Team:Yale/MaterialsMethods
From 2014.igem.org
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Readymix for sequencing. Sequencing was completed by Keck DNA Sequencing Facility. The alignment was analyzed using Geneious. | Readymix for sequencing. Sequencing was completed by Keck DNA Sequencing Facility. The alignment was analyzed using Geneious. | ||
</p></ul> | </p></ul> | ||
- | < | + | <li> |
- | < | + | <strong>Assembly of T7 Phage Promoter-super-folder GFP in pZA21 backbone</strong> |
</p> | </p> | ||
- | < | + | <ul><li> |
The plasmid pZA21_T7_sfGFP was assembled from a linear fragment of sfGFP with a RBS and T7 promoter attached to the 5’ untranslated region (UTR) amplified | The plasmid pZA21_T7_sfGFP was assembled from a linear fragment of sfGFP with a RBS and T7 promoter attached to the 5’ untranslated region (UTR) amplified | ||
from plasmid pZE21::sfGFP and the pZA21 backbone amplified from pZA21_tRNA_TAGG. The linear fragment of T7_RBS_sfGFP was PCR amplified from pZE21::sfGFP | from plasmid pZE21::sfGFP and the pZA21 backbone amplified from pZA21_tRNA_TAGG. The linear fragment of T7_RBS_sfGFP was PCR amplified from pZE21::sfGFP | ||
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plasmid was dubbed pZE21::T7sfGFP. | plasmid was dubbed pZE21::T7sfGFP. | ||
</p> | </p> | ||
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Screening for the replacement of the original P<sub>LtetO</sub> promoter was verified by sequencing. Sequencing primers for the pZE backbone | Screening for the replacement of the original P<sub>LtetO</sub> promoter was verified by sequencing. Sequencing primers for the pZE backbone | ||
pz-integration-f and pz-integration-r were used with Hifi Hotstart Readymix with the NEB protocol to amplify the multiple cloning site of the pZE21 | pz-integration-f and pz-integration-r were used with Hifi Hotstart Readymix with the NEB protocol to amplify the multiple cloning site of the pZE21 | ||
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analyzed using Geneious. | analyzed using Geneious. | ||
</p> | </p> | ||
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The pZA21 backbone was amplified with primers T7sfGFP_pZA21_F and T7sfGFP_pZA21_R and Hifi Hotstart Readymix with the NEB protocol. The reaction was | The pZA21 backbone was amplified with primers T7sfGFP_pZA21_F and T7sfGFP_pZA21_R and Hifi Hotstart Readymix with the NEB protocol. The reaction was | ||
carried out with an annealing temperature of 56°C and an extension time of 00:03:00. The product was treated with Dpn1 to eliminate remaining template DNA. | carried out with an annealing temperature of 56°C and an extension time of 00:03:00. The product was treated with Dpn1 to eliminate remaining template DNA. | ||
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fragment was PCR purified. | fragment was PCR purified. | ||
</p> | </p> | ||
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A linear fragment of T7_sfGFP was amplified with overhangs to pZA21 containing the restriction sites AatII and BamHI-HF. T7_sfGFP was amplified from | A linear fragment of T7_sfGFP was amplified with overhangs to pZA21 containing the restriction sites AatII and BamHI-HF. T7_sfGFP was amplified from | ||
pZE21::T7sfGFP previously constructed using primers pZE21_T7sfGFP_AatII_F and pZA21_T7sfGFP_BamHI_R and Hifi Hotstart Readymix with the NEB protocol. The | pZE21::T7sfGFP previously constructed using primers pZE21_T7sfGFP_AatII_F and pZA21_T7sfGFP_BamHI_R and Hifi Hotstart Readymix with the NEB protocol. The | ||
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restriction enzymes AatII and BamHI-HF. The resulting fragment was PCR purified. | restriction enzymes AatII and BamHI-HF. The resulting fragment was PCR purified. | ||
</p> | </p> | ||
- | < | + | <li> |
A ligation reaction using T4 DNA ligase from NEB was conducted with the fragment of PZA21 backbone and T7sfGFP following the NEB protocol. Following the | A ligation reaction using T4 DNA ligase from NEB was conducted with the fragment of PZA21 backbone and T7sfGFP following the NEB protocol. Following the | ||
ligation, 5 μL of the reaction mixture was transformed into Mach1 cells. The colonies were picked the next day and grown up overnight. Liquid culture were | ligation, 5 μL of the reaction mixture was transformed into Mach1 cells. The colonies were picked the next day and grown up overnight. Liquid culture were | ||
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<h1 style="margin-top:15px; margin-bottom:25px; font-size:35px;text-align:center;">Anti-Microbial Peptide Construct</h1> | <h1 style="margin-top:15px; margin-bottom:25px; font-size:35px;text-align:center;">Anti-Microbial Peptide Construct</h1> | ||
<div class = "well"> | <div class = "well"> | ||
- | < | + | <ol type="I"><li><strong>Strains, Plasmids, and Reagents</strong><ul style="list-style-type:square"> |
- | The construct sequence was synthesized by Genscript and shipped as pUC57-Kan_2StrepFLAGLLFP151GFP, and transplanted to the pZE21 plasmid, pZE21_2StrepFLAGLLFP151GFP (BBa_K1396000). | + | <li><strong>Construct Synthesis and Expression: Strains, Plasmids, and Reagents</strong> <br /> |
- | + | <ul><li>The construct sequence was synthesized by Genscript and shipped as pUC57-Kan_2StrepFLAGLLFP151GFP, and transplanted to the pZE21 plasmid, pZE21_2StrepFLAGLLFP151GFP (BBa_K1396000). | |
+ | |||
All plasmids were first grown in Mach1, then purified and retransformed into C31POE.ompT.lon.endA.ΔtolC, a recoded strain with all amber stop codons (TAG) replaced, and Release Factor 1 replaced with Streptomycin resistance. It is thus able to encode nonstandard amino acids such as L-DOPA, the incorporation of which is facilitated by the DOPA orthogonal translation system (OTS). | All plasmids were first grown in Mach1, then purified and retransformed into C31POE.ompT.lon.endA.ΔtolC, a recoded strain with all amber stop codons (TAG) replaced, and Release Factor 1 replaced with Streptomycin resistance. It is thus able to encode nonstandard amino acids such as L-DOPA, the incorporation of which is facilitated by the DOPA orthogonal translation system (OTS). | ||
<br /> | <br /> | ||
- | A second strain was made with the Tyrosine suppressor system transformed instead, so the construct can be expressed with tyrosines in the place of L-DOPA, as L-DOPA is very toxic to cells. The construct was then separated into smaller constructs such as pZE21_LLFP151 (BBa_K1396001), pZE21_FP151GFP (BBa_K1396002), pZE21_FP151 (BBa_K1396003). | + | <li>A second strain was made with the Tyrosine suppressor system transformed instead, so the construct can be expressed with tyrosines in the place of L-DOPA, as L-DOPA is very toxic to cells. The construct was then separated into smaller constructs such as pZE21_LLFP151 (BBa_K1396001), pZE21_FP151GFP (BBa_K1396002), pZE21_FP151 (BBa_K1396003). |
</p> | </p> | ||
- | + | </ul> | |
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<strong> We hypothesize that we can develop an improved version of the current adhesives by developing a fusion protein of Mgfp-5 with Mefp-1 as the anchoring region for the anti-biofouling peptide. </strong> An integral part of developing this peptide is to co-translationally insert L-DOPA into our peptide, which has never been done before with mussel foot proteins (Figure 1). In this process of orthogonal translation, we first will get rid of the UAG stop codon and then transform the strain to synthesize tRNA and tRNA transferase that corresponds to the UAG codon and the L-DOPA non-standard amino acid to develop the genetically recoded organism (GRO). The advantage of this procedure is that we have the ability to skip the time-consuming and inefficient tyrosinase enzyme treatment step. | <strong> We hypothesize that we can develop an improved version of the current adhesives by developing a fusion protein of Mgfp-5 with Mefp-1 as the anchoring region for the anti-biofouling peptide. </strong> An integral part of developing this peptide is to co-translationally insert L-DOPA into our peptide, which has never been done before with mussel foot proteins (Figure 1). In this process of orthogonal translation, we first will get rid of the UAG stop codon and then transform the strain to synthesize tRNA and tRNA transferase that corresponds to the UAG codon and the L-DOPA non-standard amino acid to develop the genetically recoded organism (GRO). The advantage of this procedure is that we have the ability to skip the time-consuming and inefficient tyrosinase enzyme treatment step. | ||
</p><br> | </p><br> | ||
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<p style = "padding-top:20px;"> | <p style = "padding-top:20px;"> | ||
- | <strong>Protein Purification</strong> | + | <li><strong>Protein Purification</strong> |
- | We plan to purify the protein by using the Twin Strep Tag in tandem with the | + | We plan to purify the protein by using the Twin Strep Tag in tandem with the FLAG tag, which was included in our master construct of the anti-biofouling peptide (Figure 2). |
</p><br> | </p><br> | ||
<center><img src ="https://static.igem.org/mediawiki/2014/3/39/IGEM_construct_Design_wiki.png" width = "600" height = "auto"></img> <br /> | <center><img src ="https://static.igem.org/mediawiki/2014/3/39/IGEM_construct_Design_wiki.png" width = "600" height = "auto"></img> <br /> | ||
- | <i><strong>Figure 2. </strong>A diagram illustrating the components in our final construct. The Twin Strep and | + | <i><strong>Figure 2. </strong>A diagram illustrating the components in our final construct. The Twin Strep and FLAG tags are indicated.</i></center><br> |
<p> | <p> | ||
- | The | + | <ul><li>The FLAG tag is perfectly cleavable by the enzyme enterokinase. The FLAG tag is made up of 8 amino acids and works well for low-abundance proteins. It is hydrophilic, so it will most likely not interfere with protein folding and function of the target protein. The Strep tag is also made up of 8 amino acids that will not disturb the protein’s functions. We chose the FLAG tag because it is perfectly cleavable. The protein will be purified in a Strep-Tactin<sup>R</sup> Sepharose<sup>R</sup> column. In order to address the adhesive L-DOPA component, our final step is to elute with a base to reduce the amount of the anti-biofouling peptide that sticks to the column due to L-DOPA adhesion (Figure 3).</p> |
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<div class = "well"> | <div class = "well"> | ||
<p> | <p> | ||
- | <ul><li><strong><u>Adhesion:</u></strong> <ul><li><strong> Subject peptide coated surfaces to liquid erosion: </strong><ul><li>A number of ASTM assays used in industrial coating testing were investigated, but none offered the level of quantitation desired for our applications. Therefore, an original rig was designed and built to introduce liquid based erosion by laminar flow through a bath. This system directly mimics the drag that a coated surface might experience on a ship's hull. Precise specifications of the rig are provided in a separate section below.</ul><br> | + | <ol type="I"><li><strong>Strains, Plasmids, and Reagents</strong><ul style="list-style-type:square"> |
+ | <li><strong><u>Adhesion:</u></strong> <ul><li><strong> Subject peptide coated surfaces to liquid erosion: </strong><ul><li>A number of ASTM assays used in industrial coating testing were investigated, but none offered the level of quantitation desired for our applications. Therefore, an original rig was designed and built to introduce liquid based erosion by laminar flow through a bath. This system directly mimics the drag that a coated surface might experience on a ship's hull. Precise specifications of the rig are provided in a separate section below.</ul><br> | ||
<center><img src="https://static.igem.org/mediawiki/2014/thumb/d/d5/Erosion_Rig_Image.png/800px-Erosion_Rig_Image.png"></center> | <center><img src="https://static.igem.org/mediawiki/2014/thumb/d/d5/Erosion_Rig_Image.png/800px-Erosion_Rig_Image.png"></center> | ||
<p> | <p> | ||
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<p> | <p> | ||
<center> | <center> | ||
- | <i><strong>Figure 6.</strong> This diagram illustrates how a DNA handle can be linked to a protein of interest to bind the protein to an optical tweezer bead into which the high intensity laser can be fired to engender a pull force. We intend to conduct a similar protocol with our adhesive peptide. <sup> | + | <i><strong>Figure 6.</strong> This diagram illustrates how a DNA handle can be linked to a protein of interest to bind the protein to an optical tweezer bead into which the high intensity laser can be fired to engender a pull force. We intend to conduct a similar protocol with our adhesive peptide.<sup>23</sup> This measurement was conducted with the assistance of Dr. Junyi Jiao in the lab of Dr. Yongli Zhang from the Yale Department of Cell Biology.</i> |
</center> | </center> | ||
- | </p> | + | </p></ul> |
+ | <li><strong>Preparation of Cell-Tak<sup>TM</sup> films</strong><ul><li> | ||
+ | Cell-Tak<sup>TM</sup> is a mixture of mussel foot proteins 1 and 2 in an approximate 75% to 25% ratio, respectively. The protocol used to deposit Cell-Tak<sup>TM</sup>relies upon the property of L-DOPA to come out of solution when the pH is increased. Cell-Tak<sup>TM</sup> is constituted in 5% acetic acid. To prepare a film, 10 µL of a 2.36 mg/mL Cell-Tak<sup>TM</sup> solution was spotted onto the substrate. To trigger binding, 10 µL of 0.2 M sodium bicarbonate was added to increase the pH to ~8-9. Films were then allowed to dry for 30 min at 37ºC and then washed with DI water. Prepared films were stored in an incubator until ready for use. | ||
+ | <li>Spin coating was investigated as a new modality for depositing a protein monolayer. However, the hydrophobicity of the protein did not allow for adequate wetting of the substrates by Cell-Tak<sup>TM</sup> for proper spin coating. In addition, a method used for hydrogel preparation involving incubation of a coverslip in Rain-X was tested to deposit protein layers. A coverslip was coated in Cell-Tak<sup>TM</sup> and then covered by the super hydrophobic Rain-X coated coverslip. The coverslips were then pulled apart and the protein coated surface was allowed to dry. However, the consistency in thickness desired for our application made the precipitation preparation the method we chose as our standard. | ||
</div> | </div> | ||
Latest revision as of 03:37, 18 October 2014
Materials and Methods |
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T7 Riboregulation System
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Anti-Microbial Peptide Construct
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Methods for Assaying Coating Adhesion Properties |
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