Team:Potsdam Bioware

From 2011.igem.org

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<p style="text-align:justify;">One key task of biopharmaceuticals is the binding and blocking of deregulated proteins. Towards this goal, we mutate and select microviridins, which are tricyclic depsipeptides from cyanobacteria. They are small but stable due to their post-translational side-chain crosslinking. Microviridins have a high potential for therapy as they can block disease-relevant proteases. Yet, the possibilities of cyclic peptides are largely untapped since genetic systems for optimization are not well established. Thus, we developed synthetic systems for the mutation, selection and production of such peptides. We use the 6.5 kb microviridin (mdn) gene cluster cloned in E. coli plasmids, established random mutagenesis and generated focused libraries of microviridins. For selection against a panel of proteases, we are applying and testing phage display, and we are constructing a novel in-vivo selection device, which links protease blocking to antibiotic resistance. Our systems, including the 6.5 kb cluster, adhere to the BioBrick standards.
<p style="text-align:justify;">One key task of biopharmaceuticals is the binding and blocking of deregulated proteins. Towards this goal, we mutate and select microviridins, which are tricyclic depsipeptides from cyanobacteria. They are small but stable due to their post-translational side-chain crosslinking. Microviridins have a high potential for therapy as they can block disease-relevant proteases. Yet, the possibilities of cyclic peptides are largely untapped since genetic systems for optimization are not well established. Thus, we developed synthetic systems for the mutation, selection and production of such peptides. We use the 6.5 kb microviridin (mdn) gene cluster cloned in E. coli plasmids, established random mutagenesis and generated focused libraries of microviridins. For selection against a panel of proteases, we are applying and testing phage display, and we are constructing a novel in-vivo selection device, which links protease blocking to antibiotic resistance. Our systems, including the 6.5 kb cluster, adhere to the BioBrick standards.
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Revision as of 08:40, 20 September 2011

Project

One key task of biopharmaceuticals is the binding and blocking of deregulated proteins. Towards this goal, we mutate and select microviridins, which are tricyclic depsipeptides from cyanobacteria. They are small but stable due to their post-translational side-chain crosslinking. Microviridins have a high potential for therapy as they can block disease-relevant proteases. Yet, the possibilities of cyclic peptides are largely untapped since genetic systems for optimization are not well established. Thus, we developed synthetic systems for the mutation, selection and production of such peptides. We use the 6.5 kb microviridin (mdn) gene cluster cloned in E. coli plasmids, established random mutagenesis and generated focused libraries of microviridins. For selection against a panel of proteases, we are applying and testing phage display, and we are constructing a novel in-vivo selection device, which links protease blocking to antibiotic resistance. Our systems, including the 6.5 kb cluster, adhere to the BioBrick standards.

Software

BioLog – The new allround talent in the lab for your smart phone! Our app combines several features frequently used in the lab. The software stores basic protocols in your pocket - easy, handy and ready to use… [more]

Team

  • Nicole Albrecht

    Nicole Albrecht

  • Katharina Berger

    Katharina Berger

  • Nadja Bjelopoljak

    Nadja Bjelopoljak

  • Nadine Boehmer

    Nadine Boehmer

  • Vanessa Boehmer

    Vanessa Boehmer

  • Jessica Eger

    Jessica Eger

  • Steffi Sempert

    Steffi Sempert

  • Niels Weisbach

    Niels Weisbach

  • Sebastian Hanke

    Sebastian Hanke

  • Sascha Ramm

    Sascha Ramm

  • Paul Kaufmann

  • Stefan Wahlefeld

    Stefan Wahlefeld

  • Sandrina Heyde

    Sandrina Heyde

  • Sabine Meyer

    Sabine Meyer

  • Niklas Laasch

    Niklas Laasch

  • Oliver Zimmer

  • Tobias Wenzel

    Tobias Wenzel

BioBricks

Yes, we have some… check it out! :D [more]

Safety & Ethics

We communicated safety issues and ethic controversies in seminars and polled all members of the German parliament for their opininon on synthetic biology. Learn more about German views. [more]

Labjournal

All the hours spent in the lab - thinking, laughing, sweating and hoping. Here is the guide through our lab work.[more]

Modelling

Lorem ipsum dolor sit amet, consetetur sadipscing elitr, sed diam nonumy eirmod tempor invidunt ut labore et dolore magna aliquyam erat, sed diam voluptua. [more]