https://news.cornell.edu/stories/2021/04/soil-bacteria-could-improve-crop-yields-fungi

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        Soil bacteria could improve crop yields, via fungi

        By Michael J. Haas |

        April 6, 2021
            

        A team of researchers from the Boyce Thompson Institute (BTI)
        has discovered a distinct group of bacteria that may help
        fungi and plants acquire soil nutrients. The findings could
        point the way to cost-effective and eco-friendly methods of
        enriching soil and improving crop yields, reducing farmers'
        reliance on conventional fertilizers.

        Researchers know that a type of fungi called arbuscular
        mycorrhizal (AM) fungi establishes symbiotic relationships
        with the roots of 70% of all land plants. In this
        relationship, plants trade fatty acids for the fungi's
        nitrogen and phosphorus. However, AM fungi lack the enzymes
        needed to free nitrogen and phosphorus from complex organic
        molecules.

        Arbuscular mycorrhizal fungi
        Maria Harrison/Provided
       
        Arbuscular mycorrhizal fungi extend long filament-like
        structures called hyphae far out into the soil. The hyphae,
        which are smaller than a human hair, can be seen here among
        the roots of a grass plant.

        A trio of BTI scientists led by Maria Harrison, the William
        H. Crocker Professor at BTI, wondered whether other soil
        microbes might help the fungi access those nutrients. In a
        first step toward examining that possibility, the team
        investigated whether AM fungi associate with a specific
        community of bacteria. Their research appeared March 1 in The
        ISME Journal.

        The team examined bacteria living on the surfaces of long
        filament-like structures called hyphae, which the fungi
        extend into the soil far from their host plant. On hyphae
        from two species of fungi, the team discovered highly similar
        bacterial communities whose composition was distinct from
        those in the surrounding soil.

        "This tells us that, just like the human gut or plant roots,
        the hyphae of AM fungi have their own unique microbiomes,"
        said Harrison, who is also adjunct professor in the School of
        Integrative Plant Science in Cornell's College of Agriculture
        and Life Sciences. "We're already testing a few interesting
        predictions as to what these bacteria might do, such as
        helping with phosphate acquisition.

        "If we're right, then enriching the soil for some of these
        bacteria could increase crop yields and, ultimately, reduce
        the need for conventional fertilizers along with their
        associated costs and environmental impacts," she added.

        Her co-researchers on the study were former BTI scientists
        Bryan Emmett and Veronique Levesque-Tremblay.

        In the study, the team used two species of AM fungi, Glomus
        versiforme and Rhizophagus irregularis, and grew them in
        three different types of soil in symbiosis with Brachypodium
        distachyon, a grass species related to wheat. After letting
        the fungus grow with the grass for up to 65 days, the
        researchers used gene sequencing to identify bacteria
        sticking to the hyphae surfaces.

        The team found remarkable consistency in the makeup of
        bacterial communities from the two fungal species. Those
        communities were similar in all three soil types, but very
        different from those found in soil away from the filaments.

        The function of these bacteria is not yet clear, but their
        composition has already sparked some interesting
        possibilities, Harrison said.

        "We predict that some of these bacteria liberate phosphorus
        ions in the immediate vicinity of the filaments, giving the
        fungus the best chance to capture those ions," Harrison said.
        "Learning which bacteria have this function could be key to
        enhancing the fungi's phosphate acquisition process to
        benefit plants."

        Harrison's group is investigating the factors that control
        which bacteria assemble on the filaments. Harrison thinks the
        AM fungi may secrete molecules that attract these bacteria,
        and in turn, the bacterial communities may influence which
        molecules the fungus secretes.

        Among the hyphae microbiomes were members of Myxococcales and
        other taxa that include "bacterial predators" that kill and
        eat other bacteria by causing them to burst and release their
        contents.

        These predators move by gliding along surfaces so "the fungal
        filaments could serve as linear feeding lanes," said Emmett,
        who is currently a research microbiologist for the U.S.
        Department of Agriculture's Agricultural Research Service in
        Ames, Iowa. "Many soil bacteria appear to travel along fungal
        hyphae in soil, and these predators may make it a more
        perilous journey."

        While not every member of those taxa on the filaments may be
        predatory, Harrison's group plans to investigate how and why
        those potential predators assemble there. "It's possible that
        the actions of predatory bacteria make mineral nutrients
        available to everyone in the surrounding soil - predators and
        fungi alike," she said.

        The research work was supported by the U.S. Department of
        Energy.

        Michael J. Haas is a freelance writer for the Boyce Thompson
        Institute.

        Food & Agriculture
        Life Sciences & Veterinary Medicine
        Media Inquiries
       
        Media Contact

        Lindsey Hadlock

        lmh267@cornell.edu
        607-269-6911
        -------------------------------------------------------------
       
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