Team:Tec-Monterrey/projectdescription
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Production of sugarcane used to be a high profit activity in the Mexican industry. Nonetheless, the increasing demand of high fructose syrup has become a rising threat to most sugar companies. Our project expects to apply synthetic biology to use sugar, obtained from sugarcane, in an industrial sugar-fructose process intending to make it easier and more profitable. The new genetic construct will be able to immobilize invertase by fusing it to bacterial natural membrane protein fragments using a technique for cell surface display. This system will catalyze the transformation of sucrose into fructose directly, without the need of any chemical or mechanical purification process to obtain the enzyme, reducing the amount of unit operations, and cutting production costs. Also, we will use the same principle to immobilize cellulase, converting cellulose from bagasse into something useful to produce biofuels. | Production of sugarcane used to be a high profit activity in the Mexican industry. Nonetheless, the increasing demand of high fructose syrup has become a rising threat to most sugar companies. Our project expects to apply synthetic biology to use sugar, obtained from sugarcane, in an industrial sugar-fructose process intending to make it easier and more profitable. The new genetic construct will be able to immobilize invertase by fusing it to bacterial natural membrane protein fragments using a technique for cell surface display. This system will catalyze the transformation of sucrose into fructose directly, without the need of any chemical or mechanical purification process to obtain the enzyme, reducing the amount of unit operations, and cutting production costs. Also, we will use the same principle to immobilize cellulase, converting cellulose from bagasse into something useful to produce biofuels. | ||
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Cell surface display is a technique to display proteins on the surface of bacteria, fungi, or mammalian cells by fusing them to surface anchoring motifs. This technique has a wide range of biotechnological and industrial applications, including development of vaccines, peptide and antibody libraries, bioremediation, whole-cell-biocatalysis, and whole-cell-biosensors. When protein is expressed in the outer membrane of E. coli the cell envelope acts as a matrix. It is achievable thanks to several systems as outer membrane porins, lipoproteins, GPI-anchored-proteins, fimbriae, and autotransporters. (Jana S & Deb JK, 2005; Lee SH <i>et al</i>., 2004) Displaying proteins on the cell surface also makes preparing or purifying the protein unnecessary in many instances. Whole cells displaying the molecule of interest can be used in reactions or analytical assays and then can be simply removed by centrifugation. (Joachim J & Meyer TF, 2007) | Cell surface display is a technique to display proteins on the surface of bacteria, fungi, or mammalian cells by fusing them to surface anchoring motifs. This technique has a wide range of biotechnological and industrial applications, including development of vaccines, peptide and antibody libraries, bioremediation, whole-cell-biocatalysis, and whole-cell-biosensors. When protein is expressed in the outer membrane of E. coli the cell envelope acts as a matrix. It is achievable thanks to several systems as outer membrane porins, lipoproteins, GPI-anchored-proteins, fimbriae, and autotransporters. (Jana S & Deb JK, 2005; Lee SH <i>et al</i>., 2004) Displaying proteins on the cell surface also makes preparing or purifying the protein unnecessary in many instances. Whole cells displaying the molecule of interest can be used in reactions or analytical assays and then can be simply removed by centrifugation. (Joachim J & Meyer TF, 2007) | ||
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Joachim J & Meyer TF (2007) The Autodisplay Story, from Discovery to Biotechnical and Biomedical Applications. Microbiology and Molecular Biology Reviews. Vol. 71, No. 4. p. 600–619 | Joachim J & Meyer TF (2007) The Autodisplay Story, from Discovery to Biotechnical and Biomedical Applications. Microbiology and Molecular Biology Reviews. Vol. 71, No. 4. p. 600–619 |