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10/02/2018 - ‘Spacesuits’ Protect Microbes Destined to Live in Space

(Originally published by The University of California, Berkeley)

October 1, 2018

A 2D MOF wraps around the bacteria to form a soft cloak that expands as the bacteria grow and split. The MOF protects them from oxygen, the reverse of a spacesuit, which protects astronauts from the airlessness of space.A 2D MOF wraps around the bacteria to form a soft cloak that expands as the bacteria grow and split. The MOF protects them from oxygen, the reverse of a spacesuit, which protects astronauts from the airlessness of space.

Just as spacesuits help astronauts survive in inhospitable environments, newly developed “spacesuits” for bacteria allow them to survive in environments that would otherwise kill them.

University of California, Berkeley, chemists developed the protective suits to extend the bacteria’s lifespan in a unique system that pairs live bacteria with light-absorbing semiconductors in order to capture carbon dioxide and convert it into chemicals that can be used by industry or, someday, in space colonies.

The system mimics photosynthesis in plants. But while plants capture carbon dioxide and, with the energy from sunlight, convert it to carbohydrates that we often eat, the hybrid system captures CO2 and light to make a variety of carbon compounds, depending on the type of bacteria.

The bacteria used in the experiment are anaerobic, which means they are adapted to live in environments without oxygen. The suit – a patchwork of mesh-like pieces called a metal-organic framework, or MOF – is impermeable to oxygen and reactive oxygen molecules, like peroxide, which shorten their lifespan.

The hybrid system could be a win-win for industry and the environment: It can capture carbon dioxide emitted by power plants and turn it into useful products. It also provides a biological way to produce needed chemicals in artificial environments such as spaceships and habitats on other planets.

“We are using our biohybrid to fix CO2 to make fuels, pharmaceuticals and chemicals, and also nitrogen fixation to make fertilizer,” said Peidong Yang, the S. K. and Angela Chan Distinguished Chair in Energy in UC Berkeley’s Department of Chemistry. “If Matt Damon wants to grow potatoes on Mars, he needs fertilizer.”

Yang, a faculty scientist at Lawrence Berkeley National Laboratory and a co-director of the Kavli Energy NanoScience Institute (Kavli ENSI), was referring to the actor who played the protagonist in the movie The Martian. Damon’s character was marooned on Mars and had to use his own waste as fertilizer to grow potatoes for food.

The research, funded by NASA through UC Berkeley’s Center for the Utilization of Biological Engineering in Space, will be posted online this week in advance of publication in the journal Proceedings of the National Academy of Sciences.

A hybrid of bacteria and semiconductor

When fed cadmium, the bacterium Moorella thermoacetica decorates itself with cadmium sulfide particles that absorb light, creating a hybrid artificial photosynthesis system that converts sunlight and carbon dioxide into valuable chemical products.When fed cadmium, the bacterium Moorella thermoacetica decorates itself with cadmium sulfide particles that absorb light, creating a hybrid artificial photosynthesis system that converts sunlight and carbon dioxide into valuable chemical products.

Yang and his colleagues developed the hybrid bacterial system over the past five years based on their work on light-absorbing semiconductors such as nanowires: solid wires of silicon a few hundred nanometers across, where a nanometer is a billionth of a meter. Arrays of nanowires can be used to capture light and generate electricity, promising cheap solar cells.

The hybrid system takes advantage of efficient light capture by semiconductors to feed electrons to anaerobic bacteria, which normally scavenge electrons from their environment to live. The goal is to boost carbon capture by the bacteria to churn out useful carbon compounds.

“We are interfacing these bugs with a semiconductor that overwhelms them with electrons, so they can do more chemistry,” Yang said. “But at the same time this process also generates all these reactive oxygen species, which are detrimental to the bugs. We are putting these bacteria in a shell so that if any of these oxidative species comes in, this first defense, the shell, decomposes them.”

The suit is made of a MOF mesh that wraps around the bacteria, covering it in patches. Wearing these MOF suits, the bacteria live five times longer at normal oxygen concentrations – 21 percent by volume – than without the suits, and often longer than in their natural environment, Yang said. Their normal lifespan ranges from weeks to months, after which they can be flushed from the system and replaced with a fresh batch.

In this experiment, the researchers used bacteria called Morella thermoacetica, which produce acetate (acetic acid, or vinegar), a common precursor in the chemical industry. Another one of their test bacteria, Sporomusa ovata, also produces acetate.

“We picked these anaerobic bacteria because their selectivity toward one chemical product is always 100 percent,” he said. “In our case, we picked a bug that gives us acetate. But you could select another bug to give you methane or alcohol.”

In fact, the bacteria that ferment the alcohol in beer and wine and turn milk into cheese and yoghurt are all anaerobic.

While Yang’s first experiments with the hybrid system paired bacteria with a bristle of silicon nanowires, in 2016 he discovered that feeding the bacteria cadmium encouraged them to decorate themselves with a natural semiconductor, cadmium sulfide, that acts as an efficient light absorber feeding the bacteria electrons.

In the current experiment, the researchers took bacteria decorated with cadmium sulfide and enshrouded them with a flexible, one-nanometer thick layer of MOF. While a rigid MOF interfered with the bacteria’s normal process of growth and splitting, a zirconium-based MOF patch turned out to be soft enough to allow the bacteria to swell and divide while still clothed with MOF, after which new MOF in the solution re-clothed them.

“You can think of the 2D MOF like a sheet of graphene: a one-layer-thick cloak that covers the bacteria,” said co-author Omar Yaghi, a pioneer of MOFs, the James and Neeltje Tretter Chair in the Department of Chemistry and co-director of Kavli ENSI. “The 2D MOF is floating in solution with the bacteria, and as the bacteria replicate they are covered further with the 2D MOF layer, so it protects the bacteria from oxygen.”

Yang and his colleagues are also working to improve the hybrid system’s efficiency of light capture, electron transfer and production of specific compounds. They envision combining these optimized capabilities with new metabolic pathways in these bacteria to produce ever more complex molecules.

“Once you fix or activate CO2 – and that is the most difficult part – you can use many existing chemical and biological approaches to upgrade them to fuels, pharmaceuticals and commodity chemicals,” he said.

Co-authors with Yang and Yaghi are UC Berkeley graduate students Zhe Ji and Hao Zhang and former postdoctoral fellow Hao Liu, now at Donghua University in Shanghai, China.

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