Difference between revisions of "Part:BBa K3352009"

 
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The composite part utilizes a T7 Promoter (BBa_J64997), extended RBS (BBa_K3352002), Φ29 polymerase (BBa_K3352001), and a T7 Terminator (BBa_K3352003).
 
The composite part utilizes a T7 Promoter (BBa_J64997), extended RBS (BBa_K3352002), Φ29 polymerase (BBa_K3352001), and a T7 Terminator (BBa_K3352003).
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<b><font size="+1.2"> Construct Design </font></b>
 
<b><font size="+1.2"> Construct Design </font></b>
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<b><font size="+1.2"> Improvement of an Existing Part </font></b>
 
<b><font size="+1.2"> Improvement of an Existing Part </font></b>
  
We optimized the protein coding region for Φ29 DNA polymerase by adding a N-terminal 6x histidine tag and a GS linker (BBa_K3352001). This improves the existing Φ29 DNA polymerase (BBa_K2918034) from team TUDelft 2019. To test whether our improved sequence was better, we expressed our Φ29 (BBa_K3352009), which contains (BBa_K3352001) alongside TUDelft’s (BBa_K2918034) and analyzed the expression levels by SDS-PAGE. We grew bacterial cultures overnight at 37°C. We then diluted the cultures to an OD600 of 0.2 and grew them to an OD600 of 0.5, at which point we collected a 1mL sample. We then added IPTG and grew the cultures for another 4 hours after which another 1mL sample was collected. We centrifuged all samples and resuspended the pellets in 1x Sample Buffer and performed SDS-PAGE analysis. In our protein gel, we saw that our construct was able to better express Φ29 polymerase, especially after inducing it with IPTG, relative to the pre-existing part (Figure 4). To further confirm that the observed band was indeed Φ29 polymerase, we purified the enzyme using Ni sepharose affinity chromatography. The results showed a clear band at 68.2 kDa for the elution fractions that were not present in the flow-through or wash fractions, indicating that we successfully expressed and purified His-tagged Φ29 polymerase (Figure 5).
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We optimized the protein coding region for Φ29 DNA polymerase for high expression in E. coli. We also inserted 3 additional codons that should be present as found in the Φ29 DNA polymerase amino acid sequence in the parent organism Bacillus phage Φ29. To isolate the enzyme after expression, we added  a N-terminal 6x histidine tag to the Φ29 DNA polymerase sequence through a GS linker (BBa_K3352001). This improves the existing Φ29 DNA polymerase sequence (BBa_K2918034) from team TUDelft 2019. To test whether our improved sequence was better, we expressed our Φ29 DNA polymerase (BBa_K3352009), which contains (BBa_K3352001) alongside TUDelft’s (BBa_K2918034) and analyzed the expression levels by SDS-PAGE. We grew bacterial cultures overnight at 37°C. We then diluted the cultures to an OD600 of 0.2 and grew them to an OD600 of 0.5, at which point we collected a 1mL sample. We then added IPTG and grew the cultures for another 4 hours after which another 1mL sample was collected. We centrifuged all samples and resuspended the pellets in 1x Sample Buffer and performed SDS-PAGE analysis. In our protein gel, we saw that our construct was able to better express Φ29 polymerase, especially after inducing it with IPTG, relative to the pre-existing part (Figure 4). To further confirm that the observed band was indeed Φ29 polymerase, we purified the enzyme using Ni sepharose affinity chromatography. The results showed a clear band at 68.2 kDa for the elution fractions that were not present in the flow-through or wash fractions, indicating that we successfully expressed and purified His-tagged Φ29 polymerase (Figure 5).
  
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https://2020.igem.org/wiki/images/d/dd/T--TAS_Taipei--Registry_12.png
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<b>Figure 4: Comparison between part (BBa_K2918034) and part (BBa_K3352009) showing our improved Φ29 construct. We can clearly see a band that is around 68kDa in the post-induced pET T7 promoter and Φ29 construct (red) that is not present in the post-induced TUDelft 2019 Φ29 construct (blue), which suggests that our construct can better express Φ29 DNA Polymerase.</b>
  
 
https://2020.igem.org/wiki/images/4/49/T--TAS_Taipei--Registry_6.png
 
https://2020.igem.org/wiki/images/4/49/T--TAS_Taipei--Registry_6.png
 
   
 
   
  
<b>Figure 4: Comparison between part (BBa_K2918034) and part (BBa_K3352009) showing our improved Φ29 construct. We can clearly see a band that is around 68kDa in the post-induced pET T7 promoter and Φ29 construct (red) that is not present in the post-induced TUDelft 2019 Φ29 construct (blue), which suggests that our construct can better express Φ29 DNA Polymerase.</b>
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<b>Figure 5: Comparison between part (BBa_K2918034) and part (BBa_K3352009) showing our improved Φ29 construct. We can clearly see a band that is around 68kDa in the post-induced pET T7 promoter and Φ29 construct (red) that is not present in the post-induced TUDelft 2019 Φ29 construct (blue), which suggests that our construct can better express Φ29 DNA Polymerase.</b>
  
  

Latest revision as of 13:34, 25 October 2020


T7 + New RBS & Terminator + Phi29 DNA Polymerase Expressing Construct

The composite part utilizes a T7 Promoter (BBa_J64997), extended RBS (BBa_K3352002), Φ29 polymerase (BBa_K3352001), and a T7 Terminator (BBa_K3352003).


Construct Design

We improved the constructs (BBa_K3352006) and (BBa_K33352007) by using the pET11a vector with appropriate BioBrick prefixes and suffixes that fulfill the assembly standard. The pET vector includes the T7 promoter, which promotes high level transcription. By utilizing both a T7 promoter, T7 terminator, and an extended UTR sequence around the RBS and before the terminator, we would maximize the protein expression for our enzymes. These composite parts were synthesized by GenScript.


800px-T--TAS_Taipei--Experimental_9.png

Figure 1: T7 + New RBS & Terminator + Phi29 DNA Polymerase Expressing Construct


Characterization


pET11a Promoter with Extended RBS and T7 Terminator

We also aimed to improve this construct by using a pET11a vector with appropriate BioBrick prefixes and suffixes that fulfill the assembly standard. pET vectors include the T7 promoter, which promotes high level transcription [1]. By utilizing both a T7 promoter, T7 terminator, and an extended UTR sequence around the RBS and before the terminator, we can maximize protein expression for our enzymes (Figure 2) [1]. These composite parts were synthesized by GenScript.

T--TAS_Taipei--Registry_13.png

Figure 2: Characterization of the pET T7 promoter with Φ29 polymerase (BBa_K3352009) construct and pET T7 promoter with SplintR (BBa_K3352008). We digested both constructs at the XbaI and PstI sites. The part (BBa_K3352001) was ligated into a pET11a backbone that is about 5500bps to form part (BBa_K3352009). Similarly, the part (BBa_K3352000) was ligated into pET3a backbone with a size of 4400bps which forms part (BBa_K3352008).


Protein Expression and Purification

We transformed our plasmids into BL21(DE3) E. coli cells. We grew bacterial cultures overnight at 37°C, diluted them to an OD600 of 0.2, and then grew them to 0.5, where we collected a sample of 1mL. We then added IPTG and grew the cultures for another 4 hours. After the additional 4 hours, we then collected another 1mL sample. We centrifuged both samples and resuspended the pellets in 1x Sample Buffer. The samples containing IPTG expressed the protein more strongly, which suggests that our protein was present (Figure 3).

T--TAS_Taipei--Registry_8.png

Figure 3: SDS-PAGE results show that SplintR ligase and Φ29 polymerase was expressed by E. coli. We grew the bacterial cultures overnight at 37°C, diluted them to an OD600 of 0.2, and then grew them to 0.5, where we collected a sample of 1mL. We then added IPTG and grew the cultures for another 4 hours. After the additional 4 hours, we then collected another 1mL sample. We centrifuged both samples and resuspended the pellets in 1x Sample Buffer. The sample with the IPTG expressed the protein more strongly, which suggests that our protein was present at 68.2 kDa.


Improvement of an Existing Part

We optimized the protein coding region for Φ29 DNA polymerase for high expression in E. coli. We also inserted 3 additional codons that should be present as found in the Φ29 DNA polymerase amino acid sequence in the parent organism Bacillus phage Φ29. To isolate the enzyme after expression, we added a N-terminal 6x histidine tag to the Φ29 DNA polymerase sequence through a GS linker (BBa_K3352001). This improves the existing Φ29 DNA polymerase sequence (BBa_K2918034) from team TUDelft 2019. To test whether our improved sequence was better, we expressed our Φ29 DNA polymerase (BBa_K3352009), which contains (BBa_K3352001) alongside TUDelft’s (BBa_K2918034) and analyzed the expression levels by SDS-PAGE. We grew bacterial cultures overnight at 37°C. We then diluted the cultures to an OD600 of 0.2 and grew them to an OD600 of 0.5, at which point we collected a 1mL sample. We then added IPTG and grew the cultures for another 4 hours after which another 1mL sample was collected. We centrifuged all samples and resuspended the pellets in 1x Sample Buffer and performed SDS-PAGE analysis. In our protein gel, we saw that our construct was able to better express Φ29 polymerase, especially after inducing it with IPTG, relative to the pre-existing part (Figure 4). To further confirm that the observed band was indeed Φ29 polymerase, we purified the enzyme using Ni sepharose affinity chromatography. The results showed a clear band at 68.2 kDa for the elution fractions that were not present in the flow-through or wash fractions, indicating that we successfully expressed and purified His-tagged Φ29 polymerase (Figure 5).


T--TAS_Taipei--Registry_12.png

Figure 4: Comparison between part (BBa_K2918034) and part (BBa_K3352009) showing our improved Φ29 construct. We can clearly see a band that is around 68kDa in the post-induced pET T7 promoter and Φ29 construct (red) that is not present in the post-induced TUDelft 2019 Φ29 construct (blue), which suggests that our construct can better express Φ29 DNA Polymerase.

T--TAS_Taipei--Registry_6.png


Figure 5: Comparison between part (BBa_K2918034) and part (BBa_K3352009) showing our improved Φ29 construct. We can clearly see a band that is around 68kDa in the post-induced pET T7 promoter and Φ29 construct (red) that is not present in the post-induced TUDelft 2019 Φ29 construct (blue), which suggests that our construct can better express Φ29 DNA Polymerase.


References


1. T7 Promoter System Vectors for Highest Expression Levels in Bacteria. (n.d.). Sigma-Aldrich. Retrieved October 22, 2020, from https://www.sigmaaldrich.com/life-science/molecular-biology/cloning-and-expression/vector-systems/t7-promoter-system.html


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal BsaI site found at 676
    Illegal SapI.rc site found at 1074