Part:BBa_K2974500

Medium Promoter (BBa_J23106) Toehold LacZ

T7 Toehold LacZ is a construct that was developed to be applied as a biosensor. The part BBa_I732005 was submitted by 2007 UTSC iGEM that singularly included the LacZ gene encoding the Beta-galactosidase protein. In an effort to build on this biobrick and implement LacZ blue color expression as a biosensor, Lambert iGEM obtained a LacZ toehold switch construct assembled with a medium-strength T7 promoter BBa_J23106. The medium-strength promoter replaced the strong T7 promoter BBa_J23100 obtained from the Styczynski Lab at the Georgia Institute of Technology used in the 2018 Lambert iGEM project. The strong promoter was responsible for leakiness in the toehold, and the team sought to diminish this overexpression to improve the 2018 part BBa_K2550000 contributed by Lambert iGEM. When assembled with a distinct RNA sequence complementary to the trigger sequence, the produced blue pigment expression can be characterized based on a Red, Green, Blue (RGB) scale.

Description
Toehold switches are synthetic RNA strands that mimic messenger RNA sequences. They contain a complementary recognition sequence for a specific sequence of RNA stimuli , and a ribosomal binding site where a ribosome binds to initiate the translation of a reporter protein. The switch has a hairpin loop structure that is formed through binding to complementary sections of its own sequence. When in the presence of the complementary trigger sequence the hairpin loop opens to allow downstream expression. The Ribosomal Binding Site and starting sequence are concealed in the toehold switch until initiated. Switches can provide rapid, convenient, in-field detection that can be developed in both cellular systems and cell-free tests.
In the T7 LacZ Toehold construct, the lac operon is induced by lactose and IPTG (isopropyl β-D-1-thiogalactopyranoside); this region of the genome is responsible for transporting and metabolizing lactose. Within the lac operon, the gene, LacZ, codes for the B-galactosidase protein. When this protein is expressed, it breaks down X-gal (5-bromo-4-chloro-3-indolyl-β-D-galactoside) into galactose and an insoluble blue pigment. Therefore, when the gene is synthesized in the chassis, the colonies will appear blue. This mechanism was implemented in the toehold switch construct to identify the presence of specific substances.

Results
Currently, the team is undertaking cloning workflow using Gibson Assembly to assemble these parts. The team used Polymerase Chain Reaction with Gibson primers of the designed LacZ fragments to amplify specific strains. The team then ligated these fragments and transformed using Dh5a cells, which grew colonies.

Sequence and Features