• Humans disrupting 66 million-year-old fe

    From ScienceDaily@1:317/3 to All on Thursday, April 21, 2022 22:30:46
    Humans disrupting 66 million-year-old feature of ecosystems
    Diet-size relationship found across deep time, multiple vertebrate groups


    Date:
    April 21, 2022
    Source:
    University of Nebraska-Lincoln
    Summary:
    Human-related extinctions of the largest herbivores and carnivores
    are disrupting what appears to be a fundamental feature of past
    and present ecosystems, says a new study.



    FULL STORY ==========================================================================
    The U-shaped relationship between diet and size in modern land mammals
    could also stand for "universal," says a new study, which has found
    that the relationship spans at least 66 million years and a range of
    vertebrate animal groups.


    ==========================================================================
    It's been several decades since ecologists realized that graphing the
    diet-size relationship of terrestrial mammals yields a U-shaped curve when aligning those mammals on a plant-to-protein gradient. As illustrated by
    that curve, the plant-eating herbivores on the far left and meat-eating carnivores on the far right tend to reach sizes much larger than those
    of the all-consuming omnivores and the invertebrate-feasting invertivores
    in the middle.

    To date, though, virtually no research had looked for the pattern
    beyond mammals or the modern day. In a new study, researchers from the University of Nebraska-Lincoln and institutions on four continents have concluded that the pattern actually dates back to deep time and applies
    to land-dwelling birds, reptiles and even saltwater fishes.

    But the study also suggests that human-related extinctions of the largest herbivores and carnivores are disrupting what appears to be a fundamental feature of past and present ecosystems, with potentially unpredictable consequences.

    "We're not sure what's going to happen, because this hasn't happened
    before," said Will Gearty, a postdoctoral researcher at Nebraska and
    co-author of the study, published April 21 in the journalNature Ecology
    and Evolution. "But because the systems have been in what seems to be
    a very steady state for a very long time, it's concerning what might
    happen when they leave that state." Size up, size down The evolutionary
    and ecological histories of animal species can be told in part through
    the intertwined influences of diet and size, Gearty said. A species'
    diet determines its energy consumption, which in turn drives growth and ultimately helps dictate its size. Yet that size can also limit the
    quality and quantity of food available to a species, even as it sets
    thresholds for the quality and quantity needed to survive.



    ==========================================================================
    "You can be as big as your food will allow you to be," Gearty said. "At
    the same time, you're often as big as you need to be to catch and process
    your food. So there's an evolutionary interplay there." Because the plant-based diet of herbivores is relatively poor in nutrition, they often
    grow massive for the sake of covering more ground to forage more food --
    and accommodating long, complex digestive tracts that extract maximum
    nutrients from it. Carnivores, meanwhile, must grow large enough to both
    keep up with and take down those herbivores. Though the buffet-style
    menu of omnivores usually keeps their stomachs full, their high energy
    demands generally leave them focusing on nuts, insects and other small, energy-dense foods. And while invertivores enjoy mostly protein-rich prey,
    the diminutive nature of that prey, combined with stiff competition from
    many other invertivores, relegates them to the smallest sizes of all.

    The ultimate result: a U-shaped distribution of both average and maximum
    body sizes in mammals. To analyze the generalizability of that pattern
    in the modern day, the team compiled body-size data for a huge number
    of surviving species: 5,033 mammals, 8,991 birds, 7,356 reptiles and
    2,795 fishes.

    Though the pattern was absent in marine mammals and seabirds, probably
    due to the unique demands of living in water, it did emerge in the other vertebrate groups -- reptiles, saltwater fishes and land-based birds -- examined by the team. The pattern even held across various biomes --
    forests vs. grasslands vs.

    deserts, for instance, or the tropical Atlantic Ocean vs. the temperate
    North Pacific -- when analyzing land mammals, land birds and saltwater
    fishes.

    "Showing that this exists across all these different groups does suggest
    that it is something fundamental about how vertebrates acquire energy, how
    they interact with one another, and how they coexist," said co-author Kate Lyons, assistant professor of biological sciences at Nebraska. "We don't
    know whether it's necessary -- there might be other ways of organizing vertebrate communities with respect to body size and diet -- but it
    certainly is sufficient." But the researchers were also interested in
    learning how long the U-curve may have endured. So they analyzed fossil
    records from 5,427 mammal species, some of which date as far back as the
    Early Cretaceous Period of 145 million to 100 million years ago. Lyons
    and colleagues originally collected the fossil data as part of a 2018
    study on the extinction of large mammals at the hands of humans and
    their recent ancestors.



    ==========================================================================
    "To my knowledge, this is the most extensive investigation of the
    evolution of body size and especially diet in mammals over time,"
    Gearty said.

    It revealed that the U-curve stretches back at least 66 million years,
    when non-avian dinosaurs had just been wiped out but mammals had yet to diversify into the dominant animal class that they are today.

    "It is really interesting, and really striking," Gearty said, "to
    see that this relationship persists even when you have other dominant
    animals around.

    "We suspect that it's actually existed since the inception of mammals
    as a group." The shape of things to come Having catalogued the present
    and past of the U-curve, Gearty, Lyons and their colleagues turned to
    its future, or potential lack thereof. The median sizes of herbivores
    and omnivores have plummeted roughly 100-fold since the emergence of Neanderthals and Homo sapiens over the past few hundred thousand years,
    the team reported, with the size of carnivores dropping by about 10
    times in that same span. As a result, the U-curve that has persisted
    for so long has begun to noticeably flatten, Gearty said.

    In that vein, the team has projected a greater than 50% chance that
    multiple large- and medium-sized mammals -- including the tiger and
    Javan rhinoceros, both of which count humans as their only predators --
    will go extinct within the next 200 years. Those predicted extinctions
    would only exacerbate the disruption of the U-curve, the researchers
    said, especially to the extent that the loss of large herbivores could
    trigger or accelerate the loss of the large carnivores that prey on them.

    "It's certainly possible that as we take some of these animals off the top
    (of the U-curve), and as we collapse some of these ranges of body sizes,
    that we're altering the way the energy is divvied up," Gearty said. "That
    could perhaps have fundamental repercussions for the environment and
    ecosystem as a whole." It's also possible, the researchers concluded,
    that the forthcoming decline in mammal body sizes could outpace even
    the unprecedented drop observed over the past few hundred thousand years.

    "You keep seeing, in ecological literature, people speculating about
    how ecosystems are less stable now, and less resilient, and more prone
    to collapse," Lyons said. "I think this is just another line of evidence suggesting that that may indeed be the case in the future." Gearty and
    Lyons authored the study with Robert Cooke, from the UK Centre for Ecology
    & Hydrology; Amanda Bates, from the University of Victoria (Canada);
    Abbie Chapman, from University College London; Jillian Dunic, from
    Simon Fraser University (Canada); Graham Edgar and Rick Stuart-Smith,
    from the University of Tasmania (Australia); Jonathan Lefcheck, from
    the Smithsonian Environmental Research Center; Craig McClain, from the Louisiana Universities Marine Consortium; and Gil Rilov, from Israel Limnological and Oceanographic Research.


    ========================================================================== Story Source: Materials provided by
    University_of_Nebraska-Lincoln. Original written by Scott Schrage. Note: Content may be edited for style and length.


    ========================================================================== Related Multimedia:
    * Charts_and_illustrations_comparing_mammalian_herbivores,_omnivores,
    invertivores_and_carnivores.

    ========================================================================== Journal Reference:
    1. Rob Cooke, William Gearty, Abbie S. A. Chapman, Jillian Dunic,
    Graham J.

    Edgar, Jonathan S. Lefcheck, Gil Rilov, Craig R. McClain, Rick
    D. Stuart- Smith, S. Kathleen Lyons, Amanda E. Bates. Anthropogenic
    disruptions to longstanding patterns of trophic-size structure
    in vertebrates. Nature Ecology & Evolution, 2022; DOI:
    10.1038/s41559-022-01726-x ==========================================================================

    Link to news story: https://www.sciencedaily.com/releases/2022/04/220421131006.htm

    --- up 7 weeks, 3 days, 10 hours, 51 minutes
    * Origin: -=> Castle Rock BBS <=- Now Husky HPT Powered! (1:317/3)