Tag Archives: DARPA Living Foundries

Synthetic Biology and DARPA

silica

Twist Bioscience announced that it raised $26 million in a Series B financing to commercialize the company’s semiconductor-based synthetic gene manufacturing process. Nick and Joby Pritzker, through their family’s firm Tao Invest, led the round, with participation from ARCH Venture Partners, Paladin Capital Group, Yuri Milner and additional strategic corporate and venture investors. All existing investors participated in the round.

The company also received a $5.1 million contract from the Defense Advanced Research Projects Agency (DARPA) to fund development of Twist’s technology platform for the large-scale, high-throughput construction of genetic designs. DARPA granted the contract under the Living Foundries: 1000 Molecules Program, which seeks to build a scalable, integrated, rapid design and prototyping infrastructure for the facile engineering of biology…

Said Emily Leproust, Ph.D., chief executive officer of Twist Bioscience. “Today, we have all the necessary components in place to automate and scale our synthetic gene manufacturing process and staff strategically, with the goal of bringing our first products and services to the market in 2015.”

According to to Twist Bioscience “At Twist Bioscience, our expertise is synthetic DNA. We have developed a proprietary semiconductor-based synthetic DNA manufacturing process featuring a 10,000-well silicon platform capable of producing synthetic biology tools, such as oligonucleotides, genes, pathways, chassis and genomes. By synthesizing DNA on silicon instead of on traditional 96-well plastic plates, our platform overcomes the current inefficiencies of synthetic DNA production, and enables cost-effective, rapid, high-quality and high throughput synthetic gene production. The Twist Bioscience platform has the potential to greatly accelerate the development of personalized medicine, sustainable chemical production, improved agriculture production as well as new applications such as in vivo diagnostics, biodetection and data storage. 

Twist Bioscience Secures $31.1 Million,  PRESS RELEASE, May 27, 2014

See also DARPA and Industrial Revolution in Genetic Engineering

See also DARPA Biological Technologies Office

The Biological Technologies Office of DARPA

Image from wikipedia

From the DARPA website

The mission of the Biological Technologies Office (BTO) is to foster, demonstrate, and transition breakthrough fundamental research, discoveries, and applications that integrate biology, engineering, and computer science for national security. BTO seeks to establish and invest in new communities of scientific interest at the intersection of traditional and emerging disciplines. Its investment portfolio goes far beyond life sciences applications in medicine to include areas of research such as human-machine interfaces, microbes as production platforms, and deep exploration of the impact of evolving ecologies and environments on U.S. readiness and capabilities. BTO’s programs operate across a wide range of scales, from individual cells to complex biological systems including mammalian and non-mammalian organisms and the macro- and micro-environments in which they operate.

BTO Focus Areas

Restore and Maintain Warfighter Abilities Military readiness depends on the health and wellbeing of military service members. A critical part of BTO’s mission is to cultivate new discoveries that help maintain peak warfighter abilities and restore those abilities as quickly and fully as possible when they are degraded or lost. This focus area is grounded in the development of new techniques and therapeutic strategies for addressing current and emerging threats, but extends beyond medical applications to include exploration of complex biological issues that can impact an individual’s ability to operate and interact in the biological and physical world. The research portfolio includes neuroscience to drive a deeper understanding of the human brain, how it interfaces with the body and the external world, and how it directs and coordinates behavior, including decision-making in demanding environs. BTO will extend work involving human participants and apply insights from physiology, biochemistry, psychology, sociology, and related sciences to such emerging-science domains as bioengineering, bioinformatics, and microbiomics.

Harness Biological Systems The highly evolved functional and synthetic capabilities of biological systems can be harnessed to develop new products and systems in support of national security with advantages over what even the most advanced conventional chemistry and manufacturing technologies can achieve. This space and its opportunities are just becoming tangible due to the rapid, simultaneous development of genome-scale engineering tools, enormous genomic datasets, new analytical capabilities, and the convergence of several engineering and scientific disciplines with biology. BTO seeks to establish a fundamental understanding of natural processes and the underlying design rules that govern the behavior of biological systems, and apply that knowledge to forward-engineer new systems and products with novel functionality. To support this work, BTO develops techniques at the intersection of automation, computer science, and biology to explore biological data at massive scales.

Apply Biological Complexity at Scale Biological systems operate over an enormous range of spatial, physical, and temporal scales. Some organisms thrive as individual cells, while many others, including humans, are colonized by communities of foreign cells that greatly outnumber their own and have potentially significant but still largely mysterious impacts on metabolism, psychological state, performance, and health. Disease vectors migrate around the globe slowly and stealthily at times, and at other times in devastating waves of breathtaking speed—poorly understood dynamics that can threaten national security. And because they are so difficult to parse from larger biological and ecological phenomena, population-level effects of relevance to agriculture and food security remain largely unplumbed. BTO is looking into pursuing new insights derived from biological complexity and living-system dynamics with the goal of developing applications to enhance global-scale stability and human wellbeing.

See also http://www.darpa.mil/Our_Work/BTO/Programs/

See also DARPA Pushes for Industrial Revolution in Genetic Engineering

DARPA Pushes for Industrial Revolution in Genetic Engineering

From DARPA’s Website: Living Foundries

[Current State of Bio-engineering]

Current approaches to engineering biology rely on an ad hoc, laborious, trial-and-error process, wherein one successful project often does not translate to enabling subsequent new designs. As a result, the state of the art development cycle for engineering a new biologically manufactured product often takes 7+ years and tens to hundreds of millions of dollars (e.g. microbial production of artemisinic acid for the treatment of malaria and the non-petroleum-based production 1,3-propanediol).

[DARPA Goal]

Transforming biology into an engineering practice would enable on-demand production of new and high-value materials, devices and capabilities for the Department of Defense (DoD) and address complex challenges that today have no or few solutions.

The Living Foundries Program seeks to create the engineering framework for biology, speeding the biological design-build-test cycle and expanding the complexity of systems that can be engineered. The Program aims to develop new tools, technologies and methodologies to decouple biological design from fabrication, yield design rules and tools, and manage biological complexity through abstraction and standardization. These foundational tools would enable the rapid development of previously unattainable technologies and products, leveraging biology to solve challenges associated with production of new materials, novel capabilities, fuel and medicines. For example, one motivating, widespread and currently intractable problem is that of corrosion/materials degradation. The DoD must operate in all environments, including some of the most corrosively aggressive on Earth, and do so with increasingly complex heterogeneous materials systems. This multifaceted and ubiquitous problem costs the DoD approximately $23 Billion per year. The ability to truly program and engineer biology, would enable the capability to design and engineer systems to rapidly and dynamically prevent, seek out, identify and repair corrosion/materials degradation.

Accomplishing this vision requires an approach that is more than multidisciplinary – it requires a new engineering discipline built upon the integration of new ideas, approaches and tools from fields spanning computer science and electrical engineering to chemistry and the biological sciences. The best innovations will introduce new architectures and tools into an open technology platform to rapidly move new designs from conception to execution.  Performers must ensure and demonstrate throughout the program that all methods and demonstrations of capability comply with national guidance for manipulation of genes and organisms and follow all guidance for biological safety and Biosecurity.

A Broad Agency Announcement (BAA) solicitation for phase one, Advanced Tools and Capabilities for Generalizable Platforms (ATCG), closed in November, 2011. The BAA called for the development of the advanced, translatable tools and capabilities that will make up an end-to-end technology platform for rapidly, safely and predictably engineering biological production systems. The goals of these advanced tools and capabilities are to compress the biological design-build-test cycle by at least 10x in both time and cost while increasing the complexity of the systems that can be designed and executed by orders of magnitude. These advancements should enable the ability to rapidly design and build new systems to create novel capabilities and to address complex challenges.

See Amyris