When a
partial fossil specimen of a primordial marine worm was unearthed in Utah in
1969, scientists had a tough go identifying it. Usually, such worms are recognized
and categorized by the arrangement of little knobs on their plates. But in this
case, the worm’s plates were oddly smooth, and important bits of the worm were
missing altogether.
This new fossil specimen of the worm Utahscolex ratcliffei helped
University of Kansas graduate student Anna Whitaker solve a 50-year-old
marine-worm mystery. This specimen preserves the everted mouthparts (upper
left). The body of the worm is covered of rows of tiny round plates, which were
used to redescribe the species. Credit: Whitaker, et. al.
Discouraged,
researchers placed the mystery worm in a “wastebasket” genus called
Palaeoscolex, and interest in the lowly critter waned for the next 50 years.
That all
changed recently when Paul Jamison, a teacher from Logan, Utah, and private
collector, and his student Riley Smith were hunting fossils in the Spence Shale
in Utah, a 506-million-year-old geologic unit housing a plethora of
exceptionally preserved soft-bodied and biomineralized fossils.
(Paleontologists call such a mother lode of fossils a “Lagerstätte.”) There,
Smith discovered a second, more thoroughly preserved example of the worm.
Eventually,
thanks to Jamison’s donation, the new fossil specimen arrived at the University
of Kansas Biodiversity Institute, where Anna Whitaker, a graduate student in
museum studies, researched and analyzed the worm with scanning electron
microscopes, energy-dispersive X-ray spectrometry and optical microscopy.
At last,
Whitaker determined the worm represented a new genus of Cambrian sea worm
heretofore unknown to science. She’s the lead author of a description of the
worm just published in the peer-reviewed paleontological journal PalZ.
“Before
the new species that we acquired there was only one specimen known from the
Spence Shale,” she said. “But with our new specimen we discovered it had
characteristics that the original specimen didn’t have. So, we were able to
update that description, and based on these new characteristics — we decided it
didn’t fit in its old genus. So, we moved it to a new one.”
Whitaker
and her colleagues — Jamison, James Schiffbauer of the University of Missouri
and Julien Kimmig of KU’s Biodiversity Institute — named the new genus
Utahscolex.
“We think
they’re closely related to priapulid worms that exist today — you can find them
in the oceans, and they are very similar to priapulids based on their mouth
parts,” Whitaker said. “What’s characteristic about these guys is that they
have a proboscis that can evert, so it can turn itself inside out and it’s
covered with spines — that’s how it grabs food and sucks it in. So, it behaved
very similarly to modern priapulid worms.”
While today,
Utah is not a place you’d look for marine life, the case was different 506
million years ago, when creatures preserved in the Spence Shale were
fossilized.
“The
Spence Shale was a shelf system, and it’s really interesting because it
preserves a lot of environments — nearshore to even deeper offshore, which is
kind of unusual for a Lagerstätte, and especially during the Cambrian. These
animals were living in kind of a muddy substrate. This worm was a carnivore, so
it was preying on other critters. But there would have been whole diversity of
animals — sponges, and trilobites scuttling along. We have very large, for the
time, bivalve arthropods that would be predators. The Spence has a very large
diversity of arthropods. It would have looked completely alien to us today.”
Whitaker
hopes to complete her master’s degree this spring, then to attend the
University of Toronto to earn her doctorate. The description of Utahscolex is
Whitaker’s first academic publication, but she hopes it won’t be her last. She
said the opportunity to perform such research is a chief reason for attending
KU.
“I came
for the museum studies program,” she said. “It’s one of the best in the
country, and the program’s flexibility has allowed me to focus on natural
history collections, which is what I hopefully will have a career in, and also
gain work experience in the collections and do research — so it’s kind of
everything I was looking for in the program.”
While
ancient sea worms could strike many as a meaninglessly obscure subject for such
intense interest and research, Whitaker said filling in gaps in the fossil
record leads to a broader understanding of evolutionary processes and offers
more granular details about the tree of life.
“I know
some people might say, ‘Why should we care about these?’” she said. “But the
taxonomy of naming all these species is really an old practice that started in
the 1700s. It underpins all the science that we do today. Looking at
biodiversity through time, we have to know the species diversity; we have to
know as correctly as we can how many species there were and how they were
related to each other. This supports our understanding of — as we move into
bigger and bigger, broader picture — how we can interpret this fossil record
correctly, or as best we can.”
Reference:
“Re-description of the Spence Shale palaeoscolecids in light of new
morphological features with comments on palaeoscolecid taxonomy and taphonomy”
by Anna F. Whitaker, Paul G. Jamison, James D. Schiffbauer and Julien Kimmig,
26 February 2020, PalZ.
Original article Here
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