Difference between revisions of "Part:BBa K4083004"

(Part functionality)
 
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__NOTOC__
 
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<partinfo>BBa_K4083004 short</partinfo>
 
<partinfo>BBa_K4083004 short</partinfo>
  
nadE from Pseudomonas aeruginosa is coding for NAD synthetase which synthesizes NAD+
+
<em>nadE</em> from <em>Pseudomonas aeruginosa</em> is coding for NAD synthetase which synthesizes NAD+
  
 
===Usage and Biology===
 
===Usage and Biology===
  
Our team extracted nadE gene from P. aeruginosa to add it into novel plasmid called pRGPDuo2 for P. putida. Apart from nadE gene, planned to add rhlA and rhlB genes that are responsible for rhamnolipid synthesis. Thus, we predicted that dual expression of NAD synthetase and Rhamnosyltrnasferse can allow P. putida to express rhamnolipids in higher rates.   
+
Our team extracted <em>nadE</em> gene from <em>P. aeruginosa</em> to add it into novel plasmid called pRGPDuo2 for <em>P. putida</em>. Apart from <em>nadE</em> gene, planned to add <em>rhlA</em> and <em>rhlB</em> genes that are responsible for rhamnolipid synthesis. Thus, we predicted that dual expression of NAD synthetase and Rhamnosyltrnasferse can allow <em>P. putida</em> to express rhamnolipids in higher rates.   
  
Pseudaminas aeuriginosa - is gram negative bacilus and opportunistic pathogen.
+
<em>Pseudaminas aeuriginosa</em> - is gram negative bacilus and opportunistic pathogen.
NH(3) dependent NAD-synthetase converts deamido-NAD+ to NAD+ by ATP-dependent amidation [1].
+
NH<sub>3</sub> dependent NAD-synthetase converts deamido-NAD<sup>+</sup> to NAD<sup>+</sup> by ATP-dependent amidation [1].
ATP + deamido-NAD+ + NH4+ -> AMP + diphosphate + H+ + NAD+
+
ATP + deamido-NAD<sup>+</sup> + NH<sub>4</sub><sup>+</sup> -> AMP + diphosphate + H<sup>+</sup> + NAD<sup>+</sup>
  
 
https://static.igem.org/mediawiki/parts/thumb/4/45/BBa_K4083004-NADS_reaction.png/799px-BBa_K4083004-NADS_reaction.png
 
https://static.igem.org/mediawiki/parts/thumb/4/45/BBa_K4083004-NADS_reaction.png/799px-BBa_K4083004-NADS_reaction.png
The NAD+ is important for metabolism in organisms. NAD+ can reduce into NADH during cell digestion like glucolysis or Krebs cycle. Thus, more available NAD+ can lead to faster substrate catabolism.
 
Moreover, NADH interacts with the electron transport chain where it releases one electron and one proton. As an electron moves, more protons exit the bacterial membrane which increases the proton gradient. Finally, to reach equilibrium, protons enter the cell by ATP synthase, and one proton can generate up to 3 ATP molecules this way. Thus, one NADH that releases one proton can generate 3 ATP molecules. Finally, NAD+ can interact with NAD kinase to convert into NADP+ which plays a direct role in biosynthesis of rhamnolipids. [2]
 
  
https://static.igem.org/mediawiki/parts/thumb/3/3d/BBa_K4083004-NAD_synthetase_P.aeruginosa.jpg/800px-BBa_K4083004-NAD_synthetase_P.aeruginosa.jpg
+
<em><strong>Figure 1.</strong> NADS function</em>
  
3D model from PDB of NH(3)-dependent NAD(+) synthetase from Pseudomonas aeruginosa [3]. The picture was made in Jmol 14.31.57.
+
 
 +
The NAD+ is important for metabolism in organisms. NAD<sup>+</sup> can reduce into NADH during cell digestion like glycolysis or the Krebs cycle. Thus, more available NAD+ can lead to faster substrate catabolism.  
 +
Moreover, NADH interacts with the electron transport chain where it releases one electron and one proton. As an electron moves, more protons exit the bacterial membrane which increases the proton gradient. Finally, to reach equilibrium, protons enter the cell by ATP synthase, and one proton can generate up to 3 ATP molecules this way. Thus, one NADH that releases one proton can generate 3 ATP molecules. Finally, NAD<sup>+</sup> can interact with NAD kinase to convert into NADP<sup>+</sup> which plays a direct role in the biosynthesis of rhamnolipids. [2]
  
 
===Part functionality===
 
===Part functionality===
We used our assembled nadE primers to extract the nadE gene. (https://parts.igem.org/Part:BBa_K4083019, https://parts.igem.org/Part:BBa_K4083020). Obtained genes were amplified in a PCR machine. Then, these PCR products were analyzed in gel electrophoresis:
 
  
https://static.igem.org/mediawiki/parts/f/f6/NadE.jpg
+
<strong>Visualisation</strong>
  
We additionally conducted another gel electrophoresis:
+
We used our assembled <em>nadE</em> primers to extract the <em>nadE</em> gene. (https://parts.igem.org/Part:BBa_K4083019, https://parts.igem.org/Part:BBa_K4083020). Obtained genes were amplified in a PCR machine. Then, these PCR products were analyzed in 2 gel electrophoresis experiments:
  
https://static.igem.org/mediawiki/parts/c/c8/T--NU_Kazakhstan--figure-1.1.jpg
+
https://static.igem.org/mediawiki/parts/0/01/NadE_emphasized.jpg
  
Figure 1.1 Gel electrophoresis of PCR products.
+
https://static.igem.org/mediawiki/parts/d/d6/NadE_emphasized1.jpg
  
Key:
+
<em><strong>Figure 2.</strong> Gel electrophoresis of PCR products.</em>
  
E - nadE for restriction digestion with nhe1 (insert for MCS2)
 
  
 
It can be observed that nadE genes were properly extracted as their bands are located below 1kbp which is near the actual size of the nadE gene (883bp). The smears in each well can result from the high concentration of primers, we learned from our mistake and tried to lower the concentration.
 
It can be observed that nadE genes were properly extracted as their bands are located below 1kbp which is near the actual size of the nadE gene (883bp). The smears in each well can result from the high concentration of primers, we learned from our mistake and tried to lower the concentration.
  
Next, these gels were eluted, and collected genes were inserted into the pRGPDuo2 plasmid. To incorporate nadE genes, we digested plasmids with NheI, SacI, SalI restrictases, and T4 ligase. These plasmids with incorporated nadE gene were electroporated into Pseudomonas putida and Pseudomonas aeruginosa. Unfortunately, due to the lack of time from the COVID-19 situation and late reagents delivery, we were not able to properly insert our genes into P. putida. However, we managed to cultivate P. aeruginosa in kanamycin in LB agar. Then, we extracted these engineered plasmids, and double digested them by SacI and SalI restrictases:
+
Next, these gels were eluted, and collected genes were inserted into the pRGPDuo2 plasmid. To incorporate nadE genes, we digested plasmids with NheI, SacI, SalI restrictases, and T4 ligase. These plasmids with incorporated nadE gene were electroporated into <em>Pseudomonas putida</em> and <em>Pseudomonas aeruginosa</em>. Unfortunately, due to the lack of time from the COVID-19 situation and late reagents delivery, we were not able to properly insert our genes into <em>P. putida</em>. However, we managed to cultivate <em>P. aeruginosa</em> in kanamycin in LB agar. Then, we extracted these engineered plasmids, and double digested them by SacI and SalI restrictases:
  
https://static.igem.org/mediawiki/parts/4/4a/Final_electrophoresis.jpeg
+
https://static.igem.org/mediawiki/parts/3/3a/NadE%2Bplasmid_emphasized1.jpg
  
In this picture,  C well contains pRGPDuo2+nadE which was double digested. The base pair length corresponds to the actual length of pRGPDuo2 and nadE.  
+
<em><strong>Figure 3.</strong> Gel Electrophoresis of extracted plasmids with genes</em>
 +
 
 +
 
 +
In this picture,  C well contains pRGPDuo2+<em>nadE</em> which was double digested. The base pair length corresponds to the actual length of pRGPDuo2 and nadE.  
 +
 
 +
<strong>Bioelectrochemical testing</strong>
  
 
To analyze the effect of NAD on rhamnolipid production, we tested the electro fermentation experiment and analysis of biosurfactants.  
 
To analyze the effect of NAD on rhamnolipid production, we tested the electro fermentation experiment and analysis of biosurfactants.  
  
Genetically modified P. aeruginosa was introduced to the minimal salt media with crude oil and incubated it for 24 hours. Bioelectrochemical experiments were conducted using the chronoamperometric (CA) method and cyclic voltammetry (CV).  
+
Genetically modified <em>P. aeruginosa</em> was introduced to the minimal salt media with crude oil and incubated it for 24 hours. Bioelectrochemical experiments were conducted using the chronoamperometric (CA) method and cyclic voltammetry (CV).  
  
 
Cyclic voltammetry (CV) method
 
Cyclic voltammetry (CV) method
Line 52: Line 54:
 
https://static.igem.org/mediawiki/parts/thumb/f/fd/Cyclicvoltammetry.png/751px-Cyclicvoltammetry.png
 
https://static.igem.org/mediawiki/parts/thumb/f/fd/Cyclicvoltammetry.png/751px-Cyclicvoltammetry.png
  
Figure 1. Cyclic voltammograms (CV) at 10mV/s scan rate between -400mV and 400mV for the different electro fermentative setups for production of rhamnolipids by the different test P. aeruginosa strains (engineered and wild type). Media used: MSM (minimum salt media) + oil + casein
+
<em><strong>Figure 4.</strong> Cyclic voltammograms (CV) at 10mV/s scan rate between -400mV and 400mV for the different electro fermentative setups for production of rhamnolipids by the different test <em>P. aeruginosa</em> strains (engineered and wild type). Media used: MSM (minimum salt media) + oil + casein</em>
 +
 
  
Cyclic voltammetry (CV) plot shows distinct oxidation (upwards) and reduction (downward) curves which imply that the set-ups are redox-active (electrochemically active). Figure 1 depicts that P. aeruginosa with overexpressed nadE (red line) had the highest peak among the test strains after 24 h incubation. This can be explained by the increased respiratory activity of the strain caused by increased NAD synthetase production. This in turn increases metabolic reactions that involve NAD as an electron carrier. It can be hypothesized that such a scenario will lead to faster cell growth of bacteria thereby inducing an increased expression of rhlB and rhlA genes and resulting in a higher yield of desired biosurfactants.  
+
Cyclic voltammetry (CV) plot shows distinct oxidation (upwards) and reduction (downward) curves which imply that the set-ups are redox-active (electrochemically active). Figure 1 depicts that <em>P. aeruginosa</em> with overexpressed <em>nadE</em> (red line) had the highest peak among the test strains after 24 h incubation. This can be explained by the increased respiratory activity of the strain caused by increased NAD synthetase production. This in turn increases metabolic reactions that involve NAD as an electron carrier. It can be hypothesized that such a scenario will lead to faster cell growth of bacteria thereby inducing an increased expression of <em>rhlB</em> and <em>rhlA</em> genes and resulting in a higher yield of desired biosurfactants.  
Although other strains of P. aeruginosa with overexpressed rhlA and rhlB genes and wild-type strain showed some peaks at similar oxidation-reduction spots, they had less respiratory activity because they did not possess overexpressed NAD synthetase. Therefore, we hypothesized that this increased respiratory activity could be significant in enhanced biosurfactant yields as well.
+
Although other strains of <em>P. aeruginosa</em> with overexpressed <em>rhlA</em> and <em>rhlB</em> genes and wild-type strain showed some peaks at similar oxidation-reduction spots, they had less respiratory activity because they did not possess overexpressed NAD synthetase. Therefore, we hypothesized that this increased respiratory activity could be significant in enhanced biosurfactant yields as well.
  
 
Chronoamperometric (CA) method
 
Chronoamperometric (CA) method
Line 61: Line 64:
 
https://static.igem.org/mediawiki/parts/thumb/6/61/Chromoamperometric.png/800px-Chromoamperometric.png
 
https://static.igem.org/mediawiki/parts/thumb/6/61/Chromoamperometric.png/800px-Chromoamperometric.png
  
Figure 2. Chronoamperometry data (CA) at 400mV poised potential for the different electro fermentative setups for production of rhamnolipids by the different test P. aeruginosa strains (engineered and wild type). Media used: MSM + oil + casein
+
<em><strong>Figure 5.</strong> Chronoamperometry data (CA) at 400mV poised potential for the different electro fermentative setups for production of rhamnolipids by the different test <em>P. aeruginosa</em> strains (engineered and wild type). Media used: MSM + oil + casein</em>
  
It can be observed that all the engineered strains yielded higher current outputs than the wild type strain with highest current generated by the P. aeruginosa nadE set up.
 
  
Total electrical charge in Coulombs produced after 24 h incubation by the different test setups carrying the different strains is shown above. The graph depicts that P. aeruginosa nadE setup produced the highest charge of 10.8 mC at 24 h. The trend in total charge production was the following: P. aeruginosa nadE > P. aeruginosa rhlA > P. aeruginosa wild type > P. aeruginosa rhlB.  
+
It can be observed that all the engineered strains yielded higher current outputs than the wild-type strain with the highest current generated by the <em>P. aeruginosa nadE</em> set up.
  
 +
The total electrical charge in Coulombs produced after 24 h incubation by the different test setups carrying the different strains is shown above. The graph depicts that <em>P. aeruginosa</em> <em>nadE</em> setup produced the highest charge of 10.8 mC at 24 h. The trend in total charge production was the following: <em>P. aeruginosa nadE > P. aeruginosa rhlA > P. aeruginosa wild type > P. aeruginosa rhlB</em>.
  
 
===Reference===
 
===Reference===

Latest revision as of 01:18, 22 October 2021

nadE gene of Pseudomonas aeruginosa

nadE from Pseudomonas aeruginosa is coding for NAD synthetase which synthesizes NAD+

Usage and Biology

Our team extracted nadE gene from P. aeruginosa to add it into novel plasmid called pRGPDuo2 for P. putida. Apart from nadE gene, planned to add rhlA and rhlB genes that are responsible for rhamnolipid synthesis. Thus, we predicted that dual expression of NAD synthetase and Rhamnosyltrnasferse can allow P. putida to express rhamnolipids in higher rates.

Pseudaminas aeuriginosa - is gram negative bacilus and opportunistic pathogen. NH3 dependent NAD-synthetase converts deamido-NAD+ to NAD+ by ATP-dependent amidation [1]. ATP + deamido-NAD+ + NH4+ -> AMP + diphosphate + H+ + NAD+

799px-BBa_K4083004-NADS_reaction.png

Figure 1. NADS function


The NAD+ is important for metabolism in organisms. NAD+ can reduce into NADH during cell digestion like glycolysis or the Krebs cycle. Thus, more available NAD+ can lead to faster substrate catabolism. Moreover, NADH interacts with the electron transport chain where it releases one electron and one proton. As an electron moves, more protons exit the bacterial membrane which increases the proton gradient. Finally, to reach equilibrium, protons enter the cell by ATP synthase, and one proton can generate up to 3 ATP molecules this way. Thus, one NADH that releases one proton can generate 3 ATP molecules. Finally, NAD+ can interact with NAD kinase to convert into NADP+ which plays a direct role in the biosynthesis of rhamnolipids. [2]

Part functionality

Visualisation

We used our assembled nadE primers to extract the nadE gene. (https://parts.igem.org/Part:BBa_K4083019, https://parts.igem.org/Part:BBa_K4083020). Obtained genes were amplified in a PCR machine. Then, these PCR products were analyzed in 2 gel electrophoresis experiments:

NadE_emphasized.jpg

NadE_emphasized1.jpg

Figure 2. Gel electrophoresis of PCR products.


It can be observed that nadE genes were properly extracted as their bands are located below 1kbp which is near the actual size of the nadE gene (883bp). The smears in each well can result from the high concentration of primers, we learned from our mistake and tried to lower the concentration.

Next, these gels were eluted, and collected genes were inserted into the pRGPDuo2 plasmid. To incorporate nadE genes, we digested plasmids with NheI, SacI, SalI restrictases, and T4 ligase. These plasmids with incorporated nadE gene were electroporated into Pseudomonas putida and Pseudomonas aeruginosa. Unfortunately, due to the lack of time from the COVID-19 situation and late reagents delivery, we were not able to properly insert our genes into P. putida. However, we managed to cultivate P. aeruginosa in kanamycin in LB agar. Then, we extracted these engineered plasmids, and double digested them by SacI and SalI restrictases:

NadE%2Bplasmid_emphasized1.jpg

Figure 3. Gel Electrophoresis of extracted plasmids with genes


In this picture, C well contains pRGPDuo2+nadE which was double digested. The base pair length corresponds to the actual length of pRGPDuo2 and nadE.

Bioelectrochemical testing

To analyze the effect of NAD on rhamnolipid production, we tested the electro fermentation experiment and analysis of biosurfactants.

Genetically modified P. aeruginosa was introduced to the minimal salt media with crude oil and incubated it for 24 hours. Bioelectrochemical experiments were conducted using the chronoamperometric (CA) method and cyclic voltammetry (CV).

Cyclic voltammetry (CV) method

751px-Cyclicvoltammetry.png

Figure 4. Cyclic voltammograms (CV) at 10mV/s scan rate between -400mV and 400mV for the different electro fermentative setups for production of rhamnolipids by the different test P. aeruginosa strains (engineered and wild type). Media used: MSM (minimum salt media) + oil + casein


Cyclic voltammetry (CV) plot shows distinct oxidation (upwards) and reduction (downward) curves which imply that the set-ups are redox-active (electrochemically active). Figure 1 depicts that P. aeruginosa with overexpressed nadE (red line) had the highest peak among the test strains after 24 h incubation. This can be explained by the increased respiratory activity of the strain caused by increased NAD synthetase production. This in turn increases metabolic reactions that involve NAD as an electron carrier. It can be hypothesized that such a scenario will lead to faster cell growth of bacteria thereby inducing an increased expression of rhlB and rhlA genes and resulting in a higher yield of desired biosurfactants. Although other strains of P. aeruginosa with overexpressed rhlA and rhlB genes and wild-type strain showed some peaks at similar oxidation-reduction spots, they had less respiratory activity because they did not possess overexpressed NAD synthetase. Therefore, we hypothesized that this increased respiratory activity could be significant in enhanced biosurfactant yields as well.

Chronoamperometric (CA) method

800px-Chromoamperometric.png

Figure 5. Chronoamperometry data (CA) at 400mV poised potential for the different electro fermentative setups for production of rhamnolipids by the different test P. aeruginosa strains (engineered and wild type). Media used: MSM + oil + casein


It can be observed that all the engineered strains yielded higher current outputs than the wild-type strain with the highest current generated by the P. aeruginosa nadE set up.

The total electrical charge in Coulombs produced after 24 h incubation by the different test setups carrying the different strains is shown above. The graph depicts that P. aeruginosa nadE setup produced the highest charge of 10.8 mC at 24 h. The trend in total charge production was the following: P. aeruginosa nadE > P. aeruginosa rhlA > P. aeruginosa wild type > P. aeruginosa rhlB.

Reference

[1] UniProt. (n.d.). nadE - NH(3)-dependent NAD(+) synthetase - Pseudomonas aeruginosa (strain PA7) - nadE gene & protein. https://www.uniprot.org/uniprot/A6VD32

[2] Alberts, B., Johnson, A., Lewis, J., Raff, M., Roberts, K., & Walter, P. (2002). Molecular biology of the cell. New York: Garland Science.

[3] UniProt. (n.d.). nadE - NH(3)-dependent NAD(+) synthetase - Pseudomonas aeruginosa (strain PA7) - nadE gene & protein. https://www.uniprot.org/uniprot/A6VD32 Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal XhoI site found at 208
    Illegal XhoI site found at 475
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal NgoMIV site found at 400
    Illegal NgoMIV site found at 470
    Illegal NgoMIV site found at 691
  • 1000
    COMPATIBLE WITH RFC[1000]