Cracking the Case of How One of the Earliest Predators Hunted
A “weird shrimp” prowled Earth’s early seas, but how did it capture its
prey?
Portland, Ore., USA: Early in animal evolution, complex life was mostly
limited to the sea floor. But a few organisms evolved to move through the
water, giving them a big competitive advantage over those left scuttling
around in the mud.
Anomalocaris canadensis
, thought to be one of the first predator animals, is one of those early
swimmers. But paleontologists are still working out how exactly it hunted.
New research
, which will be presented at the Geological Society of America’s Connects
2021 annual meeting on Wednesday, aims to define how exactly this animal
used its long, spider-like front appendages to hunt.
With the mouth of a barnacle, the swimming style of a cuttlefish, the front
legs of a spider, and the overall feel of a giant shrimp, the 50-centimeter A. canadensis is the poster child for the evolutionary test
factory that was the Cambrian period (542 to 485 million years ago). The
“weird shrimp,” which is a rough translation of the animal’s Latin name, is
preserved in the Burgess Shale, a paleontological site known for
exceptional preservation of soft-bodied organisms. The unique ancient
environment provides scientists today with valuable insights into early
animals like A. canadensis, whose soft body parts are difficult to
preserve.
“As a complete animal, there really isn’t anything today that is moderately
comparable. However, if we split it up into major components, we can find
useful modern analogues,” said Russell Bicknell, an evolutionary
paleontologist at the University of New England in Australia who is
presenting the work.
In paleontology, there is a longstanding idea that A. canadensis
could have been responsible for some of the scarred and crushed trilobite
exoskeletons found during its time. But the animal was essentially
soft-bodied, meaning it lacked the hard exoskeleton “armor” of some of its
contemporaries (such as trilobites). That raises questions over if, and
how, the “soft and squishy” A. canadensis could have hunted
armored prey.
After reconstructing A. canadensis in 3D and micro-CT scanning two
modern animals with relatively similar frontal appendages, whip spiders and
whip scorpions, Bicknell and his colleagues used detailed, 3D modeling to
stretch and contract A. canadensis’s front appendages, the “legs”
thought to have been used for grabbing prey. They can do so by relying on
the geometry of the segmented fossil parts.
“In the model, I move each segment sequentially, and I only stop when
something is effectively impaling another part of the body. So we are using
the shapes to effectively put limitations on its range of motion,” Bicknell
said. Once the range of motion was established, they compared it to
movements to modern scorpions and spiders with similar appendages.
“That comparison of maximum extension and minimum rolling to modern forms
is how we were able to confidently demonstrate that these animals
definitely used their appendages to grab things,” Bicknell said.
However, it’s not enough to simply establish a range of motion; there’s a
question of strength, too. Now, Bicknell and his colleagues are virtually
applying muscles to the 3D model to understand the limits of the appendages
in grabbing. By using this biomechanical approach, they can test whether
the limbs had the strength to crack and crush shells. The model results
will help determine, after all these years, whether A. canadensis
could have been a trilobite hunter.
For Bicknell, the whole effort is a deep dive into the weird, wonderful
world of early animal life. “Anomalocaris epitomizes the Cambrian
when life was like, ‘I’m going to stick things together and see what we
get. Is this how we build a predator?’” he said. “It really showcases that
life was in this highly dynamic place where evolution was effectively
trying to produce animals to fill up all these ecological niches that had
developed.”
Paper 237-5: Exploring Anomalocaris Raptorial Appendages with 3D
Kinematics
https://gsa.confex.com/gsa/2021AM/meetingapp.cgi/Paper/366182
2:35–2:50 p.m. PDT
Russell Bicknell, University of New England, rbickne2@une.edu.au
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