962-6970 |
| 27. |
Vernon, L. P., and M. D. Kamen.
1954.
Hematin compounds in photosynthetic bacteria.
J. Biol. Chem.
211:643-662 |
| 28. | Weaver, P. F., J. D. Wall, and H. Gest. 1975. Characterisation of Rhodopseudomonas capsulata. Arch. Microbiol. 105:207-216[CrossRef][Medline]. |
| 29. |
Yasui, M.,
S. Harada,
Y. Kai,
N. Kasai,
M. Kusunoki, and Y. Matsuura.
1992.
3-Dimensional structure of ferricytochrome c' from Rhodospirillum rubrum at 2.8 Å resolution.
J. Biochem.
111:317-324 |
| 30. |
Yoshimura, T.,
H. Iwasaki,
S. Shidara,
S. Suzuki,
A. Nakahara, and T. Matsubara.
1988.
Nitric oxide complex of cytochrome c' in cells of denitrifying bacteria.
J. Biochem.
103:1016-1019 |
| 31. | Yoshimura, T., S. Shidara, T. Ozaki, and H. Kamada. 1993. 5 coordinated nitrosylhemoprotein in the whole cells of denitrifying bacterium, Achromobacter xylosoxidans NCIB 11015. Arch. Microbiol. 160:498-500[CrossRef]. |
Journal of Bacteriology, March 2000, p. 1442-1447, Vol. 182, No. 5
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Heurlier, K., Thomson, M. J., Aziz, N., Moir, J. W. B.
(2008). The Nitric Oxide (NO)-Sensing Repressor NsrR of Neisseria meningitidis Has a Compact Regulon of Genes Involved in NO Synthesis and Detoxification. J. Bacteriol.
190: 2488-2495
[Abstract] [Full Text] -
Kruglik, S. G., Lambry, J.-C., Cianetti, S., Martin, J.-L., Eady, R. R., Andrew, C. R., Negrerie, M.
(2007). Molecular Basis for Nitric Oxide Dynamics and Affinity with Alcaligenes xylosoxidans Cytochrome c. J. Biol. Chem.
282: 5053-5062
[Abstract] [Full Text] -
Klotz, M. G., Arp, D. J., Chain, P. S. G., El-Sheikh, A. F., Hauser, L. J., Hommes, N. G., Larimer, F. W., Malfatti, S. A., Norton, J. M., Poret-Peterson, A. T., Vergez, L. M., Ward, B. B.
(2006). Complete Genome Sequence of the Marine, Chemolithoautotrophic, Ammonia-Oxidizing Bacterium Nitrosococcus oceani ATCC 19707. Appl. Environ. Microbiol.
72: 6299-6315
[Abstract] [Full Text] -
Alric, J., Pierre, Y., Picot, D., Lavergne, J., Rappaport, F.
(2005). Spectral and redox characterization of the heme ci of the cytochrome b6f complex. Proc. Natl. Acad. Sci. USA
102: 15860-15865
[Abstract] [Full Text] -
Choi, P. S., Grigoryants, V. M., Abruna, H. D., Scholes, C. P., Shapleigh, J. P.
(2005). Regulation and Function of Cytochrome c' in Rhodobacter sphaeroides 2.4.3. J. Bacteriol.
187: 4077-4085
[Abstract] [Full Text] -
Hutchings, M. I., Mandhana, N., Spiro, S.
(2002). The NorR Protein of Escherichia coli Activates Expression of the Flavorubredoxin Gene norV in Response to Reactive Nitrogen Species. J. Bacteriol.
184: 4640-4643
[Abstract] [Full Text] -
Anjum, M. F., Stevanin, T. M., Read, R. C., Moir, J. W. B.
(2002). Nitric Oxide Metabolism in Neisseria meningitidis. J. Bacteriol.
184: 2987-2993
[Abstract] [Full Text] -
Cross, R., Lloyd, D., Poole, R. K., Moir, J. W. B.
(2001). Enzymatic Removal of Nitric Oxide Catalyzed by Cytochrome c' in Rhodobacter capsulatus. J. Bacteriol.
183: 3050-3054
[Abstract] [Full Text]
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Copyright © 2009 by the American Society for Microbiology. For an alternate route to Journals.ASM.org, visit: http://intl-journals.asm.org | More Info»