Three-banded panther worm debuts as a new model in the study of regeneration
And yet, these little-studied organisms possess the ability to regenerate any part of their bodies and are amenable to molecular studies in the lab, making them a valuable addition to a field keen on understanding how mechanisms controlling regeneration have evolved over millennia and how they might be activated in humans.
Four years ago, postdoctoral researcher Mansi Srivastava and Reddien, collected these intriguing animals swimming among submerged mangrove leaves and other aquatic detritus in a chilly Bermudan pond. Known scientifically as Hofstenia miamia, the worm earned its common name from the three cream-colored stripes running across its body as well as its voracious appetite for live prey.
Found in the Caribbean, Bahamas, Bermuda, and even as far away as Japan and the Red Sea, the worms were reported to be endowed with regenerative capabilities. In the 1960s, one scientist described the fact that three-banded panther worms could regrow a severed head, although no additional reports followed.
“It was a big risk for us—it was not a project where you knew it was going to work from the beginning,” says Reddien, who is also an associate professor of biology at MIT and a Howard Hughes Medical Institute (HHMI) Investigator. “I had no idea how successful we'd be with culturing the animals or how successful the methods for development would be. There are all kinds of ways we could've failed on this one, but it was fun. It's the kind of science that has an adventurous spirit to it. And the organism is an even better model organism than we could have hoped for.”
Reddien and Srivastava present their new model to the scientific community in the May 19th issue of the journal Current Biology.
Once the worms arrived in their new home in Cambridge, the first test was to acclimate them to lab life and determine their needs for survival. Initially, the worms were dying. The salinity of their water was off, even though it matched the pond where they were found. Hofstenia also rejected the liver that is the dietary mainstay for Reddien's other model of regeneration, the planarian (Schmidtea mediterranea). The three-banded panther worms shrank in size and some resorted to cannibalism.
Eventually, the water quality was fixed and a preferred food source was identified: sea monkeys, also known as brine shrimp. Now the worms are thriving and laying numerous eggs, enough to create an ample supply of animals for experiments.
Through a series of dissections, Reddien and Srivastava established that Hofstenia not only regenerate their heads, but, like planarians, are also able to regrow any body part. The scientists then documented the worm's transcriptome—a list of all of the genes that are transcribed in the animal—and established that RNA interference (RNAi) could be used in this animal to inhibit specific genes and unlock the molecular functions that allow regeneration.
With these tools in hand, they determined that in Hofstenia, as in planarians, Wnt signaling controls regeneration along the anterior-posterior (head-tail) axis and Bmp-Admp signaling controls regeneration along the dorsal-ventral (back-belly) axis.
If Hofstenia and planarians were phylogenetically close, such similarities would not be surprising. But after analyzing the Hofstenia transcriptome, the team determined that the three-banded panther worm and planarians are only very distantly related, a view that had been proposed based on analyses with sequences from a small number of genes.
“I find that there is no evidence, even with this large dataset, for Hofstenia to be classified with planarians, which means the last common ancestor that these two species shared existed 550 million years ago. This is the common ancestor that we, humans, also share with these species,” says Srivastava, who has a background in evolutionary developmental biology and authored the Current Biology article. “The cool thing is that this raises the question of whether our common ancestor used these pathways—Wnt and Bmp signaling—to regenerate or not.”
This work is supported by the Jane Coffin Childs Memorial Fund, Human Frontier Science Program, and the Keck Foundation.
Written by Nicole Giese Rura
Peter Reddien's primary affiliation is with Whitehead Institute for Biomedical Research, where his laboratory is located and all his research is conducted. He is also a Howard Hughes Medical Institute Investigator and an Associate Professor of Biology at the Massachusetts Institute of Technology.
“Whole-body acoel regeneration is controlled by Wnt and Bmp-Admp signaling”
Current Biology, May 19, 2014.
Mansi Srivastava (1), Kathleen L. Mazza-Curll (1), Josien C. van Wolfswinkel (1), and Peter W. Reddien (1).
1. Howard Hughes Medical Institute, Whitehead Institute for Biomedical Research, and Department of Biology, Massachusetts Institute of Technology, 9 Cambridge Center, Cambridge, MA 02142, USA.
All news from this category: Life Sciences
Articles and reports from the Life Sciences area deal with applied and basic research into modern biology, chemistry and human medicine.
Valuable information can be found on a range of life sciences fields including bacteriology, biochemistry, bionics, bioinformatics, biophysics, biotechnology, genetics, geobotany, human biology, marine biology, microbiology, molecular biology, cellular biology, zoology, bioinorganic chemistry, microchemistry and environmental chemistry.
Researchers confront optics and data-transfer challenges with 3D-printed lens
Researchers have developed new 3D-printed microlenses with adjustable refractive indices – a property that gives them highly specialized light-focusing abilities. This advancement is poised to improve imaging, computing and communications…
Research leads to better modeling of hypersonic flow
Hypersonic flight is conventionally referred to as the ability to fly at speeds significantly faster than the speed of sound and presents an extraordinary set of technical challenges. As an…
Researchers create ingredients to produce food by 3D printing
Food engineers in Brazil and France developed gels based on modified starch for use as “ink” to make foods and novel materials by additive manufacturing. It is already possible to…