Team:Bielefeld-Germany/Protocols/Production

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Production


Contents

Production

Here all our methods according to cultivation and purification are listed.

Pre-Cultivation

Precultivation of E.Coli KRX (with or without BioBrick)

  • 50 mL LB-medium, if nessassary with 20-60 mg L-1 chloramphenicol or with 100-300 mg L-1 ampicillin, in 300 mL shaking flask with baffles (Schott) with silicon plugs
  • 1 mL Glycerinculture or 1 colony
  • Cultivation temperature: 37 °C
  • Shaking at 140 rpm

Precultivation of E.Coli Rosetta Gami 2 (with or without BioBrick)

  • 50 mL LB-medium with 60 mg L-1 chloramphenicol and with 300 mg L-1 ampicillin, in 300 mL shaking flask with baffles (Schott) with silicon plugs
  • 1 mL Glycerinculture or 1 colony
  • Cultivation temperature: 37 °C
  • Shaking at 140 rpm

Precultivation of Pichia Pastoris GS115 (complex-medium)

  • 50 mL YPD-medium in 300 mL shaking flask with baffles (Schott) with silicon plugs
  • 1 mL Glycerinculture or 1 colony
  • Cultivation temperature: 30 °C
  • Shaking at 140 rpm

Precultivation of Pichia Pastoris GS115 (minimal-medium)

  • 50 mL YNB-medium in 300 mL shaking flask with baffles (Schott) with silicon plugs
  • 1 mL Glycerinculture or 1 colony
  • Cultivation temperature: 30 °C
  • Shaking at 140 rpm


Cultivation

Cultivations in Autoinduction-Medium were supplemented with 0.1 % L-rhamnose as inducer, when the designated OD600 was reached, as described in the Promega protocol

Expression of Laccase

  • Chassis: Promega's E.Coli KRX
  • Medium: Autoinduction-Medium supplemented with Chloramphenicol (final concentration 60 μg mL-1)

Cultivation with E. coli KRX in shaking flask(with baffles):

  • 200 mL culture in 1000 mL shaking flask with baffles (Schott) with silicon plugs
  • Cultivation temperature: 37 °C
  • Autoinduction-medium with 20-60 mg L-1 chloramphenicol and if nessassary with 100-300 mg L-1 ampicillin
  • Shaking at 140 rpm
  • for characterizations: automatic sampling every 30 min

Bioreactor cultivations with E. coli KRX

To obtain higher amounts and concentration of proteins we cultivated and expressed in a bioreactor. It is possible to cultivate several liters and to control temperature, pH and pO_2.

  • Bioreactor: Braun Biostat B Bioreactor (3L), Infors Labfors Bioreactor (3L), Bioengineering NLF22 Bioreactor (7 L),
  • Autoinduction-medium with 60 mg L-1 chloramphenicol
  • Culture volume: 3,0-6,0 L
  • Starting OD600: 0.1 - 0.2
  • Airflow: 5 NL/min
  • pO2-Control: 30 % airsaturation (controlled with stirrer cascade starting with 200 rpm)
    • pO2=100% calibration with 300rpm
  • pH: 7.0 (controlled with 2M phosphoric acid and 2 M NaOH)
  • Antifoam: BASF pluronic PE-8100
  • Harvest after 12-13 h

Cell Harvesting

  • Harvest cells by centrifugation at 10,000 g for 10 min at 4 °C
  • if the purification should start the next day store the cell pellet at 4°C !(the laccase must not be frozen!)
  • Resuspend the pellet in 5 mL special buffer or binding buffer for each gramm of cell paste


Solubilization of inclusion bodies

  • centrifugation of the celllysate at 40,000 g for 30 minutes
  • resuspend the pellet of the lysate in 1 mL 6M Urea solution, incubation for 1 hour
  • centrifugation for 10 minutes at 10,000 rpm
  • resuspend the pellet in SDS running buffer


Cell disruption strategies

B-PER lysis (chemical lysis)

B-Per bacterial Protein Extraction Reagnt was used for a cell disruption screening according to the following protocol of Thermo Scientific.

  • add 4 mL B-Per Reagent per gram of cell pellet
  • resuspend the cell pellet by pipetting the suspension up and down until it is homogenous.
  • incubate the solution for 10- 15 min at room temperature
  • centrifuge lysate at 15.000g for 10 min
  • decant the supernatant in a clean tube

The lysate is ready for a following purification step.

enzymatical lysis with lysozym

The lysis with lysozym was used for a cell disruption screening. The following protocol was utilized:

  • resuspend the cell pellet in 600 µL of lysozym-solution per gramm
  • incubate the solution for 1 h at 4°C
  • centrifuge the lysate toseperate soluble proteins from insoluble proteins and cell debris.

combination of chemical and enzymatical lysis

B-Per bacterial Protein Extraction Reagnt was used for a cell disruption screening according to the following protocol of Thermo Scientific.

  • add 4 mL B-Per Reagent per gram of cell pellet
  • add 2µL of lysozym-solution(50 mg mL -1) and 2 µL DNaseI (2500 U mL -1) per mL B-Per Reagent. (For laccases:Do not use EDTA!)
  • resuspend the cell pellet by pipetting the suspension up and down until it is homogenous.
  • incubate the solution for 10- 15 min at room temperature
  • centrifuge lysate at 15.000g for 10 min
  • decant the supernatant in a clean tube

The lysate is ready for a following purification step.


Mechanical lysis

The method of choice to disrupt the cells depends on the amount of biomass.


Mechanical lysis of the (shaking flask) cultivation

Sonication

  • Sonication of the re-suspended pellet on ice
    • cycle number depends on the volume of the resuspended cells (e.g. 3 mL means 3 cycles)
    • one cycle means sonification treatment for 1,5 min with Sonifier 450 by Branson, max. 50 %, cooled on ice, make sure not to heat the cells too much

Precellyse 24 homogenization

  • homogenization with the Precellyse 24
    • fill the precellyse tubes with a sample volume between 1 mL up to 1,5 mL (for 2 mL tubes)
    • homogenize the samples for 3 cycles (6500 rpm for 35 sec. ), to make sure not to heat the cells to much, the sample were stored for 5 min in ice between 2 cycles.

Mechanical lysis of the (bio-reactor) cultivation

Cell disruption with a high-pressure homogenizer

  • high-pressure homogenisation with a Rannie Homogenizer:
  • disruption of the cells by 3 cycles with cooling phases between the cycles, pressure = 1200 bar, make sure not to heat the cells too much


Purification

Ultra-/Diafiltration


  • Arrange the filtration module as shown on the right side.
  • Microfiltration (0.22 µm) or cross flow filtration with 300 kDa (we used a Milipore Pellicon XL 300) membrane of sample before ultrafiltration.
  • For concentrating the sample just filter it until the desired volume is left in the feed reservoir. For diafiltration (e.g. buffer exchange, desalting) dilute the feed reservoir several times and filter continously.
  • Used membranes: Milipore Pellicon XL 50 or XL 100 membranes
    • 50 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
Filtrationsystem to purify the disrupted cells from cell debris, RED ARROW: Filtrationunits Millipore Pellicon XL 50 with 50 kDa (right) and 300 kDa (left)

His-tag affinity chromatography


Used Chromatographycolumns:
left 1 mL HisTrap FF crude by GE Healthcare
middle 15 mL HisTrap FF crude by GE Healthcare
right TALON His-Tag Purification Resin by Clonetech
  • For buffers see here

Syringe method

  • Column: 1 mL HisTrap FF crude by GE Healthcare
  • Equilibrate with binding buffer (10mL)
  • Load sample onto column (max. 6 mL)
  • Wash with 10 mL binding buffer
  • Elute with 5 mL of elution buffer (500 mM imidazole)
  • Collect the eluate in 1 mL fractions, the purified protein is most likely in the first or second fraction
  • Re-equilibrate the column with binding buffer

ÄKTA method

  • Columns:
  1. 15 mL HisTrap FF crude by GE Healthcare
  2. 50 mL TALON-Histag-Purification Resin by Clonetech

Column preparation

  • If Column is not loaded with Ni-ions /Cobalt-ions:
    • Wash column with 5 - 8 Columnvolumes (CV) of deionized water
    • Load column with metal-ions(4 CV)
      • For HisTrap FF crude: 1,4% NiSO4-Solution
      • For TALON-Histag-Purification Resin: CoCl2-Solution

Chromatography protocol for the Äkta-system

Äkta Prime by GE Healthcare
  • Wash column with 10 CV of deionized water
  • Equilibrate column with 10 CV of binding buffer
  • Load column with supernatant of the lysed cells (Collect the Flow through for SDS-PAGE analysis)
  • Wash Column with 10 CV of binding buffer (Collect the Flow through for SDS-PAGE analysis)
  • Elute Protein with an increasing elutionbuffer ratio (gradient 0%-100%, length 200mL)
  • Collect the eluate in 10 mL fractions
  • Elute remaining proteins with 100% Elutionbuffer (4 CV)



An typical chromatogram of purified laccases is illustrated in the following grafic:

A typical chromatogram of the purification procedure of laccases. the different steps of the purification are illustrated: 1.) Equlibration, 2.) Sample Loading, 3.) Wasch, 4.)Elution, 5.) Regeneration




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