ExxonMobil doubled oil production from algae in biofuel breakthrough

algae
Photo — Synthetic Genomics’ scientists use advanced cell engineering technologies

Previous attempts to increase algae oil production volume were hindered due to slow growth

ExxonMobil and Synthetic Genomics Inc. announced a breakthrough into advanced biofuels involving the modification of an algae strain that more than doubled its oil content without significantly inhibiting the strain’s growth, according to a press release.

Using advanced cell engineering technologies at Synthetic Genomics, the ExxonMobil-Synthetic Genomics research team modified an algae strain to enhance the algae’s oil content from 20 per cent to more than 40 per cent.

Results of the research were published today in the peer-reviewed journal Nature Biotechnology by lead authors Imad Ajjawi and Eric Moellering of Synthetic Genomics.

algae

Researchers at Synthetic Genomics’ laboratory in La Jolla discovered a new process for increasing oil production by identifying a genetic switch that could be fine-tuned to regulate the conversion of carbon to oil in the algae species, Nannochloropsis gaditana.

“This key milestone in our advanced biofuels program confirms our belief that algae can be incredibly productive as a renewable energy source with a corresponding positive contribution to our environment. Our work with Synthetic Genomics continues to be an important part of our broader research into lower-emission technologies to reduce the risk of climate change,” said Vijay Swarup, VP research and development at ExxonMobil.

The team established a proof-of-concept approach that resulted in the algae doubling its lipid fraction of cellular carbon compared to the parent – while sustaining growth.

Algae has been regarded as a potential sustainable fuel option, but researchers have been hindered for the past decade in developing a strain that is high in oil content and grows quickly – two critical characteristics for scalable and cost-efficient oil production.

Slower growth has been an adverse effect of previous attempts to increase algae oil production volume.

“The major inputs for phototropic production are sunlight and carbon dioxide, two resources that are abundant, sustainable and free. Discoveries made through our partnership with ExxonMobil demonstrate how advanced cell engineering capabilities at Synthetic Genomics can unlock biology to optimize how we use these resources and create solutions for many of today’s sustainability challenges – from renewable energy to nutrition and human health,” said said Oliver Fetzer, Ph.D., CEO at Synthetic Genomic.

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A key objective of the ExxonMobil-Synthetic Genomics collaboration has been to increase the lipid content of algae while decreasing the starch and protein components without inhibiting its growth.

Limiting availability of nutrients such as nitrogen is one way to increase oil production in algae, but it can also dramatically inhibit or even stop photosynthesis, stunting algae growth and ultimately the volume of oil produced.

The ability to sustain growth while increasing oil content is an important advance. Algae has other advantages over traditional biofuels because it can grow in salt water and thrive in harsh environmental conditions, therefore limiting stress on food and fresh water supplies.

Oil from algae can also potentially be processed in conventional refineries, producing fuels no different from convenient, energy-dense diesel.

It also holds promise as a potential feedstock for chemical manufacturing.

Since 2009, ExxonMobil and Synthetic Genomics have been partners in researching and developing oil from algae to be used as a renewable, lower-emission alternative to traditional transportation fuels.

Swarup said that while the breakthrough is an important step, the technology is still many years from potentially reaching the commercial market.

“Advancements as potentially important as this require significant time and effort, as is the case with any research and development project. Each phase of our algae research, or any other similar project in the area of advanced biofuels, requires testing and analysis to confirm that we’re proceeding down a path toward scale and commercial viability,” concluded Swarup.

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