In a paper placed online in advance of print in the Feb. 13 issue of the journal Cell Reports, the UO team shows that two molecular pathways work in concert to allow adult zebra fish to perfectly replace bones lost upon fin amputation.
One pathway resets existing bone cells to a developmental stem cell-like state and then supports their growth to replace lost cells. The second directs the newly formed cells to turn back into functional, organized bone. Using genetic, cellular and molecular approaches, the authors detailed how the opposing pathways cross-communicate to keep the regenerative process in balance.
Unlike humans, some vertebrates, including zebra fish, have amazing innate abilities to regenerate lost appendages and organs, said co-author Kryn Stankunas, a professor of biology and member of the UO Institute of Molecular Biology.
According to the authors, a mysterious process triggers residual cells to revert to a less developed state upon tissue damage, a process known as dedifferentation. The process is unique to animals like zebra fish and could be the key to their ability to perfectly restore lost tissue. Understanding the mechanisms could support the design of regenerative therapies that direct human cells to behave similarly.
►Kryn Stankunas on the science (1 minute, 38 seconds)
►Scott Stewart provides a simple overview (33 seconds)
►Implications for human health, Stankunas (44 seconds)
►The zebra fish model — using nature’s way (28 seconds)
“We focused on the bones of the zebra fish tail fin,” Stankunas said, “and asked how amputation induces mature bone-lining cells to go backwards in their developmental age to what’s called a progenitor state.”
The researchers found that cell-to-cell signaling mediated by the Wnt pathway helps existing mature bone cells become progenitor cells after fin amputation. This starts the bone regeneration process. Local Wnt production at the tip of the regrowing fin then maintains a pool of dividing bone progenitor cells until the fin is fully replaced. The job of second pathway, BMP, is to convert the progenitor cells back into mature bone that forms the characteristic bony rays of a fish’s fins. The authors show that both Wnt and BMP are needed to complete the process and describe how they engage in a cellular tug of war to balance their opposing roles.
Mammals, including humans, have these same pathways, and defects in them are associated with various human bone diseases, said the paper’s lead author Scott Stewart, an associate member of the UO Institute of Molecular Biology.
Manipulating the two pathways could lead to new therapies, he said. “Striking that balance involves manipulating these pathways in the correct sequence, Wnt and then BMP,” he said. “They have different roles and must act in a specific order.”
The U.S. Food and Drug Administration allows for the use of recombinant BMP to encourage bone-growth following some surgical procedures. However, Stankunas said, the treatment is not always effective. The new findings, he said, suggests that too much BMP may upset the optimum balance of Wnt and BMP signaling, and that alternative approaches may be more successful.
“Our research suggests that enhancing human bone repair or even inducing bone regeneration isn’t a ridiculous idea,” he said. “As we discover the cellular and molecular roles of the signals in zebra fish and pinpoint the missing network connections in mammals, maybe we could coax human bones to repair themselves equally as well.”
“The University of Oregon is renowned worldwide for its longstanding program of pioneering zebra fish research, which helped crack the genetic code of health and disease,” said Kimberly Andrews Espy, vice president for research and innovation and dean of the UO Graduate School. “This research by Drs. Stankunas and Stewart continues that trajectory by elucidating the natural process of bone regeneration in zebra fish. The insights from this study could one day be used to develop new treatments for bone fractures, post-surgical therapies and other ailments.”
Co-authors with Stewart and Stankunas were UO undergraduate student Alan W. Gomez, now a research assistant, doctoral student Benjamin E. Armstrong and research assistant Astra Henner. All are associated with UO Institute of Molecular Biology. Grants from the National Institutes of Health (5T32HD007348, 2T32GM007413 and 5R00HL087598) were associated with the project.
About the University of Oregon
The University of Oregon is among the 108 institutions chosen from 4,633 U.S. universities for top-tier designation of “Very High Research Activity” in the 2010 Carnegie Classification of Institutions of Higher Education. The UO also is one of two Pacific Northwest members of the Association of American Universities.
Media Contact: Jim Barlow, director of science and research communications, 541-346-3481, email@example.com
Sources: Scott Stewart, senior research associate, Institute of Molecular Biology, 541-346-9180, firstname.lastname@example.org, and Kryn Stankunas, assistant professor of biology, Institute of Molecular Biology, 541-346-7416, email@example.com
Follow UO Science on Facebook: http://www.facebook.com/UniversityOfOregonScience
UO Science on Twitter: http://twitter.com/UO_Research
More UO Science/Research News: http://uoresearch.uoregon.edu
Note: The University of Oregon is equipped with an on-campus television studio with a point-of-origin Vyvx connection, which provides broadcast-quality video to networks worldwide via fiber optic network. In addition, there is video access to satellite uplink, and audio access to an ISDN codec for broadcast-quality radio interviews.