Friday, August 25, 2017

New Microbe Has Potential to Help Rebalance Earth's Nitrogen Cycle

Date: August 23, 2017
Source: University of Alberta
Summary: Microbiologists have now provided unparalleled insight into the Earth's nitrogen cycle, identifying and characterizing the ammonia-oxidizing microbe, Nitrospira inopinata.

New research from University of Alberta and University of Vienna microbiologists provides unparalleled insight into the Earth's nitrogen cycle, identifying and characterizing the ammonia-oxidizing microbe, Nitrospira inopinata. The findings, explained Lisa Stein, co-author and professor of biology, have significant implications for climate change research.

"I consider nitrogen the camouflaged beast in our midst," said Stein.

"Humans are now responsible for adding more fixed nitrogen, in the form of ammonium, to the environment than all natural sources combined. Because of that, the nitrogen cycle has been identified as the most unbalanced biogeochemical cycle on the planet."

The Camouflaged Beast

Earth's nitrogen cycle has been thrown significantly off balance by the process we use to make fertilizer, known as the Haber-Bosch process, which adds massive quantities of fixed nitrogen, or ammonium, to the environment. Downstream effects of excess ammonium has huge environmental implications, from dead zones in our oceans to a greenhouse gas effect 300 times that of carbon dioxide on a molecule to molecule basis.

Isolation and characterization of the Nitrospira inopinata microbe, Stein said, could hold the answers for Earth's nitrogen problem.

Practical Applications

"The Nitrospira inopinata microbe is an ammonium sponge, outcompeting nearly all other bacteria and archaea in its oxidation of ammonium in the environment," explained Stein. "Now that we know how efficient this microbe is, we can explore many practical applications to reduce the amount of ammonium that contributes to environmental problems in our atmosphere, water, and soil."

The applications range from wastewater treatment, with the development of more efficient biofilms, to drinking water and soil purification to climate change research.

"An efficient complete ammonia oxidizer, such as Nitrospira inopinata, may produce less nitrous oxide," explained Kits. "By encouraging our microbe to outgrow other, incomplete oxidizers, we may, in turn, reduce their contribution to the greenhouse gas effect. Further investigation is required."

Story Source:
University of Alberta. "New microbe has potential to help rebalance Earth's nitrogen cycle." ScienceDaily. ScienceDaily, 23 August 2017. www.sciencedaily.com/releases/2017/08/170823142427.htm

Wednesday, August 9, 2017

Antibiotics Come With 'Environmental Side Effects'

Report published in Microchemical Journal wins Elsevier's Atlas award

Date: July 25, 2017
Source: Elsevier
Summary: Researchers are bringing attention to the fact that commonly used antibiotic drugs are making their way out into the environment, where they can harm microbes that are essential to a healthy environment.

Researchers writing in Microchemical Journal are bringing attention to the fact that commonly used antibiotic drugs are making their way out into the environment, where they can harm microbes that are essential to a healthy environment. Their review article has been selected for the Elsevier Atlas Award, which recognizes research that could significantly impact people's lives around the world or has already done so.

"The amount of antibiotics is very, very low -- there are normally nanograms per liter of these molecules found in natural environments," said Dr. Paola Grenni, a microbial ecologist at the National Research Council's Water Research Institute in Italy. "But the antibiotics and also other pharmaceuticals can have an effect even in low concentrations, the so-called environmental side-effects."

When people take antibiotics, their bodies break down and metabolize only a portion of the drugs. The rest is excreted and enters wastewater. Because wastewater treatment plants aren't designed to fully remove antibiotic or other pharmaceutical compounds, many of those compounds reach natural systems where they can accumulate and harm microbes in nature.

That's a big concern, Dr. Grenni said, because many microbial species found in the environment are beneficial, playing important roles in natural cycles of nutrients, primary production and climate regulation. Some microbes also degrade organic contaminants, such as pesticides.

The review paper published by Dr. Grenni along with colleagues Drs. Valeria Ancona and Anna Barra Caracciolo highlights commonly used antibiotic compounds and their active ingredients. Some of those medications are used to treat people. Many others are used in veterinary medicine, especially to treat farm animals including cattle, pigs and poultry.

The release of antibiotics into natural systems is a "real-life experiment" with consequences that aren't yet fully known. Dr. Grenni and her colleagues say there's a need for more specific protections of environmental microbes given their importance to functioning ecosystems.

It's important for nations to work to reduce unnecessary antibiotic use and the release of those antibiotics that are needed into the environment. To that end, efforts should be made to equip wastewater treatment plants for removal of those compounds and to devise methods to improve the degradation of antibiotics once they reach natural environments. Members of the public can help by taking care to use antibiotics only when they are truly needed, and by disposing of expired medications properly.

"There are only a few researchers working in this field, but it's very important," Dr. Grenni said. "We need to know the different molecules we normally use that are in the environment and the effect they have. We need more research in this field."

Story Source: Elsevier. "Antibiotics come with 'environmental side effects': Report published in Microchemical Journal wins Elsevier's Atlas award." ScienceDaily. ScienceDaily, 25 July 2017. https://www.sciencedaily.com/releases/2017/07/170725122046.htm.