250:
44:
550:
Heidelberg, J.F.; Seshadri, R.; Haveman, S.A.; Hemme, C.L.; Paulsen, I.T.; Kolonay, J.F.; Eisen, J.A.; Ward, N.; Methe, B.; Brinkac, L.M.; Daugherty, S.C.; Deboy, R.T.; Dodson, R.J.; Durkin, A.S.; Madupu, R.; Nelson, W.C.; Sullivan, S.A.; Fouts, D.; Haft, D.H.; Selengut, J.; Peterson, J.D.; Davidsen,
671:
Mukhopadhyay, Aindrila; He, Zhili; Alm, Eric J.; Arkin, Adam P.; Baidoo, Edward E.; Borglin, Sharon C.; Chen, Wenqiong; Hazen, Terry C.; He, Qiang; Holman, Hoi-Ying; Huang, Katherine; Huang, Rick; Joyner, Dominique C.; Katz, Natalie; Keller, Martin (2006).
328:
This microbe also responds to increased salinity by using its efflux systems to pump excess salt ions out of the cell. This process, as well as GB import, requires more energy than the cells normally require.
278:. During the removal of metals from mine waste piles, there was a removal efficiency of 99% by sulfate-reducing bacteria. However, it has been found that, at high concentrations, heavy metals can be toxic to
551:
T.M.; Zafar, N.; Zhou, L.W.; Radune, D.; Dimitrov, G.; Hance, M.; Tran, K.; Khouri, H.; Gill, J.; Utterback, T.R.; Feldblyum, T.V.; Wall, J.D.; Voordouw, G.; Fraser, C.M. (2004).
333:
also responds by increasing transcript levels of all Hmc operon members, indicating that electron channeling increases during salt stress. One notable characteristic of
321:. These molecules may either be synthesized in the cell or imported in. However, GB is only imported into the cell, and proline is not the preferred molecule to use by
1014:
485:
Zhou, J.; He, Q.; Hemme, C.L.; Mukhopadhyay, A.; Hillesland, K.; Zhou, A.; He, Z.; Van
Nostrand, J.D.; Hazen, T.C.; Stahl, D.A.; Wall, J.D.; Arkin, A.P. (2011).
309:
genes may help move the cells away from the stressful environment. Another common response is the accumulation of neutral, polar, small molecules that serve as
123:
988:
729:
Pereira, Patrícia M.; He, Qiang; Valente, Filipa M. A.; Xavier, António V.; Zhou, Jizhong; Pereira, Inês A. C.; Louro, Ricardo O. (2008-05-01).
246:
by increasing their pH. SRBs also play a key role in biogeochemical cycles. Studies have shown that SRBs grow best with hydrogen and sulfate.
1027:
219:
sequenced. It is ubiquitous in nature and has also been implicated in a variety of human bacterial infections, although it may only be an
522:
291:
975:
1001:
17:
242:
is a sulfate-reducing bacterium (SRB) that plays an important role in cycling elements. The metabolism of SRBs contributes to
1006:
337:
is that it changes to have a more elongated structure when exposed to high salinity, possibly caused by inhibition of
1053:
940:
223:. This microbe also has the ability to endure high salinity environments, which is done through the utilization of
1032:
786:"Prevention of Acid Mine Drainage by Sulfate Reducing Bacteria: Organic Substrate Addition to Mine Waste Piles"
553:"The genome sequence of the anaerobic, sulfate-reducing bacterium Nitratidesulfovibrio vulgaris Hildenborough"
255:
347:
has been linked to several human bacterial infections but may just be an opportunistic pathogen. Overall,
199:
family. It is also an anaerobic sulfate-reducing bacterium that is an important organism involved in the
731:"Energy metabolism in Nitratidesulfovibrio vulgaris Hildenborough: insights from transcriptome analysis"
440:"Toxic effects of dissolved heavy metals on Nitratidesulfovibrio vulgaris and Desulfovibrio sp. strains"
249:
439:
1058:
192:
883:
384:
Devereux, R.; He, S.H.; Doyle, C.L.; Orkland, S.; Stahl, D.A.; LeGall, J.; Whitman, W.B. (1990).
220:
74:
1081:
993:
902:
189:
785:
674:"Salt Stress in Nitratidesulfovibrio vulgaris Hildenborough: an Integrated Genomics Approach"
228:
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8:
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844:
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603:"Desulfovibrio desulfuricans Bacteremia and Review of Human Desulfovibrio Infections"
574:
506:
487:"How sulphate-reducing microorganisms cope with stress: lessons from systems biology"
467:
459:
415:
618:
401:
386:"Diversity and origin of Desulfovibrio species: phylogenetic definition of a family"
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836:
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742:
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274:. It can also carry out this process while being exposed to high concentrations of
271:
86:
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455:
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275:
817:"Reduction of Chromate by Nitratidesulfovibrio vulgaris and Its c 3 Cytochrome"
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Cabrera, G.; Pérez, R.; Gómez, J. M.; Ábalos, A.; Cantero, D. (2006-07-31).
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genes and the downregulation of flagellar biosynthesis. The upregulation of
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for sulfur-reducing bacteria and was the first of such bacteria to have its
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471:
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can be used to remove metals from the environment due to its production of
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is exposed to increased salinity, it responds with the upregulation of
43:
954:
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Goldstein, E.J.C.; Citron, D.M.; Peraino, V.A.; Cross, S. A. (2003).
896:
919:
569:
552:
364:
62:
367:. These infections are an infrequent cause of diseases in humans.
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318:
185:
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216:
549:
784:
Kim, Sang D.; Kilbane, John J.; Cha, Daniel K. (1999–2003).
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815:
Lovley, Derek R.; Phillips, Elizabeth J. P. (1994–2002).
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383:
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783:
355:has a higher pathogenic potential than most other
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42:
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409:
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892:- the Bacterial Diversity Metadatabase
14:
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821:Applied and Environmental Microbiology
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666:
162:(Postgate & Campbell 1966) Waite
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290:metal to a less toxic, less soluble
24:
25:
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790:Environmental Engineering Science
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286:can also reduce the highly toxic
607:Journal of Clinical Microbiology
619:10.1128/JCM.41.6.2752-2754.2003
525:from the original on 2020-10-14
402:10.1128/jb.172.7.3609-3619.1990
808:
777:
722:
478:
444:Journal of Hazardous Materials
377:
359:species. Most infections with
234:
13:
1:
886:Nitratidesulfovibrio vulgaris
841:10.1128/aem.60.2.726-728.1994
456:10.1016/j.jhazmat.2005.11.058
370:
345:Nitratidesulfovibrio vulgaris
335:Nitratidesulfovibrio vulgaris
331:Nitratidesulfovibrio vulgaris
323:Nitratidesulfovibrio vulgaris
299:Nitratidesulfovibrio vulgaris
268:Nitratidesulfovibrio vulgaris
240:Nitratidesulfovibrio vulgaris
209:Nitratidesulfovibrio vulgaris
175:Nitratidesulfovibrio vulgaris
156:Nitratidesulfovibrio vulgaris
36:Nitratidesulfovibrio vulgaris
351:may be a weak pathogen, but
256:Oleidesulfovibrio alaskensis
7:
491:Nature Reviews Microbiology
263:) cells on stainless steel.
10:
1098:
909:
747:10.1007/s10482-007-9212-0
193:sulfate-reducing bacteria
152:
145:
52:Scientific classification
50:
41:
34:
261:Desulfovibrio alaskensis
802:10.1089/ees.1999.16.139
735:Antonie van Leeuwenhoek
678:Journal of Bacteriology
390:Journal of Bacteriology
75:Thermodesulfobacteriota
1020:desulfovibrio-vulgaris
941:Desulfovibrio vulgaris
911:Desulfovibrio vulgaris
264:
221:opportunistic pathogen
181:Desulfovibrio vulgaris
18:Desulfovibrio vulgaris
252:
557:Nature Biotechnology
207:in the environment.
124:Nitratidesulfovibrio
27:Species of bacterium
833:1994ApEnM..60..726L
690:10.1128/JB.01921-05
503:10.1038/nrmicro2575
363:are susceptible to
211:is often used as a
197:Desulfovibrionaceae
111:Desulfovibrionaceae
265:
99:Desulfovibrionales
1069:
1068:
1041:Open Tree of Life
903:Taxon identifiers
684:(11): 4068–4078.
353:D. fairfieldensis
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16:(Redirected from
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935:Wikispecies
284:N. vulgaris
280:N. vulgaris
235:Description
164:et al.
529:2019-07-05
371:References
313:, such as
307:chemotaxis
303:chemotaxis
259:(formerly
178:(formerly
849:0099-2240
755:1572-9699
698:0021-9193
464:0304-3894
317:(GB) and
231:systems.
132:Species:
1076:Category
994:11068148
920:Wikidata
867:16349200
763:18060515
716:16707698
637:12791922
579:15077118
523:Archived
511:21572460
472:16386832
365:imipenem
253:Related
106:Family:
70:Phylum:
63:Bacteria
58:Domain:
981:3220452
968:6376540
950:BacDive
926:Q593811
829:Bibcode
771:6536698
707:1482918
519:1195223
420:2361938
319:proline
292:Cr(III)
195:in the
186:species
184:) is a
118:Genus:
94:Order:
82:Class:
1059:743065
1046:968875
1007:961288
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288:Cr(VI)
229:efflux
217:genome
1054:WoRMS
989:IRMNG
767:S2CID
515:S2CID
297:When
1028:NCBI
1015:LPSN
1002:ITIS
976:GBIF
955:4105
890:Dive
863:PMID
845:ISSN
759:PMID
751:ISSN
712:PMID
694:ISSN
633:PMID
575:PMID
507:PMID
468:PMID
460:ISSN
416:PMID
227:and
166:2020
1033:881
963:EoL
853:PMC
837:doi
798:doi
743:doi
702:PMC
686:doi
682:188
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