BCH401G: CH5
11. Recall What is the basis for the separation of proteins by the follow- ing techniques? (a) gel-filtration chromatography (b) affinity chromatography (c) ion-exchange chromatography (d) reverse phase HPLC
(a) Size. (b) Specific ligand-binding ability (c) Net charge (d) Polarity.
peptide sequencing
*can be accomplished by edman degradation *relatively short sequences (10-40 amino acids) can be determined quickly *so efficient, today N/C-terminal residues usually not done by enzymatic/chemical cleavage
which would be best to separate positively charged proteins
Cation exchanged
electrophoresis separates molecules on
a gel medium by passing electrical current through the gel proteins are separated on the gel based on their size, shape and charge
with SDS polyacrylamide gel electrophoresis proteins separate based on
molecular weight
gel-filtration chromatography
size
what physical parameters of a protein control its migration electrophoresis
size, shape and charge
what tends to happen to the percent recovery during a protein's purification
the number usually decreases during the purification
Electrophoresis 1) basis? 2) what are the materials? 3) process?
*Basis:* 1) Charged particles migrate in electric field toward opposite charge 2) Proteins have different mobility: - Charge - Size - Shape *Materials:* 1) Agarose used as matrix for nucleic acids 2) Polyacrylamide (continuous cross-linked matrix that can manipulate pore sizes) - used mostly for proteins - has more resistance towards larger molecules than smaller *Steps:* 1) Protein is treated with detergent (SDS) sodium dodecyl sulfate - this gives all proteins a uniform NEGATIVE charge - breaks all noncovalent interactions of the tertiary and quaternary levels, therefore component polypeptide chains can be analyzed 2) SDS-PAGE gives molecular weight of protein by comparing the sample w/ standard samples 3) Smaller proteins move through faster (charge and shape usually similar) *shape and charge are approximately the same for the proteins in the sample, thus the size of the protein becomes the determining factor in separation*
Primary structure determination
*Hydrolysis of proteins (HPLC analysis):* 1) high resolution columns that can be run under high pressures are used 2) separation that might take hours on standard column can be done in minutes w/ HPLC 3) Reverse phase HPLC is used for the separation of nonpolar molecules *Sequence-specific cleavage:* trypsin chymotrypsin CNBr
Peptide Sequencing
1) Can be accomplished by Edman Degradation 2) Relatively short sequences (30-40 amino acids) can be determined quickly 3) So efficient, today N-/C-terminal residues usually not done by enzymatic/chemical cleavage *method takes off an amino acid one at @ a time from N terminus*
How is 1˚ structure determined?
1) Determine which amino acids are present (amino acid analysis by HPLC) 2) Determine the N- and C- termini of the sequence (a.a sequencing; check to see if there are more than one polypeptide chain) 3) Determine the sequence of smaller peptide fragments (most proteins > 100 a.a) *- Edman degradation -* 4) Some type of cleavage into smaller units necessary *- Edman degradation -*
13. Recall What are two ways that a compound can be eluted from an affinity column? What could be the advantages and disadvantages of each?
A compound can be eluted by raising the salt concentration or by adding a mobile ligand that has a higher affinity for the bound protein than the stationary resin ligand does. Salt is cheaper but less specific. A specific ligand may be more specific, but it is likely to be expensive
14. Recall What are two ways that a compound can be eluted from an ion-exchange column? What could be the advantages or disadvantages of each?
A compound can be eluted by raising the salt concentration or by changing the pH. Salt is cheap, but it might not be as specific for a particular protein. Changing the pH may be more specific for a tight pI range, but extremes of pH may also denature the protein
An amino acid mixture consisting of phenylala- nine, glycine, and glutamic acid is to be separated by HPLC. The stationary phase is aqueous and the mobile phase is a solvent less polar than water. Which of these amino acids will move the fastest? Which one will move the slowest? In reverse-phase HPLC, the stationary phase is nonpolar and the mobile phase is a polar solvent at neutral pH. Which of the three amino acids will move fast- est on a reverse-phase HPLC column? Which one will move the slowest?
A nonpolar mobile solvent will move the nonpolar amino acids fastest, so phenylalanine will be the first to elute, followed by gly- cine and then glutamic acid The nonpolar amino acids will stick the most to the stationary phase, so glutamic acid will move the fastest, followed by glycine and then phenylalanine.
Gel-filtration chromatography is a useful method for removing salts, such as ammonium sulfate, from protein solu- tions. Describe how such a separation is accomplished.
A protein solution from an ammonium sulfate preparation is passed over a gel-filtration column where the proteins of interest will elute in the void volume. The salt, being very small, will move through the column slowly. In this way, the proteins will leave the salt behind and exit the column without it.
Determining Protein Sequence
After cleavage, mixture of peptide fragments produced. 1) Can be separated by HPLC or other chromatographic techniques 2) Use different cleavage reagents to help in 1˚ determination
what peptides would be released from the following peptide by treatment with trypsin ? Ala-Ser-Thr-Lys-Gly-Arg-Ser-Gly
Ala-Ser-Thr-Lys GLy-Arg Ser-Gly
Isoelectric Focusing
Based on differing isoelectric points (pI) of proteins *PI:* pH at which a protein (aa or peptide) has no net charge Isolectric focusing is a variation of gel electrophoresis *How it works:* 1) Gel is prepared with pH gradient that parallels electric-field 2) As protein moves through the gel, it encounters regions of different pH, so the charge on the protein changes, but protein stops at the region of its PI - Charge on the protein changes as it migrates - When it gets to pI, has no charge and stops
Cleavage by CnBr
Cleaves @ C-terminal of INTERNAL methionines
Primary Structure Determination Peptide Digestion
Cyanogen bromide hydrolyzes peptide bonds at the carboxyl terminus of methionine residues This reaction is used to reduce the size of polypeptide segments for identification and sequencing
Which of the chemicals or enzymes normally used for cutting proteins into fragments would be the least useful to you? Which enzymes or chemicals would you choose to use to cut the protein? Why?
Cyanogen bromide would be useless, because there is no methionine. Trypsin would be little better, because the protein is 35% basic residues. Trypsin would shred the protein into more than 30 pieces, which would be very hard to analyze Chymotrypsin would be a good choice. There are more than four residues of aromatic amino acids. The protein, containing 100 amino acids, would be cut four times, possibly yielding nice fragments roughly 20-30 amino acids long, which can be sequenced effectively by the Edman degradation.
the order of elution of AAs H, E & K from a cation exchange by apt 6 buffer is
E, H, K
one of the first protein ID techniques designed was
Enzyme-linked Immunoabsorbent Assay (ELISA)
how could you isolate mitochondria from liver cells using differential centrifugation ?
First homogenize the liver cells using a Potter-Elvejhem homogenizer. Then spin the homogenate at 500 g to sediment the unbroken cells and nuclei. Centrifuge the supernatant at 15,000 g and collect the pellet, which con- tains the mitochondria.
Affinity chromatography 1) How does it work? 2) When to use this? 3) What are some problems?
Form of column chromatography Advantages: 1) Uses specific binding properties of molecules/proteins 2) Produces very pure proteins How it works: 1) Stationary phase has a polymer that can be covalently linked to a compound called a ligand that specifically binds to the desired protein 2) After the unwanted proteins are eluted, more ligand or salt is added 3) Salt weakens the binding of protein to the ligand and extra free ligand competes with the column ligand in protein binding *-a change of pH or ionic strength will disrupt the ligand-protein interaction-* Use this after getting partially pure protein to get pure protein Problems: 1) ligand doesn't bind properly to polymer 2) ligand binds too strongly; can't remove 3) expensive
An amino acid mixture consisting of lysine, leu- cine, and glutamic acid is to be separated by ion-exchange chroma- tography, using a cation-exchange resin at pH 3.5, with the eluting buffer at the same pH. Which of these amino acids will be eluted from the column first? Will any other treatment be needed to elute one of these amino acids from the column?
Glutamic acid will be eluted first because the column pH is close to its pI. Leucine and lysine will be positively charged and will stick to the column. To elute leucine, raise the pH to around 6. To elute lysine, raise the pH to around 11.
Why is the order of separation based on size opposite for gel filtration and gel electrophoresis, even though they often use the same compound to form the matrix?
In a polyacrylamide gel used for gel-filtration chromatography, the larger proteins can travel around the beads, thereby having a shorter path to travel and therefore eluting faster. With electro- phoresis, the proteins are forced to go through the matrix, so the larger ones travel more slowly because there is more friction
What is the main difference between reverse phase HPLC and standard ion-exchange or gel filtration chromatography? how would you purify protein X using ion-exchange chromatography if it turns out the protein is only stable at a pH between 6 and 6.5?
In most chromatography systems, the ligands and solvents are polar. In reverse phase HPLC, a solution of nonpolar compounds is put through a column that has a nonpolar liquid immobilized on an inert matrix. A more polar liquid serves as the mobile phase and is passed over the matrix. The solute molecules are eluted in proportion to their solubility in the more polar liquid Use a cation-exchange column, such as CM-Sepharose, and run it at pH 6. Protein X will have a positive charge and will stick to the column.
What would happen during an amino acid sequencing experiment using the Edman degradation if you acci- dentally added twice as much Edman reagent (on a per-mole basis) as the peptide you were sequencing?
In the first cycle, the first and second amino acids from the N-terminal end would be reacted and released as PTH deriva- tives. You would get a double signal and not know which one was the true N-terminus.
In protein purification, what are the methods highlighted that are based on column chromatography?
Ion-exchange chromatography -Cation-exchange chromatography -Anion-exchange chromatography Size-exclusion chromatography Affinity chromatography
A sample of a peptide of unknown sequence was treated with trypsin; another sample of the same peptide was treated with chymotrypsin. The sequences (N-terminal to C-terminal) of the smaller peptides produced by trypsin digestion were as follows:
Met!Val!Ser!Thr!Lys!Leu!Phe!Asn!Glu!Ser! Arg!Val!Ile!Trp!Thr!Leu!Met!Ile
Primary Structure Determination Protein Cleavage
Protein cleaved at specific sites by: Enzymes: - Trypsin - Chymotrypsin Chemical reagents: - Cyanogen bromide *Enzymes:* 1) Trypsin: cleaves @ C-terminal of (+) charged side chains (e.g., lysine, arginine) 2) Chymotrypsin: cleaves @ C-terminal of aromatics (e.g., tyrosine, tryptophan, and phenylalanine) *Chemical reagents:* 1) CNBr: cleaves internal methionine residues - sulfur of the methionine reactions w/ carbon of the CNBr to produce homoserine lactone @ the C-terminal end of fragment *Sequence of a set of peptides produce by one reagent overlap the sequences produced by another reagent; peptides can be arranged in the proper order after their own sequences have been determined*
Ion-Exchange Chromatography 1) basis? 2) how does it work?
Protein separation based on NET charge; much like affinity chromatography, but is less specific *How it works:* 1) Stationary phases (resins) have a ligand with different charges at a defined pH - positive or negative *Cation-exchange chromatography:* 2) negatively charged resin (negative charges on the surface); therefore, there is an exchange of cations - generally bound to Na+ or K+ *Anion-exchange chromatography:* 3) positively charged resin (positive charges on the surface); therefore, there is an exchange of anions - generally bound to Cl- 4) Exchange resin is bound to counterions 5) Mixture of proteins is loaded on the column and allowed to flow through 6) Proteins that have a net charge opposite to that of the exchanger stick to the column, exchanging places w/ the bound counterions 7) Proteins that have no net charge or same charge as the exchanger elute 8) After unwanted proteins are eluted, eluent is changed either to a buffer that has a pH that removes the charge on the bound proteins or to one w/ a higher salt concentration 9) Higher salt concentration will outcompete the bound proteins for the limited binding space on the column 10) Desired molecules are eluted
Why do most people elute bound proteins from an ion- exchange column by raising the salt concentration instead of chang- ing the pH?
Raising the salt concentration is relatively safe. Most proteins will elute this way, and, if the protein is an enzyme, it will still be active. If necessary, the salt can be removed later via dialysis. Changing the pH enough to remove the charge can cause the proteins to become denatured. Many proteins are not soluble at the isoelectric points
3. Recall What is meant by "salting out"? How does it work?
Salting out is a process whereby a highly ionic salt is used to re- duce the solubility of a protein until it comes out of solution and can be centrifuged. The salt forms ion-dipole bonds with the water in the solution, which leaves less water available to hydrate the protein. Nonpolar side chains begin to interact between pro- tein molecules, and they become insoluble.
Draw an example of a compound that would serve as a cation exchanger. Draw one for an anion exchanger
See Figure 5.7
Design an experiment to purify protein X on an anion-exchange column. Protein X has an isoelectric point of 7.0
Set up an anion-exchange column, such as Q-Sepharose (qua- ternary amine). Run the column at pH 8.5, a pH at which the protein X has a net negative charge. Put a homogenate contain- ing protein X on the column and wash with the starting buffer. Protein X will bind to the column. Then elute by running a salt gradient.
Size-exclusion chromatography 1) Advantages? 2) How does it work? 2) What is eluted first?
Size-exclusion (or gel filtration) chromatography is a form of column chromatography *Advantages:* 1) proteins are separated by size 2) estimate molecular weight by comparing the sample w/ a set of standards Stationary phase composed of cross-linked gel particles: 1) particles are in bead form 2) consists of one of two kinds of polymers; a carbohydrate polymer (dextran or agarose) or polyacrylamide *How it works:* 1) Cross-linked structure of these polymers produce pores in the material 2) Extent of cross-linking can be controlled to produced desired pore size 3) Smaller molecules enter the pores and are delayed in elution time (only after escaping the pores) 4) Larger molecules do not enter and elute from column before smaller ones
WORKED EXAMPLE: Ion Exchange of Peptides A biochemist wants to separate two peptides by ion-exchange chromatography. At the pH of the mobile phase to be used on the column: Peptide A has a net charge of −3, due to the presence of more Glu and Asp residues than Arg, Lys, and His residues. Peptide B has a net charge of +1. Which peptide would elute first from a cation-exchange resin? Which would elute first from an anion-exchange resin?
Solution: A cation-exchange resin has negative charges and binds positively charged molecules, retarding their progress through the column. Peptide B, (+1) with its net positive charge, will interact more strongly with the cation-exchange resin than peptide A, (-3) and thus peptide A will elute first. On the anion-exchange resin, peptide B (+1) will elute first. Peptide A, (-3) being negatively charged, will be retarded by its interaction with the positively charged resin. Note: Separation can be optimized by changing pH or salt concentration.
Column Chromatography 1) What is the basis of separation? 2) What are the two phases? 3) What are the steps?
Stationary vs. mobile phases *Basis of Chromatography:* Different mobilities of the components of the sample are the basis of separation *Two phases:* 1) Stationary: samples interacts with this phase 2) Mobile (eluent): flows over the stationary phase and carries along with it the sample to be separated *Steps:* A) material of the stationary phase is packed in a column B) sample is a small volume of concentrated solution that is applied to the top of the column C) eluent is passed through the column D) sample is diluted by eluent 5) separation process increases the volume occupied by the sample
Why is it no longer considered necessary to determine the N-terminal amino acid of a protein as a separate step? What useful information might you get if you did determine the N-terminal amino acid as a separate step?
The Edman degradation will give the identity of the N-terminal amino acid in its first cycle, so doing a separate experiment is not necessary It might tell you if the protein were pure or if there were subunits.
The accompanying figure is from an electrophoresis experiment using SDS-PAGE. The left lane has the following standards: bovine serum albumin (MW 66,000), ovalbumin (MW 45,000), glyceraldehyde 3-phosphate dehydrogenase (MW 36,000), carbonic anhydrase (MW 24,000), and trypsinogen (MW 20,000). The right lane is an unknown. Calculate the MW of the unknown.
The MW is 37,000 Da.
Why can the Edman degradation not be used effectively with very long peptides? Hint: Think about the stoichi- ometry of the peptides and the Edman reagent and the percent yield of the organic reactions involving them.
The amount of Edman reagent must exactly match the amount of N-termini in the first reaction. If there is too little Edman reagent, some of the N-termini will not react. If there is too much, some of the second amino acid will react. In either case, there will be a small amount of contaminating phenylthiohydantoin (PTH) de- rivatives. This error grows with the number of cycles run until the point that two amino acids are released in equal amounts, and you cannot tell which one was supposed to be the correct one
An enzyme examined by means of gel filtration in aqueous buffer at pH 7.0 had an apparent molecular weight of 160,000. When examined by gel electrophoresis in SDS solution, a single band of apparent molecular weight 40,000 was formed. Explain these findings
The detergent SDS causes the dissociation of quaternary structures and allows the determination of molecular weight of the component subunits. The data suggest that the enzyme comprises four identical subunits of 40K each, yielding the tetramer of 160K
12. Recall What is the order of elution of proteins on a gel-filtration column? Why is this so?
The largest proteins elute first; the smallest elute last. Larger proteins are excluded from the interior of the gel bead so they have less available column space to travel. Essentially, they travel a shorter distance and elute first
4. Recall What differences between proteins are responsible for their differential solubility in ammonium sulfate?
Their amino acid content and arrangements make some proteins more soluble than others. A protein with more highly polar amino acids on the surface is more soluble than one with more hydrophobic ones on the surface
You are in the process of determining the amino acid sequence of a peptide. After trypsin digestion fol- lowed by the Edman degradation, you see the following peptide fragments: Leu!Gly!Arg Gly!Ser!Phe!Tyr!Asn!His Ser!Glu!Asp!Met!Cys!Lys Thr!Tyr!Glu!Val!Cys!Met!His What is abnormal concerning these results? What might have been the problem that caused it?
There are two fragments that have C-termini that are not lysine or arginine, which is what trypsin is specific for. Normally there would be only one fragment ending with an amino acid that was not Arg or Lys, and we would immediately know that it was the C-terminus. Histidine is a basic amino acid, although it is usually neutral and therefore does not react with trypsin. It is possible that, in the pH environment of the reaction, the histidine was positively charged and was recognized by trypsin.
Isoelectric Focusing 2
This technique separates proteins according to their isoelectric points A stable pH gradient is established in the gel by the addition of appropriate ampholytes A protein mixture is placed in a well on the gel. With an applied electric field, proteins enter the gel and migrate until each reaches a pH equivalent to its pI Remember that when pH = pI, the net charge of a protein is zero Incubate longer to make it look pure
If you had a mixture of proteins with different sizes, shapes, and charges and you separated them with electrophoresis, which proteins would move fastest toward the anode (positive electrode)?
Those with the highest charge/mass ratio would move the fast- est. There are three variables to consider, and most electro- phoreses are done in a way to eliminate two of the variables so that the separation is by size or by charge, but not by both.
Cell fractionation
To begin the process of purification, proteins are released from cells using homogenization using a variety of physical techniques such as blender processing or a tissue sonicator This is followed by differential centrifugation. As the homogenate is subjected to increasing g forces in a series of steps, smaller and smaller cell components end up in the pellet *What comes out during differential centrifugation:* 1) @ 600 x g: nuclei and any unbroken cells 2) @ 15,000 x g: mitochondria, lysosomes and microbes 3) @ 100,000 x g: ribosomes, microsomes, ER, golgi and plasma membrane fragments
A sample of an unknown peptide was divided into two aliquots. One aliquot was treated with trypsin; the other was treated with cyanogen bromide. Given the following sequences (N-terminal to C-terminal) of the resulting fragments, deduce the sequence of the original peptide.
Val!Leu!Gly!Met!Ser!Arg!Asn!Thr!Trp!Met! Ile!Lys!Gly!Tyr!Met!Gln!Phe
What could be an advantage of using an an- ion exchange column based on a quaternary amine [i.e., resin- N1(CH2CH3)3] as opposed to a tertiary amine [resin-NH1 (CH2CH3)2]?
With a quaternary amine, the column resin always has a net positive charge, and you don't have to worry about the pH of your buffer altering the form of the column. With a tertiary amine, there is a dissociable hydrogen, and the resin may be positive or neutrally charged, depending on the buffer pH.
What are two ways that a compound can be eluted from an affinity column and advantage/disadvantage of each.
a compound can be eluted by raising the salt concentration or by adding a mobile ligand that has a higher affinity for the bounded protein than the stationary resin ligand does. salt is cheaper but less specific. a specific ligand may be more specific but it is likely to be expensive
in any form of chromatography how will a compound which interacts more strongly with stationary phase elute compare to one that interacts less strongly
a compound interacting more strongly with elute later than now with weaker interactions
Salting out? how does it work
a process where by a highly ionic salt is used to reduce the solubility of a protein until it comes out of solution and can be centrifuge. the salt forms ion-dipole bonds with the water in the solution , which leaves less water available to hydrate the protein. non polar side cans begin to interact b/t protein molecules and the become insoluble
what types of compounds make up the gels used in electrophoresis ?
agarose and polyacrylamide
Sephadex G-75 has an exclusion limit of 80,000 MW for globular proteins. If you tried to use this column material to separate alcohol dehydrogenase (MW 150,000) from B-Amylase (MW 200,000), what would happen?
both proteins would elute in the void volume together and would not be separated
which chromatography would be best to separate proteins of similar size?
cation or anion exchange
intal purification steps are accomplished using
differential centrifugation and salting out with ammonium sulfate
in a ample consisting of lysine, leucine and glutamic acid which will be eluted last from an anion exchange resin at pH 7?
glutamic acid
they typical order fro the major steps of enzyme isolation would be ( 1st to last)
homogenization salt fractionation column chromatography electrophoresis
to begin the process of purification proteins are released from cells using
homogenization using a variety of physical techniques
why ammonium sulfate is useful in protein purification ?
it forms ion-dipole interactions with water making proteins less soluble and more likely to precipitate
WORKED EXAMPLE: What happens when the following amino acids are added to a column packed with a cation exchange resin? Aspartate Serine Lysine
lysine is eluted last due to being the most positively charge amino acid
ion-exchange chromatography
net charge
size-exclusion /gel- filtration
smaller molecules enter the pores and are delayed in elution time larger moles do not enter and elute from column before smaller ones
what does SDS_PAGE stand for ?
sodium dodecyl-sulfate polyacrylamide gel electrophoresis
what types of homogenization techniques are available for solubilizing a protein?
sonication freezing and thawing french press detergents
the purity of an enzyme at various staged of purification is best measured by ?
specific activity of the enzyme
affinity chromatography
specific ligand -binding ability
proteomics
systematic analysis of an organism's complete complement of proteins
what is the order of elution of proteins on a gel-filtration column? why is this so?
the largest proteins elute first the smallest elute last larger proteins are excluded from the interior of the gel bead so they have less available column space to travel. essentially they travel a shorter distance and elute first
WESTERN blot
the transfer of protein from an electrophoretic gel onto a thin membrane of nitrocellulose for identification similar to that of the ELISA technique
differential centrifugation at low speeds is a useful step when
there are either organelles or debris to separate
several methods of cleavage ( such as proteolytic enzymes) are used in determining the primary structure of a protein
to I've overlapping peptides which can be compared to obtain a complete sequence
wha is the benefit of ding SDS-PAGE
with SDS-PAGE the charge and shape differences of proteins are eliminated so that the only parameter determining the migration is the size of the protein
Could you separate B-Amylase (MW 200,000) from bovine serum albumin (MW 66,000) using a column with an exclusion limit of 80,000 MW?
yes, the b-amylase would come out in the void volume, but the bovine serum albumin would be included in the column bead and would elute more slowly
