Fluorescent biosensors light up high-throughput metabolic engineering
Boston – Synthetic biologists are learning to turn microbes and unicellular organisms into highly productive factories by re-engineering their metabolism to produce valued commodities such as fine chemicals, therapeutics and biofuels. To speed up identification of the most efficient producers, researchers at Harvard's Wyss Institute for Biologically Inspired Engineering describe new approaches to this process and demonstrate how genetically encoded fluorescent biosensors can enable the generation and testing of billions of individual variants of a metabolic pathway in record time. The discussion and findings are reported in Trends in Biotechnology and the Proceedings of the National Academy of Sciences (PNAS).
Biotechnologists that tinker with the metabolism of microorganisms to produce valued products look at the engineering process through the lens of the so-called 'design-build-test cycle.' The idea is that multiple iterations of this cycle ultimately allow the identification of combinations of genetic and metabolic elements that produce the highest levels of a desired drug or chemical. Key to the cycle's efficiency, however, is the ability to construct and test the largest number of variants possible; in the end, only a few of these variants will produce the product in industrially attractive amounts.
In the Trends in Biotechnology article, Wyss Institute scientists George Church and Jameson Rogers lay out the current state-of-the-art for designing, building and testing many variants at a time, a methodology that bioengineers call 'multiplexing'. Church is a Wyss Core Faculty member and Professor of Genetics at Harvard Medical School and Rogers, currently with the Boston Consulting Group, performed his work as a Harvard Pierce Fellow and Doctoral Student mentored by Church.
Bioengineers thoroughly understand how metabolic pathways work on the biochemical level and have a plethora of DNA sequences encoding variants of all of the necessary enzymes at their disposal. Deploying these sequences with the help of computational tools and regulating their expression with an ever-growing number of genetic elements, gives them access to an almost infinite pool of design possibilities. Similarly, revolutionary advances in technologies enabling DNA synthesis and manipulation have made the construction of billions of microorganisms, each containing a distinct design variant, a routine process.
"The real bottleneck in achieving high-throughput engineering cycles lies in the testing step. Current technology limits the number of designs scientists can evaluate to hundreds, or maybe even a thousand, different designs per day. Often the assays necessary are painstaking and prone to user error," said Rogers.
Church and Rogers discuss how genetically encoded biosensors can help bioengineers overcome this hurdle. Such biosensors work by coupling the amount of a desired product produced within a microorganism to the expression of an antibiotic resistance gene such that only high producers survive. Alternatively, the expression of a fluorescent protein can be used for high-speed sorting of rare but highly productive candidates from large populations of less productive microbes.
"Now, by having developed both types of genetically encoded biosensors we can close the loop of a fully multiplexed engineering cycle. This enables exploration of design spaces for specific metabolic pathways in much greater breadth and depth. Fluorescent biosensors, in particular, enable a brand new type of pipeline engineering in which we can observe metabolic product levels at all times during the process with extraordinary sensitivity and ability to further manipulate the engineering cycle," said Church.
Earlier work by Church's team at the Wyss Institute already demonstrated that the levels of commercially valuable chemicals produced by bacteria could be raised through several rounds of a design-build-test cycle that employed an antibiotic selection-based biosensor. Now, Church and Rogers report in PNAS the unique advantages that fluorescent biosensors provide to bioengineers.
"Our fluorescent biosensors are built around specialized proteins that directly sense commercially valuable metabolites. These sensor proteins switch on the expression of a fluorescent reporter protein, resulting in cellular brightness that is proportional to the amount of chemical produced within the engineered cells. We can literally watch the biological production of valuable chemicals in real-time as the synthesis occurs and isolate the highest producers out of cultures with billions of candidates," said Rogers, who was named one of Forbes' "30 Under 30" in Science for opening new perspectives in bioengineering.
Using this strategy, the Wyss researchers have established fluorescent biosensors for the production of super-absorbent polymers and plastics like the coveted acrylate from which a range of products is made. In fact, the study established the first engineered pathway able to biologically produce acrylate from common sugar, rather than the previously required petroleum compounds.
"This newly emerging biosensor technology has the potential to transform metabolic engineering in areas ranging from industrial manufacturing to medicine, and it can have a positive impact on our environment by making the production of drugs and chemicals independent from fossil fuels," said Wyss Institute Founding Director Donald Ingber, M.D., Ph.D., who is the Judah Folkman Professor of Vascular Biology at HMS and the Vascular Biology Program at Boston Children's Hospital, as well as Professor of Bioengineering at the Harvard John A. Paulson School of Engineering and Applied Sciences.
Wyss Institute for Biologically Inspired Engineering at Harvard University
Benjamin Boettner, [email protected], +1 917-913-8051
Wyss Institute for Biologically Inspired Engineering at Harvard University
Seth Kroll, [email protected], +1 617-432-7758
The Wyss Institute for Biologically Inspired Engineering at Harvard University uses Nature's design principles to develop bioinspired materials and devices that will transform medicine and create a more sustainable world. Wyss researchers are developing innovative new engineering solutions for healthcare, energy, architecture, robotics, and manufacturing that are translated into commercial products and therapies through collaborations with clinical investigators, corporate alliances, and formation of new startups. The Wyss Institute creates transformative technological breakthroughs by engaging in high risk research, and crosses disciplinary and institutional barriers, working as an alliance that includes Harvard's Schools of Medicine, Engineering, Arts & Sciences and Design, and in partnership with Beth Israel Deaconess Medical Center, Brigham and Women's Hospital, Boston Children's Hospital, Dana-Farber Cancer Institute, Massachusetts General Hospital, the University of Massachusetts Medical School, Spaulding Rehabilitation Hospital, Boston University, Tufts University, Charité – Universitätsmedizin Berlin, University of Zurich and Massachusetts Institute of Technology.
Harvard Medical School has more than 7,500 full-time faculty working in 11 academic departments located at the School's Boston campus or in one of 47 hospital-based clinical departments at 16 Harvard-affiliated teaching hospitals and research institutes. Those affiliates include Beth Israel Deaconess Medical Center, Brigham and Women's Hospital, Cambridge Health Alliance, Boston Children's Hospital, Dana-Farber Cancer Institute, Harvard Pilgrim Health Care, Hebrew Senior Life, Joslin Diabetes Center, Judge Baker Children's Center, Massachusetts Eye and Ear Infirmary, Massachusetts General Hospital, McLean Hospital, Mount Auburn Hospital, Schepens Eye Research Institute, Spaulding Rehabilitation Hospital and VA Boston Healthcare System.