Colored pI standards and gel isoelectric focusing in strongly acidic pH

Colored, low molecular weight pI markers have been developed for isoelectric focusing (IEF) in acidic pH range. Their isoelectric points (pIs) were determined by direct measurement of the pH of the focused bands after completion of IEF on polyacrylamide gels. The practicable suitability of the proposed pI markers as pI standards for IEF was tested by applying gel IEF. The acidic pH gradient was created either by commercial synthetic carrier ampholytes or by mixture of simple buffers consisting of acids (non-ampholytes) and ampholytic buffers. By applying simple acids, it was possible to extend the acidic pH range beyond those achievable with commercial synthetic carrier ampholytes. By using an experimental arrangement without electrode electrolyte reservoirs with electrodes creating the fixed end of the gel, the strongly acidic pH gradient was stable even for prolonged focusing time.     

Fractionation of carrier ampholytes for isoelectric focusing.

A simple method for fractionating synthetic carrier ampholytes is reported, based on the principle of continuous-flow isoelectric focusing in gel-stabilized layers. An 8% ampholyte solution, encompassing the pH range 3-9.5, is separated into 12 fractions in a chamber filled with Sephadex G-100 by a continuous-flow technique. We are thus able to obtain ampholytes of narrow pH range, encompassing approximately 2 pH units, whose resolving power is comparable with that obtained with commercial Ampholine covering similar pH ranges.     

Extension of separation range in capillary isoelectric focusing for resolving highly basic biomolecules

The non-availability of commercial carrier ampholytes in the pH range greater than 11 has contributed to difficulties in focusing and resolving highly basic proteins/peptides using capillary isoelectric focusing (cIEF). Two different approaches, involving the use of N,N,N',N'-tetramethylethylenediamine (TEMED) and ampholyte 9-11, are investigated for their effects on the extension of separation range in cIEF. The addition of TEMED into pharmalyte 3-10 not only prevents the peptides/proteins from focusing in sections of the capillary beyond the detection point, but also extends the separation range to at least isoelectric point (pI) 12. The combination of ampholyte 9-11 with pharmalyte 3-10 surprisingly provides baseline resolution between bradykinin (pI 12) and cytochrome c (pI 10.3). The sample mixture, containing bradykinin, the high-pI protein calibration kit (pI 5.2-10.3), and cytochrome c digest, is employed to demonstrate the cIEF separation of proteins and peptides over a wide pH range of 3.7-12.     

Isoelectric buffers, part 3: determination of pKa and pI values of diamino sulfate carrier ampholytes by indirect UV-detection capillary electrophoresis

Ampholytes with close pK(a) values (i.e., good carrier ampholytes (CAs)) are needed as buffers in pH-biased isoelectric trapping (IET) separations. The syntheses of two families of such good CAs were reported recently. Members of the family of diamino sulfate ampholytes (first series) had pI values in the 5.7 < pI < 9.0 range. Members of the family of quaternary ammonium dicarboxylic acid ampholytes (second series) had pI values in the pI < 4.3 range. To further characterize the diamino sulfate ampholytes, their effective mobilities were measured by indirect UV-absorbance detection capillary electrophoresis in a series of background electrolytes (BGEs) with different pH values. The pK(a) and limiting ionic mobility values of the CAs were obtained by fitting these mobility values, as a function of the pH and the ionic strength of the BGEs, to the theoretical mobility expression. These diamino sulfates complete the list of CAs suitable for IET separations.     

Preparative free-flow isoelectric focusing: modeling and experiments

Free-flow isoelectric focusing was adapted to preparative scale separations and chemical engineering methods were used to describe the main mechanisms operating in the apparatus. A mixture of human serum albumin (pI 4.6) and beta-lactoglobulin (pI 5.22) was separated in pH gradients, generated with carrier ampholytes of different origin and covering the pH ranges 4-6.5, 3.5-5, 4-5.5 and 4.5-5.0. Best results were obtained in the pH 4-5.5 range. The experimental results have validated the results obtained with a numerical model.     

Itaconic acid carrier ampholytes for isoelectric focusing.

Commercial carrier ampholytes, obtained by coupling polyethylene polyamines to acrylic acid, exhibit a conductivity minimum in the pH range 5.5-6.5 owing to the lack of appropriate pK values of the polyamine in this pH region. By replacing acrylic with itaconic acid, it has been possible to effect substantial improvements in the pH range 5.5-6.5 as itaconic acid has a pK2 value of 5.45. Upon coupling, the pK of the gramma-carboxyl group remains virtually unaltered. With itoconic acid carrier ampholytes it has been possible to improve the conductivity in the pH range 5.5-6.5 by as much as 400% compared with conventional carrier ampholytes. It is suggected that the commercial products should be supplemented with itaconic acid carrier ampholytes in order to obtain a more uniform conductivity and buffering capacity in the pH range 3-10.     

Experimental and theoretical dynamics of isoelectric focusing: IV. Cathodic, anodic and symmetrical drifts of the pH gradient

The production of anodic, cathodic and symmetrical drifts of a pH 3.5-10 gradient formed by isoelectric focusing in polyacrylamide gels is demonstrated experimentally by manipulation of the electrolyte concentrations. Experimental behavior is reproduced by computer simulation of a model mixture of 15 hypothetical carrier ampholytes whose pIs span the pH range 3-10. The mechanism which produces the drifts is elucidated and approaches to minimize such drifts are discussed. The data suggest why most experimentally observed drifts are cathodic.     

Electrotitration curves of human gastric pepsinogens in agarose gels

Electrotitration curves (ETC) of a marker protein mixture, pH 2.5-5.65, and human pepsinogens were performed in an agarose gel, containing 2% acid carrier ampholytes, forming a pH range of 2.5-5. Although the establishment of the pH gradient by isoelectric focusing was not quite complete and linear, both biochemically and immunochemically different types of pepsinogen C (PGC) and pepsinogen A (PGA) zymogens as well as the acid isoelectric points (pI) marker proteins were separated with good resolution. Three main fractions of PGA (Pg3, Pg4, and Pg5) were detected. To obtain an exact determination of the pepsinogen pIs, a simple and very fast 10 s pressure blot technique was applied. Human pepsinogens were separated alone or mixed with pI marker proteins in the pH range 2.4-5.65. No effect of the markers was observed on the pepsinogen migration. To visualize the different protein samples in the gel and on nitrocellulose membrane, we have used colloidal gold (AuroDye) staining, proteolytic activity, and immunostaining with monoclonal antibodies anti PGA and PGC. The described method shows an ability to separate proteins at acidic conditions with a resolution comparable to isoelectric focusing with immobilized pH gradients, but much faster, easier, and cheaper. In addition, the technique allows us to determine precise and exact pI values, and is suitable for studies of the pepsinogen polymorphism and its role in gastric diseases.     

Haptoglobin subtyping by isoelectric focusing in miniaturized polyacrylamide gels rehydrated in presence of 2-mercaptoethanol

A fast isoelectric focusing method for routine haptoglobin (Hp) subtyping is presented. This method is based on isoelectric focusing, under reducting conditions, of neuraminidase-treated plasma samples by using dry miniaturized (interelectrode distance: 55 mm) polyacrylamide gel, rehydrated in presence of 2-mercaptoethanol and a mixture of pharmalyte carrier ampholytes (pH 4-6.5 and pH 6-8) followed by immunoblotting. The presence of 2-mercaptoethanol in the gel prevented refolding of the Hp alpha and Hp beta chains during focusing, making it possible to obtain a sharp Hp band pattern with a clear separation of the different Hp alpha allelic products (1S, 1F, 2FS, 2SS and 2FF). A population study carried out with 250 unrelated individuals living in Central Spain is also presented.     

Sampling strategies for capillary isoelectric focusing with electroosmotic zone mobilization assessed by high-resolution dynamic computer simulation

The impact of initial sample distribution on separation and focusing of analytes in a pH 3–11 gradient formed by 101 biprotic carrier ampholytes under concomitant electroosmotic displacement was studied by dynamic high-resolution computer simulation. Data obtained with application of the analytes mixed with the carrier ampholytes (as is customarily done), as a short zone within the initial carrier ampholyte zone, sandwiched between zones of carrier ampholytes, or introduced before or after the initial carrier ampholyte zone were compared. With sampling as a short zone within or adjacent to the carrier ampholytes, separation and focusing of analytes is shown to proceed as a cationic, anionic, or mixed process and separation of the analytes is predicted to be much faster than the separation of the carrier components. Thus, after the initial separation, analytes continue to separate and eventually reach their focusing locations. This is different to the double-peak approach to equilibrium that takes place when analytes and carrier ampholytes are applied as a homogenous mixture. Simulation data reveal that sample application between two zones of carrier ampholytes results in the formation of a pH gradient disturbance as the concentration of the carrier ampholytes within the fluid element initially occupied by the sample will be lower compared to the other parts of the gradient. As a consequence thereof, the properties of this region are sample matrix dependent, the pH gradient is flatter, and the region is likely to represent a conductance gap (hot spot). Simulation data suggest that sample placed at the anodic side or at the anodic end of the initial carrier ampholyte zone are the favorable configurations for capillary isoelectric focusing with electroosmotic zone mobilization.     

Advanced online mass spectrometry detection of proteins separated by capillary isoelectric focusing after sequential injection

Capillary isoelectric focusing hyphenated with mass spectrometry detection, following the sequential injection of the carrier ampholytes and the sample zone, is highly efficient for the characterization of proteins. The main advantage of the sequential injection protocol is that ampholytes, with pH ranges, which are not supposed to cover the isoelectric points of the sample components, can be used for separation. The method then allows online mass spectrometry detection of separated analytes either in the absence (substances that have left the pH gradient) or in the presence of low‐level ampholytes (substances that are migrating within the pH gradient). The appearance of the substances within, or outside the pH gradient depends on, e.g., the composition of the ampholytes (broad or narrow pH range) or on the composition of electrolyte solutions. The experiments performed in coated capillaries (with polyvinyl alcohol or with polyacrylamide) show that the amount and the injection length of the ampholytes influence the length of the pH gradient formed in the capillary.     

Direct detection of carrier ampholytes in immobilized pH gradients using picric acid precipitation.

A protocol is described for monitoring the heterogeneity of end products of organic syntheses yielding amphoteric molecules containing two or more amino groups. This protocol was found to be a valuable aid in synthesis of carrier ampholytes for specific isoelectric focusing applications. This method does not depend on the ampholytes themselves to dictate the conditions under which they are analyzed. Carrier ampholytes have been found previously to be insoluble in picric acid and the insolubility property was not dependent upon the pI of individual ampholyte species. This insolubility property was exploited in the protocol. Immobilized pH gradients were used to focus the carrier ampholytes. Ampholytes were then visualized in situ by picric acid precipitation. The data shows that the protocol is useful for analyzing the results of chemical manipulations for enhancing the resolution of carrier ampholytes. A direct relationship was shown between carrier ampholyte heterogeneity as demonstrated by this protocol and the resolution of complex protein mixtures in isoelectric focusing gels. Picric acid formed visible precipitates with a variety of organic compounds which contained more than one amino group.     

Human alpha-1-antitrypsin subtyping by hybrid isoelectric focusing in miniaturized polyacrylamide gel

The polymorphism of alpha-1-antitrypsin (PI) has been studied by hybrid isoelectric focusing in miniaturized immobilized pH gradient gels, with an interelectrode distance of 55 mm, in two narrow ranges of pH 4.35-4.75 and 4.35-4.55), following rehydration with pH 4.2-4.9 carrier ampholytes. The use of the separator N-(2-acetamido)-2-aminoethanesulfonic acid (ACES) in combination with carrier ampholytes for gel rehydration has been shown to enhance PI band sharpness. The influence of different additives (sucrose, sorbitol and glycerol) on the PI band pattern has also been evaluated. Glycerol has been shown to be responsible for the change in the relative mobility of the M3 band. The analysis of the minor M-7 isoprotein zone by hybrid isoelectric focusing followed by silver staining has permitted a more reliable classification of PIM subtypes. A population study carried out with 164 unrelated individuals living in Spain is also presented.     

On-line coupling of capillary isoelectric focusing with transient isotachophoresis-zone electrophoresis: a two-dimensional separation system for proteomics

A microdialysis junction is employed as the interface for on-line coupling of capillary isoelectric focusing with transient isotachophoresis-zone electrophoresis in a two-dimensional separation system. Capillary isoelectric focusing not only provides high-resolution separation of tryptic peptides based on their differences in isoelectric point, but also potentially allows the analysis of low-abundance proteins with a typical concentration factor of 50-100 times. Carrier ampholytes, employed for the creation of a pH gradient during focusing, are further utilized as the leading electrolyte in the second separation dimension, transient isotachophoresis-zone electrophoresis. Many peptides which have the same isoelectric point would most likely have different charge-to-mass ratios, and thus different electrophoretic mobilities in zone electrophoresis. Two-dimensional separation of proteolytic peptides is demonstrated using standard proteins, including cytochrome c, ribonuclease A, and carbonic anhydrase II. The maximum peak capacity is estimated to be around approximately 1600 and can be significantly increased by simply increasing the capillary column length and manipulating the range of pH gradient in isoelectric focusing. In addition to enhanced separation efficiency and resolution, this two-dimensional electrokinetic separation system permits sensitive and comprehensive analysis of peptide fragments, especially when integrated with electrospray ionization mass spectrometry for peptide/protein identification.     

Fast and high resolution analysis of human serum transferrin by high performance isoelectric focusing in capillaries

Human serum transferrin is a mixture of isoforms (isoproteins) having different amounts of carbohydrates. Each isoform may exist in iron-free and iron-complexed molecular form. The genetic variations in different populations increase the number of combinations of the different forms of transferrin. To resolve the many components in transferrin preparations, the new high performance capillary technique was employed for isoelectric focusing. Iron-free transferrin and transferrin samples of known iron content were examined. The above method gives an exceptionally rapid analysis (within 15-25 min) of small amounts of samples (less than 1 microgram protein) and as good as or better resolution than other isoelectric focusing techniques previously used for transferrin analysis. By monitoring the focused protein zones at both 280 and 460 nm the molecular forms of transferrin (iron-free, monoferric and differic complexes) can easily be identified. Both steps of isoelectric focusing in capillaries (i.e., prefocusing and mobilization) can be used for analysis. We observed that chelating agents (e.g., carrier ampholytes, nitrilotriacetate) may release iron from microsyringes having metal pistons causing the formation of iron-transferrin complexes.     

Capillary isoelectric focusing-mass spectrometry for shotgun approach in proteomics

We report on capillary isoelectric focusing-mass spectrometry (CIEF-MS) of complex peptide mixtures in the absence of carrier ampholytes. Furthermore, the use of low concentrations of carrier ampholytes as mere spacers is investigated. Carrier ampholytes are complex mixtures of amphoteric compounds with high buffering capacity. Since all peptides are amphoteric compounds by themselves, the use of carrier ampholytes may be superfluous to establish a stable pH gradient in CIEF analysis of protein digests. Our research showed that when carrier ampholytes are omitted, the analyte ions are not focused at their isoelectric point. The analytes are charged, leading to electrophoretic mobility uncharacteristic for CIEF. The method was tested for a five-protein-mixture at 0.02 mg/mL per protein and 0.05 mg/mL per protein. At the lower concentration, the analytes were stacked during the focusing process in only a limited length of the capillary. Therefore, the higher concentration led to better separation efficiency. It was found that at low concentration (0.20%) the carrier ampholytes could work as spacers. Though it led to sensitivity losses of 15-45%, this was compensated by the higher separation efficiencies seen. The method was evaluated with an eight-protein-mixture, of which all could be identified after performing MS/MS.     

Dynamics of gel isoelectric focusing with ampholytic dyes monitored by camera in real-time

The dynamics of gel isoelectric focusing were studied by using amphoteric low-molecular-mass colored substances (isoelectric point markers). The polyacrylamide gel in slab format was in direct contact with the electrodes. In addition to isoelectric focusing with a pH gradient composed of synthetic carrier ampholytes, pH gradients created by simple buffers of acetic acid, 2-(N-morpholino)ethanesulfonic acid, histidine and N,N,N',N'-tetramethylethylenediamine were applied. The progress of the electrofocusing process was monitored by a charge-coupled device camera and video recording. The gradient profile and dynamics were approximated from the positions of isoelectric point markers, which were focused both on boundaries between individual zones of simple buffers and within the zones themselves. The obtained animated records enabled the observation of the entire real focusing run within fractions of a minute, which is useful both for the understanding and optimization of the focusing.     

Synthesis and characterization of quaternary ammonium dicarboxylic acid isoelectric buffers and their use in pH-biased isoelectric trapping separations

Two approaches are described in this paper for the synthesis of isoelectric buffers that have pI values in the 1.5 < pI < 4.3 range. The first synthesis relies on the alkylation of existing aminodicarboxylic acids and recovery of the ampholyte as an inner salt. The second synthesis method forms low-pI ampholytes by reacting a secondary amine with two equivalents of an alkylester of a haloalkanecarboxylic acid, followed by hydrolysis of the intermediate in an alkaline solution and recovery of the ampholyte as an inner salt. The new ampholytes have been analytically characterized by capillary electrophoresis, high-resolution electrospray ionization-mass spectrometry, one- and two-dimensional nuclear magnetic resonance (NMR) spectroscopy, and X-ray crystallography. The isoionic solutions of the new ampholytes have high buffering capacity and conductivity, making them good pH biasers in the receiving stream in preparative-scale pH-biased isoelectric trapping separations.     

Carrier ampholyte‐free isoelectric focusing on a paper‐based analytical device for the fractionation of proteins

Isoelectric focusing plays a critical role in the analysis of complex protein samples. Conventionally, isoelectric focusing is implemented with carrier ampholytes in capillary or immobilized pH gradient gel. In this study, we successfully exhibited a carrier ampholyte‐free isoelectric focusing on paper‐based analytical device. Proof of the concept was visually demonstrated with color model proteins. Experimental results showed that not only a pH gradient was well established along the open paper fluidic channel as confirmed by pH indicator strip, the pH gradient range could also be tuned by the catholyte or anolyte. Furthermore, the isoelectric focusing fractions from the paper channel can be directly cut and recovered into solutions for post analysis with sodium dodecyl sulfate‐polyacrylamide gel electrophoresis and matrix‐assisted laser desorption/ionization‐time‐of‐flight mass spectrometry. This paper‐based isoelectric focusing method is fast, cheap, simple and easy to operate, and could potentially be used as a cost‐effective protein sample clean‐up method for target protein analysis with mass spectrometry.     

Electrophoretic phenotyping of erythrocyte enzymes.

Erythrocyte acid phosphatase (EAP), esterase D (ESD) and phosphoglucomutase (PGM) phenotypes among the erythrocyte enzyme types of blood groups are surveyed and a modified cellulose acetate membrane isoelectric focusing (CAM-IEF) method for their exploration is described. The phenotyping procedures are usually classified as either equilibrium or non-equilibrium IEF. Equilibrium IEF, which is based on differences in pI values, includes three methods: (i) a narrow pH range of carrier ampholytes, (ii) a relatively narrow pH range of carrier ampholytes containing chemical separators and (iii) immobilized pH gradient gels. Among the three methods, immobilized pH gradients provides a better resolution of isozymes. Conversely, the disadvantages of immobilized pH gradients include longer focusing times and complex gel preparations. Moreover, immobilized pH gradients are unsuitable for stain analysis because of the insensitivity of PGM1 detection. A hybrid IEF system and a commercial immobilized pH gradient dry plate have overcome these problems. However, EAP typing is extremely expensive and ESD typing is not well distinguished by hybrid IEF. As each method has both merits and demerits, the most suitable technique should be selected based on the kind of erythrocyte enzyme types and sample conditions. On the other hand, non-equilibrium IEF is a rapid method because isozymes are detected on the basis of their charge differences under non-equilibrium conditions. Moreover, the appropriate addition separators increases the charge difference and provides a good resolution within a shorter time. Addition of more separators produces a narrow pH range in the gel and takes a substantially longer time to reach the optimum pH range for charge difference.(ABSTRACT TRUNCATED AT 250 WORDS)