Team:RHIT/Project
From 2012.igem.org
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<h1>Basic Description</h1> | <h1>Basic Description</h1> | ||
- | The Checkmate project | + | The Checkmate project is designed to address an existing challenge for yeast researchers. The typical test to determine the mating type of haploid cells is laborious and takes about 40 hours. Our goal is to streamline this process and reduce the time required to about four hours. |
<h2>Background</h2> | <h2>Background</h2> | ||
- | + | Haploid and diploid yeast cells both use mitosis to reproduce and grow vegetatively. Diploid cells can also use meiosis to sporulate and produce four haploid spores. To leverage this facile genetic system, it is often necessary to determine the mating type of haploid cells, which are one of two mating types, MATa or MATalpha. Each secretes its own type of mating pheremone and has receptors for the opposite type mating pheromone on its surface. When haploids of opposite mating type encounter one another they costimulate, which activates the mating pheromone response pathway in each. The key transcription factor Ste12 is activated as part of this response. It subsequently binds to Ste12-binding elements to induce expression of other genes necessary for mating and diploid formation. | |
<h2>Current Test</h2> | <h2>Current Test</h2> | ||
The current test for mating type takes several days. It involves mixing the unknown strain with two known tester strains, each of which have a known auxotrophic deficiency, which is different from the auxotrophic deficiency of the known strain. The mixes are then plated on media that is deficient in both substances that are unable to be produced by the haploid strains, such that neither tester strain nor unknown strain can survive as a haploid. If the cells mate, then they get a working copy of their defective gene, so the diploid can survive. Below is a graphic illustrating the current test process.<br /><br /> | The current test for mating type takes several days. It involves mixing the unknown strain with two known tester strains, each of which have a known auxotrophic deficiency, which is different from the auxotrophic deficiency of the known strain. The mixes are then plated on media that is deficient in both substances that are unable to be produced by the haploid strains, such that neither tester strain nor unknown strain can survive as a haploid. If the cells mate, then they get a working copy of their defective gene, so the diploid can survive. Below is a graphic illustrating the current test process.<br /><br /> | ||
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<p>Synthetic biology combines DNA sequences discovered in nature and synthetic DNA sequences designed in the laboratory (parts) to produce new functions in living cells (machines). Different types of regulatory and protein-encoding parts used to engineer useful machines. This approach is being applied to produce various things, including insulin from bacteria and biofuels from algae. And it can be used to address many of the world's grand challenges, from hunger to disease epidemics and alternative energy.</p><br /> | <p>Synthetic biology combines DNA sequences discovered in nature and synthetic DNA sequences designed in the laboratory (parts) to produce new functions in living cells (machines). Different types of regulatory and protein-encoding parts used to engineer useful machines. This approach is being applied to produce various things, including insulin from bacteria and biofuels from algae. And it can be used to address many of the world's grand challenges, from hunger to disease epidemics and alternative energy.</p><br /> | ||
<h2>Yeast background</h2><br /> | <h2>Yeast background</h2><br /> | ||
- | <p>Yeast is a single-celled eukaryote, which means that it shares many properties with cells of multi-cellular organisms, including humans. It is commonly used for laboratory research and commercial applications. Yeast can exist as diploid cells, which have two copies of each chromosome, like most animal cells, or as haploid cells, which have only one copy of each chromosome. Haploid cells also are one of two mating types, MATa or MATalpha. They are, therefore, similar in these respects to animal eggs and sperm. Diploid yeast cells are produced when haploid cells of opposite mating type sense one another and fuse together. What each haploid senses is mating | + | <p>Yeast is a single-celled eukaryote, which means that it shares many properties with cells of multi-cellular organisms, including humans. It is commonly used for laboratory research and commercial applications. Yeast can exist as diploid cells, which have two copies of each chromosome, like most animal cells, or as haploid cells, which have only one copy of each chromosome. Haploid cells also are one of two mating types, MATa or MATalpha. They are, therefore, similar in these respects to animal eggs and sperm. Diploid yeast cells are produced when haploid cells of opposite mating type sense one another and fuse together. What each haploid senses is mating pheromone produced by cells of the opposite mating type. MATa cells produce a-pheromone that binds a-receptors on MATalpha cells, while MATalpha cells produce alpha-pheromone, which binds alpha-receptors on MATa cells. This "cross-signalling" activates the mating pheromone response pathway (MPRP), leading to fusion of the two haploids and formation of a diploid cell.</p><br /> |
<h2>The Checkmate Project</h2><br /> | <h2>The Checkmate Project</h2><br /> | ||
- | <p>Yeast researchers must often determine the mating type of yeast haploids. This is a tedious and time-consuming task, which can take 2-3 days. To streamline the process, we designed a cellular system called Checkmate, which produces a colorful protein in response to | + | <p>Yeast researchers must often determine the mating type of yeast haploids. This is a tedious and time-consuming task, which can take 2-3 days. To streamline the process, we designed a cellular system called Checkmate, which produces a colorful protein in response to pheromone secreted by cells of the opposite mating type. We hope it will simplify the process and reduce the time necessary to identify a haploid's mating type. The system uses a genetic circuit that is turned on when the MPRP of a cell is activated. Once turned on, a positive feedback mechanism will maintain production of the colorful protein, even after the MPRP shuts off. Typical mating type testing will be done by mixing Checkmate mating type detector cells with unknown haploids and examining them for a colorful response. Such a response indicates that the mating type of the unknown is opposite that of the Checkmate detector used in the test.</p><br /> |
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Revision as of 00:36, 4 October 2012