Team:Lethbridge Canada/The Project
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- | Construct 2 focuses on red fluorescent production and release as a proof of principle for insulin.'' | + | |
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+ | '''Construct 2 focuses on red fluorescent production and release as a proof of principle for insulin.'''<br> | ||
[[Image:Insulin.JPG|center|px]] | [[Image:Insulin.JPG|center|px]] | ||
''Insulin secretion construct containing a pLac promoter, ribosomal binding site, TAT sequence fused to a red fluorescent protein, and a double terminator:'' | ''Insulin secretion construct containing a pLac promoter, ribosomal binding site, TAT sequence fused to a red fluorescent protein, and a double terminator:'' | ||
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'''Delivery System''' <br> | '''Delivery System''' <br> | ||
- | The method of delivery of our organism can be through direct delivery in the bloodstream or through the NASA Bio capsule. It is feasible to use a system that enters the blood stream because there are already millions of E. coli cells in our body, and we can use a strain that does not cause an immune response. Alternatively, the NASA Bio capsule, which is a tangle of carbon nanotubes that will be used to contain particular cells and eventually medicinal substances inside it, could also be used. The capsule could contain our cells, and, should the body need insulin, automatically start secretion. The Bio capsule is tiny, inserted into the skin, non-reactive and fast acting. | + | The method of delivery of our organism can be through direct delivery in the bloodstream or through something such as the NASA Bio capsule. It is feasible to use a system that enters the blood stream because there are already millions of E. coli cells in our body, and we can use a strain that does not cause an immune response. Alternatively, the NASA Bio capsule, which is a tangle of carbon nanotubes that will be used to contain particular cells and eventually medicinal substances inside it, could also be used. The capsule could contain our cells, and, should the body need insulin, automatically start secretion. The Bio capsule is tiny, inserted into the skin, non-reactive and fast acting. |
Revision as of 06:40, 17 June 2012
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Treating type I diabetes: A synthetic biology approachHyperglycemic diabetes mellitus (type I diabetes) is a disorder in which pancreatic beta (insulin-producing) cells within the body are compromised, and results in the inability of the body to control glucose levels. Conventional methods of treatment can have unfavorable implications. Therefore, our team worked on using synthetic biology to derive another, potentially more viable treatment. Our project involves engineering a glucose detection and insulin production/secretion system. As a method of glucose detection, we are utilizing the natural mechanism of glucose-induced gene expression present in Escherichia coli — mlc inhibition coupled with the phosphotransferase system. The induced gene will be red fluorescent protein (RFP) as a proof of principle in place of insulin. In order to secrete insulin (or RFP respectively), we will use N-terminal signal sequences to direct targeting across the cell membrane. We are testing two—twin arginine tag and heat-stable toxin I— to determine their efficiency in secreting proteins.
Worldwide 346 million people suffer from diabetes, including 2.7 million people in Canada. In higher income countries diabetes usually affects people over 50 years of age the most. Lower income countries face double the mortality rate when compared to the higher income countries as a result of diabetes. Diabetes can give someone a predisposition to heart disease and 4 out of 5 diabetic patients die from heart disease. 1 in 3 people who have diabetes are unaware they have it, on average people have diabetes for 7 years before diagnosis. The cost of medication and supplies range from 1,000 to 15,000 dollars every year. It is estimated that diabetes will cost the Canadian health care system 19.2 billion dollars by 2020. (Source: Get Serious | Facts + Stats | Canadian Diabetes Association. In Canadian Diabetes Association. Retrieved June 2012, from http://www.diabetes.ca/getserious/facts/.) Glucose Detection Sensory transduction is a mechanism used by many organisms to monitor their external environments. E. coli detects changes in glucose levels in its environment by means of phosphotransferase system (PTS). This system uses E. coli’s enzyme II, which consists of the membrane-bound protein EIICBGlc, as well as enzyme I (EI), a histidine phosphocarrier protein HPr, and another protein called EIIAGlc. Enzyme II is responsible for the phosphorylation and transportation of glucose into the cell. Mlc is a repressive protein that binds to a specific DNA sequence and prevents it from being transcribed. This regulates the transcription of specific genes so certain proteins are only made when they are needed. This is the mechanism we are going to use to regulate the transcription of the gene for insulin. When glucose enters the cells via enzyme II, it picks up a phosphoryl group that was originally bound to EIICBGlc. The dephosphorylated form of EIICBGlc has a high affinity with Mlc and recruits MCL from its binding site on the DNA sequence. The gene is now free to be transcribed. Due to the fact that this sequence is originally stimulated by an increase in glucose concentration as it enters the cell, it is the perfect circuit for us to use to regulate the production of inulin. Nam, T., Cho, S., Shin, D., Kim, J., Jeong, J., Lee, J., Roe, J., & Kang, S. (2001). The Escherichia coli glucose transport enzyme iicb(glc) recruits the global repressor mlc.
Glucose sensing construct with a promoter, mlc binding sequence, ribosomal binding site, red fluorescent protein and double terminator
Insulin secretion construct containing a pLac promoter, ribosomal binding site, TAT sequence fused to a red fluorescent protein, and a double terminator:
Delivery System
'Full construct containing a promoter, mlc binding site, ribosomal bonding site, TAT signal sequence fused to a red fluorescent protein and a double terminator
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