Difference between revisions of "Part:BBa K525305"

(Methods)
(Methods)
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'''Production of SgsE'''
 
'''Production of SgsE'''
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Cultivation
 
Cultivation
 
* Bioreactor: [http://www.bioengineering-inc.com/standard-reactors.php?id=2.1 Bioengineering NLF22 7 L] with Bioengineering DCU
 
* Bioreactor: [http://www.bioengineering-inc.com/standard-reactors.php?id=2.1 Bioengineering NLF22 7 L] with Bioengineering DCU
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* Induction after 4 h cultivation time with 2 % rhamnose and 0.1 mM IPTG (in culture medium)
 
* Induction after 4 h cultivation time with 2 % rhamnose and 0.1 mM IPTG (in culture medium)
 
* Harvest after 13 h
 
* Harvest after 13 h
 
  
 
Cell lysis
 
Cell lysis

Revision as of 13:50, 28 October 2011

Fusion Protein of S-Layer SgsE and mCitrine

Bielefeld-Germany2011-S-Layer-Geometrien.jpg

Fusion protein of S-layer SgsE and mCitrine

S-layers (crystalline bacterial surface layer) are crystal-like layers consisting of multiple protein monomers and can be found in various (archae-)bacteria. They constitute the outermost part of the cell wall. Especially their ability for self-assembly into distinct geometries is of scientific interest. At phase boundaries, in solutions and on a variety of surfaces they form different lattice structures. The geometry and arrangement is determined by the C-terminal self assembly-domain, which is specific for each S-layer protein. The most common lattice geometries are oblique, square and hexagonal. By modifying the characteristics of the S-layer through combination with functional groups and protein domains as well as their defined position and orientation to eachother (determined by the S-layer geometry) it is possible to realize various practical applications ([http://onlinelibrary.wiley.com/doi/10.1111/j.1574-6968.2006.00573.x/full Sleytr et al., 2007]).


Usage and Biology

S-layer proteins can be used as scaffold for nanobiotechnological applications and devices by e.g. fusing the S-layer's self-assembly domain to other functional protein domains. It is possible to coat surfaces and liposomes with S-layers. A big advantage of S-layers: after expressing in E. coli and purification, the nanobiotechnological system is cell-free. This enhances the biological security of a device.

This fluorescent S-layer fusion protein is used to characterize purification methods and the S-layer's ability to self-assemble on surfaces. It is also possible to use the characteristic of mCitrine as a pH indicator ([http://pubs.acs.org/doi/abs/10.1021/bm901071b Kainz et al., 2010]).


Important parameters

Experiment Characteristic Result
Expression (E. coli) Localisation Inclusion body
Compatibility E. coli KRX and BL21(DE3)
Induction of expression expression of T7 polymerase + IPTG or lactose
Inhibition of expression glucose
Specific growth rate (un-/induced) 0.139 h-1 / 0.071 h-1
Doubling time (un-/induced) 4.98 h / 9.78 h
Purification Molecular weight 110.2 kDa
Theoretical pI 5.74
Excitation / emission 515 / 529 nm
Immobilization behaviour Saturation protein / bead ratio 5 - 7 * 10-4
Immobilization time 4 h


Sequence and Features

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BglII site found at 167
    Illegal BglII site found at 1022
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal NgoMIV site found at 76
    Illegal AgeI site found at 3121
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal BsaI site found at 1657


Expression in E. coli

The SgsE gene under the control of a T7 / lac promoter (BBa_K525303) was fused to mCitrine (BBa_J18931) using Freiburg BioBrick assembly for characterization experiments.

The SgsE|mCitrine fusion protein was overexpressed in E. coli KRX after induction of T7 polymerase by supplementation of 0.1 % L-rhamnose and 1 mM IPTG using the autoinduction protocol by Promega.

Figure 1: Growth curve of E. coli KRX expressing the fusion protein of SgsE and mCitrine with and without induction, cultivated at 37 °C in autoinduction medium with and without inductor, respectively. A curve depicting KRX wildtype is shown for comparsion. After induction at approximately 4 h the OD600 of the induced BBa_K525305 visibly drops when compared to the uninduced culture. Both cultures grow significantly slower than KRX wildtype probably due to a leaky promoter and metabolic stress by the high copy plasmid.
Figure 2: RFU to OD600 ratio of E. coli KRX expressing the fusion protein of SgsE and mCitrine with and without induction. A curve depicting KRX wildtype is shown for comparsion. After induction at approximately 4 h the RFU to OD600 ratio starts to rise in the induced culture. Compared to the uninduced culture the ratio is roughly four times higher. The KRX wildtype shows no variation in the RFU to OD600 ratio.

Purification of SgsE fusion protein

After the analysis of cultivations with expression of SgsE | mCitrine fusion proteins different cell fractions were analyzed. It could be seen that the proteins form inclusion bodies in E. coli. Inclusion bodies have the advantage that they are relatively easy to clean-up and are resistant to proteases. So the first purification step is to solve and set-free the inclusion bodies. This step is followed by two filtrations (300 kDa UF and 100 kDa DF/UF) to further concentrate and purify the S-layer proteins. After the filtrations, the remaining protein solution is dialized against ddH2O for 18 h at 4 °C in the dark. The dialysis leads to a precipitation of the water-insoluble proteins. After centrifugation of the dialysate the water-soluble S-layer monomers remain in the supernatant and can be used for recrystallization experiments.

The fluorescence of the collected fractions of this purification strategy is shown in the following figure 3:

Fig. 3: Fluorescence of collected fractions during purification of BBa_K525305 fusion protein.

A lot of protein is lost during the purification especially after centrifugation steps. The fluorescence in the urea containing fractions is lowered due to denaturation of the fluorescent protein. Some fluorescence could be regenerated by the recrystallization in HBSS (Hank's buffered saline solution with pH 7.4). This purification strategy is very simple and can be carried out by nearly everyone in any lab being one first step to enable do it yourself nanobiotechnology.

His-tag affinity chromatography By fusing the SgsE gene with a C terminal His-6-tag the S-layer protein could be simply purified by using a His-tag affinity chromatography. This purification strategie has the advantage that no inclusion body purification and filtration is necessary to degrade native E. coli proteins.

Immobilization behaviour

After purification, solutions of monomeric SgsE S-layer proteins can be recrystallized and immobilized on silicon dioxide beads or silicon wavers in HBSS. After the recrystallization procedure the beads are washed with and stored in ddH2O at 4 °C in the dark. The fluorescence of the collected fractions of a recrystallization experiment with BBa_K525305 is shown in fig. 4. 100 mg beads were coated with 100 µg of protein. The figure shows, that not all of the protein is immobilized on the beads (supernatant fraction) but the immobilization is pretty stable (very low fluorescence in the wash). After the immobilization, the beads show a high fluorescence indicating the binding of the SgsE | mCitrine fusion protein.

Fig. 4: Measured fluorescence of collected fractions of immobilization of purified BBa_K525305 on silicon dioxide beads (n = 3, 100 mg mL-1 SiO2, time of recrystallization: 4 h).


Optimal bead to protein ratio for immobilization

To determine the optimal ratio of silica beads to protein for immobilization, the degree of clearance ϕC in the supernatant is calculated and plotted against the concentration of silica beads used in the accordant immobilization experiment (compare fig. 5):


Bielefeld-Germany2011-degreeofclearanceformula.png
(1)


The data was collected in three independent experiments. The fluorescence of the samples was measured in the supernatant of the immobilization experiment after centrifuging the silica beads. The fluorescence of the control was measured in a sample which was treated exactly like the others but no silica beads were added. 100 µg protein was used for one immobilization experiment. The data was fitted with a sigmoidal dose-response function of the form


Bielefeld Doseresponse fit.jpg
(2)


with the Hill coefficient p, the bottom asymptote A1, the top asymptote A2 and the switch point log(x0) (R² = 0.874).

The fit indicates that a good silica concentration for 100 µg of protein is 150 - 200 mg mL-1. This set-up leads to saturated beads with low waste of protein. So a good protein / bead ratio to work with is 5 - 7 * 10-4.


Fig. 5: Degree of clearance of the fluorescence in the supernatant plotted against the concentration of silicium dioxide beads used to immobilize BBa_K525305 (n = 3). Data is fitted with dose-reponse function (eq. (2), R² = 0.874).

Methods

Expression of S-layer genes in E. coli in shaking flasks

  • Chassis: Promega's [http://www.promega.com/products/cloning-and-dna-markers/cloning-tools-and-competent-cells/bacterial-strains-and-competent-cells/single-step-_krx_-competent-cells/ E. coli KRX]
  • Medium: LB medium supplemented with 20 mg L-1 chloramphenicol
    • For autoinduction: Cultivations in LB-medium were supplemented with 0.1 % L-rhamnose and 1 mM IPTG as inducer and 0.05 % glucose
  • cultivation: 37 °C with 120 rpm in shaking flasks


Production of SgsE

Cultivation

  • Bioreactor: [http://www.bioengineering-inc.com/standard-reactors.php?id=2.1 Bioengineering NLF22 7 L] with Bioengineering DCU
  • Medium: [http://2011.igem.org/Team:Bielefeld-Germany/Protocols/Materials#HSG_medium HSG medium] with 20 mg L-1 chloramphenicol
  • Culture volume: 4 L
  • Inoculation OD600: 0.2
  • DO: 40 % airsaturation (controlled with stirrer cascade starting with 200 rpm)
  • pH: 7.0 (controlled with 20 % phosphoric acid and 2 M NaOH)
  • Induction after 4 h cultivation time with 2 % rhamnose and 0.1 mM IPTG (in culture medium)
  • Harvest after 13 h

Cell lysis

  • Centrifuge down the cells (10000 g, 30 min, 4 °C)
  • Resuspend pellet in enzyme buffer
  • Cell lysis with high-pressure homogenizer (800 bar, 3 cycles at 4 °C)
  • Centrifuge down the lysate (10000 g, 60 min, 4 °C)

Purification

  • Inclusion body clean-up
    • wash pellet from cell lysis with water twice
    • after washing the pellet: incubate the pellet in [http://2011.igem.org/Team:Bielefeld-Germany/Protocols/Materials#Denaturation_buffer_for_inclusion_bodies denaturation buffer] for 60 min, 4 °C with vertical rotator
      • final concentration in denaturation buffer: 0.5 mg wet biomass per mL
    • centrifuge (60 min, >17000 g, 4 °C)
      • in general with all centrifugations during this clean-up: the higher the speed, the better the result
    • collect supernatant and incubate the pellet again in denaturation buffer (60 min, 4 °C, vertical rotator)
    • centrifuge (60 min, >17000 g, 4 °C)
    • collect supernatant and discard pellet


  • Filtration
    • Arrange the filtration module as shown on the right side.
    • Collect permeate of cross flow filtration with 300 kDa membrane of sample before ultrafiltration
      • This step is for removing cell debris
    • Diafiltrate with 100 kDa membrane against [http://2011.igem.org/Team:Bielefeld-Germany/Protocols/Materials#Denaturation_buffer_for_inclusion_bodies denaturation buffer]
      • constantly delute permeate with the buffer, keeping the permeate volume as low as possible
    • Used membranes: [http://www.millipore.com/catalogue/module/C7493 Milipore Pellicon XL 50] or XL 100 membranes
      • 50, 100 or 300 kDa cut-off
      • 50 cm2 filtration area
      • tangential flow filter
      • Hydrophilic polyvinylidene fluoride membrane
    • Used pump: SciLog TANDEM 1081 peristaltic pump
      • flow rate during filtration: 40 mL min-1
  • Dialysis
    • Fill retentate from DF/UF in dialysis tube ([http://www.carl-roth.de/ Roth], cellulose, 10 kDa cut-off)
    • Dialyse against ddH2O for 18 h at 4 °C in the dark
    • After dialysis: centrifuge down the precipitation (45 min, 17000 g, 4 °C) and collect the supernatant
    • Measure protein concentration in supernatant, dilute to 1 mg mL-1 with ddH2O and store at 4 °C in the dark


Measuring of mCitrine

  • Take at least 500 µL sample for each measurement (200 µL is needed for one measurement) so you can perform a repeat determination
  • Freeze biological samples at -80 °C for storage, keep cell-free at 4 °C in the dark
  • To measure the samples thaw at room temperature and fill 200 µL of each sample in one well of a black, flat bottom 96 well microtiter plate (perform at least a repeat determination)
  • Measure the fluorescence in a platereader (we used a [http://www.tecan.com/platform/apps/product/index.asp?MenuID=1812&ID=1916&Menu=1&Item=21.2.10.1 Tecan Infinite® M200 platereader]) with following settings:
    • 20 sec orbital shaking (1 mm amplitude with a frequency of 87.6 rpm)
    • Measurement mode: Top
    • Excitation: 488 nm
    • Emission: 529 nm
    • Number of reads: 25
    • Manual gain: 100
    • Integration time: 20 µs

References

Kainz B, Steiner K, Möller M, Pum D, Schäffer C, Sleytr UB, Toca-Herrera JL (2010) Absorption, Steady-State Fluorescence, Fluorescence Lifetime, and 2D Self-Assembly Properties of Engineered Fluorescent S-Layer Fusion Proteins of Geobacillus stearothermophilus NRS 2004/3a, [http://pubs.acs.org/doi/abs/10.1021/bm901071b Biomacromolecules 11(1):207-214].

Sleytr UB, Huber C, Ilk N, Pum D, Schuster B, Egelseer EM (2007) S-layers as a tool kit for nanobiotechnological applications, [http://onlinelibrary.wiley.com/doi/10.1111/j.1574-6968.2006.00573.x/full FEMS Microbiol Lett 267(2):131-144].