Team:UANL Mty-Mexico/Project

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<h1>Introduction</h1>
<h1>Introduction</h1>
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Temperature sensing RNA sequences, known as RNA thermometers, regulate translation by preventing the ribosome from binding the transcript until higher temperatures shift it to an open structure. Several naturally occurring RNA thermometers have been described and synthetic sequences that emulate them have been designed and proved to regulate genetic expression at different temperature ranges. Here, we intend to build a genetic circuit that incorporates two synthetic RNA thermometers, resulting in three discrete states whose transition can be regulated by temperature changes in the medium only. Most notably, our circuit integrates transcriptional and post-transcriptional regulation, widening the spectrum of potential genetic circuit topologies for synthetic biology, with applications that range from basic research to the replacement of chemical inducers for industrial-scale processes.
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<p align="align">RNA thermometers (RNATs) are RNA sequences found in the 5' untranslated region of some genes and that regulate in <i>cis</i>their translation without the need of other factors. These RNAT sequences show certain three dimensional structures, some of which interact with the ribosome binding site of their regulated genes and hinders the proccessivity of the ribosome complex at certain temperatures. The dynamics of the formation of these structures is temperature dependent and is the basis of RNA thermoregulation.</p>
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<p>Functional RNAT have been found in different organisms, mainly pathogenic bacteria, and many others have been predicted from a number of bioinformatic studies. They have been found to regulate the expression of virulence factors, heat and cold shock response factors and even proteins involved the development of some bacteriophages.</p>
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<p>Their apparent widespread presence in living organisms has made RNATs attractive for some applications, specially the ones related to the replacement of chemical inducers and for the development of new drugs, since RNATs are usually found in pathogenic bacteria.</p>
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<p>However, from the experience of those who have been working extensively with RNAT in the later years, it is remarkable that the accurate bioinformatic prediction of functional RNAT has proven to be a difficult task. The reasons for this are pointed to be the poor sequence conservation observed in RNATs and the gaps in our current understanding of the RNAT function.  
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<p>The discovery of new RNATs has relied on a mixed approach that involves bioinformatics and experimental validation, as well as approaches that involve mutational libraries, synthetic constructions and directed evolution.</p>
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<p>Nevertheless, even when the naturally found RNATs usually regulate the expression of transcription factors, the synthetic constructions made so far have focused mainly to characterize the effect of a given RNAT using a reporter protein (LacZ or a fluorescent protein) directly downstream of a RNAT. In our work, we intend to prove that RNATs can also be employed to effectively regulate the expression of transcription factors in synthetic circuits and point at possible applications for the circuit topologies that would be made feasible with this new kind of synthetic regulatory device.</p>
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Revision as of 22:05, 5 September 2013

UANL México


Introduction

RNA thermometers (RNATs) are RNA sequences found in the 5' untranslated region of some genes and that regulate in cistheir translation without the need of other factors. These RNAT sequences show certain three dimensional structures, some of which interact with the ribosome binding site of their regulated genes and hinders the proccessivity of the ribosome complex at certain temperatures. The dynamics of the formation of these structures is temperature dependent and is the basis of RNA thermoregulation.

Functional RNAT have been found in different organisms, mainly pathogenic bacteria, and many others have been predicted from a number of bioinformatic studies. They have been found to regulate the expression of virulence factors, heat and cold shock response factors and even proteins involved the development of some bacteriophages.

Their apparent widespread presence in living organisms has made RNATs attractive for some applications, specially the ones related to the replacement of chemical inducers and for the development of new drugs, since RNATs are usually found in pathogenic bacteria.

However, from the experience of those who have been working extensively with RNAT in the later years, it is remarkable that the accurate bioinformatic prediction of functional RNAT has proven to be a difficult task. The reasons for this are pointed to be the poor sequence conservation observed in RNATs and the gaps in our current understanding of the RNAT function.

The discovery of new RNATs has relied on a mixed approach that involves bioinformatics and experimental validation, as well as approaches that involve mutational libraries, synthetic constructions and directed evolution.

Nevertheless, even when the naturally found RNATs usually regulate the expression of transcription factors, the synthetic constructions made so far have focused mainly to characterize the effect of a given RNAT using a reporter protein (LacZ or a fluorescent protein) directly downstream of a RNAT. In our work, we intend to prove that RNATs can also be employed to effectively regulate the expression of transcription factors in synthetic circuits and point at possible applications for the circuit topologies that would be made feasible with this new kind of synthetic regulatory device.

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