Synthetic biology promises to create high-impact solutions to challenges in the areas of biotechnology, human/animal health, the environment, energy, materials and food security. Equally, synthetic biologists create tools and strategies that have the potential to help us answer important fundamental questions in biology. Warwick Integrative Synthetic Biology (WISB) pursues both of these mutually complementary ‘build to apply’ and ‘build to understand’ approaches. This is reflected in our research structure, in which a core theme on predictive biosystems engineering develops underpinning understanding as well as next-generation experimental/theoretical tools, and these are then incorporated into three applied themes in which we engineer biosynthetic pathways, microbial communities and microbial effector systems in plants. WISB takes a comprehensive approach to training, education and outreach. For example, WISB is a partner in the EPSRC/BBSRC-funded U.K. Doctoral Training Centre in synthetic biology, we have developed a new undergraduate module in the subject, and we have established five WISB Research Career Development Fellowships to support young group leaders. Research in Ethical, Legal and Societal Aspects (ELSA) of synthetic biology is embedded in our centre activities. WISB has been highly proactive in building an international research and training network that includes partners in Barcelona, Boston, Copenhagen, Madrid, Marburg, São Paulo, Tartu and Valencia.
[1]
Gürol M. Süel,et al.
Ion channels enable electrical communication in bacterial communities
,
2015,
Nature.
[2]
G. Rodrigo,et al.
Functionalization of an Antisense Small RNA
,
2016,
Journal of molecular biology.
[3]
Antonia P. Sagona,et al.
Genetically modified bacteriophages.
,
2016,
Integrative biology : quantitative biosciences from nano to macro.
[4]
Christian Rogers,et al.
Standards for plant synthetic biology: a common syntax for exchange of DNA parts.
,
2015,
The New phytologist.
[5]
Gürol M. Süel,et al.
Metabolic codependence gives rise to collective oscillations within biofilms
,
2015,
Nature.
[6]
Orkun S. Soyer,et al.
Challenges in microbial ecology: building predictive understanding of community function and dynamics
,
2016,
The ISME Journal.
[7]
P. Schäfer,et al.
Growth versus immunity--a redirection of the cell cycle?
,
2015,
Current opinion in plant biology.
[8]
Orkun S. Soyer,et al.
Microbial diversity arising from thermodynamic constraints
,
2016,
The ISME Journal.
[9]
Satya Prakash,et al.
Dynamic signal processing by ribozyme-mediated RNA circuits to control gene expression
,
2015,
bioRxiv.