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1. Biosecurity Assessments for Emerging Transdisciplinary Biotechnologies: Revisiting Biodefense in an Age of Synthetic Biology

   https://doi.org/10.1089/apb.2024.0005  

   DiEuliis, Diane; Imperiale, Michael J; Berger, Kavita M (September 2024, Applied Biosafety)

   Byers, Karen B; Johnson, Barbara (Ed.)

   Introduction: Rapid advances in biotechnologies and transdisciplinary research are enhancing the ability to perform full-scale engineering of biology, contributing to worldwide efforts to create bioengineered plants, medicines, and commodities, which promise sustainability and innovative properties. Objective: This rapidly evolving biotechnology landscape is prompting focused scrutiny on biosecurity frameworks in place to mitigate harmful exploitation of biotechnology by state and non-state actors. Concerns about biosafety and biosecurity of engineering biology research have existed for decades as views about how advances in this and associated fields might provide new capabilities to malicious actors. This article considers biosecurity concerns using examples of research advances in engineering biology. Methods: The authors explore risk assessment and mitigation of transdisciplinary biotechnology research and development, using the framework developed in the National Academies' study on Biodefense in an Age of Synthetic Biology. Results: The Synthetic Biology Assessment Framework focuses on risks of using advanced approaches and technologies to enhance or create novel pathogens and toxins. The field of engineering biology continues to advance at a pace that challenges current risk assessment frameworks. Conclusions: This framework likely is sufficient to assess new science and technology advances affecting conventional biological agents. However, the risk assessment framework may have limited applicability for technologies that are not usable with conventional biological agents and result in economic or broader national security concerns. Finally, the vast majority of discourse has been focused primarily on risks rather than benefits, and analyzing both in future evaluations is critical to balancing scientific progress with risk reduction. 

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2. Intro to Synthetic Biology

   Sheets, Michael; Atkinson, Joshua (June 2023, Engineering Biology Research Consortium)

   About the slide set The slides are divided into sections (“Concepts”) including: What is engineering/synthetic biology? (Concept 1-1); the “Design, Build, Test, & Learn” cycle (Concept 1-2), Core Tools for engineering biology (Concepts 1-3 and 1-4), and finally exploring Impacts & Applications of engineering biology (Concept 1-5). The slides can be used as a complete lecture, or any concept topic can be used to supplement existing material. For example, Concept 1-1 could be used to introduce synthetic biology to professionals outside the field, or the Concept 1-5 Data Science section could be modified to show the intersections of the field in a computer science course. The slides are available to use under Creative Commons license CC BY-NC-SA. The goal of these slides is to provide free, accessible, and modular explanations of key Engineering Biology topics. EBRC provides this curricular module under a Creative Commons Attribution-NonCommercial-ShareAlike 2.0 license, which allows free use in noncommercial settings with credit for the material given to EBRC and the content authors. By downloading these resources, you agree to these terms. If you are interested in using EBRC material in a commercial setting or have other usage questions, please contact us at education@ebrc.org. The slides were created by Michael Sheets (Boston University) and Joshua Atkinson (Univ. of Southern California), with support from the EBRC Education Working Group. Audience These lecture slides are designed for educators looking to incorporate current synthetic & engineering biology practices into their teaching material. These slides were designed with a target audience of undergraduate and graduate students, but could be adapted for high school students (and coupled with BioBuilder material, for a great experience). Recommended student knowledge: “biology 101” level, generally how DNA & cells work Learning Objectives You will be able to answer: - What is synthetic/engineering biology? - How can I Design, Build, Test, and Learn from biological systems? - What are the Core Tools of engineering biology? - How and where can engineering biology be applied to positively impact society? You will have: Planned a design cycle to approach a current problem Learned about engineering biology tools that can help you develop your idea Discovered the many sectors that engineering biology can positively impact 

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3. Development of a Freeze-Dried CRISPR-Cas12 Sensor for Detecting Wolbachia in the Secondary Science Classroom

   https://doi.org/https://doi.org/10.1021/acssynbio.1c00503  

   Rybnicky, Grant A. (January 2022, ACS synthetic biology)

   Training the future synthetic biology workforce requires the opportunity for students to be exposed to biotechnology concepts and activities in secondary education. Detecting Wolbachia bacteria in arthropods using polymerase chain reaction (PCR) has become a common way for secondary students to investigate and apply recombinant DNA technology in the science classroom. Despite this important activity, cutting-edge biotechnologies such as clustered regularly interspaced short palindromic repeat (CRISPR)-based diagnostics have yet to be widely implemented in the classroom. To address this gap, we present a freeze-dried CRISPR-Cas12 sensing reaction to complement traditional recombinant DNA technology education and teach synthetic biology concepts. The reactions accurately detect Wolbachia from arthropod-derived PCR samples in under 2 h and can be stored at room temperature for over a month without appreciable degradation. The reactions are easy-to-use and cost less than $40 to implement for a classroom of 22 students including the cost of reusable equipment. We see these freeze-dried CRISPR-Cas12 reactions as an accessible way to incorporate synthetic biology education into the existing biology curriculum, which will expand biology educational opportunities in science, technology, engineering, and mathematics. 

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4. A new era of synthetic biology—microbial community design

   https://doi.org/10.1093/synbio/ysae011  

   Matuszyńska, Anna; Ebenhöh, Oliver; Zurbriggen, Matias D; Ducat, Daniel C; Axmann, Ilka M (January 2024, Synthetic Biology)

   Abstract Synthetic biology conceptualizes biological complexity as a network of biological parts, devices, and systems with predetermined functionalities and has had a revolutionary impact on fundamental and applied research. With the unprecedented ability to synthesize and transfer any DNA and RNA across organisms, the scope of synthetic biology is expanding and being recreated in previously unimaginable ways. The field has matured to a level where highly complex networks, such as artificial communities of synthetic organisms, can be constructed. In parallel, computational biology became an integral part of biological studies, with computational models aiding the unravelling of the escalating complexity and emerging properties of biological phenomena. However, there is still a vast untapped potential for the complete integration of modelling into the synthetic design process, presenting exciting opportunities for scientific advancements. Here, we first highlight the most recent advances in computer-aided design of microbial communities. Next, we propose that such a design can benefit from an organism-free modular modelling approach that places its emphasis on modules of organismal function towards the design of multispecies communities. We argue for a shift in perspective from single organism–centred approaches to emphasizing the functional contributions of organisms within the community. By assembling synthetic biological systems using modular computational models with mathematical descriptions of parts and circuits, we can tailor organisms to fulfil specific functional roles within the community. This approach aligns with synthetic biology strategies and presents exciting possibilities for the design of artificial communities. Graphical Abstract   

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5. Engineering tRNA abundances for synthetic cellular systems

   https://doi.org/10.1038/s41467-023-40199-9  

   Maheshwari, Akshay J.; Calles, Jonathan; Waterton, Sean K.; Endy, Drew (December 2023, Nature Communications)

   Abstract Routinizing the engineering of synthetic cells requires specifying beforehand how many of each molecule are needed. Physics-based tools for estimating desired molecular abundances in whole-cell synthetic biology are missing. Here, we use a colloidal dynamics simulator to make predictions for how tRNA abundances impact protein synthesis rates. We use rational design and direct RNA synthesis to make 21 synthetic tRNA surrogates from scratch. We use evolutionary algorithms within a computer aided design framework to engineer translation systems predicted to work faster or slower depending on tRNA abundance differences. We build and test the so-specified synthetic systems and find qualitative agreement between expected and observed systems. First principles modeling combined with bottom-up experiments can help molecular-to-cellular scale synthetic biology realize design-build-work frameworks that transcend tinker-and-test. 

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