Biosafety System Lac of Growth

Overview

Figure 1: Principle of electron transfer from bacteria to anode via nanowires.

The tetracyclin repressor (TetR)/ operator (TetO) originally is used by E. coli to work against the antibiotic tetracycline but in many cases it is used for regulated expression for industrial processes. When there is no tetracycline available the TetR binds with high affinity the tetracycline operator. When tetracycline is available the TetR switches his conformation and so it comes to a dissolution of the TetR and the TetO. Because of this the polymerase isn’t enhanced anymore and is able to express the genes which lies behind the TetO. In our system the TetR is under the control of a rhamnose promotor (rha-promotor) which only works in the presence of rhamnose. When the bacteria would break out of the MFC there wouldn’t be enough rhamnose in the environment to activate the promotor in a way that enough TetR would be produced to block the polymerase by binding at the TetO. Therefore the polymerase binds to the promotor of TetO and it comes to the expression of RNase Ba and the degradation of the DNA.

Genetic Approach

The lac repressor/operator system uses E.coli to regulate the production of enzymes and because of this E. coli also regulate its metabolic stress. Enzymes only are produced when they are required. LacI is a repressor which is able to inhibit the lac operon in the absence of lactose by binding to the DNA at the lac operator site called lacO. Because of this repressor DNA polymerase is inhibited so it can’t read the sequences behind the operator lacZ (β-galactosidase), lacY (lactose permease) and lacA (thiogalactosidase transacetylase) which are responsible for transporting and metabolism of lactose in E. coli can’t be transcribed. The structure of the lac operon is shown in the image below.

Figure 1:Structure of the lactose operon and regulatory units.

When L-rhamnose is in the milieu where E. coli is located it can be taken up by the RhaT transport system which converts it to L-rhamnulose by the isomerase RhaA. It continues by phosphorylating by the kinase RhaB in rhamnulose-1-phosphate. This is hydrolyzed by the aldolase RhaD into dihydroxyacetone phosphate and lactate aldehyde. Dihydroxyacetone is metabolized in glycolysis, and lactate aldehyde aerobe to lactate. If there are anaerobe conditions lactate aldehyde is reduced to L-1,2,-propandiol. The gene RhaBAD functions as an operon and is transcribed by RhaPBAD. Two activators, RhaR and RhaS, have to be expressed to regulate the system. This expression of these activators is in opposite direction than the expression of rhaBAD. When L-rhamnose is available RhaR binds to RhaPRS and activates the production of RhaR and RhaS. RhaS binds with L-rhamnose as an effector to RhaPBAD and RhaPT promoter and activates the transcription of the structural genes.

L-rhamnose inducible expression system.

Results

References