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Paper offers glimpse of 500-million-year-old sea worm named after ‘Dune’ monster
LAWRENCE — Excavations by a University of Kansas paleontologist working in a treasure trove of fossils called the “Spence Shale Lagerstätte” have revealed an ancient sea worm unknown to science until now. The fieldwork took place in the High Creek area of the Spence Shale, a geologic formation straddling northern Utah and southern Idaho. The findings recently were published in the peer-reviewed journal Historical Biology.
Researchers to identify key brain, behavioral changes in aging women with premutations of the Fragile X gene
LAWRENCE — Only in the past 20 years have scientists recognized a condition known as Fragile X-associated tremor/ataxia syndrome (FXTAS). First documented in a small group of men who had grandchildren with Fragile X syndrome, it has more recently been identified in women. Researchers at the University of Kansas Life Span Institute and partners are currently recruiting women ages 60-75 with known FMR1 premutations and those without to participate in tests examining changes in cognition, grip strength and posture, and brain function in aging.
Full stories below.
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Contact: Brendan Lynch, KU News Service, 785-864-8855, [email protected], @BrendanMLynch
Paper offers glimpse of 500-million-year-old sea worm named after ‘Dune’ monster
LAWRENCE — Excavations by a University of Kansas paleontologist working in a treasure trove of fossils called the “Spence Shale Lagerstätte” have revealed an ancient sea worm unknown to science until now.
When she found the fossil, Rhiannon LaVine, a research associate with the KU Biodiversity Institute and Natural History Museum, was part of a team camping and carrying out fieldwork in the High Creek area of the Spence Shale, a geologic formation straddling northern Utah and southern Idaho. The area has been famed since the 1900s for its abundance in some 90 species of Cambrian trilobites and soft-bodied fossils.
Their findings recently were published in the peer-reviewed journal Historical Biology.
“One of the last times we were out there, I split open one of these pieces of rock and instantly knew it was something that wasn’t typical,” LaVine said. “The first thing we see are these radial blades that look like stars or flowers. Immediately, I showed it to (lead author) Julian Kimmig. He was perplexed. He’s said, ‘I’ve never seen anything like that.’ We were out with Paul Jamison, a local who’s been working the site for years — and if there’s something in there that somebody’s seen, he’s seen it. But he hadn’t seen it.”
After transporting the fossil specimen back to the KU Biodiversity Institute — where today it’s part of the permeant paleontological collection — LaVine consulted with colleagues about the mysterious fossil.
“I was showing it to everybody, asking, ‘What do you think this is?,’” LaVine said. “Nobody had an idea. We thought maybe it’s a wiwaxia, a very peculiar animal from about that time — but we don’t have too many representatives of it from the Spence area. Or maybe it’s a scale worm, but there’s no real scale worms known from that time. Maybe it was a juvenile jellyfish, but it’s so bladed and the lines are so straight on those things, it would be kind of odd. So, I couldn’t get a solid answer.”
Next, LaVine teamed with colleagues at the University of Missouri to conduct scanning electron microscopy and energy-dispersive X-ray spectrometry on the fossil.
“We mainly wanted to make sure that this was a biological thing, because it’s possible it could have just been some weird mineral growth with the way it looked,” said the KU researcher. “So that was primarily why we brought it to them. It’s about 7 or 8 centimeters long, maybe a little shorter than the length of a smartphone. It’s sizable for a fossil of that sort. We did the scanning to rule out that it wasn’t just a mineral growth, and we were able to do that.”
Finally, LaVine and her co-authors were able to determine the fossil to be a previously unknown species of annelid, a diverse phylum of some 21,000 “segmented worm” species found in terrestrial, freshwater and marine environments all over the world.
As the discoverer of the new fossil worm and a co-author on the paper describing it, LaVine bestowed the species with its scientific name: Shaihuludia shurikeni. Shai-Hulud is the indigenous name for the worms on the planet Arrakis in the “Dune” novels by Frank Herbert, while “shuriken” is the Japanese word for throwing star, representing the shape of the blade-like chaetae (chaetae are the stiff bristles that characterize many annelids).
“I’ve been involved in describing species before, but this is the first one I’ve named,” LaVine said. “Actually, I was able to name its genus — so I can put that feather in my cap. It was the first thing that came to mind, because I’m a big ol’ nerd and at the time I was getting really excited for the ‘Dune’ movies.”
Like worm’s sci-fi namesake, Shaihuludia shurikeni is a big deal: Describing a new species of Cambrian annelid doesn’t happen every day.
“Annelids are very rare in the Cambrian of North America, and so far we only knew of a single specimen from the Spence Shale,” said lead author Julien Kimmig, a paleontologist with the State Museum of Natural History in Karlsruhe, Germany. “The new annelid Shaihuludia shurikeni is especially interesting, as it had some very impressive chaetae, which makes it unique among the Cambrian annelids. The way that the fossil is preserved is also of particular interest, because most of the soft tissue is preserved as an iron oxide ‘blob,’ suggesting the animal died and was decomposing for a while before it was fossilized. However, with the analytical methods used in the paper, we show that even with limited preservation you can identify fossils.”
In the process, the team reexamined a fossilized annelid previously found in the Spence Shale and reclassified it as Burgessochaeta — a surprise because until then, Burgessochaeta have only been found in another famed fossil deposit in British Columbia, Canada.
“Burgessochaeta is really only known from the Burgess Shale,” LaVine said. “A similar worm was collected in our Spence Shale decades ago, and it was named Canadia, which is kind of a wastebasket genus for a lot of the annelids that come out of these types of deposits.
“Nobody really looked into it for a long time, but when we got this one, we took a little closer look at the other annelid found there. Maybe this was another version of it, or it was related in some way,” LaVine said. “We determined the other annelid from the Spence Shale is actually closer to Burgessochaeta — this is the first time it’s been described outside of the Burgess Shale.”
Both worm species would have inhabited a marine ecosystem ruled by invertebrate organisms, like trilobites, brachiopods, mollusks and early forms of arthropods. The mid-Cambrian is noted for the intense biodiversity of its marine life.
“This discovery gets us to think about deep time,” LaVine said. “When we look outside, we see all the animals that we know. Now we can walk past a duck, go to the beach and see a starfish and all the critters that exist in the ocean. We kind of know what to expect. But then we can let our imaginations go a little bit to imagine what happened a million years ago or, in this case, over 500 million years ago. What does the ocean look like then? You’re going to see a lot of the similar players, but they’re a little bit alien because evolution has taken place. It’s very cool to think about our planet as a record of history and all of the different environments that have happened over billions of years, all on the same ground we stand on. We’ve had alien worlds beneath our feet.”
LaVine and Kimmig’s co-authors were James Schiffbauer, Sven Egenhoff, Kevin Shelton and Wade Leibach.
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Contact: Christina Knott, Life Span Institute, [email protected], @kulifespan
Researchers to identify key brain, behavioral changes in aging women with premutations of the Fragile X gene
LAWRENCE — Only in the past 20 years have scientists recognized a condition known as Fragile X-associated tremor/ataxia syndrome (FXTAS). First documented in a small group of men who had grandchildren with Fragile X syndrome, it has more recently been identified in women. Researchers at the University of Kansas Life Span Institute now are working to learn more about its effects in women.
At one time, the genetic markers, or premutation alleles, of the Fragile X gene FMR1 were thought to be relatively benign in an individual carrying them in their genetic code; researchers only knew that the premutation alleles contributed to the risk for having a child with Fragile X syndrome, which causes a range of developmental problems in young children. Scientists now know that premutation alleles can contribute to severe changes in cognition and movement as carriers age. Those changes include tremor, balance issues and memory loss, and it can lead to a loss of independence.
“We know very little about which premutation carriers will develop FXTAS,” said Matt Mosconi, associate director and senior scientist at KU’s Life Span Institute and professor of clinical child psychology. “We know males are at greater risk than females. Otherwise, we don’t know a whole lot about which premutation carriers are going to get it. And we don’t know what changes are happening in the brain, as those seem to be different in men and women.”
Mosconi’s team, in collaboration with colleagues at Kansas State University and the University of California-Davis, are leading new studies of motor, cognitive and brain changes in female FMR1 premutation carriers to identify key symptoms to track during aging. They hope to better understand the causes of FXTAS in females.
Approximately 1 in 450 men carries the premutation that can lead to FXTAS, compared to about 1 in 200 women. Of those, about 40% of men and 16-20% of women will develop FXTAS symptoms. While usually more severe in men, FXTAS can still be debilitating in women.
FXTAS symptoms typically present when individuals reach their 50s or 60s but often are missed during early stages or misdiagnosed as Parkinson’s or Alzheimer’s disease. Greater knowledge of the key brain and behavioral changes associated with FXTAS in women is essential for identifying initial disease stages when treatments may be most effective.
Mosconi’s team is currently recruiting women ages 60-75 with known FMR1 premutations and those without to participate in tests examining changes in cognition, grip strength and posture, and brain function in aging.
The long-term goal of this study is to clarify neurodegenerative mechanisms of FXTAS in women so that more sensitive methods can be established to track disease progression and development, as well as to advance targeted therapeutic interventions.
For more information about participating in FMR1 research, visit the KU FMR1 research website or contact the KU BRAIN Lab at [email protected].
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