Researchers Find First Ever Evidence for Epigenetics in Archaea

A team of scientists from the University of Nebraska-Lincoln and the University of California, Santa Cruz, has found evidence that an evolutionary phenomenon at work in complex organisms is at play in archaea, a group of single-celled microorganisms famous for their love of living in extreme environments.

Microscopy image of Sulfolobus solfataricus. Image credit: D. Janckovik / W. Zillig.

Microscopy image of Sulfolobus solfataricus. Image credit: D. Janckovik / W. Zillig.

Species most often evolve through mutations in DNA that get inherited by successive generations.

A few decades ago, researchers began discovering that multicellular species can also evolve through epigenetics: traits originating not from genetic changes but from the inheritance of cellular proteins that control access to an organism’s DNA.

Because those proteins can respond to shifts in an organism’s environment, epigenetics resides on the ever-thin border between nature and nurture.

Evidence for it had emerged only in eukaryotes, the multicellular domain of life that comprises animals, plants and several other kingdoms.

But the new experiments have shown that epigenetics can pass along extreme acid resistance in a species of archaea, Sulfolobus solfataricus.

“The surprise is that it’s in these relatively primitive organisms, which we know to be ancient,” said senior author Professor Paul Blum, from the University of Nebraska-Lincoln and the University of California, Santa Cruz.

“We’ve been thinking about this as something (evolutionarily) new. But epigenetics is not a newcomer to the planet.”

Sulfolobus solfataricus is a sulfur-eating species that thrives in the boiling, vinegar-acidic springs (the species grows optimally at pH 3.0 and 80 degrees Celsius) of Yellowstone National Park.

By exposing Sulfolobus solfataricus to increasing levels of acidity over several years, the team evolved three strains that exhibited a resistance 178 times greater than that of their Yellowstone ancestors.

One of those strains evolved the resistance despite no mutations in its DNA, while the other two underwent mutations in mutually exclusive genes that do not contribute to acid resistance.

And when the scientists disrupted the proteins thought to control the expression of resistance-relevant genes — leaving the DNA itself untouched — that resistance abruptly disappeared in subsequent generations.

“We predicted that they’d be mutated, and we’d follow the mutations, and that would teach us what caused the extreme acid resistance. But that’s not what we found,” Professor Blum said.

Though epigenetics is essential to some of the most productive and destructive physiological processes in humans — the differentiation of cells into roughly 200 types, the occurrence of cancers — it remains difficult to study in eukaryotes.

“The simplicity of archaea, combined with the fact that their cells resemble eukaryotes’ in some important ways, should allow us to investigate epigenetic questions much faster and more cheaply than was possible before,” Professor Blum said.

“We don’t know what flips the switch in humans that changes epigenetic traits.”

“And we sure don’t know how to reverse it very often. That’s the first thing we’ll go after: how to turn it on, how to turn it off, how to get it to switch. And that has benefits when you think about (managing) traits in us or traits in plants.”

“Yet the discovery also raises questions, especially about how both eukaryotes and archaea came to adopt epigenetics as a method of inheritance,” said study first author Sophie Payne, a doctoral student at the University of Nebraska-Lincoln.

“Maybe both of them had it because they diverged from a common ancestor that had it. Or maybe it evolved twice. It’s a really interesting concept from an evolutionary perspective.”

“We’re curious about whether and how epigenetics might explain why no known archaea cause disease or wage antibiotic-armed warfare against their brethren, as bacteria do,” Professor Blum said.

“There are no antibiotics going on in that world. Why is that? We’re thinking (that) it’s got something to do with epigenetics, and so their interactions among each other are fundamentally different than bacteria.”

“The discovery also introduces an even broader question. What was the benefit for them to have this? We don’t know.”

The findings appear in the Proceedings of the National Academy of Sciences.

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Sophie Payne et al. 2018. Nonmutational mechanism of inheritance in the archaeon Sulfolobus solfataricus. PNAS 115 (48): 12271-12276; doi: 10.1073/pnas.1808221115

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