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Characterization of recombinant effector proteins

Text. See proteinbiochemical methods for further informatons.

Eryhtromycin Esterase

[...] description [...] reaction

Protein data table for BioBrick BBa_ automatically created by the BioBrick-AutoAnnotator version 1.0
Nucleotide sequence in RFC 25, so ATGGCCGGC and ACCGGT were added (in italics) to the 5' and 3' ends: (underlined part encodes the protein)  ATGGCCGGCAGGTTCGAA ... GTTTATGAAACCGGT  ORF from nucleotide position -8 to 1260 (excluding stop-codon)
Amino acid sequence: (RFC25 scars in shown in bold, other sequence features underlined; both given below) 1  MAGRFEEWVKDKHIPFKLNHPDDNYDDFKPLRKIIGDTRVVALGENSHFIKEFFLLRHTLLRFFIEDLGFTTFAFEFGFAEGQIINNWIHGQGTDDEIGR 101  FLKHFYYPEELKTTFLWLREYNKAAKEKITFLGIDIPRNGGSYLPNMEIVHDFFRTADKEALHIIDDAFNIAKKIDYFSTSQAALNLHELTDSEKCRLTS 201  QLARVKVRLEAMAPIHIEKYGIDKYETILHYANGMIYLDYNIQAMSGFISGGGMQGDMGAKDKYMADSVLWHLKNPQSEQKVIVVAHNAHIQKTPILYDG 301  FLSCLPMGQRLKNAIGDDYMSLGITSYSGHTAALYPEVDTKYGFRVDNFQLQEPNEGSVEKAISGCGVTNSFVFFRNIPEDLQSIPNMIRFDSIYMKAEL 401  EKAFDGIFQIEKSSVSEVVYETG*
Sequence features: (with their position in the amino acid sequence, see the list of supported features) None of the supported features appeared in the sequence
Amino acid composition: Ala (A) 27 (6.4%) Arg (R) 16 (3.8%) Asn (N) 20 (4.7%) Asp (D) 29 (6.9%) Cys (C) 3 (0.7%) Gln (Q) 14 (3.3%) Glu (E) 30 (7.1%) Gly (G) 31 (7.3%) His (H) 15 (3.5%) Ile (I) 36 (8.5%) Leu (L) 34 (8.0%) Lys (K) 29 (6.9%) Met (M) 12 (2.8%) Phe (F) 31 (7.3%) Pro (P) 14 (3.3%) Ser (S) 22 (5.2%) Thr (T) 19 (4.5%) Trp (W) 4 (0.9%) Tyr (Y) 19 (4.5%) Val (V) 18 (4.3%)
Amino acid counting Total number: 423 Positively charged (Arg+Lys): 45 (10.6%) Negatively charged (Asp+Glu): 59 (13.9%) Aromatic (Phe+His+Try+Tyr): 69 (16.3%)	Biochemical parameters Atomic composition: C2204H3348N568O636S15 Molecular mass [Da]: 48459.2 Theoretical pI: 5.55 Extinction coefficient at 280 nm [M-1 cm-1]: 50310 / 50498 (all Cys red/ox)
Codon usage Organism: E. coli B. subtilis S. cerevisiae A. thaliana P. patens Mammals Codon quality (CAI): good (0.74) good (0.77) good (0.75) good (0.80) good (0.76) good (0.66)
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Analytical preparation

Figure 3:

Figure 3:

Figure 3:

Degradation of a chromogenic esterase substrate: 4-Nitrophenyl butyrate

Figure 3:

Degradation of Erythromycin

Reaction conditions HPLC Kirby Bauer-Assay

[...] Characterization

Laccase

[...] description [...] reaction [...] production

Laccase a is a secreted enzyme

Figure 3:

Analytical präparation

[...] Characterization

Figure 3:

Figure 3:

Structural consideration of Laccase from B. pumilus

Activity determination using ABTS

Figure 3:

The enzymatic activity of the purified laccae was determined by the ABTS-assay. In a first pre experiment the appropriate dilution factor was determined to 100-fold. The elution fractions obtained from size exclusion chromatography were diluted 1:100 in PBS and in an ELISA plate 100 µl of the enzyme and 100 µl of ABTS substrate were mixed and a kinetic measurement at 405 nm was performed. The absorption at 280 nm in the SEC chromatogramm (blue) identifies three main protein peaks, with a first peak corresponding to aggregated protein, a shoulder which also corresponds to higher molecular protein and a single peak which was proposed to be the monomeric laccase. The relative activity obtained for the different elution fractions was plotted in the same diagramm and shows a clear peak which matches the laccase peak in the SEC. Beside this major peak a second smaller peak of active fraction was visible which appeared in earlier elution fractions and might correspond to dimerized laccase. As the laccase is a secreted enzyme which also bears disluphide bonds it was produced in the cytoplasm and subsequently it was oxidized to form the proper disulphide bond. As this process might be only partial there is a possiblity for the formation of disulphid dimers. Never the less the fractions 14 to 17 were pooled for further experiments as they showed the highest enzymatic activity. The protein concentration of the pooled fraction was determined to 0.48 mg/ml after SEC.

Oxidation of relevant xenobiotics

Diclofenac

Figure 3:

Estradiol

Nano Luciferase

The Nano Luciferase (NanoLuc) which was introduced in 2013 by Promega is a new member of the luciferase reporter gene/protein familiy and shows some advantages compared to the other family members. The NanoLuc is very small (19 kDa) compared to the firefly luciferase (61 kDa) and the Renilla luciferase (36 kDa). On the other hand it is also said that the specific activity of the NanoLuc is about 150-fold stronger compared to conventional luciferases and the background caused by autoluminescense of the substrate shel be smaller.

Production in E. coli and purification

Figure 3:Analytical size exclusion chromatography on a Superdex 200 10/30 column showing a single elution peak for the NanoLuc.

Figure 3:Preperative size exclusion chromatography on a Superdex 75 10/30 column showing a single elution peak for the NanoLuc.

Therefore the NanoLuc was synthesized as a BioBrick in RFC[25] and was produced in E. coli using the pBad expression system with a C-terminal Strep-tag. After the production (2 l of LB-media for analytical and 12 l for preparative preparations) the cells were disrupted using sonification and the lysate was dialysed against 5 l of 1x SA-buffer. Afterwards the lysate was applied to a Streptavidin-Affinity (SA) column and was subsequently washed using SA-Buffer until a baseline was reached and the protein was then eluted using 5 mM of biotin (Attention: These are special columns which are not availible commercially. If you are using commercial colum material you have to use d-Desthiobiotin because usual biotin will elute your protein but you will not be able to regenerate the column after your chromatography). After the SA-chromatography the protein was concentrated using centrifugal concentration units (MWCO: 10 kDa). The concentrated protein was then applied on a Superdex S200/75 size exclusion chromatography.

Structure of the Nano Luciferase

Figure 3:

There is no structure availible for the NanoLuc in the [http://www.rcsb.org/pdb/home/home.do Proein Data Bank]. The protein modelling

Activity determination of Luminescense

Figure 3:

Figure 3:

XylE

[...] description [...] reaction [...] production

Analytical präparation

[...] Characterization

DDT-Dehydrochlorinase

[...] description [...] reaction [...] production

Analytical präparation

[...] Characterization

PP1

Figure 3:

Figure 3:

SpyCatcher & SpyTag

[...] description [...] reaction [...] production

Analytical präparation

[...] Characterization

References:

http://www.ncbi.nlm.nih.gov/pubmed/6327079 Edens et al., 1984

1. http://www.ncbi.nlm.nih.gov/pubmed/6327079 Edens et al., 1984 Edens, L., Bom, I., Ledeboer, A. M., Maat, J., Toonen, M. Y., Visser, C., and Verrips, C. T. (1984). Synthesis and processing of the plant protein thaumatin in yeast. Cell, 37(2):629–33.
2. http://udel.edu/~gshriver/pdf/Pimenteletal1997.pdf Pmentel et al., 1997 Pimentel, D., Wilson, C., McCullum, C., Huang, R., Dwen, P., Flack, J. Tran, Q., Saltman, T., Cliff, T. (1997). Economic and environmental benefits of biodiversity. BioScience, Vol. 47, No. 11., pp. 747-757.

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