Difference between revisions of "Team:OLS Canmore AB CA/Description"
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− | <td><p>This year our team chose to tackle the hairy global problem of keratin waste build-up. We are working to solve this issue by constructing a | + | <td><p>This year our team chose to tackle the hairy global problem of keratin waste build-up. We are working to solve this issue by constructing a Keratinase-expressing E. coli system that will break down the keratin protein, leading to the rapid degradation of both hair and feathers in industrial waste streams. |
− | The reason that both hair and feathers present waste-management problems is that they are made up of the same protein: keratin. Keratin is one of the strongest proteins found in nature due to its hydrogen bonds, disulphide bonds, and its tightly wrapped helixes (1), or parallel sheets of polypeptide chains with amino acids (3). Keratinase is a proteolytic enzyme that is capable of breaking the strong bonds that hold keratin together. In nature, keratinases are expressed in a variety of organisms, including bacteria and fungi, which exist in many different habitats. These habitats include Antarctic soils, soybean waste, Mediterranean Sea, solfataric muds, polluted rivers, and hot springs (2). The current understanding of | + | The reason that both hair and feathers present waste-management problems is that they are made up of the same protein: keratin. Keratin is one of the strongest proteins found in nature due to its hydrogen bonds, disulphide bonds, and its tightly wrapped helixes (1), or parallel sheets of polypeptide chains with amino acids (3). Keratinase is a proteolytic enzyme that is capable of breaking the strong bonds that hold keratin together. In nature, keratinases are expressed in a variety of organisms, including bacteria and fungi, which exist in many different habitats. These habitats include Antarctic soils, soybean waste, Mediterranean Sea, solfataric muds, polluted rivers, and hot springs (2). The current understanding of Keratinase shows the Bacillus genera to be the most prominent natural Keratinase producers (2).</p></td> |
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− | <td><p>Designing a biological system that can produce functional | + | <td><p>Designing a biological system that can produce functional Keratinase at a low cost and high output rate provides an opportunity for real improvement on the current reality of keratin waste management. Aside from the industrial applications already discussed, Keratinases can have expanded application value in the cosmetic industry; as a natural alternative to caustic drain cleaner products; in the leather production industry, to assist in dehairing hides; or as an animal feed supplement, allowing livestock to receive more nutrients from their food (2). |
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<p font-size="12px"><strong>Citations:</strong> | <p font-size="12px"><strong>Citations:</strong> |
Revision as of 19:32, 18 September 2015
Description
This year our team chose to tackle the hairy global problem of keratin waste build-up. We are working to solve this issue by constructing a Keratinase-expressing E. coli system that will break down the keratin protein, leading to the rapid degradation of both hair and feathers in industrial waste streams. The reason that both hair and feathers present waste-management problems is that they are made up of the same protein: keratin. Keratin is one of the strongest proteins found in nature due to its hydrogen bonds, disulphide bonds, and its tightly wrapped helixes (1), or parallel sheets of polypeptide chains with amino acids (3). Keratinase is a proteolytic enzyme that is capable of breaking the strong bonds that hold keratin together. In nature, keratinases are expressed in a variety of organisms, including bacteria and fungi, which exist in many different habitats. These habitats include Antarctic soils, soybean waste, Mediterranean Sea, solfataric muds, polluted rivers, and hot springs (2). The current understanding of Keratinase shows the Bacillus genera to be the most prominent natural Keratinase producers (2). |
Picture from http://blogs.inquirer.net/insidescience/2008/08/01/filipino-scientist-finds-good-use-for-chicken-feathers/
Picture from http://slocumbros.com/category/news/ and the San Antonio Water System |
Our inspiration to tackle the issue of hair and feather build came from a cartoon that was published in our local paper entitled “The Epic Poo Race”. This cartoon was published as a funny way to educate the public about the issue that was affecting our town. Hair being flushed into wastewater treatment systems was getting tangled and trapped to the point of restricting the flow of sewage. |
Photo courtesy of the Town of Canmore |
From visiting our local waste water treatment plant we learnt the following. These build-ups of hair can be so damaging that they can stop pumps from working leading to backup, blockages, and the breakage of many wastewater treatment components costing millions in repairs. Perhaps the worst thing about this issue is how the hair is currently removed from the waste treatment facilities. These clogs, no matter their size, must be removed manually by the unlucky worker given this terrible task. Our team knew there must be a better way to tackle this problem. Of course, we thought that synthetic biology would be the perfect answer to this problem. |
Team member Alina Arvisais at the Canmore Waste Water Treatment Plant |
From visiting our local waste water treatment plant we learnt the following. These build-ups of hair can be so damaging that they can stop pumps from working leading to backup, blockages, and the breakage of many wastewater treatment components costing millions in repairs. Perhaps the worst thing about this issue is how the hair is currently removed from the waste treatment facilities. These clogs, no matter their size, must be removed manually by the unlucky worker given this terrible task. Our team knew there must be a better way to tackle this problem. Of course, we thought that synthetic biology would be the perfect answer to this problem. |
Designing a biological system that can produce functional Keratinase at a low cost and high output rate provides an opportunity for real improvement on the current reality of keratin waste management. Aside from the industrial applications already discussed, Keratinases can have expanded application value in the cosmetic industry; as a natural alternative to caustic drain cleaner products; in the leather production industry, to assist in dehairing hides; or as an animal feed supplement, allowing livestock to receive more nutrients from their food (2).
Citations:
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