Ancient Rocks Tell a Billion-Year-Old Tale: The Evolution of Animal Diets

Bearded Fireworm

Using tools from geology and genetics, researchers are uncovering evidence of a shift in how the first living things ate, based on molecular fossils, organic traces from billion-year-old rocks. Present-day annelid worms, like earthworms and this bearded fireworm, have retained a gene to make some types of lipids that most animals have lost.

Paleontologists, led by David Gold, are uncovering the evolution of early life through chemical traces in ancient rocks and genetic studies. They’ve discovered that changes in sterol lipids in rocks correspond with significant shifts in animal diets and the rise of algae, shedding light on life over a billion years ago.

Paleontologists are getting a glimpse at life over a billion years in the past based on chemical traces in ancient rocks and the genetics of living animals. Research published on December 1 in Nature Communications combines geology and genetics, showing how changes in the early Earth prompted a shift in how animals eat.

Molecular Paleontology: Bridging Geology and Biology

David Gold, associate professor in the Department of Earth and Planetary Sciences at the University of California, Davis, works in the new field of molecular paleontology, using the tools of both geology and biology to study the evolution of life. With new technology, it’s possible to recover chemical traces of life from ancient rocks, where animal fossils are scarce.

Lipids in particular can survive in rocks for hundreds of millions of years. Traces of sterol lipids, which come from cell membranes, have been found in rocks up to 1.6 billion years old. In the present day, most animals use cholesterol — sterols with 27 carbon atoms (C27) — in their cell membranes. In contrast, fungi typically use C28 sterols, while plants and green algae produce C29 sterols. The C28 and C29 sterols are also known as phytosterols.

Tracing Life’s Evolution Through Chemical Markers

C27 sterols have been found in rocks 850 million years old, while C28 and C29 traces appear about 200 million years later. This is thought to reflect the increasing diversity of life at this time and the evolution of the first fungi and green algae.

Without actual fossils, it’s hard to say much about the animals or plants these sterols came from. But a genetic analysis by Gold and colleagues is shedding some light.

Don’t Make It, Eat It

Most animals are not able to make phytosterols themselves, but they can obtain them by eating plants or fungi. Recently, it was discovered that annelids (segmented worms, a group that includes the common earthworm) have a gene called smt, which is required to make longer-chain sterols. By looking at smt genes from different animals, Gold and colleagues created a family tree for smt first within the annelids, then across animal life in general.

They found that the gene originated very far back in the evolution of the first animals, and then went through rapid changes around the same time that phytosterols appeared in the rock record. Subsequently, most lineages of animals lost the smt gene.

“Our interpretation is that these phytosterol molecular fossils record the rise of algae in ancient oceans, and that animals abandoned phytosterol production when they could easily obtain it from this increasingly abundant food source,” Gold said. “If we’re right, then the history of the smt gene chronicles a change in animal feeding strategies early in their evolution.”

Reference: “Common origin of sterol biosynthesis points to a feeding strategy shift in Neoproterozoic animals” by T. Brunoir, C. Mulligan, A. Sistiaga, K. M. Vuu, P. M. Shih, S. S. O’Reilly, R. E. Summons and D. A. Gold, 31 November 2023, Nature Communications.
DOI: 10.1038/s41467-023-43545-z

Co-authors on the paper are: at UC Davis, Tessa Brunoir and Chris Mulligan; Ainara Sistiaga, University of Copenhagen; K.M. Vuu and Patrick Shih, Joint Bioenergy Institute, Lawrence Berkeley National Laboratory; Shane O’Reilly, Atlantic Technological University, Sligo, Ireland; Roger Summons, Massachusetts Institute of Technology. The work was supported in part by a grant from the National Science Foundation.

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