Synthetic Biology: Nanoscopic Cages for Big Applications
News Apr 18, 2013
The findings, published in Science and led by a multidisciplinary team of researchers from the University of Bristol, could potentially be used to deliver bioactive molecules, such as drugs, to cells and eventually diseased tissues in the body.
The research, led by Professor Dek Woolfson from the University's Schools of Chemistry and Biochemistry, describes how small protein molecules, known as peptides, can be designed from scratch to deliver a toolkit for constructing more-complex structures and materials. This is part of an emerging global effort to engineer biological systems more predictably and reliably, known as synthetic biology.
In the new work, the Bristol team has used parts from the toolkit to make larger hexagonal protein assemblies, which then piece themselves together to make protein sheets, resembling the pattern of hexagons in chicken wire. Curiously, the protein sheets then fold over on themselves and close to form hollow spheres.
These spheres are 100nm across - which equates to about one hundredth the width of a human hair - they are just one sheet of molecules thick, and they have nanometer-sized openings on their surfaces. They are in fact nanoscale cages, which the team call SAGEs. These have a number of potential practical applications. For instance, the team will be pursuing ideas such as using the SAGEs as the basis for new vaccines; to deliver bioactive molecules, such as drugs, to cells and eventually diseased tissues in the body; and to concentrate enzyme molecules to perform chemical reactions more efficiently and controllably.
Professor Woolfson said: "We are extremely excited by this new work. First of all, it has been fun bringing a really talented team from across the University together to do the research. Also, we are really looking forward to developing potential applications of the SAGEs. For this, we are going to grow the team and explore new areas in medicine and synthetic biology. It's going to be challenging to do this, but extremely interesting and hopefully rewarding."
Much of the work has been done by Dr Jordan Fletcher, a post-doctoral researcher in Prof Woolfson's lab.
The project has involved a multidisciplinary team of researchers from across the University. For example, images of the SAGEs using Scanning Electron Microscopy were collected by Dr Paul Verkade and Judith Mantell from the School of Biochemistry, while the hexagonal surface structure has been observed using advanced atomic force microscopy methods developed by Dr Rob Harniman, Dr Massimo Antognozzi and Professor Merv Miles from the School of Physics. Finally, the entire process of assembly and folding of the SAGEs has been modelled using computers by Dr Richard Sessions from the School of Biochemistry and Prof Noah Linden from the School of Mathematics.
The work has been funded by the BBSRC through a grant to Professor Dek Woolfson and Professor Paula Booth from the School of Biochemistry.
UK Not Ready for Brexit’s Impact on Food, Report WarnsNews
Severe problems with the UK food system are likely unless issues are addressed, according to latest expert reportREAD MORE
Edith Heard Unanimously Selected as Next Director General of EMBLNews
At its 53rd meeting yesterday, EMBL Council selected Edith Heard as the organization’s fifth Director General. Heard’s mandate is scheduled to begin 1 January 2019.READ MORE
CRISPR Transforms Living Cells Into Data Storage DevicesNews
Genome engineering technology transforms living cells into archival data storage devices that capture, store, and propagate information over time.READ MORE
Comments | 0 ADD COMMENT
EMBL Course: Next Generation Sequencing: RNA Sequencing Library Preparation
Apr 23 - Apr 27, 2018
EMBO Practical Course: Microbial Metagenomics: A 360º Approach
Apr 23 - Apr 30, 2018
EMBL Course: Next Generation Sequencing: Whole Genome Sequencing Library Preparation
Apr 16 - Apr 20, 2018
EMBL Course: Introduction to Next Generation Sequencing
Apr 09 - Apr 12, 2018