Focusing of pepsin in strongly acidic immobilized pH gradients

A new acrylamido buffer has been synthesized, for use in isoelectric focusing in immobilized pH gradients. This compound (2-acrylamido glycolic acid) has a pK = 3.1 (at 25 degrees C, 20 mM concentration during titration) and is used, by titration with the pK 9.3 Immobiline, to produce a linear pH gradient in the pH 2.5-3.5 interval. Pepsin (from pig stomach) focused in this acidic pH gradient is resolved into four components, two major (with pI values 2.76 and 2.78) and two minor (having pI values 2.89 and 2.90). This is the first time that such strongly acidic proteins could be focused in an immobilized pH gradient. Even in conventional isoelectric focusing in amphoteric buffers it has been impossible to focus reproducibly very-low-pI macromolecules.     

Isoelectric focusing of basic proteases in immobilized pH gradients

By exploiting a new, alkaline immobilized pH gradient spanning the pH 10-11 interval, it has been possible to focus and to detect, by in situ zymogramming with cellulose acetate foils impregnated with fluorogenic substrates, 2 alkaline proteases, namely elastase and trypsin. Elastase gave a sharp array of 3 bands, with the following pIs (at 10 degrees C): 10.60 (major component), 10.53 (intermediate species) and 10.45 (minor isoform). Trypsin was resolved into 2, about equally abundant, species having pIs of 10.70 and 10.53. However, the latter enzyme gave smears in between these 2 forms and also anodic to the lower pI species. As hydrophobic interaction with the Immobiline matrix was excluded, it is suggested that these smears represent product of auto-digestion due to the very alkaline pH during the focusing process.     

Preparative isoelectric focusing in immobilized pH gradients. II. A case report

The preparative aspects of isoelectric focusing (IEF) in immobilized pH gradients (IPG) have been investigated as a function of the following parameters: environmental ionic strength (I), gel geometry and shape of pH gradient. As model proteins, hemoglobin (Hb) A and a minor, glycosylated component (HbA1c), with a delta pI = 0.04 pH units, have been selected. The load capacity increases almost linearly, as a function of progressively higher I values, from 0.5 X up to 2 X molarity of buffering Immobiline (pK 7.0) to abruptly reach a plateau at 3 X concentration of buffering ion. The load capacity also increases almost linearly as a function of gel thickness from 1 to 5 mm, without apparently levelling off. When decreasing the pH interval from 1 pH unit (pH 6.8-7.8) to 1/2 pH unit (pH 7.05-7.55) the amount of protein loaded in the HbA zone could be increased by 40%. In 5 mm thick gels, at 2 X pK 7.0 Immobiline concentration, over a 1/2 pH unit span, up to 350 mg HbA (in a 12.5 X 11 cm gel) could be loaded in a single zone, the load limit of the system being around 45 mg protein/ml gel volume.     

Isoelectric focusing in immobilized pH gradients: Principle,methodology and some applications

A new technique for generating pH gradients in isoelectric focusing is described, based on the principle that the buffering groups are covalently linked to the matrix used as anticonvective medium. For the generation of this type of pH gradient in polyacrylamide gels, a set of buffering monomers, called Immobiline (in analogy with Ampholine), is used. The pH gradient gels are cast in the same way as pore gradient gels, but instead of varying the acrylamide content, the light and heavy solutions are adjusted to different pH values with the aid of the Immobiline buffers. Available Immobiline species make it possible to generate any narrow linear pH gradient between pH 3 and 10. The behaviour of these types of gradients in isoelectric focusing is described.Immobilized pH gradients show a number of advantages compared with carrier ampholyte generated pH gradients. The most important are: (1) the cathodic drift is completely abolished; (2) they give higher resolution and higher loading capacitu; (3) they have uniform conductivity and buffering capacity; (4) they represent a milieu of known and controlled ionic strenght.     

Isoelectric focusing as the crow flies

The evolution of isoelectric focusing is traced back over the years, from a somewhat shaky origin to present-day immobilized pH gradients. Four generations of methodology are classified and discussed: (A) Kolin's approach, consisting of a two-step technique, generation of a pH gradient by diffusion followed by a rapid electrokinetic protein separation; (B) Svensson-Rilbe's approach, consisting of creating a pH gradient in an electric field by utilizing as buffers a multitude of carrier ampholytes, i.e. of amphoteric species possessing good buffering capacity and conductivity at their pI; (C) immobilized pH gradients, by which non-amphoteric buffers and titrants (acrylamido weak acids and bases), titrated around their pK values, are grafted (insolubilized) onto a polyacrylamide gel matrix and (D) mixed-bed carrier ampholyte-Immobiline gel, by which a soluble, carrier ampholyte generated pH gradient coexists in the same matrix with an insoluble, Immobiline generated, pH gradient.     

Isoelectric focusing in immobilized pH gradients: generation and optimization of wide pH intervals with two-chamber mixers

A new technique for generating extended pH gradients (5 pH units) in Immobiline gels is reported. The previously described (J. Biochem. Biophys. Methods 7, 1983, 123-142) five-chamber gradient mixer has been replaced by a two-vessel device. A single mixture of the available Immobilines (pK 3.6, 4.6, 6.2, 7.0, 8.5 and 9.3) is made, with relative concentrations adjusted so as to produce the most uniform buffering power throughout the desired pH interval. This mixture is then divided into two portions, which are titrated to the extremes of the required pH span with an acidic titrant (Immobiline pK approximately 1) and a basic species (Immobiline pK 9.95). Highly reproducible pH gradients (pH 4-9) are thus generated, which appear extremely useful for the first dimensioned of 2-dimensional techniques. Our previously reported computer program has been implemented with an optimization algorithm which, given any cocktail of Immobilines, automatically adjusts the relative initial concentrations until the smoothest possible beta power is found. For the first time it is possible to perform IEF under controlled physico-chemical parameters: pH span and linearity, beta power, ionic strength and molarity of the buffering species.     

Isoelectric protein purification by orthogonally coupled hydraulic and electric transports in a segmented immobilized pH gradient

A new method is described for preparative protein purification, based on isoelectric focusing on immobilized pH gradients. The principle is entirely new, as it is based on keeping the protein of interest isoelectric, in a flow-chamber, and focusing the impurities in the Immobiline gel. For this, a hydraulic flow is coupled orthogonally to an electric flow, sweeping away the non-isoelectric impurities from the recycling chamber. The sample flow-chamber is built in the centre of the apparatus, and is coupled to an upper and lower segment of an immobilized pH gradient. The protein to be purified is kept isoelectric in the flow-chamber and prevented from leaving it by arranging for the extremities of the immobilized pH gradient, forming the ceiling and the floor of this chamber, to have isoelectric points just higher (e.g. +0.05 pH units, on the cathodic side) and just lower (e.g. -0.05 pH units, on the anodic side) than the known pI of the species of interest. Macromolecules and small ions leave the flow chamber at a rate corresponding to a first order reaction kinetics (the plot of log C vs. time being linear). In general, for macromolecules, 12 h of recycling under current allow removal of 95% impurities. After 24 h of recycling, the protein of interest is more than 99.5% pure. The recoveries are very high (approaching 100%) as the sample under purification never enters the Immobiline gel and thus does not have to be extracted from a hydrophilic matrix, as typical of preparative gel electrophoresis.     

Stable storage conditions of Immobiline chemicals for isoelectric focusing

Most of the problems connected with the use of the Immobiline chemicals (a set of six, non-amphoteric, acrylamido buffers having pK values in the pH 3.5-9.5 interval) can be attributed to the alkaline species (with pK values 6.2, 7.0, 8.5 and 9.3). These compounds, to varying degrees are subjected to two degradation pathways: (a) hydrolysis of the amido bond, producing free acrylic acid and a diamine, the latter unable to be incorporated into the polyacrylamide matrix; (b) spontaneous auto-polymerization, producing a number of oligomers up to n-mers, able to aggregate and precipitate large proteins. Storage of their water solutions as frozen aliquots, a method widely employed, only partially alleviates the problem. Addition of trace-amounts of inhibitors, as lately adopted by the manufacturer, could only reduce the problem of auto-polymerization, but not block the hydrolysis of the amido bond. A new solution has been found, which abolishes both phenomena: storage in n-propanol. As demonstrated by gas chromatography, HPLC analyses and two-dimensional separations of complex samples, storage in organic solvent completely abolishes both hydrolysis and auto-polymerization and allows production of highly reproducible focusing patterns.     

Synthesis of an hydrophilic, pK 8.05 buffer for isoelectric focusing in immobilized pH gradients

The synthesis of a new, pK 8.05 acrylamido weak base for isoelectric focusing in immobilized pH gradients (IPG) is here reported. This compound N,N-bis(2-hydroxyethyl)-N'-acryloyl-1,3-diaminopropane is strongly hydrophilic, and thus inhibits any potential hydrophobic interaction among proteins and the grafted basic groups in an IPG matrix. In addition, this novel buffer represents a step ahead towards the goal of closing the 'gap' between the commercially available Immobilines, pK 7.0 and 8.5. Owing to the large distance between these two neighboring pK values, it is difficult to arrange for linear narrow pH gradients in this region. IPG compositions obtained with this new buffer give highly linear pH gradients and protein profiles identical to those obtained with commercial Immobilines.     

Isoelectric protein purification in segmented immobilized pH gradients. Effect of salts on rate of contaminants' removal

A method is described for keeping a constant salt background during protein purification in a segmented immobilized pH gradient. It is based on an external hydraulic flow replenishing the salt loss due to combined electric and diffusional mass transport (similar to the concept of Ribes' steady-state rheoelectrolysis). Such a minimum of ionic strength might be needed for proteins which tend to precipitate and aggregate at or in vicinity of the isoelectric point. However, it is found that any salt level in the sample feed (already at 1 mM concentration) deteriorates transport of non-isoelectric proteins, because of the much larger current fraction carried by the ions themselves as opposed to proteins. In addition, high salt levels in the sample reservoir might form cathodic and anodic ion boundaries, alkaline and acidic, respectively, which might hamper protein migration and even induce denaturation. Thus, when high salt backgrounds are needed in the sample feed, external pH control should be exerted, e.g. with a pH-stat. Three parameters influence protein transport in the segmented IPG chamber: (a) cross-sectional area of the Immobiline membranes; (b) delta pI between the isoelectric protein and the contaminants and (c) salt molarity in the sample reservoir. The first 2 show a positive, the last a negative correlation.     

Two-dimensional maps in the most extended (pH 2.5-11) immobilized pH gradient interval

In conventional isoelectric focusing in soluble, amphoteric buffers, it has been quite difficult to produce two-dimensional (2-D) separations in pH intervals greater than pH 4-8. In general more alkaline proteins were analyzed by non-equilibrium IEF in the first dimension. Even with the advent of immobilized pH gradients (IPG), separations could be extended to pH gradients not wider than pH 3-10, due to a lack of suitable buffers. Since more acidic and more alkaline acrylamido buffers have recently been synthesized, we have been able to optimize what is believed to be the widest possible immobilized pH gradient, a pH 2.5-11 span. We report here for the first time 2-D separations of total tissue lysates in such extended pH 2.5-11 gradients. It appears that, with the IPG technique, close to 100% of all possible cell products can be displayed in a single 2-D map.     

Strategies for the enrichment and identification of basic proteins in proteome projects

Two-dimensional gel electrophoresis (2-DE) is currently the method of choice for separating complex mixtures of proteins for visual comparison in proteome analysis. This technology, however, is biased against certain classes of proteins including low abundance and hydrophobic proteins. Proteins with extremely alkaline isoelectric points (pI) are often very poorly represented using 2-DE technology, even when complex mixtures are separated using commercially available pH 6-11 or pH 7-10 immobilized pH gradients. The genome of the human gut pathogen, Helicobacter pylori, is dominated by genes encoding basic proteins, and is therefore a useful model for examining methodology suitable for separating such proteins. H. pylori proteins were separated on pH 6-11 and novel pH 9-12 immobilized pH gradients and 65 protein spots were subjected to matrix-assisted laser desorption/ionization-time of flight mass spectrometry, leading to the identification of 49 unique proteins. No proteins were characterized with a theoretical pI of greater than 10.23. A second approach to examine extremely alkaline proteins (pI > 9.0) utilized a prefractionation isoelectric focusing. Proteins were separated into two fractions using Gradiflow technology, and the extremely basic fraction subjected to both sodium dodecyl sulphate-polyacrylamide gel electrophoresis and liquid chromatography (LC) - tandem mass spectrometry post-tryptic digest, allowing the identification of 17 and 13 proteins, respectively. Gradiflow separations were highly specific for proteins with pI > 9.0, however, a single LC separation only allowed the identification of peptides from highly abundant proteins. These methods and those encompassing multiple LC 'dimensions' may be a useful complement to 2-DE for 'near-to-total' proteome coverage in the alkaline pH range.     

Isoelectric focusing and two-dimensional electrophoresis of tubulin using immobilized pH gradients under denaturing conditions

Modifications of the LKB Immobiline isoelectric focusing (IEF) technique are described for use under conditions that solubilize and denature most proteins (8 M urea and 2% Nonidet-P40). This procedure permits pH gradients that are four- to fivefold shallower than previously available with conventional ampholine-IEF procedures. It can also be used as a first dimension in two-dimensional gel electrophoresis. The advantage of the stable ultranarrow pH gradient is demonstrated by directly comparing the resolution of vertebrate brain tubulins using (i) denaturing conventional ampholine-IEF and (ii) denaturing Immobiline-IEF. Analysis of tubulin on the Immobiline-IEF gel increases the separation distance between the individual tubulins and distinguishes differences among tubulin samples that could not be resolved by conventional ampholine isoelectric focusing.     

Protein desalting by isoelectric focusing in a segmented immobilized pH gradient

We have recently described an apparatus for protein purification based on a segmented Immobiline gel, having one or more liquid interlayers in between. The principle is entirely new, as it is based on keeping the protein of interest isoelectric, in a flow chamber, and focusing the impurities in an Immobiline gel. For this, a hydraulic flow is coupled orthogonally to an electric flow, sweeping away the non-isoelectric impurities from the recycling chamber. We now demonstrate that the present apparatus can be efficiently used for protein desalting. Hemoglobin A samples, containing 50 mM NaCl or 50 mM ammonium acetate, could be efficiently desalted in 2 h of recycling, after which the total salt content had decreased to less than 0.005 mM (a salt decrement of more than 10,000 fold the initial input). However, with polyprotic buffers (sulphate, citrate, phosphate, oligoamines) the desalting process was much slower, typically of the order of 20 h, possibly due to interaction of these species with the surrounding Immobiline matrix. In this last case, outside pH control (e.g. with a pH-stat) is necessary during protein purification, as, due to the faster removal of the monovalent counterion, the solution in the recycling chamber can become rather acidic or alkaline. It is demonstrated that the 2 extremities of the Immobiline segments facing the sample recycling chamber act indeed as isoelectric membranes, having a good buffering capacity, preventing the protein macroion from leaving the chamber by continuously titrating it to its isoelectric point.     

Preparative isoelectric focusing in immobilized pH gradients. I. General principles and methodology

A new method for preparative protein purification is described, based on the use of Immobiline matrices. After electrofocusing, the protein zone of interest is recovered by electrophoretic transfer to a hydroxyapatite gel, from which it is eluted with 0.2 M phosphate buffer, pH 6.8, with yields for the proteins studied in the range 76-98%. For six different proteins, the focusing step gives a common upper limit of approximately 45 mg protein/ml gel as mean concentration in a focused protein zone. It is demonstrated that in practical preparative work, components with a pI difference of 0.007 pH units can be completely resolved, and that on a 5-mm-thick gel of dimensions 240 X 110 mm, samples containing as much as 400 mg of the major protein component can be applied. Focusing of large amounts of a salt-containing sample is demonstrated with the aid of human serum. A theoretical expression is given relating the concentration distribution and maximum protein concentration within a focused zone to the applied voltage, the pH slope used and the zone width. Based on this expression and the finding of an upper concentration limit for a protein we shown how to optimize the parameters in preparative work with immobilized pH gradients in relation to the separation power needed. Finally, it is shown that, in comparison with conventional preparative electrofocusing in polyacrylamide gels, immobilized pH gradients allow a ten-fold increase in load, whilst still giving a resolution comparable to that of analytical isoelectric focusing.     

Preparative two-dimensional gel electrophoresis at alkaline pH using narrow range immobilized pH gradients

A reproducible high-resolution protein separation method is the basis for a successful differential proteome analysis. Of the techniques currently available, two-dimensional gel electrophoresis is most widely used, because of its robustness under various experimental conditions. With the introduction of narrow range immobilized pH gradient (IPG) strips (also referred to as ultra-zoom gels) in the first dimension, the depth of analysis, i.e. the number of proteins that can be resolved, has increased substantially. However, for poorly understood reasons isoelectric focusing on ultra-zoom gels in the alkaline region above pH 7 has suffered from problems with resolution and reproducibility. To tackle these difficulties we have optimized the separation of semipreparative amounts of proteins on alkaline IPG strips by focusing on two important phenomena: counteracting water transport during isoelectric focusing and migration of dithiothreitol (DTT) in alkaline pH gradients. The first problem was alleviated by the addition of glycerol and isopropanol to the focusing medium, leading to a significant improvement in the resolution above pH 7. Even better results were obtained by the introduction of excess of the reducing agent DTT at the cathode. With these adaptations together with an optimized composition of the IPG strip, separation efficiency in the pH 6.2-8.2 range is now comparable to the widely used acidic ultra-zoom gels. We further demonstrated the usefulness of these modifications up to pH 9.5, although further improvements are still needed in that range. Thus, by extending the range covered by conventional ultra-zoom gels, the depth of analysis of two-dimensional gel electrophoresis can be significantly increased, underlining the importance of this method in differential proteomics.     

Amphoteric, isoelectric immobiline membranes for preparative isoelectric focusing

Amphoteric, isoelectric agarose membranes, as devised by Martin and Hampson [Martin, A.J.P. and Hampson, F. (1978) J. Chromatogr. 159, 101-110], are found unsuitable for blocking electroendosmosis in multi-compartment electrolysers during preparative isoelectric focusing, due to the poor and highly unpredictable incorporation of carboxyls and amino groups on the polysaccharide moiety. New, polyacrylamide-based membranes are described, containing as buffers and titrants the Immobiline chemicals used to produce immobilized pH gradients. These new membranes are supported on both faces by a non-woven polypropylene cloth, a material exhibiting minimal adsorption properties for proteins. Due to the extensively developed Immobiline technology, membranes with highly predictable isoelectric points, well-defined buffering capacity and conductivity can be synthesized at any pH value along the pH 3-10 scale. They are effective in blocking electroendosmosis even when the delta pH on either side of the membrane is as high as 1.5 pH unit.     

Isoelectric focusing of sparingly soluble proteins in immobilized pH gradients, exemplified by microvillar membrane hydrolases

A novel fractionation technique is described for analysis of membrane-bound enzymes and sparingly soluble proteins: isoelectric focusing in a mixed-type matrix, containing a primary, immobilized pH gradient with a superimposed, secondary carrier ampholyte pH gradient. Three microvilli hydrolases: dipeptidyl peptidase IV, gamma-glutamyl transferase and alkaline phosphatase exhibit an array of sharply focused, enzyme active bands in the pH 4-6.5 range. The separation pattern obtained is by far superior to any separation achieved by either technique separately.     

Mitochondrial pH monitored by a new engineered green fluorescent protein mutant

We here describe a new molecularly engineered green fluorescent protein chimera that shows a high sensitivity to pH in the alkaline range. This probe was named mtAlpHi, for mitochondrial alkaline pH indicator, and possesses several key properties that render it optimal for studying the dynamics of mitochondrial matrix pH, e.g. it has an apparent pK(a) (pK(a)') around 8.5, it shows reversible and large changes in fluorescence in response to changes in pH (both in vitro and in intact cells), and it is selectively targeted to the mitochondrial matrix. Using mtAlpHi we could monitor pH changes that occur in the mitochondrial matrix in a variety of situations, e.g. treatment with uncouplers or Ca(2+) ionophores, addition of drugs that interfere with ATP synthesis or electron flow in the respiratory chain, weak bases or acids, and receptor activation. We observed heterogeneous pH increases in the mitochondrial matrix during Ca(2+) accumulation by this organelle. Finally, we demonstrate that Ca(2+) mobilization from internal stores induced by ionomycin and A23187 cause a dramatic acidification of the mitochondrial matrix.     

pK values of histidine residues in ribonuclease Sa: effect of salt and net charge

The primary goal of this study was to gain a better understanding of the effect of environment and ionic strength on the pK values of histidine residues in proteins. The salt-dependence of pK values for two histidine residues in ribonuclease Sa (RNase Sa) (pI=3.5) and a variant in which five acidic amino acids have been changed to lysine (5K) (pI=10.2) was measured and compared to pK values of model histidine-containing peptides. The pK of His53 is elevated by two pH units (pK=8.61) in RNase Sa and by nearly one pH unit (pK=7.39) in 5K at low salt relative to the pK of histidine in the model peptides (pK=6.6). The pK for His53 remains elevated in 1.5M NaCl (pK=7.89). The elevated pK for His53 is a result of screenable electrostatic interactions, particularly with Glu74, and a non-screenable hydrogen bond interaction with water. The pK of His85 in RNase Sa and 5K is slightly below the model pK at low salt and merges with this value at 1.5M NaCl. The pK of His85 reflects mainly effects of long-range Coulombic interactions that are screenable by salt. The tautomeric states of the neutral histidine residues are changed by charge reversal. The histidine pK values in RNase Sa are always higher than the pK values in the 5K variant. These results emphasize that the net charge of the protein influences the pK values of the histidine residues. Structure-based pK calculations capture the salt-dependence relatively well but are unable to predict absolute histidine pK values.