Difference between revisions of "Part:BBa K863010"

Latest revision as of 18:32, 21 October 2021

tthl laccase from Thermus thermophilus with T7 promoter, RBS and His-tag

tthl (Laccase from Thermus thermophilus) with T7, RBS and HIS tag

Usage and Biology

Slovenia HS characterized this part in 2015.

Escherichia coli BL21 (DE3) bacteria were transformed with the expression plasmids (BBa_K863005 and BBa_K863010) and grown in 10 ml at 37 °C in LBC medium overnight. To express both recombinant proteins, 10 ml of overnight cultures shaker cultures were grown at 37 °C in LB broth supplemented with 30 µg/ml chloramphenicol and shaking with 225 rpm. Expression of the recombinant protein was induced by addition of IPTG to a final concentration of 1 mM, when the cell density reached an OD600 of 0.8. After induction, cells were grown for 5 h and then collected by centrifugation at 6000g for 10 min. The cell pellet collected from 400 ml of bacterial culture was resuspended in 20 ml of resuspension buffer (50 mM HEPES pH 7.5, 500 mM NaCl, 20 mM imidazole) and sonified 3 × 6 min on ice. Following centrifugation at 30 000 × g for 10 min to remove insoluble debris, the supernatant was applied to a Ni-NTA Superflow Cartridge (Qiagen) connected to ÄKTA FPLC system, washed with the resuspension buffer and eluted in the same buffer, but containing 250 mM imidazole. The peak fractions were collected and 15 µl of each fraction was collected and resolved on 12 % SDS-PAGE.

We found that while BBa_K863005 shows excellent activity, BBa_K863010 shows no activity under the same conditions.

IPTG Induction of K863010 (2019 PuiChing_Macau)

Figure 1. Western Blot and SDS-PAGE (coomassie blue) of K863000 and K863010 laccase. Both laccase should be with His-tag.

Consistent with characterization by previous iGEM teams, we found no expression of laccase with K863010 plasmid (contains a fungal laccase, expected to be IPTG regulated), as shown in Figure 1. To the best of our knowledge, there is no functional IPTG-regulated fungal laccase in the iGEM part registry. We here successfully add one (K3021002), as an improvement of the part K863010, which cannot be expressed. For detail information of K3021002, refer to 2019 PuiChing_Macau K3021002

Team TecCEM Characterization

TecCEM Characterization, purification and degradation of dyes

For the characterization of the Laccase BBa_K863010 we conducted an IPTG induction experiment in which we transformed the plasmid pSB1C3 containing the Laccase in E. coli BL21-DE3. We thought that we could use another strain called SoluBL21 but results were not successful as no expression was found. We verified the presence of the protein through an SDS-PAGE with a gel concentration of 12% and found a visible band with a mass of around 50 kDa. We also analyzed soluble and insoluble fractions and the presence of protein in the culture medium. This can be seen in figure 1.

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Figure 1. The lanes correspond to the following. M: Molecular weight marker; 1: Total protein after induction; 2: Total protein before induction; 3: Protein found in the Culture Medium after induction; 4: Cytoplasmic soluble fraction; 5: Inclusion bodies of the insoluble fraction; 6: Concentrated Culture Medium after induction. The band observed in lanes 1, 3 and 6 weighs around 48 kDa and corresponds to the expected size.

We found that the protein was mostly found on the culture medium but can also be found on the cytoplasmic soluble fraction. The band that was appreciated in figure 1. indicates that there’s an expression of the Laccase after it’s induction with IPTG so our results and experience using this part was different from what 2019 PuiChing Macau’s team reported previously, since they found no expression and a lack of an IPTG functional protein.

To demonstrate activity of the lacasse purified, we conducted a dye degradation assay. Owing to their broad substrate specificity, laccases have attracted considerable interest in terms of applications to many fields, such as environmental detoxification. Some fungal laccases have been reported to perform dye decolorization of a variety of dyes, such as azo, anthraquinone, and aromatic methane. Synthetic dyes are widely used in several industries, including textiles, food processing, paper printing, cosmetics, and pharmaceuticals. Three dyes were selected according to previous reports of laccase degradation, malachite green, methylene blue and rose Bengal (Cheriaa J. & Bakhrouf A., 2009 [1]; Forootanfar, H., 2012; Pramanik, S., & Chaudhuri, S. 2018 [2]). Based on the chemical structure of chromogenic groups, dyes are classified as azo, heterocyclic/polymeric or triphenylmethanes. About 60% of produced dyes belong to the azo group which are categorized as monoazo, diazo, and triazo dyes. Malachite green is a triphenylmethane dye belonging to a basic dyes class, used extensively for dyeing silk, wool and cotton. Rose Bengal, an Azo dye is used in apoptosis assays, biological staining photography, recording industry, etc., this dye is genotoxic and microbial toxic. Methylene blue is a heterocyclic aromatic compound that has a wide use in biological and medicine applications in addition to textile-processing industries. To prove that the Laccase was being expressed, we conducted a dye degradation involving three colorants that act as a substrate: methylene blue, malachite green and rose bengal. We based this experiment upon the findings of D. Singh et al. (2014) [3], in which they used agar plates with these colorants to determine the expression of Laccases in a medium. The first assays we conducted were only to find out if there was any color change with the presence of our extracted Laccase either from the cytoplasmic soluble fraction or from the culture medium. We used Citrate Buffer and found a change of color in different samples of Laccase after its purification using Ni Affinity. We also verified that the effect we saw wasn’t related to a change in pH. The results are available in figure 2.

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Figure 2. First dye degradation assay conducted. In section a) we can see the change of color of the substrates used (methylene blue, malachite green and rose bengal from left to right). a)-I. corresponds to the cytoplasm soluble fraction while a)-II. corresponds to the secreted protein from the culture medium. In section b) we can see that the pH remained unchanged throughout the assay.

After this first assay, we decided that we had to establish a purification protocol through which we could get the most enzyme possible. We used a Ni Affinity Column and a system of recollection of the different phases. We collected the enzyme from both the culture medium and the cytoplasmic soluble fraction and measured the absorbance of the fractions collected at 280 nm. In total, we got 21 fractions for the cytoplasm proteins and 20 fractions for the culture medium. The purification conditions were established using a growing elution buffer concentration. These conditions are shown in figures 3 and 4.