|![[Search]](https://talks.cam.ac.uk/images/search.gif?1209136071)
|![[A-Z Index]](https://talks.cam.ac.uk/images/az.gif?1209136071)
|![[Contact]](https://talks.cam.ac.uk/images/contact.gif?1209136071)
||![[University of Cambridge]](https://talks.cam.ac.uk/images/identifier2.gif?1209136071){kind=small} |
COOKIES: By using this website you agree that we can place Google Analytics Cookies on your device for performance monitoring. | ![[Talks.cam]](https://talks.cam.ac.uk/images/talkslogosmall.gif?1209136071) |
University of Cambridge > Talks.cam > Plant Sciences Departmental Seminars > A synthetic biology approach to harness the regulatory potential of miRNAs in the green alga Chlamydomonas reinhardtii
A synthetic biology approach to harness the regulatory potential of miRNAs in the green alga Chlamydomonas reinhardtiiAdd to your list(s) Download to your calendar using vCal
If you have a question about this talk, please contact sl750. microRNAs (miRNAs), small RNA molecules of 20–24 nts, have a number of features that make them ideal tools to regulate gene expression — small size, flexible design, target predictability and action at a late stage of the gene expression pipeline. The regulatory potential of miRNAs goes beyond gene repression, as they can confer robustness to gene expression, a feature which is desirable to implement in plant synthetic gene networks. In order to harness the regulatory potential of miRNAs, a comprehensive understanding of the quantitative parameters and mode of action of miRNAs is required, which is, however, hindered by the complexity of natural systems. By using principles of synthetic biology, we have constructed a platform to characterize regulatory properties of miRNAs in the model alga Chlamydomonas reinhardtii. Using this system, we observed that the level of repression by a miRNA depends on its abundance and degree of sequence complementarity to its target mRNA. We also found that sequence complementarity between the miRNA and its target mRNA defined the mRNA’s response curve to the miRNA, and that the mode of action of a fully complementary miRNA to its target was the result of a combined action of RNA slicing and RNA destabilization. We are now using this information to design further applications of miRNAs, and studying their effect in regulatory loops. This work will be used as a proof-of-concept for the engineering of miRNA-based gene circuits in higher plants. This talk is part of the Plant Sciences Departmental Seminars series. This talk is included in these lists:
Note that ex-directory lists are not shown. |
Other listsEarly Detection breakfast meetings RCEAL Tuesday Colloquia Physics of Living Matter lectures Slavonic Studies Vascular Biology Research Seminars MethSoc: Cambridge Student Methodist SocietyOther talksParacelsus' Chickens - Strange Tales from the History of Chemistry Enhancing the Brain and Wellbeing in Health and Disease Political Thought, Time and History: An International Conference Communicating Your Research to the Wider World Understanding and Estimating Physical Parameters in Electric Motors using Mathematical Modelling Human Brain Development Modelled in a Dish |
Francisco J. Navarro, Baulcombe group
Thursday 01 June 2017, 13:00-13:30