Difference between revisions of "Part:BBa K3972001"

(Usage and Biology)
 
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__NOTOC__
 
__NOTOC__
 
<partinfo>BBa_K3972001 short</partinfo>
 
<partinfo>BBa_K3972001 short</partinfo>
E.coli codon-optimized TtrS([https://parts.igem.org/Part:BBa_K3972000 BBa_K3972000]) and TtrR ([https://parts.igem.org/Part:BBa_K3972001 BBa_K3972001]) are two basic parts that are derived from the two-component system of the marine bacterium Shewanella Baltica. TtrS is the first component of this system and functions as the membrane-bound sensor kinase (SK), which can sense tetrathionate outside the cell. The second component, TtrR, is the DNA-binding response regulator (RR) that binds to promotor PttrB185-269 ([https://parts.igem.org/Part:BBa_K2507019 BBa_K2507019]), which can induce gene expression (Figure 1) [1].
 
  
[[File:T—TU_Eindhoven--TtrR-S-system.png|200px|]]
+
E.coli codon-optimized TtrS ([https://parts.igem.org/Part:BBa_K3972000, BBa_K3972000]) and TtrR ([https://parts.igem.org/Part:BBa_K3972001, BBa_K3972001]) are two basic parts that are derived from the two-component system of the marine bacterium Shewanella Baltica. TtrS is the first component of this system and functions as the transmembrane sensor kinase, which binds tetrathionate extracellularly with high specificity. The second component, TtrR, is the DNA-binding response regulator (RR) that is activated by TtrS and subsequently binds to the optimized pTtrB185-269 promoter ([https://parts.igem.org/Part:BBa_K2507019 BBa_K2507019]) as a phosphorylated dimer, which can induce gene expression (Figure 1) [1].
  
''Figure 1. The two-component system TtrR TtrS.''
+
 
 +
[[File:T—TU_Eindhoven--TtrR-S-system.png|600px|]]
 +
 
 +
''Figure 1. The two-component system TtrS/R.''
  
 
===Usage and Biology===
 
===Usage and Biology===
The receptor protein TtrS can be activated in the presence of tetrathionate. After binding of tetrathionate, autophosphorylation of TtrS will take place. The phosphorylated TtrS activates the response regulator TtrR, which can bind to the PttrB185-269 promoter. To visualize the activation of the TtrR/S system, a superfold GFP protein can be expressed under the regulation of the PttrB185-269 promoter. The IPTG inducible promoter Ptac ([https://parts.igem.org/Part:BBa_K2558004 BBa_K2558004]) regulates TtrS, while TtrR is regulated by an anhydrotetracycline inducible promoter pLtetO-1 [https://parts.igem.org/Part:BBa_K3332034 BBa_K3332034]) [1].
+
The receptor protein TtrS can be activated in the presence of tetrathionate. After binding of the ligand tetrathionate, TtrS undergoes a conformational change, resulting in autophosphorylation of the transmembrane receptor protein. The phosphorylated TtrS activates the response regulator TtrR by transferring the phosphor group. The formed phosphorylated TtrR dimerizes and then acts as a transcription factor which can bind to the pTtrB185-269 promoter. To characterize the activation of the TtrR/S system, a superfold GFP protein was expressed under the regulation of the pTtrB185-269 promoter. The IPTG inducible promoter Ptac ([https://parts.igem.org/Part:BBa_K2558004 BBa_K2558004]) regulates TtrS, while TtrR is regulated by a leaky anhydrotetracycline inducible promoter pLtetO-1 [https://parts.igem.org/Part:BBa_K3332034 BBa_K3332034]) [1].
  
 
==Characterization==
 
==Characterization==
 
<strong>Expression</strong>
 
<strong>Expression</strong>
 
<br>
 
<br>
This part is optimized for the expression of TtrS in E.coli cells. As can be seen on the agar plate below (figure 2), the plasmid containing the TtrS protein was successfully transformed into E.coli BL21(DE3) cells. To successfully co-transform the TtrR and TtrS plasmids in BL21(DE3) cells, multiple attempts were needed to discover that SOC medium should be used to recover the cells after heat shock.
+
The DNA sequence for TtrR is optimized for the expression of TtrR in E.coli cells. As can be seen on the agar plates below (Figure 2), the plasmid containing the TtrR protein was successfully transformed into E.coli BL21 (DE3) cells and also co-transformed together with TtrR in E. Coli BL21 (DE3) cells. To successfully co-transform the TtrR and TtrS plasmids in BL21(DE3) cells, multiple attempts were required to discover that SOC medium should be used to recover the cells after heat shock, instead of LB medium.
  
[[File: T--TU-Eindhoven--TtrR-S-plate.jpeg|200px|]]
 
  
''Figure 2. Agar plate with co-transfected TtrR TtrS in BL21(DE3) cells.''
+
[[File: T--TU-Eindhoven--TtrR-S-plate2.jpeg|600px|]]
  
For protein expression, the cells were first harvested in a small culture and hereafter, in a large culture (figure 3 &4). The conditions used during these culturing experiments were based on literature. [1]
+
''Figure 2. Agar plates with (a) transfected TtrR in BL21 (DE3) cells and with (b) co-transfected TtrR TtrS in BL21(DE3) cells.''
  
[[File: T--TU-Eindhoven--TtrR-S SC.jpeg|200px|]]
+
For protein expression, the cells were first multiplied in a small culture and thereafter, in a large culture in which they were induced with IPTG  (Figure 3 & 4). The conditions used during these culturing experiments were based on literature [1].
  
''Figure 3. Small culture of TtrR TtrS in BL21(DE3).''
 
  
[[File: T--TU-Eindhoven--TtrR-S LC.jpeg|200px|]]
+
[[File: T--TU-Eindhoven--TtrR-S SC.jpeg|600px|]]
  
''Figure 4. Large culture of TtrR TtrS in BL21(DE3).''
+
''Figure 3. Small cultures of TtrR TtrS in BL21(DE3). All four small cultures contain the TtrR/S sensing system.''
  
The expression of TtrS was tested using the two-component system TtrR/S. When TtrS is expressed and tetrathionate is present, TtrS will activate the production of TtrR, which subsequently expresses the superfold GFP gene. Furthermore, constitutively expressed mCherry will be used to normalize the sfGFP expression.
+
[[File: T--TU-Eindhoven--TtrR-S LC.jpeg|600px|]]
To test the complete two-component system, multiple concentrations of tetrathionate inducer were used, combined with a constant concentration of doxycycline and IPTG. As can be seen in the graph below (figure 5), all samples display the same fluorescence intensity. The chosen doxycycline concentration was based on information from a research paper of Mazumder et al. [2]. The used IPTG concentration was based on consultation with our supervisors and a concentration was used, which is usually added in the lab at our university. Since the article of Daeffler et al. included a dose-response curve of tetrathionate, the used tetrathionate concentrations were based on this curve.
+
  
[[File:T—TU-Eindhoven--first-TtrR-S.png|200px|]]
+
''Figure 4. Large culture of TtrR TtrS in BL21(DE3) induced with various inducer concentrations. ''
  
''Figure 5. sfGFP measurement.''
+
The expression of TtrS was tested using the entire two-component system TtrR/S. As described above, when TtrS is expressed and tetrathionate is present, TtrS will activate TtrR, which subsequently activates the expression of the superfold GFP gene. Furthermore, constitutively expressed mCherry will be used to normalize the sfGFP expression by dividing by the theoretical maximum of emission intensities of each sample.
 +
To characterize the complete two-component system, multiple concentrations of tetrathionate inducers were used, combined with a constant concentration of doxycycline and IPTG. As can be seen in the graph below (Figure 5), all samples displayed a similar fluorescence intensity. The tetrathionate concentrations used to generate a dose-response curve were based on the concentrations used in literature as described by Daeffler et al.[1]. Though the chosen doxycycline concentration was based on information from a research paper written by Mazumder et al. [2] and the used IPTG concentration was determined based on consultation with our supervisors, and on what concentration is conveniently used in our lab. Both these concentrations are higher than prescribed by the original paper [1].
  
Since all samples displayed the same fluorescence intensity, the experiment was repeated with concentrations of IPTG, tetrathionate, and doxycycline shown in figure 6. The corresponding sfGFP graph can be seen in figure 7. As can be concluded from this graph, the presence of a higher concentration of doxycycline influences the fluorescence intensity.
 
  
[[File:T—TU-Eindhoven--second-TtrR-S-inducers.png|200px|]]
+
[[File:T—TU-Eindhoven--first-TtrR-S.png|600px|]]
  
''Figure 6. Concentrations of inducers.''
+
''Figure 5. Dose-response curve measured in BL21 (DE3) lysate, induced with 0.1 mM IPTG,250 ng/mL dox and various concentrations of tetrathionate. The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.''
  
[[File:T—TU-Eindhoven--second-TtrR-S.png|200px|]]
+
It is not clear what caused these results. Since the co-transformations worked and the ordered plasmids had not been changed, we suspected the inducers to cause these unexpected results. Therefore, eight different combinations of Ttr, doxycycline (dox), and IPTG were tested for induction, by measuring the sfGFP fluorescence. Therefore, the experiment was repeated with varying concentrations of IPTG, tetrathionate, and doxycycline and sfGFP intensities were measured (Figure 6).  
  
''Figure 7.sfGFP measurement.''
+
From these experiments can be concluded that the sensor is working properly; however, the concentration of 250 ng/ml doxycycline causes overexpression of the TtrR proteins, resulting in high GFP expression.  
  
To overcome this problem, two experiments were conducted, to understand which concentration of doxycycline would be optimal to use for the two-component system to function as a tetrathionate sensor. As can be seen in figure 8, doxycycline concentrations below 10 ng/mL show the same fluorescence intensity, while the doxycycline concentrations of 100 and 250 ng/mL give higher sfGFP expression levels. Since the tetrathionate concentrations were kept the same in all samples, it can be concluded that the optimal doxycycline concentration should be lower than 100 ng/mL. Figure 9 shows the doxycycline concentrations used in this experiment. As can be seen in figure 10, a concentration of 250 ng/mL doxycycline indeed overexpresses the sfGFP, even without the presence of tetrathionate. The presence of tetrathionate gives a 7-fold increase of signal with induction up to 10ng/mL. Between below 100 ng/mL samples, there is no difference between the GFP expression.
 
After consulting with our supervisors, the optimal dox concentration for the sensor was 0 ng/mL. This corresponds with the article of Daeffler et al., since no inducer was used for the expression of TtrR. [1]
 
  
[[File:T—TU-Eindhoven--third-TtrR-S.png|200px|]]
+
[[File:T—TU-Eindhoven--second-TtrR-S.png|600px|]]
  
''Figure 8. sfGFP measurement.''
+
''Figure 6. a) Signal measured in BL21 (DE3) lysate, induced with 0.1 mM IPTG, with and without doxycycline (250 ng/ml) and with and without tetrathionate (1 mM). b) Signal measured in BL21 (DE3) lysate, induced with 0.01 mM IPTG, with and without doxycycline (250 ng/ml) and with and without tetrathionate (1 mM). The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.''
  
[[File:T—TU-Eindhoven--fourth-TtrR-S-inducer.png|200px|]]
+
To overcome this problem, two experiments were performed to determine the optimal concentration of doxycycline for minimal background fluorescence, and a maximal tetrathionate sensor performance of the two-component system (Figure 7). As can be concluded from these results, doxycycline concentrations of 100 and 250 ng/ml have higher sfGFP intensity compared to below 10 ng/mL while the tetrathionate concentrations were constant for all samples. According to the previous experiment, those higher sfGFP intensities result in overexpression of the sfGFP. Therefore, it could be concluded that the optimal doxycycline concentration should be below 10 ng/mL.  
  
''Figure 9. Concentrations of inducers.''
+
[[File:T—TU-Eindhoven--third-TtrR-S.png|600px|]]
  
[[File:T—TU-Eindhoven--fourth-TtrR-S.png|200px|]]
+
''Figure 7. Signal measured in BL21 (DE3), induced with 0.1 mM IPTG, 1 mM tetrathionate and various concentrations of doxycycline. The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.''
  
''Figure 10. sfGFP measurement.''
+
Based on these results, we choose to further test these doxycycline concentrations with and without tetrathionate to discover which of these concentrations have the largest difference between the background fluorescence and the sfGFP fluorescence from the induced cells (Figure 8). After discussions with our supervisors and based on these results and the literature, we decided to further test the sensor without dox [1]. Furthermore, these results show that a concentration of 250 ng/mL doxycycline indeed causes overexpression of sfGFP, even without the presence of tetrathionate.  
  
Using the optimal doxycycline concentration, the full dose-response curve with induction of tetrathionate was defined, using the concentrations of doxycycline, tetrathionate, and IPTG shown in figure 11. The full dose-response curve can be seen in figure 12.
 
  
[[File:T—TU-Eindhoven--S-Curve-inducers.png|200px|]]
+
[[File:T—TU-Eindhoven--fourth-TtrR-S-inducer.png|600px|]]
  
''Figure 11. Concentrations of inducers for the dose-response curve.''
 
  
[[File:T—TU-Eindhoven--S-Curve-TtrR-S.png|200px|]]
+
''Figure 8. Signal measured in BL21 (DE3), induced with 0.1 mM IPTG, with and without 1 mM tetrathionate and various concentrations of doxycycline. The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.''
  
''Figure 12. Dose response curve of tetrathionate.''
+
With the optimal inducer concentration of 0 ng/mL doxycycline, we performed one more characterization experiment with varying tetrathionate concentrations, which resulted in the dose-response curve (Figure 9).
 +
 
 +
 
 +
[[File:T—TU-Eindhoven--S-Curve-TtrR-S.png|800px|]]
 +
 
 +
''Figure 9. Normalized GFP emission of the TtrS/R system induced with various concentrations of doxycycline, IPTG and tetrathionate. a) Dose-response curve measured in BL21 (DE3), induced with 0.1 mM IPTG, 0 ng/mL doxycycline and different concentrations tetrathionate. In addition a positive control (0.1 mM IPTG, 250 ng/mL doxycycline and 1 mM tetrathionate) and a negative control (no IPTG, doxycline and tetrathionate) were added. b) The dose-response from figure 9a plotted in a line-plot with logarithmic scale (EC50 = 49.1 ± 2.3 uM, n=1). The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.''
  
 
==References==
 
==References==
 
[1] Daeffler, K. N., Galley, J. D., Sheth, R. U., Ortiz-Velez, L. C., Bibb, C. O., Shroyer, N. F., Britton, R. A., & Tabor, J. J. (2017). Engineering bacterial thiosulfate and tetrathionate sensors for detecting gut inflammation. Molecular systems biology, 13(4), 923. https://doi.org/10.15252/msb.20167416
 
[1] Daeffler, K. N., Galley, J. D., Sheth, R. U., Ortiz-Velez, L. C., Bibb, C. O., Shroyer, N. F., Britton, R. A., & Tabor, J. J. (2017). Engineering bacterial thiosulfate and tetrathionate sensors for detecting gut inflammation. Molecular systems biology, 13(4), 923. https://doi.org/10.15252/msb.20167416
[2] Mostafizur Mazumder, Katherine E. Brechun, Yongjoo B. Kim, Stefan A. Hoffmann, Yih Yang Chen, Carrie-Lynn Keiski, Katja M. Arndt, David R. McMillen, G. Andrew Woolley (2015).  An Escherichia coli system for evolving improved light-controlled DNA-binding proteins.  Protein Engineering, Design and Selection, Volume 28, Issue 9, Pages 293–302, https://doi.org/10.1093/protein/gzv033
+
 
 +
[2] Mostafizur Mazumder, Katherine E. Brechun, Yongjoo B. Kim, Stefan A. Hoffmann, Yih Yang Chen, Carrie-Lynn Keiski, Katja M. Arndt, David R. McMillen, G. Andrew Woolley (2015).  An Escherichia coli system for evolving improved light-controlled DNA-binding proteins.  Protein Engineering, Design, and Selection, Volume 28, Issue 9, Pages 293–302, https://doi.org/10.1093/protein/gzv033
 
   
 
   
<!-- -->
+
==Sequence and Features==
 +
 
 
<span class='h3bb'>Sequence and Features</span>
 
<span class='h3bb'>Sequence and Features</span>
 
<partinfo>BBa_K3972001 SequenceAndFeatures</partinfo>
 
<partinfo>BBa_K3972001 SequenceAndFeatures</partinfo>

Latest revision as of 08:28, 21 October 2021

TtrR

E.coli codon-optimized TtrS (BBa_K3972000) and TtrR (BBa_K3972001) are two basic parts that are derived from the two-component system of the marine bacterium Shewanella Baltica. TtrS is the first component of this system and functions as the transmembrane sensor kinase, which binds tetrathionate extracellularly with high specificity. The second component, TtrR, is the DNA-binding response regulator (RR) that is activated by TtrS and subsequently binds to the optimized pTtrB185-269 promoter (BBa_K2507019) as a phosphorylated dimer, which can induce gene expression (Figure 1) [1].


T—TU Eindhoven--TtrR-S-system.png

Figure 1. The two-component system TtrS/R.

Usage and Biology

The receptor protein TtrS can be activated in the presence of tetrathionate. After binding of the ligand tetrathionate, TtrS undergoes a conformational change, resulting in autophosphorylation of the transmembrane receptor protein. The phosphorylated TtrS activates the response regulator TtrR by transferring the phosphor group. The formed phosphorylated TtrR dimerizes and then acts as a transcription factor which can bind to the pTtrB185-269 promoter. To characterize the activation of the TtrR/S system, a superfold GFP protein was expressed under the regulation of the pTtrB185-269 promoter. The IPTG inducible promoter Ptac (BBa_K2558004) regulates TtrS, while TtrR is regulated by a leaky anhydrotetracycline inducible promoter pLtetO-1 BBa_K3332034) [1].

Characterization

Expression
The DNA sequence for TtrR is optimized for the expression of TtrR in E.coli cells. As can be seen on the agar plates below (Figure 2), the plasmid containing the TtrR protein was successfully transformed into E.coli BL21 (DE3) cells and also co-transformed together with TtrR in E. Coli BL21 (DE3) cells. To successfully co-transform the TtrR and TtrS plasmids in BL21(DE3) cells, multiple attempts were required to discover that SOC medium should be used to recover the cells after heat shock, instead of LB medium.


T--TU-Eindhoven--TtrR-S-plate2.jpeg

Figure 2. Agar plates with (a) transfected TtrR in BL21 (DE3) cells and with (b) co-transfected TtrR TtrS in BL21(DE3) cells.

For protein expression, the cells were first multiplied in a small culture and thereafter, in a large culture in which they were induced with IPTG (Figure 3 & 4). The conditions used during these culturing experiments were based on literature [1].


T--TU-Eindhoven--TtrR-S SC.jpeg

Figure 3. Small cultures of TtrR TtrS in BL21(DE3). All four small cultures contain the TtrR/S sensing system.

T--TU-Eindhoven--TtrR-S LC.jpeg

Figure 4. Large culture of TtrR TtrS in BL21(DE3) induced with various inducer concentrations.

The expression of TtrS was tested using the entire two-component system TtrR/S. As described above, when TtrS is expressed and tetrathionate is present, TtrS will activate TtrR, which subsequently activates the expression of the superfold GFP gene. Furthermore, constitutively expressed mCherry will be used to normalize the sfGFP expression by dividing by the theoretical maximum of emission intensities of each sample. To characterize the complete two-component system, multiple concentrations of tetrathionate inducers were used, combined with a constant concentration of doxycycline and IPTG. As can be seen in the graph below (Figure 5), all samples displayed a similar fluorescence intensity. The tetrathionate concentrations used to generate a dose-response curve were based on the concentrations used in literature as described by Daeffler et al.[1]. Though the chosen doxycycline concentration was based on information from a research paper written by Mazumder et al. [2] and the used IPTG concentration was determined based on consultation with our supervisors, and on what concentration is conveniently used in our lab. Both these concentrations are higher than prescribed by the original paper [1].


T—TU-Eindhoven--first-TtrR-S.png

Figure 5. Dose-response curve measured in BL21 (DE3) lysate, induced with 0.1 mM IPTG,250 ng/mL dox and various concentrations of tetrathionate. The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.

It is not clear what caused these results. Since the co-transformations worked and the ordered plasmids had not been changed, we suspected the inducers to cause these unexpected results. Therefore, eight different combinations of Ttr, doxycycline (dox), and IPTG were tested for induction, by measuring the sfGFP fluorescence. Therefore, the experiment was repeated with varying concentrations of IPTG, tetrathionate, and doxycycline and sfGFP intensities were measured (Figure 6).

From these experiments can be concluded that the sensor is working properly; however, the concentration of 250 ng/ml doxycycline causes overexpression of the TtrR proteins, resulting in high GFP expression.


T—TU-Eindhoven--second-TtrR-S.png

Figure 6. a) Signal measured in BL21 (DE3) lysate, induced with 0.1 mM IPTG, with and without doxycycline (250 ng/ml) and with and without tetrathionate (1 mM). b) Signal measured in BL21 (DE3) lysate, induced with 0.01 mM IPTG, with and without doxycycline (250 ng/ml) and with and without tetrathionate (1 mM). The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.

To overcome this problem, two experiments were performed to determine the optimal concentration of doxycycline for minimal background fluorescence, and a maximal tetrathionate sensor performance of the two-component system (Figure 7). As can be concluded from these results, doxycycline concentrations of 100 and 250 ng/ml have higher sfGFP intensity compared to below 10 ng/mL while the tetrathionate concentrations were constant for all samples. According to the previous experiment, those higher sfGFP intensities result in overexpression of the sfGFP. Therefore, it could be concluded that the optimal doxycycline concentration should be below 10 ng/mL.

T—TU-Eindhoven--third-TtrR-S.png

Figure 7. Signal measured in BL21 (DE3), induced with 0.1 mM IPTG, 1 mM tetrathionate and various concentrations of doxycycline. The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.

Based on these results, we choose to further test these doxycycline concentrations with and without tetrathionate to discover which of these concentrations have the largest difference between the background fluorescence and the sfGFP fluorescence from the induced cells (Figure 8). After discussions with our supervisors and based on these results and the literature, we decided to further test the sensor without dox [1]. Furthermore, these results show that a concentration of 250 ng/mL doxycycline indeed causes overexpression of sfGFP, even without the presence of tetrathionate.


T—TU-Eindhoven--fourth-TtrR-S-inducer.png


Figure 8. Signal measured in BL21 (DE3), induced with 0.1 mM IPTG, with and without 1 mM tetrathionate and various concentrations of doxycycline. The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.

With the optimal inducer concentration of 0 ng/mL doxycycline, we performed one more characterization experiment with varying tetrathionate concentrations, which resulted in the dose-response curve (Figure 9).


T—TU-Eindhoven--S-Curve-TtrR-S.png

Figure 9. Normalized GFP emission of the TtrS/R system induced with various concentrations of doxycycline, IPTG and tetrathionate. a) Dose-response curve measured in BL21 (DE3), induced with 0.1 mM IPTG, 0 ng/mL doxycycline and different concentrations tetrathionate. In addition a positive control (0.1 mM IPTG, 250 ng/mL doxycycline and 1 mM tetrathionate) and a negative control (no IPTG, doxycline and tetrathionate) were added. b) The dose-response from figure 9a plotted in a line-plot with logarithmic scale (EC50 = 49.1 ± 2.3 uM, n=1). The GFP emission (at 512 nm) is normalized on the mCherry emission at 610 nm.

References

[1] Daeffler, K. N., Galley, J. D., Sheth, R. U., Ortiz-Velez, L. C., Bibb, C. O., Shroyer, N. F., Britton, R. A., & Tabor, J. J. (2017). Engineering bacterial thiosulfate and tetrathionate sensors for detecting gut inflammation. Molecular systems biology, 13(4), 923. https://doi.org/10.15252/msb.20167416

[2] Mostafizur Mazumder, Katherine E. Brechun, Yongjoo B. Kim, Stefan A. Hoffmann, Yih Yang Chen, Carrie-Lynn Keiski, Katja M. Arndt, David R. McMillen, G. Andrew Woolley (2015). An Escherichia coli system for evolving improved light-controlled DNA-binding proteins. Protein Engineering, Design, and Selection, Volume 28, Issue 9, Pages 293–302, https://doi.org/10.1093/protein/gzv033

Sequence and Features

Sequence and Features


Assembly Compatibility:
  • 10
    INCOMPATIBLE WITH RFC[10]
    Illegal PstI site found at 317
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal PstI site found at 317
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    INCOMPATIBLE WITH RFC[23]
    Illegal PstI site found at 317
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal PstI site found at 317
    Illegal AgeI site found at 247
  • 1000
    COMPATIBLE WITH RFC[1000]