Team:Freiburg Bioware/Project/Results

From 2010.igem.org

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<a name="highlights" class="onlyAnchor"><h1>Result Highlights</h1></a>
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<h1>Summary</h1>
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Gene delivery is a very promising approach, which yet has to live up to its potentials. Despite several clinical trials, no modular and at the same time exhaustive line of attack has been published. We took advantage of current knowledge to generate a fully modular recombinant Adeno-associated virus (rAAV) based system, which incorporates an extensive set of known surface modifications. In addition, we utilize recently developed binding molecules to generate and demonstrate a novel tumor-targeting approach for rAAV. Our modules have been first extensively tested individually and then in combination for viral production and infectivity. They compared well or exceeded performance of existing systems. The BioBrick-compatible viral vectors demonstrated their ability of tissue-specific delivery of genes coding for fluorescent protein reporters as well as prodrug-activating enzymes for tumor therapy. Using these viruses, we demonstrate specific prodrug-mediated killing of human tumor cells overexpressing a tumor-specific receptor while a reference cell line was unaffected.
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During the development of our system we mastered several hurdles and developed the know-how to manipulate the viral genome. We had to generate a new version of the standard iGEM backbone, since we need additional singular restriction sites to enable swapping of sequences coding for the viral loop structures, which can be used to determine the tropism. Our systems allows to exchange two loops of the virus for a His affinity tag, which enables purification, a biotinylation tag, or an antibody binding motif. We demonstrated functional assembly of viruses with all three modifications.
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In addition we established two N-terminal fusions to the capsid proteins using the binding scaffolds of DARPins and Affibodies. To our knowledge, neither the use of these motifs in a viral setting nor the tumor targeting of rAAV by N-terminal fusion have been demonstrated so far.
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We applied a wide range of techniques to achieve our goals. Cloning was performed in E. coli, viruses were produced in a human kidney cell line, and viral infections were tested in further human cell lines. Viruses were purified by liquid chromatography and virus samples were analyzed by quantitative real-time PCR and ELISA. Expression of virally delivered reporter genes was analyzed by fluorescence microscopy including time-lapse imaging. Expression and cell viability upon infection was also assessed by flow cytometry and MTT-assays. Viral samples were additionally analyzed by atomic force microscopy and electron microscopy.
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We provide an extensive lab journal, a well documented set of over 100 BioBricks and a detailed manual for the Virus Construction Kit.
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List with milestones reaches
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Our key achievements are:
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<li>A BioBrick set and assembled plasmids for gene delivery. This set comprises the AAV ITRs, a CMV and a hTERT promoter, as well as the genes of interest mVenus, mCherry as reporters and thymidine kinase and cytosin deaminase constructs for prodrug activation, as well as a beta-globin intron and a hGH polyadenylation tag to control gene expression.</li>
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<li>A Biobrick set and plasmids for viral capsid production and modification. This set comprises an Affibody and a DARPin targeting the EGF-receptor and a set of linkers which can be utilized for N-terminal fusions. A modified gene coding for viral capsid proteins, which is modified for the fusion. In addition we provide a viral capsid gene for loop modification and the fitting loop modifications coding for a His-tag, biotinylation sequence, and antibody binding site.</li>
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<li>An extensive set of experiments demonstrating the functionality of our constructs.</li>
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<a name="highlights" class="onlyAnchor"><h2>Highlights</h2></a>

Revision as of 03:43, 28 October 2010

Summary

Gene delivery is a very promising approach, which yet has to live up to its potentials. Despite several clinical trials, no modular and at the same time exhaustive line of attack has been published. We took advantage of current knowledge to generate a fully modular recombinant Adeno-associated virus (rAAV) based system, which incorporates an extensive set of known surface modifications. In addition, we utilize recently developed binding molecules to generate and demonstrate a novel tumor-targeting approach for rAAV. Our modules have been first extensively tested individually and then in combination for viral production and infectivity. They compared well or exceeded performance of existing systems. The BioBrick-compatible viral vectors demonstrated their ability of tissue-specific delivery of genes coding for fluorescent protein reporters as well as prodrug-activating enzymes for tumor therapy. Using these viruses, we demonstrate specific prodrug-mediated killing of human tumor cells overexpressing a tumor-specific receptor while a reference cell line was unaffected. During the development of our system we mastered several hurdles and developed the know-how to manipulate the viral genome. We had to generate a new version of the standard iGEM backbone, since we need additional singular restriction sites to enable swapping of sequences coding for the viral loop structures, which can be used to determine the tropism. Our systems allows to exchange two loops of the virus for a His affinity tag, which enables purification, a biotinylation tag, or an antibody binding motif. We demonstrated functional assembly of viruses with all three modifications. In addition we established two N-terminal fusions to the capsid proteins using the binding scaffolds of DARPins and Affibodies. To our knowledge, neither the use of these motifs in a viral setting nor the tumor targeting of rAAV by N-terminal fusion have been demonstrated so far. We applied a wide range of techniques to achieve our goals. Cloning was performed in E. coli, viruses were produced in a human kidney cell line, and viral infections were tested in further human cell lines. Viruses were purified by liquid chromatography and virus samples were analyzed by quantitative real-time PCR and ELISA. Expression of virally delivered reporter genes was analyzed by fluorescence microscopy including time-lapse imaging. Expression and cell viability upon infection was also assessed by flow cytometry and MTT-assays. Viral samples were additionally analyzed by atomic force microscopy and electron microscopy. We provide an extensive lab journal, a well documented set of over 100 BioBricks and a detailed manual for the Virus Construction Kit. List with milestones reaches Our key achievements are:

  • A BioBrick set and assembled plasmids for gene delivery. This set comprises the AAV ITRs, a CMV and a hTERT promoter, as well as the genes of interest mVenus, mCherry as reporters and thymidine kinase and cytosin deaminase constructs for prodrug activation, as well as a beta-globin intron and a hGH polyadenylation tag to control gene expression.
  • A Biobrick set and plasmids for viral capsid production and modification. This set comprises an Affibody and a DARPin targeting the EGF-receptor and a set of linkers which can be utilized for N-terminal fusions. A modified gene coding for viral capsid proteins, which is modified for the fusion. In addition we provide a viral capsid gene for loop modification and the fitting loop modifications coding for a His-tag, biotinylation sequence, and antibody binding site.
  • An extensive set of experiments demonstrating the functionality of our constructs.
  • Highlights

    Modularization

    Gene of interest
    The Virus Construction Kit enables researchers to encapsidate virtually any given DNA sequence into AAV-2 particles. As one example from therapeutic focus of our project, prodrug-activating enzymes are provided within the kit for efficient tumor cell killing. Additionally included fluorescent proteins allow monitoring of transduced cells by fluorescence microscopy and flow cytometry. Transgene expression can be fine-tuned using promoters of different specificity and enhancer elements also provided.
    RepVP123
    AAV-2 genes essential for the production of viral particles in a specialized cell line were identified by literature search, isolated on genetic level and modified to meet the requirements of BioBrick assembly. For this purpose, a specialized variant of the iGEM default backbone was created, proven functional and submitted.

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    Targeting

    One aim of our research is on the one hand to knock down the natural tropism of the Adeno-associates virus particles and on the other hand to specifically target tumor cells. This is achieved by genetic engineering of the virus surface. For this purpose, two different strategies were developed, including Targeting via Loops or fusion to the N-terminus of the viral protein VP2.

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    Arming

    The specifically targeted tumor cells were killed by prodrug activation approaches. Viral particles were charged with thymidine kinase and cytosine deaminase constructs to induce apoptosis in cancer cells upon delivery of ganciclovir or 5-Fluorocytosine, respectively.

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    Modeling

    Gene of interest
    The Virus Construction Kit enables researchers to encapsidate virtually any given DNA sequence into AAV-2 particles. As one example from therapeutic focus of our project, prodrug-activating enzymes are provided within the kit for efficient tumor cell killing. Additionally included fluorescent proteins allow monitoring of transduced cells by fluorescence microscopy and flow cytometry. Transgene expression can be fine-tuned using promoters of different specificity and enhancer elements also provided.
    RepVP123
    AAV-2 genes essential for the production of viral particles in a specialized cell line were identified by literature search, isolated on genetic level and modified to meet the requirements of BioBrick assembly. For this purpose, a specialized variant of the iGEM default backbone was created, proven functional and submitted.

    banner banner
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