Covered in rivers and lakes of liquid methane, icy boulders and dunes of soot-like “sand,” Saturn’s moon Titan has long fascinated scientists and invited speculation on whether lifeforms might lurk beneath its thick, hazy atmosphere.
An international team of researchers set out to develop a realistic scenario of what life on Saturn’s moon might look like if life does exist, where it is most likely to occur and how much of it might be present.
“In our study, we focus on what makes Titan unique when compared to other icy moons: its plentiful organic content,” explained Antonin Affholder from the University of Arizona Department of Ecology and Evolutionary Biology and lead author of the study.
Evidence for a small amount of life in Titan’s ocean
Using bioenergetic modelling, the team found that Titan’s subsurface ocean, estimated to be as deep as about 300 miles, may support lifeforms that consume organic material.
They discovered that while Titan could possibly harbour simple, microscopic life, it likely could support only a few pounds of biomass overall.
Often described as “Earthlike on the surface, ocean world on the inside”, Titan is the target for future exploration via NASA’s Dragonfly mission. While researchers have speculated about possible scenarios that could give rise to living organisms on Titan based on its abundant organic chemistry, previous estimates have suffered from what Affholder considers an overly simplistic approach.
“There has been this sense that because Titan has such abundant organics, there is no shortage of food sources that could sustain life,” he said.
“We point out that not all of these organic molecules may constitute food sources; the ocean is really big, and there’s limited exchange between the ocean and the surface, where all those organics are, so we argue for a more nuanced approach.”
Back to basics with fermentation
At the core of the research lies a back-to-basics approach that attempted to come up with a plausible scenario for life on Saturn’s moon, which assumed one of the simplest and most remarkable of all biological metabolic processes: fermentation.
Familiar to those on Earth for its use in sourdough breadmaking, beer brewing and its role in spoiling forgotten leftovers, fermentation only requires organic molecules but no “oxidant” such as oxygen, a crucial requirement for other metabolic processes such as respiration.
Affholder said: “Fermentation probably evolved early in the history of Earth’s life and does not require us to open any door into unknown or speculative mechanisms that may or may not have happened on Titan.
“We asked if similar microbes could exist on Titan. If so, what potential does Titan’s subsurface ocean have for a biosphere feeding off of the seemingly vast inventory of abiotic organic molecules synthesised in Titan’s atmosphere, accumulating at its surface and present in the core?”
Only a small amount of Titan’s microbes could support life
The researchers specifically focused on one organic molecule, glycine, the simplest of all known amino acids.
“We know that glycine was relatively abundant in any sort of primordial matter in the Solar System,” Affholder stated. “When you look at asteroids, comets, the clouds of particles and gas from which stars and planets like our Solar System form, we find glycine or its precursors in pretty much all those places.”
However, computer simulations revealed that only a small fraction of organic material on Saturn’s moon may be suitable for microbial consumption. Glycine-consuming microbes in Titan’s ocean would depend on a steady supply of the amino acid from the surface through the thick icy shell.
Previous work by the same team had shown that meteorites impacting the ice could leave behind “melt pools” of liquid water, which then sink through the ice and deliver surface materials to the ocean.
Overall, the new study shows that this supply may only be sufficient to sustain a very small population of microbes weighing a total of only a few kilogrammes at most – equivalent to the mass of a small dog. Such a tiny biosphere would average less than one cell per litre of water over Titan’s entire vast ocean.
Knowledge for future missions to Saturn’s moon
For a future mission to Saturn’s moon, the odds of finding life – if it is indeed there – could be like looking for a needle in a haystack, unless Titan’s potential for life is to be found elsewhere than in its surface organic content, the team suggests.
“We conclude that Titan’s uniquely rich organic inventory may not in fact be available to play the role in the moon’s habitability to the extent one might intuitively think,” Affholder concluded.
