Team:Jefferson VA SciCOS/Results
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'''Testing''' | '''Testing''' | ||
- | We hoped to determine KGF and FGF production by our transformed E. coli under hypoxic and anoxic conditions. However, we ran out of time and resources to test our bacteria. | + | We hoped to determine KGF and FGF production by our transformed E. coli under hypoxic and anoxic conditions. However, we ran out of time and resources to completely test our bacteria. But if we did have additional time and money, we would test them with the following protocol. |
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We were ultimately unsuccessful in our efforts to create a genetically engineered | We were ultimately unsuccessful in our efforts to create a genetically engineered | ||
bacteria that would create growth factor in anaerobic conditions to aid in wound healing. However, our team gained powerful insight into our subject area. Our teacher and mentor, Dr. Burnett, once said that when you first start something, you should make as many mistakes as quickly as possible because that’s the best way to learn. We have certainly accomplished this and look forward to next year, when we can use what we learned to create a fantastic and impactful iGEM project! | bacteria that would create growth factor in anaerobic conditions to aid in wound healing. However, our team gained powerful insight into our subject area. Our teacher and mentor, Dr. Burnett, once said that when you first start something, you should make as many mistakes as quickly as possible because that’s the best way to learn. We have certainly accomplished this and look forward to next year, when we can use what we learned to create a fantastic and impactful iGEM project! | ||
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+ | '''Works Cited''' | ||
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+ | Fox, Sue. WHOLE CELL EXTRACT PREPARATION. Molecular Biology Science Retrieved from http://groups.molbiosci.northwestern.edu/morimoto/research/Protocols/III.%20Proteins/C.%20DNA-Protein%20Interactions/2.%20Whole%20cell%20extract.pdf | ||
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+ | Human Keratinocyte Growth Factor(KGF) ELISA Kit. My Bio Source. Retrieved from http://www.mybiosource.com/images/tds/protocol_others/MBS268958.pdf | ||
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+ | Tastan, C. (2009, October). Oxygen promoter-Vitreoscilla hemoglobin(VHb) promoter in E. coli. Igem. Retrieved from http://parts.igem.org/Part:BBa_K258005. | ||
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+ | (2009 February, 9). Bacterial Cell Culture. Open Wet Ware. Retrieved from http://openwetware.org/wiki/Bacterial_cell_culture | ||
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Latest revision as of 04:03, 22 June 2013
Background Wound healing is an integral part of everyday life. From a tiny paper cut to a large burn, wound healing is a vital life process that we depend on everyday. The process of wound healing is a process made up of four constructed steps. The first of these steps is called hematosis. During this stage of wound healing, vascular constriction occurs along with platelet aggregation, degranulation, and fibrin formation (thrombus). During the next step of the healing process, called the inflammatory stage, white blood cells eat away any dead tissue. This step also involves the formation of neutrophils, the infiltration of lymphocytes and monocytes, and the differentiation of monocytes to macrophages. The third step, proliferation, includes re-epithelialization, angiogenesis (the formation of blood vessels), collagen synthesis, and ECM formation. This step is very important in the wound healing process as it ensures that the wound will heal completely. The final step of wound healing is collagen remodeling and vascular maturation and regeneration.
We hoped to determine KGF and FGF production by our transformed E. coli under hypoxic and anoxic conditions. However, we ran out of time and resources to completely test our bacteria. But if we did have additional time and money, we would test them with the following protocol.
We expected our bacteria to be able to respond to changes in oxygen levels by creating a maximum level of growth factor at a 2% oxygen threshold. When the oxygen levels are lower than 2%, we expected to observe a sharp decrease in production, and when oxygen levels are higher than 2%, we expected to observe a decrease in production in between the 2% and 3% threshold, with a linear increase in production for all thresholds above 3%. Oxygen thresholds below 2% should result in a sharp decrease in production of growth factor because the oxygen-dependent control mechanisms used by the promoter cause production to be maximally induced under hypoxic but not completely anaerobic conditions in E.coli. 2% is the ideal oxygen threshold according to the control mechanisms, but slightly higher thresholds should also produce significant yields.
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Works Cited |
Fox, Sue. WHOLE CELL EXTRACT PREPARATION. Molecular Biology Science Retrieved from http://groups.molbiosci.northwestern.edu/morimoto/research/Protocols/III.%20Proteins/C.%20DNA-Protein%20Interactions/2.%20Whole%20cell%20extract.pdf
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