A new method for pH determination in isoelectric focusing experiments

A rapid and reproducible method for the pH measurement in the effluent from density gradient electrofocusing is described. By this procedure, after preparative isoelectric focusing, the detection of protein zones and pH measurement can be accomplished simultaneously, by serially coupling a uv flow cell with a pH flow cell. This last one is connected to the recorder by a control unit, which allows the simultaneous printing of pH and uv absorption on the same chart.     

Isoelectric focusing of proteins using a pH gradient created by a concentration gradient of nonelectrolytes in solution.

A new method of producing a stable pH gradient in buffer solutions is suggested, obtained by the concentration gradient of a nonelectrolyte in buffer solutions as a result of the gradual change in the dielectric properties of the solution. The maximal concentrations of nonelectrolyte which do not influence the protein configuration allow a pH gradient with a range of two pH units to be produced. It is suggested that the properties of some polyols (i.e. glycerol or mannitol) be used to change the pH of the borate buffer for the production of greater pH gradient with a range of up to 4-5 pH units. Creating the gradient of concentration of polyols, one can obtain a pH gradient in borate buffer solutions. Though the polylydroxyl compound-borate complexes posses mobility in an electric field, a stable pH gradient can be achieved during 12 days of electrophoresis. The isoelectric focusing of haemoglobin, human serum albumin and immunoglobulins was carried out in both systems suggested. These findings were compared with isoelectric focusing in Ampholines. There was a good agreement between the methods compared. The possible differences are discussed.     

Isoelectric focusing using non-amphoteric buffers in free solution: II. Apparatus and measures of pH stability

Isoelectric focusing of amino acids or proteins requires a time-invariant pH gradient. The maintenance, in an electric field, of such profiles with simple non-amphoteric buffers is possible in multicompartment cells using well determined concentration profiles. The method for determining these concentration profiles has been proposed in a preceding paper. A multicompartment cell has been built for the purpose of verifying the assumptions made. The technical characteristics of this cell will be described here. The time-stability of pH profiles obtained with sodium acetate/acetic acid buffers has been measured for concentration profiles determined so as to keep constant the transport number of each ion throughout the cell. Measured over a time span of 10 h and with a current density of 96 mA cm-2, the pH shift is, in the worst case, 0.009 pH unit/h. This corresponds to a much better stability than the one obtained with a constant concentration of sodium acetate in all compartments, and justifies the chosen concentration profiles based on the condition of constant transport numbers. The above mentioned method for the computation of the buffer concentration assumed a constant relative mobility of the ions. The experiments have shown the limits of this assumption, i.e. the variation of ionic mobilities with the ionic strength and the temperature diminishes the stability of the pH gradient. However, slight adjustments of the concentration in the end compartments allow some improvement of the stability. If the temperature could be precisely controlled in each compartment, a better pH stability than what has been achieved in these experiments should be reached. Two methods of compensation of the migration of ions in the end compartments (buffer renewal method and external recycling method) have been tested and will be discussed.     

Isoelectric focusing of plant cell protoplasts: separation of different protoplast types

The surface charge of plant protoplasts has been measured by a new technique, isoelectric focusing. The protoplasts were loaded in a dextran density gradient over which a pH gradient was superimposed. When voltage was applied, protoplasts moved to a point in the gradient corresponding to their isoelectric point (pI). The pI of the protoplasts varied with the compounds used for pH gradient generation. Using commercial ampholytes for pH gradient formation, the pI of all protoplasts tested was 4.4 ± 0.2, and viability following electrophoresis was low. Using an acetate/acetic acid mixture to generate the pH gradient, the pI of protoplasts varied from 3.7 to 5.3 depending on the species and tissue type of the parental cells. Postelectrophoresis viability was high. Using isoelectric focusing techniques, it was possible to separate mixtures of protoplasts derived from different species of plants.     

High resolution two-dimensional electrophoresis of basic as well as acidic proteins.

A previously described two-dimensional electrophoresis procedure (O'Farrell, 1975) combined isoelectric focusing and sodium dodecylsulfate slab gel electrophoresis to give high resolution of proteins with isoelectric points in the range of pH 4–7. This paper describes an alternate procedure for the first dimension which, unlike isoelectric focusing, resolves basic as well as acidic proteins. This method, referred to as nonequilibrium pH gradient electrophoresis (NEPHGE), involves a short time of electrophoresis toward the cathode and separates most proteins according to their isoelectric points. Ampholines of different pH ranges are used to optimize separation of proteins with different isoelectric points. The method is applied to the resolution of basic proteins with pH 7–10 Ampholines, and to the resolution of total cellular proteins with pH 3.5–10 Ampholines. Histones and ribosomal proteins can be readily resolved even though most have isoelectric points beyond the maximum pH attained in these gels. The separation obtained by NEPHGE with pH 3.5–10 Ampholines was compared to that obtained when isoelectric focusing was used in the first dimension. The protein spot size and resolution are similar (each method resolving more than 1000 proteins), but there is less resolution of acidic proteins in this NEPHGE gel due to compression of the pattern. On the other hand, NEPHGE gels extend the range of analysis to include the 15–30% of the proteins which are excluded from isoelectric focusing gels. The distribution of cell proteins according to isoelectric point and molecular weight for a procaryote (E. coli) was compared to that of a eucaryote (African green monkey kidney); the eucaryotic cell proteins are, on the average, larger and more basic.     

Isoelectric focusing in immobilized pH gradients in the pH 10-11 range

With the synthesis of a new, strongly basic Immobiline (pK 10.3 at 10 degrees C) it has been possible to formulate a new pH 10-11 recipe for focusing very alkaline proteins, not amenable to fractionation with conventional isoelectric focusing in carrier ampholyte buffers. In this formulation, water is added as an acidic Immobiline having pK = 14 and a unit molar concentration (or with a pK = 15.74 and standard 55.56 molarity) since around pH 11 its buffering power becomes significant. The gel contains a 'conductivity quencher', i.e. a density gradient incorporated in the matrix, with the dense region located on the cathodic side (pH 11) for (a) smoothing the voltage gradient on the separation cell and (b) reducing the anodic electrosmotic flow due to the net positive charge acquired by the matrix at pH 11 (1 mM excess protonated amino groups to act as counterions to the 1 mm OH- groups in the bulk water solution generated by the local value of pH 11). Excellent focusing is obtained for such alkaline proteins as lysozyme (pI 10.55), So-6 (a leaf protein, pI 10.49), cytochrome c (pI 10.45) and ribonuclease (pI 10.12).     

Analysis of an HL-A antiserum by iso-electric focusing.

An anti-HL-A 3 antiserum with cross-reacting activity for HL-A 1 and HL-A 11 was subjected to isoelectric focusing over a pH 5-8 gradient. The cytotoxic activity of the serum focused into three distinct peaks, one at the basic end of the gradient, one between pH 6 and pH 7 and one at the acidic end. The first and second peaks reacted with HL-A 3 positive cells and HL-A 3 negative cells positive for cross-reacting antigens. The third peak reacted only with HL-A 3 positive cells.     

Optical tweezers cause physiological damage to Escherichia coli and Listeria bacteria

We investigated the degree of physiological damage to bacterial cells caused by optical trapping using a 1,064-nm laser. The physiological condition of the cells was determined by their ability to maintain a pH gradient across the cell wall; healthy cells are able to maintain a pH gradient over the cell wall, whereas compromised cells are less efficient, thus giving rise to a diminished pH gradient. The pH gradient was measured by fluorescence ratio imaging microscopy by incorporating a pH-sensitive fluorescent probe, green fluorescent protein or 5(6)-carboxyfluorescein diacetate succinimidyl ester, inside the bacterial cells. We used the gram-negative species Escherichia coli and three gram-positive species, Listeria monocytogenes, Listeria innocua, and Bacillus subtilis. All cells exhibited some degree of physiological damage, but optically trapped E. coli and L. innocua cells and a subpopulation of L. monocytogenes cells, all grown with shaking, showed only a small decrease in pH gradient across the cell wall when trapped by 6 mW of laser power for 60 min. However, another subpopulation of Listeria monocytogenes cells exhibited signs of physiological damage even while trapped at 6 mW, as did B. subtilis cells. Increasing the laser power to 18 mW caused the pH gradient of both Listeria and E. coli cells to decrease within minutes. Moreover, both species of Listeria exhibited more-pronounced physiological damage when grown without shaking than was seen in cells grown with shaking, and the degree of damage is therefore also dependent on the growth conditions.     

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.     

The internal-alkaline pH gradient, sensitive to uncoupler and ATPase inhibitor, in growing Clostridium pasteurianum.

1. The intracellular pH was measured in growing Clostridium pasteurianum with and acid-base equilibrium distribution method. [14C]Dimethyloxazolidinedione, [14]methylamine and [14C]acetic acid were used as "deltapH-indicators". During growth the extracellular pH decreased from 7.1 to 5.1; simultaneously the intracellular pH changed from 7.5 to 5.9. Thus, the intracellular pH was more alkaline than the extracellular pH by 0.4 to 0.8 pH-units. 2. This pH gradient (interior alkaline) was abolished by the proton conductor carbonylcyanide m-chlorophenylhydrazone and the ATPase inhibitor N,N'-dicyclohexylcarbodiimide. The pH gradient could not be demonstrated in cells depleted of an energy substrate. These results suggest that the pH gradient is formed by an ATPase-driven extrusion of protons from the cells rather than by a Donnan potential. 3. Growth of the organism was inhibited by low concentrations of both carbonylcyanide m-chlorophenylhydrazone (5 muM) and dicyclohexylcarbodiimide (5 muM). This finding suggests that the pH gradient is essential for the growing cell as it may be required for substrate accumulation and other types of transport processes.     

Isoelectric focusing by free solution capillary electrophoresis.

A reproducible, quantitative isoelectric focusing method using capillary electrophoresis that exhibits high resolution and linearity over a wide pH gradient was developed. RNase T1 and RNase ba are two proteins that have isoelectric points (pI's) at the two extremes of a pH 3-10 gradient. Site-directed mutants of the former were separated from the wild-type form and pI's determined in the same experiment. The pI's of RNase T1 wild-type, its three mutants, and RNase ba were determined for the first time as 2.9, 3.1, 3.1, 3.3, and 9.0, respectively. The paper describes the protocol for isoelectric focusing by capillary electrophoresis, as well as presenting data describing the linearity, resolution, limits of mass loading, and reproducibility of the method.     

Introduction of Additional Charges as an Aid in Protein Purification: Isolation of Elongation Factor 2 from Sulfolobus acidocaldarius by Preparative Isoelectric Focusing Before and After ADP-Ribosylation

Diphtheria toxin catalyzes the ADP-ribosylation of elongation factor 2 (EF-2) in eukaryotes and archaebacteria. As the reaction is strictly EF-2 specific and introduces two negative charges into the molecule, the resulting shift in the isoelectric point (pI) by 0.2 pH units was used to establish a new purification method for EF-2 from Sulfolobus acidocaldarius. The cells were lysed with dithiothreitol at pH 9 and EF-2 was purified by ammonium sulfate precipitation, gel filtration on Sephadex G-200, and three isoelectric focusing steps. The EF-2-containing fractions from the first isoelectric focusing step at pH 4-9 were refocused in a more narrow pH-gradient (pH 5-7). The EF-2 peak from the second step was eluted, collecting only the fractions above the pH region where ADP-ribosylated EF-2 would focus. The EF-2 was then ADP-ribosylated with diphtheria toxin and NAD and subjected to further isoelectric focusing (pH 5-7). The EF-2 was almost homogeneous since ADP-ribosylation had shifted it into a region of the pH gradient free of contaminating proteins. Diphtheria toxin was immobilized on CNBr-activated Sepharose to prevent a possible contamination by proteins from the diphtheria toxin preparation which might have the same pI as ADP-ribosylated EF-2. Finally, the ADP-ribosyl group was removed by equilibrium dialysis using diphtheria toxin and nicotinamide at pH 6.3. The obtained EF-2 was active in protein synthesis.     

Scanning isoelectric focusing in small density-gradient columns: I. Use of a Standard Spectrophotometer Cuvette for Focusing. Chemical Modification of Proteins by Migrating Reactive Ions

By the method of isoelectric focusing in a sucrose density gradient, small protein samples (less than 100 μg) have been separated and analyzed within 2 hr, using as electrolysis column a commercial standard quartz spectrophotometer cuvette, equipped with platinum electrodes and placed in an optical scanning device. Preparation of the cuvette prior to an isoelectric focusing experiment required about half an hour with no external apparatus, as the density gradient was created spontaneously in the cell by free interdiffusion of sucrose solutions. The cuvette temperature could be controlled by circulating water. The optical detection device permitted repeated scanning of the cuvette during the electrolysis process, thus providing information about the events occurring to a protein during focusing or prolonged electrolysis. By scanning with wavelength at the positions where the proteins have focused, their absorption spectra were obtained. the isoelectric points of separated proteins were estimated by fractionation of the cell contents and subsequent pH measurements on the fractions.The present paper also describes how individual Ampholine components, or groups of components, in their focused states gave rise to easily detected refractive-index gradients within the cell. The optical scanning device has been built in such a way that interference of these gradients with absorption measurements was abolished.Application of the technique to the isoelectric separation of commercial sperm whale myoglobin is reported. Ferrous or ferric forms of the focused myoglobin components were obtained by migration of reducing or oxidizing agents through the zones.     

Isoelectric focusing of proteins at the 10−10 to 10−9-g level

A microisoelectric focusing method is described which is sensitive at the 10^?10 g level, and is comparable in its pH gradient characteristics to conventional isoelectric focusing methods in acrylamide gels.     

Red cell pH of lamprey (Lampetra fluviatilis) is actively regulated

Summary The red cell pH of lamprey (Lampetra fluviatilis) was measured using the DMO method (based on the passive distribution of the wead acid, DMO, across the red cell membrane). The measured red cell pH was higher than the pH of the incubation medium throughout the pH range (7.2–8.2) studied, and higher than the red cell pH calculated from the chloride distribution ratio. Treatment of cells with the metabolic inhibitors 2,4-dinitrophenol or KCN caused a drop in the red cell pH to values lower than the pH of incubation medium, and abolished the difference between the measured red cell pH and the pH calculated from the chloride distribution ratio. These data strongly suggest that the proton gradient across lamprey red cell membrane is actively maintained. Acid extrusion from lamprey red cells may require sodium, as indicated by the observation that when choline was substituted for sodium in the incubation medium, the intracellular pH decreased significantly.     

THE SEPARATION OF DIFFERENT CELL CLASSES FROM LYMPHOID ORGANS : III. The Purification of Erythroid Cells by pH-Induced Density Changes

1. Mammalian erythrocytes swell as the pH of the isotonic suspending medium is lowered, as a direct consequence of the specialized permeability properties of the erythrocyte membrane. Lymphocytes and granulocytes from a variety of sources did not exhibit this property. 2. The behaviour of mouse bone marrow erythroid cells at various stages of differentiation was studied by using a change in buoyant density with pH as an index of swelling. The ability to swell with a pH drop was acquired while the cell was still nucleated. All non-nucleated cells showed swelling. Most small erythroblasts shared this property, whereas most large erythroblasts did not. 3. The density shift with pH was used to provide a purification scheme specific for erythroid cells. The bone marrow cells were first centrifuged to equilibrium in an isotonic albumin density gradient at neutral pH. Regions of the gradient containing the erythroid cells were collected, and the cells were recovered and redistributed in an albumin gradient at acid pH. The erythroid cells showed a specific density shift which removed them from contaminants. Preparations containing 90–97% erythroblasts were obtained by this technique. 4. Differentiation within the erythroid series was accompanied by a general increase in cell buoyant density at neutral pH. This density increase may have been a discontinuous process, since erythroid cells appeared to form a number of density peaks. 5. The pH shift technique, in association with established density distribution and sedimentation velocity procedures, provides a range of cell separation techniques for biological or biochemical studies of erythroid cell differentiation in the complex cell mixtures in bone marrow or spleen.     

A method for two-dimensional electrophoresis of proteins from green plant tissues

A method of extraction of proteins from green plant tissues for two-dimensional electrophoresis is presented. The method is demonstrated on barley and potato leaves and on spruce needles for use in isoelectric focusing as well as in nonequilibrium pH gradient electrophoresis. The following three-step procedure was used: (i) The tissue was ground in liquid nitrogen and then in a pH 5.0 buffer with thiourea added to inhibit phenoloxidase and polyvinylpyrrolidone to bind phenolic compounds. (ii) The proteins were precipitated with acetone at -20 degrees C. (iii) The proteins were dialyzed. Protease activity was generally not a problem during this procedure.     

Does a cell perform isoelectric focusing?

A model of intracellular electrical sorting of enzymes and organelles in the cytosol, based on isoelectric focusing, is proposed. The focusing is suggested to take place over a centrally symmetric pH gradient which in the cytosol of the yeast Saccharomyces cerevisiae is known to be 7.2-6.4. From published data on the energetic capacity and from the computed electric resistance of the S. cerevisiae cell, the maximum value of the electric field that can be maintained in the cytosol was estimated. The results showed that the strength of a centrally symmetric intracytosolic electric field could be as high as 90 mV/cm, which is sufficient to account for sorting of cytosolic proteins according to their isoelectric points. Although direct experimental evidence for intracellular isoelectric focusing is still missing, several phenomena of physiological importance can be understood on the assumption of its real existence.     

Separation of bacterial cells by isoelectric focusing, a new method for analysis of complex microbial communities.

A simple isoelectric focusing (IEF) method for whole bacterial cells was developed. In a pH gradient of 2 to 10 and an electric field of 11.5 V cm-1, mixtures of cells from the three different bacterial strains Chlorobium limicola 6230, Pseudomonas stutzeri DSM 50227, and Micrococcus luteus DSM 20030 could be separated. A density gradient of Ficoll prevented convective currents in the system. The method was tested with a concentrated mixture of bacteria from a shallow eutrophic lake and yielded up to 10 different bands. Species composition in each IEF band was analyzed by PCR plus denaturing gradient gel electrophoresis (DGGE). Each IEF band exhibited a different species composition. After the separation of cells by IEF three times more 16S ribosomal DNA signals could be detected by DGGE than in the unfractionated natural bacterial community. It is concluded that the resolution of these molecular biological methods is significantly enhanced if cells are first separated by IEF. At the same time, the IEF fractions are enriched for certain species, which can be used in subsequent cultivation experiments.     

Preparative immobiline isoelectric focusing of plasma apolipoproteins on vertical slab gels

An effective preparative isoelectric focusing method has been developed using the LKB Immobiline system in a vertical slab gel apparatus. Advantages of this procedure are ease of sample application, excellent resolution, and the direct visualization of focused bands. Narrow pH gradients have been used to separate apolipoprotein E3 isoforms (pH gradient 4.9-5.9) and to resolve the apolipoprotein C mixture (pH gradient 4.0-5.0). Recoveries ranged from 40 to 70%. The method should be valuable for protein and isoform purification.