Difference between revisions of "Part:BBa K5043009"

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<partinfo>BBa_K5043009 short</partinfo>
 
<partinfo>BBa_K5043009 short</partinfo>
  
PhtAc codes for phthalate dioxygenase ferredoxin subunit. It is a subunit of ring-hydroxylating oxygenase enzyme complexes which participate in biodegradation of polycyclic aromatic hydrocarbons. [1]
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<i>phtAc</i> codes for phthalate dioxygenase ferredoxin subunit. It is a subunit of ring-hydroxylating oxygenase enzyme complexes which participate in biodegradation of polycyclic aromatic hydrocarbons. It is a subunit of various ring-hydroxylating oxygenase enzyme complexes which participate in biodegradation of polycyclic aromatic hydrocarbons. [1–3]
This part encodes for the same protein as BBa_J73042. It only differs in synonym codon usage.  
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This part encodes for the same protein as <html><a href="https://parts.igem.org/Part:BBa_J73042">BBa_J73042</a></html>. It only differs in synonym codon usage.<br><br>
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__TOC__
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<br>
  
Enzyme characterization
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==Background==
Background
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<html>
1. Enzyme production and production
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  <p style="text-align: justify;">
2. Characterization of ferredoxin reductase PhtAd and ferredoxin PhtAc
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    It is well-established that <a href="https://parts.igem.org/Part:BBa_K5043009"><i>phtAc</i></a> and
2.1. Kinetic characterization of PhtAd
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    <a href="https://parts.igem.org/Part:BBa_K5043010"><i>phtAd</i></a> together function as an electron transport chain, facilitating electron transfer from NADH [1].This system is crucial for supplying electrons to various dioxygenase systems, which are involved in the reduction of polycyclic aromatic hydrocarbons (PAHs). One such complex with dioxygenase activity is formed by <a href="https://https://parts.igem.org/Part:BBa_K5043001"><i>nidA</i></a> and <a href="https://https://https://parts.igem.org/Part:BBa_K5043002"><i>nidB</i></a>together with phtAc and phtAd, capable of degrading pyrene into <i>cis</i>-4,5-dihydroxy-4,5-dihydropyrene [2].
2.1.1. Method
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</p>
2.1.2. Results
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</html>
2.2. Kinetic characterization of PhtAc
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2.2.1. Method
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2.2.2. Results
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3. Activity assay coupled with HPLC analysis
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3.1. Method
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3.2. Results
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References
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Background
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<html>
In this project, we aimed to establish a pyrene degradation pathway in Pseudomonas vancouverensis and to integrate it with the organism's native phenanthrene degradation pathway [2]. It is established that PhtAcAd, as electron transfer components, along with a ring-hydroxylating dioxygenase system formed by pdoA2 and pdoB2, aggregate to create a complex exhibiting dioxygenase activity [3, 4, 5]. This complex is capable of converting phenanthrene-4-carboxylate, an intermediate product of pyrene degradation, into cis-3,4-dihydroxyphenanthrene an intermediate in the native phenanthrene degradation pathway of P. vancouverensis, thereby facilitating the conjunction of the two pathways [4, 5]. Given that this enzyme complex serves as a critical junction within the pathways, we opted to conduct a more detailed characterization. The components of the electron transport chain, PhtAc a ferredoxin reductase and ferredoxin PhtAd, were produced and purified to elucidate their kinetic parameters. Subsequently, we aimed to analyze the complex formation with PdoA2B2 through HPLC analysis.
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  <p style="text-align: justify;">
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In this project, our complex of interest is formed by the ring-hydroxylating dioxygenase system, composed by <html><a href="https://parts.igem.org/Part:BBa_K5043006"><i>pdoA2</i> </a></html> and <html><a href="https://parts.igem.org/Part:BBa_K5043007"><i>pdoB2</i> </a></html>. Together with phtAcAd, these components aggregate to form a complex that exhibits dioxygenase activity [4–6]. This complex is capable of converting phenanthrene-4-carboxylate, an intermediate product of pyrene degradation, into <i>cis</i>-3,4-dihydroxy-phenanthrene-4-carboxylate, see Figure 1 [5, 6]. Given this reaction’s importance in pyrene degradation, we opted to conduct a more detailed characterization. The components of the electron transport chain, <i>phtAc</i> a ferredoxin and ferredoxin reductase <i>phtAd</i>, were produced and purified to elucidate their kinetic parameters. Subsequently, we aimed to analyze the complex formation with <i>pdoA2B2</i> through HPLC analysis.
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1. Enzyme production and purification
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Enzymes coding sequences were cloned in pQE bacterial expression plasmid with a cleavable N-terminal, 6x-His tag. Proteins were expressed in E. coli BL21 (DE3). Main cultures were incubated at 37°C until an OD600 of 0.5 was reached. Subsequently, cultures were induced with a final concentration of 0.5 mM IPTG and incubated overnight at 30°C. Purification was performed using Immobilized Metal Affinity Chromatography (IMAC). Both production and purification samples were analyzed via SDS-PAGE and Coomassie Staining (data not shown). Enzyme concentration was determined using the Bradford Assay and for most of the enzymes we were able to get a high yield.
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  </style>
  
2. Characterization of ferredoxin reductase PhtAd and ferredoxin PhtAc
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  <figure>
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    <img src="https://static.igem.wiki/teams/5043/registry/bba-k5043010-fig1.png">
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    <figcaption>Figure 1: Enzymatic reaction of <i>phtAcAd-pdoA2B2</i> complex [3].<br>
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<i><small>Proposed schema of a catalytic cycle mediated by pdoA2B2-PhtAcAd. Reaction: A molecule of dioxygen is integrated into polycyclic aromatic hydrocarbons (PAHs) through the transfer of two electrons supplied by NADH, facilitated by the electron transport complex phtAcAd.</small></i></figcaption>
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  </figure>
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<br></html>
  
The characterization of PhtAd (insert part) activity was performed by evaluating its ability to reduce 2,6-dichlorophenolindophenol (DCPIP), which serves as an electron acceptor [6]. In its oxidized form, DCPIP displays a blue color, which transitions to colorless upon reduction, facilitating the evaluation of PhtAd activity [6]. The decrease in absorbance was monitored at 600 nm [6].  
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==Enzyme production and purification==
The activity of PhtAc (insert part) was assessed using a coupled assay. The increase in absorbance resulting from an electron transfer to Cytochrome c signifies an interaction between ferredoxin PhtAc and ferredoxin reductase PhtAd [6]. The increase in absorbance was monitored at 5500 nm [6]. Both reactions needed NADH and FADH as cofactors [6].  
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Enzyme coding sequences were cloned into pQE bacterial expression vector with a N-terminal, hexahistidine tag. Proteins were expressed in <i>E. coli</i> BL21 (DE3). Main cultures were incubated at 37°C until an OD600 of 0.5 was reached. Subsequently, cultures were induced with a final concentration of 0.5 mM IPTG and incubated overnight at 30°C. Purification was performed using Immobilized Metal Affinity Chromatography (IMAC). Both production and purification samples were analyzed via SDS-PAGE and Coomassie staining (data not shown). Enzyme concentration was determined using the Bradford Assay [7]. The final protein yield was 511.5 µM. <br>
  
2.1. Kinetic characterization of PhtAd
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==Kinetic Characterization of ferredoxin <i>phtAc</i> coupled to <i>phtAd</i>==
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Prior to conducting the <i>phtAc</i> kinetic analysis, the kinetic parameters of phtAd were initially established to verify the activity of <html><a href="https://parts.igem.org/Part:BBa_K5043010"><i>phtAd</i> </a></html>, since the activity of <i>phtAc</i> was assessed using a coupled assay. The increase in absorbance resulting from an electron transfer to cytochrome c signifies an interaction between ferredoxin <i>phtAc</i> and ferredoxin reductase <i>phtAd</i>. The increase in absorbance was monitored at 550nm. NADH and FADH are needed as cofactors. [3] <br>
  
2.1.1. Method
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===Method===
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Initial measurements were conducted in accordance with the methodology outlined by Wu et al. (2020) [3]. However, the assay produced inconclusive results, as no variation in absorption was observed over time. This lack of change was attributed to the high concentration of cytochrome c (600 µM) utilized in the initial trials. Consequently, we opted to conduct further assays employing varying concentrations of cytochrome c and NADH to identify the optimal concentrations that would facilitate a measurable increase in absorption. In alignment with the approach taken by Wu et al. (2020) [3], subsequent assays were performed using a <i>phtAd</i> to <i>phtAc</i> ratio of 1:3. The increase in absorbance was measured over a 30-minute period at 2-minute intervals at 550 nm. After the optimal cytochrome c concentration was established, further assays were performed varying the NADH concentration to determine the kinetic parameters. <br>
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===Results===
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<b>Determination of the optimal substrate concentration</b><br>
  
Initially, the optimal reaction time and enzyme concentration were established by measuring the decrease in absorbance over a 30-minute period at 2-minute intervals. Following the determination of these parameters, the reaction was assessed using varying concentrations of NADH while maintaining a constant enzyme concentration to determine the kinetic parameters. The reaction was initiated by the addition of a specified amount of PhtAd and monitored at 600 nm using a UV/Vis spectrometer.
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In the initial assay conducted with 250 µM cytochrome c, no change in absorbance was observed (see Figure 2A). Considering this outcome, the subsequent assay was performed using 100 µM cytochrome c in conjunction with a higher concentration of NADH (200 µM). This combination resulted in a measurable increase in absorbance, demonstrating a linear progression over a duration of 26 minutes (see Figure 2C) indicating the oxidation of cytochrome c. To validate this outcome, additional assays were conducted utilizing 100 µM cytochrome c alongside varying concentrations of NADH, both higher and lower. The assay employing 250 µM NADH also demonstrated a linear increase in absorption (Figure 2B) in the first 26 minutes. Conversely, the assay with 100 µM NADH (See Figure 2D) also exhibited a linear increase in absorption, albeit at a reduced rate. Notably, no saturation point was observed at this concentration, in contrast to the higher concentrations, which indicated saturation occurring approximately 30 minutes into the assay.<br>
 
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<html><br><br>
2.1.2. Results
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        <figure>
 
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          <img src="https://static.igem.wiki/teams/5043/registry/bba-k5043009-fig1.png" style="width:90%">
Determination of the optimal enzyme concentration
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          <figcaption>Figure 2: Oxidation of Cytochrome c catalyzed by <i>phtAc</i>, in conjunction with <i>phtAd</i>, under varying concentrations of cytochrome c and NADH.<br>
 
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<i>The oxidation of cytochrome c by phtAc coupled with phtAd was monitored for 30 min at a constant enzyme concentration and varying amount of substrate. The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 100 – 250 µM NADH, 100 and 250 µM cyt. c, 0.5 µM FAD, 1 µM phtAd and 3.5 µM phtAc. Reaction was performed at room temperature.</i></figcaption>
Initial optical analysis indicates that the assay conducted with the highest concentration of PhtAd, 1.25 µM, resulted in the complete reduction of DCPIP, as evidenced by the solution's transition to a fully colorless state (see Fig. 1). On the other hand, figure 2 shows that there is no significant difference in the absorbance measurements between the assays conducted with 1 µM and 1.25 µM PhtAd. However, the reaction conducted with 0.5 µM PhtAd exhibited a lesser decrease in absorbance over the 30-minute period, indicating that the reaction proceeded at a relatively slow rate.
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        </figure><br></html>
 
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Fig. 1 Reduction of DCPIP with different PhtAd concentration
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Regarding the optimal reaction time, Figure 2 illustrates that within the initial 10 minutes, absorbance decreases rapidly, indicating that the reduction of DCPIP occurs predominantly during this period. Beyond the 10-minute mark, absorbance measurements stabilize, suggesting that the reaction has reached a saturation point. This phenomenon may be attributed to the complete occupation of all enzyme’s active sites or the inability of the reaction to proceed further due to the lack of NADH regeneration.
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Fig. 2 Reduction of DCPIP performed with Different PhtAd concentrations.
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Based on the results obtained, we chose a concentration of 100 µM cytochrome c for the subsequent tests, as this concentration showed a measurable increase in absorbance. For the reaction time, we decided to run further reactions for 34 minutes to confirm the saturation point. <br>
The reduction of DCPIP by PhtAd was monitored for 30 min at a constant substrate quantity and varying amount of enzyme.  The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 100 µM NADH, 30 µM DCPIP, 0.5 µM FAD and 0.5, 1, 1.25 µM PhtAd. Reaction was performed at room temperature.  
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Based on the results obtained, we selected a concentration of 1.25 µM PhtAd for the subsequent assay, as this concentration demonstrated a complete reduction of DCPIP.  
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===Kinetic parameters of <i>phtAc</i>===
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For the determination of the kinetic parameters the assay was run with different NADH concentrations ranging from 40 µM to 400 µM. Data obtained from these assays were then analyzed using Michaelis-Menten kinetics (see Figure 3) and a Lineweaver-Burk plot (see Figure 4) was constructed to provide a linear representation of the enzyme kinetics to determine key parameters such as Vmax and Km. <br>
  
Kinetic parameters of PhtAd
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<html><br><br>
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        <figure>
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          <img src="https://static.igem.wiki/teams/5043/registry/bba-k5043009-fig2.png" style="width:60%">
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          <figcaption>Figure 3: Michaelis-Menten Curve for <i>phtAc.<br>
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The velocity <i><small>v = ΔE/(ε × d × Δt)</small></i> was calculated utilizing the Lambert-Beer Law with the extinction coefficient of Cytochrome C (ε550 21 mM-1 x cm–1) [3]. A logarithmic trend line was applied as a preliminary approximation.</i></figcaption>
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        </figure><br></html>
  
For the determination of the kinetic parameters the Assay was runned with different NADH concentrations ranging from 40 µM to 250 µM. Data obtained from these assays were then analyzed using Michaelis-Menten kinetics (See Fig. 4) and a Lineweaver-Burk plot (See Fig. 5) was constructed to provide a linear representation of the enzyme kinetics to determine key parameters such as Vmax and Km.  
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<html><br><br>
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        <figure>
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          <img src="https://static.igem.wiki/teams/5043/registry/bba-k5043009-fig3.png" style="width:60%">
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          <figcaption>Figure 4: Lineweaver-Burk plot.<br>
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<i>Graphs show the fitted linear function and its correlation coefficient.</i></figcaption>
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        </figure><br></html>
 
   
 
   
Fig. 4 Michaelis-Menten Curve for PhtAd
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The <b>Vmax, Km, kcat, kcat/Km values</b> of the ferredoxin <i>phtAc</i> were <b>0.00043 mM/min, 0.31 mM, 0.12 1/min and 3.9 1/mM x min</b>, respectively.  Significant deviations from the literature values [3] were observed; however, the reaction was conducted with a substantially lower concentration of cytochrome c and elevated concentrations of enzymes, as the enzymes produced exhibited reduced activity.<br>
The velocity was calculated utilizing the Lambert-Beer Law with the extinction coefficient of Cytochrome C (ε600 23 mM-1 x cm–1) [6]. A logarithmic trend line was applied as a preliminary approximation.
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Fig. 5 Lineweaver-Burk plot
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Graphs show the fitted linear function and its correlation coefficient.
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The Vmax, Km, kcat, kcat/Km values of the ferredoxin reductase PhtAd were 0.0011 mM/min, 0.028 mM, 1.12 min-1 and 39.46 mM-1 x min-1, respectively.  Notable discrepancies from the values reported in the literature (Wu et al., 2019) were identified, which can be attributed to variations in enzyme concentration. The reaction was performed using a higher enzyme concentration due to the observed diminished activity of the produced enzymes.
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2.2. Kinetic Characterization of PhtAc
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Moreover, the R² value of 0.5378 derived from the kinetic analysis of <i>phtAc</i> is marginally higher than that of <html><a href="https://parts.igem.org/Part:BBa_K5043010"><i>phtAd</i> </a></html>. This marginally elevated value may indicate a greater reliability of the data or a more consistent enzymatic response across varying NADH concentrations. Nevertheless, the Lineweaver-Burk plot does not accurately characterize the relationship between 1/[NADH] and 1/V. Although the fit is moderate, it implies that factors such as experimental variability, biological complexity, or non-linear enzyme behavior could be responsible for the observed deviations from the expected linear relationship.<br>
  
2.2.1. Method  
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==Activity assay coupled with HPLC analysis==
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We successfully characterized and demonstrated the activity of <i>phtAc</i> and <i>phtAd</i> both individually and as a complex. This complex functions as an electron carrier for <i>pdoA2B2</i> [4–6]. The subsequent step involved conducting an activity assay in conjunction with HPLC analysis with the aim to evaluate the function of <i>pdoA2B2</i> both independently and in complex with <i>phtAcAd</i>, forming a tetramer. <br>
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===Method===
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Initially, the activity assay was conducted, wherein the enzymes were incubated at 30°C for approximately 15 to 20 minutes, both in the presence and absence of NADH to examine the effect of NADH on enzymatic aggregation. Subsequently, phenanthrene-4-carboxylate (P4C) was added to initiate the reaction. The reaction mixture was then incubated for 30 minutes at 30°C, after which the reaction was terminated by the addition of 100% methanol. Following this, HPLC analysis was performed using a Zorbax SB-C18 column, employing an acetonitrile/water gradient at a flow rate of 0.4 ml/min, with the column oven maintained at room temperature. The gradient elution program commenced with an initial mobile phase of 60:40 (v/v) acetonitrile to water, transitioning linearly to 100% acetonitrile over 14 minutes, followed by a return to the initial phase (60:40) after 5 minutes. The total duration for each analysis was 35 minutes. For the negative control, an assay was conducted using denatured enzymes, achieved by heating the enzymes at 95°C for 10 minutes. Peaks were analyzed at 270nm absorbance.<br>
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===Results===
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Initial activity assays were performed solely with <i>pdoA2</i> and <i>pdoB2</i> to form a dimer, thereby validating their enzymatic activity and evaluating their aggregation characteristics. Monomers were incubated together for aggregation in the presence and absence of NADH to determine whether NADH, as a cofactor, influences the aggregation process.
  
Initial measurements were conducted in accordance with the methodology outlined by Wu et al. (2019). However, the assay produced inconclusive results, as no variation in absorption was observed over time. This lack of change was attributed to the high concentration of Cytochrome C (600 µM) utilized in the initial trials. Consequently, we opted to conduct further assays employing varying concentrations of Cytochrome C and NADH to identify the optimal concentrations that would facilitate a measurable increase in absorption. In alignment with the approach taken by Wu et al. (2019), subsequent assays were performed using a PhtAd to PhtAc ratio of 1:3.5. The increase in absorbance was measured over a 30-minute period at 2-minute intervals at 550 nm. After the optimal Cytochrome C concentration was established, further assays were performed varying the NADH concentration to determine the kinetic parameters.  
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The efficacy of the reaction was assessed by measuring the absorbance of phenanthrene-4-carboxylate (P4C) and NADH using HPLC. The area under the resulting peaks corresponding to the levels of P4C and NADH was determined, enabling a comparative analysis of the consumption of P4C and NADH against established standards and between the samples. In this context, phenanthrene-4-carboxylate consumption refers to the extent of P4C degradation, as indicated by a reduction in peak area compared to the standard. In the absence of additional samples with different concentrations, it is not possible to quantify the remaining P4C in the samples. The only conclusion that can be drawn is whether P4C has been degraded, as evidenced by the decrease in the area of the corresponding peak; this applies also to NADH.
  
2.2.2. Results  
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Furthermore, to eliminate potential statistical errors in the assessment of our results, we employed triplicate measurements for each sample and calculated their averages. The results are presented in Figure 5. Results indicated that the assays in which NADH was added prior to aggregation exhibited enhanced P4C degradation and, correspondingly, increased NADH consumption compared to the assays where NADH was added after aggregation. However, the observed NADH consumption was relatively low, which may be attributed to the absence of the electron carrier dimer (<i>phtAcAd</i>) in the sample, thereby limiting NADH consumption. <br>
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<html><br><br>
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        <figure>
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          <img src="https://static.igem.wiki/teams/5043/registry/bba-k5043010-fig10.png" style="width:90%">
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          <figcaption>Figure 5: Comparative Analysis of phenanthrene-4-carboxylate (P4C) and NADH Consumption in <i>pdoA2</i>:<i>pdoB2</i> activity assays.<br>
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<i>The degradation of P4C by <i>pdoA2</i>:<i>pdoB2</i> was monitored for 30 min at a constant substrate and enzyme concentration.  The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 25 µM P4C, 1 µM <i>pdoA2</i> and 1 µM <i>pdoB2</i>. The 100 µM NADH were either added after or before aggregation. </i></figcaption>
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        </figure><br></html>
  
Determination of the optimal substrate concentration
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Considering the initial results, the analysis of the tetramer aggregation process and the degradation of phenanthrene-4-carboxylat was conducted by introducing NADH prior to the aggregation process. <br><br>
  
In the initial assay conducted with 250 µM Cytochrome C, no change in absorbance was observed (see Fig. 3A). Considering this outcome, the subsequent assay was performed using 100 µM Cytochrome C in conjunction with a higher concentration of NADH (200 µM). This combination resulted in a measurable increase in absorbance, demonstrating a linear progression over a duration of 26 minutes (see Fig. 3C) indicating the oxidation of Cytochrome C. To validate this outcome, additional assays were conducted utilizing 100 µM Cytochrome C alongside varying concentrations of NADH, both higher and lower. The assay employing 250 µM NADH also demonstrated a linear increase in absorption (see Fig. 3B) in the first 26 minutes. Conversely, the assay with 100 µM NADH (See Fig. 3D) also exhibited a linear increase in absorption, albeit at a reduced rate. Notably, no saturation point was observed at this concentration, in contrast to the higher concentrations, which indicated saturation occurring approximately 30 minutes into the assay.
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<b>Degradation of phenanthrene-4-carboxylat by enzyme complex with dioxygenase activity using NADH as a cofactor</b> <br>
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Fig. 5 Oxidation of Cytochrome c catalyzed by PhtAc, in conjunction with PhtAd, under varying concentrations of Cytochrome c and NADH.
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The oxidation of Cytochrome C by PhtAc coupled with PhtAd was monitored for 30 min at a constant enzyme concentration and varying amount of substrate. The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 100 – 250 µM NADH, 100 and 250 µM Cyt. C, 0.5 µM FAD, 1 µM PhtAd and 3.5 µM PhtAc. Reaction was performed at room temperature.
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Based on the results obtained, we chose a concentration of 100 µM cytochrome C for the subsequent tests, as this concentration showed a measurable increase in absorbance. For the reaction time, we decided to run further reactions for 34 minutes to confirm the saturation point.  
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The presence of the functional enzyme complex with dioxygenase activity is anticipated to result in a reduction in the quantity of phenanthrene-4-carboxylate. This reduction can be quantified by determining the decrease in the area of the corresponding peak in comparison to the standard. Given the unknown stoichiometry of this enzyme complex, we conducted assays utilizing two distinct stoichiometric ratios. The first assay employed a 1:1 stoichiometry of all monomers, while the second utilized a ratio of <i>pdoA2<sup>1</sup></i>:<i>pdoB2<sup>1</sup></i>:<i>phtAc</i><sup>3</sup>:<i>phtAd<sup>1</sup></i>. This latter stoichiometry was selected based on previous kinetic analyses of <i>phtAc</i>, which were performed with a ratio of three <i>phtAc</i> molecules to one <i>phtAd</i> for determining kinetic parameters. [3] This ratio was employed in the present assays to assess its influence on the degradation of phenanthrene-4-carboxylate and to determine whether the presence of three equivalents <i>phtAc</i> enhanced the efficiency of the electron transfer process, thereby accelerating the breakdown of phenanthrene-4-carboxylate. However, results showed (see Figure 6) that the breakdown of phenanthrene-4-carboxylat was slightly more efficient with the 1:1 ratio of the monomers; this could suggest that a higher ratio of <i>phtAc</i> does not enhance the electron transfer process. And that the complex with 1:1 ratio of all enzymes aggregates better. <br>
  
Kinetic parameters of PhtAc
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To confirm the aggregation of the enzyme complex and the successful degradation of P4C by this complex, negative controls were prepared. For this, assays were prepared with denatured enzymes with the stoichiometries described above. Results showed (see Figure 6) that the peak area of P4C within these assays was higher in comparison with the assays with the active enzyme complex.  The comparison of these results indicates that the enzyme complex was successfully formed and demonstrated the capacity to degrade P4C. <br>
 
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<html><br><br>
For the determination of the kinetic parameters the Assay was runned with different NADH concentrations ranging from 40 µM to 400 µM. Data obtained from these assays were then analyzed using Michaelis-Menten kinetics (See Fig. 6) and a Lineweaver-Burk plot (See Fig. 7) was constructed to provide a linear representation of the enzyme kinetics to determine key parameters such as Vmax and Km.  
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        <figure>
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          <img src="https://static.igem.wiki/teams/5043/registry/bba-k5043010-fig11-1.png" style="width:100%">
Fig. 6 Michaelis-Menten Curve for PhtAc
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          <figcaption>Figure 6: Comparative Analysis of phenanthrene-4-carboxylate (P4C) and NADH Consumption in <i>pdoA2</i>:<i>pdoB2</i>:<i>phtAc</i>:<i>phtAd</i> activity assays.<br>
The velocity was calculated utilizing the Lambert-Beer Law with the extinction coefficient of Cytochrome C (ε550 21 mM-1 x cm–1) [6]. A logarithmic trend line was applied as a preliminary approximation.
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<i>The degradation of P4C by the enzyme complex was monitored for 30 min at a constant substrate and enzyme concentration. The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 200 µM NADH, 40 µM P4C, 1 µM pdoA2, 1 µM pdoB2, 1 or 3 µM and 1 µM phtAd</i>.</figcaption>
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        </figure><br></html>
 
   
 
   
Fig. 7 Lineweaver-Burk plot
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Another negative control was conducted by excluding any enzymes from the assay. In comparison to samples containing denatured enzymes, the results showed a reduced peak area in the peak corresponding to phenanthrene-4-carboxylate, suggesting either a diminished quantity of P4C in the sample or its degradation. However, the possibility of cross-reactivity with other components in the assay can be discounted, as such interactions would also manifest in the other negative controls. This observation indicates the presence of an independent source of error. Potential issues may involve the unintentional introduction of enzymes or inadequate substrate concentration. The presence of enzymes in the assay can be corroborated by taking into consideration the amount of NADH; notably, the peak area of NADH in this sample was diminished suggesting the possibility that a reaction has taken place, and the results are more consistent with those obtained from the assay conducted with a 1:3 enzyme ratio (see Figure 6). While numerous errors could have arisen, a systematic issue such as cross-reactivity, which would render the enzyme ineffective, can be dismissed by comparing the sample to those with non-functional enzymes. <br>
Graphs show the fitted linear function and its correlation coefficient.
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The Vmax, Km, kcat, kcat/Km values of the ferredoxin PhtAc were 0.00043 mM/min, 0.31 mM, 0.12 1/min and 3.9 1/mM x min, respectively.  Significant deviations from the literature values (Wu et al., 2019) were observed; however, the reaction was conducted with a substantially lower concentration of Cytochrome C and elevated concentrations of enzymes, as the enzymes produced exhibited reduced activity.
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Moreover, as anticipated, the samples containing the active enzyme complex demonstrated a decrease in the peak area associated with NADH relative to the standard (see Figure 6). This finding corroborates the functionality of the electron carrier dimer, which collaborates with <i>pdoA2B2</i> in the degradation of P4C. In contrast, the assay involving denatured enzymes at a 1:1 ratio revealed no consumption of NADH, indicating the absence of any reaction. <br>
  
 +
However, the results of NADH consumption from the assay involving denatured enzymes, utilizing three equivalents of <i>phtAc</i> in conjunction with a 1:1 ratio of the other enzymes, demonstrate a reduction in NADH consumption, as evidenced by the diminished area of the corresponding peak relative to the standard. This observation indicates the presence of an independent source of error, as the other assay performed with denatured enzymes shows no NADH consumption. Potential issues may include insufficient NADH concentration. If the NADH concentration was low, degradation could have occurred over time, as the activity assays were conducted days prior to the HPLC analysis. The thawing process and exposure of the sample to temperature fluctuations may have contributed to NADH degradation due to its inherent instability. Additionally, the possibility of incomplete denaturation should be considered. If the enzymes were not fully denatured during the assay, residual active enzyme could remain, resulting in NADH consumption. The denaturation conditions may not have been adequate to completely inactivate the enzymes. This is further supported by the observation that P4C consumption was slightly lower in comparison to the sample with denatured enzymes with the 1:1 ratio. <br>
  
3. Activity assay coupled with HPLC analysis 
+
==Conclusion==
 
+
In conclusion, the enzyme complex with dioxygenase activity demonstrated its ability to degrade phenanthrene-4-carboxylate (P4C), with slightly greater efficiency observed in the assay utilizing a 1:1 ratio of monomers compared to the 1:3 ratio of <i>phtAc</i> to <i>pdoA2</i>:<i>pdoB2</i>:<i>phtAd</i>. This suggests that a higher ratio of <i>phtAc</i> does not enhance electron transfer efficiency. Negative controls, including assays with denatured enzymes and no enzymes, confirmed that the active enzyme complex was responsible for P4C degradation, while the reduction in NADH in some denatured enzyme assays points to possible errors, such as NADH degradation or incomplete enzyme denaturation. Further assays with stricter controls are needed to confirm these findings and minimize potential sources of error.
We successfully characterized and demonstrated the activity of PhtAc and PhtAd both individually and as a complex. This complex functions as an electron carrier for PdoA2B2 [2, 3, 4]. The subsequent step involved conducting an activity assay in conjunction with HPLC analysis with the aim to evaluate the function of PdoA2B2 both independently and in complex with PhtAcAd, forming a tetramer.
+
 
+
3.1. Method
+
 
+
Initially, the activity assay was conducted, wherein the enzymes were incubated at 30°C for approximately 15 to 20 minutes, both in the presence and absence of NADH to examine the effect of NADH on enzymatic aggregation. Subsequently, Phenanthrene-4-carboxylate (P4C) was added to initiate the reaction. The reaction mixture was then incubated for 30 minutes at 30°C, after which the reaction was terminated by the addition of 100% methanol. Following this, High-Performance Liquid Chromatography (HPLC) analysis was performed using a Zorbax SB-C18 column, employing an acetonitrile/water gradient at a flow rate of 0.4 ml/min, with the column oven maintained at room temperature. The gradient elution program commenced with an initial mobile phase of 60:40 (v/v) acetonitrile to water, transitioning linearly to 100% acetonitrile over 14 minutes, followed by a return to the initial phase (60:40) after 5 minutes. The total duration for each analysis was 35 minutes. For the negative control, an assay was conducted using denatured enzymes, achieved by heating the enzymes at 95°C for 10 minutes.
+
 
+
3.2. Results
+
 
+
Initial activity assays were performed solely with PdoA2 and PdoB2 to form a dimer, thereby validating their enzymatic activity and evaluating their aggregation characteristics. Monomers were incubated together for aggregation in the presence and absence of NADH to determine whether NADH, as a cofactor, influences the aggregation process.
+
The efficacy of the reaction was assessed by measuring the absorbance of Phenanthrene-4-carboxylate (P4C) and NADH using HPLC. The area under the resulting peaks corresponding to the levels of P4C and NADH was determined, enabling a comparative analysis of the consumption of P4C and NADH against established standards and between the samples. Furthermore, to eliminate potential statistical error in the assessment of our results, we employed triplicate measurements for each sample and calculated their averages. The results are presented in Figure 1. Results indicated that the assays in which NADH was added prior to aggregation exhibited enhanced P4C degradation and, correspondingly, increased NADH consumption compared to the assays where NADH was added after aggregation. However, the observed NADH consumption was relatively low, which may be attributed to the absence of the electron carrier dimer (PhtAcAd) in the sample, thereby limiting NADH consumption.
+
+
Fig. 8 Comparative Analysis of Phenanthrene-4-carboxylat (P4C) and NADH Consumption in PdoA2:PdoB2 activity assays.
+
The degradation of P4C by PdoA2:PdoB2 was monitored for 30 min at a constant substrate and enzyme concentration.  The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 25 µM P4C, 1 µM PdoA2 and 1 µM PdoB2. The 100 µM NADH were either added after aggregation (a.A) or before aggregation (b.A). 
+
 
+
Considering the initial results, the analysis of the tetramer aggregation process and the degradation of Phenanthrene-4-carboxylat was conducted by introducing NADH prior to the aggregation process.
+
 
+
Degradation of Phenanthrene-4-carboxylat by enzyme complex with dioxygenase activity using NADH as a cofactor 
+
 
+
The presence of the functional enzyme complex with dioxygenase activity is anticipated to result in a reduction in the quantity of Phenanthrene-4-carboxylate. This reduction can be quantified by determining the decrease in the area of the corresponding peak in comparison to the standard. Given the unknown stoichiometry of this enzyme complex, we conducted assays utilizing two distinct stoichiometric ratios. The first assay employed a 1:1 stoichiometry of all monomers, while the second utilized a ratio of PdoA2:PdoB2:PhtAc3:PhtAd. This latter stoichiometry was selected based on previous kinetic analyses of PhtAc, which were performed with a ratio of three PhtAc molecules to one PhtAd for determining kinetic parameters. This ratio was employed in the present assays to assess its influence on the degradation of Phenanthrene-4-carboxylate and to determine whether the presence of three PhtAc molecules enhanced the efficiency of the electron transfer process, thereby accelerating the breakdown of Phenanthrene-4-carboxylate. However, results showed (see Fig. 2) that the breakdown of Phenanthrene-4-carboxylat was slightly more efficient with the 1:1 ratio of the monomers; this could suggest that a higher ratio of PhtAc does not enhance the electron transfer process. And that the 1:1 ratio may have created a more favorable environment for the interaction of the active site with the substrate.
+
 
+
To confirm the aggregation of the enzyme complex and the successful degradation of P4C by this complex, negative controls were prepared. For this, assays were prepared with denatured enzymes with the stoichiometries described above. Results showed (see Fig. 2) that the peak area of P4C within these assays was higher in comparison with the assays with the active enzyme complex.  The comparison of these results indicates that the enzyme complex was successfully formed and demonstrated the capacity to degrade P4C.
+
 
+
Another negative control was conducted by excluding any enzymes from the assay.  In comparison to samples containing denatured enzymes, the results showed a reduced peak area in the peak corresponding to Phenanthrene-4-carboxylat, suggesting either a diminished quantity of P4C in the sample or its degradation. However, the possibility of cross-reactivity with other components in the assay can be discounted, as such interactions would also manifest in the other negative controls. This observation indicates the presence of an independent source of error. Potential issues may involve the unintentional introduction of enzymes or inadequate substrate concentration. The presence of enzymes in the assay can be corroborated by taking into consideration the amount of NADH; notably, the peak area of NADH in this sample was diminished suggesting the possibility that a reaction has taken place, and the results are more consistent with those obtained from the assay conducted with a 1:3 enzyme ratio (see Fig. 2). While numerous errors could have arisen, a systematic issue such as cross-reactivity, which would render the enzyme ineffective, can be dismissed by comparing the sample to those with non-functional enzymes.
+
Moreover, as anticipated, the samples containing the active enzyme complex demonstrated a decrease in the peak area associated with NADH relative to the standard (see Fig. 2). This finding corroborates the functionality of the electron carrier dimer, which collaborates with PdoA2B2 in the degradation of P4C. In contrast, the assay involving denatured enzymes at a 1:1 ratio revealed no consumption of NADH, indicating the absence of any reaction.
+
 
+
However, if we observed the results of NADH consumption from the assay involving denatured enzymes, utilizing three molecules of PhtAc in conjunction with a 1:1 ratio of the other enzymes, demonstrate a reduction in NADH consumption, as evidenced by the diminished area of the corresponding peak relative to the standard. This observation indicates the presence of an independent source of error, as the other assay performed with denatured enzymes shows no NADH consumption. Potential issues may include insufficient NADH concentration. If the NADH concentration was low, degradation could have occurred over time, as the activity assays were conducted days prior to the HPLC analysis. The thawing process and exposure of the sample to temperature fluctuations may have contributed to NADH degradation due to its inherent instability. Additionally, the possibility of incomplete denaturation should be considered. If the enzymes were not fully denatured during the assay, residual active enzyme could remain, resulting in NADH consumption. The denaturation conditions may not have been adequate to completely inactivate the enzymes. This is further supported by the observation that P4C consumption was slightly lower in comparison to the sample with denatured enzymes with the 1:1 ratio.
+
 
+
In conclusion, the enzyme complex with dioxygenase activity demonstrated its ability to degrade Phenanthrene-4-carboxylate (P4C), with slightly greater efficiency observed in the assay utilizing a 1:1 ratio of monomers compared to the 1:3 ratio of PhtAc to PdoA2:PdoB2:PhtAd. This suggests that a higher ratio of PhtAc does not enhance electron transfer efficiency. Negative controls, including assays with denatured enzymes and no enzymes, confirmed that the active enzyme complex was responsible for P4C degradation, while the reduction in NADH in some denatured enzyme assays points to possible errors, such as NADH degradation or incomplete enzyme denaturation. Further assays with stricter controls are needed to confirm these findings and minimize potential sources of error.  
+
 
+
Fig. 9 Comparative Analysis of Phenanthrene-4-carboxylat (P4C) and NADH Consumption in PdoA2:PdoB2:PhtAc:PhtAd activity assays.
+
The degradation of P4C by the enzym complex was monitored for 30 min at a constant substrate and enzyme concentration.  The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 200 µM NADH, 40 µM P4C, 1 µM PdoA2, 1 µM PdoB2, 1 or 3 µM PhtAc and 1 µM PhtAd.
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===Usage and Biology===
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<span class='h3bb'>Sequence and Features</span>
 
<span class='h3bb'>Sequence and Features</span>
 
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<partinfo>BBa_K5043009 SequenceAndFeatures</partinfo>
 
 
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===Functional Parameters===
 
<partinfo>BBa_K5043009 parameters</partinfo>
 
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== References ==
 
== References ==
 
<small>
 
<small>
[1] S.-J. Kim, O. Kweon, R. C. Jones, J. P. Freeman, R. D. Edmondson, and C. E. Cerniglia, "Complete and integrated pyrene degradation pathway in Mycobacterium vanbaalenii PYR-1 based on systems biology," Journal of bacteriology, vol. 189, no. 2, pp. 464–472, 2007, doi: 10.1128/JB.01310-06.
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[1] L. Guo et al., "Characterization of a novel aromatic ring-hydroxylating oxygenase, NarA2B2, from thermophilic Hydrogenibacillus sp. strain N12," Applied and environmental microbiology, vol. 89, no. 10, e0086523, 2023, doi: 10.1128/aem.00865-23.<br>
[2]     Y. Yang, R. F. Chen, and M. P. Shiaris, "Metabolism of naphthalene, fluorene, and phenanthrene: preliminary characterization of a cloned gene cluster from Pseudomonas putida NCIB 9816," Journal of bacteriology, vol. 176, no. 8, pp. 2158–2164, 1994, doi 10.1128/jb.176.8.2158-2164.1994.
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[2] S.-J. Kim, O. Kweon, R. C. Jones, J. P. Freeman, R. D. Edmondson, and C. E. Cerniglia, "Complete and integrated pyrene degradation pathway in Mycobacterium vanbaalenii PYR-1 based on systems biology," Journal of bacteriology, vol. 189, no. 2, pp. 464–472, 2007, doi: 10.1128/JB.01310-06.<br>
[3] Pagnout, C., Frache, G., Poupin, P., Maunit, B., Muller, J., & Férard, J. (2007). Isolation and characterization of a gene cluster involved in PAH degradation in Mycobacterium sp. strain SNP11: Expression in Mycobacterium smegmatis mc2155. Research in Microbiology, 158(2), 175–186. https://doi.org/10.1016/j.resmic.2006.11.002
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[3] Y. Wu, Y. Xu, and N. Zhou, "A newly defined dioxygenase system from Mycobacterium vanbaalenii PYR-1 endowed with an enhanced activity of dihydroxylation of high-molecular-weight polyaromatic hydrocarbons," Front. Environ. Sci. Eng., vol. 14, no. 1, 2020, doi: 10.1007/s11783-019-1193-5.<br>
[4] Yuan, K., Xie, X., Wang, X., Lin, L., Yang, L., Luan, T., & Chen, B. (2018). Transcriptional response of Mycobacterium sp. strain A1-PYR to multiple polycyclic aromatic hydrocarbon contaminations. Environmental Pollution, 243, 824–832. https://doi.org/10.1016/j.envpol.2018.09.001
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[4] C. Pagnout, G. Frache, P. Poupin, B. Maunit, J.-F. Muller, and J.-F. Férard, "Isolation and characterization of a gene cluster involved in PAH degradation in Mycobacterium sp. strain SNP11: expression in Mycobacterium smegmatis mc(2)155," Research in microbiology, vol. 158, no. 2, pp. 175–186, 2007, doi: 10.1016/j.resmic.2006.11.002.<br>
[5] Krivobok, S., Kuony, S., Meyer, C., Louwagie, M., Willison, J. C., & Jouanneau, Y. (2003). Identification of Pyrene-Induced Proteins in Mycobacterium sp. Strain 6PY1: Evidence for Two Ring-Hydroxylating Dioxygenases. Journal of Bacteriology, 185(13), 3828–3841. https://doi.org/10.1128/jb.185.13.3828-3841.2003
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[5] K. Yuan et al., "Transcriptional response of Mycobacterium sp. strain A1-PYR to multiple polycyclic aromatic hydrocarbon contaminations," Environmental pollution (Barking, Essex : 1987), vol. 243, Pt B, pp. 824–832, 2018, doi: 10.1016/j.envpol.2018.09.001.<br>
[6] Wu, Y., Xu, Y., & Zhou, N. (2019). A newly defined dioxygenase system from Mycobacterium vanbaalenii PYR-1 endowed with an enhanced activity of dihydroxylation of high-molecular-weight polyaromatic hydrocarbons. Frontiers of Environmental Science & Engineering, 14(1). https://doi.org/10.1007/s11783-019-1193-5
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[6] S. Krivobok, S. Kuony, C. Meyer, M. Louwagie, J. C. Willison, and Y. Jouanneau, "Identification of pyrene-induced proteins in Mycobacterium sp. strain 6PY1: evidence for two ring-hydroxylating dioxygenases," Journal of bacteriology, vol. 185, no. 13, pp. 3828–3841, 2003, doi: 10.1128/jb.185.13.3828-3841.2003.<br>
 
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[7] M. M. Bradford, "A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding," Analytical biochemistry, vol. 72, pp. 248–254, 1976, doi: 10.1006/abio.1976.9999.
 
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</small>
 
</small>

Latest revision as of 04:16, 2 October 2024


phtAc from M. vanbaalenii Pyr-1

phtAc codes for phthalate dioxygenase ferredoxin subunit. It is a subunit of ring-hydroxylating oxygenase enzyme complexes which participate in biodegradation of polycyclic aromatic hydrocarbons. It is a subunit of various ring-hydroxylating oxygenase enzyme complexes which participate in biodegradation of polycyclic aromatic hydrocarbons. [1–3] This part encodes for the same protein as BBa_J73042. It only differs in synonym codon usage.


Background

It is well-established that phtAc and phtAd together function as an electron transport chain, facilitating electron transfer from NADH [1].This system is crucial for supplying electrons to various dioxygenase systems, which are involved in the reduction of polycyclic aromatic hydrocarbons (PAHs). One such complex with dioxygenase activity is formed by nidA and nidBtogether with phtAc and phtAd, capable of degrading pyrene into cis-4,5-dihydroxy-4,5-dihydropyrene [2].

In this project, our complex of interest is formed by the ring-hydroxylating dioxygenase system, composed by pdoA2 and pdoB2 . Together with phtAcAd, these components aggregate to form a complex that exhibits dioxygenase activity [4–6]. This complex is capable of converting phenanthrene-4-carboxylate, an intermediate product of pyrene degradation, into cis-3,4-dihydroxy-phenanthrene-4-carboxylate, see Figure 1 [5, 6]. Given this reaction’s importance in pyrene degradation, we opted to conduct a more detailed characterization. The components of the electron transport chain, phtAc a ferredoxin and ferredoxin reductase phtAd, were produced and purified to elucidate their kinetic parameters. Subsequently, we aimed to analyze the complex formation with pdoA2B2 through HPLC analysis.

Figure 1: Enzymatic reaction of phtAcAd-pdoA2B2 complex [3].
Proposed schema of a catalytic cycle mediated by pdoA2B2-PhtAcAd. Reaction: A molecule of dioxygen is integrated into polycyclic aromatic hydrocarbons (PAHs) through the transfer of two electrons supplied by NADH, facilitated by the electron transport complex phtAcAd.

Enzyme production and purification

Enzyme coding sequences were cloned into pQE bacterial expression vector with a N-terminal, hexahistidine tag. Proteins were expressed in E. coli BL21 (DE3). Main cultures were incubated at 37°C until an OD600 of 0.5 was reached. Subsequently, cultures were induced with a final concentration of 0.5 mM IPTG and incubated overnight at 30°C. Purification was performed using Immobilized Metal Affinity Chromatography (IMAC). Both production and purification samples were analyzed via SDS-PAGE and Coomassie staining (data not shown). Enzyme concentration was determined using the Bradford Assay [7]. The final protein yield was 511.5 µM.

Kinetic Characterization of ferredoxin phtAc coupled to phtAd

Prior to conducting the phtAc kinetic analysis, the kinetic parameters of phtAd were initially established to verify the activity of phtAd , since the activity of phtAc was assessed using a coupled assay. The increase in absorbance resulting from an electron transfer to cytochrome c signifies an interaction between ferredoxin phtAc and ferredoxin reductase phtAd. The increase in absorbance was monitored at 550nm. NADH and FADH are needed as cofactors. [3]

Method

Initial measurements were conducted in accordance with the methodology outlined by Wu et al. (2020) [3]. However, the assay produced inconclusive results, as no variation in absorption was observed over time. This lack of change was attributed to the high concentration of cytochrome c (600 µM) utilized in the initial trials. Consequently, we opted to conduct further assays employing varying concentrations of cytochrome c and NADH to identify the optimal concentrations that would facilitate a measurable increase in absorption. In alignment with the approach taken by Wu et al. (2020) [3], subsequent assays were performed using a phtAd to phtAc ratio of 1:3. The increase in absorbance was measured over a 30-minute period at 2-minute intervals at 550 nm. After the optimal cytochrome c concentration was established, further assays were performed varying the NADH concentration to determine the kinetic parameters.

Results

Determination of the optimal substrate concentration

In the initial assay conducted with 250 µM cytochrome c, no change in absorbance was observed (see Figure 2A). Considering this outcome, the subsequent assay was performed using 100 µM cytochrome c in conjunction with a higher concentration of NADH (200 µM). This combination resulted in a measurable increase in absorbance, demonstrating a linear progression over a duration of 26 minutes (see Figure 2C) indicating the oxidation of cytochrome c. To validate this outcome, additional assays were conducted utilizing 100 µM cytochrome c alongside varying concentrations of NADH, both higher and lower. The assay employing 250 µM NADH also demonstrated a linear increase in absorption (Figure 2B) in the first 26 minutes. Conversely, the assay with 100 µM NADH (See Figure 2D) also exhibited a linear increase in absorption, albeit at a reduced rate. Notably, no saturation point was observed at this concentration, in contrast to the higher concentrations, which indicated saturation occurring approximately 30 minutes into the assay.


Figure 2: Oxidation of Cytochrome c catalyzed by phtAc, in conjunction with phtAd, under varying concentrations of cytochrome c and NADH.
The oxidation of cytochrome c by phtAc coupled with phtAd was monitored for 30 min at a constant enzyme concentration and varying amount of substrate. The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 100 – 250 µM NADH, 100 and 250 µM cyt. c, 0.5 µM FAD, 1 µM phtAd and 3.5 µM phtAc. Reaction was performed at room temperature.

Based on the results obtained, we chose a concentration of 100 µM cytochrome c for the subsequent tests, as this concentration showed a measurable increase in absorbance. For the reaction time, we decided to run further reactions for 34 minutes to confirm the saturation point.

Kinetic parameters of phtAc

For the determination of the kinetic parameters the assay was run with different NADH concentrations ranging from 40 µM to 400 µM. Data obtained from these assays were then analyzed using Michaelis-Menten kinetics (see Figure 3) and a Lineweaver-Burk plot (see Figure 4) was constructed to provide a linear representation of the enzyme kinetics to determine key parameters such as Vmax and Km.



Figure 3: Michaelis-Menten Curve for phtAc.
The velocity v = ΔE/(ε × d × Δt) was calculated utilizing the Lambert-Beer Law with the extinction coefficient of Cytochrome C (ε550 21 mM-1 x cm–1) [3]. A logarithmic trend line was applied as a preliminary approximation.



Figure 4: Lineweaver-Burk plot.
Graphs show the fitted linear function and its correlation coefficient.

The Vmax, Km, kcat, kcat/Km values of the ferredoxin phtAc were 0.00043 mM/min, 0.31 mM, 0.12 1/min and 3.9 1/mM x min, respectively. Significant deviations from the literature values [3] were observed; however, the reaction was conducted with a substantially lower concentration of cytochrome c and elevated concentrations of enzymes, as the enzymes produced exhibited reduced activity.

Moreover, the R² value of 0.5378 derived from the kinetic analysis of phtAc is marginally higher than that of phtAd . This marginally elevated value may indicate a greater reliability of the data or a more consistent enzymatic response across varying NADH concentrations. Nevertheless, the Lineweaver-Burk plot does not accurately characterize the relationship between 1/[NADH] and 1/V. Although the fit is moderate, it implies that factors such as experimental variability, biological complexity, or non-linear enzyme behavior could be responsible for the observed deviations from the expected linear relationship.

Activity assay coupled with HPLC analysis

We successfully characterized and demonstrated the activity of phtAc and phtAd both individually and as a complex. This complex functions as an electron carrier for pdoA2B2 [4–6]. The subsequent step involved conducting an activity assay in conjunction with HPLC analysis with the aim to evaluate the function of pdoA2B2 both independently and in complex with phtAcAd, forming a tetramer.

Method

Initially, the activity assay was conducted, wherein the enzymes were incubated at 30°C for approximately 15 to 20 minutes, both in the presence and absence of NADH to examine the effect of NADH on enzymatic aggregation. Subsequently, phenanthrene-4-carboxylate (P4C) was added to initiate the reaction. The reaction mixture was then incubated for 30 minutes at 30°C, after which the reaction was terminated by the addition of 100% methanol. Following this, HPLC analysis was performed using a Zorbax SB-C18 column, employing an acetonitrile/water gradient at a flow rate of 0.4 ml/min, with the column oven maintained at room temperature. The gradient elution program commenced with an initial mobile phase of 60:40 (v/v) acetonitrile to water, transitioning linearly to 100% acetonitrile over 14 minutes, followed by a return to the initial phase (60:40) after 5 minutes. The total duration for each analysis was 35 minutes. For the negative control, an assay was conducted using denatured enzymes, achieved by heating the enzymes at 95°C for 10 minutes. Peaks were analyzed at 270nm absorbance.

Results

Initial activity assays were performed solely with pdoA2 and pdoB2 to form a dimer, thereby validating their enzymatic activity and evaluating their aggregation characteristics. Monomers were incubated together for aggregation in the presence and absence of NADH to determine whether NADH, as a cofactor, influences the aggregation process.

The efficacy of the reaction was assessed by measuring the absorbance of phenanthrene-4-carboxylate (P4C) and NADH using HPLC. The area under the resulting peaks corresponding to the levels of P4C and NADH was determined, enabling a comparative analysis of the consumption of P4C and NADH against established standards and between the samples. In this context, phenanthrene-4-carboxylate consumption refers to the extent of P4C degradation, as indicated by a reduction in peak area compared to the standard. In the absence of additional samples with different concentrations, it is not possible to quantify the remaining P4C in the samples. The only conclusion that can be drawn is whether P4C has been degraded, as evidenced by the decrease in the area of the corresponding peak; this applies also to NADH.

Furthermore, to eliminate potential statistical errors in the assessment of our results, we employed triplicate measurements for each sample and calculated their averages. The results are presented in Figure 5. Results indicated that the assays in which NADH was added prior to aggregation exhibited enhanced P4C degradation and, correspondingly, increased NADH consumption compared to the assays where NADH was added after aggregation. However, the observed NADH consumption was relatively low, which may be attributed to the absence of the electron carrier dimer (phtAcAd) in the sample, thereby limiting NADH consumption.


Figure 5: Comparative Analysis of phenanthrene-4-carboxylate (P4C) and NADH Consumption in pdoA2:pdoB2 activity assays.
The degradation of P4C by pdoA2:pdoB2 was monitored for 30 min at a constant substrate and enzyme concentration. The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 25 µM P4C, 1 µM pdoA2 and 1 µM pdoB2. The 100 µM NADH were either added after or before aggregation.

Considering the initial results, the analysis of the tetramer aggregation process and the degradation of phenanthrene-4-carboxylat was conducted by introducing NADH prior to the aggregation process.

Degradation of phenanthrene-4-carboxylat by enzyme complex with dioxygenase activity using NADH as a cofactor

The presence of the functional enzyme complex with dioxygenase activity is anticipated to result in a reduction in the quantity of phenanthrene-4-carboxylate. This reduction can be quantified by determining the decrease in the area of the corresponding peak in comparison to the standard. Given the unknown stoichiometry of this enzyme complex, we conducted assays utilizing two distinct stoichiometric ratios. The first assay employed a 1:1 stoichiometry of all monomers, while the second utilized a ratio of pdoA21:pdoB21:phtAc3:phtAd1. This latter stoichiometry was selected based on previous kinetic analyses of phtAc, which were performed with a ratio of three phtAc molecules to one phtAd for determining kinetic parameters. [3] This ratio was employed in the present assays to assess its influence on the degradation of phenanthrene-4-carboxylate and to determine whether the presence of three equivalents phtAc enhanced the efficiency of the electron transfer process, thereby accelerating the breakdown of phenanthrene-4-carboxylate. However, results showed (see Figure 6) that the breakdown of phenanthrene-4-carboxylat was slightly more efficient with the 1:1 ratio of the monomers; this could suggest that a higher ratio of phtAc does not enhance the electron transfer process. And that the complex with 1:1 ratio of all enzymes aggregates better.

To confirm the aggregation of the enzyme complex and the successful degradation of P4C by this complex, negative controls were prepared. For this, assays were prepared with denatured enzymes with the stoichiometries described above. Results showed (see Figure 6) that the peak area of P4C within these assays was higher in comparison with the assays with the active enzyme complex. The comparison of these results indicates that the enzyme complex was successfully formed and demonstrated the capacity to degrade P4C.


Figure 6: Comparative Analysis of phenanthrene-4-carboxylate (P4C) and NADH Consumption in pdoA2:pdoB2:phtAc:phtAd activity assays.
The degradation of P4C by the enzyme complex was monitored for 30 min at a constant substrate and enzyme concentration. The reaction mixture contained 100 mM Tris/HCl (pH 7.5), 200 µM NADH, 40 µM P4C, 1 µM pdoA2, 1 µM pdoB2, 1 or 3 µM and 1 µM phtAd.

Another negative control was conducted by excluding any enzymes from the assay. In comparison to samples containing denatured enzymes, the results showed a reduced peak area in the peak corresponding to phenanthrene-4-carboxylate, suggesting either a diminished quantity of P4C in the sample or its degradation. However, the possibility of cross-reactivity with other components in the assay can be discounted, as such interactions would also manifest in the other negative controls. This observation indicates the presence of an independent source of error. Potential issues may involve the unintentional introduction of enzymes or inadequate substrate concentration. The presence of enzymes in the assay can be corroborated by taking into consideration the amount of NADH; notably, the peak area of NADH in this sample was diminished suggesting the possibility that a reaction has taken place, and the results are more consistent with those obtained from the assay conducted with a 1:3 enzyme ratio (see Figure 6). While numerous errors could have arisen, a systematic issue such as cross-reactivity, which would render the enzyme ineffective, can be dismissed by comparing the sample to those with non-functional enzymes.

Moreover, as anticipated, the samples containing the active enzyme complex demonstrated a decrease in the peak area associated with NADH relative to the standard (see Figure 6). This finding corroborates the functionality of the electron carrier dimer, which collaborates with pdoA2B2 in the degradation of P4C. In contrast, the assay involving denatured enzymes at a 1:1 ratio revealed no consumption of NADH, indicating the absence of any reaction.

However, the results of NADH consumption from the assay involving denatured enzymes, utilizing three equivalents of phtAc in conjunction with a 1:1 ratio of the other enzymes, demonstrate a reduction in NADH consumption, as evidenced by the diminished area of the corresponding peak relative to the standard. This observation indicates the presence of an independent source of error, as the other assay performed with denatured enzymes shows no NADH consumption. Potential issues may include insufficient NADH concentration. If the NADH concentration was low, degradation could have occurred over time, as the activity assays were conducted days prior to the HPLC analysis. The thawing process and exposure of the sample to temperature fluctuations may have contributed to NADH degradation due to its inherent instability. Additionally, the possibility of incomplete denaturation should be considered. If the enzymes were not fully denatured during the assay, residual active enzyme could remain, resulting in NADH consumption. The denaturation conditions may not have been adequate to completely inactivate the enzymes. This is further supported by the observation that P4C consumption was slightly lower in comparison to the sample with denatured enzymes with the 1:1 ratio.

Conclusion

In conclusion, the enzyme complex with dioxygenase activity demonstrated its ability to degrade phenanthrene-4-carboxylate (P4C), with slightly greater efficiency observed in the assay utilizing a 1:1 ratio of monomers compared to the 1:3 ratio of phtAc to pdoA2:pdoB2:phtAd. This suggests that a higher ratio of phtAc does not enhance electron transfer efficiency. Negative controls, including assays with denatured enzymes and no enzymes, confirmed that the active enzyme complex was responsible for P4C degradation, while the reduction in NADH in some denatured enzyme assays points to possible errors, such as NADH degradation or incomplete enzyme denaturation. Further assays with stricter controls are needed to confirm these findings and minimize potential sources of error.


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]

References

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[2] S.-J. Kim, O. Kweon, R. C. Jones, J. P. Freeman, R. D. Edmondson, and C. E. Cerniglia, "Complete and integrated pyrene degradation pathway in Mycobacterium vanbaalenii PYR-1 based on systems biology," Journal of bacteriology, vol. 189, no. 2, pp. 464–472, 2007, doi: 10.1128/JB.01310-06.
[3] Y. Wu, Y. Xu, and N. Zhou, "A newly defined dioxygenase system from Mycobacterium vanbaalenii PYR-1 endowed with an enhanced activity of dihydroxylation of high-molecular-weight polyaromatic hydrocarbons," Front. Environ. Sci. Eng., vol. 14, no. 1, 2020, doi: 10.1007/s11783-019-1193-5.
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[5] K. Yuan et al., "Transcriptional response of Mycobacterium sp. strain A1-PYR to multiple polycyclic aromatic hydrocarbon contaminations," Environmental pollution (Barking, Essex : 1987), vol. 243, Pt B, pp. 824–832, 2018, doi: 10.1016/j.envpol.2018.09.001.
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[7] M. M. Bradford, "A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding," Analytical biochemistry, vol. 72, pp. 248–254, 1976, doi: 10.1006/abio.1976.9999.