Difference between revisions of "Part:BBa K3490020"

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Regulating the growth rate of bacteria.


The first vesion of growth switch


Overview

For our project, we need the bacteria to stay alive in our contact lenses until it can be used. However, bacteria can’t live for a long time in such a small space, especially with such limited nutrients. To solve this problem, we designed a growth switch to put bacteria into hibernation for storage, which we can then resuscitate after exposure to external stimulation.

Fig.1. The big picture of growth switch

Toxin-antitoxin system TA System

The hicA-hicB locus located on E. coli chromosome is a toxin-antitoxin system (TA system). The TA system is composed of linked genes, encoding a toxic protein that can inhibit cell growth and an antitoxic protein which neutralize the toxic protein^[1]. For our project, a kind of the TA system effect called the stress tolerance effect, is used to induce bacteria hibernation. By making use of this mechanism of the TA system, we designed a growth switch to regulate the growth of bacteria.

According to a research^[2], HicA is a toxin promoting mRNA degradation, leading to the hibernation of bacteria, while HicB is an antitoxin that can neutralize the effect of HicA. Hence, through regulating the expression of hicA and hicB genes, we can control the growth of bacteria, hibernating the bacteria before the contact lens are used.

The blue light-sensitive system: EL222

Since contact lens are sealed during the process of production, it is impossible to regulate the growth switch through chemical induction; hence, we turned to external stimuli such as light, temperature, etc. At first, we used EL222 to regulate the system^[3] (a blue light-sensitive protein), pBlind (a promoter activated by EL222), FLP, and FRT to change the orientation of our promoter^[4], which is activated by blue light (Fig.2). In other words, we have to illuminate the contact lens with blue light for 30 minutes before use.

Fig.2. The first version of design: BBa_K3490020. This design enables us to control the bacteria growth in three stages.

First, the production stage is when we are culturing our bacteria. Without any arabinose addition during culture, the bacteria will be able to grow normally. After the production process, we will put the bacteria and arabinose into the contact lens together, so the pBAD promoter will transcribe hicA, causing the bacteria to hibernate. When we need to resuscitate the bacteria, EL222 will be activated by blue light to induce pBlind promoter, and then FLP will be transcribed. FLP will act on the FRT sites to change the orientation of the pBAD promoter, as a result, the bacteria will start to transcribe hicB to neutralize HicA and thus continue to grow.
We replaced hicA and hicB with GFP and OFP gene to build a test plasmid because it is much easier to observe the color change than to count the CFU (Fig.3). If the color of fluorescence changes from green to orange, the experiment is successful to prove that the design is feasible.
However, during the experiment process, we had difficulty constructing both plasmid. With the doubt that the EL222-FLP system might be harmful to the growth of bacteria, we changed the design of blue-sensitive protein EL222 into thermo-sensitive protein CI857 on the plasmid pCP20 provided by our PI, Prof. Ng (Fig.4).

Fig.3. The plasmid map which changes the toxin-antitoxin gene into fluorescent genes

Fig.4. The heat-activated plasmid pCP20

Result: Fail

Reference

[1]Guglielmini J, Van Melderen L. Bacterial toxin-antitoxin systems. Mobile Genetic Elements. 2011;1(4):283-306.
[2]Jørgensen MG, Pandey DP, Jaskolska M, Gerdes K. HicA of Escherichia coli Defines a Novel Family of Translation-Independent mRNA Interferases in Bacteria and Archaea. Journal of Bacteriology. 2008;191(4):1191-1199.‌
[3]Motta-Mena LB, Reade A, Mallory MJ, et al. An optogenetic gene expression system with rapid activation and deactivation kinetics. Nature Chemical Biology. 2014;10(3):196-202.
[4]Branda CS, Dymecki SM. Talking about a Revolution. Developmental Cell. 2004;6(1):7-28.

Sequence and Features