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Denitrification, its importance once diluted, may be back on top, Princeton-led team says
September 03, 2009After more than a decade of inquiry, a Princeton-led team of scientists has turned the tables on a long-standing controversy to re-establish an old truth about nitrogen mixing in the oceans.
For decades, scientists thought they had a handle on the workings of an intricate natural mechanism known as the nitrogen cycle, essential to maintaining life on Earth. This process, one of nature's most elegant sleights-of-hand, shuttles nitrogen from the soils to the oceans to the atmosphere and back.
A key part of that cycle, researchers once thought, was a process known as denitrification. In low-oxygen -- or anaerobic -- conditions seen in large stretches of ocean sediments and in a few important regions of the open ocean, bacteria act as "denitrifyers," performing the crucial task of gobbling up nitrates and converting them to nitrogen gases, which complete the cycle by flowing back to the atmosphere.
In 1995, a group of Dutch scientists who had been studying the cycling of nitrogen through wastewater treatment plants came up with a startling conclusion. A new process, which they called anaerobic oxidation or "anammox" and that involved different bacteria, was the real player in removing nitrogen in low-oxygen environments, they said. They found the process worked to break down materials in sewage, and they confirmed that the mechanism also was operating in low-oxygen marine environments. They went so far as to suggest that the nitrogen cycle for oceans needed to be revised, as denitrification, according to their inquiry, did not play the major role that had been thought.
The notion was controversial and did not sit well with some scientists.
Now, a research team, led by Bess Ward, the William J. Sinclair Professor of Geosciences at Princeton University, writing in the Sept. 3 issue of Nature, is presenting data that could re-establish denitrification as the main actor in returning nitrogen to the air. After traveling through some of the key low-oxygen sites of the world's oceans, the team has found the telltale chemical signatures proving that denitrification and not anammox is the pivotal process at work most of the time.
"In our paper, we report that in the world's largest anoxic marine ecosystem -- the low-oxygen waters of the Arabian Sea -- denitrification rather than anammox is the dominant process," said Ward, who is also chair of the Department of Geosciences at Princeton. "If denitrification is important in the Arabian Sea, then it is important on a global scale, and the nitrogen cycle must be evaluated in that light."
The work, according to a leading expert in the marine nitrogen cycle, confirms his own observations of seawater processes showing that denitrification is key and indicates that the current mainstream view in science may be based on a false impression. "My suspicions that future work would, once again, demonstrate the importance of conventional denitrification have now been confirmed," said Louis A. Codispoti, an oceanographer and research professor at Horn Point Laboratory, part of the University of Maryland in Cambridge, who was not involved with the research.
The researchers who discovered the anammox process nearly 15 years ago, led by Gifjs Kuenen, then at the Delft University of Technology in the Netherlands, moved beyond the original discovery in wastewater treatment plants and found the reaction was also at work in removing nitrogen in a few regions of the ocean known as "oxygen minimum zones." Zeroing in on a low-oxygen zone off the coast of Peru, the work of Dutch, Danish and German scientists found that anammox reactions, rather than denitrification, were operating there.
"That was astounding," Ward remembered.
Thinking there may be a problem with the methodology or that scientists didn't understand the nitrogen cycle as much as they thought they did, she began to devise experiments to seek answers.
Working with other members of her team over the next decade, they learned the methods of the European experts and started to plan to replicate the studies. In 2005, they confirmed that bacteria supporting the anammox reaction dominated the removal of nitrogen in a low-oxygen region off the Peru coast. But when they took samples of water in the Arabian Sea, they found just the opposite -- denitrification was a major force there. The European researchers had found anammox in the Peru system but had never reported on the Arabian Sea.
The notion that microbial processes can vary in low-oxygen zones around the world is startling and important to know, the researchers said.
"We care because nitrogen is a key limiting nutrient to primary productivity," said Jeremy Rich, a former postdoctoral fellow in Ward's lab and now an assistant professor of environmental studies at Brown University, who contributed to the study. "We already knew these zones removed nitrogen, but now that we know the actual processes taking place, we'll be in a much better position to predict how these zones change. And how these zones change will in turn influence primary productivity."
The findings have forced the scientists to re-evaluate what they already knew.
"This made us think -- this means the Arabian Sea is somehow different from the Peru system," Ward said. "Previously, we thought they were the same. Clearly, something was different and that, in and of itself, is an important insight. And, clearly, denitrification is important -- you cannot rewrite the nitrogen cycle."
Because the Arabian Sea is the world's largest anoxic marine ecosystem, that body's most dominant process is almost certainly the primary way for nitrogen to be removed from the world's oceans.
To confirm the conclusions, the team designed a new way of sampling and identifying chemicals and repeated the experiments. The results were the same.
The nitrogen cycle is one of the most important nutrient cycles in nature, providing a transformative process in which nitrogen is taken from the atmosphere and converted into a form that can be consumed by plants. Nitrogen makes up about 80 percent of the earth's atmosphere. It is used by living organisms to produce a number of complex organic molecules, including DNA.
Processing or fixation is necessary to convert gaseous nitrogen into forms usable by living organisms. Most is done by bacteria that possess a nitrogenase enzyme that combines gaseous nitrogen with hydrogen to produce ammonia, which is then converted by the bacteria to make their own organic compounds.
In low-oxygen conditions, denitrification by bacteria occurs when nitrates are converted to nitrogen gases like nitrous oxide and returned to the atmosphere. In the anammox process, nitrates are reduced to nitrites and then combine with ammonium before returning to the atmosphere.
In addition to Ward and Rich, other authors on the paper include: Silvia Bulow, a graduate student, and Amal Jayakumar, a senior professional specialist, in Princeton's Department of Geosciences; Allan Devol, research professor of oceanography, and Bonnie Chang, a graduate student, at the University of Washington; and Hema Naik, a scientist, and Anil Pratihary, a graduate student, at the National Institute of Oceanography in India.
The research was funded by the National Science Foundation.
Princeton University
In 1995, a group of Dutch scientists who had been studying the cycling of nitrogen through wastewater treatment plants came up with a startling conclusion. A new process, which they called anaerobic oxidation or "anammox" and that involved different bacteria, was the real player in removing nitrogen in low-oxygen environments, they said. They found the process worked to break down materials in sewage, and they confirmed that the mechanism also was operating in low-oxygen marine environments. They went so far as to suggest that the nitrogen cycle for oceans needed to be revised, as denitrification, according to their inquiry, did not play the major role that had been thought.
The notion was controversial and did not sit well with some scientists.
Now, a research team, led by Bess Ward, the William J. Sinclair Professor of Geosciences at Princeton University, writing in the Sept. 3 issue of Nature, is presenting data that could re-establish denitrification as the main actor in returning nitrogen to the air. After traveling through some of the key low-oxygen sites of the world's oceans, the team has found the telltale chemical signatures proving that denitrification and not anammox is the pivotal process at work most of the time.
"In our paper, we report that in the world's largest anoxic marine ecosystem -- the low-oxygen waters of the Arabian Sea -- denitrification rather than anammox is the dominant process," said Ward, who is also chair of the Department of Geosciences at Princeton. "If denitrification is important in the Arabian Sea, then it is important on a global scale, and the nitrogen cycle must be evaluated in that light."
The work, according to a leading expert in the marine nitrogen cycle, confirms his own observations of seawater processes showing that denitrification is key and indicates that the current mainstream view in science may be based on a false impression. "My suspicions that future work would, once again, demonstrate the importance of conventional denitrification have now been confirmed," said Louis A. Codispoti, an oceanographer and research professor at Horn Point Laboratory, part of the University of Maryland in Cambridge, who was not involved with the research.
The researchers who discovered the anammox process nearly 15 years ago, led by Gifjs Kuenen, then at the Delft University of Technology in the Netherlands, moved beyond the original discovery in wastewater treatment plants and found the reaction was also at work in removing nitrogen in a few regions of the ocean known as "oxygen minimum zones." Zeroing in on a low-oxygen zone off the coast of Peru, the work of Dutch, Danish and German scientists found that anammox reactions, rather than denitrification, were operating there.
"That was astounding," Ward remembered.
Thinking there may be a problem with the methodology or that scientists didn't understand the nitrogen cycle as much as they thought they did, she began to devise experiments to seek answers.
Working with other members of her team over the next decade, they learned the methods of the European experts and started to plan to replicate the studies. In 2005, they confirmed that bacteria supporting the anammox reaction dominated the removal of nitrogen in a low-oxygen region off the Peru coast. But when they took samples of water in the Arabian Sea, they found just the opposite -- denitrification was a major force there. The European researchers had found anammox in the Peru system but had never reported on the Arabian Sea.
The notion that microbial processes can vary in low-oxygen zones around the world is startling and important to know, the researchers said.
"We care because nitrogen is a key limiting nutrient to primary productivity," said Jeremy Rich, a former postdoctoral fellow in Ward's lab and now an assistant professor of environmental studies at Brown University, who contributed to the study. "We already knew these zones removed nitrogen, but now that we know the actual processes taking place, we'll be in a much better position to predict how these zones change. And how these zones change will in turn influence primary productivity."
The findings have forced the scientists to re-evaluate what they already knew.
"This made us think -- this means the Arabian Sea is somehow different from the Peru system," Ward said. "Previously, we thought they were the same. Clearly, something was different and that, in and of itself, is an important insight. And, clearly, denitrification is important -- you cannot rewrite the nitrogen cycle."
Because the Arabian Sea is the world's largest anoxic marine ecosystem, that body's most dominant process is almost certainly the primary way for nitrogen to be removed from the world's oceans.
To confirm the conclusions, the team designed a new way of sampling and identifying chemicals and repeated the experiments. The results were the same.
The nitrogen cycle is one of the most important nutrient cycles in nature, providing a transformative process in which nitrogen is taken from the atmosphere and converted into a form that can be consumed by plants. Nitrogen makes up about 80 percent of the earth's atmosphere. It is used by living organisms to produce a number of complex organic molecules, including DNA.
Processing or fixation is necessary to convert gaseous nitrogen into forms usable by living organisms. Most is done by bacteria that possess a nitrogenase enzyme that combines gaseous nitrogen with hydrogen to produce ammonia, which is then converted by the bacteria to make their own organic compounds.
In low-oxygen conditions, denitrification by bacteria occurs when nitrates are converted to nitrogen gases like nitrous oxide and returned to the atmosphere. In the anammox process, nitrates are reduced to nitrites and then combine with ammonium before returning to the atmosphere.
In addition to Ward and Rich, other authors on the paper include: Silvia Bulow, a graduate student, and Amal Jayakumar, a senior professional specialist, in Princeton's Department of Geosciences; Allan Devol, research professor of oceanography, and Bonnie Chang, a graduate student, at the University of Washington; and Hema Naik, a scientist, and Anil Pratihary, a graduate student, at the National Institute of Oceanography in India.
The research was funded by the National Science Foundation.
Princeton University
Denitrification Current Events and Denitrification News RSSIron controls patterns of nitrogen fixation in the Atlantic
Scientists including researchers from the National Oceanography Centre, Southampton and the University of Essex have discovered that interactions between iron supply, transported through the atmosphere from deserts, and large-scale oceanic circulation control the availability of a crucial nutrient, nitrogen, in the Atlantic.
University of Copenhagen
Unchecked global warming would leave ocean dwellers gasping for breath. Dead zones are low-oxygen areas in the ocean where higher life forms such as fish, crabs and clams are not able to live. In shallow coastal regions, these zones can be caused by runoff of excess fertilizers from farming.
Nutrients in water may be a bonus for agriculture
Agriculture producers may find they don't have to bottle their water from the Seymour Aquifer in the Rolling Plains to make it more valuable, according to Texas AgriLife Research scientists.
Nitrous Oxide Emissions Respond Differently to No-Till Depending on the Soil Type
The practice of no-till has increased considerably during the past 20 yr. The absence of tillage coupled with the accumulation of crop residues at the soil surface modifies several soil properties but also influence nitrogen dynamics.
Evolving designer ecosystem sheds light on unintended consequences
Amidst the semi-arid stretches of Phoenix, a visitor might blink twice at the sight of a sailboat cutting across the horizon. Tempe Town Lake, on the northern edge of Arizona State University (ASU), is just one of a multitude of lakes, small ponds, canals and dams combining flood control, water delivery, recreational opportunities and aesthetics, and altering perception of water availability and economics in the area.
Pesticides Persist in Ground Water
Numerous studies over the past four decades have established that pesticides, which are typically applied at the land surface, can move downward through the unsaturated zone to reach the water table at detectable concentrations.
UMCES-led research team quantifies nutrient pollution reductions from urban stream restoration
A team of researchers led by University of Maryland Center for Environmental Science researcher Dr. Sujay Kaushal has been among the first able to quantify the amount of excess nitrogen removed from an urban stream during environmental restoration projects.
No laughing matter -- bacteria are releasing a serious greenhouse gas
Unlike carbon dioxide and methane, laughing gas has been largely ignored by world leaders as a worrying greenhouse gas. But nitrous oxide must be taken more seriously.
Small streams mitigate human influence on coastal ecosystems
Healthy streams play a major role in minimizing the amount of human-generated pollutants, such as nitrogen, that are delivered downstream.
Scientists show that streams are critical to preservation of oceanic coastal zones
The plight of the world's oceans is dire, according to recent studies, through insults from human-derived activities depopulating and damaging reefs, altering coastlines, and creating pollutants, such as nitrogen runoff from terrestrial watersheds.
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Denitrification by J. W. Payne (Author) Covers bacteriology and physiology of the dentrification process, and examines the four anaerobic reductive steps that comprise bacterial dentrification. Describes deleterious effects of denitrifying activity in crop soils and discusses strategies to minimize nitrogen losses. Examines interrelationships among plants, animals, and denitrifying bacteria in aquatic as well as soil systems. Reviews use of dentrification in water purification and suggests approaches to control of denitrification. | |
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Garlic Boost Plus - 6 oz. by MARC WEISS COMPANIES All natural garlic aquarium addition organically enhances the life of all the aquatics in your aqauarium. This natural anti-oxidant enhances your fishes' appetites and their immune systems. A special organic de-nitrification agent gives your biological a hand neutralizing dangerous compounds. Promotes health and vitality in your entire aquarium. |
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Nitrification and Denitrification in the Activated Sludge Process by Michael H. Gerardi (Author) Nitrification and Denitrification in the Activated Sludge Process, the first in a series on the microbiology of wastewater treatment, comprises the critical topics of cost-effective operation, permit compliance, process control, and troubleshooting in wastewater treatment plants. Avoiding the technical jargon, chemical equations, and kinetics that typically accompany such texts, Nitrification and Denitrification in the Activated Sludge Process directly addresses plant operators and technicians, providing necessary information for understanding the microbiology and biological conditions that occur in the treatment process. Of special interest to wastewater treatment plant operators are the bacteria that degrade nitrogenous wastes–the nitrifying bacteria–and the bacteria that... |
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Nitrification-denitrification via nitrite accumulation for nitrogen removal from wastewaters [An article from: Bioresource Technology] by G. Ruiz (Author), D. Jeison (Author), O. Rubilar (Author), G. Ciudad (Author), Chamy (Author) This digital document is a journal article from Bioresource Technology, published by Elsevier in . The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: The biological nitrification-denitrification process is used extensively for removal of ammonia nitrogen from wastewaters. Saves in aeration, organic matter (for denitrification) and surplus sludge are achievable if nitrite accumulation is possible in the nitrification step. In this paper, operational parameters were studied for each process for maximum nitrite accumulation in the nitrification step and nitrite adaptation in the denitrification step. Nitrite accumulation during nitrification can be controlled by... |
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Nitrification and Denitrification Facilities Wastewater Treatment by U.S. Environmental Protection Agency (Author) | |
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Denitrification in created riverine wetlands: Influence of hydrology and season [An article from: Ecological Engineering] by M.E. Hernandez (Author), W.J. Mitsch (Author) This digital document is a journal article from Ecological Engineering, published by Elsevier in 2007. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: Created riverine wetlands play an important role in nitrate removal from non-point source pollution. In this study, we investigated the effect of flooding frequency on seasonal denitrification rates in two created riverine wetlands in the Midwest USA receiving controlled hydrologic pulses. Denitrification was measured using the in situ acetylene block technique; sampling plots were distributed in a longitudinal gradient, i.e., along the water flow and in a transverse gradient from the edge to the center of the... |
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N"2O emissions and product ratios of nitrification and denitrification as affected by freezing and thawing [An article from: Soil Biology and Biochemistry] by P.T. Morkved (Author), P. Dorsch (Author), T.M. Henriksen (Author), L Bakken (Author) This digital document is a journal article from Soil Biology and Biochemistry, published by Elsevier in 2006. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: Agricultural soils contribute significantly to atmospheric nitrous oxide (N"2O). A considerable part of the annual N"2O emission may occur during the cold season, possibly supported by high product ratios in denitrification (N"2O/(N"2+N"2O)) and nitrification (N"2O-N/(NO"3^--N+NO"2^--N)) at low temperatures and/or in response to freeze-thaw perturbation. Water-soluble organic materials released from frost-sensitive catch crops and green manure may further increase winter emissions. We conducted... |
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Potential denitrification in wetland sediments with different plant species detritus [An article from: Ecological Engineering] by S.K. Bastviken (Author), P.G. Eriksson (Author), A. Premrov (Author), Tonders (Author) This digital document is a journal article from Ecological Engineering, published by Elsevier in . The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: The effect of detritus originating from different plant species on denitrifying capacity was investigated in a Swedish wastewater treatment wetland. Intact sediment cores containing sediment with a detritus layer were collected from wetland basins dominated by Typha latifolia, Phragmites australis, or Elodea canadensis in November 2000 and potential denitrification was measured using the acetylene-inhibition method. The cores from stands of E. canadensis showed more than three times higher denitrification capacity... |
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Denitrification of the underground waters by specific resin exchange of ion [An article from: Desalination] by M. Boumediene (Author), D. Achour (Author) This digital document is a journal article from Desalination, published by Elsevier in 2004. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: The underground waters that we use for drinking are exposed to different types of pollution especially that of nitrates. The pollution by nitrates comes essentially from the excessive use of chemical and organic fertilizers used in agriculture. This pollution phenomenon particularly affects underground waters that are found in areas where there is intensive agriculture. The nitrate contents of these waters generally exceed the international norms (OMS) admitted for drinking water (50 mg/l). Nitrates present in great... |
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Denitrification: Webster's Timeline History, 1898 - 2007 by Icon Group International (Author) Webster's bibliographic and event-based timelines are comprehensive in scope, covering virtually all topics, geographic locations and people. They do so from a linguistic point of view, and in the case of this book, the focus is on "Denitrification," including when used in literature (e.g. all authors that might have Denitrification in their name). As such, this book represents the largest compilation of timeline events associated with Denitrification when it is used in proper noun form. Webster's timelines cover bibliographic citations, patented inventions, as well as non-conventional and alternative meanings which capture ambiguities in usage. These furthermore cover all parts of speech (possessive, institutional usage, geographic usage) and contexts, including pop culture, the arts,... |
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