Compiled by Jim Haseloff at the University of Cambridge.
This site contains details of recent papers and activity in Synthetic Biology, with particular emphasis on: (i) development of standards in biology and DNA parts, (ii) microbial and (iii) plant systems, (iv) research and teaching in the field at the University of Cambridge, (v) hardware for scientific computing and instrumentation, (vi) tools for scientific productivity and collected miscellany.
Technology is driving revolutionary changes in biology. Over the past decade, scientists and engineers have begun to define the path forward in the genomic era. Systems Biology has arisen...
Now that we know the sequences of many genomes, from a wide variety of organisms and even from individuals with unique characteristics, many researchers have turned to making intentional...
The developments within synthetic biology promise to change the world in significant ways. Yet synthetic biology is largely unrecognized within conservation. The purpose of the meeting...
(Re-)constructing and Re-programming Life This conference will provide an in-depth discussion forum among practitioners of the various fields underlying Synthetic Biology. It aims to...
The BioBricks Foundation is pleased to announce The BioBricks Foundation Synthetic Biology 6.0 Conference (SB6.0), which will take place on July 9-11, 2013 at Imperial College, London,...
This course will focus on how the complexity of biological systems, combined with traditional engineering approaches, results in the emergence of new design principles for synthetic...
Biotechnol J. 2011 Feb 16;
Authors: Krivoruchko A, Siewers V, Nielsen J
Constant progress in genetic engineering has given rise to a number of promising areas of research that facilitated the expansion of industrial biotechnology. The field of metabolic engineering, which utilizes genetic tools to manipulate microbial metabolism to enhance the production of compounds of interest, has had a particularly strong impact by providing new platforms for chemical production. Recent developments in synthetic biology promise to expand the metabolic engineering toolbox further by creating novel biological components for pathway design. The present review addresses some of the recent advances in synthetic biology and how these have the potential to affect metabolic engineering in the yeast Saccharomyces cerevisiae. While S. cerevisiae for years has been a robust industrial organism and the target of multiple metabolic engineering trials, its potential for synthetic biology has remained relatively unexplored and further research in this field could strongly contribute to industrial biotechnology. This review also addresses are general considerations for pathway design, ranging from individual components to regulatory systems, overall pathway considerations and whole-organism engineering, with an emphasis on potential contributions of synthetic biology to these areas. Some examples of applications for yeast synthetic biology and metabolic engineering are also discussed.
PMID: 21328545 [PubMed - as supplied by publisher]
(Via pubmed: "synthetic biology".)