Difference between revisions of "Part:BBa K2933004"

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===Usage and Biology===
 
===Usage and Biology===
AFM-1 is a type of subclass B metal beta-lactamases. The beta lactamases of the AFM family can hydrolyze almost all available beta lactam antibiotics (except aztreonam) clinically, including the broad-spectrum antibiotic carbapenems. Because of the extensive substrate profile of this enzyme, the clinical strains carrying it become a great threat to human life and health.
+
AFM-1 is a type of subclass B1 metallo-beta-lactamases. The beta lactamases of the AFM family can hydrolyze almost all available beta lactam antibiotics (except aztreonam) clinically, including the broad-spectrum antibiotic carbapenems. Because of the extensive substrate profile of this enzyme, the clinical strains carrying it become a great threat to human life and health.
  
 
===Molecular cloning===
 
===Molecular cloning===
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<p style="text-align: center;">
 
<p style="text-align: center;">
 
   [[File:T--TJUSLS China--AFM 1 gel jiaotu+fengtu.png]]<br>
 
   [[File:T--TJUSLS China--AFM 1 gel jiaotu+fengtu.png]]<br>
'''Figure 1.'''  (a) The result of gel filtration used the superdex75 column with the AKTA system, which shows that the target protein is monomeric. (b) The result of SDS-PAGE. And the target protein is about 28.2kD.<br>
+
'''Figure 4.'''  (a) The result of gel filtration used the superdex75 column with the AKTA system, which shows that the target protein is monomeric. (b) The result of SDS-PAGE. And the target protein is about 28.2kD.<br>
 
</p>
 
</p>
  
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<p style="text-align: center;">
 
<p style="text-align: center;">
 
     [[File:T--TJUSLS China--AFM-1 enzyme 1.png|300px]][[File:AFM hou.jpeg|300px]]<br>
 
     [[File:T--TJUSLS China--AFM-1 enzyme 1.png|300px]][[File:AFM hou.jpeg|300px]]<br>
'''Figure 2.'''  The concentration of CDC-1 was fixed at 10.5 μM and the enzyme concentration was changed within a certain range, and the fluorescence value was measured with a function of reaction time. Left: First, we selected three gradient concentrations (with large intervals) for pre-experiment, and determined the gradient range of the formal experiment through the experimental results. Right: The appropriate enzyme concentration was selected for determination of the gradient, and the reaction curve of gradual rise was obtained.<br>
+
'''Figure 5.'''  The concentration of CDC-1 was fixed at 10.5 μM and the enzyme concentration was changed within a certain range, and the fluorescence value was measured with a function of reaction time. Left: First, we selected three gradient concentrations (with large intervals) for pre-experiment, and determined the gradient range of the formal experiment through the experimental results. Right: The appropriate enzyme concentration was selected for determination of the gradient, and the reaction curve of gradual rise was obtained.<br>
 
</p>
 
</p>
 
<p style="text-align: center;">
 
<p style="text-align: center;">
 
     [[File:T--TJUSLS China--AFM-1 EC80.png|300px]]<br>
 
     [[File:T--TJUSLS China--AFM-1 EC80.png|300px]]<br>
'''Figure 3.'''  We took the emission fluorescence at 27.2nm as the maximum emission fluorescence, and took the logarithm value of different AFM-1 enzyme concentrations to make the relationship curve between protein concentration and fluorescence emission rate. When the emittance of the system was 80%, the protein concentration was 0.9421nM.<br>
+
'''Figure 6.'''  We took the emission fluorescence at 27.2nm as the maximum emission fluorescence, and took the logarithm value of different AFM-1 enzyme concentrations to make the relationship curve between protein concentration and fluorescence emission rate. When the emittance of the system was 80%, the protein concentration was 0.9421nM.<br>
 
</p>
 
</p>
  
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<p style="text-align: center;">
 
<p style="text-align: center;">
 
     [[File:T--TJUSLS China--AFM 1 buffer.png|600px]]<br>
 
     [[File:T--TJUSLS China--AFM 1 buffer.png|600px]]<br>
'''Figure 4.'''  Effect of different buffer condition on enzyme activity.<br>
+
'''Figure 7.'''  Effect of different buffer condition on enzyme activity.<br>
 
</p>
 
</p>
 
According to the experimental results, we chose NaCl concentration of 300mM, ZnCl concentration of 110 micron and pH of 8.5. The effect of DMSO on protein activity can be excluded in the range of 2-10%. (6% in the system)<br>
 
According to the experimental results, we chose NaCl concentration of 300mM, ZnCl concentration of 110 micron and pH of 8.5. The effect of DMSO on protein activity can be excluded in the range of 2-10%. (6% in the system)<br>
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<p style="text-align: center;">
 
<p style="text-align: center;">
 
     [[File:T--TJUSLS China--AFM 1 M.png|300px]]<br>
 
     [[File:T--TJUSLS China--AFM 1 M.png|300px]]<br>
'''Figure 5.'''  The relationship between the substrate concentration and the maximum initial rate was obtained by using the Michaelis-Menten plot.<br>
+
'''Figure 8.'''  The relationship between the substrate concentration and the maximum initial rate was obtained by using the Michaelis-Menten plot.<br>
 
</p>
 
</p>
 
<p style="text-align: center;">
 
<p style="text-align: center;">
 
     [[File:T--TJUSLS China--AFM-1 Kcat1.png|400px]]<br>
 
     [[File:T--TJUSLS China--AFM-1 Kcat1.png|400px]]<br>
'''Figure 6.'''  The relationship between the maximum fluorescence value and substrate concentration.
+
'''Figure 9.'''  The relationship between the maximum fluorescence value and substrate concentration.
 
</p>
 
</p>
  
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<p style="text-align: center;">
 
<p style="text-align: center;">
 
     [[File:T--TJUSLS China--AFM-1 screen system.png|300px]]<br>
 
     [[File:T--TJUSLS China--AFM-1 screen system.png|300px]]<br>
'''Figure12.'''  Protein concentration and optimal buffer components of AFM-1.
+
'''Figure10.'''  Protein concentration and optimal buffer components of AFM-1.
 
</p>
 
</p>
  
 
<p style="text-align: center;">     
 
<p style="text-align: center;">     
 
     [[File:T--TJUSLS China--AFM-1 screen system1u.png|400px]]<br>
 
     [[File:T--TJUSLS China--AFM-1 screen system1u.png|400px]]<br>
'''Figure13.'''  The inhibitor screening system of AFM-1.
+
'''Figure11.'''  The inhibitor screening system of AFM-1.
  
 
===Effective inhibitors in vitro we founded===
 
===Effective inhibitors in vitro we founded===
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[[File:Cloxacillin.png|600px|]]
 
[[File:Cloxacillin.png|600px|]]
  
===extracorporeal IC50 and inhibitory mechanism of inhibitors===
+
===extracorporeal IC<sub>50</sub> and inhibitory mechanism of inhibitors===
We tested the IC50 of two inhibitors and the inhibitory mechanism of Adapalene.<br>
+
We tested the IC<sub>50</sub> of two inhibitors and the inhibitory mechanism of Adapalene.<br>
 
</p>
 
</p>
 
<p style="text-align: center;">
 
<p style="text-align: center;">
 
[[File:Adapalene AFM IC50.jpeg|300px]][[File:Bukeni adapalin.jpeg|300px|]]<br>
 
[[File:Adapalene AFM IC50.jpeg|300px]][[File:Bukeni adapalin.jpeg|300px|]]<br>
'''Figure 14.'''  IC50 and inhibitory mechanism of Adapalene for AFM-1. Its inhibition type is irreversible inhibition.<br>
+
'''Figure 12.'''  IC<sub>50</sub> and inhibitory mechanism of Adapalene for AFM-1. Its inhibition type is irreversible inhibition.<br>
 
</p>
 
</p>
 
<p style="text-align: center;">
 
<p style="text-align: center;">
 
   [[File:TA AFM IC50.jpg|300px]]<br>
 
   [[File:TA AFM IC50.jpg|300px]]<br>
'''Figure 15.'''  IC50 of Tannic acid for AFM-1.<br>
+
'''Figure 13.'''  IC<sub>50</sub> of Tannic acid for AFM-1.<br>
 
</p>
 
</p>
  
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<p style="text-align: center;">
 
<p style="text-align: center;">
 
   [[File:AFM TANNIC.jpeg|300px|]]<br>
 
   [[File:AFM TANNIC.jpeg|300px|]]<br>
'''Figure 16.'''  Monitoring in living bacterial cells with antibiotics and Tannic acid.<br>
+
'''Figure 14.'''  Monitoring in living bacterial cells with antibiotics and Tannic acid.<br>
 
</p>
 
</p>
  
 
===Conclusion===
 
===Conclusion===
In conclusion, AFM-1 protein was successfully expressed in this part. We measured enzyme activity, established the high-throughput screening system, successfully screened some effective inhibitors with CDC-1 probes and then verified one of them with live bacteria to determine the IC50 of the inhibitors in vivo. We found that the inhibitors can effectively inhibit the activity of the enzyme in vivo and prevent the hydrolysis of cefazolin by the enzyme. We are proud that our results have laid the foundation for further research.
+
In conclusion, AFM-1 protein was successfully expressed in this part. We measured enzyme activity, established the high-throughput screening system, successfully screened some effective inhibitors with CDC-1 probes and then verified one of them with live bacteria to determine the IC<sub>50</sub> of the inhibitors in vivo. We found that the inhibitors can effectively inhibit the activity of the enzyme in vivo and prevent the hydrolysis of cefazolin by the enzyme. We are proud that our results have laid the foundation for further research.

Latest revision as of 13:16, 21 October 2019


subclass B1 metallo-beta-lactamase AFM-1, codon optimized in E. coli

This part encodes a protein called AFM-1, which is a metallo-beta-lactamase of subclass B1.

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


Usage and Biology

AFM-1 is a type of subclass B1 metallo-beta-lactamases. The beta lactamases of the AFM family can hydrolyze almost all available beta lactam antibiotics (except aztreonam) clinically, including the broad-spectrum antibiotic carbapenems. Because of the extensive substrate profile of this enzyme, the clinical strains carrying it become a great threat to human life and health.

Molecular cloning

First, we used the vector pGEX-6p-1 to construct our expression plasmid. And then we converted the plasmid constructed to E. coli DH5α to expand the plasmid largely.

AFM-1-PCR.png
Figure 1. Left: The PCR result of AFM-1. Right: The verification results by enzyme digestion.

After verification, it was determined that the construction is successful. We converted the plasmid to E. coli BL21(DE3) for expression and purification.

Expression and purification

Pre-expression:
The bacteria were cultured in 5mL LB liquid medium with ampicillin(100 μg/mL final concentration) in 37℃ overnight.

Massive expressing:
After taking samples, we transfered them into 1L LB medium and add antibiotic to 100 μg/mL final concentration. Grow them up in 37°C shaking incubator. Grow until an OD 600 nm of 0.8 to 1.2 (roughly 3-4 hours). Induce the culture to express protein by adding 1 mM IPTG (isopropylthiogalactoside, MW 238 g/mol). Put the liter flasks in 16°C shaking incubator for 16h.

Affinity Chromatography:
We used the GST Agarose to purify the target protein. The GST Agarose can combine specifically with the GST tag fused with target protein.

  • First, wash the column with GST-binding buffer for 10 minutes to balance the GST column.
  • Second, add the protein solution to the column, let it flow naturally and bind to the column.
  • Third, add GST-Washing buffer several times and let it flow. Take 10μl of wash solution and test with Coomassie Brilliant Blue. Stop washing when it doesn’t turn blue.
  • Forth, add 400μL Prescission Protease (1mg/mL) to the agarose. Digest for 16 hours in 4℃.
  • Fifth, add GST-Elution buffer several times. Check as above. Collect the eluted proteins for further operation.

T--TJUSLS China--AFM 1 GST.jpg
Figure 2. The result of SDS-page.

Anion exchange column:
According to the predicted pI of the protein and the pH of the ion-exchange column buffer, firstly select the appropriate ion exchange column (anion exchange column or cation exchange column). The pH of buffer should deviate from the isoelectric point of the protein. Since the isoelectric point of our protein is 6.04 in theory, we choose buffer pH of 7.4 and use anion exchange column for purification. The protein is concentrated with a 10KD concentration tube, and then the exchange buffer is used to exchange the protein to the ion-exchange liquid A. Finally, it is concentrated to less than 5ml by centrifuging at 4℃ and 3400rpm for 10 minutes in a high-speed centrifuge to remove insoluble substances and bubbles. Balance the selected column with liquid A. Through the AKTApure protein purification system, the samples are loaded to the column at a flow rate of 0.5ml/min, and continue washing for 5min. Gradually increase the content of liquid B in the column, change the salt concentration and then change the interaction between the sample and the column, and collect the corresponding eluent according to the position of the peak. Use SDS-PAGE to check the result.

T--TJUSLS China--AFM 1 Q.jpg
Figure 3. The result of SDS-page of superdex75 Q column.

Gel filtration chromatography:
The collected protein samples are concentrated in a 10 KD concentrating tube at a speed of 3400 rpm and concentrated for a certain time until the sample volume is 500 μl. At the same time, the superdex 200 column is equilibrated with a buffer to balance 1.2 column volumes. The sample is then loaded and 1.5 cylinders are eluted isocratically with buffer. Determine the state of protein aggregation based on the peak position and collect protein samples based on the results of running the gel.

T--TJUSLS China--AFM 1 gel jiaotu+fengtu.png
Figure 4. (a) The result of gel filtration used the superdex75 column with the AKTA system, which shows that the target protein is monomeric. (b) The result of SDS-PAGE. And the target protein is about 28.2kD.

Enzyme activity determination

We used CDC-1, a probe with a similar structure from the beta lactam ring and a luminescent group for enzyme activity measurements. For more information on the substrate CDC-1, please see our project introduction.

Materials:
General 96-well plates (Black)
Infinite M1000 Pro Automatic Microplate Reader
Multi-channel adjustable pipette
Ultrasonic Cleaner

Buffer:
100% DMSO
Fluorescent Probe(CDC-1)
Target Enzyme(beta-lactamase)

Determination of enzyme concentration

T--TJUSLS China--AFM-1 enzyme 1.pngAFM hou.jpeg
Figure 5. The concentration of CDC-1 was fixed at 10.5 μM and the enzyme concentration was changed within a certain range, and the fluorescence value was measured with a function of reaction time. Left: First, we selected three gradient concentrations (with large intervals) for pre-experiment, and determined the gradient range of the formal experiment through the experimental results. Right: The appropriate enzyme concentration was selected for determination of the gradient, and the reaction curve of gradual rise was obtained.

T--TJUSLS China--AFM-1 EC80.png
Figure 6. We took the emission fluorescence at 27.2nm as the maximum emission fluorescence, and took the logarithm value of different AFM-1 enzyme concentrations to make the relationship curve between protein concentration and fluorescence emission rate. When the emittance of the system was 80%, the protein concentration was 0.9421nM.

Determination of the buffer condition

T--TJUSLS China--AFM 1 buffer.png
Figure 7. Effect of different buffer condition on enzyme activity.

According to the experimental results, we chose NaCl concentration of 300mM, ZnCl concentration of 110 micron and pH of 8.5. The effect of DMSO on protein activity can be excluded in the range of 2-10%. (6% in the system)

Michaelis-Menten plot

T--TJUSLS China--AFM 1 M.png
Figure 8. The relationship between the substrate concentration and the maximum initial rate was obtained by using the Michaelis-Menten plot.

T--TJUSLS China--AFM-1 Kcat1.png
Figure 9. The relationship between the maximum fluorescence value and substrate concentration.

Establishment of AFM-1 inhibitor screening system

After the above determination of enzyme activity and the trial of concentration and buffer components, we determined the optimal conditions of AFM-1 enzyme activity and then established the screening system.

T--TJUSLS China--AFM-1 screen system.png
Figure10. Protein concentration and optimal buffer components of AFM-1.

T--TJUSLS China--AFM-1 screen system1u.png
Figure11. The inhibitor screening system of AFM-1.

Effective inhibitors in vitro we founded

Above, we have established the AFM-1 high-throughput screening system, and then we used the microplate reader to conduct high-throughput screening to screen out nearly 8 inhibitors with significant inhibitory effect on AFM-1 from the drug library containing over 4000 small molecules.

TJUSLS China--AFM-1 inhibitor.png AFM2.png AFM7.png AFM3.png AFM4.png AFM5.png AFM6.png Cloxacillin.png

extracorporeal IC50 and inhibitory mechanism of inhibitors

We tested the IC50 of two inhibitors and the inhibitory mechanism of Adapalene.

Adapalene AFM IC50.jpegBukeni adapalin.jpeg
Figure 12. IC50 and inhibitory mechanism of Adapalene for AFM-1. Its inhibition type is irreversible inhibition.

TA AFM IC50.jpg
Figure 13. IC50 of Tannic acid for AFM-1.

Monitoring in living bacterial cells with antibiotics

After high-throughput screening, tannic acid was screened as the inhibitor of AFM-1. We have used the UV visible method to assess the effectiveness of the treatment. The results are as follows:

AFM TANNIC.jpeg
Figure 14. Monitoring in living bacterial cells with antibiotics and Tannic acid.

Conclusion

In conclusion, AFM-1 protein was successfully expressed in this part. We measured enzyme activity, established the high-throughput screening system, successfully screened some effective inhibitors with CDC-1 probes and then verified one of them with live bacteria to determine the IC50 of the inhibitors in vivo. We found that the inhibitors can effectively inhibit the activity of the enzyme in vivo and prevent the hydrolysis of cefazolin by the enzyme. We are proud that our results have laid the foundation for further research.