The team's new study suggests that these versatile bacteria may play a more significant role in the biogeochemistry of the oceans, and thus global climate processes, than previously thought. Their findings are published this week in the prestigious international journal PNAS.

The researchers, who include Otago marine scientist Dr Federico Baltar, investigated a marine bacterium called Dokdonia which contains a light-absorbing pigment named proteorhodopsin (PR).

Marine bacteria are the most abundant organisms in the ocean, accounting for up to 90% of its global biomass, and up to half are thought to be PR-containing.

Dr Baltar says this pigment's existence in ocean bacteria was first discovered by other researchers in 2000, revealing a whole new class of micro-organisms capable of harnessing sunlight in the ocean through means other than photosynthesis.

To tease out the mechanisms underlying how such bacteria were using light to grow, he and his co-authors analysed gene expression in Dokdonia in light and dark and nutrient rich and nutrient poor conditions.

"We discovered that light profoundly affects Dokdonia's patterns of gene expression and metabolic activities, and that these responses are influenced by the availability of organic matter and its quality," Dr Baltar says.

The changes included that when they were exposed to light the bacteria switched to obtaining one-third of their cellular carbon from CO2.

"These bacteria's ability to use both inorganic and organic carbon to grow makes them remarkably flexible micro-organisms that can quickly adapt to the highly variable conditions in their ocean environment," he says.

Dr Baltar says the findings are the microbial equivalent of discovering that kittens lie in the sun not because they enjoy the warmth, but because they are using light energy for sustenance until their next meal.

More information: Joakim Palovaara, Neelam Akram, Federico Baltar, Carina Bunse, Jeremy Forsberg, Carlos Pedrós-Alió, José M. González, and Jarone Pinhassi. "Stimulation of growth by proteorhodopsin phototrophy involves regulation of central metabolic pathways in marine planktonic bacteria." PNAS 2014, DOI: 10.1073/pnas.1402617111