Difference between revisions of "Part:BBa K4011003"
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<partinfo>BBa_K4011003 short</partinfo> | <partinfo>BBa_K4011003 short</partinfo> | ||
− | Fre-SttH is a fusion protein used to halogenate the sixth carbon of tryptophan ( | + | Fre-SttH is a fusion protein used to halogenate the sixth carbon of tryptophan (trp) in the dye production of 6, 6’dibromoindigo (tyrian purple) and 6, 6’dichloroindigo (tyrian red), with the help of another fusion protein: TnaA-FMO. Fre-SttH is composed of two separate domains: Fre and SttH, fused together with a rigid 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>. |
<br>The part collection includes: Parts expressing Fre-SttH to convert Trp to 6-X-Trp. | <br>The part collection includes: Parts expressing Fre-SttH to convert Trp to 6-X-Trp. | ||
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Quantifying the production of 6-X-Trp in Fre-SttH. A) Concentration-time graph of Trp and 6-Br-Trp in ptac-Fre-SttH in <i>E. coli DH5a ΔTnaA</i> with 1.5mM Trp and NaBr. B) Concentration-time graph of Trp and 6-Cl-Trp in a culture of ptac-Fre-SttH in <i>E. coli DH5a ΔTnaA</i> with 1.7mM Trp and NaCl. C) HPLC results, from top to bottom, of Trp, 6-Br-Trp, 040 + NaBr culture at 0, 6, 12, 18, and 24h. D) HPLC results, from top to bottom, of Trp, 6-Cl-Trp, 040 + NaCl culture at 0, 6, 12, 18, and 24h. ]] | Quantifying the production of 6-X-Trp in Fre-SttH. A) Concentration-time graph of Trp and 6-Br-Trp in ptac-Fre-SttH in <i>E. coli DH5a ΔTnaA</i> with 1.5mM Trp and NaBr. B) Concentration-time graph of Trp and 6-Cl-Trp in a culture of ptac-Fre-SttH in <i>E. coli DH5a ΔTnaA</i> with 1.7mM Trp and NaCl. C) HPLC results, from top to bottom, of Trp, 6-Br-Trp, 040 + NaBr culture at 0, 6, 12, 18, and 24h. D) HPLC results, from top to bottom, of Trp, 6-Cl-Trp, 040 + NaCl culture at 0, 6, 12, 18, and 24h. ]] | ||
− | === | + | ===Production of dyes using Fre-SttH supernatant=== |
− | + | We attempted to produce dyes using Fre-SttH and TnaA-FMO 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 TnaA-FMO cultures 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. The successful production of tyrian red and tyrian purple in all cultures confirms the viability and stability of Fre-SttH expression and activity. | |
− | [[Image:T--LINKS China--Figure | + | [[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. ]] |
+ | ===Modelling: Determining Vmax and Km of Fre-SttH=== | ||
+ | Part of our measurement is to show how trp is converted into 6-Br-trp (by TnaA-FL-FMO) over time. We added about 1.7mM trp in a Fre-SttH saturated solution, then measured the concentrations of trp and 6-Br-trp every 6 hours for 4 times (24h in total). We obtained the raw data and fitted a natural exponential curve (equation) to the data in order to describe the relationship between time and trp concentration (note: we chose the natural exponential equation because it showed the highest R^2 among other equations we tried fitting). After that, we determined the reaction velocity at x-values (times) 6(h), 12(h), 18(h), and 24(h) (i.e. different trp concentrations) by taking the gradients of the natural exponential equation at the above points, thus obtaining 4 reaction velocities with respect to their substrate concentrations. Then, we fitted the Michealis-Meten equation to the calculated data and determined Vmax and Km. | ||
+ | |||
+ | ==Contribution: SUSTech Shenzhen 2022== | ||
+ | [[Image:no6.png|thumbnail|500px|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 produced by using culture of fermentation with Fre-sttH and trp. ]] | ||
+ | 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. | ||
+ | We then culture strain that has been induced to express Fre-sttH by NPB solution and 2.5mM trp and 300mM NaBr as substrate and fermetation for 24h. And then, we attempt to produce tyrian purple by TnaA-FL-FMO using the culture after fermentation of trp and NaBr with Fre-sttH and the result has no difference from fermentation using standard 1mM 6-Br-trp | ||
<span class='h3bb'>'''Sequence and Features'''</span> | <span class='h3bb'>'''Sequence and Features'''</span> | ||
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<partinfo>BBa_K4011003 parameters</partinfo> | <partinfo>BBa_K4011003 parameters</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 08:13, 8 October 2022
Fre-SttH
Fre-SttH is a fusion protein used to halogenate the sixth carbon of tryptophan (trp) in the dye production of 6, 6’dibromoindigo (tyrian purple) and 6, 6’dichloroindigo (tyrian red), with the help of another fusion protein: TnaA-FMO. Fre-SttH is composed of two separate domains: Fre and SttH, fused together with a rigid 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
Fre-SttH is a fusion protein used to halogenate the sixth carbon of the tryptophan in the dye production. Fre-SttH is composed of two separate domains: Fre is from E.coli and SttH is from Streptomyces toxytricini. They are fused by a rigid linker with the protein sequence EAAAKEAAAK. SttH is a trp-6-haloganese that requires FADH2 as a cofactor to convert trp and halogen ions into 6-X-trp, and is highly insoluble in E.coli. Therefore, Fre, a highly-soluble flavin reductase which reduces FAD to FADH2 from E.coli, is fused with SttH as a N-terminal soluble tag, enabling the protein to become soluble and eliminating the need for costly FADH2 cofactors to be added. We express Fre-SttH in ptac system and measured its enzymatic activity using HPLC (Lee et al, 2021).
Characterization
SDS-PAGE
We expressed Fre-SttH under T7 promoter in E. coli BL21(DE3) (Fig. 1A). SDS-PAGE of the sample showed decent Fre-SttH expression but suboptimal water solubility, since the supernatant sample has less intense target band compared to the whole cell sample (Fig. 1B).
For producing tyrian purple, Fre-SttH and TnaA has to be in two different strains, so we used a ΔTnaA E. coli strain, courtesy of Sha Zhou. However, our ΔTnaA E. coli was supplied as E. coli DH5α, which was incompatible with the T7 promoter.
Because of the need for a ΔTnaA E. coli strain, we decided to switch from the T7 system to the E. coli DH5α compatible ptac system. We constructed two ptac plasmids, ptac-Fre-SttH and ptac-histag-Fre-SttH, and transformed them into E. coli DH5α ΔTnaA (Fig. 1C).
We then induced expression of both proteins and performed SDS-PAGE. Results show that histag-Fre-SttH expression and solubility were poor, but Fre-SttH had extremely high expression and solubility (Fig. 1D). Thus, ptac-Fre-SttH in E. coli DH5α ΔTnaA was used for all further experiments.
HPLC
In order to model the enzymatic dynamics of Fre-SttH, we induced Fre-SttH expression and added the substrates. We then took samples of the culture in 6-hour-intervals for 24 hours for HPLC, and calculated the relative concentrations of trp and 6-X-trp (Fig. 2C & D). To learn about the detailed experimental setup, visit our experiment and measurement pages.
For sample added with trp and NaBr, the concentration of trp decreased from approximately 1.5 mM to 0.5mM, while the concentration of 6-Br-Trp increased from approximately 0mM to 1.0mM (Fig. 2A). We obtained similar result from sample with trp and NaCl, which the trp concentration went from approximately 1.7mM to 0.4mM and 6-Cl-Trp concentration increased from 0 to 1.3mM (Fig. 2B). For both samples, the yield of trp to 6-X-trp conversion by Fre-SttH was near 100%. As trp still remains after 24h in both cultures, a fermentation time of 36 or 48h might yield a higher concentration of 6-X-Trp, should it be desired. From this, we acquired several enzymatic constants for Michaelis-Menten equation, which was vital to our modeling team.
Production of dyes using Fre-SttH supernatant
We attempted to produce dyes using Fre-SttH and TnaA-FMO 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 TnaA-FMO cultures 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. The successful production of tyrian red and tyrian purple in all cultures confirms the viability and stability of Fre-SttH expression and activity.
Modelling: Determining Vmax and Km of Fre-SttH
Part of our measurement is to show how trp is converted into 6-Br-trp (by TnaA-FL-FMO) over time. We added about 1.7mM trp in a Fre-SttH saturated solution, then measured the concentrations of trp and 6-Br-trp every 6 hours for 4 times (24h in total). We obtained the raw data and fitted a natural exponential curve (equation) to the data in order to describe the relationship between time and trp concentration (note: we chose the natural exponential equation because it showed the highest R^2 among other equations we tried fitting). After that, we determined the reaction velocity at x-values (times) 6(h), 12(h), 18(h), and 24(h) (i.e. different trp concentrations) by taking the gradients of the natural exponential equation at the above points, thus obtaining 4 reaction velocities with respect to their substrate concentrations. Then, we fitted the Michealis-Meten equation to the calculated data and determined Vmax and Km.
Contribution: SUSTech Shenzhen 2022
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. We then culture strain that has been induced to express Fre-sttH by NPB solution and 2.5mM trp and 300mM NaBr as substrate and fermetation for 24h. And then, we attempt to produce tyrian purple by TnaA-FL-FMO using the culture after fermentation of trp and NaBr with Fre-sttH and the result has no difference from fermentation using standard 1mM 6-Br-trp
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12INCOMPATIBLE WITH RFC[12]Illegal NheI site found at 576
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25INCOMPATIBLE WITH RFC[25]Illegal NgoMIV site found at 948
- 1000INCOMPATIBLE WITH RFC[1000]Illegal SapI.rc site found at 424
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