Difference between revisions of "Team:IIT Delhi/Design"
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| + | <h2 id="pfont1">The potential of genetic clock lies in its role to triggering logic reaction for sequential biological circuits. A square wave generator could be used as a genetic clock, since square waves lie at the heart of clocks. Further, these clocks could be used in any cellular system to time particular events. | ||
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| + | <h2 id="pfont1">This could be used to study correlation between two genes, by coupling one of the genes to the oscillator, then observe the dynamics of the second gene. In this manner, the effect of one gene on the others could be studied. | ||
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<li> Periodic Drug delivery - Like diabetic patients, insulin needs to be provided externally through injections or other means. Our oscillator system could be used as a patch containing bacteria that are oscillating to produce square levels of insulin to the patient once. This then would deliver insulin automatically at intervals, guided by our system .Further when the requirement for insulin would be high, the amount of insulin being delivered to them could be changed through some source which could dive a change in frequency of the oscillations (future applications could be focused on engineering frequency modulation). | <li> Periodic Drug delivery - Like diabetic patients, insulin needs to be provided externally through injections or other means. Our oscillator system could be used as a patch containing bacteria that are oscillating to produce square levels of insulin to the patient once. This then would deliver insulin automatically at intervals, guided by our system .Further when the requirement for insulin would be high, the amount of insulin being delivered to them could be changed through some source which could dive a change in frequency of the oscillations (future applications could be focused on engineering frequency modulation). | ||
<li> Metabolic Switching – A bacterial species could be engineered to produce levels of the permease for a particular sugar in the form of a square wave. Thus, at varying intervals of time, the permease (say lac permease) would be expressed, which would cause the bacteria to start metabolizing lactose. When it goes off, the bacteria would not express the lac permease and consume glucose. In this manner, we could tune the frequency of the oscillations to ensure metabolic switching and activation of pathway shunts in the manner that we want. | <li> Metabolic Switching – A bacterial species could be engineered to produce levels of the permease for a particular sugar in the form of a square wave. Thus, at varying intervals of time, the permease (say lac permease) would be expressed, which would cause the bacteria to start metabolizing lactose. When it goes off, the bacteria would not express the lac permease and consume glucose. In this manner, we could tune the frequency of the oscillations to ensure metabolic switching and activation of pathway shunts in the manner that we want. | ||
Revision as of 17:38, 1 November 2017
Introduction
Several circuits have been proposed, constructed, and implemented, leading to landmark discoveries in synthetic biology. These include systems such as the bi-stable toggle switch, and the repressilator, which brought about a paradigm shift in the field. Since then, several systems have been constructed to employ memory modules, create counters, adders, digital biosensors, and a whole wide range of other products.
Figure – A brief timeline of major notable events in the creation and development of synthetic biology (Source: Del Vecchio, Domitilla et al, Journal of The Royal Society Interface 13.120 (2016): 20160380.)
However, there are several limitations that still need to be overcome, as the field continues to make strides in every area. These involve the fact that biological systems have a lot of noises that cannot be modeled accurately to date, and the fact that metabolic burden is a major issue. Along these lines, one of the central issues is the distinct lack of digital responses in synthetic biology.
Thus, as described in the project overview, we wished to use the high cooperativity TetR homologs in such a manner so as to generate a square wave oscillator circuit. Such a system could have a whole multitude of applications; some of which were mentioned briefly in the overview, and the same are also discussed below,
Applications
