Ancient Sea Monsters Swallowed a Lot of Salty Water. This Is How They Got Rid of It.

Here’s how ancient sea monsters got rid of all that salty seawater they swallowed while hunting in the deep, blue sea.

ALBUQUERQUE, N.M. — Ancient sea monsters inadvertently swallowed mouthfuls of seawater whenever they gulped down prey, but they had a stealthy trick to get rid of all that salt.

Their secret? Salt-secreting glands, which removed any salt surpluses, Judy Massare, a professor emerita in the Earth Sciences Department at The College at Brockport, State University of New York, said here at a presentation today (Oct. 17) at the 78th annual meeting of the Society of Vertebrate Paleontology. Massare helped locate these glands in ichthyosaurs — fearsome dolphin-like reptiles that lived during the dinosaur age.

Massare and her colleagues spotted evidence for the ichthyosaur’s salt-removing glands on either side of the prehistoric creature’s skull, just behind the external naris, the opening for breathing, she said. “When we saw odd structures in bones that border the external naris, we suspected that they were defining the position of a salt gland duct,” Massare told Live Science. [Image Gallery: Ancient Monsters of the Sea]

However, scientists weren’t sure if some ancient reptiles, such as ichthyosaurs, also sported salt glands. Corroborating evidence suggested they did: fossilized hooklets from squid-like animals are often found in the ribs of ichthyosaurs, so it follows that these predators likely swallowed lots of seawater when guzzling these invertebrates, Massare said.

“That means a lot of salt was taken in and needed to be removed,” Massare said.

It wasn’t until a 2012 study in the journal Paludicolathat Bill Wahl, a paleontologist at the Wyoming Dinosaur Center, identified evidence for the first salt glands on an ichthyosaur (Ophthalmosaurus natans) from Wyoming dating to the Jurassic period, which lasted from about 199 million to 145 million years ago. (It’s not odd to find fossilized sea creatures in the middle of America. This ichthyosaur once swam in a giant seaway that covered much of the U.S. Midwest and South from about 100 million to about 75 million years ago.)

Now, Massare, who is leading the new project, Wahl and their colleague Dean Lomax, a paleontologist at the University of Manchester in England, have identified even more salt glands in other fossilized species, such as the Jurassic ichthyosaurs Ichthyosauruslarkiniand Ichthyosaurus somersetensis.

An ichthyosaur from the genus Ichthyosaurus that is on display at the Natural History Museum in London. You can spot evidence for a salt gland duct by looking at the tiny circular bump in the crevice (the nares) to the left of the eye and above the jaw.
Credit: Dean Lomax

The research has yet to be published in a peer-review journal.

Granted, the research team hasn’t found the actual salt glands, which were made of soft tissue and didn’t fossilize. Rather, they found “previously unexplained projections on bones … indicating the position of a duct from a nasal salt gland,” Massare said.

This would have been a prime location for a salt gland duct. “As the ichthyosaur swam, salt water passing over the skull would be disrupted by the raised posterior edge of the naris, creating eddies that would flush out the back portion of the naris,” Massare said. “A concentrated salt solution could be carried away easily by the water as the ichthyosaur swam.”

The team has made a good case that that these bony structures might be evidence of salt glands, especially since the structures appear fairly consistent across different ichthyosaur species, said Takuya Konishi, an assistant professor-educator in the Department of Biological Sciences at the University of Cincinnati, who was not involved with the research.

However, the case would be strengthened if researchers were to find these structures in earlier, Triassic period ichthyosaurs, too, when these reptiles were first preserved in the fossil record. (Massare, for her part, said she has yet to extensively look for evidence of salt glands in Triassicspecimens.)

“The salt gland must have been evolved at the very beginning, at the time that they became marine,” Konishi said. “I would be very excited to see a follow-up study to further augment [this idea] by finding more osteological marks, even in these Triassic forms.”

Originally published on Live Science


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