Part:BBa_K1017603

37℃ RBS + LuxR

This unit includes 37℃ RBS and LuxR. 37℃ RBS, a RBS which is controlled by temperature. LuxR, a protein which can activate P_lux after binding with AHL. This unit act as a biotheometer, which can act on temperature changing. When the temperature is higher than 37℃, the downstream gene LuxR is expressed. Therefore , P_lux is activated and the downstream gene, sRNA, can be produced, then the sRNA will bind to the rRBS so the Shine-Dalgarno sequence can't be exposed. Without the ribosome binding, causing the downstream gene of the rRBS can't be translated. When lower than 37℃, P_lux is no longer activated , which means sRNA production shuts down. Thus, the downstream gene of the rRBS, mRFP or mYFP, can be expressed normally.

Mechanism

Unlike normal RBS, the 37℃ RBS has a unique rather stable hairpin structure which shape like a lock. If the temperature drops below 37℃, the base-pairing neucleotides on the RNA will form a stable hairpin structure, occluding the Shine-Dalgarno sequence thus disabling the ribosome to bind. The base-pairing of this RNA region will block the expression of the protein encoded within.When the temperature is higher than 37℃, the bonds will be broken, the hairpin would be unfolded, causing the Shine-Dalgarno sequence to be exposed and permitting the binding of the ribosome, which then starts the translational machinery so the downstream gene, luxR, can be expressed.

Data

From chart 1, we can clearly found that the time to reach same O.D. 0.8 various as the temperature changes. The expression of mGFP under 37°C and 42°C reached a higher OD value in less time than the expression under 32°C and 27°C. This demonstrates the fact that 37°C RBS functions more efficiently above or at 37°C. In our project, our goal is to get a certain product by a certain condition, but when under 37°C, the RBS also functions, which is out of our expectation. As a result, we cannot make sure that our system produces the only protein under 37°C.

Sequence and Features