Difference between revisions of "Part:BBa K4348000"
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=Introduction= | =Introduction= | ||
− | + | The McGill iGEM team set out to develop a cholesterol lowering probiotic as a preventative for cardiovascular disease. Both endogenously synthesized cholesterol and dietary cholesterol end up in the gut, where they are absorbed and sent around the body. McGill iGEM’s project consists of developing a novel metabolic pathway to convert cholesterol, which is absorbed in the gut, into coprostanol, a molecule that cannot be absorbed and is thus excreted from the gut. The metabolic pathway consists of a three step pathway with four metabolites: cholesterol, which is converted to cholestenone, then coprostanone and finally coprostanol. We repurposed existing enzymes to engineer a metabolic pathway to do this conversion, then packaged it in a probiotic bacterium. By converting intestinal cholesterol into coprostanol, this probiotic bacterium can prevent cholesterol absorption as a preventative for high cholesterol-induced cardiovascular disease. | |
==Biology== | ==Biology== |
Revision as of 20:22, 13 October 2022
AKR1D1_his
A human 5-beta reductase used in bile acid synthesis. Used in the 2022 McGill project to catalyze the second step of the cholesterol -> coprostanol pathway, which is 4-cholesten-3-one to coprostanone. Coprostanol cannot be absorbed by the gut, which is a unique property.
Introduction
The McGill iGEM team set out to develop a cholesterol lowering probiotic as a preventative for cardiovascular disease. Both endogenously synthesized cholesterol and dietary cholesterol end up in the gut, where they are absorbed and sent around the body. McGill iGEM’s project consists of developing a novel metabolic pathway to convert cholesterol, which is absorbed in the gut, into coprostanol, a molecule that cannot be absorbed and is thus excreted from the gut. The metabolic pathway consists of a three step pathway with four metabolites: cholesterol, which is converted to cholestenone, then coprostanone and finally coprostanol. We repurposed existing enzymes to engineer a metabolic pathway to do this conversion, then packaged it in a probiotic bacterium. By converting intestinal cholesterol into coprostanol, this probiotic bacterium can prevent cholesterol absorption as a preventative for high cholesterol-induced cardiovascular disease.
Biology
Results
AKR1D1 was optimized for IPTG induction concentration, temperature and incubation time for best protein expression yield. 30mL cultures of AKR1D1 were induced and grown at 37˚C for 4 hours, 30˚C for 6 hours, 24˚C for 12 hours and 16˚C for 24 hours with ampicillin and 4mM IPTG. The conditions that yielded the darkest bands were then used for protein purification using his-tag cobalt resin beads.
The flowthrough and dialysis samples AKR1D1 were run on SDS-PAGE. The gel was subsequently stained with coomassie blue stain (figure 1).
We began by assembling our reactions following our tested reaction mixture to confirm the activity of our proteins. We started off by testing our proteins individually to see if they would be able to perform the hypothesized substrate to product conversion. To achieve this we incubated AKR1D1 with cholestenone and then performed an ethyl acetate extraction, derivatization, and resuspension before measuring enzyme activity on GC-MS (figure 2).
A protocol we developed to test proteins without protein purification, which builds off of a pre-existing protocol for protein expression. Liquid cultures of protein-expressing E. coli are pelleted, washed with PBS, frozen at -80°C, resuspended in 2mL PBS. These samples are sonicated on ice, 3 times for 30 second bursts at an amplitude of 20kHz, then spun at 12000 rpm and 4°C for 20 minutes to release proteins into the supernatant. The protein-containing supernatant (potassium phosphate buffer) is extracted and has other reaction components added to it before being run on the GCMS (figure 3).
This allowed us to test AKR1D1 and confirm whether it still maintains activity following our incubation of extract with the appropriate sterol, and cofactor.
Instead of incubating our reactions for 16h, we incubated the reactions for 1h to see if they would still have catalytic activity that would be detectable on the GC-MS (figure 4).
This allowed us to test AKR1D1 and confirm whether it still maintains activity following our reduced incubation time.
Importantly, we also modified our GCMS procedure slightly by incubating our reactions with the derivatization reagent for an hour, instead of immediately evaporating the derivatization reagent after adding it to our reaction. This change greatly increases the detection capability.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]