Team:Illinois/Bimolecular Fluorescence

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=== Bimolecular Fluorescence Biosensor ===
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Bimolecular Fluorescence Biosensor
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We hope to design a soluble molecular biosensor that, when it comes in contact with an 'activating' ligand such as a virus, bacterium, or specific antibody, generates a fluorescent response using bimolecular complementation. Traditionally unimolecular constructs such as Green Fluorescent Protein (GFP) can be split into two heterologous protein fragments, which can then bind and reinitiate fluorescence upon close spatial proximity. GFP fragments are often fused to endogenous intracellular proteins to study protein-protein interactions: complementation between these GFP fragments is achieved only when they are tethered to proteins which interact (bind) strongly.
We hope to design a soluble molecular biosensor that, when it comes in contact with an 'activating' ligand such as a virus, bacterium, or specific antibody, generates a fluorescent response using bimolecular complementation. Traditionally unimolecular constructs such as Green Fluorescent Protein (GFP) can be split into two heterologous protein fragments, which can then bind and reinitiate fluorescence upon close spatial proximity. GFP fragments are often fused to endogenous intracellular proteins to study protein-protein interactions: complementation between these GFP fragments is achieved only when they are tethered to proteins which interact (bind) strongly.
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We seek to harness this powerful molecular tool for an inverse task: instead of studying putative interactions between known proteins, we are designing fusion constructs to detect the presence of proteins known ''a priori'' to interact, for deployment as a one-step diagnostic assay. For example, virus envelopes are often composed of large multiprotein complexes; one GFP fragment could be fused to an antibody against on envelope protein, and the complementary fragment fused to an antibody against an adjacent protein. In solution, only the presence of this specific multiprotein complex would generate GFP complementation and the resulting fluorescence, providing a robust one-step method for the detection of pathogens. Similarly, many secreted bacterial enterotoxins form multiprotein complexes, such as Cholera Toxin; also, many immunoglobulin biomolecules can form aggregates in the circulation.
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We seek to harness this powerful molecular tool for an inverse task: instead of studying putative interactions between known proteins, we are designing fusion constructs to detect the presence of proteins known ''a priori'' to interact, for deployment as a one-step diagnostic assay. For example, virus envelopes are often composed of large multiprotein complexes; one GFP fragment could be fused to an antibody against on envelope protein, and the complementary fragment fused to an antibody against an adjacent protein. In solution, only the presence of this specific multiprotein complex would generate GFP complementation and the resulting fluorescence, providing a robust one-step method for the detection of pathogens. Similarly, many secreted bacterial enterotoxins form multiprotein complexes, such as cholera toxin. Additionally, many immunoglobulin biomolecules can form aggregates in the circulation.
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==Literature References==
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==Planned Labwork==

Latest revision as of 02:58, 12 June 2008

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Bimolecular Fluorescence Biosensor


Contents

Core Team Members

Luke Edelman, Adam Zoellner, Meghan McCleary, Katrina Keller

Project Summary

We hope to design a soluble molecular biosensor that, when it comes in contact with an 'activating' ligand such as a virus, bacterium, or specific antibody, generates a fluorescent response using bimolecular complementation. Traditionally unimolecular constructs such as Green Fluorescent Protein (GFP) can be split into two heterologous protein fragments, which can then bind and reinitiate fluorescence upon close spatial proximity. GFP fragments are often fused to endogenous intracellular proteins to study protein-protein interactions: complementation between these GFP fragments is achieved only when they are tethered to proteins which interact (bind) strongly.

We seek to harness this powerful molecular tool for an inverse task: instead of studying putative interactions between known proteins, we are designing fusion constructs to detect the presence of proteins known a priori to interact, for deployment as a one-step diagnostic assay. For example, virus envelopes are often composed of large multiprotein complexes; one GFP fragment could be fused to an antibody against on envelope protein, and the complementary fragment fused to an antibody against an adjacent protein. In solution, only the presence of this specific multiprotein complex would generate GFP complementation and the resulting fluorescence, providing a robust one-step method for the detection of pathogens. Similarly, many secreted bacterial enterotoxins form multiprotein complexes, such as cholera toxin. Additionally, many immunoglobulin biomolecules can form aggregates in the circulation.

Literature References

Planned Labwork