Team:Bielefeld-Germany/Results/Summary

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Results

Summary

Cultivation and Purification of the different laccases

During our research we cultivated the following BioBricks and produced several laccase. To simplify the presentation of our results we named the produced laccase like the following system

Produced and generated BioBricks with the source strain of the DNA-sequence, promoter, protein name and the names given by the iGEM Team Bielefeld
BioBrick code strain promoter name of protein name given by the iGEM Team
<partinfo>K863000</partinfo> Bacillus pumilus DSM 27 T7 promoter CotA BPUL
<partinfo>K863005</partinfo> E. coli BL21(DE3) T7 promoter CueO ECOL
<partinfo>K863010</partinfo> Thermus thermophilus HB27 T7 promoter tthL TTHL
<partinfo>K863012</partinfo> Thermus thermophilus constitutive promoter (<partinfo>BBa_J23100</partinfo>) tthL TTHL
<partinfo>K863015</partinfo> Xanthomonas campestris pv. campestris B100' T7 CopA XCCL
<partinfo>K863020</partinfo> Bacillus halodurans C-125 T7 Lbh1 BHAL
<partinfo>K863022</partinfo> Bacillus halodurans C-125 constitutive promoter (<partinfo>BBa_J23100</partinfo>) Lbh1 BHAL


All BioBricks of the iGEM Team Bielefeld were screened to identify the best conditions for protein expression. The first trials were made by shaking flask cultivations with different parameters. These parameters were various shaking flask designs , different temperatures, different concentrations of chloramphenicol, various induction strategies , several cultivation times and some cultivations in absence or presence of CuCl2. To detect the produced laccases different analysis methods were performed like SDS-PAGE analysis as well as MALDI-TOF.

Purification

To prove the activity of the produced laccases we used a Immobilized Metallion affinity chromatography to purify our laccases. The purification of the laccases were made by a syringe system or a column system including a Ni-NTA resin. The following picture illustrate a typical chromatogram of the purification procedure.

Illustration of a typical chromatogram of the produced laccases: 1. equilibration, 2. sample loading, 3. wash step, 4. elution (linear elution gradient), 5. column regeneration

Due to the high UV-detection signal of the loaded samples and to simplify the illustration of the detected product peak only the UV-detection signal of the wash step and the elution are shown.


After measuring activity a scale up to 3 L as well as up to 6 L.




Datapage


How our system works

Data for our favorite new parts

  1. <partinfo>K863000</partinfo> - bpul (laccase from Bacillus pumilus) with T7 promoter, RBS and HIS tag:
  2. <partinfo>K863005</partinfo> - ecol (laccase from E. coli) with T7 promoter, RBS and HIS tag:

Data for pre-existing parts

We have also characterized the following parts

  1. <partinfo>BBa_K863012</partinfo> - tthl laccase ( from T. thermophilus) with constitutive promoter J23100, RBS and HIS tag:
  2. <partinfo>BBa_K863022</partinfo> - bhal laccase (from Bacillus halodurans) with constitutive promoter J23100, RBS and HIS tag:

Laccase from Bacillus pumilus DSM 27 (ATCC7061)

First some trials of shaking flask cultivations were made with different parameters to define the best conditions for the production of the His-tagged CotA aus Bacillus pumilus DSM 27 (ATCC7061) named BPUL. Because of no activity in the cell lysate a purification method was established (using Ni-NTA-Histag resin). The purified BPUL could be detected by SDS-PAGE (molecular weight of 58.6 kDa) as well as MALDI-TOF. To improve the purification strategies the length of the elution gradient was increased. The fractionated samples were also tested concerning their activity. A maximal activity of X was reached. After measuring activity of BPUL a scale up was made up to 3 L and also up to 6 L.


Shaking Flask Cultivation

The first trials to produce the CotA-laccase from Bacillus pumilus DSM 27 (ATCC7061, named BPUL) were performed in shaking flasks with various designs (from 100 mL-1 to 1 L flasks, with and without baffles) and under different conditions. The parameters we have changed during our screening experiments were temperature (27 °C,30 °C and 37 °C), different concentrations of chloramphenicol (20 to 170 µg mL-1), induction strategies (autoinduction and manual induction with 0,1 % rhamnose) and cultivation time (6 - 24 h). Further we cultivated with and without 0,25 mM Cu2Cl, to provide a sufficient amount of copper, which is needed for the active center of the laccase. Due to the screening experiments we identified the best conditions for expression of BPUL (see below). The addition of Cu2Cl did not lead to better results, so it was omitted.

  • flask design: shaking flask without baffles
  • medium: autoinduction medium
  • antibiotics: 60 µg mL-1 chloramphenicol
  • temperature: 37 °C
  • cultivation time: 12 h

The reproducibility and repeatability of the measured data and results were investigated for the shaking flask and bioreactor cultivation.

3 L Fermentation E. coli KRX with <partinfo>BBa_K863000</partinfo>

Figure 1: Fermentation of E. coli KRX with <partinfo>BBa_K863000</partinfo> (BPUL) in Braun Biostat B, scale: 3 L, autoinduction medium + 60 µg/mL chloramphenicol, 37 °C, pH 7, agitation on cascade to hold a pO2 of 50 %, OD600 measured every 30 minutes.

After the measurement of BPUL activity we made a scale-up and fermented E. coli KRX with <partinfo>BBa_K863000</partinfo> in Braun Biostat B with a total volume of 3 L. Agitation speed, pO2 and OD600 were determined and illustrated in Figure 1. We got a long lag phase of 2 hours due to a relatively old preculture. The cell growth caused a decrease in pO2 and after 3 hours the value fell below 50 %, so that the agitation speed increased automatically. After 8.5 hours the deceleration phase started and therefore the agitation speed was decreased. The maximal OD600 of 3.53 was reached after 10 hours, which means a decrease in comparison to the fermentation of E. coli KRX under the same conditions (OD600,max =4.86 after 8.5 hours, time shift due to long lag phase). The cells were harvested after 11 hours.


Purification of BPUL

The harvested cells were resuspended in Ni-NTA-equilibrationbuffer, mechanically lysed by homogenization and centrifuged. The supernatant of the lysed cell paste was loaded on the Ni-NTA-column (15 mL Ni-NTA resin) with a flowrate of 1 mL min-1 cm-2. The column was washed with 10 column volumes (CV) Ni-NTA-equilibrationbuffer. The bound proteins were eluted by an increasing Ni-NTA-elutionbuffer gradient from 0 % to 100 % with a total volume of 100 mL and the elution was collected in 10 mL fractions. Due to the high UV-detection signal of the loaded samples and to simplify the illustration of the detected product peak only the UV-detection signal of the wash step and the elution are shown. A typical chromatogram of purified laccases is illustrated here. The chromatogram of the BPUL-elution is shown in figure 2:


Figure 2: Chromatogram of wash and elution from FLPC Ni-NTA-Histag purification of BPUL produced by 3 L fermentation of E. coli KRX with <partinfo>BBa_K863000</partinfo>. BPUL was eluted between a process volume of 460 mL to 480 mL with a maximal UV-detection signal of 69 mAU

The chromatogram shows a remarkable widespread peak between the process volume of 460 mL to 480 mL with the highest UV-detection signal of 69 mAU, which can be explained by the elution of bound proteins. The corresponding fractions were analyzed by SDS-PAGE analysis. Afterwards the UV-signal increased caused by the changing imidazol concentration during the elution gradient. Between the process volume of 550 and 580 mL there are several peaks (up to a UV-detection-signal of 980 mAU) detectable. These results are caused by an accidental detachment in front of the UV-detector. Just to be on the safe side, the corresponding fractions were analyzed by SDS-PAGE analysis. The results of the SDS-PAGE are shown in the following pictures.


SDS-PAGES of purified BPUL

Figure 3: SDS-Pages of purified E. coli KRX containing <partinfo>BBa_K863000</partinfo> lysate (fermented in 3 L Biostat Braun B). The flow-through, wash and the elution fractions 7 and 8 are shown. The arrow marks the BPUL band with a molecular weight of 58.6 kDa.

Figure 3 shows the purified E. coli KRX with <partinfo>BBa_K863000</partinfo> lysates (fermented in 3 L Braun Biostat B) including flow-through, wash and the elution fractions 7 and 8. These two fractions were chosen due to a remarkable peak in the chromatogram. BPUL has a molecular weight of 58.6 kDA and was marked with a red arrow. The band appears in both fractions. There are also some other non-specific bands, which could not be identified. To improve the purification the elution gradient length should be longer and slower the next time.

The appearing bands were analysed by MALDI-TOF and could be identified as CotA (BPUL).

6 L Fermentation of E. coli KRX with <partinfo>BBa_K863000</partinfo>

Figure 4: Fermentation of E. coli KRX with <partinfo>BBa_K863000</partinfo> (BPUL) in Bioengineering NFL22, scale: 6 L, autoinduction medium + 60 µg/mL chloramphenicol, 37 °C, pH 7, agitation increased when pO2 was below 30 %, OD600 measured every hour.

Another scale-up for E. coli KRX with <partinfo>BBa_K863000</partinfo> was made up to a final working volume of 6 L in a Bioengineering NFL22. Agitation speed, pO2 and OD600 were determined and illustrated in Figure 3. There was no noticeable lag phase. Agitation speed was increased up to 425 rpm after one hour due to problems caused by the control panel. The pO2 decreased until a cultivation time of 4.75 hours. The increasing pO2-Level indicates the beginning of the deceleration phase. There is no visible break in cell growth caused by an induction of protein expression. A maximal OD600 of 3.68 was reached after 8 hours of cultivation, which is similar to the 3 L fermentation (OD600 = 3.58 after 10 hours, time shift due to long lag phase). The cells were harvested after 12 hours.


Purification of BPUL

The harvested cells were prepared in Ni-NTA-equilibrationbuffer, mechanically lysed by homogenization and centrifuged. The supernatant of the lysed cell paste was loaded on the Ni-NTA-column (15 mL Ni-NTA resin) with a flowrate of 1 mL min-1 cm-2. The column was washed with 5 column volumes (CV) Ni-NTA-equilibrationbuffer. The bound proteins were eluted by an increasing elutionbuffer gradient from 0 % (equates to 20 mM imidazol) to 100 % (equates to 500 mM imidazol) with a length of 200 mL. This strategy was chosen to improve the purification by a slower increase of Ni-NTA-elutionbuffer concentration. The elution was collected in 10 mL fractions.Due to the high UV-detection signal of the loaded samples and to simplify the illustration of the detected product peak only the UV-detection signal of the wash step and the elution are shown. A typical chromatogram of purified laccases is illustrated here. The chromatogram of the BPUL-elution is shown in figure 5.


Figure 5: Chromatogram of wash and elution from FLPC Ni-NTA-Histag Purification of BPUL produced by 6 L fermentation of E. coli KRX with <partinfo>BBa_K863000</partinfo>. BPUL was eluted between a process volume of 832 mL and 900 mL with a maximal UV-detection signal of 115 mAU.

The chromatogram shows a peak at the beginning of the elution. This can be explained by pressure fluctuations upon starting the elution procedure. Between a process volume of 832 mL and 900 mL there is remarkable widespread peak with a UV-detection signal of 115 mAU. This peak corresponds to an elution of bound proteins at a Ni-NTA-elutionbuffer concentration between 10 % and 20 % (equates to 50-100 mM imidazol) . The corresponding fractions were analyzed by SDS-PAGE. The ensuing upwards trend of the UV-signal is caused by the increasing imidazol concentration during the elution gradient. Towards the end of the elution procedure there is a constant UV-detection signal, which shows, that most of the bound proteins was already eluted. Just to be on the safe side, all fractions were analyzed by SDS-PAGE to detect BPUL. The results of the SDS-PAGE are shown in the following pictures.


SDS-PAGES of purified BPUL

Figure 7: SDS-PAGE of purified E. coli with <partinfo>BBa_K863000</partinfo> lysate (fermented in Bioengineering, 6 L). The flow-through, wash and elution fraction 1 to 9 are shown. The arrow marks the BPUL band with a molecular weight of 58.6 kDa.

In figure 7 the SDS-PAGE of the Ni-NTA-Histag purification of the lysed culture of E. coli KRX containing <partinfo>BBa_K863000</partinfo> is illustrated. It shows the flow-through, wash and elution fractions 1 to 9. BPUL has a molecular weight of 58.6 kDA and was marked with a red arrow. The band appears in all fractions from 2 to 9 with varying strength, the strongest ones in fractions 7 to 9. There are also some other non-specific bands, which could not be identified. Therefore the purification method could moreover be improved.

Furthermore the bands were analysed by MALDI-TOF and identified as CotA (BPUL).

Laccase from Escherichia coli BL21 (DE3)

First some trails of shaking flask cultivations were made with changing parameters to identify the best conditions for the production of the laccase ECOL fused to a Histag. Because of no activity in the cell lysate a purification method was established (using Ni-NTA-Histag resin). The purified ECOL could be identified by SDS-PAGE (molecular weight of 53,4 kDa) as well as MALDI-TOF. The fractionated samples were also tested concerning their activity. A maximal activity of X was reached. After measuring activity of ECOL a scale up was made up to 3 L and then also up to 6 L.


Shaking Flask Cultivations

The first trails to produce ECOL were produced in shaking flask with various designs (from 100 mL-1 to 1 L flasks, with and without baffles) and under different conditions. The parameters we have changed during our screening experiments were the temperature (27 °C,30 °C and 37 °C), different concentrations of chloramphenicol (20-170 µg mL-1), various induction strategies ([autoinduction autoinduction and manual induction), several cultivation times (6 - 24 h) and in absence or presence of 0.25 mM Cu2Cl. Due to the screening experiments we identified the best conditions under which ECOL was expressed:

  • flask design: shaking flask without baffles
  • medium: autoinduction medium
  • antibiotics: 60 µg mL-1 chloramphenicol
  • temperature: 37 °C
  • cultivation time: 12 h

The reproducibility and repeatability of the measured data and results were investigated for the shaking flask and bioreactor cultivation with n ≤ 3.

3 L Fermentation E. coli KRX with <partinfo>BBa_K863005</partinfo>

Figure 1: Fermentation of E. coli KRX with <partinfo>BBa_K863005</partinfo> (ECOL) in Infors Labfors Bioreactor, scale: 3 L, autoinduction medium + 60 µg/mL chloramphenicol, 37 °C, pH 7, agitation on cascade to hold a pO2 of 50 %, OD600 taken every 30 minutes.

After the measurement of activity of ECOL we made a scale-up and fermented E. coli KRX with <partinfo>BBa_K863005</partinfo> in Infors Labfors with a total volume of 3 L. Agitation speed, pO2 and OD600 were determined and illustrated in Figure 1. The exponential phase started after 1.5 hours of cultivation. The cell growth caused a decrease in pO2. After 2 hours of cultivation the agitation speed increased up to 629 rmp (5.9 hours) to hold the minimal pO2 level of 50 %. Then, after 4 hours there was a break in cell growth due to induction of protein expression. The maximal OD600 of 2.78 was reached after 5 hours. In comparison to E. coli KRX (OD600,max =4.86 after 8.5 hours) and to E. coli KRX with <partinfo>BBa_K863000</partinfo> (OD600,max =3.53 after 10 hours, time shift due to long lag phase) the OD600 max is lower. In the following hours, the OD600,max and the agitation speed decreased and the pO2 increased, which indicates the death phase of the cells. This is caused by the celltoxicity of ECOL (reference: DBU final report). Therefore they were harvested after 12 hours.



Purification of ECOL

The harvested cells were resuspended in Ni-NTA-equilibrationbuffer, mechanically lysed by homogenization and centrifuged. The supernatant of the lysed cell paste was loaded on the Ni-NTA-column (15 mL Ni-NTA resin) with a flowrate of 1 mL min-1 cm-2. Then the column was washed by 10 column volumes (CV) with Ni-NTA-equilibrationbuffer. The bound proteins were eluted by an increasing Ni-NTA-elutionbuffer step elution from 5 % (equates to 25 mM imidazol) with a length of 60 mL, to 50 % (equates to 250 mM Imidazol) with a length of 60 mL, to 80 % (equates to 400 mM imidazol) with a length of 40 mL and finally to 100 % (equates to 500 mM imidazol) with a length of 80 mL. This strategies was chosen to improve the purification caused by a step by step increasing Ni-NTA-elutionbuffer concentration. The elution was collected in 10 mL fractions. Due to the high UV-detection signal of the loaded samples and to simplify the illustration of the detected product peak only the UV-detection signal of the wash step and the elution are shown. A typical chromatogram of purified laccases is illustrated here.The chromatogram of the ECOL-elution is shown in figure 2:

Figure 2: Chromatogram of wash and elution from FLPC Ni-NTA-Histag Purification of ECOL produced by 3 L fermentation of E. coli KRX with <partinfo>BBa_K863005</partinfo>. ECOL was eluted by a concentration of 50 % (equates to 250 mM imidazol) with a maximal UV-detection signal of 292 mAU.

The chromatogram shows two remarkable peaks. The first peak was detected by a Ni-NTA-equilibrationbuffer concentration of 5 % (equates to 25 mM imidazol) and resulted from the elution of weakly bound proteins. After increasing the Ni-NTA-elutionbuffer concentration to 50 % (equates to 250 mM imidazol) a peak up to a UV-detection signal of 292 mAU was measured. The area of this peak indicates that a high amount of protein was eluted. The corresponding fractions were analysed by SDS-PAGE analysis to detect ECOL. There were no further peaks detectable. The following increasing UV-dectection-signals equates to the imidazol concentration of the Ni-NTA-elutionbuffer. The corresponding SDS-PAGES are shown in figure 3.


SDS-PAGE of ECOL purification

Figure 3: SDS-Pages of purified E. coli KRX containing BBa_K863005 lysate (fermented in 3 L Infors Labfors). The flow-through, wash and elution fraction 2-9 are shown. The arrow marks the ECOL band with a molecular weight of 53.4 kDa.

In figure 3 the SDS-PAGE of the Ni-NTA-Histag purification of the lysed culture ( E. coli KRX containing BBa_K863005) is illustrated including the flow-through and the fractions 2 to 9. The red arrow indicates the band of ECOL with a molecular weight of 53.4 kDa, which appears in all fractions. The strongest bands appear in fractions 6 and 7. Another small band with a lower molecular weight appears, but was not identified.

Furthermore the bands were analysed by MALDI-TOF and identified as CueO (ECOL).

6 L Fermentation E. coli KRX with <partinfo>BBa_K863005</partinfo>

Figure 4: Fermentation of E. coli KRX with <partinfo>BBa_K863005</partinfo> (ECOL) in Bioengineering NFL22, scale: 6 L, autoinduction medium + 60 µg/mL chloramphenicol, 37 °C, pH 7, agitation increased when pO2 was below 30 %, OD600 taken every hour.

Another scale-up of the fermentation of E. coli KRX with <partinfo>BBa_K863005</partinfo> was made up to a final working volume of 6 L in Bioengineering NFL 22. Agitation speed, pO2 and OD600 were determined and illustrated in Figure 3. There was no noticeable lag phase and the cells immediatly began to grow. The cells were in an exponential phase between 2 and 4 hours of cultivation, which results in a decrease of pO2 value and therefore in an increase of agitation speed. After 4 hours of cultivation the maximal OD600 of 2.76 was reached, which is comparable to the 3 L fermentation of E. coli KRX with <partinfo>BBa_K863005</partinfo>. Due to induction of protein expression there is a break in cell growth. The death phase started, which is indicated by an increasing pO2 and a decreasing OD600. This demonstrates the cytotoxity of the laccases for E. coli, which was reported by the DBU. In comparison to the fermentation of E. coli KRX with <partinfo>BBa_K863000</partinfo> under the same conditions (OD600,max= 3.53), the OD600,max was lower. Cells were harvested after 12 hours.


Purification of ECOL

The harvested cells were resuspended in Ni-NTA-equilibrationbuffer, mechanically lysed by homogenization and centrifuged. The supernatant of the lysed cell paste was loaded on the Ni-NTA-column (15 mL Ni-NTA resin) with a flowrate of 1 mL min-1 cm-2. The column was washed by 10 column volumes (CV) with Ni-NTA-equilibrationbuffer. The bound proteins were eluted by an increasing Ni-NTA-elutionbuffer gradient from 0 % to 100 % with a length of 200 mL and the elution was collected in 10 mL fractions.Due to the high UV-detection signal of the loaded samples and to simplify the illustration of the detected product peak only the UV-detection signal of the wash step and the elution are shown. A typical chromatogram of purified laccases is illustrated here. The chromatogram of the ECOL-elution is shown in figure 4:

Figure 5: Chromatogram of wash and elution from FLPC Ni-NTA-Histag purification of ECOL produced by 3 L fermentation of E. coli KRX with <partinfo>BBa_K863005</partinfo>. ECOL was eluted between a process volume 670 mL to 750 mL with a maximal UV-detection signal of 189 mAU.


After washing the column with 10 CV Ni-NTA-elutionbuffer the elution process was started. At a process volume of 670 mL to 750 mL the chromatogram shows a remarkable widespread peak (UV-detection signal 189 mAU) caused by the elution of a high amount of proteins. The run of the curve show a fronting. This can be explained by the elution of weakly bound proteins, which elutes at low imidazol concentrations. A better result could be achieved with a step elution strategy (see purification of the 3 L Fermentation above). To detect ECOL the corresponding fractions were analysed by SDS-PAGE analysis.


SDS-PAGES of ECOL purification

Figure 6: SDS-Pages of lysed culture of E. coli KRX containing BBa_K863005 (fermented in 6 L Bioengineering NFL22) after purification. The flow-through, wash and elution fraction 1-15 are shown (except from fraction 11/12). The arrow marks the ECOL band with a molecular weight of 53.4 kDa.


In figure 6 the result of thnbsp;vonbsp;volumes (CV) Ni-NTA-equilibrationbuffer. The bound proteins were eluted by an increasing elutionbuffer gradient from 0nbsp;h

The reproducibility and repeatability of the measured data and results were investigated for the shaking flask and bioreactor cultivation with n ≤ 3.

==3lumes (CV) Ni-NTA-equilibrationbuffer. The bound proteins were eluted by an increasing elutionbuffer gradient from 0nbsp;h

The reproducibility and repeatability of the measured data and results were investigated for the shaking flask and bioreactor cultivation with n ≤ 3.

==3sub>600e Ni-NTA-Histag purification of the lysed culture E. coli KRX containing BBa_K863005 (6 L fermentation) including the flow-through, wash and the fractions 1 to 15 (except from fraction 11/12) are shown. The red arrow indicates the band of ECOL with a molecular weight of 53.4 kDa, which appears in all fractions. The strongest bands appear from fractions 3 and 8 with a decreasing amount of other non-specific bands.

Furthermore the bands were analysed by MALDI-TOF and identified as CueO (ECOL).

Laccase from Thermus thermophilus HB27

First some trails of shaking flask cultivations were made with different parameters to define the best conditions for the production of the His-tagged TTHL. Because of no activity in the cell lysate a purification method was established (using Ni-NTA-Histag resin). The purified TTHL could not be detected by SDS-PAGE (theoretical molecular weight of 53 kDa) by using the '' E. coli'' KRX as expression system. Due to this results we decided to change the expression to ''E. coli'' Rossetta-Gami 2. With this expression system the TTHL could be detected by SDS-PAGE as well as MALDI-TOF analysis. To prove the activity of the produced laccase we used a small scale Ni-NTA-column to purify our laccase. The fractionated samples were also tested concerning their activity. A maximal activity of X was reached. After measuring activity of TTHL a scale up was made up to 6 L


Shaking Flask Cultivation

The first trials to produce the Thermo thermophilus-laccase (Ltth) called TTHL were produced in shaking flask with various designs (from 100 mL-1 to 1 L flasks, with and without baffles) and under different conditions. The parameters we have changed during our screening experiments were the temperature (27 °C,30 °C and 37 °C), different concentrations of chloramphenicol (20-170 µg mL-1), various induction strategies (autoinduction and manual induction), several cultivation times (6 - 24 h) and in absence or presence of 0,25 mM CuCl2. Due to the screening experiments we wasn't able to detect the best conditions for the production with the E. coli KRX chassi. Due to the failed screening results we decided to produce the TTHL in an other E. coli strain called E. coli Rosetta-Gami 2 containing <partinfo>BBa_K863012</partinfo>. We decided to use E. coli Rosetta-Gami 2 becaus of his skill to translate rare codons. We produced our TTHL with the following conditions:

  • flask design: shaking flask without baffles
  • medium: LB-Medium
  • antibiotics: 60 µg mL-1 chloramphenicol and 300 µg mL-1 ampicillin
  • temperature: 37 °C
  • cultivation time: 24 h

The reproducibility and repeatability of the measured data and results were investigated for the shaking flask and bioreactor cultivation with n≤3.

The Results of the SDS-PAGE analysis are shown in the following images:

SDS PAGES!!!!!


ACTIVITÄTSMESSUNGEN VOM ERSTEN AKTIVEN B PUMI!!!!!!

Fermentation of E. coli KRX with <partinfo>BBa_K863012</partinfo>

After measuring activity of TTHL we made a scale-up and fermented E. coli Rosetta-Gami 2 with <partinfo>BBa_K863000</partinfo> in Bioengineering NFL22 with a total volume of 6 L. Agitation speed, pO2 and OD600 were determined and illustrated in Figure 1. The cells immediatly began to grow and therefore the pO2 decreased up to a value of 0 %, because the breakdown of the control unit. After a cultivation time of 9 hours the agitation speed was increased up to a 500 rpm, which resulted in a pO2 value of more than 100 % for the rest of the cultivation. During the whole process the OD600 increased slowly in comparison to the fermentation of E. coli KRX with <partinfo>BBa_K863000</partinfo> or <partinfo>BBa_K863005</partinfo>. The maximal OD600 was reached after 19 hours of cultivation, when the cells were harvested.

Figure 1: Fermentation of E. coli Rosetta-Gami 2 with <partinfo>BBa_K863012</partinfo> (TTHL) in Bioengineering NFL22, scale: 6 L, autoinduction medium + 60 µg/mL chloramphenicol, 37 °C, pH 7, agitation increased when pO2 was below 30 %, OD600 taken every hour.



Purification of TTHL

The cells were harvested and resuspended in Ni-NTA-equilibrationbuffer, mechanically lysed by homogenization and centrifuged. After preparing the cell paste we did not have the possibility to purificate the TTHL with the 15 mL. To detect and to analyse our produced TTHL we implement a small scale purification of 6 mL of the supernatant with a 1 mL Ni-NTA-column. The results of the SDS-PAGE analysis are shown the following images:

SDS-PAGE of purification TTHL

Laccase from Bacillus halodurans C-125

First some trails of shaking flask cultivations were made with various parameters to identify the best conditions for the production of the His-tagged BHAL. Because of no activity in the cell lysate a purification method was established (using Ni-NTA-Histag resin). The BHAL could not be detected by SDS-PAGE (theoretical molecular weight of 56 kDa) by using the '' E. coli'' KRX as expression system. Due to this results we decided to change the expression to ''E. coli'' Rossetta-Gami 2. With this expression system the BHAL could be found by SDS-PAGE as well as MALDI-TOF analysis. To prove the activity of the produced laccase we used a small scale Ni-NTA-column to purify our laccase. The fractionated samples were also tested concerning their activity. A maximal activity of X was reached. A scale up could not be implemented yet.

Laccase from Trametes versicolor


TVEL0 Activity Tests

TVEL0 was characterized in terms of its activity to establish activity test protocols and to create a standard which can be used as a reference.

Immobilization

Subtrate Analytics


Dilutioin series

Figure 1.1:The detection range of ethinyl estradiol. Concentrations between 0.1 µg ml -1 and 3 µg ml -1 are detecable.

At first we mesured dilution series of all different substrates. While estradiol and ethinyl estradiol where easy to mesure, we didnt succed often with the estrone calibration curves. This was caused by its bad solubility. The retention time for estradiol is 5.8 minutes, for estrone 4.7 minutes and for ethinyl estradiol 5.2 minutes. For all estrogens we could use the same extinction and emmission values: Ex 230, Em 310.

The next substrate class where the analgesics. These three substrates have different optimal extinction and emission values. Additional difficulties occured with naproxene and ibuprofen. Instead of one single peak we found two for each substrate, and none of them correlated with the used concentration. With diclofenac we are still not sure which extinction and emmission values are to use. We found different values and aditionaly we analysed it with a spectrofluorometer but this has also shown no clear peak for diclofenac.

Three of the four PAH´s have the same extinction and emmission values. Simular to the estrogens, the PAH calibration curves are easy to generate. Naphthalene has a retention time of 9.6 minutes and its detection range ist also 0.1 till 2.5 µg*mL-1. Acenaphthene with a retention time of 15.1 minutes and phenantrene with a retention time of 17 minutes have maximal detectable concentration of 1.5 µg*mL-1.

Anthracene will be mesured later.


Negative controls

The results of our negative controls of the first Polycyclic aromatic hydrocarbon, PAH, degradations showed, that PAH´s decay without laccase with a high speed. So we take a closer look at the three PAH´s in Britton Robinson (BR)-buffer. The result can be seen in figure 2.1. After one hour most of the used substrates decayed.

Figure 2.1:The PAH´s naphthalene, acenaphthene and phenantrene in BR-buffer at 30 °C. The startconcentration was 1 µg mL -1 for all PAH´s. After 1 houre nearly all PAH´s decayed completely.

The next step was to check if and which substance cause the decay. In this test we dissolved naphthalene in acetonitrile and in methanol and compared the pure solvents with the influence of the BR-buffer and BR-buffer with ABTS. With pure methanol or acetonitrile naphthalene decays slow in comparison to BR-buffer. In BR-buffer with or without ABTS the decay happens faster and under nearly the same velocity. So BR-buffer seems to be a bad choice to test if our laccases degrade PAH´s.

Figure 2.2:Naphthalene decay in four different conditions. Dissolved in methanol, dissolved in acetonitrile, with BR-buffer and with BR-buffer together with ABTS


Degradation

Degradation reactions with ABTS showed the expected results. Team Activity test already showed, that the laccases have the ability to oxidise ABTS. The fact that oxidised ABTS react chemical with the substrates explains, that all of our active laccases have the ability to degrade ethinly estradiol and other substrates.

Figure 3.1:Comparison between two of our Laccases BPUL and ECOL with the purchased Laccase TVEL0 under ABTS influence.

The potential of the purchased laccase TVEL0 is much higher. TVEL0 degrades ethinyl estradiol without ABTS.

Figure 3.2:Purchased laccase TVEL0 degrades ethinyl estradiol. Estradiol in BR-buffer without laccase as negative control.

BPUL has not the same potential as the purchased laccase. But BPUL degrades estradiol without the influence of ABTS.

Figure 3.3:Our Laccases BPUL in unknown concentration degrades estradiol. Estradiol in BR-buffer without laccase as negative control.


Outlook

Anthracene, lindane and diclofenac are to be detected with the HPLC. Ibuprofen and naproxen need a good calibration curve. For naphthalene, acenaphthene and phenantrene we have to test different buffers or lower the temperature too keep ist more stable. We have only tested BPUL and ECOL, and there will be not only TTHL to test, bot also the trametis versicolor laccases TVEL5, TVEL10, TVEL13 and TVEL20. Additional we want to determine kcat/km for the degradable substances.

Cellulose binding domain


Introduction

In the field of cheap protein-extraction cellulose binding domains (CBD) have made themselfes a name. A lot of publications have been made, concerning a cheap strategy to capture a protein from the cell-lysate with a CBD-tag. Also enhanced segregation with CBD-tagged proteins have been observed. Here the idea is different, we want to take advantage of the binding capacity of binding domains not only for purification reasons (it is still a benefit), but also as an immobilizing-protocol for our laccases.

Figure 1:Graphical sequence-alignment of <partinfo>K392014</partinfo> and the Xyn10A gene of C.josui

To make a purification and immobilization-tag out of a protein domain, there are a lot of decisions and characterizations you have to get through.

Starting with the choice of the binding domain, the first limitation is accessibility. Our first place to look was, of course the Partsregistry. We found a promising Cellulose binding motif of the C. josui Xyn10A gene (<partinfo>BBa_K392014</partinfo>) there and ordered it right from the spot for our project. After some research later concerning the sequence of that BioBrick it turned out that the part is not the CBD of the Xylanase as it should be, but the glycosyl hydrolase domain of the protein (Figure 1). This result made the part useless for our project (complete review) and it was the only binding domain in the Partsregistry that fitted to our project.

So we started to search the accessible organisms we had via NCBI for binding-domains, -proteins and -motifs and asked in work-groups if they could help us out. The results of our database research were only two chitin/carbohydate binding modules within the Bacillus halodurans genome (we ordered that stain for it's laccase <partinfo>BBa_K863020</partinfo>). One is in the Cochin chitinase gene and the other in a chitin binding protein.

Figure 2: Plasmid-map of p714 with CBDcex; Origin: Fermentation group of Bielefeld University
Figure 3: Plasmid-map of p570 with CBDclos; Origin: Fermentation group of Bielefeld University

Meanwhile the Fermentation of our university group offered use two plasmids (p570 & p671), containing two different cellulose binding domains. The Cellulose binding domain of the Cellulomonas fimi ATCC 484 exoglucanase gene (CBDcex) and the Cellulose binding domain of Clostridium cellulovorans cellulose binding protein gene (cbp A) (CBDclos). At that point we decided to use these two domains. Staying within the cellulose binding domain-family and leave other protein domains like carbohydrate binding domains aside will keep the results comparable. Like changing to a different binding material would change the binding capacities of both domains in the same way. Also we would stay within bacterial CBD and didn't have to spend time thinking about post-translational modification and glycosylation.

To get to know more about these two domains, their properties and their proteins we consulted NCBI and used the BLAST-tool to identify the cellulose binding domains and ExPASy-tools for further measurements.

Figure 5: Crystal structure of the CBM_2-family

The CBD of the Cellulomonas fimi ATCC 484 exoglucanase gene (Figure 6) is a 100 amino acid long domain, close to the C-terminal ending of the protein with a theoretical pI of 8.07 and a molecular weight of 10.3 kDa. It is classified to be stable and belongs to the Cellulose Binding Modul family 2 (pfam00553/cl02709). This means two tryptophan residues are involved in cellulose binding, this type of CBD is only found in bacteria. Also a CBM49 Carbohydrate binding domain is found within the protein domain, where binding studies have shown, that it binds to crystalline cellulose, which could be a possible target for immobilization.

Figure 8: Crystal structure of the CBM_3-family

The CBD of the Clostridium cellulovorans cellulose binding protein gene (cbp A) on the other hand is a N-terminal domain with 92 amino acids, theoretical pI of 4.56 and ist also classified as stable. It belongs to the Cellulose Binding Modul family 3 (pfam00942/cl03026) and is part of a very large cellulose binding protein with four other carbohydrate binding moduls and a lot of docking interfaces for the proteins in its amino acid sequence (Figure 7).

The Binding Assay

Aequorea victoria green fluorescent protein in action

To measure the capacity and strength of the bonding between the cellulose binding domains and different types of cellulose many different assays have been made. One of the simplest and most often used is the fusion of the CBD to a reporter-protein, especially green or red fluorescent protein (GFP/RFP) is very common. The place of the CBD is measured through the fluorescence of the fused GFP and quantification can easily been done.

Protocol:

  • Harvest the E coli-cells producing the fusion-protein of CBD and GFP and centifuge 10 minutes at top speed.
  • Re-suspend the cell-pellet in 50 mM Tris-HCl-Buffer (pH 8.0).
  • Break down cells via sonication.
  • Centrifuge at top speed for 20 minutes to get rid of the cell-debris.
  • Take the supernatant and measure the emission at 511 nm (excitation at 501 nm) (<partinfo>E0040</partinfo>)
  • Mix a definite volume of lysate with a definite volume or mass of e.g. crystalline cellulose (CC) or reactivated amorphous cellulose (RAC)
  • Wait 15 (RAC) to 30 (CC) minutes
  • Take supernatant and measure the emission at 511 nm again.
  • The difference between the first an the second measurement is the relative quantity of what has bound to the cellulose.

Cloning of the Cellulose Binding Domains

The cloning of the CBDs should fit to the cloning of our laccases, so the BioBricks were designed with a T7-promoter and the B0034 RBS to have a similar method of cultivation. After investigating the restriction-sites it showed, that at least for the characterization of the CBDs a quick in-frame assembly of the CBDs and a GFP would be possible, because neither the CBDs nor the GFP (<partinfo>I13522</partinfo>) of the Partsregistry inherits a AgeI- or NgoMIV-site, which makes Freiburg-assembly possible. To do so, primers for the constructs <partinfo>BBa_K863101</partinfo> (CBDcex(T7)), carrying the CBDcex domain from the C. fimi exoglucanase and <partinfo>BBa_K863111</partinfo> (CBDclos(T7)), carrying the CBDclos domain from the C.cellulovorans binding protein were designed. The protein-BLAST of the two CBDs gave an exact picture of which bases belong to the binding domains and which don't. To be sure not to disturb the folding anyway 6 to 12 bases up and downstream of the domains as conserved sequences were kept. Even if the CBDcexis an C-terminal domain both domains were made N-terminal, so the BioBricks can carriy all regulatory parts and the linked protein can easily be exchanged. This also would be nice for other people using this part.

CBDcex_T7RBS 80 TGAATTCGCGGCCGCTTCTAGAGTAATACGACTCACTATAGGGAAAGAGGAGAAATAATGGGT
CCGGCCGGGTGCCAGGT
CBDcex_2AS-Link_compl 56 CTGCAGCGGCCGCTACTAGTATTAACCGGTGCTGCCGCCGACCGTGCAGGGCGTGC
CBDclos_T7RBS 73 CCGCTTCTAGAGTAATACGACTCACTATAGGGAAAGAGGAGAAATAATGTCAGTTGAATTTTACAACTCTAAC
CBDclos_2ASlink_compl 63 CTGCAGCGGCCGCTACTAGTATTAACCGGTGCTGCCTGCAAATCCAAATTCAACATATGTATC

The listed complementary primers added, besides the Freiburg-suffix, a two amino acid Glycine-Serine-linker to the end of the CBDs. This is a very short linker, but as GFP-experts and publications described GFP and CBDs are very stable proteins and should cope with a very short linker. The benefit of a short linker is that protease activity is kept minimal.

The GFP <partinfo>K863121</partinfo> we wanted to use for the assay was an alternated version of the <partinfo>BBa_I13522</partinfo>. We made primers that added a Freiburg-pre- and suffix to the GFP coding sequence and a His-tag to the C-terminus to get it purified for the measurements. This part <partinfo>BBa_K863121</partinfo> (GFP_His) should be easily added to the CBDs and assemble to the fusion-proteins <partinfo>BBa_K863103</partinfo> CBDcex(T7)+GFP_His] and <partinfo>BBa_K863113</partinfo> CBDclos(T7)+GFP_His]).

GFP_Frei 54 TACGGAATTCGCGGCCGCTTCTAGATGGCCGGCATGCGTAAAGGAGAAGAACTT
GFP_His6_compl 74 CTGCAGCGGCCGCTACTAGTATTAACCGGTGTGATGGTGATGGTGATGTTTGTATAGTTCATCCATGCCATGTG

Since we added a His-tag to the end of the GFP, we had to make an alternated version of the <partinfo>BBa_I13522</partinfo> to compare binding of GFP with and without CBD. Therefore we made a forward primer, to amplify the whole <partinfo>BBa_I13522</partinfo> and used the GFP_His_compl-primer to add the His-tag to the C-terminus.

GFP_FW_SV 39 acgtcacctgcgtgtagctCGTAAAGGAGAAGAACTTTT

Due to bad cleavage efficiency at the PstI restriction-site in nearly all PCR-products the cloning of the CBDs (CBDcex(T7) and CBDclos(T7))and especially the insertion of GFP_His to the CBDs took a lot more time as expected. This was because, while designing the primers, we missed to add additional base pairs from the cleavage-site to the termini to increase the efficiency to standard. When we got aware of the problem, cloning got a lot quicker and more successful.

As the project went on and the T7-constructs didn't seem to work one suspected reason was that a stop codon (TAA) that accidentally resulted between the RBS and ATG could be the reason for that. To solve the problem we started to change to a constitutive promoter (<partinfo>BBa_J61101</partinfo>) using the Freiburg-assembly. Therefore Freiburg forward primers for the CBDs were made.

CBDcex_Freiburg-Prefix 54 GCTAGAATTCGCGGCCGCTTCTAGATGGCCGGCGGTCCGGCCGGGTGCCAGGTG
CBDclos_Freiburg-Prefix 57 GCTAGAATTCGCGGCCGCTTCTAGATGGCCGGCTCATCAATGTCAGTTGAATTTTAC

The second advantage of these primers were, that the order of the fusion proteins could easily been changed, when a Freiburg suffix-primer for the GFP would be available, so we ordered that.

GFP_Freiburg_compl 61 ACGTCTGCAGCGGCCGCTACTAGTATTAACCGGTTTTGTATAGTTCATCCATGCCATGTGT
PCR-product of BBa_K863104 with S3N10-primers

Sadly the primers arrived just a few days before wiki freeze and we had no time to test that. The switching to the constitutive promoter had no obvious effect (no green colonies or culture). Changing the expression strain from E. coli KRX to E. coli BL21 didn't do a positive effect ether. Which led us to the conclusion, that besides further information the problem has to be the space in between the two proteins and the CBD and GFP must hamper each other from folding correctly. To test and solve this a very long linker with three serines followed by ten asparagines should be assembled in the already existing parts via a blunt end cloning. This also is right at hand, just wasn't successful in the time which was left.

S3N10_Cex_compl 40 TTGTTGTTGTTCGAGCTCGAGCCGACCGTGCAGGGCGTGC
S3N10_Clos_compl 40 TTGTTGTTGTTCGAGCTCGAGCTGCCGCCGACCGTGCAGG
S3N10_GFP 40 CAATAACAATAACAACAACCGTAAAGGAGAAGAACTTTTC

Literature

Kavoosi et al. (2007) Strategy for selecting and characterizing linker peptides for CBM9-tagged fusion proteins expressed in Escherichia coli. Biotechnol Bioeng. Oct 15;98(3):599-610. Urbanowicz et al. (2007) A tomato endo-beta-1,4-glucanase, SlCel9C1, represents a distinct subclass with a new family of carbohydrate binding modules (CBM49). J Biol Chem. Apr 20;282(16):12066-74. Epub 2007 Feb 23. Sugimoto et al. (2012) Cellulose affinity purification of fusion proteins tagged with fungal family 1 cellulose-binding domain. Protein Expr Purif. Apr;82(2):290-6. Epub 2012 Jan 28. Hong et al. (2008) Bioseparation of recombinant cellulose-binding module-proteins by affinity adsorption on an ultra-high-capacity cellulosic adsorbent. Anal Chim Acta. Jul 28;621(2):193-9. Epub 2008 May 27.


Shuttle vector

here is space for the summary

Description of the shuttle vector system

The design of a minimal shuttle vector system with defined regions (or better DNA fragments) for expression and secretion of proteins of interest (POI) like laccase which needed glycolisation is the basic concept. The shuttle vector needs a bacterial part for cloning in bacteria (like E. coli) and an eucaryotic part for genomic integration and selection in yeast (like P. pastoris). For other teams it is able to clone in frame their POI via the AarI restriction site. With only one restriction-ligation-cloning step the shuttle vector will be ready to use and integrate in the eucaryote P. pastoris.

The shuttle vector consists of the plasmid pSB1C3, 5' UTR of alcohol oxidase 1 gene (aox1), Kozak sequence, mating factor alpha 1 (MFalpha1), AarI restriction site, aox1 terminater, his4 gene and 3' UTR of aox1 gene. Cloning and plasmid replication in E. coli is able via the pSB1C3 part. The protein of interest (like laccase) can be included in frame with MFalpha1 via AarI restriction site. With the N-terminal MFalpha1 the POI could be secreted in the media. Genomic intregation of MFalpha1-taged POI is able via the 5' UTR and 3' UTR of the aox1 gene. This allows a double cross over and the genomic integration without any bacterial proportion of DNA which could be a decisive point for industrial application. The complementation of histidine auxotrophie via his4 gene is choosen instead of a zeocine resistance. This selection strategy is choosen because we want to avoid the application of antibiotics as many as possible.

Gibson assembly is used for building the shuttle vector and the fragments with 5' overlap were amplified via PCR. In addition, die fragments were designed as basic BioBrick parts for use. The origin of the DNA sequence for design of the shuttle vector and the source of DNA for PCR is listed in the table below.

Elements of the shuttle vector and their origin

Element Origin of DNA sequence of design Origin of DNA sequence of PCR
pSB1C3 pSB1C3 pSB1C3
5'UTR of aox1 plasmid pPICZalphaA (Invitrogen) P. pastoris wild type X-33
Kozak sequence BBa_J63003 integrated in primer sequence
MFalpha1 plasmid pPICZalphaA (Invitrogen) plasmid pPICZalphaA (Invitrogen)
aox1 terminater plasmid pPIC9K P. pastoris wild type X-33
his4 plasmid pPIC9K P. pastoris wild type X-33
3'UTR of aox1 plasmid pPIC9K P. pastoris wild type X-33


  • Kerngedanke + enzymatische Integration über Schnittstelle
  • Parts beschreiben plus Quelle, Link auf die Partsregistry
  • Methode
Plasmid map from shuttle vector pSB1C3::BBa_K863204.

Shuttle vector in E. coli

  • Testverdau
  • Seuenzierergebnisse
  • Wie sind die Unterschiede/Mutationen zu erklären?

Shuttle vector in P. pastoris

  • Bild von Platte
  • Testpcr: Untersuchung des Genotyps

GFP integrated in shuttle vector

  • Produkt fertig
  • nächste Schritte: Transformation in P. pastoris, Genotyp-characterisierung, Kultivierung, Fluoreszensmessung



Collaboration with UCL

The BioBrick BBa_K729002 from the University College London was characterized by us. Therefore E. coli KRX containing BBa_K729002 and E. coli KRX as negative were cultivated shaking flasks and a growth kinetics determined. The harvested cells were lysed via sonification and the supernatant was purified from substances with a low molecular weight. After purification it was analyzed by SDS-PAGE, activity assay as well as MALDI-TOF. A maximal activity of X was reached. For a comparison E. coli KRX containing BBa_K7863005 was cultivated and also analysed by SDS-PAGE and activity assay.


Introduction

Sequencing analysis

For the improvement of the data collection, the BioBrick of the University College London iGEM team was sequenced. The sequence analysis shows, that the

Cultivation

We transformed E. coli KRX with the BioBrick <partinfo>K729002</partinfo> of the iGEM team of University College of London (including the DNA sequence of a laccase). The transformed cells were used to characterize the BioBrick by using our methods for cultivation, cell disruption and activity determent . The E. coli KRX containing <partinfo>K729002</partinfo> was cultivated 50 mL for 12 h at 37°C (120 rpm) in 250 mL shaking flasks without baffles. To generate a higher amount of the protein, we cultivated 200 mL in a 1 L shaking flask without baffles. The OD600 values were determined every hour. To measure the influence of the transfered BioBrick on the growth of the cells, a negative control (E. coli KRX chassi)was cultivated identically . The Measured OD600 are shown in the following picture:

Figure 1:Comparison of the cultivated E. coli KRX and E. coli KRX containing <partinfo>K729002</partinfo> cultivations. The OD600 was determined every hour for 12  h

Like expected the E. coli KRX containing <partinfo>K729002</partinfo> showed a lower growth rates compared to the negative controll. This can be explained by the protein expression of the transformed E. coli KRX during the cultivation.

The cells were harvested after 12 h by centrifuging. The harvested cells were resuspended in 100mM Na-Acetat-buffer, lysed by sonification and centrifuged at 10,000xg for 10 minutes. The supernatant was taken for SDS-PAGE and Activitytests.


Figure 2: SDS-PAGE of the lysis supernatants from cultivation (09/23). We cultivated E. coli KRX with <partinfo>BBa_K729006</partinfo> , E. coli KRX without plasmid (negative control) and with <partinfo>BBa_K863005</partinfo> (positive control), 60 mL in 250 mL flasks without baffles, LB-medium or autoinduction medium for <partinfo>BBa_K863005</partinfo>, 60 µg/mL chloramphenicol, 37 °C for 12 hours.


Activity Tests

Expecting the laccase in the supernatant of the lysed cell samples, we did activity tests using 198 µL of the sample and 2 µL ABTS. Since laccases are capable of oxidzing ABTS we are able to detect active laccases through measuring the absorption of oxidized ABTS at 420 nm. As a positive control we took the samples containing <partinfo>K863005</partinfo> which we already characterized. Using this approach we could not detect any activity over a period of 40 minutes (see Figure 1). To gain some activity we incubated the samples with 0.4 mM CuCl for at least 2 hours. After incubation time we started another setting using 198 µL of the samples containing <partinfo>K729002</partinfo> and <partinfo>K863005</partinfo> and applied 0.01 mM ABTS. The measurements lasted for 5 hours but the results did not show a decrease in oxidized ABTS again (see Figure 2). We figured out that contaminants in the samples, e.g. salts, could affect the activity of the tested laccases. The samples were rebuffered into deionized H2O using HiTrap Desalting Columns and then again incubated with 0.4 mM CuCl for 2 hours. This time the measurement setup differed because no buffer remained in the samples. The new measurements were done with 100 mM sodium acetate buffer (pH 5), 158 µL sample and 0.01 mM ABTS for 5 hours at a temperature of 25°C. This preparation of the samples led to oxidizing activity of the laccases and therefore to an increase in oxidized ABTS (see Figure 3). After 5 hours both laccases, <partinfo>K729002</partinfo> and <partinfo>K863005</partinfo>, showed great activity and had oxidized ~8 µM ABTS. Since both laccases derive from the same organism they both show a similar reaction behavior.

Figure 1: Activity measurement of <partinfo>K729002</partinfo> and <partinfo>K863005</partinfo> using ABTS over a time period of 40 minutes. No increase in oxidized ABTS is distinguishable.
Figure 2: Activity measurement of <partinfo>K729002</partinfo> and <partinfo>K863005</partinfo> after a 2 hour incubation with 0.4 mM CuCl using ABTS over a time period of 5 hours. No activity of both laccases can be detected since there is no increase in oxidized ABTS.
Figure 3: Activity measurement of <partinfo>K729002</partinfo> and <partinfo>K863005</partinfo> after desalting and a 2 hour incubation with 0.4 mM CuCl using ABTS over a time period of 5 hours. A considerable increase in oxidized ABTS is noticeable. After 5 hours both laccases were capable of oxidizing 8 µM ABTS.

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PCIL - Laccase from Pycnoporus cinnabarinus

TVEL5 - Laccase from Trametes versicolor

TVEL10 - Laccase from Trametes versicolor

TVEL13 - Laccase from Trametes versicolor

TVEL20 - Laccase from Trametes versicolor

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