Protein purification

Question 1

What are the two main frameworks for protein purification?

Answer 1

• Purification from naturally available sources (organs, tissues, cell culture…
• Using recombinant technologies (following introduction of expression vectors encoding a protein of interest into host cells)

Question 2

Which source/host can….

i. Give a high yield
ii. give a high yield, but is difficult to get a hold of
iii. Give a lot of material from fermentation
iv. Is often a very good source of material

Answer 2

i. Plant cells
ii. Animal cells
iii. Bacteria
iv. Yeast

Question 3

Which measures need to be taken in a protein purification procedure when activity is essential, regarding the host?

Answer 3

The source/host has to allow correct folding and post-translational modifications when required.

This is relevant with regard to the use of recominant technologies.

Question 4

Which measures need to be taken in a protein purification procedure when activity is essential, with regard to the steps of the procedure?

Answer 4

Taking steps to protect activity of protein by:

a) Adding stabilisers
b) Reducing the number of purification steps to the bare minimum so as to minimise activity loss
c) Working quickly at low T

Question 5

What are the 4 general steps of protein purification?

Answer 5

1. Choice of framework and source/host.
2. Extraction, solubilisation and choice of solvents (for protein of interest to be intact&functional, if required)
3. Protein separation procedures, many of which are based on chromatography
4. Analysis of protein purity, molecular properties and functionality

Question 6

What are the most important factors to take into account when making choices about protein sources/hosts? (6)

Answer 6

• Characteristics of the desired protein (properties of the protein can change with the source/host)
• Source availability
• Yield of product
• Safety considerations
• Regulatory constraints and patenting issues
• Consumer perception

Question 7

How is a cell extract made?

Answer 7

1. Culture cells
2. Separate intro centrifuge pots and centrifuge at 10-15000g
3. Take cell pellet, resuspend in extraction buffer and subjected to breakage

Cell extract!

Question 8

What is cell breakage/homogenisation?

Answer 8

The plasma membrane is raptured and the contents are released.

Question 9

What are the two main categories of homogenisation techniques?

Answer 9

Mechanical: liquid shear (ultrasound, agitation, pressure) and solid shear (grinding, pressure)

Non-Mechanical: _Dessication (_air, vacuum, freeze or solvent drying) or Lysis (physical [osmotic shock, freeze-thaw, pressure release], chemical [cationic and anionic detergents], enzymatic [lysozyme and related enzymes])

Question 10

What does a homogeneate contain? (8)

Answer 10

Cell wall fragments, membrane fragments, fibrous tissue, intracellular organelles, soluble and insoluble protein, NA, carbohydrates

Question 11

What is the difference between cytosol and cytoplasm?

Answer 11

Cytoplasm: aqueous cell contents and suspended particles/organelles.

Cytosol: portion of the cytoplasm that remains in the supernatant after centrifugation of a homogeneate at 150,000g for 1h. It contains concentrated solution of enzymes.

Question 12

What is differential sedimentation?

Answer 12

Cell extract: contains a mixed suspension of organlles and particles of all sizes ⇒ centrifugate at low speed ⇒ P1 contains largest components ⇒ Take SN1, centrifugate at higher speed ⇒ P2 predominantly contains medium-sized particles ⇒ Take SN2, centrifugate ⇒ P3 contains the remaining small particles.

Question 13

Name 4 ways of “dealing with the lipid” to release membrane-associated and membrane-integral proteins

Answer 13

1. Ultrasonication ( break cells with high freq sound)
2. Detergent solubilisation (like dissolves like)
3. Organic solvent extraction
4. Digestion of phospholipid

These are normally followed by centrifugation.

Question 14

How is denaturation prevented?

Answer 14

• Avoid extremes of pH and temperature: use buffers around neutrality, carry out initial steps on ice
• Avoid organic solvents and chaotropic agents such as urea and guanidinium

Question 15

What is a chaotropic agent?

Answer 15

A chaotropic agent is a molecule in water solution that can disrupt the hydrogen bonding network between water molecules

Question 16

How is inactivation avoided? (3)

Answer 16

Inactivation is defined as the disruption of the active site of the enzyme, which is extremely reactive. To prevent this, we must

• Avoid oxidising conditions, especially if protein contains C-C bonds (reducing agents such as DTT or BME can be added)
• Add chelatros (EDTA, EGTA) to avoid metal ions
• Stabilise cofactor-requiring enzymes by adding the appropriate cofactor to the extraction/purification buffers.

Question 17

How is proteolysis avoided?

Answer 17

• Work fast and at low T to avoid proteolytic damage
• Add cocktails of protease inhibitors

Question 18

True or false:

Bufferin capacity of a buffer drops dramatically 1 pH unti either side of their pKa.

Answer 18

TRUE

Question 19

Should a buffer be used outside of its buffering capacity range?

Answer 19

Nope.

Question 20

Name 4 commonly used buffers.

Answer 20

HEPES, Phosphate, Succinate, TRIS

Question 21

How does dialysis work?

Answer 21

From Tutorial 6:

Dialysis facilitates the removal of small, unwanted compounds from macromolecules in solution. In this case, it facilitates the removal of ammonium sulphate from the proteins in solution.

This is done by placing the protein solution, or sample, in a dialysis tube that is enclosed by a semi-permeable membrane, and placing the tube inside a vessel containing buffer solution. The semi-permeable membrane has pores of a specific size, which will allow small molecules such as salt ions to diffuse freely towards the buffer solution following a concentration gradient, but at the same time will retain the larger molecules inside the tube. Thus, the concentration of ions in the protein solution will be effectively reduced.

Question 22

What’s a protease inhibitors that is effective against serine proteases?

Answer 22

PMSF (phenylmethylsulphonyl fluoride)

Question 23

What’s a protease inhibitor effective against proteases that contain metal ions?

Answer 23

Chelating agents such as EDTA.

Question 24

What’s a protease inhibitor effective against cysteine-dependent proteases?

Answer 24

Cysteine reagents.

Question 25

What’s a protease inhibitor effective against acid proteases?

Answer 25

Pepstatin A

Question 26

What are th two main types of protein separation procedures?

Answer 26

• Crude protein separation (salt precipitation)
• Chromatography based procedures

Question 27

What is the principle of salt precipitation?

Answer 27

From Tutorial 6:

Ammonium sulphate is one of the most widely used agents in protein separation and protein purification through the process of salting-out. This method is based on the disparities in protein solubility in aqueous solution at different concentrations of salt.

When in aqueous solution, a protein is surrounded by a hydration shell. Ammonium sulphate (and other similar agents) can be used to strip the water molecules away from the protein and eliminate the hydration shell, thus forcing the proteins to interact with each other and precipitate. Given that different proteins have different compositions, i.e. different ratios of hydrophilic and hydrophobic patches, they precipitate at different salt concentrations.

When the salt concentration is low, its presence stabilises the various charged groups on the protein, thus attracting the protein into the solution and enhancing its solubility (salting-in). However, as the salt concentration increases, a point of maximum solubility is attained, after which, assuming that the concentration of salt continues to increase, there won’t be sufficient water molecules to interact with the protein molecules (salting out). This is when the protein starts to precipitate. A diagram of the process is provided below.

Question 28

What is the principle of separation in chromatography-based methods?

Answer 28

As proteins migrate through the column, they are retarded to different degrees by their different interactions with the matrix material. Individual types of proteins (such as A, B, and C) gradually separate from each other, forming bands and eluting separately.

Question 29

What are the stationary phase and the mobile phase? (in general, for chromatography-based purification procedures)

Answer 29

Stationary phase- solid porous matrix

Mobile phase- solution from the reservoir and solution containing mixture of proteins (protein sample)

Question 30

What is the separation principle behind size exclusion chromatography?

Answer 30

Gel filtration separates proteins according to their size and shape.

Question 31

What is the separation principle behind chromatofocusing?

Answer 31

The PI of different proteins

Question 32

What is the separation principle behind affinity chromatography?

Answer 32

It exploits a particular biological function (binding affinity).

Question 33

How does gel filtration chromatography work?

Answer 33

The underlying principle behind this method is that different proteins vary in size and shape, and thus can be separated accordingly. A solution containing a variety of proteins, including the protein of interest, flows through a separation column. The matrix of the column contains a cross-linked polymer of beads that have pores of a certain size.

When the mixture of proteins travels through the column, the smaller proteins will be retained in the pores and will take longer to make their way through the column because they will follow a more intricate path. On the other hand, larger proteins will not be retained in the pores and thus will migrate through the column a lot faster, i.e. they will elute earlier. Different fractions can be collected and then assayed for specific enzyme activity.

Proteins whose Mr is above the exclusion limit are consequently excluded from penetrating the gel matrix.

Question 34

How does ion exchange chromatography work?

Answer 34

Specific proteins have distinct net electric charges at a given pH, due to the ionisation state of the amino acid side chains that they’re made up of. These differences in net charge between different proteins can be exploited for protein separation and purification by using ion exchange chromatography.

The matrix of the separation column for anion exchange chromatography contains positively charged particles, which locks the more negatively charged proteins to the matrix, while more positively charged proteins will have little or no affinity for the synthetic polymer in the matrix and will flow through the column.

To elute the proteins that are tightly bound to DEAE-cellulose, the protein-matrix interactions must be broken. This can be achieved by gradually increasing the concentration of competing free salt in the surrounding solution, a method that is known as elution by anionic counter ion.

Question 35

In anion exchange chromatography, the matrix is ________ charged.

Answer 35

Positively

Question 36

In cation exchange chromatography, the matrix is ________ charged.

Answer 36

Negatively.

Question 37

Above its PI value, a protein has a _____ charge.

Answer 37

Negative

Question 38

Below its PI value, a molecule has a _______ charge.

Answer 38

Positive.

Question 39

What is the underlying principle of ion exchange chromatography?

Answer 39

Separating proteins using theri net charge at a given pH:

At a given pH, proteins which have different PI valuse will have a different charge.

Question 40

What is the basis of hydrophobic interaction chromatography?

Answer 40

HIC exploits the differences in hydrophobicity of proteins. The matrix is a synthetic polymer containing bound hyrdophobic groups.

Contrary to ion-exchange, binding is at high salt, elution is at low salt: water shield hydrophobic interactions between protein and matrix, salt strips away the water and allows the interactions to take place.

More in detail:

Close to the surface of the hydrophobic ligand and solute, the water molecules are more highly ordered than in the bulk water and appear to ‘‘shield off’’ the hydrophobic ligand and the hydrophobic protein patch. Added salt interacts strongly with the water molecules leaving less water available for the ‘‘shielding off’’ effect.

Question 41

What is the basis of affinity chromatograpy, and how does it work?

Answer 41

AC separates proteins by exploiting their binding specificities, i.e their biological function.

Proteins retained on the column are those that bind specifically to a ligand, cross-linked to the beads.

Proteins that do not bind to the ligand are washed thorugh and the bound protein of interest is eluted by a solution containing free ligand or other competing small molecule.

Question 42

Which methods are used to analyse the purity, properties and functionality of a purified protein? (4)

Answer 42

1. Measuring protein amounts/concentration
2. Assessing protein heterogeneity
3. Determining molecular mass
4. Enzyme assays and other functional assays

Question 43

True or false:

Spectrophotometric methods are often used to measure protein concentration.

Answer 43

So true.

Question 44

What is the Beer-Lambert law?

Answer 44

Question 45

What is the principle of the SDS page?

Answer 45

Protein is denatured with heat. Also, thiols are added in order to remove the disulphide bonds that contribute to stabilising the protein’s tertiary structure.

Protein is treated with SDS (sodium dodecyl sulfate):SDS molecules bind to the unfolded peptide chain and give them a strong, uniform -ve charge.

This allows size to be the only separation principle, as charge is uniform.

Question 46

True or false:

SDS page allows to determine the native (non-denatured) size of the protein.

Answer 46

False, that’s size exclusion.

Question 47

How can we determine the non-denatured, native Mr of a protein?

Answer 47

By means of size exclusion chromatography:

Ve (elution volume) depends mainly on molecular size.

By comparing the Ve of a protein of interest with that of a known standard, its Mr can be determined.

Question 48

What is the general principle of MS?

Answer 48

Molecules to be analyzed are first ionized in a vacuum. When the newly charged molecules are introduced into an electric and/or magnetic field, their paths through the field are a function of their mass-to-charge ratio, m/z. This measured property of the ionized species can be used to deduce the mass (M) of the molecule with very high precision.

Question 49

What are two MS methods for analysis of proteins?

Answer 49

MALDI MS (matrix-assisted laser desorption/ionisation MS)

ESI MS (electrospray ionisation MS)

Question 50

How does ESI MS work?

Answer 50

A protein solu@on is dispersed into highly charged droplets by passage through a needle under the influence of a high-voltage electric field. The droplets evaporate, and the ions (with added protons) enter the mass spectrometer for m/z measurement.

The spectrum generated is a family of peaks, with each successive peak corresponding to a charged species increased by 1 in both mass and charge. A computer-generated transformation of this spectrum is shown in the inset.

Question 51

What are the 3 basic components of an enzyme assay?

Answer 51

1. Reaction mixture (includes buffer, substrate, cofactors or stabilisers if required by enzymes), often brought to T of the assay prior to initiating the reaction.
2. Initiating the incubation by addition of enzyme or fractions from a purification protocol.
3. Some assays require termination by inactivating the enzyme, which can sometimes be combined with colour development.

Question 52

What are the units of enzyme activity?

Answer 52

micro moles/ min

Enzyme activity is defined as the amount of enzyme that catalyses the conversion of 1 micromole of substrate per minute under defined conditions of temperature and pH.

Question 53

What is activity?

Answer 53

Total units of enzyme in a solution (remains the same throughout purification)

Question 54

What is specific activity?

Answer 54

number of enzyme units per miligram of total protein (activity expressed as a ratio)

It is a measure of enzyme purity: increases throughout purification procedure, becomes maximal and constant when enzyme is pure.

Question 55

How is the final purification fold calculated?

Answer 55

e.g in a 5 step purification procedure

Overall /final purification factor (fold) = Specific Activity at step 5/Specific Activity at step 1

Question 56

How is the overall yield (%) calculated?

Answer 56

e.g in a 5 step procedure

Overall yield (%) = [Activity (total) at step 5/ Activity (total) at step 1] x 100

Question 57

What is homologous protein production?

Answer 57

The removal or isolation of a gene sequence/cDNA derived from a particular species and to subsequently produce its gene productby recombinant means in the same species.

In this case the host cell is producing a recombinant protein that it is capable of producing naturally. In these cases the manipulation may allow the product to be produced in higher quantities and problems such as gene repression can be over come. + OSDM, maybe?

Question 58

What is heterologous protein production?

Answer 58

The expression of recombinant proteins in cells which they do not naturally occur is termed heterologous expression. The vast majority of recombinant proteins are produced in this way

Question 59

Name 4 host cells

Answer 59

1. Bacteria (E.Coli)
2. Yeasts
3. Insect cells

(these first three can be grown in great quantities)

4. Mammalian cells (if protein to be purified requires post-translational modifications)

Question 60

What are expression vectors?

Answer 60

Expression vectors include a gene of interest that can be modified by adding “tags” to generate fusion-recombinant proteins
Tags for affinity purification, sometimes also solubility

e.g polyHis, GST, FLAG-peptide, MBP

Question 61

How are tags introduced?

Answer 61

Question 62

What is the main function of tags?

Answer 62

To allow for simpler purification based on one, single affinity chromatography step.

Question 63

What are the IL and what is used for elution of

a) Poly-His
b) GST
c) FLAG-peptide
d) MBP

Answer 63

a) Ni2+, Co2+ - Imidazole
b) Glutathione - reduced glutathione
c) Anti-FLAG monoclonal antibody - FLAG-peptide
d) Cross-linked amylose (maltose)-Maltose (disaccharide derived from amylose)

Question 64

What is IMAC?

Answer 64

Immobilised metal ion affinity chromatography, basis for affinity chrm with GST tag

Question 65

Explain purification with affinity chrm using GST

Answer 65

Question 66

Explain purification with affinity chrm using a His6 tag bound to MBP and recombinant TEV-protease with a His6 tag

Answer 66

MBP is only used for solubility and purifica.on is based on His6 tag (IMAC)

Recombinant TEV- protease also has His6 tag and is retained on the matrix together with cleaved His6-MBP tags.

Only cleaved target protein is unbound (in flow through = ft)

Question 67

How can tags be used for detection?

Answer 67

Antibodies can be used to recognize a tag in a recombinant fusion protein- can be used to detect the protein for example by Western blotting

Question 68

4 adv and 4 disadv of heterologous protein production in E.Coli

Answer 68

Question 69

One of the disadv of heterologous protein production in E.Coli is the formation of inclusion bodies. What are the causes?

Answer 69

• Very high local concentrations of expressed protein in the cytoplasm lead to non-specific precipitation
• Insufficient chaperones to aid in the correct folding with subsequent aggregation of partially folded and mis-folded intermediates

Question 70

6 ways of facilitating the production of soluble heterologous proteins in bacteria (i.e approaches to avoid the production of inclusion bodies)

Answer 70

• Empirical determina@on of the op@mal expression system in terms of host strain, plasmid, plasmid copy number and promoter sequence etc.
• Expression of the desired product as a fusion protein, fused to a highly soluble and na@ve host cytoplasmic protein.
• Expression behind an export signal such as a signal sequence that directs the expressed protein to the periplasmic space or out of the cell completely.
• Co-expression with chaperone proteins that improve the solubility of the expressed protein by aiding in the folding pathway of the protein.
• Providing appropriate cofactors that may increase the soluble yield of a recombinant protein requiring that cofactor.
• Growth of the recombinant cells at sub-op@mal temperatures: growth of E. Coli cells at lower temperatures than op@mal oIen discourages inclusion body forma@on.

Question 71

What are the 3 major effects that the advent of recombinant DNA technology has had on the science of protein purification?

Answer 71

1. Overcoming problems of source availability
2. Overcoming problems of source safety
3. Modifications made possible

Question 72

Overcoming problems of source availability

Answer 72

Many naturally occurring proteins are expressed at low level (e.g. cytokines) or may only exist in difficult sources (e.g. human tissue).

High level of expression achieved by recombinant technology
results in high specific ac.vity in the cell extract and consequently fewer purifica.on steps and overall fold-purifica.on is needed to achieve the required level of purity.

Question 73

Overcoming problems of source safety

Answer 73

Some proteins are produced naturally by dangerous or pathogenic species (e.g. microbial pathogens, snakes etc.); there is a possibility of dangerous contaminants during purifica.on or in the final product.

Furthermore associated hazards may not be clearly defined
(you may not know what problems are associated with a par.cular .ssue).

Recombinant technology procedures are developed within strict, standardized regula.ons.

Question 74

Modifications are possible

Answer 74

target protein can be modified if desired by procedures (such as site-directed mutagenesis) which can lead to improved quali.es of the desired product and/or facilitate purifica.on (e.g. tags)

The tag itself may enhance stability and solubility of the protein.

Very large purifica.on in a single step usually results from the use of affinity chromatography based on a specific tag.

Question 75

4 examples of proteins produced recombinantlu of industrial/medical significance

Answer 75

Insulin

Glucagon

HCG

Blood factors

Question 76

3 factors that influence the acceptability of genetically engineered proteins

Answer 76

1. benefit to user (whether or not it cures life threatening diseases)
2. Intimacy with product
3. May be the only source?

Question 77

What is insulin used for?

Answer 77

Treatment of type I diabetes, as the hormone is no longer produced internally. Also used in over 40% of type II diabetes patients

Question 78

adv and siadv of recombinant insulin

Answer 78

Question 79

What is chymosin? what are its adv and disadv?

Answer 79

Acid protease used to produce milk solids for cheese manufacture.

Question 80

What are the adv and disadv of recombinant proteases, lipases and amylases used as biological cleaning agents?

Answer 80