Difference between revisions of "Part:BBa K4011004"

 
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TnaA-FL-FMO is a fused protein used to convert 6-Halogen-Trpytophan (6-X-Trp) into di-halogenated indigoid dyes such as tyrian purple. It is composed of two seperate domains: TnaA and FMO, fused with a flexible linker. This is a part in a part collection where we enable the production of indigo, tyrian purple, and related dyes from tryptophan in <i>E. coli</i>.  
 
TnaA-FL-FMO is a fused protein used to convert 6-Halogen-Trpytophan (6-X-Trp) into di-halogenated indigoid dyes such as tyrian purple. It is composed of two seperate domains: TnaA and FMO, fused with a flexible linker. This is a part in a part collection where we enable the production of indigo, tyrian purple, and related dyes from tryptophan in <i>E. coli</i>.  
  
The part collection includes: Parts expressing Fre-SttH to convert Trp to 6-X-Trp. <partinfo>BBa_K4011003</partinfo> and <partinfo>BBa_K4011012</partinfo>. Parts expressing fusion protein TnaA-FMO to convert 6-X-Trp into indigoid dyes. <partinfo>BBa_K4011004</partinfo>, <partinfo>BBa_K4011005</partinfo>, <partinfo>BBa_K4011013</partinfo>, <partinfo>BBa_K4011014</partinfo>, <partinfo>BBa_K4011015</partinfo>, and <partinfo>BBa_K4011019</partinfo>.  
+
<br>The part collection includes: Parts expressing Fre-SttH to convert Trp to 6-X-Trp. <partinfo>BBa_K4011003</partinfo> and <partinfo>BBa_K4011012</partinfo>. Parts expressing fusion protein TnaA-FMO to convert 6-X-Trp into indigoid dyes. <partinfo>BBa_K4011004</partinfo>, <partinfo>BBa_K4011005</partinfo>, <partinfo>BBa_K4011013</partinfo>, <partinfo>BBa_K4011014</partinfo>, <partinfo>BBa_K4011015</partinfo>, and <partinfo>BBa_K4011019</partinfo>.  
  
Our part collection can be used to help and inspire future teams to design and perfect different indigoid dye production pathways in <i>E. coli</i>, adding to the collection.
+
<br>Our part collection can be used to help and inspire future teams to design and perfect different indigoid dye production pathways in <i>E. coli</i>, adding to the collection.
  
 
==Usage and Biology==
 
==Usage and Biology==
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TnaA and FMO are two vital but separate enzymes for converting trp/6-Br-trp to our indigo and tyrian purple dye. To increase the overall reaction speed, we fused these two proteins together into TnaA-linker-FMO.
 
TnaA and FMO are two vital but separate enzymes for converting trp/6-Br-trp to our indigo and tyrian purple dye. To increase the overall reaction speed, we fused these two proteins together into TnaA-linker-FMO.
  
We designed and engineered three strains of <i>E. coli DH5α ΔTnaA</i>: ptac-TnaA-rbs-FMO (RBS; in this strain TnaA and FMO are expressed as separate proteins), ptac-TnaA-rigid linker-FMO (RL), and ptac-TnaA-Flexible linker-FMO (FL) (Fig. 1A & C). As TnaA is expressed as a tetramer and FMO a dimer, we put the TnaA tetramer at the center of the fused protein, with FMO forming two dimers to each side of the TnaA tetramer (Fig. 1B).  
+
<br>We designed and engineered three strains of <i>E. coli DH5α ΔTnaA</i>: ptac-TnaA-rbs-FMO (RBS; in this strain TnaA and FMO are expressed as separate proteins), ptac-TnaA-rigid linker-FMO (RL), and ptac-TnaA-Flexible linker-FMO (FL) (Fig. 1A & 1C). As TnaA is expressed as a tetramer and FMO a dimer, we put the TnaA tetramer at the center of the fused protein, with FMO forming two dimers to each side of the TnaA tetramer (Fig. 1B).  
  
After culturing and inducing the expression, the three strains, the SDS-PAGE showed separate expression of TnaA (60kDa) and FMO (54kDa) for RBS, and expression of one fused protein at 114 kDa for RL and FL (Fig. 1D). This indicated that our fused proteins are expressed as expected.
+
<br>After culturing and inducing the expression, the three strains, the SDS-PAGE showed separate expression of TnaA (60kDa) and FMO (54kDa) for RBS, and expression of one fused protein at 114 kDa for RL and FL (Fig. 1D). This indicated expected expression of our fused proteins.
  
We then cultured and induced RBS, RL, and FL with IPTG. After 20 hours, 1mM of either trp, 6-Cl-trp, or 6-Br-trp was added as substrate, and the relative dye concentration produced by each strain was calculated by using a standard calibration curve (Fig. 2B). The comparison between RBS, RL, and FL shows that there is similar production of tyrian red and tyrian purple, and a significant difference between indigo production of RL and FL. Titers of indigo is approximately 0.30mM (60% yield) for FL and RBS, and 0.20mM (40% yield) for RL. Titers of tyrian red is approximately 0.30mM (60% yield) for RL, FL, and RBS. Titers of tyrian purple is approx. 0.25mM (50% yield) for FL and 0.20mM (40% yield) for RL and RBS.
+
[[Image:T--LINKS China--Figure 16.png|thumbnail|750px|center|'''Figure 1:''' Construction and expression of TnaA-FMO proteins. A) Schematic representing TnaA-RBS-FMO, TnaA-Flexible linker-FMO, and TnaA-Rigid linker-FMO transformed into <i>E. coli DH5a ΔTnaA</i>. B. Schematic representing the structure of TnaA-linker-FMO. C) The sequences between TnaA and FMO, with the rbs and amino acids labelled. FL and RL stands for flexible linker and rigid linker respectively. D) SDS-PAGE analysis of TnaA-RBS-FMO, TnaA-RL-FMO, and TnaA-FL-FMO. ]]
  
After confirming the efficacy of Fre-SttH and TnaA-FMO, we wanted to compare TnaA-rbs-FMO with our TnaA-FL-FMO. Therefore, drawing inspiration from GreatBaySZ 2019’s TnaA-rbs-FMO <partinfo>BBa_K3264022</partinfo> expression system using a constitutive promoter system(TALEsp2), we designed and constructed TALEsp2-TnaA-FL-FMO.  
+
We then cultured and induced RBS, RL, and FL with IPTG. After 20 hours, 1mM of either trp, 6-Cl-trp, or 6-Br-trp was added as substrate, and the relative dye concentration produced by each strain was calculated by using a standard calibration curve (Fig. 2B). The comparison between RBS, RL, and FL shows that there is similar production of tyrian red and tyrian purple, and a significant difference between indigo production of RL and FL. Titers of indigo is approximately 0.30mM (60% yield) for FL and RBS, and 0.20mM (40% yield) for RL. Titers of tyrian red is approximately 0.30mM (60% yield) for RL, FL, and RBS. Titers of tyrian purple is approx. 0.25mM (50% yield) for FL and 0.20mM (40% yield) for RL and RBS.  
  
Instead of using 1mM standard samples of trp or 6-X-trp, we attempted to produce dyes from trp and NaX salts. We induced Fre-SttH expression, took the sample supernatant and added it to the ptac-TnaA-FMO and TALEsp2-TnaA-FMO cultures, and compared the titers of the all using supernatant from Fre-SttH cultures as substrate (Fig. 3).There is no significant difference between any of the samples. Both TALEsp2 cultures produced titers of approx. 0.09mM for tyrian purple and 0.23mM for 6, 6’di-chloro-indigo. RL, FL, and RBS both achieved titers of 0.12 and 0.28mM for tyrian purple and tyrian red respectively.
+
[[Image:T--LINKS China--Figure 14.png|thumbnail|750px|center|'''Figure 2:''' Measuring dyes production of different TnaA-FMO strains from Trp, 6-Cl-Trp, and 6-Br-Trp. A) Pictures of TnaA-RL-FMO, TnaA-FL-FMO, and TnaA-RBS-FMO with Trp, 6-Cl-Trp, or 6-Br-Trp added. B) Comparison of production titers of TnaA-RL-FMO, TnaA-FL-FMO, and TnaA-RBS-FMO with Trp, 6-Cl-Trp, or 6-Br-Trp added, pictured in A. Error bars denote two standard deviations from the mean. ]]
 +
 
 +
After confirming the efficacy of Fre-SttH and TnaA-FMO, we wanted to compare TnaA-rbs-FMO with our TnaA-FL-FMO. Therefore, drawing inspiration from GreatBaySZ 2019’s TnaA-rbs-FMO expression system using a constitutive promoter system(TALEsp2), we designed and constructed TALEsp2-TnaA-FL-FMO.
 +
 
 +
<br>Instead of using 1mM standard samples of trp or 6-X-trp, we attempted to produce dyes from trp and NaX salts. We induced Fre-SttH expression, took the sample supernatant and added it to the ptac-TnaA-FMO and TALEsp2-TnaA-FMO cultures, and compared the titers of the all using supernatant from Fre-SttH cultures as substrate (Fig. 3). There is no significant difference between any of the samples. Both TALEsp2 cultures produced titers of approx. 0.09mM for tyrian purple and 0.23mM for 6, 6’di-chloro-indigo. RL, FL, and RBS both achieved titers of 0.12 and 0.28mM for tyrian purple and tyrian red respectively.
 +
 
 +
[[Image:T--LINKS China--Figure 15.png|thumbnail|750px|center|'''Figure 3:''' Measuring dye production of different TnaA-FMO strains from Fre-SttH + Trp + NaCl/NaBr. A) Pictures of different TnaA-FMO strains with supernatant of Fre-SttH + Trp + NaCl/NaBr added. B) Comparison of dye production titers of TALEsp2-TnaA-RBS-FMO and TALEsp2-TnaA-FL-FMO. C) Comparison of dye production titers of ptac-TnaA-RL-FMO, ptac-TnaA-FL-FMO, and ptac-TnaA-RBS-FMO. ]]
 +
 
 +
==Contribution: SUSTech Shenzhen 2022==
 +
[[Image:no4.png|thumbnail|750px|center|'''Figure 1:''' A) SDS-PAGE of TnaA-FL-FMO and Fre-sttH. WC stand for whole cell sample and S stand for supernatant sample after cell lysis.  B) Tyrian purple (left) and indigo (right) produced by 6-Br-trp and trp with TnaA-FL-FMO. C) DMSO solution of indigo (top) and tyrian purple (bottom). D) cloth dyed with tyrian purple. ]]
 +
We transform part TnaA-FL-FMO and Fre-sttH into DH5α cell without endogenous TnaA gene. After culture and induced expression of these strains, we use the SDS-PAGE to separate and show the expression of TnaA-FL-FMO and Fre-sttH. We found that we successfully express our fused proteins and these two proteins show high water solubility.
 +
 
 +
Strain that has been induced to express TnaA-FL-FMO also be cultured by NPB solution and 1mM trp or 6-Br-trp as substrate. After fermentation for 24h, we get obvious blue and purple dye in our culture tubes .
 +
 
 +
For purified indigo and tyrian purple, we  dissolve the indigo from the cell pellet by DMSO and filter with a 0.2μm strainer. By diluting DMSO with water, the pigment is precipitated from the solution to obtain a relatively pure indigo solid precipitation. We also use the tyrian purple we produce in cloth dying.
 +
[[Image:no5.png|thumbnail|400px|center|'''Figure 2:'''Relatively pure tyrian (left) and indigo (right) solid precipitation by diluting DMSO with water
 +
]]
 +
Dye concentration is calculated by a OD610/620 standard curve measured by LINKS_China 2021. We get a ~60% yield for indigo and ~20% yield for tyrian purple.
  
 
<partinfo>BBa_K4011004 SequenceAndFeatures</partinfo>
 
<partinfo>BBa_K4011004 SequenceAndFeatures</partinfo>
 +
 +
===References===
 +
 +
Lee, J., Kim, J., Song, J.E. et al. Production of Tyrian purple indigoid dye from tryptophan in Escherichia coli. Nat Chem Biol 17, 104–112 (2021). https://doi.org/10.1038/s41589-020-00684-4

Latest revision as of 08:06, 8 October 2022

TnaA-FL-FMO

TnaA-FL-FMO is a fused protein used to convert 6-Halogen-Trpytophan (6-X-Trp) into di-halogenated indigoid dyes such as tyrian purple. It is composed of two seperate domains: TnaA and FMO, fused with a flexible linker. This is a part in a part collection where we enable the production of indigo, tyrian purple, and related dyes from tryptophan in E. coli.


The part collection includes: Parts expressing Fre-SttH to convert Trp to 6-X-Trp. BBa_K4011003 and BBa_K4011012. Parts expressing fusion protein TnaA-FMO to convert 6-X-Trp into indigoid dyes. BBa_K4011004, BBa_K4011005, BBa_K4011013, BBa_K4011014, BBa_K4011015, and BBa_K4011019.


Our part collection can be used to help and inspire future teams to design and perfect different indigoid dye production pathways in E. coli, adding to the collection.

Usage and Biology

TnaA is an tryptophanase found in E. coli. It converts tryptophan (trp) and other related molecules, such as 6-Halogen-trp (6-X-trp) into indole or 6-X-indole. Its specific reaction formula is L-tryptophan + H₂O ⇌ indole + pyruvate + NH₃. Indole, play important roles in signaling in bacterial cells. FMO is a monooxygenase found in Methylophaga aminisulfidivorans. It adds a hydroxyl group onto numerous molecules, in our case adding a hydroxyl onto the third carbon on indole or 6-X-indole, allowing for spontaneous dimerization of 3-hydroxyl-indole or 3-hydroxyl-6-X-indole into indigo or tyrian purple dyes. They are fused together with the common rigid linker EAAAKEAAAK (Lee et al, 2021).

Source

TnaA-FL-FMO is composed of two main domains: tryptophanase (TnaA) from E. coli and flavin-containing monooxygenase (FMO) from Methylophaga aminisulfidivorans

Design Considerations

1. All codons were optimized for E. coli based on E. coli codon bias.

2. The sequences for the flexible linker is GGGGSGGGGS.

3. Transformed and expressed in E. coli DH5α ΔTnaA to negate influence of endogenous TnaA in measurements.

Characterization

TnaA and FMO are two vital but separate enzymes for converting trp/6-Br-trp to our indigo and tyrian purple dye. To increase the overall reaction speed, we fused these two proteins together into TnaA-linker-FMO.


We designed and engineered three strains of E. coli DH5α ΔTnaA: ptac-TnaA-rbs-FMO (RBS; in this strain TnaA and FMO are expressed as separate proteins), ptac-TnaA-rigid linker-FMO (RL), and ptac-TnaA-Flexible linker-FMO (FL) (Fig. 1A & 1C). As TnaA is expressed as a tetramer and FMO a dimer, we put the TnaA tetramer at the center of the fused protein, with FMO forming two dimers to each side of the TnaA tetramer (Fig. 1B).


After culturing and inducing the expression, the three strains, the SDS-PAGE showed separate expression of TnaA (60kDa) and FMO (54kDa) for RBS, and expression of one fused protein at 114 kDa for RL and FL (Fig. 1D). This indicated expected expression of our fused proteins.

Figure 1: Construction and expression of TnaA-FMO proteins. A) Schematic representing TnaA-RBS-FMO, TnaA-Flexible linker-FMO, and TnaA-Rigid linker-FMO transformed into E. coli DH5a ΔTnaA. B. Schematic representing the structure of TnaA-linker-FMO. C) The sequences between TnaA and FMO, with the rbs and amino acids labelled. FL and RL stands for flexible linker and rigid linker respectively. D) SDS-PAGE analysis of TnaA-RBS-FMO, TnaA-RL-FMO, and TnaA-FL-FMO.

We then cultured and induced RBS, RL, and FL with IPTG. After 20 hours, 1mM of either trp, 6-Cl-trp, or 6-Br-trp was added as substrate, and the relative dye concentration produced by each strain was calculated by using a standard calibration curve (Fig. 2B). The comparison between RBS, RL, and FL shows that there is similar production of tyrian red and tyrian purple, and a significant difference between indigo production of RL and FL. Titers of indigo is approximately 0.30mM (60% yield) for FL and RBS, and 0.20mM (40% yield) for RL. Titers of tyrian red is approximately 0.30mM (60% yield) for RL, FL, and RBS. Titers of tyrian purple is approx. 0.25mM (50% yield) for FL and 0.20mM (40% yield) for RL and RBS.

Figure 2: Measuring dyes production of different TnaA-FMO strains from Trp, 6-Cl-Trp, and 6-Br-Trp. A) Pictures of TnaA-RL-FMO, TnaA-FL-FMO, and TnaA-RBS-FMO with Trp, 6-Cl-Trp, or 6-Br-Trp added. B) Comparison of production titers of TnaA-RL-FMO, TnaA-FL-FMO, and TnaA-RBS-FMO with Trp, 6-Cl-Trp, or 6-Br-Trp added, pictured in A. Error bars denote two standard deviations from the mean.

After confirming the efficacy of Fre-SttH and TnaA-FMO, we wanted to compare TnaA-rbs-FMO with our TnaA-FL-FMO. Therefore, drawing inspiration from GreatBaySZ 2019’s TnaA-rbs-FMO expression system using a constitutive promoter system(TALEsp2), we designed and constructed TALEsp2-TnaA-FL-FMO.


Instead of using 1mM standard samples of trp or 6-X-trp, we attempted to produce dyes from trp and NaX salts. We induced Fre-SttH expression, took the sample supernatant and added it to the ptac-TnaA-FMO and TALEsp2-TnaA-FMO cultures, and compared the titers of the all using supernatant from Fre-SttH cultures as substrate (Fig. 3). There is no significant difference between any of the samples. Both TALEsp2 cultures produced titers of approx. 0.09mM for tyrian purple and 0.23mM for 6, 6’di-chloro-indigo. RL, FL, and RBS both achieved titers of 0.12 and 0.28mM for tyrian purple and tyrian red respectively.

Figure 3: Measuring dye production of different TnaA-FMO strains from Fre-SttH + Trp + NaCl/NaBr. A) Pictures of different TnaA-FMO strains with supernatant of Fre-SttH + Trp + NaCl/NaBr added. B) Comparison of dye production titers of TALEsp2-TnaA-RBS-FMO and TALEsp2-TnaA-FL-FMO. C) Comparison of dye production titers of ptac-TnaA-RL-FMO, ptac-TnaA-FL-FMO, and ptac-TnaA-RBS-FMO.

Contribution: SUSTech Shenzhen 2022

Figure 1: A) SDS-PAGE of TnaA-FL-FMO and Fre-sttH. WC stand for whole cell sample and S stand for supernatant sample after cell lysis. B) Tyrian purple (left) and indigo (right) produced by 6-Br-trp and trp with TnaA-FL-FMO. C) DMSO solution of indigo (top) and tyrian purple (bottom). D) cloth dyed with tyrian purple.

We transform part TnaA-FL-FMO and Fre-sttH into DH5α cell without endogenous TnaA gene. After culture and induced expression of these strains, we use the SDS-PAGE to separate and show the expression of TnaA-FL-FMO and Fre-sttH. We found that we successfully express our fused proteins and these two proteins show high water solubility.

Strain that has been induced to express TnaA-FL-FMO also be cultured by NPB solution and 1mM trp or 6-Br-trp as substrate. After fermentation for 24h, we get obvious blue and purple dye in our culture tubes .

For purified indigo and tyrian purple, we dissolve the indigo from the cell pellet by DMSO and filter with a 0.2μm strainer. By diluting DMSO with water, the pigment is precipitated from the solution to obtain a relatively pure indigo solid precipitation. We also use the tyrian purple we produce in cloth dying.

Figure 2:Relatively pure tyrian (left) and indigo (right) solid precipitation by diluting DMSO with water

Dye concentration is calculated by a OD610/620 standard curve measured by LINKS_China 2021. We get a ~60% yield for indigo and ~20% yield for tyrian purple.


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BamHI site found at 2812
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal AgeI site found at 1219
  • 1000
    COMPATIBLE WITH RFC[1000]

References

Lee, J., Kim, J., Song, J.E. et al. Production of Tyrian purple indigoid dye from tryptophan in Escherichia coli. Nat Chem Biol 17, 104–112 (2021). https://doi.org/10.1038/s41589-020-00684-4