Livestock antibiotics and rising temperatures disrupt soil microbial communities
Combined stressors could impair soils' ability to cycle nutrients and
trap carbon

Date:
November 8, 2021
Source:
Cary Institute of Ecosystem Studies
Summary:
Community ecologists investigated the interactive effects of
rising temperatures and a common livestock antibiotic on soil
microbes. The research team found that heat and antibiotics disrupt
soil microbial communities -- degrading soil microbe efficiency,
resilience to future stress, and ability to trap carbon.



FULL STORY ========================================================================== Soils are home to diverse microbial communities that cycle nutrients,
support agriculture, and trap carbon -- an important service for climate mitigation.

Globally, around 80% of Earth's terrestrial carbon stores are found
in soils.

Due to climate warming and other human activities that affect soil microorganisms, this important carbon sink is at risk.


==========================================================================
A new study led by Jane Lucas, a community ecologist at Cary Institute
of Ecosystem Studies, investigated the interactive effects of rising temperatures and a common livestock antibiotic on soil microbes. The
research team found that heat and antibiotics disrupt soil microbial communities -- degrading soil microbe efficiency, resilience to future
stress, and ability to trap carbon.

The work, now available online, will appear in the December issue of
Soil Biology and Biochemistry.

Lucas, says, "Most studies of soil health examine only one stressor at
a time.

Here, we wanted to explore the effects of warming temperatures and
antibiotics simultaneously, to get a sense of how two increasing stressors impact soils." Monensin was selected because it is a common antibiotic
whose use is expanding on cattle farms. Monensin is inexpensive, easy
to administer, does not require a veterinary feed directive, and is not
used in human medications. Like many antibiotics, Monensin is poorly metabolized; much of the antibiotic is still biologically active when
it enters the environment through animal waste.

The team collected samples of prairie soil from preserved land in
northern Idaho that was free of grazing livestock. Vegetation cover at
the collection site, primarily tallgrass prairie, represents typical
livestock pasture - - without inputs from cattle waste.

Soil samples were treated with either a high dose, low dose, or no dose
of the antibiotic; these were heated at three different temperatures and
left to incubate for 21 days. Temperatures tested (15, 20, and 30DEGC) represented seasonal variation plus a future warming projection. For
each treatment, the team monitored soil respiration, acidity, microbial community composition and function, carbon and nitrogen cycling, and interactions among microbes.

They found that with rising heat and antibiotic additions, bacteria
collapsed, allowing fungi to dominate and homogenize -- resulting in fewer total microbes and less microbial diversity overall. Antibiotics alone increased bioavailable carbon and reduced microbial efficiency. Rising temperatures alone increased soil respiration and dissolved organic
carbon. Increases in these labile carbon pools can lead to a reduction
in long-term carbon storage capacity.

Lucas says, "We saw real changes in soil microbe communities in both
the low and high-dose additions. Rising temperature exacerbated these antibiotic effects, with distinct microbial communities emerging at each temperature tested. Within these assemblages, we saw reduced diversity
and fewer microorganisms overall. These changes could diminish soils' resilience to future stress.

We also found that heat and antibiotics increased microbial respiration, decreasing efficiency. Essentially, microbes have to work harder to
survive when they are in a hot, antibiotic laden environment. This
is similar to how it is easier to walk a mile when it is 70 degrees
than it is to run a mile when it is 95 degrees. Decreased microbial
efficiency can cause soils to store less carbon in the long term."
As soil microbes are working harder (and inefficiently) to process carbon,
less is converted into a stable organic form, which would become trapped
in the soil. Instead, more carbon dioxide is released into the atmosphere
as a gas.

This effect could turn an important carbon sink into a carbon source, exacerbating climate change effects.

Senior author Michael Strickland, an Associate Professor at the
University of Idaho's Soil and Water Systems Department, says, "Forces
of environmental change do not play out in isolation. Our results show
that heat alone, antibiotics alone, and heat and antibiotics together
all have different effects on soil microbial communities. These findings highlight the importance of testing multiple stressors simultaneously
to more fully understand how our soils, and the essential functions
they perform, are changing." Lucas concludes, "This work aligns with
the 'One Health' approach. Agriculture, the environment, and public
health are inextricably linked. Understanding how multiple stressors
shape soil microbes is critical to supporting soil health in the
face of global change. If we do not manage for interactive effects,
things like soil carbon storage capacity and crop production could
be jeopardized. In addition to broader climate mitigation efforts,
limiting antibiotic inputs to the environment could help protect soils." ========================================================================== Story Source: Materials provided by
Cary_Institute_of_Ecosystem_Studies. Note: Content may be edited for
style and length.


========================================================================== Journal Reference:
1. Jane M. Lucas, Bronte M. Sone, Dana Whitmore, Michael S. Strickland.

Antibiotics and temperature interact to disrupt soil communities
and nutrient cycling. Soil Biology and Biochemistry, 2021; 163:
108437 DOI: 10.1016/j.soilbio.2021.108437 ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2021/11/211108161433.htm

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