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stability window for Taq polymerase
pH
ionic strength
size
isoelectric point (pI)
hydrophobicity
solubility
* temperature stability - need to work rapidly at lowered temperature
* pH stability - selection of buffers for extraction and purification; selection of conditions for ion exchange, affinity or reversed phase chromatography
* organic solvents stability - selection of conditions for reverse phase chromatography
* detergent requirement - consider effects on chromatographic steps and the need for detergent removal. consider choice of detergent.
* salt (ionic strength) - selection of conditions for precipitation techniques and hydrophobic interaction chromatography
* cofactors for stability and activity - selelection of additives, pH, salts, buffers
* protease sensitivity - need for fast removal of proteases or addition of inhibitors
* sensitivity to metal ions - need to add EDTA or EGTA in buffers
* redox sensitivity - need to add reducing agents
* molecular weight - selection of gel filtration media
* charge properties - selection of ion exchange conditions
* biospecific affinity - selection of ligand for affinity medium
* post translational modifications - selection of group specific affinity medium
* hydrophobicity - selection of medium for hydrophobic interaction chromatography
protein properties used during purification
* charge - ion exchange (IEX)
* size - gel filtration (GF)
* hydrophobicity - hydrophobic interaction (HIC), reversed phase (RPC)
* biorecognition (ligand specifity) - affinity (AC)
* charge, ligand specificity or hydrophobicity - expanded bed adsorption (EBA) follows the principles of AC, IEX or HIC
suitability of purification techniques for the Three Phase Purification Strategy:
IEX:
main features:
- high resolution
- high capacity
- high speed
capture: 3stars
intermediate: 3stars
polish: 3stars
sample start condition:
- low ionic strength
- sample volume
- not limiting
sample end condition:
- high ionic strength or pH change
- concentrated sample
HIC:
main features:
- good resolution
- good capacity
- high speed
capture: 2stars
intermediate: 3stars
polish: 1stars
sample start condition:
- high ionic strength
- sample volume
- not limiting
sample end condition:
- low ionic strength
- concentrated sample
AC (affinity chromatography):
main features:
- high resolution
- high capacity
- high speed
capture: 3stars
intermediate: 3stars
polish: 2stars
sample start condition:
- specific binding conditions
- sample volume
- not limiting
sample end condition:
- specific elution conditions
- concentrated sample
GF (gel filtration):
main features:
- high resolution
- using Superdex(TM) media
intermediate: 1stars
polish: 3stars
sample start condition:
- limited sample volume (<5% total column volume)
- limited flow rate range
sample end condition:
- buffer exchanged (if required)
- diluted sample
RPC:
main features:
- high resolution
intermediate: 1stars
polish: 3stars
sample start condition:
- requires organic solvents
sample end condition:
- in organic solvent
- risk loss of biological activity
"Ammonium sulphate precipitation is a common sample clarification and concentration step at laboratory scale and in this situation HlC (which requires high salt to enhance binding to the media) is ideal as the capture step. The salt concentration and the total sample volume will be significantly reduced after elution from the HlC column. Dilution of the fractionated sample or rapid buffer exchange using a Sephadex G-25 desalting column will prepare it for the next IEX or AC step."
"GF is well suited for use after any of the concentrating techniques (IEX, HlC, AC, EBA) since the target protein will be eluted in a reduced volume and the components from the elution buffer will not affect the gel filtration separation (gel filtration is a non-binding technique with limited volume capacity and unaffected by buffer conditions)."
Logical combinations of chromatographic steps
crude sample -> GF (desalt mode) -> AC -> ___ -> GF
crude sample -> GF (desalt mode) -> IEX -> ___ -> GF
crude sample -> Hlc (dilution may be needed) -> IEX -> GF
crude sample -> GF (desalt mode) -> IEX -> HlC -> GF
clear or very dilute samples -> AC -> GF or RPC
clear or very dilute samples -> IEX -> GF or RPC
clear or very dilute samples -> IEX -> HlC -> GF
clear or very dilute samples -> precipitation (e.g., in high ionic strength) -> resolubilise -> treat as for sample in high salt concentration
"A sample is purified using a combination of techniques and alternative selectivities. For example, in an IEX-HlC-GF Three Phase Strategy the capture step selects according to differences in charge (IEX), the intermediate purification step according to differences in hydrophobicity (HlC) and the final polishing step according to differences in size (GF)."
IEX-HlC-GF is regarded as the standard if you know nothing about the proteins.
RPC = reversed phase chromatography
Purification step Media Quantity Code No.
Capture STREAMLINE SP 300 ml 17-0993-01
Capture STREAMLINE DEAE 300 ml 17-0994-01
Capture HiPrepTM 16/10 SP XL 1 column 17-5093-01
Capture HiPrep 16/10 Q XL 1 column 17-5092-01
Intermediate purification HiPrep Phenyl (high sub) 1 column 17-5095-01
Polishing HiLoadTM 16/60 Superdex 75 prep grade 1 column 17-1068-01
Polishing HiLoad 16/60 Superdex 200 prep grade 1 column 17-1069-01
Sample clarification/conditioning Pre-packed PD-10 Column 30 columns 17-0851-01
Sample clarification/conditioning HiTrap Desalting 5 columns 17-1408-01
Sample clarification/conditioning HiPrep 26/10 Desalting 1 column 17-5087-01
Pre-packed column Sample volume Sample volume Code No.
loading per run recovery per run
HiPrep Desalting 26/10 2.5 -15 ml 7.5 - 20 ml 17-5087-01
HiTrap Desalting 0.25 - 1.5 ml 1.0 - 2.0 ml 17-1408-01
Fast Desalting PC 3.2/10 0.05 - 0.2 ml 0.2 - 0.3 ml 17-0774-01
PD-10 Desalting 1.5 - 2.5 ml 2.5 - 3.5 ml 17-0851-01
Table 6. Recommended HiTrap affinity columns for laboratory scale separation.
Code No. Quantity/ Approximate
Application HiTrap column
components binding capaci-
ty per ml gel
17-5079-01 5 x 1 ml human
Isolation of HiTrap rProtein A
17-5080-01 1 x 5 ml IgG 50 mg/ml
immunoglobulins
17-5029-02 2 x 1 ml
IgG classes, fragments
and subclasses
17-0402-01 5 x 1 ml human
IgG classes, fragments HiTrap Protein A
17-0402-03 2 x 1 ml IgG 20 mg/ml
and subclasses
17-0403-01 1 x 5 ml
17-0404-01 5 x 1 ml human
IgG classes, fragments HiTrap Protein G
17-0404-03 2 x 1 ml IgG 25 mg/ml
and subclasses
17-0405-01 1 x 5 ml
including human IgG3
strong affinity
to monoclonal mouse
IgG1 and rat IgG
Monoclonal and poly- MAbTrapTM GII 17-1128-01 HiTrap Protein G as above
clonal IgG from ascites column (1 ml),
fluid, serum and cell accessories, pre-made
culture supernatant buffers for 10 purifica-
tions
Mouse recombinant RPAS Purification 17-1362-01 HiTrap Anti-E column, 0.17 mg
Single chain antibody Module accessories, pre-made ScFv/5 ml
Fragment variable buffers for 20 purifica-
(ScFv) produced in tions
E.Coli
IgY antibodies from HiTrap IgY 17-5111-01 1 x 5 ml IgY 20 mg/ml
egg yolk Purification
IgM HiTrap IgM 17-5110-01 5 x 1 ml IgM 5 mg/ml
Purification
Group Specific Media: HiTrap Con A 17-5105-01 5 x 1 ml transferrin
Glycoproteins or 4 mg/ml
polysaccharides
Specificity: branched
mannoses,
carbohydrates
withterminal mannose
or glucose(a Man>
a Glc> GlcNAc)
Specificity: HiTrap Lentil 17-5106-01 5 x 1 ml thyroglobulin
branched mannoses Lectin 4 mg/ml
with fucose linked
a(1,6) to the N- acetyl-
glucosamine,
(a Man> a Glc>
GlcNAc) N- acetyl-
glucosamine binding
lectins
HiTrap column Code No. Quantity/ Approximate
Application
components binding capa-
city per ml gel
HiTrap Peanut 17-5108-01 5 x 1 ml asialofetuin
Specificity: Terminal ß
Lectin 3 mg/ml
-galactose, (Gal ß 1,3
GalNAc > a and ß Gal)
HiTrap Wheat 17-5107-01 5 x 1 ml ovomuroid
Specificity: chitobiose
Germ Lectin 4 mg /ml
core of N-linked oligo-
saccharides, [GlcNAc
(ß 1,4GlcNAc) 1- 2 >
ß GlcNAc]
HiTrap Lectin Test 17-5109-01 4 x 1 ml columns of as listed above
Specificity: as listed for
Kit HiTrap Con A
each column
HiTrap Lentil Lectin
HiTrap Peanut Lectin
HiTrap Wheat Germ
Lectin
Group Specific Media HiTrap Blue 17-0412-01 5 x 1 ml HSA 20 mg/ml
Various Nucleotide- 17-0413-01 1 x 5 ml
requiring enzymes,
coagulation factors,
DNA binding proteins,
a2-macro-globulin
Proteins and peptides HiTrap Chelating 17-0408-01 5 x 1 ml (His)6-tagged
with exposed amino 17-0409-01 1 x 5 ml protein (27.6
acids: His (Cys, Trp) kD) 12 mg /ml
e.g. a-2-macro-globu-
lin and interferon
Histidine-tagged fusion HisTrapTM 17-1880-01 HiTrap Chelating as above
proteins column (1 ml), acces-
sories, pre-made
buffers
Biotin and biotinylated HiTrap 17-5112-01 5 x 1 ml biotinylated
substances Streptavidin BSA 6 mg/ml
Coagulation factors, HiTrap Heparin 17-0406-01 5 x 1 ml ATIII (bovine)
lipoprotein lipases, 17-0407-01 1 x 5 ml 3 mg/ml
steroid receptors,
hormones, DNA
binding proteins,
interferon, protein
syntheses factors
Matrix for prepara- HiTrap 17-0716-01 5 x 1 ml ligand specific
tion of affinity media NHS-activated 17-0717-01 1 x 5 ml
Coupling of primary
amines
Recommended separation conditions
All HiTrap columns are supplied with a detailed protocol to ensure optimum results
Maximum flow rates: HiTrap 1 ml column: up to 4 ml/min
HiTrap 5 ml column: up to 20 ml/min
Table 7. Volatile buffer systems.
Volatile buffer systems used in ion exchange chromatography
pH range Buffer system Counter-ion pK-values for buffering ions
2.0 Formic acid H+ 3.75
2.3-3.5 Pyridine/formic acid HCOO- 3.75; 5.25
3.0-5.0 Trimethylamine/formic acid HCOO- 3.75; 9.25
3.0-6.0 Pyridine/acetic acid CH3COO- 4.76; 5.25
4.0-6.0 Trimethylamine/acetic acid CH3COO- 4.76; 9.25
6.8-8.8 Trimethylamine/HCl Cl- 9.25
7.0-8.5 Ammonia/formic acid HCOO- 3.75; 9.25
8.5-10.0 Ammonia/acetic acid CH3COO- 4.76; 9.25
7.0-12.0 Trimethylamine/carbonate CO32- 6.50; 9.25
7.9 Ammonium bicarbonate HCO3- 6.50; 9.25
8.0-9.5 Ammonium carbonate/ammonia CO32- 6.50; 9.25
8.5-10.5 Ethanolamine/HCl Cl- 10.0
8.5 Ammonium carbonate CO32- 6.50; 9.25
Extraction process Typical conditions Protein source Comment
Gentle erythrocytes E.coli
2 volumes water to lower product yield but
1 volume packed periplasm: intracellular reduced protease
Cell lysis (osmotic shock) pre-washed cells proteins release
Enzymatic digestion lysozyme 0.2 mg/ml, bacteria: intracellular lab scale only, often
37 °C, 15 mins. proteins combined with
mechanical disruption
Hand homogenisation follow equipment liver tissue
instructions
Mincing (grinding) " muscle
Moderate follow equipment muscle tissue, most
instructions animal tissues, plant
Blade homogeniser tissues
Grinding with abrasive " bacteria, plant tissues
e.g. sand
Vigorous follow equipment cell suspensions: small scale, release of
Ultrasonication instructions intracellular proteins in nucleic acids may cause
or cytoplasm, periplasm, viscosity problems
bead milling inclusion bodies inclusion
bodies must be
resolubilised
Manton-Gaulin follow equipment cell suspensions large scale only
homogeniser instructions
French press follow equipment bacteria, plant cells
instructions
Fractional precipitation see section on fractional extracellular: secreted precipitates must be
precipitation recombinants, resolubilised
monoclonal antibodies,
cell lysates
Details from Protein Purification, Principles and Practice, R.K. Scopes and other sources.
Table 9. Common substances used in sample preparation.
Typical conditions for use Purpose
Buffer components 20 mM, pH7.4 maintain pH minimise
Tris acidification caused by
lysosomal disruption
NaCl 100 mM maintain ionic strength of
medium
EDTA 10 mM reduce oxidation damage,
chelate metal ions
Sucrose or glucose 25 mM stabilise lysosomal membra-
nes, reduce protease release
Detergents See Table 10 extraction and purification of
lonic or non-ionic detergents integral membrane proteins
solubilisation of poorly soluble
proteins
DNAse and RNAse 1 μg/ml degradation of nucleic acids,
reduce viscosity of sample
solution
Protease inhibitors* Inhibits
0.5 - 1 mM
PMSF serine proteases
0.4 - 4 mM
APMSF serine proteases
0.2 mM
Benzamidine-HCl serine proteases
1 μM
Pepstatin aspartic proteases
10 - 100 μM
Leupeptin cysteine and serine proteases
10 - 100 μM
Chymostatin chymotrypsin, papain,
cysteine proteases
1 - 100 μM
Antipain-HCl papain, cysteine and serine
proteases
2 - 10 mM
EDTA metal dependent proteases,
zinc and iron
2 - 10 mM
EGTA metal dependent proteases
e.g. calcium
Reducing agents 1 - 10 mM keep cysteine residues
1, 4 dithiothreitol, DTT reduced
1 - 10 mM
1, 4 dithioerythritol, DTE
"
0.05%
Mercaptoethanol
"
Others 5 - 10% for stabilisation, up to 50% can
Glycerol be used if required
PMSF - Phenylmethylsulfonyl fluoride
APMSF - 4-Aminophenyl-methylsulfonyl fluoride
PMSF is a hazardous chemical. Half-life time in aqueous solution is 35 min. PMSF is usually stored
as 10 mM or 100 mM stock solution (1.74 or 17.4 mg/ml in isopropanol) at - 20° C.
* Protease inhibitors are available in pre-made mixes from several suppliers.
Details taken from Protein Purification, Principles and Practice, R.K. Scopes. 1994, Springer.,
Protein Purification, Principles, High Resolution Methods and Applications, J-C. Janson and L.
Rydén, 1998, 2nd ed. Wiley Inc. and other sources.
Table 10. Examples of ionic and non-ionic detergents.
Sodium dodecyl sulphate 0.1 - 0.5% denatures proteins, used for SDS-PAGE
use non-ionic detergents to avoid
denaturation
Triton-X-100 0.1 % non-ionic detergent for membrane
solubilisation.
Note: may absorb strongly at 280 nm!
Nonidet-P-40 0.05 - 2% "
Dodecyl b D maltoside 1% "
Octyl b D glucoside 1 - 1.5% "
For further information on detergents: Protein Purification, Principles, High Resolution Methods and
Applications, J-C. Janson and L. Rydén, 1998, 2nd ed. Wiley Inc.
Pre-packed column Sample volume Sample volume Code No.
loading per run recovery per run
HiPrep Desalting 26/10 2.5 -15 ml 7.5 - 20 ml 17-5087-01
HiTrap Desalting 0.25 - 1.5 ml 1.0 - 2.0 ml 17-1408-01
Fast Desalting PC 3.2/10 0.05 - 0.2 ml 0.2 - 0.3 ml 17-0774-01
PD-10 Desalting 1.5 - 2.5 ml 2.5 - 3.5 ml 17-0851-01
Precipitation agent Typical conditions for use Sample type Comment
Ammonium sulphate as described >1mg/ml proteins stabilizes proteins, no
especially immuno- denaturation, super-
globulins natant can go directly
to HIC
Dextran sulphate as described samples with high precipitates lipoprotein
levels of lipoprotein
e.g ascites
Polyvinylpyrrolidine Add 3% (w/v), stir 4 hours, alternative to dextran
"
centrifuge, discard pellet sulphate
Polyethylene glycol up to 20% wt/vol plasma proteins no denaturation super-
(PEG, M.W. >4000) natant goes direct to
IEX or AC. Complete
removal may be difficult
Acetone up to 80% vol/vol at 0 °C useful for peptide may denature protein
precipitation or con- irreversibly
centration of sample
for electrophoresis
Polyethyleneimine 0.1% w/v precipitates aggregated
nucleoproteins
Protamine sulphate 1%
"
Streptomycin sulphate 1% precipitation of nucleic
acids
Details taken from Protein Purification, Principles and Practice, R.K. Scopes. 1994, Springer.,
Protein Purification, Principles, High Resolution Methods and Applications, J-C. Janson and L.
Rydén, 1998, 2nd ed. Wiley Inc.and other sources
Table 13. Examples of denaturing agents.
Denaturing agent Typical conditions for use Removal/comment
Urea 2 - 8M remove using Sephadex G25
Guanidine hydrochloride 3 - 8M remove using Sephadex G25 or
during IEX
Triton X-100 with 2% â€
Sarcosyl 1.5% â€
N-octyl glucoside 2% â€
Sodium dodecyl sulphate 0.1 - 0.5% exchange for non-ionic detergent during
first chromatographic step, avoid anion
exchange chromatography
alkaline pH > pH 9, NaOH may need to adjust pH during
chromatography to maintain solubility
Details taken from Protein Purification, Principles and Practice, R.K. Scopes. 1994, Springer.,
Protein Purification, Principles, High Resolution Methods and Applications, J-C. Janson and
L. Rydén, 1998, 2nd ed. Wiley Inc.and other sources
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