Difference between revisions of "Part:BBa K4652002"
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<b>Figure 2.</b> Verification of pT7-SpyTag-eGFP-SpyCatcher (Part:BBa_K4652002) using colony PCR. PCR was performed using a CmR-specific forward primer from the vector and a SpyCatcher-specific reverse primer from the gene. The expected size of the amplified DNA fragments is 2204 bp. The rightmost lane displays a 1 kb DNA ladder. The numbers correspond to selected colonies, with one control derived from a mock pick from a clear zone on the plate. | <b>Figure 2.</b> Verification of pT7-SpyTag-eGFP-SpyCatcher (Part:BBa_K4652002) using colony PCR. PCR was performed using a CmR-specific forward primer from the vector and a SpyCatcher-specific reverse primer from the gene. The expected size of the amplified DNA fragments is 2204 bp. The rightmost lane displays a 1 kb DNA ladder. The numbers correspond to selected colonies, with one control derived from a mock pick from a clear zone on the plate. | ||
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==Thermostability of SpyTag-GFP-SpyCatcher== | ==Thermostability of SpyTag-GFP-SpyCatcher== | ||
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To assess whether the thermostability of GFP was enhanced by the addition of SpyTag and SpyCatcher, lysates from the transformed E. coli BL21, induced with IPTG, were subjected to a heat tolerance test at 90°C – a temperature known to degrade wild-type GFP (Figure 1). As illustrated in Figure 3, despite a pronounced decline in activity within the first minute of treatment, the fluorescence intensities remained relatively consistent up to 3 minutes. The retention of 22% GFP activity indicates a marked improvement in thermostability compared to the mere 1% observed for wild-type GFP at 90°C after 3 minutes (Figure 4). | To assess whether the thermostability of GFP was enhanced by the addition of SpyTag and SpyCatcher, lysates from the transformed E. coli BL21, induced with IPTG, were subjected to a heat tolerance test at 90°C – a temperature known to degrade wild-type GFP (Figure 1). As illustrated in Figure 3, despite a pronounced decline in activity within the first minute of treatment, the fluorescence intensities remained relatively consistent up to 3 minutes. The retention of 22% GFP activity indicates a marked improvement in thermostability compared to the mere 1% observed for wild-type GFP at 90°C after 3 minutes (Figure 4). | ||
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<b>Figure 3.</b> Thermostability of cyclized SpyTag-GFPmut3b-SpyCatcher protein at 90°C. E. coli BL21 transformed with BBa_K4652002 was induced using 0.3 mM IPTG at 25°C for 20 hrs. Bacterial lysates were subjected to 90°C treatment for 3 min with an interval of 0.5 min each. Subsequently, the fluorescence of 100μl from each treated lysate was measured at Ex/Em = 483/513 nm. All values were normalized to the average of the untreated control, with the resulting ratio representing the fluorescence fold change. | <b>Figure 3.</b> Thermostability of cyclized SpyTag-GFPmut3b-SpyCatcher protein at 90°C. E. coli BL21 transformed with BBa_K4652002 was induced using 0.3 mM IPTG at 25°C for 20 hrs. Bacterial lysates were subjected to 90°C treatment for 3 min with an interval of 0.5 min each. Subsequently, the fluorescence of 100μl from each treated lysate was measured at Ex/Em = 483/513 nm. All values were normalized to the average of the untreated control, with the resulting ratio representing the fluorescence fold change. | ||
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==== <span style="color:mediumseagreen;">100°C treatment</span> ==== | ==== <span style="color:mediumseagreen;">100°C treatment</span> ==== | ||
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==== <span style="color:mediumseagreen;">Cyclized GFP thermal tolerance properties</span> ==== | ==== <span style="color:mediumseagreen;">Cyclized GFP thermal tolerance properties</span> ==== | ||
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==== <span style="color:mediumseagreen;">Mechanism</span> ==== | ==== <span style="color:mediumseagreen;">Mechanism</span> ==== | ||
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The mechanism for the spontaneous cyclization reaction involves Asp7 on the SpyTag at the N-terminus forming double hydrogen bonds with Glu77 on the SpyCatcher at the C-terminus. This interaction strengthens the creation of an irreversible isopeptide bond between Asp7 on SpyTag and Lys31 on SpyCatcher. As a result, the protein is seamlessly cyclized, enhancing its resistance to chemical, thermal, or enzymatic degradation<sup>3</sup>. | The mechanism for the spontaneous cyclization reaction involves Asp7 on the SpyTag at the N-terminus forming double hydrogen bonds with Glu77 on the SpyCatcher at the C-terminus. This interaction strengthens the creation of an irreversible isopeptide bond between Asp7 on SpyTag and Lys31 on SpyCatcher. As a result, the protein is seamlessly cyclized, enhancing its resistance to chemical, thermal, or enzymatic degradation<sup>3</sup>. | ||
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To investigate the impact of cyclization on protein thermostability, we created a linear version of SpyTag-GFP-SpyCatcher by introducing a mutation, substituting Asp7 with Ala7 on SpyTag, using site-directed mutagenesis by high-fidelity KOD-plus DNA polymerase with a primer sequence of 5'- AGCCCACATCGTGATGGTGGCAGCCTACAAGCCGACGAAG -3’. The mutated site was confirmed by DNA sequencing. This mutant (SpyTag (D7A)-GFP-SpyCatcher, [[Part:BBa_K4652001]]) was constructed in the same format, resulting in the expression plasmid of T7-RBS-SpyTag (D7A)-GFP-SpyCatcher-Tr ([[Part:BBa_K4652003]]). | To investigate the impact of cyclization on protein thermostability, we created a linear version of SpyTag-GFP-SpyCatcher by introducing a mutation, substituting Asp7 with Ala7 on SpyTag, using site-directed mutagenesis by high-fidelity KOD-plus DNA polymerase with a primer sequence of 5'- AGCCCACATCGTGATGGTGGCAGCCTACAAGCCGACGAAG -3’. The mutated site was confirmed by DNA sequencing. This mutant (SpyTag (D7A)-GFP-SpyCatcher, [[Part:BBa_K4652001]]) was constructed in the same format, resulting in the expression plasmid of T7-RBS-SpyTag (D7A)-GFP-SpyCatcher-Tr ([[Part:BBa_K4652003]]). | ||
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==== <span style="color:mediumseagreen;">Comparison between linear and circular form of GFP proteins</span> ==== | ==== <span style="color:mediumseagreen;">Comparison between linear and circular form of GFP proteins</span> ==== | ||
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==== <span style="color:mediumseagreen;">Protein structure of SpyTag-GFP-SpyCatcher</span> ==== | ==== <span style="color:mediumseagreen;">Protein structure of SpyTag-GFP-SpyCatcher</span> ==== | ||
To validate the protein structures resulting from SpyTag and SpyCatcher cyclization and its linear counterpart generated through mutation, we conducted SDS-PAGE followed by Coomassie Blue Staining on IPTG-induced bacterial lysates. In Figure 8, the linear mutant manifested at its anticipated size of 44.22 kDa. The mobility of the cyclized protein differed, likely due to changes in charge or conformation. This observation aligns with Dr. Schoene's findings<sup>1</sup> and supports the results from our heat tolerance fluorescence experiments. Notably, our protein analysis can partly account for the diminished activity observed during high-temperature exposure in Figure 7, possibly attributable to incomplete GFP cyclization. When GFP continues exposure at near boiling temperatures, the cyclized form exhibits marked resistance over an extended duration. | To validate the protein structures resulting from SpyTag and SpyCatcher cyclization and its linear counterpart generated through mutation, we conducted SDS-PAGE followed by Coomassie Blue Staining on IPTG-induced bacterial lysates. In Figure 8, the linear mutant manifested at its anticipated size of 44.22 kDa. The mobility of the cyclized protein differed, likely due to changes in charge or conformation. This observation aligns with Dr. Schoene's findings<sup>1</sup> and supports the results from our heat tolerance fluorescence experiments. Notably, our protein analysis can partly account for the diminished activity observed during high-temperature exposure in Figure 7, possibly attributable to incomplete GFP cyclization. When GFP continues exposure at near boiling temperatures, the cyclized form exhibits marked resistance over an extended duration. | ||
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<b>Figure 8.</b> Protein structure analysis of cyclized form and linear form of SpyTag-eGFP-SpyCatcher. IPTG-induced lysates were run on a 4-12% gradient SDS-PAGE (BIO-RAD) and stained with standard Coomassie Blue. The AceColor Prestained Protein Marker (10 - 180 kDa) was used for size reference. Lane 1 refers to the cyclized proteins derived from lysates of SpyTag-GFP-SpyCatcher (BBa_K4652002). Lane 2 refers to the linear proteins derived from lysates of SpyTag (D7A)-GFP-SpyCatcher (BBa_K4652003). The predicted molecular weight for the SpyTag-GFP-SpyCatcher protein is 44.22 kDa. | <b>Figure 8.</b> Protein structure analysis of cyclized form and linear form of SpyTag-eGFP-SpyCatcher. IPTG-induced lysates were run on a 4-12% gradient SDS-PAGE (BIO-RAD) and stained with standard Coomassie Blue. The AceColor Prestained Protein Marker (10 - 180 kDa) was used for size reference. Lane 1 refers to the cyclized proteins derived from lysates of SpyTag-GFP-SpyCatcher (BBa_K4652002). Lane 2 refers to the linear proteins derived from lysates of SpyTag (D7A)-GFP-SpyCatcher (BBa_K4652003). The predicted molecular weight for the SpyTag-GFP-SpyCatcher protein is 44.22 kDa. | ||
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= <span style="color:royalblue;">CONCLUSION</span> = | = <span style="color:royalblue;">CONCLUSION</span> = | ||
Through a series of genetic and biochemical modifications, we successfully enhanced the thermostability of GFP protein. By removing its start and stop codons and integrating SpyTag and SpyCatcher at the N and C termini, respectively, we created a cyclized GFP protein with improved resilience to thermal stress. Experimental evidence from heat tolerance tests underscored the cyclized GFP's superior ability to retain activity under extreme temperatures compared to its linear counterpart and the wild-type GFP. Our findings are consistent with previous researches attempting cyclization of a protein, suggesting that the introduction of SpyTag and SpyCatcher not only provides a method to stabilize proteins but also has potential applications in synthetic biology requiring thermally stable proteins. | Through a series of genetic and biochemical modifications, we successfully enhanced the thermostability of GFP protein. By removing its start and stop codons and integrating SpyTag and SpyCatcher at the N and C termini, respectively, we created a cyclized GFP protein with improved resilience to thermal stress. Experimental evidence from heat tolerance tests underscored the cyclized GFP's superior ability to retain activity under extreme temperatures compared to its linear counterpart and the wild-type GFP. Our findings are consistent with previous researches attempting cyclization of a protein, suggesting that the introduction of SpyTag and SpyCatcher not only provides a method to stabilize proteins but also has potential applications in synthetic biology requiring thermally stable proteins. | ||
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= <span style="color:royalblue;">REFERENCE</span> = | = <span style="color:royalblue;">REFERENCE</span> = |
Latest revision as of 07:45, 23 September 2023
T7-RBS-SpyTag-GFP-SpyCatcher-Tr
SpyRing cyclization technique to enhance enzyme thermal resilience was clarified by Dr. Mark Howarth’s team1. SpyRing harbors genetically modified SpyTag (13 amino acids) on the N-terminus and SpyCatcher (12kDa) on the C-terminus on the protein of interest. This context spontaneously reacts together through an irreversible isopeptide bond. SpyRing cyclization was demonstrated successfully to increase stress resilience of β-lactamase and some industrially important enzymes.
THERMOSTABILITY OF WILD-TYPE GFP
The existing BioBrick pT7-eGFP (Part:BBa_K1833000) comprises a T7 promoter, RBS, and terminator, with an inserted gene of GFPmut3b. This plasmid was retransformed into E. coli BL21. Upon 0.3 mM IPTG induction at 25°C for 20 hrs, bacterial lysates underwent heat tests at varied temperatures for 3 minutes, as indicated in Figure 1. Relative to the untreated control, fluorescence fold change depicted thermostability trends from 70°C, 80°C, to 90°C, retaining 59%, 12%, and 1% of the GFP signal, respectively. This data provided insights into the innate heat tolerance properties of GFPmut3b protein.
Figure 1.
Thermostability of GFPmut3b protein. E. coli BL21 transformed with BBa_K1833000 was induced using 0.3 mM IPTG at 25°C for 20 hrs. Bacterial lysates were subjected to temperatures of 70°C, 80°C, and 90°C for 3 min each. Subsequently, the fluorescence of 100μl from each treated lysate was measured at Ex/Em = 483/513 nm. All values were normalized to the average of the untreated control, with the resulting ratio representing the fluorescence fold change.
IMPROVED THERMOSTABILITY OF GPF BY CYCLIZATION USING SPYRING
Plasmid Construction
To enhance the thermostability of the GFP protein, we deleted start (ATG) codon and stop (TAA) codon, and incorporated SpyTag at the N-terminus and SpyCatcher at the C-terminus. This DNA fragment was synthesized by Integrated DNA Technologies, Inc. (IDT) and then cloned into pSB1C3 (SpyTag-GFP-SpyCatcher, Basic Part:BBa_K4652000). Then, the part was connected with a T7 promoter (Part:BBa_K1833999), a strong RBS (Part:BBa_B0030), and a double terminator (Part:BBa_B0015). This setup mirrored the context of pT7-eGFP (Part:BBa_K1833000), with the exception of the added SpyTag and SpyCatcher. The final construct was verified using colony PCR (Figure 2) and further validated through DNA sequencing. This resultant construct was designated as the improved BioBrick part, pT7-SpyTag-GFP-SpyCatcher (Composite Part:BBa_K4652002).
Figure 2. Verification of pT7-SpyTag-eGFP-SpyCatcher (Part:BBa_K4652002) using colony PCR. PCR was performed using a CmR-specific forward primer from the vector and a SpyCatcher-specific reverse primer from the gene. The expected size of the amplified DNA fragments is 2204 bp. The rightmost lane displays a 1 kb DNA ladder. The numbers correspond to selected colonies, with one control derived from a mock pick from a clear zone on the plate.
Thermostability of SpyTag-GFP-SpyCatcher
90°C treatment
To assess whether the thermostability of GFP was enhanced by the addition of SpyTag and SpyCatcher, lysates from the transformed E. coli BL21, induced with IPTG, were subjected to a heat tolerance test at 90°C – a temperature known to degrade wild-type GFP (Figure 1). As illustrated in Figure 3, despite a pronounced decline in activity within the first minute of treatment, the fluorescence intensities remained relatively consistent up to 3 minutes. The retention of 22% GFP activity indicates a marked improvement in thermostability compared to the mere 1% observed for wild-type GFP at 90°C after 3 minutes (Figure 4).
Figure 3. Thermostability of cyclized SpyTag-GFPmut3b-SpyCatcher protein at 90°C. E. coli BL21 transformed with BBa_K4652002 was induced using 0.3 mM IPTG at 25°C for 20 hrs. Bacterial lysates were subjected to 90°C treatment for 3 min with an interval of 0.5 min each. Subsequently, the fluorescence of 100μl from each treated lysate was measured at Ex/Em = 483/513 nm. All values were normalized to the average of the untreated control, with the resulting ratio representing the fluorescence fold change.
Figure 4. Comparison of wild-type GFPmut3b and cyclized SpyTag-GPTmut3b-SypCatcher proteins. E. coli BL21 transformed with indicated plasmid was induced using 0.3 mM IPTG at 25°C for 20 hrs. Bacterial lysates were subjected to temperatures of 90°C for 3 min. The fluorescence of 100μl lysates was measured at Ex/Em = 483/513 nm. All values were normalized to the average of the untreated control, with the resulting ratio representing the fluorescence fold change.
100°C treatment
Furthermore, the lysates were also exposed to 100°C for durations ranging from 0.5 to 3 minutes. Remarkably, GFP activity demonstrated tolerance at boiling temperatures (Figure 5), maintaining levels comparable to those observed at 90°C (Figure 3). However, there was a more pronounced loss of activity at the 0.5-minute mark. The data is consistent with Dr. Schoene’s report where β-lactamase with SpyTag at N-terminus and SpyCatcher at C-terminus exhibited resilience to boiling temperature2.
Figure 5. Thermostability of cyclized SpyTag-GFPmut3b-SpyCatcher protein at 100°C. E. coli BL21 transformed with BBa_K4652002 was induced using 0.3 mM IPTG at 25°C for 20 hrs. Bacterial lysates were subjected to 100°C treatment for 3 min with an interval of 0.5 min each. The fluorescence of 100μl from each treated lysate was measured at Ex/Em = 483/513 nm. All values were normalized to the average of the untreated control, with the resulting ratio representing the fluorescence fold change.
Cyclized GFP thermal tolerance properties
In addition, we prolonged the exposure of cyclized GFP to 100°C up to 30 minutes. As shown in Figure 6, the GFP signal retained approximately 45% of its activity within the first minute, 30-35% up to 3 minutes, 20-28% up to 5 minutes, 10% at 10 minutes, and dropped below 5% after 15 minutes. These results clearly highlight the potential thermal tolerance of a synthetic cyclized protein engineered using SpyTag and SpyCatcher elements.
Figure 6. Thermal tolerance of cyclized SpyTag-GFPmut3b-SpyCatcher protein at 100°C. E. coli BL21 transformed with BBa_K4652002 was induced using 0.3 mM IPTG at 25°C for 20 hrs. Bacterial lysates were subjected to 100°C treatment for up to 30 min at the indicated time points. The fluorescence of 100μl from each treated lysate was measured at Ex/Em = 483/513 nm. All values were normalized to the average of the untreated control, with the resulting ratio representing the fluorescence fold change.
Linear Form of SpyTag-GFP-SpyCatcher Mutant
Mechanism
The mechanism for the spontaneous cyclization reaction involves Asp7 on the SpyTag at the N-terminus forming double hydrogen bonds with Glu77 on the SpyCatcher at the C-terminus. This interaction strengthens the creation of an irreversible isopeptide bond between Asp7 on SpyTag and Lys31 on SpyCatcher. As a result, the protein is seamlessly cyclized, enhancing its resistance to chemical, thermal, or enzymatic degradation3.
Plasmid construction
To investigate the impact of cyclization on protein thermostability, we created a linear version of SpyTag-GFP-SpyCatcher by introducing a mutation, substituting Asp7 with Ala7 on SpyTag, using site-directed mutagenesis by high-fidelity KOD-plus DNA polymerase with a primer sequence of 5'- AGCCCACATCGTGATGGTGGCAGCCTACAAGCCGACGAAG -3’. The mutated site was confirmed by DNA sequencing. This mutant (SpyTag (D7A)-GFP-SpyCatcher, Part:BBa_K4652001) was constructed in the same format, resulting in the expression plasmid of T7-RBS-SpyTag (D7A)-GFP-SpyCatcher-Tr (Part:BBa_K4652003).
Comparison between linear and circular form of GFP proteins
Figure 7 clearly demonstrates that the linear version fails to withstand temperatures of 90°C beyond 1 minute, even though it maintained high activity up to 0.5 minutes. Meanwhile, the cyclized GFP exhibited fluorescence intensities of around 20-30%, when exposed to 90°C or even under boiling conditions (100°C) for as long as 3 minutes. These outcomes underscore the enhanced thermal tolerance conferred by protein cyclization.
Figure 7. Thermal tolerance between cyclized and linear forms of SpyTag-GFPmut3b-SpyCatcher proteins. E. coli BL21 were transformed with BBa_K4652002 for the cyclized form and BBa_K4652003 for the linear form. After induced by 0.3 mM IPTG at 25°C for 20 hrs, the bacterial lysates were harvested and subjected to 90°C or 100°C treatment for up to 3 min at the intervals of 0.5 min. The fluorescence of 100μl from each treated lysate was measured at Ex/Em = 483/513 nm. All values were normalized to the average of the untreated control, with the resulting ratio representing the fluorescence fold change.
Protein structure of SpyTag-GFP-SpyCatcher
To validate the protein structures resulting from SpyTag and SpyCatcher cyclization and its linear counterpart generated through mutation, we conducted SDS-PAGE followed by Coomassie Blue Staining on IPTG-induced bacterial lysates. In Figure 8, the linear mutant manifested at its anticipated size of 44.22 kDa. The mobility of the cyclized protein differed, likely due to changes in charge or conformation. This observation aligns with Dr. Schoene's findings1 and supports the results from our heat tolerance fluorescence experiments. Notably, our protein analysis can partly account for the diminished activity observed during high-temperature exposure in Figure 7, possibly attributable to incomplete GFP cyclization. When GFP continues exposure at near boiling temperatures, the cyclized form exhibits marked resistance over an extended duration.
Figure 8. Protein structure analysis of cyclized form and linear form of SpyTag-eGFP-SpyCatcher. IPTG-induced lysates were run on a 4-12% gradient SDS-PAGE (BIO-RAD) and stained with standard Coomassie Blue. The AceColor Prestained Protein Marker (10 - 180 kDa) was used for size reference. Lane 1 refers to the cyclized proteins derived from lysates of SpyTag-GFP-SpyCatcher (BBa_K4652002). Lane 2 refers to the linear proteins derived from lysates of SpyTag (D7A)-GFP-SpyCatcher (BBa_K4652003). The predicted molecular weight for the SpyTag-GFP-SpyCatcher protein is 44.22 kDa.
CONCLUSION
Through a series of genetic and biochemical modifications, we successfully enhanced the thermostability of GFP protein. By removing its start and stop codons and integrating SpyTag and SpyCatcher at the N and C termini, respectively, we created a cyclized GFP protein with improved resilience to thermal stress. Experimental evidence from heat tolerance tests underscored the cyclized GFP's superior ability to retain activity under extreme temperatures compared to its linear counterpart and the wild-type GFP. Our findings are consistent with previous researches attempting cyclization of a protein, suggesting that the introduction of SpyTag and SpyCatcher not only provides a method to stabilize proteins but also has potential applications in synthetic biology requiring thermally stable proteins.
REFERENCE
- Schoene C, Bennett SP, Howarth M. SpyRings Declassified: A Blueprint for Using Isopeptide-Mediated Cyclization to Enhance Enzyme Thermal Resilience. Methods Enzymol. 2016;580:149-67. doi: 10.1016/bs.mie.2016.05.004. Epub 2016 Jun 16. PMID: 27586332.
- Schoene C, Fierer JO, Bennett SP, Howarth M. SpyTag/SpyCatcher cyclization confers resilience to boiling on a mesophilic enzyme. Angew Chem Int Ed Engl. 2014 Jun 10;53(24):6101-4. doi: 10.1002/anie.201402519. Epub 2014 May 9. PMID: 24817566; PMCID: PMC4286826.
- Reddington SC, Howarth M. Secrets of a covalent interaction for biomaterials and biotechnology: SpyTag and SpyCatcher. Curr Opin Chem Biol. 2015 Dec;29:94-9. doi: 10.1016/j.cbpa.2015.10.002. Epub 2015 Oct 30. PMID: 26517567.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000INCOMPATIBLE WITH RFC[1000]Illegal BsaI.rc site found at 759