Difference between revisions of "Part:BBa K3037005"

(Experiments in Detail)
(4) Measurement of fluorescence)
 
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|-
 
|-
 
|'''RFC standard'''
 
|'''RFC standard'''
|RFC 25 compatible
+
|[[Help:Assembly_standard_25|Freiburg RFC25 standard]]
 
|-
 
|-
 
|'''Backbone'''
 
|'''Backbone'''
|pSB1C3<br>  
+
|[https://parts.igem.org/Help:2019_DNA_Distribution pSB1C3<br>]
 +
|-
 +
|'''Experimental Backbone'''
 +
|[https://parts.igem.org/Part:BBa_K3037000 pOCC97<br>]
 
|-
 
|-
 
|'''Submitted by'''
 
|'''Submitted by'''
|Team:TU_Dresden 2019[https://2019.igem.org/Team:TU_Dresden]
+
|Team: [https://2019.igem.org/Team:TU_Dresden TU_Dresden 2019]
 
|}
 
|}
  
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== Overview ==
 
== Overview ==
  
This BioBrick was designed as a composite BioBrick by the team TU Dresden 2019. It is a fusion of dCas9 [https://parts.igem.org/Part:BBa_K3037002 (BBa_K3037002)] and eGFP [https://parts.igem.org/Part:BBa_K3037006 (BBa_K3037006).]
+
This BioBrick was designed as a composite BioBrick by the team TU Dresden 2019. It is a fusion of dCas9 [https://parts.igem.org/Part:BBa_K3037002 (BBa_K3037002)] and eGFP [https://parts.igem.org/Part:BBa_K3037006 (BBa_K3037006)][https://2019.igem.org/Team:TU_Dresden/Parts (more information).]
  
The dCas9 can bind to any sequence of DNA and eGFP is an enhanced reporter protein, giving emission at the wavelength of XX nm (reference)[1].  
+
The dCas9 can bind to any sequence of DNA specified by its guideRNA. The eGFP (enhanced reporter protein) is used as reporter, resulting in fluorescence emission at 530 nm [1].  
  
Additionally, the BioBrick is designed to have a N-terminal MBP fused to it [https://parts.igem.org/Part:BBa_K3037001 (BBa_K3037001).]This improves the solubility and expression and, therefore, the total cytoplasmic yield of the protein. The MBP can further be used to purify the fusion protein on an Amylose Resin and, afterwards, can be cleaved off via digestion with PreScission protease.
+
<div style="text-align:justify;">
 +
Additionally, the BioBrick is designed to have a N-terminal Maltose-binding-protein (MBP) fused to it [https://parts.igem.org/Part:BBa_K3037001 (BBa_K3037001).]This improves the solubility and expression and thus, the total cytoplasmic yield of the protein. The MBP can further be used to purify the fusion protein via amylose resin and afterwards, it can be cleaved off by digestion with a PreScission protease.
 +
 
 +
The design of the here presented BioBrick is based on [https://parts.igem.org/Part:BBa_K1994025 BBa_K1994025.] The original composite BioBrick consists of a transcriptional fusion of GFP and dCas9, both having their own promoter and RBS. A terminator separates both units. However, from our perspective having two transcriptional units as a composite part makes little sense to couple dCas9 activity with an easy readout - such as GFP. Therefore, our improvement was to fuse the dCas9 with eGFP to generate a translational fusion protein. Additionally, having the MBP fused on the N-terminus facilitates purification and easy cleaving off, as already explained before. We strongly believe that the combination of these improvements will be tremendously helpful for future iGEM teams working on dCas9 based projects. Down below, our characterization of the new improved composite part.
  
 
== Characterization ==
 
== Characterization ==
Line 35: Line 41:
 
We performed the following characterization experiments:
 
We performed the following characterization experiments:
  
1) Prove of DNA-binding ability of dCas9 via an EMSA shift assay
+
<b>1)</b> Expression using pOCC97 [https://parts.igem.org/Part:BBa_K3037000 (BBa_K3037000)] in <i>E. coli</i> pRARE T7 - Proof of the correct functioning of GFP
  
2) Characterization of guide RNA usage and DNA affinity via an EMSA shift assay with different guideRNA pools
+
<b>2)</b> Construct purification and tag-removal - Proof of the correct functioning of MBP
  
3) Expression and purification
+
<b>3)</b> Proof of DNA-binding ability of dCas9 via Electrophoretic Mobility Shift Assay (EMSA) - Proof of the correct functioning of dCas9
  
4) For fluorescence measurements refer to the BioBrick [https://parts.igem.org/Part:BBa_K3037006 BBa_K3037006]
+
<b>4)</b> Measurement of fluorescence
  
 
=== Experiments in Detail ===
 
=== Experiments in Detail ===
  
==== 1) Prove of DNA-binding ability of dCas9 via an EMSA shift assay ====
+
==== 1) Expression using pOCC97 (BBa_K3037000) in <i>E. coli</i> pRARE T7 - Proof of the correct functioning of GFP ====
 +
As a quick and easy proof of principle experiment, we used our over-expression plasmid pOCC97 ([https://parts.igem.org/Part:BBa_K3037000 BBa_K3037000) and introduced our construct (BBa_K3037005). After inducing expression in growing <i>E.coli</i> cells with IPTG, we took a sample, transferred it into an Eppendorf tupe and showed that these  <i>E.coli</i> cells glow upon excitation with UV light (Figure 1). Thus, we concluded that our construct of MBP+eGFP+dCas9 was expressed successfully.
  
 +
[[File:T--TU_Dresden--Expressing_GFP_BBa_K3037000.png|center|200px|thumb|none|Figure 1: Expression of BBa_K3037005 in pOCC97]]
  
<b>1. Materials:</b>
+
==== 2) Construct purification and tag-removal - Proof of the correct functioning of MBP ====
  
A. 100 ng of PCR amplified <span style="font-style: italic;">Sry</span> gene
+
The protein was purified via an amylose resin column with the a N-terminal-MBP-tag [https://parts.igem.org/Part:BBa_K3037001 BBa_K3037001] (Figure 2).
  
B. 200 ng of dCas9-GFP
 
  
C. 200 ng of guide RNA specifically targeting the amplified <span style="font-style: italic;">Sry</span> gene
+
[[File:T--TU_Dresden--Amilose_Resin_2_BBa_K3037005.png|center|400px|thumb|none|Figure 2: Amilose resin purification using MBP-tag. The upper arrow shows the location in the gel of this BioBrick (BBa_K3037005). The lower ones show the MBP-tag after beeing cleaved off]]
  
D. 1 x Reaction buffer - 20 mM Hepes buffer (pH 7.2)
+
The comparison of lane 4 and 5 illustrates nicely the performance of the MPP-tag with the amylose resin. Upon elution in lane 5 many truncated versions appear. This was expected since it often occurs when expressing large recombinant proteins. The high intensity of the bands shows that previously these proteins were bound to the resin as they were not in lane 4. After the digestion with 3C protease, a very strong signal appears at 42 kDa indicating that the preScission sites are intact and were recognized. The purification of the complete transcript from the cleaved off tag was achieved by cation exchange chromatography on a HiTrap SP column.
  
100 mM Nacl
+
==== 3) Prove of DNA-binding ability of dCas9 via EMSA - Proof of the correct functioning of dCas9====
  
5 mM Mgcl2
+
<b>1. Materials:</b>
  
0.1 mM EDTA  
+
*100 ng of PCR amplified <span style="font-style: italic;">sry</span> gene
 +
*200 ng of dCas9-GFP
 +
*200 ng of guide RNA specifically targeting the amplified <span style="font-style: italic;">sry</span> gene
 +
*1 x Reaction buffer - 20 mM Hepes buffer (pH 7.2)
 +
** 100 mM NaCl
 +
** 5 mM MgCl2
 +
** 0.1 mM EDTA  
  
  
Six different guide RNAs were designed for targeting different regions of <span style="font-style: italic;">Sry</span> gene. Using the online tool Benchling and FASTA sequence of <span style="font-style: italic;">Sry</span> gene:
+
Six different guide RNAs were designed for targeting different regions of <span style="font-style: italic;">sry</span> gene. Using the online tool Benchling and Fasta sequence of <span style="font-style: italic;">sry</span> gene (Table 1).
  
 
1: AACTAAACATAAGAAAGTGA
 
1: AACTAAACATAAGAAAGTGA
Line 79: Line 92:
 
6: CCATGAACGCATTCATCGTG
 
6: CCATGAACGCATTCATCGTG
  
[[File:T--TU_Dresden--EMSA_Primers_BBa_K3037005.png|500px|thumb|left]]
+
[[File:T--TU_Dresden--EMSA_Primers_BBa_K3037005.png|center|400px|thumb|left|Table 1: Overview of different guide RNAs with the context of the sequence and the PAM sequence]]
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
  
 
<b>2. Methods:</b>
 
<b>2. Methods:</b>
  
1. We wanted to check if the overall efficiency of mobility shift increases when combinations of guide RNAs are used, so individual reactions with combinations of guide RNA were used.  
+
1. We wanted to check if the overall efficiency of mobility shift increases when different combinations of guide RNAs are used.
  
2. Guide RNA, dCas9-GFP and <span style="font-style: italic;">Sry</span> gene were incubated in reaction buffer (respective amounts mentioned in the Materials section) at 37 °C for 1 hour.  
+
2. Guide RNA, dCas9-GFP and <span style="font-style: italic;">sry</span> gene were incubated in reaction buffer (respective amounts mentioned in the materials section) for 37 °C for 1 hour.  
  
3. Post incubation, they were mixed with loading dye without SDS, 20 % glycerol in Orange G dye and loaded onto 4-20 % gradient acrylamide - TBE precast gel. Gel was run for 3 hours at 75 V in 1x TBE buffer.  
+
3. Post incubation, they were mixed with loading dye without SDS, 20 % glycerol in Orange G dye and loaded onto a 4-20 % gradient acrylamide- TBE precast gel. Two gels were run for 2 and 3 hours at 75 V in 1 x TBE buffer.  
  
4. Gel was then stained using EtBR with 1:20000 dilution in 1x TBE for 10 minutes.  
+
4. Gel was then stained using EtBr with 1:20000 dilution in 1x TBE for 10 minutes.  
 
   
 
   
  
 
<b>3.1 Results and Discussion of the 2 hours gel:</b>
 
<b>3.1 Results and Discussion of the 2 hours gel:</b>
  
[[File:T--TU_Dresden--EMSA1_BBa_K3037005.png|200px|thumb|left]]
+
[[File:T--TU_Dresden--EMSA1_BBa_K3037005.png|center|400px|thumb|left|Figure 3: Electrophoretic Mobility Shift Assay (EMSA) after a two hours run using dCas9 with different guideRNAs.]]
 
+
Lane 1 - There is a clear <span style="font-style: italic;">Sry</span> gene at 800 base pairs and when <span style="font-style: italic;">Sry</span> gene is incubated with only dCas9.
+
 
+
Lane 2 - There is no shift seen in the position of the gene.
+
 
+
Lane 3 - When guide RNA 1 was incubated with the dCas9 DNA reaction mix, we see a shift in the mobility, this is because of the protein DNA interaction and the binding is hindering the gene mobility.
+
 
+
Lanes 5,6,7,8 and 9 – Different combinations of guide RNAs were used. From Lanes 7 and 8 we see the highest mobility shift.
+
 
+
From the electromobility shift assay performed above we conclude that our expressed dCas9-GFP protein is functional and is able to successfully bind to gene with the help of appropriate guide RNAs.  
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
  
 +
Lane 1+2 - There is a clear <span style="font-style: italic;">sry</span> band at 800 base pairs and when the <span style="font-style: italic;">sry</span> gene is incubated only with dCas9 without guideRNA. Over all, no shift is observed.
  
 +
Lane 3 - When guideRNA 1 was incubated with the dCas9 DNA reaction mix, we saw a shift in the mobility caused by the protein DNA interaction. The binding hinders the DNA mobility.
  
 +
Lanes 5, 6, 7, 8 and 9 – Different combinations of guide RNAs were used. From lane 7 and 8 we see the highest mobility shift.
  
 +
From the electromobility shift assay performed above, we conclude that our expressed dCas9-GFP protein is functional and is able to successfully bind to DNA with the help of appropriate guideRNAs.
  
  
 
<b>3.2 Results and Discussion of the 3 hours gel:</b>
 
<b>3.2 Results and Discussion of the 3 hours gel:</b>
  
[[File:T--TU_Dresden--EMSA2_BBa_K3037005.png|200px|thumb|left]]
+
[[File:T--TU_Dresden--EMSA2_BBa_K3037005.png|center|400px|thumb|left|Figure 4: Electrophoretic Mobility Shift Assay (EMSA) after a three hour run of the dCas9 with different guideRNAs]]
  
This second gel was run more time in order to get rid of all the secondary structures of the RNA formed.
+
This second gel was run longer in order to remove all the secondary structures derived from residual RNA fragments.
  
From Lane 3 to 7, no difference in the mobility of <span style="font-style: italic;">Sry</span> gene can be seen when only guide RNA is added to the reaction mix.
+
From lane 3 to 7, no difference in the mobility of <i>sry</i> gene can be seen when only guideRNA is added to the reaction mix.
 
   
 
   
In Lane 8, 9 and 10 a mobility shift of the gene can be appreciated and in Lane 11, when only guide RNA was loaded there is no bands.
+
In lane 8, 9 and 10 a mobility shift of the gene can be observed and in lane 11, where only guideRNA was loaded no bands were obtained.
  
In Lane 12, dCas9 is in stacking part of gel, owing to higher molecular weight.   
+
In lane 12, dCas9 is in the stacking part of gel, corresponding to higher molecular weight.   
  
 +
<b>4. Conclusions:</b>
  
 +
- We have a functional dCas9 expressed, which is able to bind successfully to <span style="font-style: italic;">sry</span> gene with the help of specific guideRNAs.
  
 +
- dCas9 on its own is unable to bind to <span style="font-style: italic;">sry</span> gene, proving that for binding at least one appropriate guideRNA is required.
 +
 +
- GuideRNAs on their own are unable to cause a mobility shift of the <span style="font-style: italic;">sry</span> gene.
  
 +
==== 4) Measurement of fluorescence ====
  
 +
The protein functionality of eGFP in the fusion protein was analyzed in the protein purified using the MBP-tag. First of all, the excitation and emission spectrum were measured with Tecan Plate Reader (Bandwith 20 nm) (Figure 5). The excitation maxima was screened from 400 to 490, being the final excitation maxima 480 nm. The emission maxima was measured from 500 to 600 nm with a final result of 512 nm.
  
  
 +
[[File:T--TU_Dresden--Fluorescence_BBa_K3037005.png|center|400px|thumb|left|Figure 5: Fluorescense spectrum measurement. Excitation maxima 480 nm. Emission maxima 512 nm.]]
  
 +
== Sequence ==
  
 
+
NOTE: Please be aware, that by combining all the basic parts used for this composite part, the registry automatically inserted a RFC23 scar. However, the design and our cloning strategy is based on RFC25.  
 
+
 
+
 
+
 
+
<b>4. Conclusions:</b>
+
 
+
- We have a functional dCas9 expressed, which is able bind successfully to <span style="font-style: italic;">Sry</span> gene with the help of guide RNA.  
+
 
+
- dCas9 on its own is unable to bind to <span style="font-style: italic;">Sry</span> gene, suggesting that for binding guide RNA is required.
+
+
- Guide RNA on their own is unable to cause mobility shift of <span style="font-style: italic;">Sry</span> gene.
+
 
+
== Sequence ==
+
  
 
<partinfo>BBa_K3037005 SequenceAndFeatures</partinfo>
 
<partinfo>BBa_K3037005 SequenceAndFeatures</partinfo>
 
  
 
== References ==
 
== References ==
  
[1]  
+
[1] https://www.biotek.com/resources/technical-notes/excitation-and-emission-of-green-fluorescent-proteins/
  
 
[2] https://www.genscript.com/bacterial-soluble-protein-expression-MBP-tag.html
 
[2] https://www.genscript.com/bacterial-soluble-protein-expression-MBP-tag.html
  
 
[3] https://www.gelifesciences.com/en/us/shop/chromatography/resins/affinity-tagged-protein/prescission-protease-for-gst-tag-removal-p-00248
 
[3] https://www.gelifesciences.com/en/us/shop/chromatography/resins/affinity-tagged-protein/prescission-protease-for-gst-tag-removal-p-00248

Latest revision as of 02:09, 22 October 2019

MBP+eGFP+dCas9

MBP/eGFP/dCas9
Function Reporter
Use in Escherichia coli
RFC standard Freiburg RFC25 standard
Backbone pSB1C3
Experimental Backbone pOCC97
Submitted by Team: TU_Dresden 2019



Overview

This BioBrick was designed as a composite BioBrick by the team TU Dresden 2019. It is a fusion of dCas9 (BBa_K3037002) and eGFP (BBa_K3037006)(more information).

The dCas9 can bind to any sequence of DNA specified by its guideRNA. The eGFP (enhanced reporter protein) is used as reporter, resulting in fluorescence emission at 530 nm [1].

Additionally, the BioBrick is designed to have a N-terminal Maltose-binding-protein (MBP) fused to it (BBa_K3037001).This improves the solubility and expression and thus, the total cytoplasmic yield of the protein. The MBP can further be used to purify the fusion protein via amylose resin and afterwards, it can be cleaved off by digestion with a PreScission protease.

The design of the here presented BioBrick is based on BBa_K1994025. The original composite BioBrick consists of a transcriptional fusion of GFP and dCas9, both having their own promoter and RBS. A terminator separates both units. However, from our perspective having two transcriptional units as a composite part makes little sense to couple dCas9 activity with an easy readout - such as GFP. Therefore, our improvement was to fuse the dCas9 with eGFP to generate a translational fusion protein. Additionally, having the MBP fused on the N-terminus facilitates purification and easy cleaving off, as already explained before. We strongly believe that the combination of these improvements will be tremendously helpful for future iGEM teams working on dCas9 based projects. Down below, our characterization of the new improved composite part.

Characterization

Outline

We performed the following characterization experiments:

1) Expression using pOCC97 (BBa_K3037000) in E. coli pRARE T7 - Proof of the correct functioning of GFP

2) Construct purification and tag-removal - Proof of the correct functioning of MBP

3) Proof of DNA-binding ability of dCas9 via Electrophoretic Mobility Shift Assay (EMSA) - Proof of the correct functioning of dCas9

4) Measurement of fluorescence

Experiments in Detail

1) Expression using pOCC97 (BBa_K3037000) in E. coli pRARE T7 - Proof of the correct functioning of GFP

As a quick and easy proof of principle experiment, we used our over-expression plasmid pOCC97 ([https://parts.igem.org/Part:BBa_K3037000 BBa_K3037000) and introduced our construct (BBa_K3037005). After inducing expression in growing E.coli cells with IPTG, we took a sample, transferred it into an Eppendorf tupe and showed that these E.coli cells glow upon excitation with UV light (Figure 1). Thus, we concluded that our construct of MBP+eGFP+dCas9 was expressed successfully.

Figure 1: Expression of BBa_K3037005 in pOCC97

2) Construct purification and tag-removal - Proof of the correct functioning of MBP

The protein was purified via an amylose resin column with the a N-terminal-MBP-tag BBa_K3037001 (Figure 2).


Figure 2: Amilose resin purification using MBP-tag. The upper arrow shows the location in the gel of this BioBrick (BBa_K3037005). The lower ones show the MBP-tag after beeing cleaved off

The comparison of lane 4 and 5 illustrates nicely the performance of the MPP-tag with the amylose resin. Upon elution in lane 5 many truncated versions appear. This was expected since it often occurs when expressing large recombinant proteins. The high intensity of the bands shows that previously these proteins were bound to the resin as they were not in lane 4. After the digestion with 3C protease, a very strong signal appears at 42 kDa indicating that the preScission sites are intact and were recognized. The purification of the complete transcript from the cleaved off tag was achieved by cation exchange chromatography on a HiTrap SP column.

3) Prove of DNA-binding ability of dCas9 via EMSA - Proof of the correct functioning of dCas9

1. Materials:

  • 100 ng of PCR amplified sry gene
  • 200 ng of dCas9-GFP
  • 200 ng of guide RNA specifically targeting the amplified sry gene
  • 1 x Reaction buffer - 20 mM Hepes buffer (pH 7.2)
    • 100 mM NaCl
    • 5 mM MgCl2
    • 0.1 mM EDTA


Six different guide RNAs were designed for targeting different regions of sry gene. Using the online tool Benchling and Fasta sequence of sry gene (Table 1).

1: AACTAAACATAAGAAAGTGA

2: GAAAGCCACACACTCAAGAA

3: ACTGGACAACAGGTTGTACA

4: GTAGGACAATCGGGTAACAT

5: TTCGCTGCAGAGTACCGAAG

6: CCATGAACGCATTCATCGTG

Table 1: Overview of different guide RNAs with the context of the sequence and the PAM sequence

2. Methods:

1. We wanted to check if the overall efficiency of mobility shift increases when different combinations of guide RNAs are used.

2. Guide RNA, dCas9-GFP and sry gene were incubated in reaction buffer (respective amounts mentioned in the materials section) for 37 °C for 1 hour.

3. Post incubation, they were mixed with loading dye without SDS, 20 % glycerol in Orange G dye and loaded onto a 4-20 % gradient acrylamide- TBE precast gel. Two gels were run for 2 and 3 hours at 75 V in 1 x TBE buffer.

4. Gel was then stained using EtBr with 1:20000 dilution in 1x TBE for 10 minutes.


3.1 Results and Discussion of the 2 hours gel:

Figure 3: Electrophoretic Mobility Shift Assay (EMSA) after a two hours run using dCas9 with different guideRNAs.

Lane 1+2 - There is a clear sry band at 800 base pairs and when the sry gene is incubated only with dCas9 without guideRNA. Over all, no shift is observed.

Lane 3 - When guideRNA 1 was incubated with the dCas9 DNA reaction mix, we saw a shift in the mobility caused by the protein DNA interaction. The binding hinders the DNA mobility.

Lanes 5, 6, 7, 8 and 9 – Different combinations of guide RNAs were used. From lane 7 and 8 we see the highest mobility shift.

From the electromobility shift assay performed above, we conclude that our expressed dCas9-GFP protein is functional and is able to successfully bind to DNA with the help of appropriate guideRNAs.


3.2 Results and Discussion of the 3 hours gel:

Figure 4: Electrophoretic Mobility Shift Assay (EMSA) after a three hour run of the dCas9 with different guideRNAs

This second gel was run longer in order to remove all the secondary structures derived from residual RNA fragments.

From lane 3 to 7, no difference in the mobility of sry gene can be seen when only guideRNA is added to the reaction mix.

In lane 8, 9 and 10 a mobility shift of the gene can be observed and in lane 11, where only guideRNA was loaded no bands were obtained.

In lane 12, dCas9 is in the stacking part of gel, corresponding to higher molecular weight.

4. Conclusions:

- We have a functional dCas9 expressed, which is able to bind successfully to sry gene with the help of specific guideRNAs.

- dCas9 on its own is unable to bind to sry gene, proving that for binding at least one appropriate guideRNA is required.

- GuideRNAs on their own are unable to cause a mobility shift of the sry gene.

4) Measurement of fluorescence

The protein functionality of eGFP in the fusion protein was analyzed in the protein purified using the MBP-tag. First of all, the excitation and emission spectrum were measured with Tecan Plate Reader (Bandwith 20 nm) (Figure 5). The excitation maxima was screened from 400 to 490, being the final excitation maxima 480 nm. The emission maxima was measured from 500 to 600 nm with a final result of 512 nm.


Figure 5: Fluorescense spectrum measurement. Excitation maxima 480 nm. Emission maxima 512 nm.

Sequence

NOTE: Please be aware, that by combining all the basic parts used for this composite part, the registry automatically inserted a RFC23 scar. However, the design and our cloning strategy is based on RFC25.


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal NheI site found at 3061
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BglII site found at 381
    Illegal BamHI site found at 1930
    Illegal BamHI site found at 5340
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal BsaI site found at 79

References

[1] https://www.biotek.com/resources/technical-notes/excitation-and-emission-of-green-fluorescent-proteins/

[2] https://www.genscript.com/bacterial-soluble-protein-expression-MBP-tag.html

[3] https://www.gelifesciences.com/en/us/shop/chromatography/resins/affinity-tagged-protein/prescission-protease-for-gst-tag-removal-p-00248