This is a transmission electron micrograph of a strain of proteobacteria that has been exposed to arsenic in place of phosphorus. The bacteria grew much larger with the addition of arsenic and the subtraction of phosphorus, and scientists think the internal vacuole-like structures shown in this image may be responsible for the larger size. Courtesy Science/AAAS

Two new studies appearing today attempted to recreate a controversial December 2010 study by Felisa Wolfe-Simon and others, who fed the bacteria a cocktail of arsenic and deprived it of phosphorus. GFAJ-1 is found in California’s Mono Lake, which contains arsenic-rich sediments. All of life uses six elements: oxygen, carbon, hydrogen, nitrogen, phosphorus and sulfur. Arsenic is chemically similar to phosphorus, but it’s toxic. Wolfe-Simon’s results indicated that at least one form of life could buck this trend and survive using arsenic.

Today in Science, Tobias Erb and colleagues at the Institute of Microbiology at ETH Zurich show that it can indeed grow under high-arsenate and low-phosphate conditions, but it needs at least a little bit of phosphate to grow at all. In Wolfe-Simon’s original paper, the authors noted the presence of a small amount of phosphorus, but concluded it was too little to sustain the organisms. This is incorrect, according to Erb et al. The small amounts of phosphorus were indeed enough to keep the bacteria alive.

The Swiss team also found some arsenate-based compounds in the growth medium, but they determined that these formed abiotically. The small amount of arsenate metabolites that GFAJ-1 formed were negligible for sustaining life, they say.

“The new research shows that GFAJ-1 does not break the long-held rules of life, contrary to how Wolfe-Simon had interpreted her group’s data,” says a statement from Science, which took flak for publishing the controversial paper in a firestorm of controversy. The journal later published eight technical comments scrutinizing Wolfe-Simon’s research methods.

For her part, Wolfe-Simon said in an email that the very small amounts of arsenate metabolites may help the organisms survive in environments with lots of arsenic.

"Key questions are, how do these cells thrive in lethal concentrations of arsenic? And where does the arsenic go?" she said.