An international team of researchers, including a neuroscientist from the University of Florida, has produced more evidence that people have a close evolutionary connection with tiny, flatworm-like organisms scientifically known as “Acoelomorphs.”
The research in the Thursday (Feb. 10) issue of Nature offers insights into brain development and human diseases, possibly shedding light on animal models used to study development of nerve cells and complex neurodegenerative diseases such as Alzheimer’s and Parkinson’s.
“It was like looking under a rock and finding something unexpected,” said Leonid L. Moroz, a professor in the department of neuroscience with the UF College of Medicine. “We’ve known there were very unusual twists in the evolution of the complex brains, but this suggests the independent evolution of complex brains in our lineage versus invertebrates, for example, in lineages leading to the octopus or the honeybee.”
The latest research indicates that of the five animal phyla, the highest classification in our evolutionary neighborhood, four contain worms. But none are anatomically simpler than “acoels,” which have no brains or centralized nervous systems. Less than a few millimeters in size, acoels are little more than tiny bags of cells that breathe through their skin and digest food by surrounding it.
Comparing extensive genome-wide data, mitochondrial genes and tiny signaling nucleic acids called microRNAs, the researchers hailing from six countries determined a strong possibility that acoels
and their kin are “sisters” to another peculiar type of marine worm from northern seas, called Xenoturbella.
From there, like playing “Six Degrees of Kevin Bacon,” the branches continue to humans.
“If you looked at one of these creatures you would say, ‘what is all of this excitement about a worm?’” said Richard G. Northcutt, a professor of neurosciences at Scripps Institution of Oceanography, who was not involved in the study. “These are tiny animals that have almost no anatomy, which presents very little for scientists to compare them with. But through genetics, if the analysis is correct — and time will tell if it is — the study has taken a very bothersome group that scientists are not sure what to do with and says it is related to vertebrates, ourselves and echinoderms (such as starfish).
“The significance of the research is it gives us a better understanding of how animals are related and, by inference, a better understanding of the history of the animals leading to humans,” Northcutt said.
Scientists used high-throughput computational tools to reconstruct deep evolutionary relationships, apparently confirming suspicions that three lineages of marine worms and vertebrates are part of a common evolutionary line called “deuterostomes,” which share a common ancestor.
“The early evolution of lineages leading to vertebrates, sea stars and acorn worms is much more complex than most people expect because it involves not just gene gain, but enormous gene loss,” said Moroz, who is affiliated with the Whitney Laboratory for Marine Bioscience and UF’s McKnight Brain Institute. “An alternative, yet unlikely, scenario would be that our common ancestor had a central nervous system, and then just lost it, still remaining a free living organism.
Understanding the complex cellular rearrangements and the origin of animal innovations, such as the brain, is critically important for understanding human development and disease, Moroz said.
“We need to be able to interpret molecular events in the medical field,” he said. “Is what’s happening in different lineages of neuronal and stem cells, for example, completely new, or is it reflecting something that is in the arrays of ancestral toolkits preserved over more than 550 million years of our evolutionary history? Working with models of human disease, you really need to be sure.”
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