Difference between revisions of "Part:BBa K117000"

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<partinfo>BBa_K117000 short</partinfo>
 
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'''For more information on how this part operates in our Detection system, please visit [https://parts.igem.org/Part:BBa_K117010 BBa_K117010(detection system)]'''
 
'''For more information on how this part operates in our Detection system, please visit [https://parts.igem.org/Part:BBa_K117010 BBa_K117010(detection system)]'''
  
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===SZU-China 2019 iGEM team===
===Usage and Biology===
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The lysis gene from colicin-producing strains of bacteria encodes the lysis protein which is only 4872Da in molecular weight and performs two functions that are instrumental to the activity of Colicin E7 (ColE7):one of its function is to Release of ColE7 from ColE7—Immunity complex and the other is Partial lysis of host cell membrane, which means that once the protein is produced and activated, the protein can cause the host cell to lyse.
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On the basis of its special biological function, it's likely to use lysis protein as a cellular structure breaker. In this year, our team decided to add a Tryptophan attenuator between a RBS and the lysis gene, making it possible to switch off or switch on the lysing mechanism  by controlling the tryptophan concentration of medium, so that the lysis protein can better serve in our project when we need to break our engineering cells to extract our product.
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SZU-China 2019 iGEM team constructed a plasmid with  BBa_K1475900 (Promoter), BBa_K2912014 (Attenuator), BBa_K117000(lysis), BBa_K3257020(terminator)(illustrated in Fig.1).
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<center><html><img src='https://2019.igem.org/wiki/images/5/5c/T--SZU-CHINA--fig.1.png' style="width:50%;margin:0 auto">
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<center> <span style="font-weight:bold">Fig.1 Plasmid construction of Trp_lysis</span> </center></html></center>
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Before the official experiment of Trp_Lysis gene. We have done the T7 promotor_lysis gene characterization experiment with IPTG inducing in LB liquid medium(illustrated in Fig.2).
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<center><html><img src='https://2019.igem.org/wiki/images/d/d9/T--SZU-CHINA--fig._7.png' style="width:50%;margin:0 auto">
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<center> <span style="font-weight:bold">Fig.2  OD600 of two different treated T7 promotor_lysis samples</span> </center></html></center>
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According to the characterization experiment's result, we can draw a conclusion that once the lysis protein is produced with IPTG inducing by HT115 (DE3) E.coli, their growth will be significantly inhibited.
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'''However, T7 promoter was too strong to be controlled, so Trp attenuator could not stop the translation as expected. Hence, we change it to another promoter.'''
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In our next step, we transformed the expression vector into HT115 (DE3) E.coli by heat-shock method, culturing in LB liquid medium to exact exponential phase, and then moved to fresh LB liquid medium with different concentration of  tryptophan, starting a eight-hour cell growth curve experiment of our engineering E.coli and then we measured the OD600 of each groups every two hours. Finally, we calculated their survival rate by using OD600 of the experimental group divided by OD600 of the blank group  (illustrated in Fig.3).
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<center><html><img src='https://static.igem.org/mediawiki/parts/3/37/T--SZU-CHINA--improved_new_data.jpg' style="width:50%;margin:0 auto">
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<center> <span style="font-weight:bold">Fig.3 The survival rate of E. coli with Trp-Lysis </span> </center></html></center>
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Besides, we also did a culturing in LB solid medium experiment in tryptophan concentration gradient.(illustrated in Fig.4)
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<center><html><img src='https://2019.igem.org/wiki/images/4/4e/T--SZU-CHINA--fig._4.png' style="width:50%;margin:0 auto">
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<center> <span style="font-weight:bold">Fig.4 growth of Trp_lysis E.coli under different treated </center></html></center>
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<center><html><img src='https://2019.igem.org/wiki/images/6/61/T--SZU-CHINA--fig_5.jpg' style="width:50%;margin:0 auto">
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<center> <span style="font-weight:bold">Fig.5 growth of T7 promotor_lysis E.coli under different treated</span> </center></html></center>
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In contrast with T7 promotor_lysis with IPTG inducing group(illustrated in Fig.5). The Trp_Lysis metabolism obviously has the advantage which is able to kill the host cell by breaking their structure in a controlled way. In other words, we can switch off or switch on the lysing mechanism by controlling the tryptophan concentration of the culture medium, and the result indicates that the concentration critical valve of tryptophan is around 0.3% which means that if the concentration is more than 0.3%, the killing metabolism will be closed so that the host cells can grow as usual.
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<partinfo>BBa_K117000 parameters</partinfo>
 
<partinfo>BBa_K117000 parameters</partinfo>
 
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Latest revision as of 02:58, 22 October 2019

Lysis gene (promotes lysis in colicin-producing bacteria strain)

This lysis gene encodes for the lysis protein in colicin-producing strains of bacteria. Once activated, it causes the host cell to lyze. It also removes the immunity protein out of colicin, and hence, activates the endonuclease activity of the colicin.

How does it work?


Lysis genes encode for the synthesis of Lysis protein. The Lysis protein is 4872Da in molecular weight and performs two functions that are instrumental to the activity of Colicin E7 (ColE7):

  • Release of ColE7 from ColE7—Immunity complex

This function causes the detachment of ColE7 from Immunity protein, hence switches on the endonuclease activity of ColE7

  • Partial lysis of host cell membrane

This function induces the lysis of host cell, exposing the interior cell contents and hence allows free diffusion of ColE7 proteins towards pathogenic bacteria strains.

NTU@ iGEM has designed and successfully synthesized Lysis genes into standard Biobrick construct using an Ampicillin resistant plasmid vector pSB1A2. The Colicin E7 with Immunity construct is 144 base pairs in length and formally registered in the Biobrick registry as the Biobrick BBa_K117000.

For more information on how this part operates in our Detection system, please visit BBa_K117010(detection system)

SZU-China 2019 iGEM team

The lysis gene from colicin-producing strains of bacteria encodes the lysis protein which is only 4872Da in molecular weight and performs two functions that are instrumental to the activity of Colicin E7 (ColE7):one of its function is to Release of ColE7 from ColE7—Immunity complex and the other is Partial lysis of host cell membrane, which means that once the protein is produced and activated, the protein can cause the host cell to lyse.

On the basis of its special biological function, it's likely to use lysis protein as a cellular structure breaker. In this year, our team decided to add a Tryptophan attenuator between a RBS and the lysis gene, making it possible to switch off or switch on the lysing mechanism by controlling the tryptophan concentration of medium, so that the lysis protein can better serve in our project when we need to break our engineering cells to extract our product.

SZU-China 2019 iGEM team constructed a plasmid with BBa_K1475900 (Promoter), BBa_K2912014 (Attenuator), BBa_K117000(lysis), BBa_K3257020(terminator)(illustrated in Fig.1).

Fig.1 Plasmid construction of Trp_lysis

Before the official experiment of Trp_Lysis gene. We have done the T7 promotor_lysis gene characterization experiment with IPTG inducing in LB liquid medium(illustrated in Fig.2).

Fig.2 OD600 of two different treated T7 promotor_lysis samples

According to the characterization experiment's result, we can draw a conclusion that once the lysis protein is produced with IPTG inducing by HT115 (DE3) E.coli, their growth will be significantly inhibited.

However, T7 promoter was too strong to be controlled, so Trp attenuator could not stop the translation as expected. Hence, we change it to another promoter.

In our next step, we transformed the expression vector into HT115 (DE3) E.coli by heat-shock method, culturing in LB liquid medium to exact exponential phase, and then moved to fresh LB liquid medium with different concentration of tryptophan, starting a eight-hour cell growth curve experiment of our engineering E.coli and then we measured the OD600 of each groups every two hours. Finally, we calculated their survival rate by using OD600 of the experimental group divided by OD600 of the blank group (illustrated in Fig.3).

Fig.3 The survival rate of E. coli with Trp-Lysis

Besides, we also did a culturing in LB solid medium experiment in tryptophan concentration gradient.(illustrated in Fig.4)

Fig.4 growth of Trp_lysis E.coli under different treated


Fig.5 growth of T7 promotor_lysis E.coli under different treated

In contrast with T7 promotor_lysis with IPTG inducing group(illustrated in Fig.5). The Trp_Lysis metabolism obviously has the advantage which is able to kill the host cell by breaking their structure in a controlled way. In other words, we can switch off or switch on the lysing mechanism by controlling the tryptophan concentration of the culture medium, and the result indicates that the concentration critical valve of tryptophan is around 0.3% which means that if the concentration is more than 0.3%, the killing metabolism will be closed so that the host cells can grow as usual.


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
    COMPATIBLE WITH RFC[1000]