Difference between revisions of "Part:BBa K4468011"

 
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<partinfo>BBa_K4468011 short</partinfo>
 
<partinfo>BBa_K4468011 short</partinfo>
 
Description
 
This is a composite component for the absorption and recovery of rare earth elements, especially for lanthanides. It consists of T7-PmrA- T7-PmrB(FP)-T7 Terminator-PmrC-oprf-Sitag-FP- T7 Terminator. It can express PmrA and PmrB protein without any induction. Besides, lanthanide ions in the external solution can initiate the expression of oprf-Sitag-LanM protein that can achieve a large amount of lanthanide adsorption and attachment on the surface of silica column. FP protein fuses dLBT and LanM proteins together. Its adsorption efficiency and amount of lanthanides are both improved compared with ordinary LanM protein.
 
  
  
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<partinfo>BBa_K4468011 parameters</partinfo>
 
<partinfo>BBa_K4468011 parameters</partinfo>
 
<!-- -->
 
<!-- -->
 +
 +
<h1>'''Description'''</h1>
 +
This is a composite component for the absorption and recovery of rare earth elements, especially for lanthanides. It consists of T7-PmrA- T7-PmrB(FP)-T7 Terminator-PmrC-oprf-Sitag-FP- T7 Terminator. It can express PmrA and PmrB protein without any induction. Besides, lanthanide ions in the external solution can initiate the expression of oprf-Sitag-LanM protein that can achieve a large amount of lanthanide adsorption and attachment on the surface of silica column. FP protein fuses dLBT and LanM proteins together. Its adsorption efficiency and amount of lanthanides are both improved compared with ordinary LanM protein.
 +
 +
<h1>'''Usage and Biology'''</h1>
 +
<h2>'''PmrA'''</h2>
 +
The PmrCAB of Salmonella is a system that can be stimulated and induced by exogenous metal ions. The main functions are executed by three parts, the transmembrane protein PmrB, the intracellular protein PmrA, and the promoter PmrC. In wild-type Salmonella, it can adsorbs extracellular Fe<sup>3+</sup>, and phosphorylates protein PmrA. Then the phosphorylated PmrA will bind on the promoter PmrC to initiate expression.<br>
 +
The expression product of PmrA is an intracellular protein which can be actived during phosphorylation by protein kinase at the C-terminus of PmrB. Phosphorylated PmrA is able to bind on the promoter PmrC and initiate its downstream genes’ expression.
 +
<h2>'''PmrB(FP)'''</h2>
 +
The PmrCAB of Salmonella is a system that can be stimulated and induced by exogenous metal ions. The main functions are executed by three parts, the transmembrane protein PmrB, the intracellular protein PmrA, and the promoter PmrC. In wild-type Salmonella, it can adsorbs extracellular Fe<sup>3+</sup>, and phosphorylates protein PmrA. Then the phosphorylated PmrA will bind on the promoter PmrC to initiate expression.<br>
 +
The expression product of PmrB is a single pass transmembrane protein whose 34to 64 amino acids are located outside the membrane to adsorb Fe<sup>3+</sup>. Near the C-terminus is a protein kinase that can phosphorylate PmrA. On the basis of protein PmrB(LanM), we further reformed its protein sequence of the extracellular domain. Thanks to HUST China 2017, we already knew that the peptide dLBT also has similar function, except that dLBT is worse than LanM and only Tb<sup>3+</sup> could be adsorbed. So we added a linker between LanM and dLBT in order to join the bipartite sequences together and reintegrated at the adsorption domain of PmrB. We believed that the new fusion protein will highly improve the absorption ability of lanthanides. We named this protein PmrB(FP).
 +
<h2>'''PmrC'''</h2>
 +
The PmrCAB of Salmonella is a system that can be stimulated and induced by exogenous metal ions. The main functions are executed by three parts, the transmembrane protein PmrB, the intracellular protein PmrA, and the promoter PmrC. In wild-type Salmonella, it can adsorbs extracellular Fe<sup>3+</sup>, and phosphorylates protein PmrA. Then the phosphorylated PmrA will bind on the promoter PmrC to initiate expression.<br>
 +
PmrC is a promoter that can bind to phosphorylated PmrA and initiate expression.
 +
<h2>'''Oprf-Sitag-FP'''</h2>
 +
Oprf-Sitag-FP is a protein composed of oprf, Sitag, dLBT and LanM peptides. It is the main element for adsorption and recovery of lanthanides. Oprf has a membrane-binding domain, which helps the protein binding on the cell membrane of our engineered bacteria. Sitag is a tag that can connect with silicon element. It allows us to easily fix our protein just using a silica column. dLBT can highly absorb Tb<sup>3+</sup>, the most representative element of lanthanides. Thanks to HUST-China 2017, we successfully obtained the dLBT with the best adsorption effect from 12 different LBT domains. LanM has great characteristics of efficient and specific absorbing lanthanides which can effectively absorb the free lanthanides in the environment. Through GS linker to combine the first three peptides and rigid linker to combine dLBT and LanM, we have connected them as a whole and created a new protein that can stick on our E. coli membrane and fix to silica column with its engineered bacteria together. When the mining wastewater flows through the column, the lanthanides can be effectively adsorbed, so as to achieve the purpose of rare earth element recovery.
 +
 +
<h1>'''Molecular cloning'''</h1>
 +
First of all, we need to amplificated all the commercially synthesized plasmid to acquire enough amount for further study. After transformation, colony PCR is applied for confirmation. Then we go for plasmid extraction.<br>
 +
Using E. coli to extraction. Through designed primers, we have obtained different high copies linearized fragments from our plasmids by PCR. These fragments are then connected together by homologous recombination to form a complete plasmid. After transformed into E. coli, colony PCR was applied for confirmation. Then we go for extracting plasmids again.<br>
 +
Finally we transformed our recombinant plasmids into E. coli BL21(DE3) competent cells. Correct as checked by colony PCR.
 +
[[File:HUST-China-11-1.png|400px|thumb|center|Fig.1  Colony PCR result of Oprf-Sitag-FP and PmrB(FP)-PmrC transformed E.coli<br><br>The band of Oprf-Sitag-FP from colony PCR is about 2000bp, identical to the theoretical length of 1944bp estimated by the designed primer location and The band of PmrB(FP)-PmrC  from colony PCR is about 1800bp, identical to the theoretical length of 1801bp estimated by the designed primer location, which could demonstrate that this target plasmid had successfully transformed into E.coli]]
 +
 +
<h1>'''SDS-PAGE'''</h1>
 +
After confirming through colony PCR and sequencing, we used the successfully transformed E. coli BL21 (DE3) for expression. We induced with IPTG and Tb<sup>3+</sup> or IPTG and Cu<sup>2+</sup> then followed by cell disruption to detect membrane proteins, as our fusion proteins would be expressed on the cell membrane.
 +
[[File:HUST-China-11-2.png|400px|thumb|center|Fig.2  SDS-PAGE result of PmrA from composite component BBa_K4468010 and BBa_K4468010 after purification of total protein extraction product through Nickel-affinity chromatography column<br><br>The target protein located around 26-30kDa, similar the theoretical 26.87kDa. PmrA could be confirmed as successfully expressed. The concentration of E. coli total protein is so high that huge amount of impure protein is included during elution. But due to difference from impure or permeate bands, its consistency among several times of elution, this band could be verified as our target FMO.]]
 +
[[File:HUST-China-11-4.png|400px|thumb|center|Fig.4  SDS-PAGE result of membrane protein oprf-Sitag-FP(PmrCAB) induced by different lanthanides.<br><br>After induction using different lanthanide ions, we obtained several strains that successfully expressed the oprf-Sitag-FP(PmrCAB). All their membrane proteins were detected by SDS-PAGE. The band of oprf-Sitag-FP(PmrCAB) is about 70kDa, identical to the theoretical length of 68.03kDa and still within explainable and acceptable range of glycosylation or phosphorylation modification. Oprf-Sitag-FP(PmrCAB) could be confirmed as successfully expressed. Besides, following elution result also could verify it.]]
 +
 +
<h1>'''Immunofluorescence labeling'''</h1>
 +
[[File:HUST-China-11-5.png|400px|thumb|center|Fig.5  Image of immunofluorescence labeling of the fusion protein from E. coli.<br><br>It is obvious to see that our target proteins are successfully expressed and immobilized on the cell membrane through the fluorescence on the bacteria cell.]]

Revision as of 11:25, 30 September 2022


T7-PmrA- T7-PmrB(FP)-T7 Terminator-PmrC-Oprf-Sitag-FP- T7 Terminator


Sequence and Features


Assembly Compatibility:
  • 10
    INCOMPATIBLE WITH RFC[10]
    Illegal PstI site found at 1619
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal NheI site found at 2858
    Illegal PstI site found at 1619
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal XhoI site found at 1138
  • 23
    INCOMPATIBLE WITH RFC[23]
    Illegal PstI site found at 1619
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal PstI site found at 1619
    Illegal NgoMIV site found at 3293
    Illegal NgoMIV site found at 4127
    Illegal AgeI site found at 1813
    Illegal AgeI site found at 2642
  • 1000
    COMPATIBLE WITH RFC[1000]


Description

This is a composite component for the absorption and recovery of rare earth elements, especially for lanthanides. It consists of T7-PmrA- T7-PmrB(FP)-T7 Terminator-PmrC-oprf-Sitag-FP- T7 Terminator. It can express PmrA and PmrB protein without any induction. Besides, lanthanide ions in the external solution can initiate the expression of oprf-Sitag-LanM protein that can achieve a large amount of lanthanide adsorption and attachment on the surface of silica column. FP protein fuses dLBT and LanM proteins together. Its adsorption efficiency and amount of lanthanides are both improved compared with ordinary LanM protein.

Usage and Biology

PmrA

The PmrCAB of Salmonella is a system that can be stimulated and induced by exogenous metal ions. The main functions are executed by three parts, the transmembrane protein PmrB, the intracellular protein PmrA, and the promoter PmrC. In wild-type Salmonella, it can adsorbs extracellular Fe3+, and phosphorylates protein PmrA. Then the phosphorylated PmrA will bind on the promoter PmrC to initiate expression.
The expression product of PmrA is an intracellular protein which can be actived during phosphorylation by protein kinase at the C-terminus of PmrB. Phosphorylated PmrA is able to bind on the promoter PmrC and initiate its downstream genes’ expression.

PmrB(FP)

The PmrCAB of Salmonella is a system that can be stimulated and induced by exogenous metal ions. The main functions are executed by three parts, the transmembrane protein PmrB, the intracellular protein PmrA, and the promoter PmrC. In wild-type Salmonella, it can adsorbs extracellular Fe3+, and phosphorylates protein PmrA. Then the phosphorylated PmrA will bind on the promoter PmrC to initiate expression.
The expression product of PmrB is a single pass transmembrane protein whose 34to 64 amino acids are located outside the membrane to adsorb Fe3+. Near the C-terminus is a protein kinase that can phosphorylate PmrA. On the basis of protein PmrB(LanM), we further reformed its protein sequence of the extracellular domain. Thanks to HUST China 2017, we already knew that the peptide dLBT also has similar function, except that dLBT is worse than LanM and only Tb3+ could be adsorbed. So we added a linker between LanM and dLBT in order to join the bipartite sequences together and reintegrated at the adsorption domain of PmrB. We believed that the new fusion protein will highly improve the absorption ability of lanthanides. We named this protein PmrB(FP).

PmrC

The PmrCAB of Salmonella is a system that can be stimulated and induced by exogenous metal ions. The main functions are executed by three parts, the transmembrane protein PmrB, the intracellular protein PmrA, and the promoter PmrC. In wild-type Salmonella, it can adsorbs extracellular Fe3+, and phosphorylates protein PmrA. Then the phosphorylated PmrA will bind on the promoter PmrC to initiate expression.
PmrC is a promoter that can bind to phosphorylated PmrA and initiate expression.

Oprf-Sitag-FP

Oprf-Sitag-FP is a protein composed of oprf, Sitag, dLBT and LanM peptides. It is the main element for adsorption and recovery of lanthanides. Oprf has a membrane-binding domain, which helps the protein binding on the cell membrane of our engineered bacteria. Sitag is a tag that can connect with silicon element. It allows us to easily fix our protein just using a silica column. dLBT can highly absorb Tb3+, the most representative element of lanthanides. Thanks to HUST-China 2017, we successfully obtained the dLBT with the best adsorption effect from 12 different LBT domains. LanM has great characteristics of efficient and specific absorbing lanthanides which can effectively absorb the free lanthanides in the environment. Through GS linker to combine the first three peptides and rigid linker to combine dLBT and LanM, we have connected them as a whole and created a new protein that can stick on our E. coli membrane and fix to silica column with its engineered bacteria together. When the mining wastewater flows through the column, the lanthanides can be effectively adsorbed, so as to achieve the purpose of rare earth element recovery.

Molecular cloning

First of all, we need to amplificated all the commercially synthesized plasmid to acquire enough amount for further study. After transformation, colony PCR is applied for confirmation. Then we go for plasmid extraction.
Using E. coli to extraction. Through designed primers, we have obtained different high copies linearized fragments from our plasmids by PCR. These fragments are then connected together by homologous recombination to form a complete plasmid. After transformed into E. coli, colony PCR was applied for confirmation. Then we go for extracting plasmids again.
Finally we transformed our recombinant plasmids into E. coli BL21(DE3) competent cells. Correct as checked by colony PCR.

Fig.1 Colony PCR result of Oprf-Sitag-FP and PmrB(FP)-PmrC transformed E.coli

The band of Oprf-Sitag-FP from colony PCR is about 2000bp, identical to the theoretical length of 1944bp estimated by the designed primer location and The band of PmrB(FP)-PmrC from colony PCR is about 1800bp, identical to the theoretical length of 1801bp estimated by the designed primer location, which could demonstrate that this target plasmid had successfully transformed into E.coli

SDS-PAGE

After confirming through colony PCR and sequencing, we used the successfully transformed E. coli BL21 (DE3) for expression. We induced with IPTG and Tb3+ or IPTG and Cu2+ then followed by cell disruption to detect membrane proteins, as our fusion proteins would be expressed on the cell membrane.

Fig.2 SDS-PAGE result of PmrA from composite component BBa_K4468010 and BBa_K4468010 after purification of total protein extraction product through Nickel-affinity chromatography column

The target protein located around 26-30kDa, similar the theoretical 26.87kDa. PmrA could be confirmed as successfully expressed. The concentration of E. coli total protein is so high that huge amount of impure protein is included during elution. But due to difference from impure or permeate bands, its consistency among several times of elution, this band could be verified as our target FMO.
Fig.4 SDS-PAGE result of membrane protein oprf-Sitag-FP(PmrCAB) induced by different lanthanides.

After induction using different lanthanide ions, we obtained several strains that successfully expressed the oprf-Sitag-FP(PmrCAB). All their membrane proteins were detected by SDS-PAGE. The band of oprf-Sitag-FP(PmrCAB) is about 70kDa, identical to the theoretical length of 68.03kDa and still within explainable and acceptable range of glycosylation or phosphorylation modification. Oprf-Sitag-FP(PmrCAB) could be confirmed as successfully expressed. Besides, following elution result also could verify it.

Immunofluorescence labeling

Fig.5 Image of immunofluorescence labeling of the fusion protein from E. coli.

It is obvious to see that our target proteins are successfully expressed and immobilized on the cell membrane through the fluorescence on the bacteria cell.