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<p align="left" class="classtheinlinecontent"><strong style="font-size:25px; color: rgb(183, 1, 1);">Expression and Purification of Enzymes</strong></p> | <p align="left" class="classtheinlinecontent"><strong style="font-size:25px; color: rgb(183, 1, 1);">Expression and Purification of Enzymes</strong></p> | ||
| - | <p class = "classtheoverview"> <strong>Gibson Assembly</strong></p> | + | <p align="left" class = "classtheoverview"> <strong>Gibson Assembly</strong></p> |
| + | <p class="classtheinlinecontent2">Scientists have long possessed the knowledge to synthesize natural and synthetic DNA sequences by combining two or more pieces of DNA. Known as recombinant DNA technology, these methods became widely used upon the discovery of endonucleases and DNA ligases. Over the years, methods have become increasingly efficient, leading to many new research discoveries. In 2009, Daniel Gibson published a paper outlining his efficient new method to combine and clone large pieces of DNA. Additionally, the method provides greater selectivity than previous cloning methods involving restriction enzymes. The method described by Gibson involves the use of commercially available enzymes, namely Taq DNA ligase (New England Biolabs, NEB), Phusion DNA polymerase (NEB), and T5 exonuclease (Epicentre).</p> | ||
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<p align="left" class = "classtheinlinecontent2">The Gibson Assembly utilizes three enzymes: (1) a thermostable DNA ligase; (2) a 5’-exonuclease; and, (3) a thermostable DNA polymerase, in an isothermal reaction to assemble together DNA fragments containing 20-40 base pair overlaps. The reaction proceeds as shown in figure 1: First, the exonuclease chews back the 5' ends of the overlapping pieces of DNA, allowing them to anneal. The amount of exonuclease must be finely tuned so that long enough sticky ends are created for the overlaps to anneal before the exonuclease becomes heat inactivated, but not a large enough amount of exonuclease that the DNA is destroyed. The polymerase then fills in the gaps created by the exonuclease until the ligase can join the strand, creating a single, unscarred, double-stranded piece.</p> | <p align="left" class = "classtheinlinecontent2">The Gibson Assembly utilizes three enzymes: (1) a thermostable DNA ligase; (2) a 5’-exonuclease; and, (3) a thermostable DNA polymerase, in an isothermal reaction to assemble together DNA fragments containing 20-40 base pair overlaps. The reaction proceeds as shown in figure 1: First, the exonuclease chews back the 5' ends of the overlapping pieces of DNA, allowing them to anneal. The amount of exonuclease must be finely tuned so that long enough sticky ends are created for the overlaps to anneal before the exonuclease becomes heat inactivated, but not a large enough amount of exonuclease that the DNA is destroyed. The polymerase then fills in the gaps created by the exonuclease until the ligase can join the strand, creating a single, unscarred, double-stranded piece.</p> | ||
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<img src="https://mywebspace.wisc.edu/mtschmitz/website%20files/gibson1.png"> | <img src="https://mywebspace.wisc.edu/mtschmitz/website%20files/gibson1.png"> | ||
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<img src="https://mywebspace.wisc.edu/mtschmitz/website%20files/gibsongene2.jpg"> | <img src="https://mywebspace.wisc.edu/mtschmitz/website%20files/gibsongene2.jpg"> | ||
<p align="left" class = "classtheinlinecontent2">Because of its simplicity and versatility, it is a very common cloning technique, however, the cost of the enzymes can be prohibitive for teams with small budgets. Therefore, we have provided an expression vector for T5 exonuclease and taq ligase, as well as a protocol for their expression and purification.</p> | <p align="left" class = "classtheinlinecontent2">Because of its simplicity and versatility, it is a very common cloning technique, however, the cost of the enzymes can be prohibitive for teams with small budgets. Therefore, we have provided an expression vector for T5 exonuclease and taq ligase, as well as a protocol for their expression and purification.</p> | ||
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| + | <p align="left" class = "classtheinlinecontent2">This groundbreaking new method has proven useful in many labs, but the expense of the necessary enzymes may be costly for smaller research labs and universities. To overcome this problem, we synthesized and cloned Pfu polymerase, Taq Ligase, and T5 exonuclease, essentially creating our own in-house enzyme mixture. A lawyer at the UW-Madison Law & Entrepreneurship Clinic was contacted regarding the legality of synthesizing these patented enzymes. It was determined that we were not infringing on the patent, as the project’s only motivation was to satisfy our idle curiosity, and is not intended bring our lab group financial gain or significant notoriety. We hope this project will be a helpful educational tool for introductory biology students, which also producing something useful and meaningful. </p> | ||
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<p class = "classtheoverview"> <strong>Purification of Enzymes</strong></p> | <p class = "classtheoverview"> <strong>Purification of Enzymes</strong></p> | ||
Revision as of 01:02, 20 September 2013
Expression and Purification of Enzymes
Gibson Assembly
Scientists have long possessed the knowledge to synthesize natural and synthetic DNA sequences by combining two or more pieces of DNA. Known as recombinant DNA technology, these methods became widely used upon the discovery of endonucleases and DNA ligases. Over the years, methods have become increasingly efficient, leading to many new research discoveries. In 2009, Daniel Gibson published a paper outlining his efficient new method to combine and clone large pieces of DNA. Additionally, the method provides greater selectivity than previous cloning methods involving restriction enzymes. The method described by Gibson involves the use of commercially available enzymes, namely Taq DNA ligase (New England Biolabs, NEB), Phusion DNA polymerase (NEB), and T5 exonuclease (Epicentre).
The Gibson Assembly utilizes three enzymes: (1) a thermostable DNA ligase; (2) a 5’-exonuclease; and, (3) a thermostable DNA polymerase, in an isothermal reaction to assemble together DNA fragments containing 20-40 base pair overlaps. The reaction proceeds as shown in figure 1: First, the exonuclease chews back the 5' ends of the overlapping pieces of DNA, allowing them to anneal. The amount of exonuclease must be finely tuned so that long enough sticky ends are created for the overlaps to anneal before the exonuclease becomes heat inactivated, but not a large enough amount of exonuclease that the DNA is destroyed. The polymerase then fills in the gaps created by the exonuclease until the ligase can join the strand, creating a single, unscarred, double-stranded piece.
Figure 1. Gibson, D.G. et al. Nat. Methods 343-345 (2009)
The Gibson Assembly is extremely useful for cloning. As the figure below shows, a gene can be designed to overlap a backbone plasmid. PCR can then be used to create the overlapping insert and backbone pieces, which can then be Gibson assembled.
Because of its simplicity and versatility, it is a very common cloning technique, however, the cost of the enzymes can be prohibitive for teams with small budgets. Therefore, we have provided an expression vector for T5 exonuclease and taq ligase, as well as a protocol for their expression and purification.
This groundbreaking new method has proven useful in many labs, but the expense of the necessary enzymes may be costly for smaller research labs and universities. To overcome this problem, we synthesized and cloned Pfu polymerase, Taq Ligase, and T5 exonuclease, essentially creating our own in-house enzyme mixture. A lawyer at the UW-Madison Law & Entrepreneurship Clinic was contacted regarding the legality of synthesizing these patented enzymes. It was determined that we were not infringing on the patent, as the project’s only motivation was to satisfy our idle curiosity, and is not intended bring our lab group financial gain or significant notoriety. We hope this project will be a helpful educational tool for introductory biology students, which also producing something useful and meaningful.
Purification of Enzymes
Following the completion of purification, a number of tests were carried out to verify the legitimacy of the protocol. Firstly, the eluted protein fraction from the Ni-NTA columns were tested against an uninduced control to ensure that a protein of interest had in fact been expressed and purified. This was done by SDS-PAGE electrophoresis. These results for taq ligase are shown in figure 2 and the results for T5 exonuclease are shown in figure 3, below.
Figure 2. This gel shows elution fractions from the taq ligase purification. It can be seen that taq ligase is expressed in very large amounts in the fractions from induced cells(extremely dark band). It can also be seen that the elution is significantly more pure than the unpurified fractons. Although a smaller band of taq ligase can be seen in samples from the uninduced fractions, the expression in the uninduced cells can be attributed to leakyness in the T7 expression system.
Figure 3. This gel shows elution fractions from the T5 exonuclease purification. It can be seen that T5 is expressed in very large amounts in the fractions from induced cells(extremely dark band). It can also be seen that the eluted fraction has significantly fewer impurities than the unpurified fractons. Although a smaller band of T5 Exonuclease can be seen in samples from the uninduced fractions, the expression in the uninduced cells can be attributed to leakyness in the T7 expression system.
Once the expression had been verified, the protein concentration of the purified enzyme was found to be
1709 × 1080
