How to Bring the “Unseen” Proteome to the Limelight via Electrophoretic Pre-Fractionation Techniques

The present review reports a panoply of electrophoretic methods as pre-fractionation tools in proteomic investigations in preparation for mass spectrometry or two-dimensional electrophoresis map analysis. Such electrophoretic pre-fractionation protocols include all those electrokinetic methodologies which are performed in free solution, most of them relying on isoelectric focusing steps (although some approaches based on gels and granulated media are also discussed). Devices associated with electrophoretic separations are multi-chamber apparatuses, such as the multi-compartment electrolyzers equipped with either isoelectric membranes or with isoelectric beads, Off-Gel electrophoresis in a multi-cup device and the Rotofor, an instrument also based on a multi-chamber system but exploiting the conventional technique of carrier-ampholyte-focusing. Other free-flow systems, as well as miniaturized chambers, are also described.     

The effect of extracellular conductivity on electroporation-mediated molecular delivery

In this work, the effect of extra-cellular conductivity on electroporation-mediated molecular delivery efficiency is investigated. A numerical model combining the Smoluchowski equation for membrane permeabilization and the Nernst–Planck equations for ion transport is used to simulate the evolution of ion concentration spatially and temporally. The results are compared with and used to interpret trends observed from previous experimental measurements. Agreements are found which suggest the critical importance of electrophoretic transport. This mechanism controls delivery efficiency on the quantitative level. Meanwhile, a simple formula is developed to predict the molecular content delivered via electrophoresis. The formula can be used as a compact model which provides good approximation to the full numerical model while avoiding the computational cost.     

A method for horizontal polyacrylamide slab gel electrophoresis

We present a simplified method of preparation of polyacrylamide gels which is totally analogous to the procedure now widely used to pour and run horizontal agarose gels. The acrylamide is poured into an open air gel mold consisting of a glass plate with a masking tape border and a comb. It is subsequently run in a submarine horizontal electrophoresis apparatus. The electrophoretic mobility and resolution of DNA fragments obtained in such gels are identical to results obtained with gels poured and run in the vertical configuration. Numerous advantages of horizontal polyacrylamide gel electrophoresis are discussed.     

Electrophoretic investigations of the acid conformational change of alpha-lactalbumin.

In order to clarify how the electrophoretic behavior reflects the conformational transition of globular proteins, moving boundary electrophoresis was applied to analysis of the acid conformational change of alpha-lactalbumin. The appearance of only a single electrophoretic boundary in the transition region of the protein suggests a very rapid transition with a half-time estimated to be smaller than 7 min on the basis of the theory of isomerizing systems in electrophoresis. The transition is clearly reflected in the dependence of the mobility on the protein net charge, which shows a sigmoidal curve closely similar to that obtained by a Linderstr?m-Lang pH-tritration plot for the carboxyl groups of alpha-lactalbumin. It was also concluded from the transition curves that the acidfication does not result in complete unfolding, but that a compact structure is maintained in the acidic region with an apparently expanded form as compared to the native state of the protein. All results obtained by electrophoresis were also supported by the results of pH-jump studies, analytical gel chromatography, and CD measurements.     

Fractionation of macromolecules in an alternating transverse electric field: simulation of the method

An electric field of alternating polarity applied in a direction transverse to the direction of solute transport is used as the basis of a method for the separation of biological macromolecules. The method derives directly from the ability of an electric field to induce movement of a charged macromolecule and from the physics of laminar fluid flow; no adsorptive immobile phase component is involved.

The method is simulated by computer for the case of solute molecules in a solvent flowing through a narrow chamber of recta generates an electric field orthogonal to the direction of solvent flow. Solute molecules repetitively traverse the solvent channel at rates determined by their electrophoretic mobility. During the transit across the channel, solute molecules are transported in the direction of solvent flow; at the channel wall, solvent velocity is negligible and solute transport is limited to that provided by transient diffusion into a mobile solvent zone. Molecules of different intrinsic electrophoretic mobility are separated.

The computer model was used to illustrate the process and to demonstrate the ‘tunability’ of the method as a function of the oscillation frequency and voltage wave form. Because of this tunability, a single instrument can function as the equivalent of several different chromatographic systems. Because fractionation is effected by direct physicochemical phenomena rather than via interaction with chromatographic sites, variations in fractionation results arising from formation of polymers for gel electrophoresis, packing of chromatography columns, or deterioration of columns with use are avoided. This method may be of particular use for the purification of nucleic acid fragments and for the analysis of protei: nucleic acid interactions.     

High-speed microchip electrophoresis method for the separation of (R,S)-naproxen

In this research, a capillary electrophoretic method for the fast enantiomeric resolution of (R,S)-naproxen was investigated. Method development involved variation of applied potential, buffer concentration, buffer pH, and cyclodextrin concentration. The optimum electrophoretic separation conditions were 110 mM sodium acetate run buffer (pH 6.0), 30 mM methyl-beta-cyclodextrin, 20% (v/v) acetonitrile, 25 degrees C. The total length of capillary was 48 cm, (50 microm I.D.) with ultra violet (UV) detection at 232 nm. Using these conditions, the number of theoretical plates was close to one million (896,000/m). The possibility of achieving a fast chiral separation of (R,S)-naproxen on a microchip of 2.5 cm in length was investigated. Complete enantiomeric resolution of naproxen was achieved in less than 1 min, on this microchip platform, with linear imaging UV detection. This system had the advantage of real-time separation monitoring, so that enantiomeric resolution could be visually observed, and high-speed chiral analysis was realized. The microchip electrophoresis (MCE) separation was compared with the capillary electrophoresis (CE) separation with regards to speed, efficiency, separation platform, and precision. This work highlights the potential of CE and MCE in future chiral separations.     

Recent advances in chromatographic and electrophoretic methods for the study of drug-protein interactions

Drug-protein binding is an important process in determining the activity and fate of a pharmaceutical agent once it has entered the body. This review examines various chromatographic and electrophoretic methods that have been developed to study such interactions. An overview of each technique is presented along with a discussion of its strengths, weaknesses and potential applications. Formats that are discussed include the use of both soluble and immobilized drugs or proteins, and approaches based on zonal elution, frontal analysis or vacancy peak measurements. Furthermore, examples are provided that illustrate the use of these methods in determining the overall extent of drug-protein binding, in examining the displacement of a drug by other agents and in measuring the equilibrium or rate constants for drug-protein interactions. Examples are also given demonstrating how the same methods, particularly when used in high-performance liquid chromatography or capillary electrophoresis systems, can be employed as rapid screening tools for investigating the binding of different forms of a chiral drug to a protein or the binding of different proteins and peptides to a given pharmaceutical agent.     

Phenomenological theory of gel electrophoresis of protein-nucleic acid complexes

A phenomenological theory of gel electrophoresis is elaborated for protein-DNA complexes involving one, two, or three binding sites on the DNA molecule. The computed electrophoretic patterns simulate experimental patterns shown by both prokaryotic and eukaryotic systems. The mechanism whereby the electrophoretic protein-DNA ladder is generated upon titration of the operator with repressor is embodied in theory of mass transport coupled to reversible interactions under chemical kinetic control. In contrast to strong interactions (association constant greater than 10(12) M-1), patterns observed with weak complexes (K less than 10(10) M-1) could be simulated only by applying the cage effect, a model of which is formulated. Theoretical underpinning is provided for the electrophoretic estimation of equilibrium association constants, and requisite chemical kinetic conditions are elucidated for direct estimation of the rate constant for dissociation of the protein-DNA complex from gel patterns. The theory thus affords an experimenter with a means for determining the conditions required to render the gel retardation method a valid procedure for evaluating equilibrium constants and/or kinetic parameters for the particular protein-nucleic acid system under investigation. These several considerations apply not only to interactions of proteins with nucleic acids (DNA or RNA) but also to a wide range of macromolecular interactions involving peptides, drugs, and other ligands as well as large assemblies such as multienzyme complexes.     

Adsorption protein layers above erythrocytes and an electrophoretic method for studying their properties under pathogenesis of infection and malignant tumors.

The use of thickness of protein layers adjacent to the surface of each erythrocyte is discussed as a diagnostic test. The given method of studying such layers is based on electrophoretic measurements which make it possible to evaluate the structure, composition and thickness of these layers. It has been shown that the normalization of erythrocyte electrophoretic mobility of stored or pathologic blood flowing through an active-carbon column may be explained by a full or partial removal of adsorption protein layers and intermicellar liquid contained it.     

Capillary electrophoresis:: theory,teaching approach and separation of oligosaccharides using indirect UV detection

Capillary electrophoresis, a recent analytical method (the first commercial instrument was sold just 10 years ago), offers an efficient alternative means compared to other current separation techniques. Due to a wide application range, this method is becoming more and more important among analytical laboratories. Thus, introductory lectures on this analytical technique are of particular interest. Moreover, the use of capillary electrophoresis aids in the understanding of the numerous parameters which influence electrophoretic migrations, such as ion mobilities, electrical field, pH, pK_a, joule heating and buffering capacity. This article presents the theory of capillary electrophoresis and various steps of an analysis of four carbohydrates using this technique. This presentation of the data is similar to the way the students, to whom this analysis was asked, presented theirs. Representative results obtained by four students out of 100 are shown.     

An electrophoretic profiling method for thiol-rich phytochelatins and metallothioneins

Thiol-rich peptides such as phytochelatins (PCs) and metallothioneins (MTs) are important cellular chelating agents which function in metal detoxification and/or homeostasis. The variations in molecular sizes and lack of chromophores of these peptides make their analysis difficult. This paper reports an electrophoresis-based method for a broad screen of thiol-rich peptides and proteins. The method uses the thiol-selective fluorescent tag, monobromobimane, coupled with Tricine--sodium dodecyl sulphate--urea polyacrylamide gel electrophoresis for a sensitive determination of both PCs and MTs. Results for PCs were confirmed by two-dimensional NMR and HPLC-tandem MS analyses. Sample throughput is substantially improved over chromatography-based methods through parallel sample analysis in 1 h of electrophoretic separation. The method is versatile in that peptides ranging from glutathione to large proteins can be analysed by simple modification(s) of the extraction and electrophoretic conditions, and the nature of the method supports serendipitous detection of unexpected or novel thiol metabolites.     

An evaluation of electrophoresis as a taxonomic method using comparative data from the macropodidae (Marsupialia)

Comparative electrophoretic data collected for seven proteins from thirty-four species of marsupial have been examined to define the advantages and shortcomings of electrophoresis as a taxonomic method. The problems of relative rates of change, convergence and parallelism are examined and the range of taxonomic ranks which can usefully be studied with this technique is determined. The relative merits of this type of data, when combined with various methods of taxonomic analysis, are discussed.     

Theory of electrophoresis of reacting systems as applied to the sulfhydryl oxidation of creatine kinase

In an attempt to explain the unusual electrophoretic behavior of fish muscle creatine kinase, a phenomenological theory of transport of reacting systems has been formulated for the electrophoresis of a sulfhydryl protein undergoing oxidation in the presence of a gradient of molecular oxygen. The model assumes slow O2-oxidation of sulfhydryl groups followed by rather rapidly reversible sulfhydryl-disulfide interchange with concomitant change in the electrophoretic mobility of the protein. The computed electrophoretic patterns for this model exhibit a sharp, unimodal ascending boundary but a bimodal descending boundary in which the proportions of the two peaks are time dependent. There is a striking similarity between the theoretical patterns and their experimental counterparts (M.D. Doherty, D.A. Bergman, V.M. Re-Miller, and D.J. Winzor, 1980, Arch. Biochem. Biophys. 202, 558-564); and hence support for consideration of the electrophoresis of fish muscle creatine kinase in these terms.     

Resolving Power: A Quantitative Measure of Electrophoretic Resolution

Resolving power is a quantitative measure of the ability of an electrophoretic system to separate DNA (and other) molecules of similar size. It is a dimensionless quantity, and hence facilitates comparison of the performance of electrophoretic systems that operate very differently. Resolving power can be determined as a function of molecular length from experimental data consisting of a series of completely resolved bands on a gel or blot; closely spaced bands are not required. We discuss factors such as the mass of DNA in a particular band and the spatial resolution of the system used to image the distribution of DNA on a gel or blot that, while not an intrinsic part of the electrophoretic system, may influence the observed resolving power. We derive an empirical global dispersion function that applies both to images of gels obtained after a fixed time of electrophoresis of all the samples and to images obtained as each species reaches a detector located at a fixed distance from the starting well. We use this dispersion function to show that the improvement in resolving power produced by extending the time or distance of electrophoresis in a static, uniform electric field asymptotically approaches a limiting value that is a function of the length of the DNA. When plotted as a function of molecular length, this limiting value defines an envelope that characterizes the intrinsic limits of performance of a particular electrophoretic system (e.g., electric field strength, gel type and concentration, buffer, temperature). Comparing the resolving power of static field agarose gel electrophoresis as routinely practiced for separating DNA molecules from 10³ to 10⁵ bp long with other electrophoretic schemes suggests that significant improvements should be achievable.     

Mass spectrometric identification and microcharacterization of proteins from electrophoretic gels: Strategies and applications

The entire genomic DNA sequences of a number of prokaryotic and eukaryotic species are now available and many more, including the human genome, will be completed in the near future. The state-of-life of a cell at any given time, however, is defined by its protein composition, i.e., its proteome. Gel electrophoresis, mass spectrometry, and bioinformatics will be important tools for protein and proteome analysis in the post-genome era. Protein identification from electrophoretic gels by mass spectrometric peptide mapping or peptide sequencing combined with sequence database searching is established and has been applied to numerous biological systems. We describe current strategies and selected applications in molecular and cell biology. The next challenges are detailed structure/function analyses, which include studying the molecular composition of multiprotein complexes and characterization of secondary modifications of proteins. The advantages and limitations of a number of mass spectrometry-based strategies designed for microcharacterization of low amounts of protein from electrophoretic gels are discussed and illustrated by examples. Proteins Suppl. 2:74–89, 1998. © 1998 Wiley-Liss, Inc.     

Visualizing ion relaxation in the transport of short DNA fragments

Ion relaxation plays an important role in a wide range of phenomena involving the transport of charged biomolecules. Ion relaxation is responsible for reducing sedimentation and diffusion constants, reducing electrophoretic mobilities, increasing intrinsic viscosities, and, for biomolecules that lack a permanent electric dipole moment, provides a mechanism for orienting them in an external electric field. Recently, a numerical boundary element method was developed to solve the coupled Navier-Stokes, Poisson, and ion transport equations for a polyion modeled as a rigid body of arbitrary size, shape, and charge distribution. This method has subsequently been used to compute the electrophoretic mobilities and intrinsic viscosities of a number of model proteins and DNA fragments. The primary purpose of the present work is to examine the effect of ion relaxation on the ion density and fluid velocity fields around short DNA fragments (20 and 40 bp). Contour density as well as vector field diagrams of the various scalar and vector fields are presented and discussed at monovalent salt concentrations of 0.03 and 0.11 M. In addition, the net charge current fluxes in the vicinity of the DNA fragments at low and high salt concentrations are briefly examined and discussed.     

Analysis of branched nucleic acid structure using comparative gel electrophoresis

Electrophoresis in polyacrylamide gels provides a simple yet powerful means of analyzing the relative disposition of helical arms in branched nucleic acids. The electrophoretic mobility of DNA or RNA with a central discontinuity is determined by the angle subtended between the arms radiating from the branchpoint. In a multi-helical branchpoint, comparative gel electrophoresis can provide a relative measure of all the inter-helical angles and thus the shape and symmetry of the molecule. Using the long-short arm approach, the electrophoretic mobility of all the species with two helical arms that are longer than all others is compared. This can be done as a function of conditions, allowing the analysis of ion-dependent folding of branched DNA and RNA species. Notable successes for the technique include the four-way (Holliday) junction in DNA and helical junctions in functionally significant RNA species such as ribozymes. Many of these structures have subsequently been proved correct by crystallography or other methods, up to 10 years later in the case of the Holliday junction. Just as important, the technique has not failed to date. Comparative gel electrophoresis can provide a window on both fast and slow conformational equilibria such as conformer exchange in four-way DNA junctions. But perhaps the biggest test of the approach has been to deduce the structures of complexes of four-way DNA junctions with proteins. Two recent crystallographic structures show that the global structures were correctly deduced by electrophoresis, proving the worth of the method even in these rather complex systems. Comparative gel electrophoresis is a robust method for the analysis of branched nucleic acids and their complexes.     

Efficient transfer of proteins from acetic acid-urea and isoelectric-focusing gels to nitrocellulose membrane filters with retention of protein antigenicity

A method which facilitates the rapid and quantitative electrophoretic transfer of proteins from gels not containing sodium dodecyl sulfate (SDS) to nitrocellulose membranes is described. The equilibration of non-SDS-polyacrylamide gel electrophoretic gels in a buffer containing SDS confers a net negative charge to the proteins present, presumably as a result of the formation of SDS-protein complexes. Proteins from gels equilibrated in the SDS buffer and then electroblotted in a Tris-glycine buffer at pH 8.3 are transferred with much greater efficiency than are proteins from untreated gels. The method has been shown to significantly enhance the electrophoretic transfer of polyoma viral proteins resolved in either acetic acid-urea or isoelectric-focusing gels to nitrocellulose membranes, and it is suggested that the method should have universal applicability to all gel electrophoresis systems currently employed. The proteins from isoelectric-focusing gels treated with SDS and transferred to nitrocellulose membranes were found to retain antigenicity to antisera prepared against either denatured or native viral proteins.     

Electrophoretic heterogeneity of ribosomal protein AT-L30 among actinomycete genera.

The ribosomal proteins from 17 type strains of species belonging to various actinomycete genera were compared by two-dimensional polyacrylamide gel electrophoresis. I detected a striking variability among certain ribosomal proteins (designated AT-L30 proteins) with respect to electrophoretic mobility in the first dimension. In contrast, such variability was not observed among ribosomal L30 proteins from other bacteria, such as Escherichia coli, Bacillus subtilis, Pseudomonas aeruginosa, and Staphylococcus aureus. Although actinomycete AT-L30 proteins from different taxa exhibited considerable heterogeneity in electrophoretic mobility, within each genus the proteins had a specific mobility characteristic. On the basis of this observation, the ribosomal AT-L30 proteins from 11 type strains of species belonging to the mycolic acid-containing genera Nocardia, Rhodococcus, Gordona, and Tsukamurella were analyzed. The relative electrophoretic mobilities of AT-L30 protein preparations from these strains, as determined by two-dimensional gel electrophoresis, revealed that the genera Nocardia, Rhodococcus, Gordona, and Tsukamurella can be sharply separated from each other. My results are consistent with the previously discussed view that each of these genera merits separate genus status.