Separation Science

Question 1

Properties of proteins

Answer 1

Mass Charge – pH Hydrophobic/Hydrophilic Properties Differential Solubility Mobility in Applied Fields

Question 2

Sep science

Answer 2

• Centrifugation
• Mass – acceleration
• Density – mass to volume ratio
• Dialysis
• Mass transport
• Size exclusion
• Lyophilisation
• Freeze-drying
• Precipitation
• Differential solubility

Question 3

Centrifugation

Answer 3

Question 4

Centrifuge g-value – Relative Centrifugal Force (RCF)

Answer 4

•The ‘g-force’ of a centrifuge is calculated from the following formula:

g=11.18 ×r × (n/1000)2

• where g is the equivalent gravitational force (1 ×g = 9.8 ms-2)
• ris the length of the rotor, cm
• nis the number of revolutions per minute, RPM

Question 5

Centrifugation field

Answer 5

Question 6

Principles of centrifugation

Answer 6

Question 7

Centrifuge classes

Answer 7

Question 8

Differential centrifugation

Answer 8

•Differential Sedimentation (standard pelleting)

•

•Change the properties of the centrifugation medium to provide differential mobility of target proteins or organelles.

•

• DensityGradientCentrifugation
• RateZonal Centrifugation –eg. Sucrose
• IsopycnicCentrifugation –eg. CsCl
• Isopycnic– fluid of the same density

Question 9

Preparation of the Density Gradient

Answer 9

Question 10

Sucose density gradient

Answer 10

Question 11

Isopycnic centrifugation

Answer 11

Isopycniccentrifugation of 15N

labelled community DNA in

CsCl/ethidiumbromide densitygradients.

A mixture of labelled(15N)

and unlabelled (14N) DNA,

extracted from Nitrosomonaseuropaea.

L, M, H in (A) indicate the positions of light,

medium, and heavy DNA bands, respectively

Question 12

Gradient centrifugation

Answer 12

Question 13

Sedimentation Coefficients

Answer 13

• Depends on the Mass and shape
• Transport property
• Svedberg Unit (non-SI unit)
• Molecule of 26 S will travel
• 26 µm per second in 106g

Question 14

Ribosome Subunits

Answer 14

• Nobel Prize in Chemistry 2009
• “for studies of the structure and function of the ribosome
• The two eukaryotic ribosomal subunits have sedimentation coefficients of 40 x 10-13 and 60 x 10-13. As one Svedberg (S) unit is 10-13, the two ribosomal subunits are referred to as the 40S and the 60S ribosomal subunits.

Question 15

Dialysis Membranes

Answer 15

• Pore sizes in the membrane
• Size separation
• Porous to small molecules
• Size cut-off
• Semi-permeable membranes
• Desalination
• Chemical Potential
• Partial Molar Free Energy

Question 16

Dialysis

Answer 16

Question 17

Dialysis examples

Answer 17

• Membranes–collodion, cellophane and cellulose. ‘Viskingtubing’. Needs to be boiled and treated with EDTA to remove contaminating materials eg. Heavy metals before use. Usual tubing 10-14,000 MW cut-off.
• Ultrafiltrationdevicesuse a membrane (polycarbonate or cellulose esters) and rely on pressure or centrifugation to force liquid through.

These are used toconcentrate protein to smaller volume remove turbidity or insoluble material

Question 18

Lyophilisation - phase diagram

Answer 18

• Freeze-Drying- removal of solvent from frozen sample.
• Often used for storage of material.
• Can cause protein denaturationand aggregation.
• Good for temperature sensitive material.
• Freeze sample and then put under a vacuum to remove water.
• Need to control since if you remove all of the water from a protein it will denature.
• Protein protectants– sugars polyols, glocols

Question 19

Separation by precipitation

Answer 19

•Precipitation with organic solvent:

• Not used much today since it can result in protein denaturation.
• Solvents used ethanol or acetone.
• Principal effect is reduction of water activity.

•DNA Extraction:

•Base sequence is preserved

Question 20

Salting out

Answer 20

• Salts compete for the solvation shell of the protein and destabilise solution
• Multivalent cations
• phosphate and sulfate
• Usually potassium, sodium or ammonium.
• Salt used most commonly is ammonium sulfate.
• Needs to be ‘enzyme grade’ as often contaminated with heavy metals which interact with cysteine residues

Question 21

Solubility Stability

Answer 21

•Proteins are usually least soluble around their isoelectricpoints (electrically neutral)

•Kosmotropes and Chaotropes

• Kosmotropes– order maker
• Chaotropes– disorder maker
• Entropy – fundamental measure of order and disorder
• Small ionic species that cover the surface of a charged protein

Question 22

Kosmotropes and Chaotropes

Answer 22

Kosmotropes increase the interactions order within the water by increasing or making order

Chaotropesdecrease the interactions within the water decreasing the order

Question 23

Ammonium Sulfate Fractionation

Answer 23

• Ammonium Sulphate Saturation Table
• Quantities of ammonium sulphate required to reach given degrees of saturation at 20oC
• Work out how much ammonium sulphate you need to add depending on your volume of extract. Add slowly while stirring on ice.
• Centrifuge, separate pellet and supernatant and add further ammonium sulphate to supernatant to reach next required concentration and repeat above.

Question 24

Ammonium Sulphate Precipitation
Procedure

Answer 24

• Take sample in a beaker containing a stir bar and place on magnetic stirrer
• While sample is stirring, slowly add ammonium sulfateof a desired saturation level (Can refer ammonium sulphate precipitation chart)
• Add ammonium sulfatevery slowly to ensure that local concentration around the site of addition does not exceed the desired salt concentration.
• Once total volume of ammonium sulfateis added, move beaker to 4°C for 6 hours or overnight.
• Collect the precipitate from the beaker and centrifuge the precipitate at 5000g for 20 minutes.
• Carefully remove and discard supernatant. Invert the tube and drain well
• Give two or three wash with distilled water
• Dissolve the precipitate in phosphate buffer saline and dialyze protein solution at low temperature overnight to get removed salt
• Determine the concentration and store at -10°C for long term storage.

Question 25

Ammonium SulfateFractionation

Answer 25

Number of g of Ammonium Sulphate

to be added to 1 L to produce a

change in % saturation

Top row – 0 – 65% requires 430g

33 – 70% requires 250 g