Separation of human alloalbumin variants by isoelectric focusing

A technique for the separation of human alloalbumin variants by means of isoelectric focusing in the presence of 8M urea and 60 mM L-serine is described. The potential usefulness of this technique in the detection and classification of genetic heterogeneity at the albumin locus is demonstrated by the differentiation of three human alloalbumin variants of European origin.     

Analysis of hemoglobin and globin chain variants by a commonly used capillary isoelectric focusing method

To analyze both hemoglobin (Hb) and globin chain variants, we modified a commonly used method, capillary isoelectric focusing (CIEF), with detection at 280 nm. The samples were hemolysates prepared from red blood cells, and globin chains obtained from the hemolysates by treatment with cold acidified acetone. When the migration time for the internal reference, carbonic anhydrase I (isoelectric point, pI 6.60), was taken as 1.0, the migration ratio for Hb A0 in normal human blood was 0.877 +/- 0.004 (mean +/- SD, n = 9), and those of the alpha- and beta-globin chains were 0.673 +/- 0.004 and 0.847 +/- 0.005 (mean +/- SD, n = 4), respectively. The ratio of peak heights between the beta- and alpha-globin chains (beta/alpha) in the normal Hbs obtained from four subjects was almost constant at 2.5 +/- 0.1 (mean +/- SD). This ratio indicates which of the globin chains includes a mutation (if one exists). When an Hb variant, Hb Hoshida (in which Gln is substituted for Glu at residue 43 in the beta-globin chain), was analyzed by this method, two main peaks were observed (migration ratios 0.836 and 0.877, corresponding to an abnormal and the normal Hb, respectively). An additional peak with an abnormal migration ratio of 0.788 was also detected in the globin chain profiles. The ratio of peak heights between normal beta- and alpha-globin chains was 1.57, indicating that a mutation exists in the beta-globin chain. We thus established a convenient system using CIEF that provides a rapid and reproducible method for the random analysis of both Hb and globin chain variants.     

Determination of the isoelectric point of proteins by capillary isoelectric focusing

Different ways of determining isoelectric points (pI) of proteins in capillary isoelectric focusing are reviewed here. Due to the impossibility of direct pH measurements in the liquid phase, such assessments have to rely on the use of pI markers. Different types of pI markers have been described: dyes, fluorescently labelled peptides, sets of proteins of known pI values. It appears that, perhaps, the best system is a set of 16 synthetic peptides, trimers to hexamers, made to contain each a Trp residue for easy detection at 280 nm. By a careful blend of acidic (Asp, Glu), mildly basic, with pK around neutrality (His), and basic (Lys, Arg) amino acids, it is possible to obtain a series of pI markers with pI values quite evenly distributed along the pH scale, possessing good buffering capacity and conductivity around their pI values and thus focusing as sharp peaks. Another approach to pI determination is the monitoring of the current during mobilization: this allows, with the aid of known pI markers, to calibrate the system with a pI/current graph. Pitfalls and common errors in pI determinations are reviewed here and guidelines given for minimizing such errors in pI estimation.     

Synthetic oligopeptides as isoelectric point markers for capillary isoelectric focusing with ultraviolet absorption detection

Sixteen peptides (trimers to hexamers) were designed for use as a set of pI markers for capillary isoelectric focusing (CIEF). Each peptide contains one tryptophan residue for detection by UV absorption and other amino acid residues having ionic side chains, which are responsible for focusing to its pI. The pIs of these peptides were determined by slab-gel IEF using commercial carrier ampholytes. The focused peptides in the gel were detected by absorption measurement at 280 nm using a scanning densitometer and the pH gradient was determined by measuring the pH of the gel using an oxidized metal membrane electrode. The pI values of the peptides ranged from 3.38 to 10.17. The obtained values agreed well with the predicted ones, which were calculated based on amino acid compositions, with root mean square differences of 0.15 pH unit. The peptides were detected at 280 nm as very sharp peaks when separated by CIEF. The pI values of some standard proteins were redetermined by CIEF by using this set of peptide pI markers and the values agreed closely with those reported previously. The sharp focusing, stability, high purity and high solubility of these synthetic pI markers should facilitate the profiling of a pH gradient in a capillary and the determination of the pI values of proteins.     

毛细管等电聚焦和电渗泵驱动聚焦区带分离蛋白质

建立了一种利用电渗泵驱动毛细管内的聚焦区带,实现毛细管电泳等电聚焦分离蛋白质的方法。通过控制电压来调节泵的输出流量,从而调节聚焦区带的迁移速度。适用于毛细管电泳等电聚焦两步法分离蛋白质等两性物质。考察了对牛血清白蛋白和溶菌酶两种粗提蛋白质混合物的分离,迁移时间的RSD分别为1.6%和1.3%,峰面积的RSD均为1.6%,证明方法可行。     

Peak identification in capillary isoelectric focusing using the concept of relative peak position as determined by two isoelectric point markers

In CIEF analysis, sample peaks can be identified by their relative peak positions (RPP) that are determined using only two internal pI markers. The two internal pI marker peaks should bracket, as close as possible, the sample peaks. The RPP values of the sample peaks are then calculated using the pI values, peak positions of the two pI markers, and peak position of the sample. Use of this method can effectively compensate for pH gradient distortions that often occur as a result of salts. Also, as shown by the results of this paper, regardless of the linearity of the pH gradient established by the given carrier ampholytes, sample peaks can be identified within an SD of 0.1 pH unit in RPP (<2% RSD) as long as the sample is run using the same carrier ampholytes and maintaining salt concentrations in the range of 0-15 mM.     

A multivariate approach for the determination of isoelectric point of human carbonic anhydrase isoforms by capillary isoelectric focusing

Human carbonic anhydrase (hCA) IX and XII are isoenzymes which are highly overexpressed in many cancer types. Recently, it has been shown that hCA IX contributes to the acidification of the tumor environment leading to chemoresistance with basic antitumoral drugs. The development of selective hCA inhibitors constitutes a new therapeutic axis. In order to elucidate the specific interactions between hCA and inhibitors, physico-chemical properties of hCA must be evaluated. This work reports the determination of the isoelectric point (pI) of a series of hCA isoforms by capillary isoelectric focusing. First, the method was optimized with synthetic UV-detectable pI markers using a central composite design. The separation was performed in a fused-silica capillary chemically derivatized with hydroxypropylcellulose and using a glycerol-water medium as the anticonvective gel. Three main factors (ampholyte content, focusing time and mobilization pressure) were optimized in order to obtain the best resolution, detection threshold and precision on the pI determination. Then, the model was validated through the analysis of standard proteins mixture having known pI values, before investigating the pI of hCA isoforms.     

Estimation of isoelectric points of human plasma proteins employing capillary isoelectric focusing and peptide isoelectric point markers

Synthetic UV-detectable peptide pI markers were used to estimate isoelectric point (pI) values of proteins separated by capillary isoelectric focusing (CIEF) followed by cathodic mobilization in the absence of denaturing agents. The pI calculation and quantitative analysis of purified proteins showed the feasibility of these peptides as pI markers and internal standards in CIEF separation of proteins. Estimation of pI values of major proteins in human plasma was performed using the peptide pI markers, and the values were compared with those previously obtained by gel isoelectric focusing (IEF). Sera of immunoglobulin G (IgG) myeloma patients, which showed characteristic peaks of myeloma IgG in their CIEF patterns, were also subjected to the analysis and the pI values of the myeloma proteins have been estimated.     

Dynamic capillary coatings with zwitterionic surfactants for capillary isoelectric focusing

The use of surfactants as additives was demonstrated for the first time in capillary isoelectric focusing (CIEF) to dynamically modify the surfaces of bare fused silica capillaries. These surfactants were zwitterionic sulfobetaines: dodecyldimethyl (3-sulfopropyl) ammonium hydroxide (C12N3SO3), hexadecyldimethyl (3-sulfopropyl) ammonium hydroxide (C16N3SO3) and coco (amidopropyl)hydroxyldimethylsulfobetaine (Rewoteric AM CAS U). They were added directly to the protein-ampholyte mixture, and remained in the capillary during isoelectric focusing and mobilization. The C16N3SO3 and CAS U coatings were shown effective in CEF. Separation of seven IEF protein standards was obtained, with significantly improved resolution compared to that from an uncoated silica capillary. The effect of these surfactants on the electroosmotic flow (EOF) in CIEF was determined. CAS U was effective in suppressing the EOF at neutral and alkaline pH conditions, C16N3SO3 was effective in suppressing EOF at acidic and neutral pH conditions. C12N3SO3 however had little effect on the EOF. The pH gradients formed inside these surfactant coated capillaries were recta-linear at pH 6 to 9 (R2 approximately equal to 0.99). Reproducibility of migration time and peak area was determined. For all three coatings, the migration time standard deviations were less than 1.6 min, and the relative standard deviations of area were below 10%. The protein recovery in the CAS U-modified capillary was quantitative or near-quantitative for five of the seven proteins studied.     

Analysis of acrylamido-buffers for isoelectric focusing by capillary zone electrophoresis

Immobilized pH gradients use a series of weak acrylamido acids and bases (Immobiline) to create a pH gradient along the separation axis. These buffers can be degraded in water by two mechanisms: (i) hydrolysis of the amido bond, with generation of free acrylic acid and either an amino acid or a diamine; (ii) autopolymerization to oligomers and/or n-mers. In order to check for these degradation products, different capillary zone electrophoresis systems for analysis of all Immobilines have been devised. The acidic compounds are resolved in 100 mM acetate, pH 4.0, whereas the alkaline Immobilines are separated in 50 mM phosphate buffer, pH 7.7 (or pH 7.2 for the weaker species). Polymers of alkaline Immobilines are resolved in 50 mM phosphate buffer, pH 2.5, in 1% Ficoll-400. All Immobilines are detected underivatized, by their adsorption at 214 or 254 nm. A calibration curve has been constructed for quantification of acrylic acid contamination. As little as 1 mol% of acrylic acid contamination in Immobiline solutions can be detected, with a sensitivity limit below 0.2 mM (at the injection port).     

Analysis of genetic variants of transferrin in human serum after desialylation by capillary zone electrophoresis and capillary isoelectric focusing

Capillary electrophoresis analysis of transferrin in human serum is used to assess genetic variants after desialylation with neuraminidase and iron saturation to reduce the complexity of the transferrin pattern and thus facilitate the recognition of transferrin polymorphisms. Asialo‐transferrin forms are analyzed by capillary zone electrophoresis using assay conditions as for the monitoring of carbohydrate‐deficient transferrin or by capillary isoelectric focusing in a pH 5–8 gradient which requires immunoextraction of transferrin prior to analysis. With the carrier ampholytes used, peaks for iron saturated and iron depleted transferrin are monitored which indicates complexation of iron ions by carrier ampholytes. For BC, CD, and BD genetic variants, the expected peaks for B, C, and D forms of transferrin were detected with both methods. Monitoring of CC patterns revealed three cases, namely those producing double peaks in both methods, a double peak in capillary isoelectric focusing only and a double peak in capillary zone electrophoresis only. For all samples analyzed, data obtained by capillary isoelectric focusing could be confirmed with gel isoelectric focusing. The two capillary electrophoresis methods are shown to represent effective tools to assess unusual transferrin patterns, including genetic variants with dissimilar abundances of the two forms.     

Capillary isoelectric focusing of erythropoietin glycoforms and its comparison with flat-bed isoelectric focusing and capillary zone electrophoresis

The influence of several operation conditions on separation of recombinant human erythropoietin glycoforms by capillary isoelectric focusing (cIEF) is explored. From this study it is deduced that in order to separate several glycoforms of erythropoietin, urea has to be added to sample, which should not be completely depleted of the excipients used in its formulation. On-line desalting does not provide separation enhancement for samples with high content of salt. Better resolution is obtained using a mixture of a broad and a narrow pH-range carrier ampholytes than with either one used separately. Under the experimental conditions, focusing voltages of 25 kV improve separation compared to lower and higher electric fields. Focusing times shorter than the time necessary for electric current to reach a minimum provide similar separations than longer focusing times at which a minimum value of the current has already been achieved. The optimized method allows the separation and quantitation in 12 min of at least seven bands containing glycoforms of recombinant erythropoietin with apparent isoelectric points in the range 3.78–4.69. Compared to flat-bed isoelectric focusing, cIEF provides better separation of bands of glycoforms in a shorter time, and allows quantitative determination. Capillary zone electrophoresis (CZE) gives rise to resolution of erythropoietin glycoforms similar to that obtained by cIEF. Although CZE requires a longer analysis time, its reproducibility in terms of peak area of glycoforms is better than in cIEF.     

固化pH梯度毛细管等电聚焦整体柱的制备及在蛋白质等电点分析中的应用

通过聚合物原位聚合反应，制备了部分填充的毛细管整体柱。pH 3~10的载体两性电解质被固化在该毛细管整体柱上。在引入八通进样阀、三通阀和四通连接单元的基础上，构建了适用于固化pH梯度毛细管等电聚焦整体柱（M-IPG）的平台。在蛋白质药物测定过程中，用M-IPG柱和羟丙基纤维素（HPC）涂层毛细管柱同时对曲托珠单抗和依那西谱的等电点进行了测定。结果表明，两种等电聚焦柱都能够同时分离混合蛋白质样品并测定蛋白质类药物中单抗和融合蛋白质的等电点（pI），M-IPG柱所测的pI值与HPC涂层毛细管柱测定的结果基本一致，表明了该柱在进一步构建多维分离平台进行蛋白质组学研究方面的潜力。     

Separation of human cerebrospinal fluid proteins by capillary isoelectric focusing in the absence of denaturing agents

Conditions of capillary isoelectric focusing (CIEF) to separate human cerebrospinal fluid (CSF) proteins were examined referring to those which we have established for the separation of human plasma/serum proteins. Since the average protein concentration in CSF is about 1/200 of plasma and the salt concentration is at almost the same level as plasma, desalting of CSF samples with minimum dilution was a prerequisite for CIEF analysis of CSF proteins. We constructed an apparatus to dialyze CSF at the level of 20-30 microL, this volume being sufficient for 3-4 repeated analyses of the CSF sample. To trace the process of dialysis, a simple device to measure the conductivity of the dialyzate was also constructed. Most of the CIEF conditions for plasma protein analysis could be applied for CSF protein analysis. However, the addition of N,N,N',N'-tetramethylethylenediamine (TEMED) at a suitable concentration was necessary to improve the resolution of basic proteins (IgG region), since some CSF patterns showed peaks of basic proteins which are not obvious in the serum of the same patient. About 70 peaks and shoulders of CSF proteins could be detected by the established CIEF technique. The results of CIEF analysis of CSF samples suggested that the technique will be useful as a survey method to detect specific proteins in CSF, which might relate to disorders in the central nervous system.     

Integration of capillary isoelectric focusing with capillary reversed-phase liquid chromatography for two-dimensional proteomics separation

On-line combination of capillary isoelectric focusing (CIEF) with capillary reversed-phase liquid chromatography (CRPLC) is developed using a microinjector as the interface for performing two-dimensional (2-D) protein/peptide separations of complex protein mixtures. The focusing effect of CIEF not only contributes to a high-resolution protein/peptide separation, but also may permit the analysis of low-abundance proteins with a typical concentration factor of 50-100 times. The preparative capabilities of CIEF are much larger than most of capillary-based electrokinetic separation techniques since the entire capillary is initially filled with a solution containing proteins/peptides and carrier ampholytes for the creation of a pH gradient inside the capillary. The focused peptides which have a similar pI are coinjected into the second separation dimension and further resolved by their differences in hydrophobicity. The resolving power of combined CIEF-CRPLC system is demonstrated using the soluble fraction of Drosophila salivary glands taken from a period beginning before steroid-triggered programmed cell death and extending to its completion. The separation mechanisms of CIEF and CRPLC are completely orthogonal and the overall peak capacity is estimated to be around approximately 1800 over a run time of less than 8 h. Significant enhancement in the separation peak capacity can be realized by further increasing the number of CIEF fractions and/or slowing the solvent gradient in CRPLC, however, at the expense of overall analysis time. The results of our preliminary studies display significant differences in the separation profiles of peptide samples obtained from salivary glands of animals staged at the 6 and 12 h following puparium formation.     

Simplified capillary isoelectric focusing with chemical mobilization for intact protein analysis

We report a capillary isoelectric focusing system based on a sequential injection method for simplified chemical mobilization. This system was coupled to an ion trap mass spectrometer with an electrokinetically pumped nanoelectrospray interface. The nanoelectrospray emitter employed an acidic sheath electrolyte. To simplify focusing and mobilization, a plug of ammonium hydroxide was first injected into the capillary, followed by a section of mixed sample and ampholyte. During focusing, the NH₃H₂O section worked as catholyte. As focusing progressed, the NH₃H₂O section was titrated to lower pH by the acidic sheath electrolyte. Chemical mobilization started automatically once the ammonium hydroxide was consumed by the acidic sheath flow electrolyte, which then acted as the mobilization solution. In this report, the lengths of the NH₃H₂O section and sample were optimized. With a 1 m long capillary, a relative short plug of the NH₃H₂O section (3 cm) produced both fast migration and reasonable separation resolution. The simplified capillary isoelectric focusing mass spectrometry system produced base peak intensity relative standard deviation of 8.5% and migration time relative standard deviation ≤0.6% for myoglobin and cytochrome C in triplicate runs.     

Sequential injection setup for capillary isoelectric focusing combined with MS detection

Capillary isoelectric focusing in the presence of electroosmosis with sequential injection of carrier ampholytes and sample was found to be suitable for MS detection. The separate injection of the sample and the ampholytes provides good condition to suppress and overcome the undesirable effect of the presence of ampholytes in MS. By the appropriate selection of ampholyte solutions, whose pH range not necessarily covers the pI values of the analytes, the migration of the components can be controlled, and the impact of the ampholytes on MS detection is decreased. The unique applicability of this setup is shown by testing several parameters, such as the application of volatile electrolyte solutions, the type of the ampholytes, the order and the number of the ampholyte and sample zones. Broad and narrow pH range ampholytes were applied in experiments using uncoated capillaries with different lengths for the analyses of substituted nitrophenol dyes to achieve optimal conditions for the MS detection. Although the sample components are not leaving the pH gradient, due to the decrease in the ampholyte concentration at the position of the components, and because the sample components migrate in charged state, the ionisation is more effective for MS detection.     

Fluorescein-based pI markers for capillary isoelectric focusing with laser-induced fluorescence detection

We prepared a series of low-molecular-mass fluorescent ampholytes with narrow pI range. These fluorescein-based ampholytes are detection compatible with argon laser-induced fluorescence (LIF) detection. The selected properties, important for their routine use as fluorescent pI markers, were examined. The pI values of new fluorescein-based pI markers were determined by capillary isoelectric focusing (CIEF) using currently available low-molecular-mass pI markers for CIEF with photometric detection. The examples of CIEF with fluorometric detection of new compounds together with fluorescein isothiocyanate (FITC) derivatized proteins are presented.     

Investigation of interaction between human hemoglobin A0 and platinum anticancer drugs by capillary isoelectric focusing with whole column imaging detection

CIEF with whole column imaging detection (WCID) was used to investigate the interaction of platinum-based anticancer drugs, cis-platinum(II) diamine dichloride (cisplatin) and [SP-4-2-{1R-trans)]-(1,2-cyclohexanediamine-N,N')[ethanedioata(2-)-O,O']platinum (oxaliplatin), with human hemoglobin A(0) (Hb). This technique facilitates the investigation and characterization of the formation of adducts between drugs and proteins. Cisplatin and oxaliplatin were mixed with the target protein at different concentrations (0:1, 1:1, 1:10, 1:50, and 1:100), and the reaction mixtures were incubated for 0, 0.5, 1, 12, 24, 48, and 72 h at 37 degrees C in a water-bath. The focused Hb-drug adduct profiles were imaged by WCID. At higher drug to protein molar ratios (for both oxaliplatin and cisplatin), the results exhibit significant changes in the peak shapes and heights, which may indicate the destabilization of the protein. However, the conformational change was less evident at lower molar ratios. In addition, a major pI shift was observed for the oxaliplatin reaction mixtures (for 1:10, 1:50, and 1:100 ratios). In comparison with previously reported findings obtained by other analytical methods, conclusions were drawn about the validity of CIEF as a simple and convenient method for the investigation of protein-drug interactions. These results may provide useful information for further understanding the activity and toxicity of these chemotherapeutic drugs and improving their clinical performance.     

Charge profiling and stability testing of biosimilar by capillary isoelectric focusing

CIEF was developed for the rapid analysis of charge heterogeneity of trastuzumab biosimilar using commercially available fluorocarbon‐coated capillary. The CIEF master mix was composed of 0.30% w/v methyl cellulose, 2.3 M urea, 56.8 mM l ‐arginine, 1.52 mM iminodiacetic acid, 4.5% v/v carrier ampholytes (broad‐range pI 3–10 and narrow‐range pI 8–10.5 with ratio of 3:1), and 0.45% v/v 10.0, 9.5, 7.0, 5.5, 4.1 pI markers. To get a robust method to analyze charge heterogeneity, some separation parameters, including focusing time and separation temperature, were investigated and optimized. The optimized method gave good precision in estimated pI values of charge variants with RSDs of not more than 0.16% intraday analysis (n = 6) and < 0.18% interday analysis (n = 9). In addition, the applications of this method including purity, stability, lot consistency, peptide N‐glycosidase F digest, and C‐terminal lysine variants characterization were also investigated.