California University scientists have discovered that tiny ‘bone-devouring worms’, known to both eat and inhabit dead whale skeletons and other bones on the sea floor, have a unique ability to release bone-melting acid.
These "bone-devouring worms," known to both eat and inhabit dead whale skeletons and other bones on the sea floor, have a unique ability to release bone-melting acid (Greg Rouse)
“These worms are unique in using bone as a habitat and nutrient source,” said study co-author Dr Sigrid Katz, a postdoctoral researcher at the University of California’s Scripps Institution of Oceanography in San Diego. “We have learned a lot about these worms in the past 10 years, but one of the most intriguing questions has been how they penetrate bone and take up nutrients.”
The worms, whose official genus name is Osedax, are up to 3-4 cm long and were discovered on a whale carcass in 2002. They come from a family of worms living in unexpected locations, with their relatives inhabiting the extremely hot and acidic hydrothermal vents in the sea. Like all worms in their family, Osedax have no mouth, anus, or gut.
Their digestion of the nutritious bone is made possible by their partnership with bacteria.
While it had been clear that the worms and their bacteria rely on nutrients such as collagen or fat from the bones they inhabit, until now it was a mystery how the worms penetrated the bones and access their nutrients. Their bodies consist of a worm-like portion and ‘roots’ that house the bacteria and penetrate the bones, but they have no body parts mechanically able to drill through bone.
The scientists looked instead for signs of a chemical drilling strategy, testing for the presence of acid-secreting enzymes in different tissues of the worm. One of the enzymes, a proton pump, was abundant in the roots, the part of the worm that penetrates the bone. The results, presented at the Society for Experimental Biology’s 2012 meeting in Salzburg, Austria, indicate that the worm secretes acid to demineralize the bones.
“The discovery of Osedax shows that nutrition is even more diverse than we imagined, and our results are a step further in understanding the special relationship between the worm and its bacteria,” Dr Katz said.
The findings of this study pertain to the females only. The males never grow beyond their larval size (about 1 mm) and they live inside the gelatinous tube that surrounds each female. Each female will have hundreds of males living in her tube.
