Team:IIT Bombay India

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A major objective of synthetic biology is to unveil the inherent design principles prevailing in biological circuits. Multiple feedback loops (having both positive and negative regulation) are highly prevalent in biological systems. The relevance of such a design in biological systems is unclear. Our team has used synthetic biology approaches to answer these questions. Our team comprises of nine undergraduates, three graduate students as student mentors and two faculty mentors, one each from biology and engineering background. The project specifically deals with the analysis of the effect of single and multiple feedback loops on gene expression. This project involves theoretical and experimental studies. We have designed synthetic constructs to mimic multiple feedbacks. The focus of our experimental work is to visualize the effect of multiple feedback loops on the synthetic construct using single cell analysis. The project provides insights into the roles of multiple feedback loops in biological systems.
A major objective of synthetic biology is to unveil the inherent design principles prevailing in biological circuits. Multiple feedback loops (having both positive and negative regulation) are highly prevalent in biological systems. The relevance of such a design in biological systems is unclear. Our team has used synthetic biology approaches to answer these questions. Our team comprises of nine undergraduates, three graduate students as student mentors and two faculty mentors, one each from biology and engineering background. The project specifically deals with the analysis of the effect of single and multiple feedback loops on gene expression. This project involves theoretical and experimental studies. We have designed synthetic constructs to mimic multiple feedbacks. The focus of our experimental work is to visualize the effect of multiple feedback loops on the synthetic construct using single cell analysis. The project provides insights into the roles of multiple feedback loops in biological systems.
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== '''Sponsors''' ==
 
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== '''Introduction''' ==

Revision as of 22:54, 21 October 2009

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Introduction

Established in 1958, [http://www.iitb.ac.in IIT Bombay] is one of the most recognized centers of academic excellence in the country today. The excellence of its academic programs, a robust research and development program with parallel improvement in facilities and infrastructure have kept it at par with the best institutions in the world. The ideas on which such institutes are built evolve and change with national aspirations, national perspectives, and global trends. At IIT Bombay we are continuously seeking to extend the boundaries of our research in a sustained manner with clear cut executable goals, grounded solidly in national realities.


This is our first year of participation and as such, we are pretty excited about the prospects. We are a group of students from the Chemical Engineering Department and from the School of Biosciences & Bioengineering. The most exciting aspect that we found about this competition was the interdisciplinary learning. A chemical reactor system invariably involves the design of control structures, and it is the design of these structures in a biological system that we wish to attain via our project.


A major objective of synthetic biology is to unveil the inherent design principles prevailing in biological circuits. Multiple feedback loops (having both positive and negative regulation) are highly prevalent in biological systems. The relevance of such a design in biological systems is unclear. Our team has used synthetic biology approaches to answer these questions. Our team comprises of nine undergraduates, three graduate students as student mentors and two faculty mentors, one each from biology and engineering background. The project specifically deals with the analysis of the effect of single and multiple feedback loops on gene expression. This project involves theoretical and experimental studies. We have designed synthetic constructs to mimic multiple feedbacks. The focus of our experimental work is to visualize the effect of multiple feedback loops on the synthetic construct using single cell analysis. The project provides insights into the roles of multiple feedback loops in biological systems.

Introduction