This is how we could live on Mars

Tuesday 19 June 2018
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Scientists at The Australian National University (ANU) have contributed to an international study that will potentially help humans to colonise Mars and find life on other planets.

The study on an organism that survives in inhospitable and low-light conditions could dramatically improve our understanding of photosynthesis, the process by which plants and other organisms make and store energy from light and produce oxygen. 

ANU worked with research institutions in Italy, France and the United Kingdom to support London’s Imperial College, which led the study. 

Cyanobacteria are one of the largest groups of bacteria on Earth, where they have existed for more than 2.5 billion years.

ANU Emeritus Professor Elmars Krausz said low-light adapted cyanobacteria could be used to colonise Mars and other planets, to produce oxygen and create a biosphere.

“This might sound like science fiction, but space agencies and private companies around the world are actively trying to turn this aspiration into reality in the not-too-distant future,” said Professor Krausz, a co-author on the Science paper from the ANU Research School of Chemistry.

“Photosynthesis could theoretically be harnessed with these types of organisms to create air for humans to breathe on Mars.

“Low-light adapted organisms, such as the cyanobacteria we’ve been studying, can grow under rocks and potentially survive the harsh conditions on the red planet.”

Certain cyanobacteria have been found growing in environments such as Antarctica and the Mojave Desert – they have even survived on the outside of the International Space Station.

Co-author Jennifer Morton, a PhD scholar at the ANU Research School of Chemistry, said certain types of chlorophylls adapted to low-energy light were indeed vital pigments in photosynthesis both in harvesting light and driving photochemistry.

Ms Morton said studying red chlorophylls also provided clues as to where to find life on other planets.

“Searching for the signature fluorescence from these pigments could help identify extra-terrestrial life,” she said.

She said a key discovery was identifying a significantly different mechanism of photosynthesis that enhances the understanding of photosynthesis, more broadly.

“This work redefines the minimum energy needed in light to drive photosynthesis,” she said.

“This type of photosynthesis may well be happening in your garden, under a rock.”

The ANU researchers used their uniquely capable optical spectrometer system to analyse the role of the red chlorophylls in photosynthesis, and they are using computer modelling to further understand their roles.

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