TY - GEN
T1 - Temperature and mutation switches in the secondary structure of small RNAs
AU - Avihoo, Assaf
AU - Barash, Danny
PY - 2005/12/1
Y1 - 2005/12/1
N2 - Conformational switching in the secondary structure of RNAs has recently attracted considerable attention, fostered by the discovery of 'riboswitches ' in living organisms. These are genetic control elements that were found in bacteria and offer a unique regulation mechanism based on switching between two highly stable states, separated by an energy barrier between them. In riboswitches, the energy barrier is crossed by direct metabolite binding, which facilitates regulation by allosteric means. However, other event triggers can cause switching to occur, such as single-point mutations and slight variations in temperature. Examples of switches with these event triggers have already been reported experimentally in the past. Here, our goal is to computationally design small RNA switches that rely on these triggers. Towards this end, our computer simulations utilize a variety of different similarity measures to assess the distances between an initial state and triggered states, based on the topology of the secondary structure itself. We describe these combined similarity measures that rely on both coarse-grained and fine-grained graph representations of the RNA secondary structure. As a result of our simulations, we provide some candidate sequences of approximately 3050 nt, along with the exact triggers that drive the switching. The event triggers under consideration can be modelled by mfold or the Vienna package. To begin with, we concentrate on designing small temperature and mutation switches.
AB - Conformational switching in the secondary structure of RNAs has recently attracted considerable attention, fostered by the discovery of 'riboswitches ' in living organisms. These are genetic control elements that were found in bacteria and offer a unique regulation mechanism based on switching between two highly stable states, separated by an energy barrier between them. In riboswitches, the energy barrier is crossed by direct metabolite binding, which facilitates regulation by allosteric means. However, other event triggers can cause switching to occur, such as single-point mutations and slight variations in temperature. Examples of switches with these event triggers have already been reported experimentally in the past. Here, our goal is to computationally design small RNA switches that rely on these triggers. Towards this end, our computer simulations utilize a variety of different similarity measures to assess the distances between an initial state and triggered states, based on the topology of the secondary structure itself. We describe these combined similarity measures that rely on both coarse-grained and fine-grained graph representations of the RNA secondary structure. As a result of our simulations, we provide some candidate sequences of approximately 3050 nt, along with the exact triggers that drive the switching. The event triggers under consideration can be modelled by mfold or the Vienna package. To begin with, we concentrate on designing small temperature and mutation switches.
UR - https://www.scopus.com/pages/publications/33749048729
U2 - 10.1109/CSBW.2005.131
DO - 10.1109/CSBW.2005.131
M3 - Conference contribution
AN - SCOPUS:33749048729
SN - 0769524427
SN - 9780769524429
T3 - 2005 IEEE Computational Systems Bioinformatics Conference, Workshops and Poster Abstracts
SP - 235
EP - 238
BT - 2005 IEEE Computational Systems Bioinformatics Conference, Workshops and Poster Abstracts
T2 - 2005 IEEE Computational Systems Bioinformatics Conference, Workshops and Poster Abstracts
Y2 - 8 August 2005 through 11 August 2005
ER -