Team:SJTU-BioX-Shanghai/The project

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[[Image:SJTU09_Project_Application1.jpg|center|thumb|400px|Project significance]]
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Thus in our circuit, we create a oscillator in '''''E.coli''''', which function like a biological clock monitoring circadian rhythm in higher animals and plants. As the bacteria alternate their states between dormancy and resuscitation, there seems an inner clock within them.
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Thus in our circuit, we create a oscillator in '''''E.coli''''', which functions like a biological clock monitoring circadian rhythm in higher animals and plants. As the bacteria alternate their states between dormancy and resuscitation, there seems an inner clock within them.
The cycle from dormancy to resuscitation is expected to be constant, so we define it as 1 day in “'''''E.coli''''' world”. It sounds crazy that we can count the age of '''''E.Coli''''' according to the “days” they have during their life time!! Here we come into another interesting topic-----the life-span of E.coli. With a low metabolic rate in dormancy, the bacteria are much like higher animals who hibernate during winter. As we all know, bears and hedgehogs keep a rather low metabolic rate during hibernation, helping them go through food shortage in winter. So do tortoises, who maintain low metabolic rate to survive a longer life-span. Can our '''''E.Coli''''' with a inner clock extend their life-span via this circadian rhythm?   
The cycle from dormancy to resuscitation is expected to be constant, so we define it as 1 day in “'''''E.coli''''' world”. It sounds crazy that we can count the age of '''''E.Coli''''' according to the “days” they have during their life time!! Here we come into another interesting topic-----the life-span of E.coli. With a low metabolic rate in dormancy, the bacteria are much like higher animals who hibernate during winter. As we all know, bears and hedgehogs keep a rather low metabolic rate during hibernation, helping them go through food shortage in winter. So do tortoises, who maintain low metabolic rate to survive a longer life-span. Can our '''''E.Coli''''' with a inner clock extend their life-span via this circadian rhythm?   

Revision as of 07:46, 19 October 2009

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Project introduction. Inspired by the natural regulator of circadian bioclock exhibited in most eukaryotic organisms, our team has designed an E.coli-based genetic network with the toxin-antitoxin system so that the bacterium oscillates between two states of dormancy and activity (more...)

Our project

Contents

Idea & background

Hypnos legend

Lovely Hypnos
Hypnos's curse

Inspiration of our idea

It is universally acknowledged that bioclock works as a circadian regulator in most eukaryotic multicellular species. This mechanism controls higher plants’ blossom time, brings insects into metamorphosis, and also wakes us up every day.

Then comes up the crazy idea: Why cannot prokaryotes live with a bioclock?

Hence, we constructed our bacteria bioclock by utilizing the toxin-antitoxin system (TA system), which forms an oscillator between two physiological states--dormancy and activity.

Inspiration of our idea: BioClock

Method implementation

The RelE toxin protein is an RNase that preferentially cleaves mRNAs in the ribosome between the 2nd and 3rd nucleotide of stop codons, UAG with the fast, UAA intermediate and UGA the slow rate. Expression of the RelE gene has been shown to severely inhibit translation and prevent colony formation, whereas coexpression of the RelB antitoxin avoid these inhibitory effects. But if the repression does happen, after RelE-mediated sequence specific cleavage of the mRNA at ribosomal A site, the blocked ribosome becomes a substrate for the tmRNA rescue system, which can recycle the stalled ribosomes through trans-translation and degrade aberrant proteins made from truncated mRNAs.

Based on these mechanisms we have designed an ingenious genetic network which functions as a bacterial bioclock oscillating between the two states of dormancy and activity. It is exciting that we manage to manipulate the lifespan of E.coli by switching the oscillator on, since the metabolic process of microbes is vastly decelerated during the dormancy state, just like bears and hedgehogs in their hibernation.

An example of how this artificial bioclock could be applied might be the preservation of scientifically valuable bacteria which mutate frequently. During the dormancy state bacteria hardly undergo mutation; therefore their genetic characteristics are retained.

Other potential applications such as biologic timing and antibiotic resistance remain intriguing to explore.

Project significance

Project significance

Thus in our circuit, we create a oscillator in E.coli, which functions like a biological clock monitoring circadian rhythm in higher animals and plants. As the bacteria alternate their states between dormancy and resuscitation, there seems an inner clock within them.

The cycle from dormancy to resuscitation is expected to be constant, so we define it as 1 day in “E.coli world”. It sounds crazy that we can count the age of E.Coli according to the “days” they have during their life time!! Here we come into another interesting topic-----the life-span of E.coli. With a low metabolic rate in dormancy, the bacteria are much like higher animals who hibernate during winter. As we all know, bears and hedgehogs keep a rather low metabolic rate during hibernation, helping them go through food shortage in winter. So do tortoises, who maintain low metabolic rate to survive a longer life-span. Can our E.Coli with a inner clock extend their life-span via this circadian rhythm?




Next, go to Project design.