Study of Ancient Invasive Species Can Improve Modern Conservation
Strategies
Denver, Colo., USA: Non-native species that invade and firmly establish
themselves in new regions have staggering economic and ecological
consequences.
Recent studies
estimate that, in the United States alone, invasive species now cause more
than US$120 billion in monetary damages per year and have contributed to
70 percent of extinctions of native aquatic species
this century, as well as many other adverse effects.
Although researchers have directly observed the impacts of biotic invasions
over annual to decadal timeframes, an understanding of how they affect
ecosystems over the longer term can only be gleaned from the study of
ancient invasions preserved in the fossil record. Now new research
presented on Tuesday at the annual meeting of The Geological Society of
America shows that it’s possible to study ancient invasions over time
scales of just a few thousand years—an unprecedented level of detail that
can inform the development of robust, long-term conservation strategies in
the Anthropocene.
“Bridging the gap in knowledge between short-term studies of modern
invasions and long-term patterns in the fossil record gives us a better
understanding of how modern invasions are likely to impact ecosystems over
larger time scales and allows for better-informed management strategies,” says Ian Forsythe, who worked on the project as a
master’s student at Ohio University and is now a doctoral student at the
University of Cincinnati.
Forsythe’s research focused on macrofaunal invertebrate fossils from the
Clarksville Phase of the Richmondian Invasion, the first pulse of a biotic
invasion that occurred during the Late Ordovician period around 450 million
years ago. At that time, a number of non-native genera invaded the shallow
sea that covered the area that is now northern Kentucky, southwestern Ohio,
and southeastern Indiana.
Forsythe became involved in the project when he started working in the lab
of Alycia Stigall, who is now a professor in the Department of Earth and
Planetary Sciences at the University of Tennessee at Knoxville. “The
Richmondian Invasion is one of the most intensely studied fossil invasion
events in terms of ecosystem and species impacts,” says Stigall. “But Ian’s
work is truly groundbreaking; he has been able to examine community-level
changes at a very fine temporal level of a few thousand years and relate
that directly to changes in sea level and timing of arrival of invaders.”
To collect this data, Forsythe used a quadrat sampling method, in which a
square grid is placed on a surface and the abundance of each taxon within
the grid cell is recorded. He then conducted an extensive
suite of analyses to comprehensively examine the ecological impacts of the
Clarksville Phase.
The results span pre-invasion, invasion, and post-invasion intervals across
a range of depositional environments. These range from the shallow ocean
where the seafloor is impacted by wave action to a nearby, offshore area up
to 100 meters deep.
Because the study was conducted within a detailed stratigraphic framework
that provided tight time resolution, Forsythe was able to relate invader
arrival and biotic changes to variations in sea level. “This represents the
most detailed analysis yet of invasion dynamics at timelines that
approximate modern ecosystems,” says Stigall.
The results indicate that biotic invasions of this type—where the invaders
occupy a low
trophic level
(such as filter feeders) and most of the recipient biota are not highly
specialized ecologically—are unlikely to result in the incumbents’
extinction. The data also suggest that taxa modify their habitat
preferences to accommodate novel competitors following Clarksville-type
invasions.
These findings can help inform decisions regarding how very limited
conservation funds should be spent, according to Forsythe. “Ecosystems of
this type may require less investment of resources than those with many
specialized species or that are combatting invasive taxa of high trophic
levels, like predators,” he says. The results also suggest that incumbents
most strongly inhibit invasion by taxa within their own guild, which can
help guide decisions regarding which invaders to target in systems
experiencing multiple invaders.
All told, says Forsythe, the research findings mean that we now better
understand the Richmondian Invasion specifically, and biotic invasions more
generally. “Although there is still much work to be done on the topic of
biotic invasions,” he concludes, “this study brings us a little bit nearer
to understanding the key details of how biotic invasions impact the
recipient biota, and I am glad to have played a part in that.”
Analysis of Ancient Invasion Illuminates Anthropocene Issues
Ian Forsythe, University of Cincinnati, forsytij@mail.uc.edu
Alycia Stigall, University of Tennessee, Knoxville, stigall@utk.edu
Tuesday, 11 October, 1:55 p.m.:
https://gsa.confex.com/gsa/2022AM/meetingapp.cgi/Paper/379115
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