1. Synthetic Biology Risks and opportunities of an emerging field Constructing Life

2. 1. Ultimate reductionism! If we view life as a machine, then we can also make it: this is the revolutionary nature of synthetic biology. Synthetic biologists want to design new life and construct this from scratch.

3. （圖片來源：紐約時報）

4. What is synthetic biology? Synthetic biology is defined as the design and construction of new biological parts, devices, and systems and the re-design of existing, natural biological systems for useful purposes Synthetic biology has been described as ‘the engineer’s approach to biology’

5. Possible abstraction hierarchy in biological systems

6. Relationship to systems biology Systems biology makes use of computational tools and mathematical modeling in an attempt to integrate and analyse the vast amounts of data that have been generated by genome sequencing and other high through-put data gathering projects.

8. Relationship to systems biology Synthetic biology tries to build an actual functioning synthetic biological system from a systems biology model and proves the model is correct.

9. Picture encoded on E. coli biofilm

10. DNA sequencing and synthesis A more specific development which has contributed directly to the emergence of synthetic biology is the increasing speed and ease of gene synthesis

11. Chain-termination methods

12. Single-Molecule DNA Sequencing

14. Polymerase cycling assembly http://en.wikipedia.org/wiki/Polymerase_cycling_assembly

15. 2. Types of synthetic biology

16. DNA-based device construction These biological components are interchangeable, functionally discrete and capable of being easily combined in a modular fashion. This results in the creation of standardized biological parts, devices and systems, called ‘BioBricks’, such as logic gates and oscillators.

17. The construction of a repressilator Michael B. Elowitz and Stanislas Leibler; Nature. 2000 Jan 20;403(6767):335-8. Retrieved from "http://en.wikipedia.org/wiki/Repressilator"http://en.wikipedia.org/wiki/Repressilator

18. The repressilator in Escherichia coli.

19. A classical genetic inverter device

20. A PoPS inverter device

21. Genome-driven cell engineering ‘top down’ attempts: to strip excess DNA away from existing genomes to make more efficient ‘chassis’. ‘bottom up’ attempts: to construct genomes from scratch, including the synthesis of viral genomes such as the polio virus, and the φX174 phage.

24. Protocell creation This approach is more interested in trying to recreate living cells. This often involves inserting molecular components into lipid vesicles.

27. 3. Scientific developments and likely applications

28. Environmental applications Bioremediation. Microorganisms or even plants could be engineered to degrade pesticides and remove pollutants

30. New drug development pathways. The construction of an artificial metabolic pathway in E. coli and yeast to produce a precursor (arteminisin) for an antimalarial drug.

32. Industrial applications Biofuels. Bacteria could be engineered to synthesize hydrogen or ethanol by degrading cellulose. Plants and algae could also be engineered to produce biodiesel.