1 Institute of Microbiology RAS, Prospect 60-let Octyabrya 7/2, 117811 Moscow, Russia
2 A. N. Bach Institute of Biochemistry, Russian Academy of Sciences, Moscow, Russia
3 Department of Environmental Biotechnology, Delft University of Technology, Julianalaan 67, 2628 BC Delft, The Netherlands
Correspondence
Dimitry Yu. Sorokin
soroc{at}inmi.da.ru
D.Y.Sorokin{at}tnw.tudelft.nl
![]() |
ABSTRACT |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
The GenBank accession number for the sequence of the 16S rRNA gene of strain ARhD 1T reported in this paper is AY360060.
![]() |
INTRODUCTION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Thiocyanate can be utilized as an energy source by chemolithotrophic sulfur-oxidizing bacteria, after primary degradation by two distinct pathways. Initial cleavage of the CS bond results in the formation of the intermediate cyanate (NCO) which, in the presence of bicarbonate, is converted further to ammonia and CO2 by the enzyme cyanase (Happold et al., 1958
; Youatt, 1954
). The alternative pathway is based on the initial hydrolytic cleavage of the nitrile bond (N
C), resulting in the formation of carbonyl sulfide (S=C=O) and ammonia (Katayama et al., 1992
, 1993
, 1998
). The carbonyl sulfide is subsequently hydrolysed further to sulfide and CO2. In both cases, the released sulfide can serve as the energy source and electron donor for autotrophic growth.
The ability to grow with thiocyanate as an electron donor for energy generation and CO2 fixation is restricted to a few strains of neutrophilic thiobacilli (De Kruyff et al., 1957; Happold et al., 1954
, 1958
; Katayama & Kuraishi, 1978
; Smith & Kelly, 1988
; Youatt, 1954
). Recently, we described several new thiocyanate-oxidizing bacteria capable of chemolithoautotrophic growth with thiocyanate at high pH and salt concentration (Sorokin et al., 2001a
). They included two novel species within the genus Thialkalivibrio, which accommodates a large number of haloalkaliphilic sulfur-oxidizing chemolithotrophic bacteria from soda lakes (Sorokin et al., 2001b
, 2002
). These bacteria degrade thiocyanate via cyanate.
Despite the substantial amount of information now available on bacterial thiocyanate degradation, almost nothing is known about the possibility of anaerobic growth with thiocyanate. An early publication of De Kruyff et al. (1957) reported that Thiobacillus denitrificans can grow with thiocyanate, aerobically or anaerobically, in the presence of nitrate as the electron acceptor, reducing the latter completely to N2, while Thiobacillus thioparus only reduced nitrate to nitrite in the presence of thiocyanate. The ability of certain strains of Tb. thioparus to grow with thiocyanate aerobically was independently confirmed by several research groups. On the other hand, the potential of Tb. denitrificans to grow with thiocyanate, either aerobically or anaerobically, has never been substantiated after the report of De Kruyff et al. (1957)
. Moreover, analysis of the quantitative data presented in De Kruyff et al. (1957)
showed substantial deviation of the stoichiometry from the theoretical values. This makes it difficult to understand the anaerobic conversion of thiocyanate by Tb. denitrificans. In more recent literature, we found only a single report of thiocyanate-dependent denitrification by a mixed bacterial population in a thiocyanate waste-treatment plant (Andreoni et al., 1988
).
The aim of this work was to investigate the possibility of anaerobic oxidation of thiocyanate, and to obtain kinetic parameters of the process. Two pure cultures of alkaliphilic, obligate chemolithoautotrophic and facultative anaerobic sulfur-oxidizing bacteria, capable of growth with thiocyanate as energy and nitrogen source under denitrifying conditions, have been obtained from soda-lake sediments. The two strains were identified as a novel species of the genus Thialkalivibrio.
![]() |
METHODS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Growth experiments with pure cultures.
Growth kinetics and product formation of the pure cultures with different combinations of electron donor/acceptor were studied, using the same mineral medium as for the enrichment. Anaerobic growth with thiocyanate and thiosulfate as substrate, and nitrate, nitrite or N2O as electron acceptor, was performed in 600 ml serum bottles with 500 ml cultures, using a fed-batch mode of thiocyanate and nitrate supply. During growth, the biomass, substrate consumption and product formation were measured periodically. Thiocyanate and nitrate were added on several occasions when the previous doses had been utilized. Aerobic cultures with thiocyanate and thiosulfate were incubated in 600 ml closed serum bottles, with 100 ml medium and 10 % O2 in the gas phase, on a rotary shaker at 100 r.p.m. Higher aeration inhibited growth.
Experiments with washed cells.
The respiration rates with different sulfur substrates of the washed cells grown under oxic or anoxic conditions were measured as described previously (Sorokin et al., 2001a). The anaerobic activity of washed cells was tested under anoxic conditions with different electron donors/acceptors (3 ml cell suspension in 9 ml serum bottles) in sodium carbonate/bicarbonate buffer, pH 10.
Analyses
Thiocyanate was analysed colorimetrically as ferric thiocyanate (Sörbo, 1957), thiosulfate by an iodimetric titration and by cyanolysis (Kelly et al., 1969
), sulfate by a turbidimetric method (Cypionka & Pfennig, 1986
),
by a phenol/hypochlorite colorimetric procedure according to Weatherburn (1967)
, and nitrite by a diazotation method (Gries-Romijn-van Eck, 1966
). Nitrate was assayed colorimetrically with the Szechrome NAS reagent (Polysciences): to 0·25 ml sample, 2·5 ml 0·5 % Szcechrome in 1 : 1 H2SO4/H3PO4 was added, and the absorbance was measured at 600 nm after 30 min incubation. Because of a strong thiosulfate interference, accurate nitrate measurements were only possible with thiocyanate as substrate. N2O was detected by a gas chromatograph (Fison Instruments) equipped with a Hayesep column and a 63Ni-electron capture detector. Cell protein was measured by the Lowry method. Cyanate (OCN) was routinely assayed as
released after acidification of solutions to pH 23 with 6 M HCl and subsequent heating in boiling water for 1 min. This procedure gave 9597 % recovery of pure cyanate added to standard sodium carbonate media at pH 10 (Sorokin et al., 2001a
).
Denaturing SDS-PAGE of whole-cell polypeptides was performed with a 10 % gel according to Laemmli (1970). Nitrate and nitrite reductase activities (NAR and NIR, respectively) in the cell-free extracts (obtained by sonication) were measured under anoxic conditions, with reduced methyl viologen as artificial electron donor, by analysing nitrate or nitrite consumption at pH 710, with boiled extract as a control. Detection of NAR and NIR polypeptides, after electrophoresis of total cell extracts, was based on the negative staining that resulted from enzyme activity in the presence of reduced methyl viologen as the electron donor and nitrate or nitrite as electron acceptors (Murillo et al., 1999
). Absorption spectra of the cytochromes in the cell-free extract were recorded with a UV/visible diode-array HP 8453 spectrophotometer (Hewlett Packard). Cyanase activity measurements, electron microscopy, DNA analysis and phylogenetic analysis were performed as described previously (Sorokin et al., 2001b
, 2002
).
![]() |
RESULTS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
|
The first attempts to grow the isolates anaerobically with thiocyanate and nitrate, nitrite or N2O did not provide satisfactory results: e.g. only one culture attempt out of many resulted in stable growth. Optimization of the medium revealed that a slight pH decrease from 10 to 9·69·8 stabilized the culture, resulting in reproducible anaerobic growth of both strains with thiocyanate as electron donor and nitrate or nitrite (<5 mM) as electron acceptor. However, no growth was observed with N2O as electron acceptor. Anaerobic growth with thiocyanate and nitrate was extremely slow compared to aerobic growth with thiocyanate and anoxic growth with thiosulfate plus nitrate, but the growth yield was only slightly lower (Table 1). Two parallel cultures of strain ARhD 1T, with starting pHs of 9·6 and 9·8, demonstrated exponential growth, with concomitant thiocyanate and nitrate consumption (Fig. 2
). CNO (up to 0·45 mM) and N2O (0·1 mM) were detected as minor intermediates, while ammonia (6575 % of the metabolized SCN nitrogen) and sulfate (9095 % of the metabolized SCN sulfur) were the final products of anaerobic thiocyanate oxidation. During the exponential growth phase, the ratio of the consumed nitrate/thiocyanate was within the range 1·31·4. However, at the end of growth, incomplete nitrate reduction to nitrite and an increase of the consumed nitrate/thiocyanate ratio to 1·61·9 were observed. The maximum specific growth rate during the exponential phase was 0·006 h1. Accumulation of free ammonia as a product of thiocyanate degradation at high pH may be extremely toxic for these alkaliphilic autotrophs (Sorokin et al., 2001a
). Therefore, to check its effect, one of the parallel anaerobic cultures of strain ARhD 1T was continuously flushed with argon to strip off the accumulating ammonia. Despite an almost complete removal of ammonia from the culture, no obvious growth stimulation was observed compared to the control culture grown without argon flushing. The anaerobic growth of both isolates with thiosulfate was much faster than growth on thiocyanate, but still much slower than that observed under aerobic conditions (Table 1
). Similar to growth with thiocyanate, no intermediate nitrite production was observed in the anaerobic cultures grown with thiosulfate plus nitrate.
|
|
Metabolic potential
Washed cells of ARhD 1T and ARhD 2, grown with either thiocyanate or thiosulfate as substrate, were capable of aerobic oxidation of thiosulfate, sulfide, polysulfide, elemental sulfur and tetrathionate to sulfate. The thiocyanate-oxidizing capacity (thiocyanate-dependent oxygen uptake and thiocyanate consumption by washed cells) was induced only in the presence of thiocyanate. The aerobic activity of cells grown anaerobically, with thiocyanate or thiosulfate as substrate, was evidently repressed compared to that of cells grown in the presence of oxygen (Table 1).
Both strains expressed a high level of cyanase while growing with thiosulfate, thiocyanate or a combination of these substrates. The activity levels were within the range of 650700, 10501700 and 650870 nmol (mg protein min)1 in cells grown with thiosulfate plus ammonia, thiosulfate plus thiocyanate, or thiocyanate alone, respectively. The presence of active cyanase in the cells grown with thiocyanate as single energy and nitrogen source clearly differentiates the new isolates from the previously described aerobic thiocyanate-oxidizing alkaliphiles, which either completely lack cyanase activity or repress its production during growth with thiocyanate. (Sorokin et al., 2001a, 2002
).
The anaerobic activity (oxidation of thiocyanate and thiosulfate in the presence of nitrogen oxides) of the cells grown with thiocyanate plus nitrate was very low, ranging from 1·5 to 6 nmol SCN oxidized (min mg protein)1 with nitrate, nitrite or N2O as electron acceptor. In contrast to the whole-cell activity with equally low nitrate- and nitrite-reduction potentials, the in vitro measurements of NARNIR activities with an artificial electron donor demonstrated the presence of a much greater NAR activity in comparison with NIR [79 and 4 nmol nitrite (min mg protein)1, respectively]. The pH optima for in vitro NAR and NIR activities were 7·0 and 9·0, respectively, suggesting that the two enzymes are located in different cellular compartments. Activity staining of native gels demonstrated the presence of two different polypeptides with NAR activity (apparent molecular masses of 150 and 230 kDa) and a 60 kDa NIR (data not shown).
Cytochrome spectra of cell extracts prepared from cells grown anaerobically with thiocyanate plus nitrate revealed several peaks typical of cytochrome cd1-containing NIR, e.g. at 422 and 468 nm in the gamma region and 553, 613 and 667 nm in the alpha region (supplementary Fig. S1 at http://mic.sgmjournals.org). In the cells of strain ARhD 1T grown aerobically with thiosulfate, cytochrome c and an unidentified cytochrome with the alpha- maximum at 585 nm were detected in the soluble fraction (supplementary Fig. S2a), and cytochromes c, b and aa3-type in the membrane fraction (supplementary Fig. S2b).
Total protein profiles obtained from cells grown with different substrates demonstrated obvious differences from the previously described aerobic strain Thialkalivibrio thiocyanoxidans strain ARh 4 in the sizes of the polypeptides specifically expressed during growth with thiocyanate (Fig. 3). While strain ARh 4 overexpressed only a single polypeptide with an apparent molecular mass of 62 kDa, the new isolates had four specific bands with apparent masses of 5961, 4750, 2829 and 17·5 kDa.
|
|
![]() |
DISCUSSION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
![]() |
![]() |
![]() |
According to the total reaction, 1·6 mol nitrate should be reduced to nitrogen gas per 1 mol thiocyanate oxidized to sulfate. Assuming that 1020 % of the electrons are utilized for CO2 reduction in anabolic reactions (Kelly, 1982; Visser et al., 1997
), the ratio must be 1·281·44 (mean 1·36). The actual stoichiometry observed in exponentially growing anaerobic ARhD 1T cultures was very close to the theoretical values (see Fig. 2b
). The extremely low specific growth rate of the anaerobic thiocyanate-utilizing cultures might indicate certain metabolic constraints in such metabolism. This is hardly surprising, since even in the presence of oxygen, instead of nitrate, as electron acceptor, the growth rate with thiocyanate in ARhD 1T was six times lower than that with thiosulfate. However, thiosulfate and nitrate are effective substrates for sulfur-oxidizing bacteria and various denitrifiers, respectively. Therefore, organisms like strains ARhD 1T and ARhD 2 might have a competitive advantage in using the anaerobic thiocyanate-oxidation reaction, when more effective substrates, such as suphide or thiosulfate, are not available. Of course, the question remains as to the availability of thiocyanate and nitrate in soda lakes. The relative ease of enrichment of aerobic thiocyanate-oxidizing alkaliphiles from soda-lake sediments (Sorokin et al., 2001a
) indirectly indicates the presence of the substrate. Nitrate production in soda lakes might be attributed to the presence of autotrophic, alkali-tolerant ammonia- and nitrite-oxidizing bacteria (Sorokin et al., 1998
, 2001c
), although this assumption might be problematic for hypersaline lakes from which nitrifying bacteria cannot be enriched.
One of our major concerns about the possibility of anaerobic growth with thiocyanate under alkaline conditions was ammonia toxicity. However, there was no obvious growth stimulation upon removal of ammonia from the medium (see Fig. 2b). Both isolates were able to grow actively at ammonia concentrations above 5 mM, and were apparently less sensitive to free ammonia than the aerobic alkaliphilic strains (Sorokin et al., 2001a
). Their higher tolerance to ammonia was also reflected by the presence of high cyanase activity (producing ammonia from cyanate) in cells growing with thiocyanate. It has been shown previously for aerobic alkaliphiles that cyanase is specifically repressed when thiocyanate is utilized as energy source, to avoid toxic ammonia accumulation (Sorokin et al., 2001a
).
Another interesting aspect of the physiology of the new isolates is that they represent the first example of complete denitrifiers (capable of complete reduction of nitrate to nitrogen gas) among the haloalkaliphilic sulfur-oxidizing chemolithoautotrophs known so far. Our numerous attempts to find such bacteria in soda lakes using sulfide or thiosulfate as electron donor yielded partial denitrifiers, such as Tv. denitrificans, which started denitrification from nitrite and grew best with nitrous oxide as electron acceptor (Sorokin et al., 2001d). When nitrate was used as the electron acceptor, enrichment either selected for nitrite-accumulating species or resulted in co-cultures of incomplete denitrifiers, consisting of nitrite-producing nitrate reducers and species similar to Tv. denitrificans, reducing nitrite to dinitrogen gas (Sorokin et al., 2003
). The major problem of autotrophic denitrification under haloalkaliphilic conditions seems to be the excessive nitrite accumulation, possibly due to the higher sensitivity of the (periplasmic) nitrite-reduction stage to extreme conditions (high pH/high salt) compared to nitrate reduction. The use of thiocyanate instead of thiosulfate as electron donor resulted in the selection of complete autotrophic denitrifiers from the soda lakes which, in contrast to the other haloalkaliphilic denitrifiers, did not accumulate nitrite during nitrate reduction. One of the possible explanations could be the extremely slow growth of the denitrifying strains with thiocyanate under anaerobic conditions, which might ensure a balance in the activity of NAR and NIR. While the in vitro measurements demonstrated a much higher (potential) NAR activity, the in vivo situation, measured with whole cells, showed low rates of both nitrate and nitrite reduction.
Apart from the possible ecological advantage, the potential for autotrophic growth with thiocyanate under denitrifying conditions might also be important in industrial treatment plants dealing with thiocyanate-containing wastewater, at least in the case of the simultaneous presence of thiocyanate and nitrate combined with oxygen limitation (Andreoni et al., 1988). Usually, microbial degradation of thiocyanate in such plants results in the excessive production of ammonium, which is further oxidized to nitrate by nitrifying bacteria present in the activated sludge (Dictor et al., 1997
). In the case of low concentrations of organic electron donors and high residual thiocyanate, the additional anaerobic pathway might be useful to enhance thiocyanate degradation.
Overall, the quantitative data presented in this paper confirm the observation of De Kruyff et al. (1957) on the possibility of bacterial thiocyanate-dependent denitrification in neutrophilic obligate chemolithoautotrophic sulfur-oxidizing bacteria. The facultative anaerobic thiocyanate-utilizing haloalkaliphilic strains ARhD 1T and ARhD 2, isolated from soda-lake sediments, can be regarded as a novel species of the genus Thialkalivibrio on the basis of their unique physiological and genetic properties. The name Thialkalivibrio thiocyanodenitrificans sp. nov. is proposed to accommodate these bacteria.
Description of Thialkalivibrio thiocyanodenitrificans sp. nov.
Thialkalivibrio thiocyanodenitrificans (thi.o.cya'n.o.de.ni.tri'fi.cans N.L. n. thiocyanatum thiocyanate; N.L. v. denitrifico denitrify; N.L. part.adj. denitrificans denitrifying; N.L. part.adj. thiocyanodenitrificans denitrifying on thiocyanate).
Cells are rod-shaped (0·50·7x1·55 µm), and motile by single polar flagella. Obligate alkaliphiles. Optimum pH for growth 9·610. Grow within a salinity range of 0·31·8 M total Na+. Obligate chemolithoautotrophs. Differ from other Thialkalivibrio species by the ability to grow anaerobically with thiocyanate as sole energy source and nitrate or nitrite as electron acceptor. Produce cyanate as intermediate of thiocyanate oxidation. Also oxidize sulfide, thiosulfate, polysulfide, elemental sulfur and tetrathionate to sulfate. Thiocyanate and ammonia, but not nitrate, can serve as nitrogen source during growth with thiosulfate. DNA G+C content 63·163·7 mol% (Tm). Closest relative among the Thialkalivibrio species is Tv. denitrificans. Other properties as for the genus.
Isolated from the sediments of Egyptian and Siberian soda lakes. The type strain is ARhD 1T (=UNIQEM 226T).
![]() |
ACKNOWLEDGEMENTS |
---|
![]() |
REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Cypionka, H. & Pfennig, N. (1986). Growth yield of Desulfotomaculum orientis with hydrogen in chemostat culture. Arch Microbiol 143, 396399.
De Kruyff, C. D., van der Walt, J. I. & Schwartz, H. M. (1957). The utilization of thiocyanate and nitrate by thiobacilli. Antonie van Leeuwenhoek 23, 305316.[Medline]
Dictor, M.-C., Battaglia-Brunet, F., Morin, D., Bories, A. & Clarens, M. (1997). Biological treatment of gold ore cyanidation wastewater in fixed bed reactors. Environ Pollut 97, 287294.[CrossRef][Medline]
Gries-Romijn-van Eck (1966). Physiological and chemical test for drinking water. NEN 1056, IY-2 Nederlandse Normalisatie Instituut Rijswijk.
Happold, F. C., Johnstone, K. I., Roger, H. S. & Youatt, J. B. (1954). The isolation and characteristics of an organism oxidizing thiocyanate. J Gen Microbiol 10, 261266.
Happold, F. C., Jones, G. L. & Pratt, D. B. (1958). Utilization of thiocyanate by Thiobacillus thioparus and T. thiocyanooxidans. Nature 182, 266267.
Katayama, Y. & Kuraishi, H. (1978). Characteristics of Thiobacillus thioparus and its thiocyanate assimilation. Can J Microbiol 24, 804810.[Medline]
Katayama, Y., Narahara, Y., Inoue, Y., Amano, F., Kanagawa, T. & Kuraishi, H. (1992). A thiocyanate hydrolase of Thiobacillus thioparus. A novel enzyme catalyzing the formation of carbonyl sulphide from thiocyanate. J Biol Chem 267, 91709175.
Katayama, Y., Kanagawa, T. & Kuraishi, H. (1993). Emission of carbonyl sulphide by Thiobacillus thioparus grown with thiocyanate in pure and mixed cultures. FEMS Microbiol Lett 114, 223228.[CrossRef]
Katayama, Y., Matsushita, Y., Kaneko, M., Kondo, M., Mizuno, T. & Nyunoya, H. (1998). Cloning of genes coding for the subunits of thiocyanate hydrolase of Thiobacillus thioparus THI 115 and their evolutionary relationships to nitrile hydratase. J Bacteriol 180, 25832589.
Kelly, D. P. (1982). Biochemistry of the chemolithoautotrophic oxidation of inorganic sulphur. Philos Trans R Soc Lond B 298, 499528.[Medline]
Kelly, D. P. & Baker, S. C. (1990). The organosulphur cycle: aerobic and anaerobic processes leading to turnover of C1-sulphur compounds. FEMS Microbiol Rev 87, 241246.[CrossRef]
Kelly, D. P., Chambers, T. A. & Trudinger, P. A. (1969). Cyanolysis and spectrophotometric estimation of trithionate in mixture with thiosulphate and tetrathionate. Anal Chem 41, 898902.
Laemmli, U. K. (1970). Cleavage of structural proteins during the assembly of the head of the bacteriophage T4. Nature 227, 680685.[Medline]
Murillo, F. M., Gugliuzza, T., Senko, J., Basu, P. & Stolz, J. (1999). A heme-C-containing enzyme complex that exhibits nitrate and nitrite reductase activity from the dissimilatory iron-reducing bacterium Geobacter metallireducens. Arch Microbiol 172, 313320.[CrossRef][Medline]
Pfennig, N. & Lippert, K. D. (1966). Über das Vitamin B12-bedürfnis phototropher Schwefel Bacterien. Arch Microbiol 55, 245256.
Smith, N. A. & Kelly, D. P. (1988). Oxidation of carbon disulphide as the sole source of energy for the autotrophic growth of Thiobacillus thioparus strain TK-m. J Gen Microbiol 134, 30413048.
Sörbo, B. (1957). A colorimetric determination of thiosulphate. Biochim Biophys Acta 23, 412416.[CrossRef]
Sorokin, D. Y., Muyzer, G., Brinkhoff, T., Kuenen, J. G. & Jetten, M. (1998). Isolation and characterization of a novel facultatively alkaliphilic Nitrobacter species Nitrobacter alkalicus. Arch Microbiol 170, 345352.[CrossRef][Medline]
Sorokin, D. Yu, Tourova, T. P., Lysenko, A. M. & Kuenen, J. G. (2001a). Microbial thiocyanate utilization under highly alkaline conditions. Appl Environ Microbiol 67, 528538.
Sorokin, D. Y., Lysenko, A. M., Mityushina, L. L., Tourova, T. P., Jones, B. E., Rainey, F. A., Robertson, L. A. & Kuenen, J. G. (2001b). Thioalkalimicrobium sibiricum, Thioalkalimicrobium aerophilum gen. nov., sp. nov., and Thioalkalivibrio versutus, Thioalkalivibrio nitratis, Thioalkalivibrio denitrificans gen. nov., sp. nov., new obligately alkaliphilic and obligately chemolithoautotrophic sulfur-oxidizing bacteria from soda lakes. Int J Syst Evol Microbiol 51, 565580.[Abstract]
Sorokin, D. Y., Tourova, T. P., Schmid, M., Wagner, M., Koops, H.-P., Kuenen, J. G. & Jetten, M. (2001c). Isolation and properties of obligately chemolithoautotrophic and extremely alkali-tolerant ammonia-oxidizing bacteria from Mongolian soda lakes. Arch Microbiol 176, 170177.[CrossRef][Medline]
Sorokin, D. Yu, Kuenen, J. G. & Jetten, M. (2001d). Denitrification at extremely alkaline conditions in obligately autotrophic alkaliphilic sulphur-oxidizing bacterium Thialkalivibrio denitrificans. Arch Microbiol 175, 94101.[CrossRef][Medline]
Sorokin, D. Y., Tourova, T. P., Lysenko, A. M., Mityushina, L. L. & Kuenen, J. G. (2002). Thialkalivibrio thiocyanoxidans sp. nov. and Thialkalivibrio paradoxus sp. nov., novel alkaliphilic, obligately autotrophic, sulphur-oxidizing bacteria from soda lakes capable of growth on thiocyanate. Int J Syst Evol Microbiol 52, 657664.
Sorokin, D. Y., Antipov, A. N. & Kuenen, J. G. (2003). Complete denitrification in coculture of obligately chemolithoautotrophic haloalkaliphilic sulfur-oxidizing bacteria from a hypersaline soda lake. Arch Microbiol 180, 127133.[CrossRef][Medline]
Visser, J. M., Robertson, L. A., Van Verseveld, H. W. & Kuenen, J. G. (1997). Sulfur production by obligately chemolithoautotrophic Thiobacillus species. Appl Environ Microbiol 63, 23002305.[Abstract]
Weatherburn, M. V. (1967). Phenol-hypochlorite reaction for determination of ammonia. Anal Chem 39, 971974.
Wood, J. L. (1975). Biochemistry. In Thiocyanic Acid and its Derivatives, pp. 156252. Edited by A. A. Newman. London, New York, San Francisco: Academic Press.
Youatt, J. B. (1954). Studies on the metabolism of Thiobacillus thiocyanooxidans. J Gen Microbiol 11, 139149.
Received 5 January 2004;
revised 3 March 2004;
accepted 6 March 2004.