Protein Purification

Protein Purification

An overview of protein isolation:

Protein isolation and purification is one the tedious job that takes a very long time if one can’t choose an efficient and suitable technique. There are numerous different types of proteins in a cell and to study about each protein is very difficult one.

Why do it?

Living organisms such as human beings and other higher eukaryotes are complex machines made up of many interacting systems. Protein constitute the majority of the working parts of these systems and these diverse reasons for isolating proteins are

• To gain insight. As with any mechanism, to study the way in which a living system works it is necessary to dismantle the machine and to isolate the component parts so that they may be studied, separately and in their interaction with other parts. The knowledge that is gained in this way may be put to practical use, for example, in the design of medicines, diagnostics, pesticides, or industrial processes. Many proteins may themselves be used as “medicines” to make up for losses or inadequate synthesis. Examples are hormones, such as insulin, which is used in the therapy of diabetes, and blood fractions, such as the so-called Factor VIII, which is used in the therapy of haemophilia. Other proteins may be used in medical diagnostics, an example being the enzymes glucose oxidase and peroxidase, which are used to measure glucose levels in biological fluids, such as blood and urine.

• For use in Industry. Many enzymes are used in industrial processes, especially where the materials being processed are of biological origin. In every case a pure protein is desirable as impurities may either be misleading, dangerous or unproductive, respectively. Protein isolation is, therefore, a very common, almost central, procedure in biochemistry.

• For use in Medicine.

The Background factors:

Properties of proteins that influence the methods used in their study

It must be appreciated that proteins have two properties which determine the overall approach to protein isolation and make this different from the approach used to isolate small natural molecules.

1. Proteins are labile

As molecules go, proteins are relatively large and delicate and their shape is easily changed, a process called denaturation, which leads to loss of their biological activity. This means that only mild procedures can be used and techniques such as boiling and distillation, which are commonly used in organic chemistry, are thus verboten.

2. Proteins are similar to one another.

All proteins are composed of essentially the same amino acids and differ only in the proportions and sequence of their amino acids, and in the 3-D folding of the amino acid chains. Consequently processes with a high discriminating potential are needed to separate proteins. The combined requirement for delicateness yet high discrimination means that, in a word, protein separation techniques have to be very subtle. Subtlety, in fact, is required of both techniques and of experimenters in biochemistry.

Protein fractionation techniques:

Figure 1: Flowchart of Protein purification steps

Protein Extraction

Since proteins are only synthesized by living systems, a protein must be isolated from biological materials or from bioproducts. The main objective of protein isolation is to separate the protein of interest from all non protein and all other unwanted proteins which occur in the same sample. As a general principle, one should aim to achieve the isolation of a protein

1. In as few steps as possible to minimize the lost in each step.

2. In as short a time as possible to prevent protein from denaturation.

Therefore, it is very important to optimize the protocol for specific protein to isolate and purify.

Where to start?

Before starting the extraction and purification process, one should know whether the proteins are extracellular and intracellular. On the basis of these and the background factors of protein, we can correctly apply the best method for extraction and purification which not only reduce the time of extraction but also save energy and money for purification.

For Extracellular proteins:

There is no need to cell disintegration for extracellular proteins. The cell culture is simply filtered and centrifuged. Then the supernatant portion of centrifuge contains extracellular proteins. E.g. Proteases, Antibiotics (proteins).

For Intracellular proteins:

In order to isolate the intracellular proteins, the cells are disrupted with using suitable buffer. As many of proteins are very sensitive in nature the choice of disruption technique should be done accurately. The appropriate method of cell disruption may reduce many steps in protein purification.

Preliminary Fractionation:

Frationation of homogenate: Once a homogenate has been prepared, cytosolic water-soluble proteins can be obtained by the removal of particulate matter, usually through centrifugation. In addition it is often desirable to isolate a specific particulate subsellular fraction if the desired protein is known to reside there. For instance of one wishes to purify a transcription factor localized to the nucleus one would first prepare nuclei and extract them. A low-speed centrifugation separates nuclei from the remainder of the homogenate. The postnuclear supernatant can then be subjected to centrifugation at intermediate speed to sediment mitochondria. Finally the postmitochondrial supernatant can be fractionated in the ultracentrifuge into a ribosomal fraction and a postribosomal supernantant which contains all soluble proteins.

Fractionation of proteins in solution

Eventually the desired protein is obtained in aqueous solution together with a host of unrelated proteins. At this moment the protein becomes amenable to a number of manipulations that can, in principle at least, separate it from all other proteins in the sample.

a. Fractionation by precipitation.

To begin the process of fractionation, it is possible to alter the composition of the buffer to force the precipitation of a portion of the proteins. This procedure takes advantage of the differential solubility of proteins under varying conditions as well as the high protein concentration of the solution which permits aggregates of protein to form over a short period of time (minutes to hours). Precipitation of one group of proteins permits their separation from other proteins that remain in solution by low speed centrifugation.

(i) "Salting out" - Ammonium Sulfate Precipitation: high salt concentrations promote precipitations. With increasing ionic strength, proteins begin to interact via hydrophobic patches on their surface, as proteins and salt compete for the residual water. Ammonium sulfate is used as the salt of choice, since it preserves protein activity and promotes precipitation at lower concentrations than other salts. (Phosphate should be better than sulfate on theoretical grounds, but is ruled out because trivalent phosphate occurs only at extremely low pH. Sodium sulfate and many potassium salts are not sufficiently soluble; many multivalent cations are toxic; also potassium phosphate at even fairly low molar concentration is too dense to allow precipitate to settle - economy of the pure salt also plays a role). One adds increasing amounts of ammonium sulfate to the extract, with intermittent centrifugation steps. These stepwise precipitations are referred to as ammonium sulfate "cuts." The amounts of solid ammonium sulfate to be added to a known volume in order to obtain the desired percentage saturation can be looked up in tables. Solid ammonium sulfate should be added slowly, while the solution is stirring to allow a uniform increase in the concentration, and in powdered form, to ensure rapid equilibration.

What are the mechanisms of protein precipitation by Ammonium Sulphate?

Polyvalent anions are more effective at salting out than univalent anions, while polyvalent cations tend to negate the effect of polyvalent anions. The best combination is therefore a polyvalent anion with a univalent cation. Anions can be arranged in a so-called “Hofmeister series”, which describes their relative effectiveness in salting out at equivalent molar concentrations2. In decreasing order of effectiveness, the series is:

citrate > sulfate > phosphate > chloride > nitrate >thiocyanate.

This series also describes a decreasing tendency for the anions to stabilise protein structure. Citrate and sulfate are thus “kosmotropes”, which tend to stabilise protein structure, while thiocyanate and nitrate are “chaotropes” which tend to destabilize protein structure. An ideal salt would, therefore, be citrate or sulfate combined with a univalent cation. Ammonium sulfate is most popular because it meets these criteria, is available in a pure form at low cost and is highly soluble, so that high solution concentrations can be attained. The sulfate ion has been viewed in a number of ways, regarding how it salts out proteins, including, ionic strength effects, kosmotropy, exclusion-crowding, dehydration, and binding to cationic sites, especially when the protein has a net positive charge (denoted ZH+)3. All of these may play a role, depending upon the salt concentration and the pHdependent charge on the protein.

Ionic strength effects. It will be noticed that the Hofmeister series goes from multivalent to univalent ions. This largely reflects the fact that the Hofmeister series is based on molarity, while ionic strength is a factor in salting out. The valency of the ion has an effect on ionic strength as can be illustrated by comparing NaCl with (NH4)2SO4.

Ionic strength is defined as:- 1/2S ci (zi)²

Where, ci = concentration of each type of ion (moles/litre)

zi= charge of each type of ion

Thus in the case of 1 M NaCl, ionic strength is 1 and for 1 M (NH4)2SO4, it is 3.

Ionic strength effects come into play at low salt concentrations M) and, as the name implies, they are not specific to ammonium sulfate. At low ionic strength, protein solubility is at its minimum at the proteinís pI. At this pH, intramolecular electrostatic forces between oppositely charged side chains are at a maximum, protein conformation is maximally tightened and protein hydration is least. On either side of the pI, titration of ionisable groups leads to a lessening of intramolecular ionic interactions. In consequence, protein structure becomes more relaxed and hydration and solubility are increased. Addition of low concentrations of salt causes a similar weakening of intramolecular ionic bonds, with similar consequences of more relaxed protein structure and greater solubility. The increase in solubility of protein upon addition of modest amounts of salt is known as “salting in”.

Kosmotropy. At concentrations above 0.2 M the sulfate ion acts as a Hofmeister kosmotrope, i.e. it stabilises protein structure, and concomitantly reduces its solubility. The effect of a kosmotrope, in stabilising protein structure, can be described by the reaction:-

Relaxed, open protein structure Û compact, tight structure

(more soluble, less stable) (less soluble, more stable)

Kosmotropes may be described as “pushing” if they act on the left of this reaction and “pulling” if they act on the right, in either case driving the reaction to the right. Sulfate can act as a pulling kosmotrope by virtue of its interaction with protein cationic sites. Consistent with this, the precipitation of proteins is usually promoted at pH values below the pI, where the protein has a maximal number of cationic sites3. Reinforcing its pulling effect is the fact that the sulfate ion is divalent, and so can bind to more than one cationic site at a time, and that it has a tetrahedral structure, with four oxygen atoms that can hydrogen bond to multiple sites on the protein. Sulfate also acts as a pushing kosmotrope by virtue of its extraordinary hydration. By virtue of its hydration, the sulfate ion can act as a dehydrating agent and, in its hydrated form, as an exclusion crowding agent. The sulfate anion has 13 or 14 water molecules in its first hydration layer and possibly more in a second layer4. Consequently, in salting out at, say, 3 M ammonium sulfate, the sulfate anion will have accreted to itself 40 to 45 M out of the total of 55 M H2O in neat water. In salting out, therefore, a large proportion of the water will be involved in hydrating the sulfate ions and increasing their effective radius. The large, hydrated, [SO4.(H2O)n]2- ions crowd and exclude the proteins, pushing them into tighter, more ordered (less soluble) conformations, with lower entropy. The preferential accretion of the water molecules to the sulfate ions excludes the proteins from a proportion of the water (the proportion increasing with the salt concentration), ultimately bringing them to their solubility limit. No other salt has the combination of properties which make ammonium sulfate so effective at salting out. Consequently, when the word salt is used in the context of salting out, it invariably means ammonium sulfate. Similarly, the term “ionic strength” is often used loosely, when what is really meant is the concentration of ammonium sulfate.

(ii) Isoelectric precipitation. Solubility of proteins depends on ionic strength and pH; usually very soluble at physiological ionic strength and pH, as cellular protein concentration can reach 40% of total mass. If the pH approaches the pI of a given protein the net charge on that protein will go to zero, and in the absence of electrostatic repulsion, weak electrostatic attractive forces may lead to aggregation and precipitation; this tendency to interact can be promoted by reducing the ionic strength or by adding organic solvent (see solvent precipitation below!). "The effects of ionic strength of the medium on the interaction between charged macroions can be summarized as follows. At very low ionic strength, the counterion atmosphere is highly expanded and diffuse, and screening is ineffective. Like-charged particles repel strongly; unlike charged particles attract one another strongly. As the ionic strength increases, the counterion atmosphere shrinks and becomes concentrated about the macroion. Screening becomes effective. - The effects of charge and ionic strength on the solubility of polyampholytes such as proteins can be explained in terms of these electrostatic interactions. Consider the behavior of the common milk protein b-lactoglobulin. The isoelectric point of this polyampholyte is about 5.3. Above or below this pH, the molecules all have either negative or positive charges and repel one another, so the protein is very soluble at either acidic or basic pH. At the isoelectric point, the net charge is zero but each molecule still carries surface patches of both positive charge and negative charge. The ionic interactions between them, together with other kinds of intermolecular interactions such as van der Waals forces, make the molecules tend to clump together and precipitate. Therefore, solubility is minimal at the isoelectric point. If the ionic strength is increased, however, the counter on atmosphere shrinks about the charged regions, and the attractive interactions between positive and negative groups are effectively screened. Hence, solubility increases, even at the isoelectric point. This effect of putting proteins into solution by increasing the salt concentration is called salting in."]

(iii) Solvent precipitation: used to be popular in the early days of protein isolation, especially in the fractionation of plasma proteins (ethanol; acetone). Mechanism: reduction of water activity (i.e. availability of water for protein solvation); most likely to occur at pI which suggests that the interaction between proteins may be similar to that in isoelectric precipitation. Order of precipitation largely determined by the size of the protein. Disadvantages: flammable (acetone); easily denatures proteins when conducted at temperatures above 0^oC. A variant of the procedure is PEG precipitation (at 20% and MW of 4000 or greater).

(iv) Selective denaturation of contaminant proteins in isolated cases can be brought about by heat, extremes of pH, and organic solvents. (examples are isolation of calmodulin from brain extracts by boiling??) but note that heat treatment may result in chemical modification of the desired protein and is therefore not recommended

Dialysis and ultrafiltration: Fractionation by means of semipermeable membranes is generally used for buffer changes but can also provide low-resolution protein fractionation. In dialysis the protein sample is enclosed in a bag consisting of a semipermeable membrane (made of cellulose) and exposed to a large volume of a desired buffer. The low-molecular weight compounds (buffering agents, salts) pass freely through the membrane pores wherease the protein is retained. This procedure lends itself to desalting steps and buffer exchanges. Ultrafiltration is similar except that the pores can be larger and therefore allow smaller proteins to pass through. In other words such membranes can be used for protein fractionation. Since dialysis speed is a function of molecular mass, ultrafiltration employs pressure to force the sample through. Membranes with various molecular weight cutoffs are available (from less than 10 to more than 100 kDa). Obviously this method is not very efficient, as only 2 fractions, a filtrate and a "retained fraction" are obtained.

Chromatographic and electrophoretic procedures

1. Chromatography - any of a number of methods in which solutes (in our case proteins) are fractionated by partitioning between a mobile or buffer and an immobile or matrix, phase. The most widely used technique involves a matrix packed in a column through which the protein sample is passed.

a. Gel filtration.

Gel filtration (also size exclusion or gel permeation chromatography) separates molecules, including proteins, on the basis of their size and shape. Large proteins do not enter the pores of the chromatographic matrix, but pass through, flowing in the interstitial space between the matrix beads; this space is also known as the void volume, V₀. For most resins, V₀ is approximately 1/3 of V_T, where V_T is the total packed volume of the resin (V_T = lr²p; where, r = radius of the column and l = length of the resin bed). If a molecule is smaller than the pores in the resin, it will diffuse into the beads. In the space outside the beads there is bulk flow only, while inside the beads solutes move by diffusion only. Therefore, large proteins confined to the interstitial space will migrate more rapidly through a resin than small molecules which diffuse into and back out of the resin and consequently are partly trapped and fall behind. Since pores vary in size, proteins of intermediate size will penetrate to varying degrees into the beads and thus are separated from each other on the basis of their size. Note:Proteins of equal mass but different shapes will differ in their apparent size. An elongated protein will appear larger, i.e. it will have a larger tumbling radius or radius of gyration and move more slowly than a spherical protein of the same mass.

A given protein will elute at a reproducible and characteristic position from a particular resin with a specific buffer. This property is usually reported as the (V_E - V₀)/(V_T - V₀) and corresponds to the R_f (= ‘relation to front’, i.e. the front of the solvent) value that is used for thin layer chromatography. A protein that elutes in the void volume will have an Rf = 0, whereas a protein that elutes at V_T will have a Rf = 1. Since, upon gel filtration, the sample is diluted by a factor of two to three or more, it is necessary to load concentrated protein samples. Under ideal conditions, the sample volume will be less than 2% of V_T. In practice, it is often difficult to concentrate the sample sufficientlly, and a sample volume that is up to 5% of the V_T can be used to give suboptimal results. The protein concentration can be as high as 50 mg/ml, and care must be taken not to disturb the packed resin with such high-density samples.

Gel filtration resins are composed of a variety of materials, including dextran, agarose, and polyacrylamide and are available in various pore sizes. Since resolution increases with bead uniformity and decreases with bead size, small homogeneous beads are preferred. Such beads tend to require higher pressures for chromatography than that achieved with conventional chromatography systems. Because the beads used in gel filtration are porous, they can be sensitive to even moderate pressure. Typically, the resins with larger pore sizes (which are more fragile) should be used at lower hydrostatic pressures than the more sturdy resins with smaller pores. Many resins are cross-linked (e.g. crosslinked dextran and agarose) to increase their strength.

b. Adsorption chromatography

In gel permeation chromatography proteins do not bind significantly to the matrix. Sorting does not occur as a result of differential binding but of differential exclusion from pores in the beads. On the other hand many sorbents are available that bind proteins with different affinities. At equilibrium the behavior of a specific protein can be described by a partition coefficient a, the fraction of the protein that is adsorbed. a therefore can have values between 0 (no binding whatever) and 1.0 (complete adsorption without any desorption). Differences in partition coefficients can be utilized for fractionation by allowing proteins to choose between a stationary, adsorbed and a mobile unadsorbed phase. In this case the completely unadsorbed protein will move with the buffer front; its mobility compared to the buffer front, R_f, will be unity. In contrast, the completely absorbed protein will not move at all, and R_f will be 0. In other words: a + R_f = 1.0

Binding of protein to the matrix is most simply achieved by mixing them. Such socalled batch adsorption is especially popular with hydroxyapatite, but can also be performed with ion exchange resins. One of the great advantages of adsorptive methods is the ability to use high volumes of sample, obviating concentration steps. This saves time and generally leads to higher overall yields in protein preparations. For example, one can load ion exchange resins in batch mode by stirring a large-volume sample with the resin. Subsequently, the resin is poured into a column for gradient elution, or batch eluted on a sintered glass funnel. Thus, one can move rapidly through large volume steps at the early stages of the preparation.

(i) Ion exchange chromatography: In this type of chromatography, the charged groups on the surface of a protein bind to an insoluble matrix with opposite charge. More precisely, the ionized protein displaces the counterions (e.g., chloride or sodium) of the matrix functional group, and will itself be displaced by an increasing concentration of ions in the elution buffer. Alternately, a pH gradient may be employed so that the net charge on the adsorbed protein decreases. Under specific starting conditions of buffer, pH, and ionic strength, the net charge on the protein of interest can be manipulated to interact with the matrix. Thus, the most important parameters to consider in an ion exchange separation are the choice of ion exchange matrix and the initial conditions.

The Ion Exchange Matrix: Ion exchangers consist of an insoluble containing charged groups. Anion exchangers contain basic groups that are positively charged below their pK's (e.g. amino functions) and cation exchangers contain acidic groups that are negatively charged above their pK's (e.g. carboxylate). For example, carboxymethyl is a weakly acidic cationic exchanger, while sulfopropyl is a strong cation exchanger, since the pK for the acidic proton is lower for sulfate than for acetate, i.e. the sulfopropyl function, i.e. the sulfopropyl function remains chraged over a greater part of the pH range than the carboxymethyl. A cationic protein will bind to both types of cation exchangers, but it will usually require higher concentration of counter ions to desorb the protein from the "stronger" ion exchanger, sulfopropyl. Similarly, DEAE is a weakly basic anion exchanger, while the quaternary ammonium ions are strong anion exchangers. A special case of ion exchange chromatography is metal chelation chromatography. Here resins contain carboxylate functions in close proximity which are capable of making coordination complexes with metal ions such as Ni²⁺. The metal cations are then capable of interacting strongly with strings of imidazols, i.e. histidine residues in proteins. The strong coordination bond can be broken by an excess of free imidazol. This type of chromatography is especially useful for the isolation of proteins under denaturing conditions, provided a string of histidines is present. Such a His tag is easily engineered into fusion proteins.

(ii) Hydrophobic Interaction Chromatography: In hydrophobic interaction chromatography (HIC) advantage is taken of hydrophobic patches on the protein surface that interact with non-polar materials under non-denaturing conditions. As in ammonium sulfate fractionation, high ionic strength promotes interactions between surface hydrophobic patches on the proteins. In HIC one raises the ionic strength to just below the point of precipitation in the presence of an immobilized hydrophobic matrix such as phenyl or octyl agarose. Under these conditions, proteins can be made to bind rather than to precipitate (note that plain agarose or Sephadex will do, as hydrophobic interactions with the polysaccharide matrix in the absence of alkyl or aryl substituents are possible). A descending salt gradient then causes desorption of proteins in the order of hydrophobic affinity between matrix and protein surface. At very low ionic strength, there may still be proteins retained by the column, and these must be removed by the addition of nonpolar or chaotropic components to the matrix. Solvent modifiers added to cause desorption of strongly bound proteins can lead to denaturation of proteins. Under those conditions, HIC becomes similar to reverse phase systems using organic solvents (Notice again the similarity to protein precipitation methods, this time solvent precipitation, and to reverse phase HPLC, which is widely used in the fracionation of peptides. Matrix:Immobilized aromatic and aliphatic compounds are used such as phenyl- and octylagarose. Also stress that HIC is possible even with unsubstituted sepharose. Loading Conditions:Protein solutions should be supplemented with a salt to promote HIC. Ammonium sulfate is a popular salt for HIC, since concentrations of 1 M (ca 25% saturation) are usually sufficient for initial conditions. Sodium or potassium chloride can be used, but often concentrations of 2 M or higher are needed to force interactions with the HIC column.

(iii) Hydroxyapatite chromatography: Chromatography of proteins on hudroxyapatite (HTP - microcrystalline precipitates of calcium phosphate Ca₅(PO₄)₃OH) which affords fractionations that often are not attainable with any other method (e.g. separation of isozymes or of antibodies that only differ in their light chains etc.). Depends on specific interaction with calcium and phosphate; elution is accomplished with an ascending gradient of phosphate. This is sometimes convenient as fairly high sodium chloride concentrations that are frequently encountered in an ion exchange column eluate do not interfere with adsorption of the sample onto the HTP column.

Monitoring the Purification Process

After each step in purification process, the protein sample should be estimated and its purity should be monitored. Through this process we can know the lost of protein and its purity level. It also helps in further purifying the protein. This monitoring process detects the efficient purification level to stop the process. There are many methods of protein purification monitoring and estimation.

For Protein Determination:

1. UVMethod:

Quantitation of the amount of protein in a solution is possible in a simple spectrom­eter. Absorption of radiation in the UV by proteins depends on the Tyr and Trp content (and to a very small extent on the amount of Phe and disulfide bonds). There­fore the A₂₈₀ varies greatly between different proteins (for a 1 mg/mL solution, from 0 up to 4 [for some tyrosine-rich wool proteins], although most values are in the range 0.5–1.5. The advantages of this method are that it is simple, and the sample is recoverable. The method has some disadvantages, including interference from other chromophores, and the specific absorption value for a given protein must be deter­mined. The extinction of nucleic acid in the 280-nm region may be as much as 10 times that of protein at their same wavelength, and hence, a few percent of nucleic acid can greatly influence the absorption.

2. Biuret Method:

In alkaline solution, proteins reduce cupric (Cu2+) ions to cuprous (Cu1+) ions which react with peptide bonds to give a blue colored complex. This reaction is called the biuret reaction and is named after the compound biuret, which is the simplest compound that yields the characteristic color. Because the reaction is with peptide bonds, there is little variation in the color intensity given by different proteins. The biuret method can be used for the measurement of protein concentration in the presence of polyethylene glycol, a common protein precipitant. A disadvantage of the biuret method is that it is relatively insensitive, so that large amounts of protein are required for the assay. A more sensitive variant of the method, the micro-biuret assay, has been devisedí, which overcomes this limitation to some extent. Another limitation is that amino buffers, such as Tris, which are commonly used in the pH range ca. 8-10, can interfere with the reaction.

3. The Lowry Method:

The most accurate method of determining protein concentration is probably acid hydrolysis followed by amino acid analysis. Most other methods are sensitive to the amino acid composition of the protein, and absolute concentrations cannot be obtained. The procedure of Lowry et al. is no exception, but its sensitivity is moderately constant from protein to protein, and it has been so widely used that Lowry protein estimations are a completely acceptable alternative to a rigorous absolute determina­tion in almost all circumstances in which protein mixtures or crude extracts are involved.

The method is based on both the Biuret reaction, in which the peptide bonds of proteins react with copper under alkaline conditions to produce Cu⁺, which reacts with the Folin reagent, and the Folin–Ciocalteau reaction, which is poorly understood but in essence phosphomolybdotungstate is reduced to heteropolymolybdenum blue by the copper-catalyzed oxidation of aromatic amino acids. The reactions result in a strong blue color, which depends partly on the tyrosine and tryptophan content. The method is sensitive down to about 0.01 mg of protein/mL, and is best used on solutions with concentrations in the range 0.01–1.0 mg/mL of protein.

4. The Bicinchonic Acid Method:

The bicinchoninic acid (BCA) assay, first described by Smith et al. is similar to the Lowry assay, since it also depends on the conversion of Cu²⁺ to Cu⁺ under alkaline conditions. The Cu⁺ is then detected by reaction with BCA. The two assays are of similar sensitivity, but since BCA is stable under alkali conditions, this assay has the advantage that it can be carried out as a one-step process compared to the two steps needed in the Lowry assay. The reaction results in the development of an intense purple color with an absorbance maximum at 562 nm. Since the production of Cu⁺ in this assay is a function of protein concentration and incubation time, the protein content of unknown samples may be determined spectrophotometrically by compari­son with known protein standards. A further advantage of the BCA assay is that it is generally more tolerant to the presence of compounds that interfere with the Lowry assay. In particular it is not affected by a range of detergents and denaturing agents such as urea and guanidinium chloride, although it is more sensitive to the presence of reducing sugars. The sensitivity for standard assay is 0.1–1.0 mg protein/mL and that of microassay is 0.5–10 µg protein/mL

5. The Bradford Method (Dye Binding Method):

A rapid and accurate method for the estimation of protein concentration is essential in many fields of protein study. An assay originally described by Bradford has become the preferred method for quantifying protein in many laboratories. This tech­nique is simpler, faster, and more sensitive than the Lowry method. Moreover, when compared with the Lowry method, it is subject to less interference by common rea­gents and nonprotein components of biological samples.

The Bradford assay relies on the binding of the dye Coomassie Blue G250 to pro­tein. Detailed studies indicate that the free dye can exist in four different ionic forms for which the pK_a values are 1.15, 1.82, and 12.4. Of the three charged forms of the dye that predominate in the acidic assay reagent solution, the more cationic red and green forms have absorbance maxima at 470 nm and 650 nm, respectively. In contrast, the more anionic blue form of the dye, which binds to protein, has an absorbance maxi­mum at 590 nm. Thus, the quantity of protein can be estimated by determining the amount of dye in the blue ionic form. This is usually achieved by measuring the absor­bance of the solution at 595 nm.

The dye appears to bind most readily to arginyl and lysyl residues of proteins. This specificity can lead to variation in the response of the assay to different proteins, which is the main drawback of the method. The original Bradford assay shows large variation in response between different proteins. Several modifica­tions to the method have been developed to overcome this problem. How­ever, these changes generally result in a less robust assay that is often more susceptible to interference by other chemicals. Consequently, the original method devised by Bradford remains the most convenient and widely used formulation. The standard assay, which is suitable for measuring between 10 and 100 µg of protein, and the microassay, which detects between 1 and 10 µg of protein are commonly used. The latter, although more sensitive, is also more prone to interference from other com­pounds because of the greater amount of sample relative to dye reagent in this form of the assay.

For Monitoring Purification

1. Spectrophotometric Method:

A single peak on spectrophotometric analysis shows the purity of protein sample.

2. Enzymatic Method:

For enzymes, the increase in purity will increase the activity of protein. The enzymatic activity can be determined by using specific substrate at specific temperature and pH optimal for the enzyme.

3. Electrophoresis Method:

A single and pure protein reveals a single distinct band upon electrophoresis. Therefore, it is also a best method for monitoring the protein purification.

A Practical Manual for Instrumentation

A Practical Manual

of

Instrumentation

For

Students of M.Sc. Microbiology

(Kantipur College of Medical Sciences)

Prepared by:

Upendra Thapa Shrestha

Faculty

Kantipur College of Medical Sciences

Department of Microbiology

Tribhuvan University

Sitapaila, <Ș>Kathmandu

2010

ACKNOWLEDGEMENT

It gives me immense pleasure to express my heartfelt appreciation to all the people who helped me in one way or another to complete this practical instrumentation manual.

Respectfully, I would like to express my sincere gratitude to Kantipur College of Medical Sciences (KCMS), Sitapaila, Kathmandu and all family of college for considering this manual suitable for M. Sc Microbiology program and publishing it.

I am indebted to my colleagues Mr. Nawaraj Adhikari, a coordinator, KCMS and Mr. Dhiraj Acharya, a faculty member of KCMS for supporting to publish.

I am much obliged to Mr. Kiran Babu Tiwari, a PhD scholar and Faculty member of KCMS for helping me to prepare this manual.

Finally I would like to appreciate my cousins Sagar and Saurav for helping me on typing this manual.

Lists of Experiments:

Experiment no 1: Introduction of different instruments used in Biochemistry and Instrumentation practical lab.

Experiment no 2: Preparation of different types of solutions (Percent, Molar, Normal, Solutions from Solutions and Titrations, Concentrated Solutions Saturated) used in biochemistry lab.

Experiment no 3: Preparation of different types of Buffers (Phosphate, Acetate, Citrate, Tris buffers, etc) used in biochemical studies.

Experiment no 4: Preparation of various sub-cellular fractions of liver cells (rat, chicken…) by Differential centrifugation method

Experiment no 5: Fractionation of serum protein by salt (Sodium chloride and Ammonium sulphate=separation of albumin and globulin)

Experiment no 6: Precipitation and separation of protein of interest by TCA (Trichloroacetic acid) method from biological sample.

Experiment no 7: Separation and identification of amino acids in a given mixture by ascending paper chromatography.

Experiment no 8: Separation and identification of amino acids in a given mixture by two dimensional paper chromatography.

Experiment no 9: Separation and identification of sugars (sugar juices) by adsorption Thin layer chromatography (TLC).

Experiment no 10: Extraction and identification of lipids from given biological samples (egg, cooking oils…..) by Thin layer chromatography.

Experiment no 11: Purification of bovine serum albumin from buffalo serum by size exclusion chromatography (gel filtration)

Experiment no 12: Determination of molecular weight of a given protein by SDS-PAGE (Sodium Dodecylsulphate Polyacrylamide Gel Electrophoresis).

Experiment no 13: Native Disc gel electrophoresis of proteins.

Experiment no 14: Determination of molecular weight of DNA (genomic and plasmid)by Agarose gel electrophoresis.

Experiment no 15: Determination of l_max of different colored and noncolored compounds by spectrophotometer.

Experiment no 16: Verification of validity of Beer’s law and determination of the molar extinction coefficient of BSA

Experiment no. 1

Introduction of different instruments used in Biochemistry and Instrumentation practical laboratory

Lists of instruments used in lab:

1. Micropipettes

a.

b.

c.

d.

e.

2. Spectrophotometer

a.

b.

c.

d.

e.

3. UV illuminator

a.

b.

c.

d.

e.

4. Centrifuge

a.

b.

c.

d.

e.

5. Homogenizer

a.

b.

c.

d.

e.

6. SDS-set

a.

b.

c.

d.

e.

7. Horizontal Electrophoresis set

a.

b.

c.

d.

e.

8. Others……

Experiment no. 2

Preparation of different types of solutions (Percent, Molar, Normal, Solutions from Solutions and Titrations, Concentrated Solutions Saturated) used in biochemistry lab

Objectives:

1. To prepare Percent, Molar, Normal, Solutions from Solutions and Titrations, Concentrated Solutions and Saturated solutions.

Principle:

1. Percent solutions

There are three types of percent solutions. All are parts of solute per 100 total parts of solution.

Based on the following definitions you may calculate the concentration of a solution or calculate how to make up a specific concentration.

1. % W/W - Percent of weight of solute in the total weight of the solution. Percent here is the number of grams of solute in 100 grams of solution.

Example:

A 100% (W/W) NaCl solution is made by weighing 100 g NaCl and dissolving in 100 g of solution.

2. % W/V - Percent of weight of solution in the total volume of solution. Percent here is the number of grams of solute in 100 ml of solution. This is probably the least significant way of naming a solution, but the most common way of doing it. In fact, any percent solution not stipulated as W/W, W/V, or V/V is assumed to be % W/V.

Example:

A 4% (W/V) NaCl solution is 4 g of NaCl in 100 ml of solution.

3. % V/V - Percent of volume of solute in the total volume of solution %V/V. Percent here is the number of milliliters of solute in 100 ml of solution.

Example:

A 10% (V/V) ethanol solution is 10 ml of ethanol in 100 ml of solution; unless otherwise stated, water is the solvent.

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MOLAR SOLUTIONS (M)

The definition of molar solution is a solution that contains 1 mole of solute in each liter of solution. A mole is the number of gram molecular weights (gmw). Therefore, we can also say a 1M = 1 gMW solute/liter solution.

1M NaCl solution would be

Na = MW of 23

Cl = MW of 35.5

NaCl = MW of 58.5

1M = 58.5 g of NaCl in 1 liter of solution.

It may be made by weighing out 58.5 g of NaCl and qs to 1 liter with water. The qs stands for quality sufficient and is a term used to designate that the total volume must be 1 liter (or whatever is stated).

58.5 g NaCl qs 1 liter with H20

Examples of other solutions would be

1 M H₂S0₄ = 98 g/L

1 M H₃P0₄ = 98 g/L

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NORMAL SOLUTIONS:

The definition of a normal solution is a solution that contains 1 gram equivalent weight (gEW) per liter solution. An equivalent weight is equal to the molecular weight divided by the valence (replaceable H ions).

1N NaCl = 58.5 g/L

1N HCl = 36.5 g/L

1N H₂S0₄ = 49 g/L

Problems involving normality are worked the same as those involving molarity but the valence must be considered:

1N HCl the MW= 36.5 the EW = 36.5 and 1N would be 36.5 g/L

1N H₂SO₄ the MW = 98 the EW = 49 and 1N would be 49 g/L

1N H₃PO₄ the MW = 98 the EW = 32.7 and 1N would be 32.7 g/L

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SOLUTIONS FROM SOLUTIONS AND TITRATIONS:

Many times the solutions we make are made from more concentrated solutions rather than dry chemicals. For figuring these out it can just be easier to remember a formula than figuring them out.

That formula is:

V₁C₁ = V₂C₂

Where V = volume

C = concentration (%, M, N)

1 = the more concentrated solution

2 = the new (dilute) solution

or in other words the volume of a concentrated solution times its concentration will contain the proper amount of chemical to give the volume of a weaker solution times its concentration.

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CONCENTRATED SOLUTIONS:

Concentrated acids and bases and other stock reagents exist as liquids and usually do not have their concentrations listed as %, M or N. They usually have specific gravity or density of the solution. The concentration may be calculated from this. Then how to make the weaker solution from this concentration solution is determined. So when the only information about the concentration of a concentrated solution is specific gravity and percent assay, we must first calculate concentration.

Specific Gravity for all purposes is the number of grams per milliliter.

For example:

HCl sp. gr. = 1.080 would mean that there is 1.080 g of HCl in every ml of solution.

Since N is in gEW per liter we need to convert to liter.

1.080 g/ml = 1080 g/L

If 1 N = 36.5 g/L

Then 1080 g/L / 36.5 g/L = 29.6N

One problem with most purchased solutions, even the best, is that they are not pure. Some of that weight is due to other substances. But the bottle will state the percent assay or what percent is really there.

e.g., 95% HCl would mean that 95% of 1.080 is HCl.

In that case

(1080) (0.95) = 1026 g/L

Now that we know the amount of solute per volume of solution, we may calculate concentration.

If we want to know concentration in % (W/V), we say (as in previous problems)

1026g / 1L is the same as 1026g /1000 ml

1026g /1000 ml = X / 100 ml

X = 102.6 g

If we have 102.6 g/100 ml that is 102.6%.

If we had wanted to know concentration as molarity we would proceed as with other molarity problems:

1 M HCl = 36.5 g/L

1M / 36.5 g/L = X / 1026 g/L

28.1 M = X

Of course, your problem may be more than just determining concentration. You may need to make up 5 liters of 0.02N H₂S0₄ from concentrated H₂S0₄ on the shelf. The bottle states:

sp. gr. = 1.64

% assay = 80%

You don't give up and leave; you remember what you did in your lab math program -- which was:

First calculate the concentration of the H₂S0₄ in the bottle.

Sp. gr. = 1.64

= 1.64 g/ml

= 1640 g/L

% assay = 80%

Therefore, 1640 x 0.80 = 1312 g/L of H₂S0₄

MW H₂S0₄ = 98

E.W. = 49

1N H₂S0₄ = 49 g/L

1312 g/L / 49 g/L= 26.8N

Second, once you know the concentration, plug it into the formula.

V₁C₁ = V₂C₂

V₁ (26.8N) = (5,000 ml) (0.02N)

V₁ = (5000 ml x 0.02 N) / 26.8 N

V₁ = 3.7 ml

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SATURATED SOLUTIONS:

Often a procedure requires a saturated solution and does not stipulate an exact quantity that you need to weigh. The laboratory will have a Handbook of Physics and Chemistry or Chemistry Handbook which, among other information, lists the saturation index of compounds in water (and other solutions may be listed). Often this is listed as the number of grams of the chemical (solute) per 100 ml of solvent. For example, the solubility of KCl in cold water is 34.7. To make 100 ml of saturated KCl you would weigh >34.7g of KCl and qs to 100 ml.

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PART PER MILLIONS:

PPM is equivalent to mg/L

1 ppm=1 mg/L

SAMPLE PROBLEMS:

1. How much 12 N HCl do you need to make 400 ml of 2N solution?

2. You took 100 ml of a concentrated acid and made 2 liters of 0.5 N solutions. What was the normality of the original solution?

3. How much 7M H₂S0₄ will you need to make 100 ml of 7N H₂S0₄?

4. How much 0.2N H₂S0₄ may be made from 80 ml of 12N H₂S0₄?

5. You weigh out 80 g of NaOH pellets and dilute to 1 liter. What is the normality?

6. You weighed out 222g of CaCl₂ and diluted to 1 liter. What is the normality?

7. How would you make a liter of 4M CaCl₂?

8. How would you make 300 ml of a 0.5M NaOH solution?

9. You weighed out 58.5 g of NaCl and diluted it to 250 ml. What is the molarity of the solution?

Experiment no. 3

Preparation of different types of Buffers (Acetate, Phosphate, Tris buffers, Citrate-

phosphate.. etc) used in biochemical studies

Objectives:

1. To prepare the different buffers for biochemical studies.

Principle:

Solutions able to retain constant pH regardless of small amounts of acids or bases added are called buffers. Classical buffer contains solution of weak acid and conjugated base. Small amounts of acids or bases added are absorbed by buffer and the pH changes only slightly. In case of high or low pH just solutions of strong acids or bases are used - for example in case of pH=1 acid concentration is relatively high (0.1 M) and small addition of acid or base doesn't change pH of such solution significantly.

How to calculate pH of buffer solution containing both acid and conjugated base?

Dissociation constant definition can be rearranged into

or

(note that due to sign change [A^-] was moved to nominator).

This is so called Henderson-Hasselbalch equation (or buffer equation). It can be used for pH calculation of solution containing pair of acid and conjugate base - like HA/A^-, HA^-/A^2- or B⁺/BOH. For solutions of weak bases sometimes it s more convenient to use equation in the form

15.3

Both equations are perfectly equivalent and interchangeable.

Henderson-Hasselbalch equation is used mostly to calculate pH of solution created mixing known amount of acid and conjugate base (or neutralizing part of acid with strong base). For example, what is pH of solution prepared mixing reagents so that it contains 0.1 M of acetic acid and 0.05 M NaOH? Half of the acid is neutralized, so concentrations of acid and conjugate base are identical, thus quotient under logarithm is 1, logarithm is 0 and pH=pK_a.

This approach - while perfectly justifiable in many cases - is dangerous, as it creates false conviction that the equation can be used this way always. That's not true.

Henderson-Hasselbalch equation is valid when it contains equilibrium concentrations of acid and conjugate base. In case of solutions containing not-so-weak acids (or not-so-weak bases) equilibrium concentrations can be far from concentrations of substances put into solution.

Let's replace acetic acid from our example with something stronger - e.g. dichloroacetic acid, with pK_a=1.5. The same reasoning leads to result pH=1.5 - which is wrong. Proper pH value can be calculated from the equation 11.13 or using pH calculator - and it is 1.78. The reason is simple. Dichloroacetic acid is strong enough to dissociate on its own and equilibrium concentration of conjugate base is not 0.05 M (as we expected from the neutralization reaction stoichiometry) but 0.0334 M.

As a rule of thumb you may remember that acids with pK_a below 2.5 dissociate too easily and use of Henderson-Hasselbalch equation for pH prediction can give wrong results, especially in case of diluted solutions. For solutions above 10 mM and acids weaker than pK_a>=2.5, Henderson-Hasselbalch equation gives results with acceptable error. The same holds for bases with pK_b>=2.5. However, the same equation will work perfectly regardless of the pK_a value if you are asked to calculate ratio of acid to conjugated base in the solution with known pH.

Materials and Reagents:

1. pH meter

2. Glasswares-volumetric flasks, funnel

3. Filter papers

4. Phosphate Buffer: Monobasic sodium phosphate and Dibasic sodium phosphate

5. Acetate Buffer: Acetic acid and Sodium acetate

6. Citrate-phosphate Buffer: Citric acid and dibasic sodium phosphate

7. Tris Buffer: Tris (Hydroxymethl) aminomethane and HCl

Procedure:

1. Make stock solutions for Acetate Buffer.

A-0.2 M acetic acid (CH₃COOH)

B-0.2M sodium acetate (CH₃COONa)

X ml of A + y ml of B, dilute to a total volume of 100 ml

x	y	pH	x	y	pH
46.3	3.7	3.6	25.5	24.5	4.6
44.0	6.0	3.8	14.8	35.2	5.0
41.0	9.0	4.0	10.5	39.5	5.2
36.8	13.2	4.2	8.8	41.2	5.4
30.5	19.5	4.4	4.8	45.2	5.6

Adjust pH with pH meter by adding required component if necessary

2. Make stock solutions for Phosphate Buffer.

A-0.2 M monobasic sodium phosphate (NaH₂PO₄)

B-0.2M dibasic sodium phosphate (Na₂HPO₄)

X ml of A + y ml of B, dilute to a total volume of 200 ml

x	y	pH	x	y	pH
93.5	6.5	5.7	56.5	43.5	6.7
90.0	10.0	5.9	39.0	61.0	7.0
85.0	15.0	6.1	16.0	84.0	7.5
77.5	22.5	6.3	5.3	94.7	8.0
68.5	31.5	6.5

Adjust pH with pH meter by adding required component if necessary

3. Make stock solutions for Tris Buffer.

A-0.2 M Tris (hydroxymethly) aminomethane

B-0.2M HCl

X ml of A + y ml of B, dilute to a total volume of 200 ml. 0.05M Tris-HCl buffer

x	y	pH	x	y	pH
50.0	5.0	9.0	50.0	26.8	8.0
50.0	8.1	8.8	50.0	32.8	7.8
50.0	12.2	8.6	50.0	38.4	7.6
50.0	16.5	8.4	50.0	41.4	7.4
50.0	21.9	8.2	50.0	44.2	7.2

Adjust pH with pH meter by adding required component if necessary

4. Make stock solutions for Citrate-phosphate Buffer.

A-0.2 M dibasic sodium phosphate

B-0.1M citric acid

X ml of A + y ml of B, dilute to a total volume of 200 ml

x	y	pH	x	y	pH
20.55	79.45	3.0	63.15	36.85	6.0
38.55	61.45	4.0	82.35	17.65	7.0
51.50	48.50	5.0	97.25	2.75	8.0

Adjust pH with pH meter by adding required component if necessary

Observation:

Note:

Components	pH range
HCl, Sodium citrate	1 - 5
Citric acid, Sodium citrate	2.5 - 5.6
Acetic acid, Sodium acetate	3.7 - 5.6
K2HPO4, KH2PO4	5.8 - 8
Na2HPO4, NaH2PO4	6 - 7.5
Borax, Sodium hydroxide	9.2 - 11
Tris Buffer	7.2-9.0

Experiment no. 4

Preparation of various sub-cellular fractions of liver cells (rat, chicken…) by

Differential Centrifugation method

Objectives:

1. To prepare various sub-cellular fractions of liver cells (rat, chicken…) by Differential centrifugation method

Principle:

The process of differential centrifugation is based on the fact that organelles have differences in size, shape and density. As a result, the effect of gravity on each is different. We can use this principle to separate an organelle from a homogenous solution of particles by artificially controlling the gravity of a solution. This is done by putting the solution in a variable speed centrifuge and rotating them at a high rate of speed. This creates a force that can be much greater than the force of gravity, and particles that would normally stay in solution will fall out and form a pellet at the bottom of the tube.

Differential centrifugation schemes involve stepwise increases in the speed of centrifugation. At each step, more dense particles are separated from less dense particles, and the successive speed of centrifugation is increased until the target particle is pelleted out. The final supernatant is removed, the pellet is resuspended and further study or purification can be done on it. The fractionation of rat liver is an example of how this process works.

Materials and Reagents:

1. Centrifuge machine

2. Centrifuge tubes

3. Homogenizer

4. Homogenization media: 5mM Tris-HCl buffer(pH 7.4) containing 0.25M sucrose

5. Liver cells

6. Cheese cloth

Procedure:

1. Weigh 1 g of liver tissue (Chicken liver) and cut into small pieces.

2. Transfer the liver slices alongwith homogenization media into chilled homogenizer. Operate the homogenizer and push the glass tube (handle) up and down to ensure the breakage of the cells.

3. Filter the homogenate through 3-4 layers of cheese cloth.

4. Pour the homogenate into a centrifuge tube and centrifuge the supernatant at 1000 X g for 10 min to sediment the heaviest material (P1-pellet- 1).

5. Remove the supernatant carefully and again centrifuge it at 3000 X g for 10 min to obtain second heaviest material (P2 pellet-2). Recover the pellet by withdrawing the supernatant with a syringe or micropipette.

6. Subject the supernatant from the preceding step to centrifuge at 10000 X g for 30 min.Gently recover the pellet by withdrawing the supernatant and labeled it P3 (pellet-3)

7. Finally centrifuge the remaining supernatant from the above step at 100000 X g for 40 min to obtain pellet P4. Decant the supernatant into a chilled beaker and store it.

8. Store all pellets separately at chilled condition and observe for the contents.

Experiment no. 5

Fractionation of serum protein by salt (Sodium chloride and Ammonium sulphate=separation of albumin and globulin)

Objectives:

1. To separate albumin and globulin of serum protein by Ammonium sulphate fractionation

2. To separate albumin and globulin of serum protein by Sodium chloride

Principle:

There are hydrophobic amino acids and hydrophilic amino acids in protein molecules. After protein folding in aqueous solution, hydrophobic amino acids usually form protected hydrophobic areas while hydrophilic amino acids interact with the molecules of solvation and allow proteins to form hydrogen bonds with the surrounding water molecules. If enough of the protein surface is hydrophilic, the protein can be dissolved in water. When the salt concentration is increased, some of the water molecules are attracted by the salt ions, which decreases the number of water molecules available to interact with the charged part of the protein. As a result of the increased demand for solvent molecules, the protein-protein interactions are stronger than the solvent-solute interactions; the protein molecules coagulate by forming hydrophobic interactions with each other. This process is known as salting out. As different proteins have different compositions of amino acids, different protein molecules precipitate at different concentrations of salt solution. Unwanted proteins can be removed from a protein solution mixture by salting out as long as the solubility of the protein in various concentrations of salt solution is known. After removing the precipitate by filtration or centrifugation, the desired protein can be precipitated by altering the salt concentration to the level at which the desired protein becomes insoluble.

Certain ions can increase the solubility of a protein when the concentration of the ions increases, instead of decreasing the solubility of the protein. Also some ions can denature certain proteins so if assays on the function of proteins are intended then either a different ion or an alternative purification method should be used. In attempting to remove a product from water, NaCl is often used to increase the ionic strength of water, thereby increasing its polarity, and then the product is moved into the organic layer where it can be extracted.

Materials and Reagents:

1. Centrifuge machine
2. Centrifuge tubes
3. Dialysis bags
4. Ammonium sulphate / Sodium chloride
5. Acetic acid / Barium chloride / Silver nitrate
6. Blood sample

Procedure:

Fractionation by Ammonium sulphate:

1. Take 2 ml of fresh blood serum in a test tube.

2. Add 2 ml of saturated ammonium sulphate in the serum sample and stir well.

3. Transfer the serum sample into a centrifuge tube as soon as precipitate appears and centrifuge at 4000 rpm for 10 min to obtain the pellet (globulin fraction).

4. Store the pellet at cool condition with label.

5. Again take the supernatant from the previous step and add the ammonium sulphate crystal slowly till precipitate observe.

6. Centrifuge again at 8000 rpm for 10 min.

7. Collect the pellet 2 (Albumin fraction) and store at cool condition.

8. Dilute each fraction in appropriate buffer and fill in dialysis bags separately.

9. Then, perform dialysis to remove the salts in the precipitates.

Fractionation by Sodium chloride:

1. Take 2 ml of fresh blood serum in a test tube.

2. Add sodium crystals in the serum sample and stir well until saturation.

3. Transfer the serum sample into a centrifuge tube as soon as precipitate appears and centrifuge at 4000 rpm for 10 min to obtain the pellet (globulin fraction).

4. Store the pellet at cool condition with label.

5. Again take the supernatant from the previous step and add acetic acid slowly till precipitate observe.

6. Centrifuge again at 8000 rpm for 10 min.

7. Collect the pellet 2 (Albumin fraction) and store at cool condition.

8. Dilute each fraction in appropriate buffer and fill in dialysis bags separately.

9. Then, perform dialysis to remove the salts in the precipitates.

Observation:

Serum is rich in proteins. About 6-8 % of the serum is protein. Among the proteins, the major two proteins in serum are albumin and globulin. Albumin constitutes 35-60 g/L of serum while globulin constitutes about 25-35 g/L of serum. Hence the ratio of the two proteins in serum should be; Albumin: Globulin=2: 1 to 2.5: 1.

Table-1: Ammonium Sulphate Concentration table

Final required concentration of ammonium sulphate (% saturation)
%	10	15	20	25	30	33	35	40	45	50	55	60	65	70	75	80	85	90	95	100
Grams solid ammonium sulphate to be added to 1 L of solution
0	56	84	114	144	176	196	209	243	277	313	351	390	430	472	516	561	610	662	713	767
10		28	57	86	118	137	190	183	216	251	288	326	365	406	449	494	540	592	640	694
15			28	57	88	107	120	153	185	220	256	294	333	373	415	459	506	556	605	657
20				29	59	78	91	123	155	189	225	262	300	340	382	424	471	520	569	619
25					30	49	61	93	125	158	193	230	267	307	348	390	436	485	533	583
30						19	30	62	94	127	162	198	235	273	314	356	401	449	496	546
33							12	43	74	107	142	177	214	252	292	333	378	426	472	522
35								31	63	94	129	164	200	238	278	319	364	411	457	506
40									31	63	97	132	168	205	245	285	328	375	420	469
45										32	65	99	134	171	210	250	293	339	383	431
50											33	66	101	137	176	214	256	302	345	392
55												30	67	103	141	179	220	264	307	353
60													34	69	105	143	183	227	269	314
65														34	70	107	147	190	232	275
70															35	72	110	153	194	237
75																36	74	115	155	198
80																	38	77	117	157
85																		39	77	118
90																			38	77
95																				39

Experiment no. 6

Precipitation and separation of protein of interest by TCA (Trichloroacetic acid)

method from biological sample

Objectives:

1. To precipitate the protein of interest by TCA (Trichloroacetic acid) method

Principle:

The solubility of proteins is determined by four variables: pH, ionic strength, temperature, and protein concentration. Numerous different techniques have been developed for protein precipitation by modifying one or more of these parameters. TCA leads to a strong decrease in pH, resulting in denaturation and consequently precipitation of the protein. Three chloro groups in the molecule also play an important role in protein precipitation

Materials and Reagents:

1. Centrifuge machine
2. Centrifuge tubes
3. Trichloroacetic acid
4. Acetone
5. serum
6. 0.1M phosphate buffer

Procedure:

1. Take 2 ml in a clean test tube and add volumes of ice cold acetone containing 10% w/v TCA.

2. Mix immediately by gentle vortexing and incubate at -20^oC for 90 minute

3. Centrifuge at 8,000 rpm, 4^oC for 10min and collect the pellet (Globulin)

4. Remove the supernatant. Again add equal volume of ice cold acetone to pellet to wash the precipitate.

5. Incubate and centrifuge as above.

6. Remove the acetone containing supernatant.

7. Add equal volume of ice cold acetone to the 10% TCA/acetone-containing supernatant to completely precipitate the protein in the supernatant.

8. The precipitate (Albumin) was dissolved in minimum volume of 0.1 M phosphate buffer, pH 7.00.

Experiment no. 7

Separation and identification of amino acids in a given mixture by ascending paper chromatography

Objectives:

1. To separate amino acids in a given mixture by ascending paper chromatography.

2. To identify the amino acids by comparing their R_f values with standard amino acids.

Principle:

Amino acids in a given mixture or sample aliquot are separated on the basis of differences in their solubilities hence differential partitioning coefficients in a binary solvent system. The amino acids with higher solubilities in stationary phase move slowly as compared to those with higher solubilities in the mobile phase. The separated amino acids are detected by spraying the air dried chromatogram with ninhydrin reagent. All amino acids give purple or bluish purple colour on reaction with ninhydrin except praline and hydroxyproline which give a yellow coloured product. The reactions leading to the formation of purple complexes are given below:

Materials and Reagents:

1. Whatman No. 1 filter paper sheet
2. Micropipette / microsyringe
3. Hair drier / Sprayer
4. Oven set at 105˚C
5. Chromatographic chamber saturated with water vapors
6. Developing solvent: butanol, acetic acid and water in the ratio of 4:1:5
7. Ninhydrin spray reagent: Prepare fresh by dissolving 0.2g ninhydrin in 100 ml acetone
8. Standard amino acids: Prepare solutions of authentic samples of amino acids such as methionine, tryptophan, alanine, glycine, threonine etc.(1 mg/ml of 10% iso-propanol)
9. A sample containing mixture of unknown amino acids

Procedure:

1. Take Whatman No. 1 filter paper and lay it on a rough filter paper. Throughout the experiment care should be taken not to handle the filter paper with naked hands and for this purpose either gloves should be used or it should be handled with the help of folded piece of rough filter paper.
2. Fold the Whatman No.1 filter paper about 2.0-2.5 cm from one edge. Reverse the paper and again fold it 2 cm further down from the first fold.
3. Draw a line across the filter paper with a lead pencil at a distance of about 2 cm from the second fold. Put circular marks along this line at a distance of 2.5 cm from each other.
4. With the help of a micropipette or microsyringe apply 20 μl of solution of each standard amino acid on a separate mark. Also apply spot of the sample or mixture to be analyzed, preferably on the mark at the center of this base line. The size of the spot should be as small as possible so that the developed spots are compact and do not overlap. If necessary, the wet sample spot should be dried with hair drier before applying additional aliquot.
5. Hang the filter paper in a chromatographic chamber which has preciously been saturated with aquerous phase of the solvent system. This is done by keeping Petri plates containing the aqueous phase at bottom of the chamber. The paper is hung from the trough/tray and a glass rod is kept to hold it in place. Care should be taken to ensure that the base line should not get submerged when the mobile phase added to the trough otherwise the spotted material would get dissolved in the solvent.
6. Close the chamber firmly so that it is airtight. Allow sufficient time for cellulose fibers of the paper to get fully hydrated.
7. Pour the mobile phase through the holes provided on the lid of the chamber into the trough. Replace the rubber bungs in the hole and allow the mobile phase to run down the paper till solvent front reaches about 5 cm from the opposite edge.
8. Remove the paper and mark the solvent front with lead pencil and let it dry at room temperature.
9. Spray the filter paper (chromatogram) with ninhydrin reagent and after drying it at room temperature, transfer it to an oven at 105˚C for 5-10 min.
10. Blue or purple colored spots would appear on the paper. Mark the boundary of each spot with lead pencil.
11. Measure the distance between the center of the spots and also the distance of the solvent front from the base line.
12. Calculate the R_f value of standard amino acids as well as those in the given mixture or sample as follows:
13. Identify the amino acids in the mixture or sample by comparing their R_f values with those of the reference standards.

Note: It is advisable to carry out chromatography in three different solvent systems before the identity of amino acid in the mixture or sample can be established with any degree of certainty.

Experiment no. 8

Separation and identification of amino acids in a given mixture by two dimensional

paper Chromatography

Objectives:

1. To separate amino acids in a given mixture by two dimensional paper chromatography.

2. To identify the amino acids by comparing their R_f values with standard amino acids.

Principle:

Amino acids have very close Rf values in a particular solvent system may appear as a single or overlapping spots in a single dimensional chromatography and may be mistaken as one component. They can be separated into individual components by developing the chromatogram again in a direction perpendicular to the first run in a second solvent system in which they have different R_f values. The main limitation of this method is that only one spot either filter paper sheet necessitating running of a large number of chromatogram for the standard amino acids.

Materials and Reagents:

1. Whatman No. 1 filter paper sheet
2. Micropipette / microsyringe
3. Hair drier / Sprayer
4. Oven set at 105˚C
5. Chromatographic chamber saturated with water vapours
6. Solvent system first: butanol: acetic acid: water= 4:1:5 v/v
7. Solvent system second: phenol: water=80:20 w/v (Add 125 ml of water to 500g of phenol and add few drops of ammonia to the mixture)
8. Ninhydrin spray reagent: Prepare fresh by dissolving 0.2g ninhydrin in 100 ml acetone
9. Standard amino acids: Prepare solutions of authentic samples of amino acids such as methionine, tryptophan, alanine, glycine, threonine etc.(1 mg/ml of 10% iso-propanol)
10. A sample containing mixture of unknown amino acids

Procedure:

1. Take Whatman No. 1 filter paper and lay it on a rough filter paper. Throughout the experiment care should be taken not to handle the filter paper with naked hands and for this purpose either gloves should be used or it should be handled with the help of folded piece of rough filter paper.
2. Draw a base line 5 cm from one edge of the paper. Reverse the paper and again draw another line perpendicular to the first line again 5 cm from one adjacent edge of the paper.
3. With the help of a micropipette or microsyringe apply 60 μl of solution at the point of intersection.
4. Repeat the same procedure for a mixture of standard amino acids in a separate chromatographic sheet for each mixture.
5. Hang the chromatographic sheets in a chromatographic chamber which has preciously been saturated with aqueous phase of the solvent system first. This is done by keeping Petri plates containing the aqueous phase at bottom of the chamber. The paper is hung from the trough/tray and a glass rod is kept to hold it in place.
6. After allowing an equilibrium period of half an hour, pour the solvent system first in to the trough of the chamber and let it run till it is about 5cm from the opposite end of the paper.
7. Take the paper out, air dry it and turn it at 90˚ and now develop the paper in the second chromatographic chamber using solvent system second.
8. Remove it when the solvent has traveled upto about 5 cm from the opposite end.
9. Spray the filter paper (chromatogram) with ninhydrin reagent and after drying it at room temperature, transfer it to an oven at 105˚C for 5-10 min.

Observation:

Calculate the R_f value of standard amino acids as well as those in the given mixture in both the solvents and identify the amino acids in the mixture or sample by comparing their R_f values with those of the reference standards.

Experiment no. 9

Separation and identification of sugars (sugar juices) by adsorption Thin layer chromatography (TLC)

Objectives:

1. To separate sugars in a given mixture by adsorption Thin layer chromatography.

Principle:

Sugars get separated on the basis of differential adsorption onto silica gel. The sugars which have higher affinity for stationary phase are adsorbed more strongly and hence they migrate slowly when mobile phase moves over them. On the other hand, those having lower affinity for stationary phase are weakly adsorbed and are more easily carried by the mobile phase. The separated sugars are then located as colored zones by spraying TLC plates with aniline diphenylamine reagent.

Materials and Reagents:

1. TLC chromatographic tank
2. Glass plates (20 х 20 cm)
3. Spreader / Hair drier / Sprayer or atomizer
4. Micropipettes / micro-syringes
5. Oven maintained at 105˚C
6. Solvent System: Prepare a mixture of ethyl acetate: iso-propanol: water: pyridine (26:14:7:2,v/v)
7. Standard sugar solutions: Prepare 1% solution of standard sugars such as glucose, ribose, lactose etc. in 10% iso-propanol (v/v). For mixture in which the sugars have to be identified, mix the sugar solutions in equal proportion
8. Aniline diphenylamine reagent: Mix 5 volumes of 1% aniline and 5 volumes of 1% diphenylamine in acetone with 1 volume of 85% phosphoric acid

Procedure:

1. Place thoroughly cleaned and dried glass plates (20x20 cm) on a flat plastic tray side by side with no gap between the two adjacent plates.
2. Prepare slurry of the stationary phase (Silica Gel G) free of clumps in water or in an appropriate buffer.
3. Spread a uniform layer of 250 µm thickness with the help of a spreader or an applicator by moving it from one end of the ray of the tray to its other end.
4. Activate the plates by keeping them at 105˚C for 30 min. Allow the plates to cool in a desiccator before use.
5. Gently put the marks in a straight line with the help of a pin at a distance of about 2 cm from one edge of the plate. The adjacent marks should be taken that silica does not get scratched of while putting these marks.
6. Carefully apply the solution of individual standard sugars and the mixture or alcoholic extract of the sample on the separate marked spots.
7. Gently put marks or draw a line 1 cm from the opposite edge.
8. Place the plate in chromatographic tank which has already been equilibrated with the solvent taking care that base line on which samples have been applied does not dip into the solvent.
9. Close the chromatographic tank with air tight lid and allow the solvent to ascend along the plate by capillary action till the solvent reaches the marked line on the upper side of the plate. This may take about 90 min.
10. Remove the plate from chromatographic tank and let it dry at room temperature.
11. For determining the location of sugars on the TLC plates, spray it with freshly prepared aniline-diphenylamine reagent ensuring that silica gel is not removed or brown off while spraying.
12. Place the plates in hot air oven at 100˚C for 10 min. Appearance of bluish spots on the white background indicates presence of sugars at that region of the plate.
13. Measure the distance from the base line to the center of the colored spot and calculate the R_f value of each sugar as described in EXPERIMENT 9.6.1.
14. Identify the sugars in the given mixture or sample by comparing their R_f values with those of sugar standards.

Precautions:

A number of precautions should be observed while performing TLC. Some of these are:

1. Thoroughly cleaned glass plates free of any greasy spots or finger marks should be used.

2. Thickness of the layer should be uniform throughout the length of the plate.

3. The slurry of the chromatographic media should be free of any clumps. This can be ensured by vigorously shaking it in an Erlenmeyer flask or by gently preparing the slurry in pestle and mortar to ensure uniform mixing.
4. The TLC plates should be activated at recommended temperature and duration. Poor resolution of components occurs on over or under activated plates.
5. The layer of chromatographic media should not get scraped off at the time of putting marks of application of samples.
6. Size of the applied spot should be as small as possible. If large volume of the sample has to be spotted, then it should be done in small aliquots with an intermittent drying. Overloading of the sample should be avoided.

The chromatographic tank should be airtight and chromatography should be performed under temperature controlled conditions.

Experiment no. 10

Extraction and identification of lipids from given biological samples (egg, cooking

oils…..) by Thin layer chromatography

Objectives:

1. To extract lipids from biological samples

2. To identify the lipids by Thin layer chromatography

Principle:

In the biological materials, lipids are found as lipoprotein complexes and these have to be extracted. Lipids, being soluble in non-polar organic solvents and proteins being soluble in polar aqueous solvents, the efficient lip[id extraction can be achieved only when an aqueous solvent like ethanol or methanol is included in th non-polar organic solvents like chloroform and diethyl ether. This would help in breaking the lipoprotein complexes. Extracted lipid components can be separated on TLC based on their differential mobility along the porous stationary phase such as silica gel and these can be located by spraying the plates with either 2’, 7’ dichlorofluorescein or 50% sulphuric acid or iodine vapor.

Materials and Reagents:

1. TLC chromatographic tank
2. Glass plates (20 х 20 cm)
3. Micropipettes / microsyringes / Spreader / Hair drier / Sprayer or atomizer
4. Oven maintained at 105˚C
5. Solvent System: petroleum ether (b.p-60-70˚C) or hexane: diethyl ether: glacial acetic acid(80:120:1 v/v)
6. Lipid standards: varied lipids such as cholesterol acetate, vitamin A, palmitate, triacyl glycerol, vegetative oils, egg, animal oils.
7. Staining reagent: 2’, 7’ dichlorofluorescein or 50% sulphuric acid or iodine crystals.

Procedure:

1. Extraction of lipids from sample: Grind 1 g of the tissue in the extraction solvents (either ethyl ether: ethanol=3:1 or chloroform: methanol=2:1) in mortal and pestle. Transfer the homogenate to a separating funnel. Shake the contents vigorously and allow it to stand till the two phases have completely separated. Drain out the lower organic layer which contains the lipids. Evaporate the solvent under vaccum and keep the concentrated lipid extract protected from light under N atmosphere.
2. Extraction from egg yolk: Make a small hole on the polar region of egg and invert in into a small beaker to separate white part (sac) till yellow part fall down. Then, mix and dissolve yolk in 5 ml of chloroform. Centrifuge it at 4000rpm for 10 min and evaporate on boiling water bath. Again redissolve in required amount of chloroform.
3. Prepare the TLC plate using silica gel as described in previous experiment-9 and activate the plates by keeping them at 105˚C for 30 min. Allow the plates to cool in a desiccator before use.
4. Carefully apply the solution of individual lipid samples on the separate marked spots.
5. Develop the plates in the solvent system described above till the solvent traveled upto 1 cm from the opposite side of the plate.
6. Remove the plate from chromatographic tank and let it dry at room temperature.
7. For determining the location of lipids on the TLC plates, spray it with freshly prepared 2’, 7’ dichlorofluorescein or 50% sulphuric acid. Or place the tank in en empty tank and add iodine crystal into the tank, then shield the tank airtightly by glass plate.
8. Calculate the R_f values of lipids standards and identify the lipids by comparing their with those of standards.

Experiment no. 11

Purification of bovine serum albumin from buffalo serum by size exclusion

chromatography (gel filtration)

Objectives:

1. To purify bovine serum albumin from buffalo serum by size exclusion chromatography (Gel Filtration).

Principle:

The chromatographic media used in this technique are porous, polymeric organic compounds with molecular sieving properties. These are cross linked polymers which swell considerably in water forming a gel of a three dimensional network of pores. The size of pore is determined by degree of cross-linking of polymeric chains. Differential solutes in a mixture get separated on the basis of their molecular size and shape during their passage through a column packed with the swollen particles. The terms “exclusion chromatography”, “gel filtration” and “molecular sieve” chromatography are used for this separation process. The large molecules in the sample are unable to penetrate through the pores into the gel and thus remain excluded from entering the beads. Therefore they travel through the interstitial spaces with high acceleration. However the small molecules enter into the gel beads and get distributed between the mobile phase inside as well as outside the gel particles. These thus follow a longer path than the larger molecules and hence their movement down is retarded. Consequently different molecules getting separated in the sample get separated from each other with larger molecule getting eluted first followed by smaller molecules.

Material and Reagents:

1. Glass column (2.5 X 25 cm)

2. Spectrophotometer

3. Sephadex G-100

4. Buffalo Serum

5. Sodium phosphate

6. 0.1 M Tris HCl buffer (pH 7.0)

7. SDS-PAGE (will be described in later)

Procedure:

1. Suspend 5 g of sephadex G-100 (coarse) in 0.1 M Tris-HCl buffer (pH 7.0) and swell it by keeping it for 3-4 h at room temperature with intermittent stirring.
2. Decant the excess of buffer alongwith any suspended fine particles to obtain slurry of reasonable thickness.
3. Fix the column upright on a burette stand with the help of clamps.
4. Keep the outlet of the column closed, place a plug of glass wool at he base of the column and pour a small volume of the buffer or water into the column.
5. Pour the slurry gradually into it along the inner surface of its wall and, if necessary with gentle tapping to expel any air bubbles.
6. Allow the chromatographic media to settle down evenly and then open the outlet to drain excess liquid from the column.
7. Place a filter paper disc or a nylon gauze on the surface of the packed bed to prevent disturbance of the upper layer while loading the sample or feeding the eluent into the column.
8. Prepare a mixture of 10mg of bovine serum and 40 mg of sodium phosphate in 2 ml Tris-HCl buffer (pH 7.0).
9. Apply it to chromatographic column by any one of the two methods:

i. The mobile phase at the top of the packing is drained out till the bed surface gets exposed. Close the outlet and gently apply the sample uniformly over the bed surface with pipette and the loaded sample is then allowed to just enter into the column by opening the outlet. A small amount of mobile phase is added to wash the traces of the sample into the column.

ii. In the second method, sucrose or glycerol, upto the concentration of 1% is added in the sample to increase its density. This sample is applied just above the surface of bed directly through the layer of the buffer in the column bed. Since the sample has higher density, it automatically settles on the surface of the gel. Then open the outlet to facilitate entry of the sample into the column. When using this procedure, it is advisable to ensure that addition of glycerol or sucrose does not interfere with the separation and subsequent analysis of the separated compounds.

10. Add sufficient amount of buffer on top of the column and connect it to the buffer reservoir.
11. Collect the fraction of 2 ml either manually or using an automatic fraction collector. Determine the protein content either by monitoring absorbance at 280 nm or any chemical detection method.
12. Plot a graph of concentration of protein and fraction number or elution volume.
13. Find out the molecular weight of each peak fraction by SDS-PAGE.

Experiment no. 12

Determination of molecular weight of a given protein by SDS-PAGE (Sodium Dodecylsulphate Polyacrylamide Gel Electrophoresis)

Objective:

1. To determine the molecular weight of a given protein by SDS-PAGE

Principle:

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) has proven to be among the most useful tools yet developed in the area of molecular biology. The discontinuous buffer system, first described by Laemmli. Acrylamide mixed with bisacrylamide forms a cross-linked polymer network when the polymerizing agent, ammonium persulfate, is added (Figure 1). The ammonium persulfate produces free radicals faster in the presence of TEMED (N, N, N, N’-tetramethylenediamine). The size of the pores created in the gel is inversely related to the amount of acrylamide used. Gels with a low percentage of acrylamide are typically used to resolve large proteins and high percentage gels are used to resolve small proteins.

Figure 1. Polymerization and cross-linking of acrylamide.

The electrophoretic mobility of a protein is determined mostly by its net charge per unit mass at the given pH, but is inversely proportional to its frictional coefficient in the gel, determined by the proteins size and shape. In the denaturing, reductive variant of PAGE, SDS-PAGE all differences between the proteins in charge per unit mass has been eliminated by the SDS (sodium dodecylsulphate) and the proteins migrate solely according to subunit size. The charged SDS molecules bind all along the polypetide chain, giving the chain equal charge per unit length. Thus, the denatured polypeptide chains are separated electrophoretically only according to their subunit length

Materials and Reagents:

1. SDS-PAGE gel apparatus.
2. Power pack.
3. Blotting apparatus.
4. Separating gel
5. Stacking gel
6. Running buffer
7. Sample buffer
8. Staining solution
9. Destaining solution

1. Separating Gel (pH 8.8)

	7%	10%	12%	15%
Distilled water	5.1 ml	4.1 ml	3.4 ml	2.4 ml
1.5 M Tris-HCl, pH 8.8	2.5 ml	2.5 ml	2.5 ml	2.5 ml
20% (w/v) SDS	0.05 ml	0.05 ml	0.05 ml	0.05 ml
Acrylamide/Bis-acrylamide (30%/0.8% w/v)	2.3 ml	3.3 ml	4.0 ml	5.0 ml
10% (w/v) ammonium persulfate	0.05 ml	0.05 ml	0.05 ml	0.05 ml
TEMED	0.005 ml	0.005 ml	0.005 ml	0.005 ml
Total monomer	10.005 ml	10.005 ml	10.005 ml	10.005 ml

2. The Stacking Gel (pH 6.8)

Ingredients Amount

Distilled water 3.075 ml

0.5 M Tris-HCl, pH 6.8 1.25 ml

0% (w/v) SDS 0.025 ml

Acrylamide/Bis-acrylamide (30%/0.8% w/v) 0.67 ml

10% (w/v) ammonium per sulfate 0.025 ml

TEMED 0.005 ml

Total Stack monomer 5.05 ml

For best results:

1. Ammonium persulfate solution should be freshly made.

2. Degas solutions should be degassed before adding TEMED for 15 min at room temperature.

3. Running the gel (5X, pH 8.3)

Ingredients Amount

Tris Base 15 g

Glycine 72 g

SDS 5 g

Distilled water 1000 ml

Dilute to 1X before use and store at room temperature until use.

4. Sample buffer

Ingredients Amount

Distilled water 4.0 ml

Tris-HCl (0.5 M) 1.0 ml

Glycerol 0.8 ml

10% SDS 1.6 ml

β-mercaptoethanol 0.4 ml

Bromophenol blue (0.05%) 0.2 ml

5. Staining Solution

Ingredients Amount

Coomasie Brilliant Blue R-250 0.5 g

Methanol 250 ml

Acetic acid 50 ml

Distilled water 200 ml

6. Destaining Solution

The destaining solution was prepared similarly but without dye.

Procedure:

Sample Solubilization

1. Boil samples in sample solubilization buffer for 5-10 min. Solubilize sample at 1 mg/mL and run 5–10 μg/lane.

Gel Preparation/Electrophoresis

2. Assemble the gel apparatus. Make two marks on the front plate to identify top of separating gel and top of spacer gel. Assuming a well depth of 12 mm, the top of the separating gel should be 3.5 cm down from the top of the back plate, and the spacer gel should be 2 cm down from the top of the back plate, leaving a stacking gel of 8 mm.
3. Combine the reagents to make the separating gel, mix gently, and pipette the solution between the plates to lowest mark on the plate. Overlay the gel solution with 2 mL of dH₂O by gently running the dH₂O down the center of the inside of the front plate. Allow the gel to polymerize for about 20 min. When polymerized, the water–gel interface will be obvious.
4. Pour off the water, and dry between the plates with filter paper. Do not touch the surface of the separating gel with the paper. Combine the reagents to make the spacer gel, mix gently, and pipette the solution between the plates to second mark on the plate. Overlay the solution with 2 mL of dH2O by gently running the dH₂O down the center of the inside of the front plate. Allow the gel to polymerize for about 20 min. When polymerized, the water–gel interface will be obvious.
5. Pour off the water, and dry between the plates with filter paper. Do not touch the surface of spacer gel with the paper. Combine the reagents to make the stacking gel and mix gently. Place the well-forming comb between the plates, leaving one end slightly higher than the other. Slowly add the stacking gel solution at the raised end (this allows air bubbles to be pushed up and out from under the comb teeth). When the solution reaches the top of the back plate, gently push the comb all the way down. Check to be sure that no air pockets are trapped beneath the comb. Allow the gel to polymerize for about 20 min.
6. When the stacking gel has polymerized, carefully remove the comb. Straighten any wells that might be crooked with a straightened metal paper clip. Remove the acrylamide at each edge to the depth of the wells. This helps prevent “smiling” of the samples at the edge of the gel. Seal the edges of the gel with 2% agarose.
7. Add freshly diluted cathode running buffer to the top chamber of the gel apparatus until it is 5–10 mm above the top of the gel. Squirt running buffer into each well with a Pasteur pipet to flush out any unpolymerized acrylamide. Check the lower chamber to ensure that no cathode running buffer is leaking from the top chamber, and then fill the bottom chamber with anode buffer. Remove any air bubbles from the under edge of the gel with a bent tip Pasteur pipette. The gel is now ready for sample loading.
8. After loading the samples and the molecular-mass markers, connect leads from the power pack to the gel apparatus (the negative lead goes on the top, and the positive lead goes on the bottom). Gels can be run on constant current, constant voltage, or constant power settings. When using the constant current setting, run the gel at 50 mA. The voltage will be between 50 and 100 V at the beginning, and will slowly increase during the run. For a constant voltage setting, begin the electrophoresis at 50 mA. As the run progresses, the amperage will decrease, so adjust the amperage to 50 mA several times during the run or
9. The electrophoresis will be very slow. If running on constant power, set between 5 and 7 W. Voltage and current will vary to maintain the wattage setting. Each system varies, so empirical information should be used to modify the electrophoresis conditions so that electrophoresis is completed in about 4 h.
10. When the dye front reaches the bottom of the gel, turn off the power, disassemble the gel apparatus, and place the gel in 200–300 mL of fixer/destainer. Gently shake for 16 h. Pour off spent fixer/destainer, and add CBB. Gently shake for 30 min. destain the gel in several changes of fixer/destainer until the background is almost clear. Then place the gel in dH₂O, and gently mix until the background is completely clear. The peptide bands will become a deep purple-blue. The gel can now be photographed or dried. To store the gel wet, soak the gel in 7% glacial acetic acid for 1 h, and seal in a plastic bag.

Experiment no. 13

Native Disc gel electrophoresis of proteins

Objective:

1. To perform the nondenaturing gel electrophoresis of protein

Principle:

Nondenaturing system is used to separate intact proteins, especially oligomeric proteins, by a nondestructive means for later assessment of biological activity. On nondenaturing system, protein separation depends on a combination of differences in molecular size and shape as well as charge. Separation by size is accomplished by varying the pore size of the acrylamide polymer as a function of both the concentration of the acrylamide (range about 3-30%, w/v) and the amount of cross-linker used. In general, the higher the acrylamide concentration, the smaller the protein that remains in gel: this can be counteracted by decreasing the amount of cross-linker used, which in turn increases the degree of gel swelling during standard staining and washing procedures. Separation by charge in nondenaturing gel systems is permitted because the protein separation can be performed at any pH between 3 and 11 to allow for maximal charge differences neighboring protein species. These include the molecular weight of the stability in the range of pH 4 to 9. Once these parameters are known optimal resolution can be obtained by varying certain components within a single gel system. For example the initial choice of the gel system for separation of acidic protein of molecular weight 20,000 might be a system operating at an alkaline pH i.e.9 with an acrylamide concentration of 12-15 %.

Materials and Reagents:

1. Same as in SDS-PAGE

1. The Stacking Gel (pH 6.8)

Ingredients Amount

Distilled water 3.075 ml

0.5 M Tris-HCl, pH 6.8 1.25 ml

Acrylamide/Bis-acrylamide (30%/0.8% w/v) 0.67 ml

Riboflavin (0.004%) 0.0625 ml

TEMED 0.005 ml

Total Stack monomer 5.05 ml

2. Separating Gel (pH 8.8)

	7%	10%	12%	15%
Distilled water	5.1 ml	4.1 ml	3.4 ml	2.4 ml
1.5 M Tris-HCl, pH 8.8	2.5 ml	2.5 ml	2.5 ml	2.5 ml
Acrylamide/Bis-acrylamide (30%/0.8% w/v)	2.3 ml	3.3 ml	4.0 ml	5.0 ml
10% (w/v) ammonium persulfate	0.05 ml	0.05 ml	0.05 ml	0.05 ml
TEMED	0.005 ml	0.005 ml	0.005 ml	0.005 ml
Total monomer	10.005 ml	10.005 ml	10.005 ml	10.005 ml

Remainings are same as for SDS-PAGE

Procedure: Same as for SDS-PAGE.

Experiment no. 14

Determination of molecular weight of DNA (genomic and plasmid) by Agarose gel

electrophoresis

Objectives:

1. To determine molecular weight of DNA by agarose gel electrophoresis

Principle:

DNA electrophoresis is an analytical technique used to separate DNA fragments by size. An electric field forces the fragments to migrate through a gel. DNA molecules normally migrate from negative to positive potential due to the net negative charge of the phosphate backbone of the DNA chain. At the scale of the length of DNA molecules, the gel looks much like a random, intricate network. Longer molecules migrate more slowly because they are more easily 'trapped' in the network. Double-stranded DNA fragments naturally behave as long rods, so their migration through the gel is relative to their radius of gyration, or, for non-cyclic fragments, size. Single-stranded DNA or RNA tend to fold up into molecules with complex shapes and migrate through the gel in a complicated manner based on their tertiary structure. Therefore, agents that disrupt the hydrogen bonds, such as sodium hydroxide or formamide, are used to denature the nucleic acids and cause them to behave as long rods again.

After the separation is completed, the fractions of DNA fragments of different length are often visualized using a fluorescent dye specific for DNA, such as ethidium bromide. The gel shows bands corresponding to different DNA molecules populations with different molecular weight. Fragment size is usually reported in "nucleotides", "base pairs" or "kb" (for 1000's of base pairs) depending upon whether single- or double-stranded DNA has been separated. Fragment size determination is typically done by comparison to commercially available DNA ladders containing linear DNA fragments of known length.

Materials and Reagents:

1. 1X TAE buffer at pH 8.0 (50X, 24.2gm Tris, 5.71ml GAA, 11.1ml of 0.5M EDTA, 100ml DW) Autoclave before use – 1.5L
2. Agarose gel in 1X TAE – 65ml
3. Loading dye (6X, 6.0ml of 50% Glycerol, 1.0ml of 2%BPB, 3ml sterile DW) – 0.5ml
4. Ethidiun Bromide (EtBr)*: 10mg/ml stock
5. λ/HindIII Marker (23.13Kb, 9.42Kb, 6.56Kb, 2.32Kb, 2.07Kb, 0.56Kb and 0.13Kb)
6. Plasmid DNA (pUC18, pBR322)

Procedure:

1. Prepare 0.8% agarose gel in TAE buffer.

2. Dissolve agarose completely in micro-oven and cool to 60⁰C.

3. CAREFULLY, add EtBr into the gel solution to final concentration of 0.5µg/ml.

4. Pour the molten gel into gel-mould. Immediately position a comb in the mould.

5. Let the gel cool for 30 minutes.

6. Pour TAE buffer into the gel buffer reservoirs.

7. Prepare sample taking 20µl of DNA sample and mix with 4µl blue juice (6X).

8. Carefully remove the comb.

9. Load the DNA (15 - 20 µl) per well, flanking wells with similarly processed DNA size standard.

10. Put the lid on the gel apparatus, attach the electrodes and adjust voltage to 100 volts.

11. Allow the gel to run until line of blue juice is visible near the end of the gel.

12. Turn off the current and visualize the gel in UV - Tran illuminator.

13. Interpret the results.

Note: the amount of the sample that can be loaded in a well depends on the thickness of the gel as well as dimensions and placing of the comb.: EtBr is carcinogen, so, handle with gloves

Experiment no. 15

Determination of l_max of different colored and noncolored compounds by spectrophotometer

Objectives:

1. To determine l_max of different colored and noncolored compounds by spectrophotometer

Principle:

For a given substance at a specified wavelength λ, the absorptivity ε_λ is a constant characteristic of the absorbing sample and is independent of both the concentration c of the solution and the thickness d of the absorbing layer. Absorptivity and, the absorption itself depend strongly on the wavelength for nearly all compounds. So, the wavelength must be specified at which the measurement of the absorbance versus concentration is made. The way in which absorbance depends on wavelength, A= f(c), defines the spectrum of the substance being studied and the wave length at which maximum absorbance in the electromagnetic spectrum occurs is known as λ_max.

Materials and Reagents:

1. UV-visible spectrophotometer

2. Standard quartz or silica cuvette (path length =1cm)

3. Colored and non-colored solutions

4. Buffer for blank

Procedure:

1. Switch on the spectrophotometer for few minutes to warm up and switch on the UV lamp.

2. Take two matched cuvettes. In the reagent blank cuvette add 3 ml of distilled water (Buffer). In the sample cuvette add noncolored compound to be tested.

3. Set the instrument at 200nm. Place the reagent blank cuvette in the holder and again adjust it to zero absorbance (or 100% transmittance).

4. Check the zero and 100% transmission to make sure that the instrument is properly adjusted.

5. Determine the absorption of sample against the blank.

6. Now reset the instrument at 210nm with reagent blank and record reading of the sample. Repeat this step at interval of 10nm each upto 390 nm.

7. For colored compounds start taking reading from 410 nm to upto 700 nm wavelengths on the tungsten lamp switching off the deuterium lamp.

8. Draw a graph of absorbance versus the wavelength to obtain the λ_max of each colored and non-colored compound.

Observation:

The graph may looks like it.

Color of Visible Light

Color Wavelength, nm Filter color/Complementary color

Voilet 400-435 Yellow-Green

Blue 435-480 Yellow

Green-Blue 480-490 Orange

Blue-Green 490-500 Red

Green 500-560 Purple

Yellow-Green 560-580 Voilet

Yellow 580-595 Blue

Orange 595-610 Blue-green

Red 610-750 Green-blue

(NOTE: blue absorbing solution appears yellow or green absorbing solution appears purple)

NOTE : Standard solution and their respective wavelength (λ_max)

Standard solutions Wavelength (λ_max) in nm

Protein solution 280

Nucleic acid 260

Bradford’s method 595

Biuret test 670

Folin Lower’s method 660

Ninhydrin method 570

Experiment no. 16

Verification of validity of Beer’s law and determination of the molar extinction

Coefficient of BSA (Bovine Serum Albumin)

Objectives:

1. To verify the validity of Beer’s Law

2. To determine the molar extinction coefficient of BSA

Principle:

Qualitative colorimetric estimations are based on two laws i.e. Lambert’s law and Beer’s law. Lambert’s law defines the relationship between the lengths of light path through the solution (The rate of decrease of intensity with the thickness of medium is directly proportional to the intensity of light). While Beer’s law states that the intensity of a beam of monochromatic light decreases exponentially with the increase in concentration of the absorbing substance arithmetically. Combining the above two statement gives the Lambert-beer law ad states that the rate of decrease of intensity of light depends on the concentration and thickness of the medium and can be express by the equation:

Where A= absorbance

ε_λ = molar absorptivity (L mol^-1 cm^-1)

d= path length of the sample (cm)

c= concentration of the sample in solution (mol L^-1)

Absorbance is directly proportional to the other parameters, as long as the law is obeyed. After certain limitation the law is not obeyed and the straight line deviates from the normal in extreme cases of the concentration of samples and is called deviation of the law. The experiment is designed to explain why, for measurements made with samples of the same thickness d, the transmittance T of a sample decreases exponentially with increasing concentration c of the absorbing substance.

The Molar absorption coefficient, molar extinction coefficient, or molar absorptivity, is a measurement of how strongly a chemical species absorbs light at a given wavelength. It is an intrinsic property of the species; the actual absorbance, A, of a sample is dependent on the pathlength l and the concentration c of the species via the Beer-Lambert law, A = εcl.

Materials and Reagents:

1. UV-visible spectrophotometer
2. Standard quartz or silica cuvette (path length =1cm)
3. Phosphate buffer
4. Bradford reagent
5. BSA solution

Procedure:

1. Switch on the spectrophotometer for few minutes to warm up and switch on the UV lamp.

2. Take two matched cuvettes. In the reagent blank cuvette add 3 ml of distilled water (Buffer). In the sample cuvette add noncolored compound to be tested.

3. Set the instrument at 200 nm. Place the reagent blank cuvette in the holder and again adjust it to zero absorbance (or 100% transmittance).

4. Check the zero and 100% transmission to make sure that the instrument is properly adjusted.

5. Determine the absorption of sample against the blank.

6. Now reset the instrument at 210nm with reagent blank and record reading of the sample. Repeat this step at interval of 10nm each upto 390 nm.

7. For colored compounds start taking reading from 410 nm to upto 700 nm wavelengths on the tungsten lamp switching off the deuterium lamp.

8. Draw a graph of absorbance versus the wavelength to obtain the λ_max of each colored and non-colored compound.

9. For the determination of Molar extinction coefficient of BSA, Prepare BSA solution of concentration 2 mg/ml in both dH₂O and 0.9% NaCl.

10. Take the absorbance of BSA solution at 280 nm wavelength and calculate the E_percent.

11. Again calculate the molar extinction coefficient.

Calculation:

Table-1: Protein quantification by the Bradford method: protocol for preparing the standard curve and samples

Tube	BSA 10 mg/ml (ml)	H2O (ml)	BSA (mg/tube)	BSA (mg/ml)	Bradford (ml)
Blank	-	2.0	-	-	3.0
1	0.1	1.9	2.0	1.0	3.0
2	0.2	1.8	4.0	2.0	3.0
3	0.4	1.6	8.0	4.0	3.0
4	0.6	1.4	12.0	6.0	3.0
5	0.8	1.2	16.0	8.0	3.0
6	1.0	1.0	20.0	10.0	3.0
Samples	2.0				3.0

Note: Standards and samples should be analyzed in triplicate and processed at the same time, using same bath of reagents and assay conditions. Samples may require dilutions to fit in the range of absorbance values of the standard curve.

For Calculation of molar extinction coefficient

(ε_percent x c x L) / 10 = A

Where: c- concentration

L- pathlength (1 cm)

E_percent- percent solution extinction coefficients

A- Absorbance

(ε_molar) 10 = (ε_percent) × (molecular weight of protein)

Observation:

Standard values

Molecular weight of BSA = 66400

ε_percent = 6.6

ε_molar = 43,824 L M^-1cm^-1

References:

1. Blackshear P. J. (1984) Systems for polyacrylamide gel electrophoresis. In Methods in enzymology (Jakoby WB eds.) vol 104: 237-255.

2. Wilson K. and Walker J. (2002) Practical Biochemistry Principles and techniques, fifth edition, Cambridge University Press.

3. Sawhney S. K. and Sigh R. (2000) Introductory Practical Biochemistry. Narosa publishing house, New Dehli.

4. Gill, S.C. and von Hippel, P.H. (1989). Calculation of protein extinction coefficients from amino acid sequence data. Anal. Biochem. 182:319- 26.

5. Gel filtration principles and methods Amersham Biosciences.

6. Walker J.M. (2002) The protein protocols handbook, second edition, Humana press.

7. Dennison C. (2002) A guide to protein isolatioin, Kluwer academic publishers, New york.

8. Chatwal G. R. and Anand S. K. (2001) Spectroscopy Atomic and Molecular Fifth revised and enlarged edition, Himalaya Publishing House, Mumbai.

9. Plummer D. (1987) An introduction to Practical Biochemistry, Third edition.

10. Shrestha et. al; Delta Endotoxin Immunocrossreactivity of Bacillus thuringiensis isolates collected from Khumbu Base Camp of Mount Everest Region (2006) J. Food Sci. & Technol. Nepal 2:128-131.