Microbial Nitrogen Cycling Processes in Oxygen Minimum Zones

被引:479
作者
Lam, Phyllis [1 ]
Kuypers, Marcel M. M. [1 ]
机构
[1] Max Planck Inst Marine Microbiol, Nutrient Grp, D-28359 Bremen, Germany
来源
ANNUAL REVIEW OF MARINE SCIENCE, VOL 3 | 2011年 / 3卷
关键词
denitrification; anammox; nitrate reduction; DNRA; nitrification; autotrophic denitrification; organic matter; nitrogen loss; ANAEROBIC AMMONIUM OXIDATION; NITRITE REDUCTASE GENES; OXIDIZING BACTERIA; NITRATE REDUCTION; ARABIAN SEA; ANAMMOX BACTERIA; ORGANIC-MATTER; SP-NOV; NITROSOMONAS-EUROPAEA; DENITRIFICATION RATES;
D O I
10.1146/annurev-marine-120709-142814
中图分类号
P3 [地球物理学]; P59 [地球化学];
学科分类号
0708 ; 070902 ;
摘要
Oxygen minimum zones (OMZs) harbor unique microbial communities that rely on alternative electron acceptors for respiration. Conditions therein enable an almost complete nitrogen (N) cycle and substantial N-loss. N-loss in OMZs is attributable to anammox and heterotrophic denitrification, whereas nitrate reduction to nitrite along with dissimilatory nitrate reduction to ammonium are major remineralization pathways. Despite virtually anoxic conditions, nitrification also occurs in OMZs, converting remineralized ammonium to N-oxides. The concurrence of all these processes provides a direct channel from organic N to the ultimate N-loss, whereas most individual processes are likely controlled by organic matter. Many microorganisms inhabiting the OMZs are capable of multiple functions in the N- and other elemental cycles. Their versatile metabolic potentials versus actual activities present a challenge to ecophysiological and biogeochemical measurements. These challenges need to be tackled before we can realistically predict how N-cycling in OMZs, and thus oceanic N-balance, will respond to future global perturbations.
引用
收藏
页码:317 / 345
页数:29
相关论文
共 171 条
[1]  
AHLERS B, 1990, FEMS MICROBIOL LETT, V67, P121, DOI 10.1111/j.1574-6968.1990.tb13847.x
[2]   Cultivation of a novel cold-adapted nitrite oxidizing betaproteobacterium from the Siberian Arctic [J].
Alawi, Mashal ;
Lipski, Andre ;
Sanders, Tina ;
Eva-Maria-Pfeiffer ;
Spieck, Eva .
ISME JOURNAL, 2007, 1 (03) :256-264
[3]   Dissimilatory iodate reduction by marine Pseudomonas sp strain SCT [J].
Amachi, Seigo ;
Kawaguchi, Nahito ;
Muramatsu, Yasuyuki ;
Tsuchiya, Satoshi ;
Watanabe, Yuko ;
Shinoyama, Hirofumi ;
Fujii, Takaaki .
APPLIED AND ENVIRONMENTAL MICROBIOLOGY, 2007, 73 (18) :5725-5730
[4]   A MODEL FOR NITRITE AND NITRATE DISTRIBUTIONS IN OCEANIC OXYGEN MINIMUM ZONES [J].
ANDERSON, JJ ;
OKUBO, A ;
ROBBINS, AS ;
RICHARDS, FA .
DEEP-SEA RESEARCH PART A-OCEANOGRAPHIC RESEARCH PAPERS, 1982, 29 (09) :1113-1140
[5]   KINETIC EXPLANATION FOR ACCUMULATION OF NITRITE, NITRIC-OXIDE, AND NITROUS-OXIDE DURING BACTERIAL DENITRIFICATION [J].
BETLACH, MR ;
TIEDJE, JM .
APPLIED AND ENVIRONMENTAL MICROBIOLOGY, 1981, 42 (06) :1074-1084
[6]   EFFECT OF MEDIUM COMPOSITION ON THE DENITRIFICATION OF NITRATE BY PARACOCCUS-DENITRIFICANS [J].
BLASZCZYK, M .
APPLIED AND ENVIRONMENTAL MICROBIOLOGY, 1993, 59 (11) :3951-3953
[7]   GROWTH OF NITROBACTER IN THE ABSENCE OF DISSOLVED-OXYGEN [J].
BOCK, E ;
WILDERER, PA ;
FREITAG, A .
WATER RESEARCH, 1988, 22 (02) :245-250
[8]   NITROGEN LOSS CAUSED BY DENITRIFYING NITROSOMONAS CELLS USING AMMONIUM OR HYDROGEN AS ELECTRON-DONORS AND NITRITE AS ELECTRON-ACCEPTOR [J].
BOCK, E ;
SCHMIDT, I ;
STUVEN, R ;
ZART, D .
ARCHIVES OF MICROBIOLOGY, 1995, 163 (01) :16-20
[9]   GROWTH OF NITROBACTER IN PRESENCE OF ORGANIC-MATTER .2. CHEMO-ORGANOTROPHIC GROWTH OF NITROBACTER-AGILIS [J].
BOCK, E .
ARCHIVES OF MICROBIOLOGY, 1976, 108 (03) :305-312
[10]  
Bock E, 2006, PROKARYOTES: A HANDBOOK ON THE BIOLOGY OF BACTERIA, VOL 2, THIRD EDITION, P457, DOI 10.1007/0-387-30742-7_16
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