Team:Peking R/Project/RNAToolkit

From 2011.igem.org

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   <p>In recent years, RNA devices have emerged  as powerful tools to regulate gene expression in vivo, and particularly,  ligand-responsive riboswitches/ribozymes enable us to manipulate translation  strength of specific genes upon different concentrations of ligands.  Ligand-responsive riboswitches/ribozymes regulate the translation rate of  downstream gene by changing conformations, cleaving or splicing upon external  addition of ligand. Compared with transcriptional and post-translational  regulation, riboswitches/ribozymes function through allostery of RNA structure,  which requires little or no assistance from proteins, so the regulation  mechanism is relatively simpler and their functions are more decoupled from  native biological activities.</p>
   <p>In recent years, RNA devices have emerged  as powerful tools to regulate gene expression in vivo, and particularly,  ligand-responsive riboswitches/ribozymes enable us to manipulate translation  strength of specific genes upon different concentrations of ligands.  Ligand-responsive riboswitches/ribozymes regulate the translation rate of  downstream gene by changing conformations, cleaving or splicing upon external  addition of ligand. Compared with transcriptional and post-translational  regulation, riboswitches/ribozymes function through allostery of RNA structure,  which requires little or no assistance from proteins, so the regulation  mechanism is relatively simpler and their functions are more decoupled from  native biological activities.</p>
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   <p>In order to fulfill the goal of  establishing an extensible and versatile platform for softcoding of genetic  program, our team reached out to a great extent to search for available  ligand-responsive riboswitches/ribozymes that meet our criteria and selected  them as our genetic rheostats.</p>
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   <p>In order to fulfill the goal of  establishing an extensible and versatile methodology for softcoding of genetic  program, our team reached out to a great extent to search for available  ligand-responsive riboswitches/ribozymes that meet our criteria and selected  them as our genetic rheostats.</p>
<p>Candidates for genetic rheostats must meet  two basic criteria: firstly, they should possess a relatively plain  dose-response curve, which would allow for precise translation strength  modulation within a wide range of ligand concentration; secondly, ligands they  recognize should be genetically and biochemically orthogonal to the host cells,  in our case, <em>E.coli</em> cells, as much as  possible.</p>
<p>Candidates for genetic rheostats must meet  two basic criteria: firstly, they should possess a relatively plain  dose-response curve, which would allow for precise translation strength  modulation within a wide range of ligand concentration; secondly, ligands they  recognize should be genetically and biochemically orthogonal to the host cells,  in our case, <em>E.coli</em> cells, as much as  possible.</p>
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<p>Two candidates emerged as promising genetic  rheostats that satisfied our requirements: thiamine pyrophosphate  (TPP)-responsive hammerhead ribozymes and theophylline-responsive riboswitches.  By altering the upstream promoter and downstream coding sequence of the genetic  rheostats, we demonstrated that their performance was independent from sequence  context, which proved that our genetic rheostats are modular.</p>
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<p>Two candidates emerged as promising genetic  rheostats that satisfied our requirements: thiamine pyrophosphate  (TPP)-responsive hammerhead ribozymes and theophylline-responsive riboswitches.  By altering the upstream promoter and downstream coding sequence of the genetic  rheostats, we demonstrated that their performance was independent of sequence  context, which proved that our genetic rheostats are modular.</p>
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<p>To further extend the range of application  of our genetic rheostats, we created a ribozyme that functions with a different  mechanism, which has an extreme low basal level. We substituted the aptamer  domain of c-di-GMP group I intron to theophylline-responsive aptamer, thus invented a group I intron that senses theophylline to perform splicing  function.</p>
+
<p>To further extend the repertoire of our genetic rheostats, we created a ribozyme that functions with a different  mechanism, which has an extreme low basal level. We substituted the aptamer  domain of c-di-GMP group I intron to theophylline-responsive aptamer, thus invented a group I intron that senses theophylline to perform splicing  function.</p>
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<p>Moreover, we introduced a general method to  evolve hammerhead ribozyme that senses a new ligand. By coupling an adenine  aptamer with hammerhead ribozyme and randomizing nucleotides in the linker  domain, we evolved new hammerhead ribozymes through dual selection, whose  self-cleavage could be regulated by adenine.</p>
+
<p>Moreover, we introduced a general method to  evolve genetic rheostat that senses a new ligand. By coupling an adenine  aptamer with hammerhead ribozyme and randomizing nucleotides in the linker  domain, we evolved new genetic rheostat through dual selection, whose  self-cleavage could be regulated by adenine.</p>
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  <p>In summary, our project harvested two RNA  devices and performed detailed characterization; we also provided new design  principles for rational or semi-rational design of riboswitches/ribozymes.</p>
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Latest revision as of 03:11, 29 October 2011

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Overview


In recent years, RNA devices have emerged as powerful tools to regulate gene expression in vivo, and particularly, ligand-responsive riboswitches/ribozymes enable us to manipulate translation strength of specific genes upon different concentrations of ligands. Ligand-responsive riboswitches/ribozymes regulate the translation rate of downstream gene by changing conformations, cleaving or splicing upon external addition of ligand. Compared with transcriptional and post-translational regulation, riboswitches/ribozymes function through allostery of RNA structure, which requires little or no assistance from proteins, so the regulation mechanism is relatively simpler and their functions are more decoupled from native biological activities.

In order to fulfill the goal of establishing an extensible and versatile methodology for softcoding of genetic program, our team reached out to a great extent to search for available ligand-responsive riboswitches/ribozymes that meet our criteria and selected them as our genetic rheostats.

Candidates for genetic rheostats must meet two basic criteria: firstly, they should possess a relatively plain dose-response curve, which would allow for precise translation strength modulation within a wide range of ligand concentration; secondly, ligands they recognize should be genetically and biochemically orthogonal to the host cells, in our case, E.coli cells, as much as possible.

Two candidates emerged as promising genetic rheostats that satisfied our requirements: thiamine pyrophosphate (TPP)-responsive hammerhead ribozymes and theophylline-responsive riboswitches. By altering the upstream promoter and downstream coding sequence of the genetic rheostats, we demonstrated that their performance was independent of sequence context, which proved that our genetic rheostats are modular.

To further extend the repertoire of our genetic rheostats, we created a ribozyme that functions with a different mechanism, which has an extreme low basal level. We substituted the aptamer domain of c-di-GMP group I intron to theophylline-responsive aptamer, thus invented a group I intron that senses theophylline to perform splicing function.

Moreover, we introduced a general method to evolve genetic rheostat that senses a new ligand. By coupling an adenine aptamer with hammerhead ribozyme and randomizing nucleotides in the linker domain, we evolved new genetic rheostat through dual selection, whose self-cleavage could be regulated by adenine.