Serial analysis of zein by isoelectric focusing and sodium dodecyl sulfate gel electrophoresis

Zein, the major storage protein of maize (Zea mays L.) endosperm, was extracted from a number of inbreds with alcohol plus a reducing agent. Isoelectric focusing (IEF) separated total zeins into 41 components, while sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) separated total zeins into about 15 components. Each procedure gave characteristic patterns of zein bands for a number of maize inbreds. IEF and SDS-PAGE were used serially so that each band separated by IEF could be assayed as an individual SDS-PAGE sample. Some IEF bands revealed only a single band after SDS-PAGE, while others revealed two or more bands. A nomenclature system is presented which integrates the two separation systems with information about chromosome locations of zein genes, maize mutations which affect zein synthesis, and inbred sources for different zeins. SDS-PAGE of zein gives apparent molecular masses which vary widely according to the standards used and the properties of the gels, therefore an artificial nomenclature for identifying zein bands after SDS-PAGE is presented. The new nomenclature provides a flexible system which is useful and can be conveniently used in different laboratories.     

Six variants of HLA-1327 identified by isoelectric focusing

Six variant forms of HLA-1327 were identified among 68 unrelated 1327-positive donors by isoelectric focusing (IEF) gel analysis. Each of the six IEF variants was distinguished by charge heterogeneity of desialated B27 heavy chains immunoprecipitated with specific monoclonal antibody (MAb). Charge differences varied from single to several charge units, indicating that these variants may have substantially different amino acid compositions. Informative family study showed that three B27 variant molecules were genetically determined. The uniqueness of these variant molecules was also demonstrable using a panel of alloantisera and MAbs recognizing 1327-associated epitopes. Six distinct serological reactivity patterns were observed. Five of these serological patterns correlated with four of the IEF-defined variants, two of these patterns being associated with one IEF variant form. The sixth serological pattern was shared by the remaining two IEF variants. Combining the results of the electrophoretic and serological analyses, it is apparent that there are more than six structural variants within the B27 alloantigen family. Some B27 variant forms were found only in individuals of particular racial origin, indicating that unique genetic variations might occur in different racial groups. In a preliminary analysis of patients with ankylosing spondylitis, no apparent correlation was observed between any specific B27 variants and disease susceptibility.     

Isoelectric focusing of high-molecular-weight protein complex under native conditions using agarose gel

The isolation and characterization of protein complexes are essential steps toward understanding cellular functions. A method for separating and characterizing high-molecular-weight protein complexes using two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) with native agarose gel isoelectric focusing (IEF) is described. Using this method, fractions containing high-molecular-weight protein complexes were analyzed. The advantages of using native agarose gel IEF include the ability to concentrate the protein complexes and the ease of handling when performing 2D separations. Although limited with respect to the size of molecules and particles that may be separated, this method is useful for the isolation and characterization of high-molecular-weight protein complexes.     

Preparative isoelectric focusing of human serum very low-density and low-density lipoproteins.

Ten percent glycerol prevented the usual precipitation of human serum very low-density lipoproteins (VLDL) and low-density lipoproteins (LDL) at their isoelectric points during their preparative isoelectric focusing (IEF), IEF separated VLDL and LDL into two major fractions. The observed optical density peaks are not artifacts caused by binding of Ampholines to VLDL or LDL since no radioactivity accumulated in the fractions containing VLDL or LDL during IEF in the presence of [¹⁴C]Ampholine, and gel filtration completely separated the lipoproteins from [¹⁴C]Ampholine. These results suggest that IEF may separate subspecies of VLDL and LDL under suitable experimental conditions.     

Characterization of the normal alpha 1-antitrypsin allele Vmunich: a variant associated with a unique protein isoelectric focusing pattern.

alpha 1-Antitrypsin (alpha 1AT), the major serum inhibitor of neutrophil elastase, is a highly polymorphic protein associated with isoelectric focusing (IEF) patterns typical for each variant. alpha 1AT Vmunich, a previously unreported normal alpha 1AT variant, has a unique IEF banding pattern in which the 7 and 8 alpha 1AT protein bands focus with the normal M-type 7 and 8 bands, despite the fact that the major fraction of the Vmunich protein focuses in the "V" region of the IEF gel. To characterize the molecular basis of this variant and its unique IEF pattern, DNA sequence analysis of the coding exons of the Vmunich alpha 1AT gene was carried out using the polymerase chain reaction. The Vmunich allele differed from the common normal M1(Val213) alpha 1AT allele by a single nucleotide substitution of cytosine for adenosine, with the resultant amino acid change Asp2 GAT----Ala GCT. Inheritance of the allele was confirmed by family analysis using allele-specific amplification with the polymerase chain reaction. The Asp2----Ala mutation explains the cathodal position of the Vmunich protein on IEF, as there is a substitution of a negatively charged amino acid by a neutral one.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effect of ampholytes on ferritin isoelectric focussing patterns

Ferritin was subjected to isoelectric focussing (IEF) on agarose gels containing different commercial carrier ampholytes. In two gels protein staining revealed banded patterns which differed from one another, while a third gel yielded zones rather than discrete bands, indicating that the bands may be artefacts.The differences between banded patterns were studied by isolating bands from an IEF gel and refocussing these on gels containing either the original ampholyte or a different ampholyte preparation. Striking differences were noted.Chromatofocussing of ferritin resulted in the elution of broad peaks between the same pH limits as indicated by IEF patterns.     

Visualization of proteins after isoelectric focusing during two-dimensional gel electrophoresis.

A modification of P. H. O'Farrell's (1975, J. Biol. Chem.259, 4007–4021) two-dimensional gel electrophoresis is described. After isoelectric focusing, the cylindrical gels were fixed and stained with Coomassie brilliant blue R before sodium dodecyl sulfate-slab gel electrophoresis in the second dimension. The modification does not alter the protein patterns obtained, but provides sharper spots. In addition, bands are made visible before separation in the second dimension. Moreover, the modification helps to reduce the amount of ampholine in the dye front during electrophoresis.     

Analysis of rat serum apolipoproteins by isoelectric focusing. I. Studies on the middle molecular weight subunits.

Analytical isoelectric focusing (IEF) has been applied to the study of the apolipoprotein components of rat serum high density and very low density lipoproteins. The apolipoproteins were separated on 7.5% polyacrylamide gels containing 6.8% urea, with a pH gradient of 4-6. The middle molecular weight range apolipoproteins were identified on IEF gels by the use of apolipoproteins purified by electrophoresis on gels containing sodium dodecyl sulfate (SDS). The A-1 protein focused as 4 to 5 bands from pH 5.46 to 5.82; the A-IV protein and the arginine-rich protein each focused as 4 to 6 bands from pH 5.31 to 5.46. The low molecular weight proteins focused from pH. 4.43 to 4.83 and are the subject of a separate communication. Comparisons of the IEF method with SDS gel electrophoresis, polyacrylamide gel electrophoresis in urea, and Sephadex chromatography are also reported. Additional studies were also carried out that tend to rule out carbamylation or incomplete unfolding of the proteins in the presence of urea as the causes of the observed heterogeneity.     

Genetic polymorphism of the human sex hormone-binding globulin: evidence of an isoelectric focusing variant with normal androgen-binding affinities

Human sex hormone-binding globulin (hSHBG) is a plasma glycoprotein composed of two identical subunits. The protein, which has high affinity for testosterone and estradiol has been purified to homogeneity. In this study we have investigated, on neuraminidase-treated serum samples, the presence of genetic variations of hSHBG by polyacrylamide gel isoelectric focusing (IEF). Based on IEF analyses of 110 serum samples from adult Mexican individuals we have identified two distinct IEF-patterns. The most frequent phenotype (95.45%) was characterized by two IEF-bands with pIs of 6.50 and 6.63, respectively. In five serum samples, a different 4-band pattern with pIs of 6.50, 6.63, 6.70 and 6.76 was identified. Family studies showed that this pattern was genetically determined. The frequency of this variant was 4.55%, and the observed phenotypes were consistent with the expression of an autosomal genetic system. The estimated gene frequencies for both alleles were shown to be in genetic equilibrium. Affinity constants, binding kinetics and serum concentrations of hSHBG from individuals having a 4-band pattern were similar to those obtained in individuals with a 2-band pattern, thus suggesting that the mechanism responsible for the generation of polymorphic variants of hSHBG reported herein did not involve the steroid binding site of the molecule. These findings may be of broad interest, as other serum binding proteins express genetic variants, which may permit their further structural and functional subclassification.     

Parallel isoelectric focusing chip

Fast isoelectric focusing (IEF) is becoming a key method in modern protein analysis. We report here the theory and experimental results of new parallel isoelectric devices (PID) for fast IEF. The main separation tool of any PID is a dielectric membrane with conducting channels filled by immobiline gels of varying pH. The pH value of the surrounding aqueous solution is not equal to the pH of any of the channels. The membrane is held perpendicular to the applied electric field. Proteins are collected (trapped) in the channels whose pH values are equal to the pI of the proteins. The fast particle transport between different channels takes place due to convection in the aqueous solution. We developed a mathematical model for PID. Experiment duration is shown to be proportional to the number of different bands N (the peak capacity in standard IEF) in contrast with N(2) for usual IEF devices. This model was validated with experimental results. Parallel IEF accelerates the fractionation of proteins by their pI values (down to several minutes) allowing a more desirable collection efficiency to be achieved. The main theoretical limitation of PID resolution is the sensitivity of proteins to pH change due to the Coulomb blockade effect. The existence of a minimal pH change deltapH(min) for each type of protein is shown: deltapH(min) approximately r(-1) for globular molecules with radius r.     

High-sensitivity isoelectric focusing of biotinylated peptides: a new method

A novel technique to selectively analyze prelabeled peptides by isoelectric focusing (IEF) is presented. The conditions are described for biotinylation of peptides, their separation in polyacrylamide gels by IEF, and their fixation to the gel matrix with glutaraldehyde. The gels are developed by a color reaction catalyzed by an avidin-coupled enzyme. The technique is suitable for peptides with at least one free amino group or guanidino group after N-terminal biotinylation. The presence of other peptides or proteins does not interfere with the detection. The sensitivity is below 10 pmol, representing a 1000-fold improvement over existing techniques for analyzing low molecular weight peptides by IEF.     

Current trends in capillary isoelectric focusing of proteins

Isoelectric focusing (IEF) in thin capillaries is reviewed here. After an introduction on the genesis and chemistry of the carrier ampholyte buffers, different approaches to IEF are discussed and evaluated. The classical approach consists on IEF under conditions of suppressed electroosmotic (EOF) flow, usually obtained by covalently bonding hydrophilic polymers to the inner capillary wall. The other approach consists of IEF in dynamically (and partially) coated capillaries, so as to allow a reduced EOF flow to coexist with the IEF process, so that focusing and transport of the train of stacked bands occurs simultaneously. The various experimental parameters: focusing, elution and detection steps, pI measurements, as well as typical drawbacks, such as isoelectric precipitation are evaluated. The review ends with some examples of analytical separations, at the moment mostlyl limited to focusing of native hemoglobins (normal and point mutants). These separations are compared with those obtained by slab-gel IEF and in immobilized pH gradients.     

A nondenaturing vertical isoelectric focusing polyacrylamide slab gel system suitable for silver staining and electrophoretic blotting

We have devised a nondenaturing vertical isoelectric focusing (IEF)-polyacrylamide gel electrophoresis (PAGE) system which is amenable to silver staining and electroblotting. Apart from being accessible, inexpensive, and simple to use, this new methodology overcomes problems inherent in current IEF methods, for example, pH gradient drift, nonuniform cooling, restricted sample volume, and inability to perform electroblotting. Two photopolymerization gel formulas were derived: a 5% acrylamide formula using bisacrylamide (Bis) as the crosslinker and a 6% acrylamide formula using diallyltartdiamide (DATD) as the crosslinker. The 5% acrylamide Bis gel gave excellent resolution and separation of proteins whereas the 6% acrylamide DATD gel expanded slightly during silver staining, resulting in mild band distortions. At least 80 ng of protein per band could be detected by the silver staining protocol devised. Both the DATD and the Bis gels were suitable for electroblot transfer. Parameters to ensure the optimum conditions for reproducible, high resolution vertical IEF-PAGE are described. IEF-PAGE silver staining and electroblotting procedures and silver staining of the nitrocellulose electroblot procedures are also described. The advantages of this methodology over previously published methods are discussed.     

Apolipoproteins as the basis for heterogeneity in high-density lipoprotein2 and high-density lipoprotein3. Studies by isoelectric focusing on agarose films

A method is described for the isoelectric focusing (IEF) of lipoproteins on thin films of agarose. Within a pH gradient of 4.60-5.30 both high-density lipoproteins 2 and 3 (HDL2 and HDL3) are resolved into more than 10 fractions which could be stained either for protein or for lipids. The isoelectric focusing patterns for HDL2 and HDL3 are similar although HDL2 appears richer in the more alkaline bands. Narrow film strips from the IEF separation of HDL2 and HDL3 were interfaced with various agarose plates containing antisera against apolipoproteins apoAI, apoAII and apoCIII either alone or in combination, to provide two-dimensional IEF immunoelectrophoresis patterns. This technique demonstrated that apoAI and apoAII were present throughout the IEF gel for both subclasses of HDL. It also provided evidence for the existence of lipoproteins containing both apoAI and apoAII and other lipoproteins present in the alkaline region of the gel which contained apoAI but no apoAII. ApoCIII was found mostly in acidic lipoproteins and was not distributed identically in HDL2 and HDL3. The lipoproteins separated by IEF on agarose were also analysed by two-dimensional IEF-SDS electrophoresis and the individual apolipoproteins were identified by reaction with antibodies to apolipoproteins AI, AII, CI, CII, CIII, D, and E. This technique confirmed that in IEF of HDL, apoAI extended throughout the spectrum of lipoproteins whereas apoE was only present in alkaline lipoproteins and apoD was only present in acidic lipoproteins. IEF on agarose of either HDL2 or HDL3 allowed us to collect eight different fractions, which have the same pI in either lipoprotein class. The apolipoprotein composition of each isolated band was analysed by electroimmuno-assays for apolipoproteins AI, AII, CI, CII, CIII, D, and E and the results expressed as the ratio of the measured apolipoprotein to measured apoAI. In both HDL2 and HDL3, acidic lipoprotein fractions were enriched in apoAII, apoCIII and apoD. ApoCII and apoCII were not similarly distributed in HDL2 and HDL3 subfractions whereas the apoCI distribution was similar in both classes. Noteworthy in all experiments was the difference in the distributions of apoCI, apoCII, and apoCIII in HDL2 and HDL3, which indicated that the existence of a lipoprotein containing simultaneously CI, CII and CIII can only account for a small fraction of these apolipoproteins. Therefore these experiments substantiate the theory of the protein basis of HDL heterogeneity and suggest that the majority of apolipoproteins are present in complexes which upon IEF result in lipoprotein fractions of identical pI for both HDL2 or HDL3.(ABSTRACT TRUNCATED AT 400 WORDS)     

Investigation of proteases with chromogenic substrates after isoelectric focusing (IEF)

Summary A technique is described for the detection of protease isoenzymes which is more sensitive than disc electrophoresis. Supernatants of crude rat and human organ homogenates are subjected to analytical isoelectric focusing (IEF) and the gel strips are finally incubated in histochemical media containing 4-methoxy-2-naphthylamine amino acids or peptides and diazonium salts for simultaneous or post-coupling. The incubation media are identical with those used for section histochemistry of proteases. This combination of IEF and proteases histochemistry yields excellent and reproducible data which cannot be obtained by protease histochemistry alone. Post-coupling delivers less and more diffuse bands than simultaneous coupling. For simultaneous coupling, Fast Blue B and Fast Black K are the most suitable diazonium salts. More bands are found in agarose gels compared with polyacrylamide. Sex-differences exist for endopeptidases in the submandibular gland, but are absent in other rat organs. Despite their uniform membrane localization in tissue sections, aminopeptidase (AP) A and M and dipeptidylpeptidase (DPP) IV and -glutamyltranspeptidase (GGT) show striking heterogenous band patterns depending on the investigated organ. The similar band patterns of APA and APM can be specified by the use of activators or inhibitors. In rat kidney, up to 26 bands are obtained with DPP II and IV substrates, 3 for APA and APM and up to 12 for GGT. DPP IV of human liver is different from that in rat liver.     

Isolation of dipeptidyl peptidase IV (DP 4) isoforms from porcine kidney by preparative isoelectric focusing to improve crystallization

Abstract In the present studies we resolved the post-translational microheterogeneity of purified porcine dipeptidyl peptidase IV (DP 4) from kidney cortex. Applying SDS-homogeneous DP 4 onto an analytical agarose isoelectric focusing (IEF) gel, pH 4-6, activity staining resulted in at least 17 isoforms between pH 4.8-6.0. These could be separated into fractions with only two to six isoforms by means of preparative liquid-phase IEF, using a Rotofor cell. Starting off with three parallel Rotofor runs under the same conditions at pH 5-6, the fractions were pooled according to the specific activity of DP 4, pH and analytical IEF profile, and further refractionated without any additional ampholytes. Since excessive dilution of ampholytes and proteins was kept to the minimum, a second refractionation step could be introduced, resulting in pH gradients between 0.022 and 0.028 pH increments per fraction. By performing two consecutive refractionation steps, the high resolution necessary for the separation of DP 4 isoforms could be achieved. This represents an alternative method if isolation of isoforms with similar pI's results in precipitation and denaturation in presence of a narrow pH range. Furthermore, it demonstrates that preparative IEF is a powerful tool to resolve post-translational microheterogeneity of a purified protein required for crystallization processing.     

The effects of βbT-lactams on the isoelectric focusing of βbT-lactamases

A range of concentrations of ceftazidime (4–64 mg I^-1) was shown to cause no induction of the TEM-1 and TEM-5 β-lactamases produced by Escherichia coli Nb. Increasing the concentration of ceftazidime in cultures of E. coli Nb caused a concomitant increase in the intensity of a satellite band of pI 5.2. The same increase in this satellite band was observed when ceftazidime was added to cell-free β-lactamase peparations from E. coli Nb and the separate addition of 11 different β-lactams to TEM-1 showed that each compound produced its own unique pattern of satellite bands. In addition, the mixing of ceftazidime with TEM-1 and 13 other TEM-derived β-lactamases caused a similar satellite band to be observed but ceftazidime did not have the same effect on PSE or SHV β-lactamases. Consequently, the addition of ceftazidime to a β-lactamase preparation prior to isoelectric focusing (IEF) may help to verify if a particular β-lactamase is TEM-derived. Purification of the satellite bands by electrodialysis and their subsequent re-focusing demonstrated that the ceftazidime-induced satellite bands can revert to a protein which has a pI similar to the parent band, illustrating the possible reversibility and dynamic nature of β-lactamase satellite bands on IEF. These results enable a better interpretation to be made of β-lactamase satellite bands observed on IEF.     

Characterization of cellulases in an extracellular fraction from Trichoderma reesei under conditions of isoelectric focusing (IEF)

Abstract A cellulase-containing fraction present in the culture fluid of Trichoderma reesei grown on cellulose was obtained by fractionated centrifugation. The buoyant density of this fraction was D = 1.060 g/ml. Its ultrastructural properties, as detected by transmission electron microscopy, are given. The fraction consists of membrane vesicles attached to a carbohydrate polymer. This polymer is positive to Ruthenium red staining.
The effect of urea on the extraction and separation of acidic cellulases from this fraction is described. Linear gradient gels for both urea (up to 8.0 M urea) and polyacrylamide gels (up to 30%) were used to determine adequate separation conditions for isoelectric focusing (IEF) in a polyacrylamide gel matrix. The effect of urea on the extraction and separation conditions was tested by titration curves. In the presence of 6.0−8.0 M urea, the main cellulase-containing hydrolase complex (pI_app4.2) from this fraction is split into 3 isoenzymes and a further cellulase (pI 5.65).     

Quantitative assay of deoxyribonuclease activity after isoelectric focusing in polyacrylamide gels: pH control and effects of enzyme diffusion

A method for the quantitative assay of nuclease activity in crude cell lysates after isoelectric focusing (IEF) in polyacrylamide slab gels is described. After IEF, an agarose overlay gel containing DNA is placed on the IEF gel and the nuclease activity quantified by the loss of ethidium bromide fluorescence of the DNA. With this method a linear response was obtained for 1 to 10 ng of DNase I. Various methods of pH equilibration after IEF were also evaluated. The use of a high buffer concentration in the overlay gel is recommended to control the pH during the enzyme reaction. An analytical solution for the diffusion of enzymes from the IEF gel to the overlay gel is also presented and an equation that may be used to choose optimum times for transfer of the enzyme from the IEF gel to the overlay gel is given.     

A new isoelectric focusing gel for two-dimensional electrophoresis constructed in microporous hollow fiber membranes

We describe the preparation of IEF tube gels inside a nonwetting microporous plastic tubing. The gel in the tube need not be extruded after the first dimension separation. Instead, the porous structure of the tubes is made wettable, and the proteins are electrophoresed "through-the-wall" into the second dimension PAGE gel. Commercial ampholytes and reagents are suitable for the procedure. A useful p/ range of 4.5-9.5 can be obtained when p/ 3-10 ampholyte mixtures are used. Because of the high surface area of the porous material, precautions must be exercised to reduce oxygen inhibition during polymerization and dehydration of the gel during storage and use. A sheath device is described that satisfies these requirements. The plastic tubes can be disposed of by incineration and pose no biohazard.