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Transcript
Protein Purification and
Characterization Techniques
Chapter 5
How can proteins be extracted from
cells?
•
Many steps/techniques are needed to extract
and separate protein of interest from many
contaminants
•
Separation techniques – size, charge and
polarity
•
Before purification begins, protein must be
released from cell by homogenization
How do we get the proteins out of the cells?
What are different ways of homogenization of
cells?

-
Grinding tissue in a blender with a suitable buffer
Releases soluble proteins and various subcellular organelles
-
Potter-Elvejhem homogenizer – A thick walled test tube
with a tight fitting plunger
Breaks open cells – organelles intact

Sonication – Sound waves to break open cells

Continuous freezing and thawing – Ruptures cells

Differential Centrifugation
•
Sample is spun, after
lysis, to separate
unbroken cells, nuclei,
other organelles and
particles not soluble in
buffer used
•
Different speeds of spin
allow for particle
separation
What is Salting out?

Ammonium sulfate (NH4SO4) - used to “salt out”
Takes away water by interacting with proteins
- makes protein less soluble because hydrophobic
interactions increases among proteins


-
Addition of salt – increases saturation
Different set of proteins precipitate
Centrifuge and save the set of proteins
What is Column Chromatography?
Basis of Chromatography
•
Different compounds distribute themselves to a
varying extent between different phases
•
2 phases:
• Stationary: Samples interacts with this phase
• Mobile: Flows over the stationary phase and carries
along with it the sample to be separated
Column Chromatography
What is Size-exclusion/Gel-filtration
chromatography?
•
Separates molecules based
on size (molecular weight).
•
Stationary phase composed
of cross-linked gel
particles (Beads).
•
Two polymers –
Carbohydrate polymer such
as dextran (Sephadex) or
agarose (Sepharose)
•
Polyacrylamide (Bio-Gel)
What is Size-exclusion/Gel-filtration
chromatography?
•
Extent of cross-linking can
be controlled to determine
pore size
•
Smaller molecules enter the
pores and are delayed in
elution time.
•
Larger molecules do not
enter and elute from column
before smaller ones
Advantages of Size-exclusion/Gelfiltration chromatography
 Separate
 Estimate
molecules based on size
molecular weight by comparing
sample with a set of standards
What is Affinity Chromatography?
•
Uses specific binding
properties of
molecules/proteins
•
Stationary phase has a
polymer that is covalently
linked to a compound called
a ligand
•
Ligands bind to desired
protein or vice versa
•
Proteins that do not bind to
ligand elute out
What is Affinity Chromatography?
 Bound
protein can be eluted from column by
adding high concentrations of ligand in
soluble/mobile form.
– proteins bound to ligand in
column will bind to mobile ligands
 Competition
 Recovered
proteins
from column – Produces pure
What is Ion-exchange chromatography?
•
Interaction based on overall
charge (less specific than
affinity)
•
Cation exchanger –
negatively charged resin –
bound to Na+ or K+ ions
•
Anion exchanger –
positively charged resin –
bound to Cl- ions
•
Figure 5.7 A and B
What is Ion-exchange chromatography?




Column is equilibrated with
buffer of suitable pH and
ionic strength
Exchange resin is bound to
counterions
Proteins – net charge
opposite to that of
exchanger stick to column
No net charge or same
charge elute - first
What is Electrophoresis?
•
Electrophoresis- Charged
particles migrate in electric
field toward opposite charge
Differences between agarose and
polyacrylamide gels
Agarose - matrix for
nucleic acids

•
Charge, size, shape

•
Agarose matrix has more
resistance towards larger
molecules than smaller

•
•
Small DNA move faster
than large DNA



Polyacrylamide - proteins
Charge, size, shape
Treated with detergent
(SDS) sodium dodecyl
sulfate – gains –ve charge
Random coil – shape
Polyacrylamide has more
resistance towards larger
molecules than smaller
Small proteins move faster
than large proteins
What is Isolectric focusing?
•
Gel is prepared with pH gradient that parallels
electric-field
•
Charge on the protein changes as it migrates
across pH
•
When it gets to pI, has no charge and stops
•
Separated and identified on differing isoelectric pts.
(pI)
What is two-dimensional gel
electrophoresis?
 Isoelectric
focussing in one dimension and
SDS-PAGE running at 90 degree angle to the
first
How is 1˚ structure determined?
1)
Determine which amino acids are present and in
what proportions (amino acid analyzer)
2)
Specific reagents - determine the N- and C- termini
of the sequence
3)
Cleave - determine the sequence of smaller peptide
fragments (most proteins > 100 a.a)
4)
Some type of cleavage into smaller units necessary
Primary Structure Determination
What is Edman degradation?
Cleaving of each amino acid in sequence followed by
their subsequent identification and removal
 Becomes difficult with increase in number of amino
acids
 Amino acid sequencing - Cleave long chains into
smaller fragments

Protein Cleavage

Enzymes or Chemical
reagents

Trypsin- Cleaves @ Cterminal of (+) charged side
chains/R-groups

Chymotrypsin- Cleaves @
C-terminal of aromatics
Figure 5.17
Cleavage by Chemical reagent

Cyanogen bromide

Cleaves @ C-terminal of
INTERNAL methionines

Sulfur of methionine reacts
with carbon of cyanogen
bromide to produce a
homoserine lactone at Cterminal end of fragment
Use different cleavage reagents to
help in 1˚ determination
Determination of primary structure of
protein
•
After cleavage, mixture of peptide fragments
are produced.
•
Sequences can overlap – peptides can be
arranged in proper order after all sequences
have been determined
•
Can be separated by HPLC or other
chromatographic techniques
Peptide sequencing by Edman
Degradation
•
Can be accomplished by Edman Degradation
•
Sequencer - relatively short sequences (30-40 amino
acids in 30-40 picomoles) can be determined quickly
•
N-/C-terminal residues - not done by
enzymatic/chemical cleavage
Peptide sequencing by Edman
Degradation





Edman’s reagent – Phenyl
isothicocyanate
Reacts with peptide’s Nterminal residue – cleaved
Leaves rest of peptide intact
– phenylthiohydantoin
derivative of amino acid
Same treatment to 2,
3,4….40
Automated Sequencer –
Process repeated
DNA sequencing

Preferred to amino acid sequencing

Easy to obtain sequence of DNA to that of protein

DNA sequencing does not determine positions of
disulfide bonds or detect amino acids like
hydroxyproline



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