• Breathing poison: Microbial life on nitr

    From ScienceDaily@1:317/3 to All on Monday, July 10, 2023 22:30:20
    Breathing poison: Microbial life on nitric oxide respiration
    In a long-term culture, scientists find and characterize two new microorganisms growing on the toxic gas nitric oxide, reducing it completely to N2

    Date:
    July 10, 2023
    Source:
    Max Planck Institute for Marine Microbiology
    Summary:
    Nitric oxide (NO) is a central molecule in the global cycling
    of nitrogen, and also toxic. Little is known about if and how
    microbes can use NO as a substrate for growth. Scientists have
    now managed to grow a microbial community dominated by two, so-far
    unknown species on NO for more than four years (and counting) and
    study their metabolism in great detail. Their research provides
    insight into the physiology of NO- respiring microorganisms,
    which have pivotal roles in the control of climate active gases,
    waste removal, and the evolution of nitrate and oxygen respiration.


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    ==========================================================================
    FULL STORY ========================================================================== Nitric oxide (NO) is a fascinating and versatile molecule, important
    for all living things as well as the environment. It is highly reactive
    and toxic, organisms use it as a signaling molecule, it depletes the
    ozone layer in our planet's atmosphere, and it is the precursor of the greenhouse gas nitrous oxide (N2O). Moreover, NO might have played
    a fundamental role in the emergence and evolution of life on Earth,
    as it was available as a high-energy oxidant long before there was oxygen.

    Thus, despite its toxicity, it makes perfect sense that microbes use
    NO to grow. However, research on the topic is scarce and, to date,
    microbes growing on it have not been cultivated. That has now changed,
    as reported by scientists around Paloma Garrido Amador and Boran Kartal
    from the Max Planck Institute for Marine Microbiology in Bremen, Germany,
    in the journal Nature Microbiology.

    They have managed to enrich two yet unknown species of microorganisms
    growing on NO in bioreactors and reveal exciting aspects of their
    lifestyle.

    From the wastewater tank to the bioreactor The study started off with
    a trip to Bremen's wastewater treatment plant. "We collected sludge
    from their denitrifying tank," Garrido Amador tells. "Back in our
    lab, we added the sludge to one of our bioreactors and we started the incubation by feeding it with NO." Bioreactors are designed and optimized
    to grow microorganisms under controlled conditions, which closely mimic
    their natural environment. This bioreactor setup was very challenging,
    though, Garrido Amador reports, "Because NO is toxic, we needed special equipment and had to take great care when handling them for our own
    safety. Nevertheless, we managed to keep the cultures growing for
    more than four years now -- and they are still happy and healthy!"
    Two new microorganisms The living conditions in the bioreactor thus
    favored microorganisms that could survive and grow anaerobically
    with NO. "Eventually, two previously unknown species turned out to
    dominate the culture," says Boran Kartal, group leader of the Microbial Physiology Research Group the Max Planck Institute in Bremen. "We named
    them Nitricoxidivorans perserverans and Nitricoxidireducens bremensis."
    Garrido Amador adds, "From just two microorganisms growing on NO,
    we gained valuable insight into how non-model microorganisms, in
    particular NO-reducers grow. Some of our observations showed us that
    these microbes did not conform to how model organisms -- organisms
    which easily cultivated and thus extensively studied -- behave,
    and showcased the limitations of metabolic predictions based solely
    on genome analyses." Importance in the environment and applications
    for waste removal "Currently we know little about the contribution of microorganisms growing on NO to nitrogen cycling in natural and engineered environments," explains Kartal. "Nevertheless, we can speculate that these microorganisms could potentially be feeding on NO and N2O released by
    other microorganisms while removing nitrosative stress and minimizing the emission of these climate active gases to the atmosphere." The enriched microorganisms converted NO to dinitrogen (N2) very efficiently.

    "There were virtually no emissions of the greenhouse gas nitrous oxide,"
    Kartal adds. The latter -- the sole production of N2 -- is particularly relevant for application: Many other microorganisms convert NO to
    nitrous oxide, which is a potent greenhouse gas. N2, in contrast, is
    harmless. Thus, each molecule of NO that is transformed into N2 instead
    of nitrous oxide is one less molecule adding to climate change.

    In a next step, the Max Planck researchers are cultivating other
    NO-respiring microorganisms using samples from natural and engineered environments.

    "Cultivation and enrichment of further NO-respiring microorganisms will
    help to elucidate the evolution of N-oxide reduction pathways and the
    enzymes involved.

    It will also allow to decipher the role of NO in known and yet-unknown processes of the nitrogen cycle and its importance in the natural and engineered environments where these processes take place.," Garrido
    Amador concludes.

    * RELATED_TOPICS
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    o Earth_&_Climate
    # Hazardous_Waste # Oil_Spills # Environmental_Science #
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    * RELATED_TERMS
    o Climate_engineering o Microorganism o Ice_core o
    Greenhouse_gas o Temperature_record_of_the_past_1000_years o
    Vegetation o Biology o Carbon_dioxide

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    ========================================================================== Journal Reference:
    1. Paloma Garrido-Amador, Niek Stortenbeker, Hans J. C. T. Wessels,
    Daan R.

    Speth, Inmaculada Garcia-Heredia, Boran Kartal. Enrichment and
    characterization of a nitric oxide-reducing microbial community
    in a continuous bioreactor. Nature Microbiology, 2023; DOI:
    10.1038/s41564- 023-01425-8 ==========================================================================

    Link to news story: https://www.sciencedaily.com/releases/2023/07/230710113927.htm

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