Fractionation of the human recombinant tissue plasminogen activator (rtPA) glycoforms by high-performance capillary zone electrophoresis and capillary isoelectric focusing.

This paper reports the fractionation of recombinant human tissue plasminogen activator (rtPA) glycoforms, a complex mixture to demonstrate the high resolving power of capillary zone electrophoresis (CZE) and capillary isoelectric focusing (cIEF). rtPA is a glycoprotein with a complex carbohydrate structure. The electropherograms and IEF patterns have been discussed in light of the known carbohydrate structures of rtPA. rtPA was treated with neuraminidase which removes the sialic acids from the carbohydrate chains. The desialylated rtPA was analyzed by both CZE and IEF and the results were compared to those of untreated rtPA. The usefulness of CZE and cIEF in the characterization of glycoproteins proteins is also discussed.     

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.     

Isoforms analysis of recombinant human erythropoietin by polarity-reversed capillary isoelectric focusing

Recombinant human erythropoietin (rhuEPO) has been extensively used as a pharmaceutical product for treating anemia in the clinic. Glycosylation of rhuEPO was crucial for affecting biological activity, immunogenicity, and pharmacokinetics. Because of the heterogeneity of glycan, the structure of rhuEPO was complex with several isoforms. Characterization of isoforms was important for quality control of rhuEPO. Here, an improved cIEF method has been established and validated. A polarity-reversed focusing step was used by reversing both the polarity of the voltage and the catholyte and anolyte vials. A weak base (100 mM ammonium hydroxide solution) was used as a chemical mobilizer to make the acidic bands mobilize stably to the detection window. Compared with CZE method in European Pharmacopoeia, the numbers of isoforms and their peak area percentage were highly consistent. Better reproducibility and higher resolution have been obtained by the improved cIEF method. Moreover, in improved cIEF method, the isoelectric points (pI) of each isoform can be calculated and used for identification. It was also the first time that the cIEF method was fully validated for rhuEPO analysis according to the International Conference on Harmonization (ICH) guidelines.     

Improved capillary isoelectric focusing method for recombinant erythropoietin analysis

Human erythropoietin (EPO) is an endogenously produced glycoprotein, which plays a key role in the erythropoiesis process. Production of erythropoietin by recombinant DNA techniques has made possible its therapeutical use besides its misuse in sport competitions. The link between glycosylated form and protein activity makes necessary a method to analyze the glycoforms' distribution in the recombinant products. In this work, a capillary isoelectric focusing (cIEF) method is presented that allows the analysis of erythropoietin glycoforms. Besides, the cIEF method can be easily implemented in different laboratories. In order to get a feasible and precise cIEF method the following factors have been studied and optimized: (i) neutral coated capillaries, 27 cm long are employed, (ii) ampholytes in the pH range 2 to 10 are used, (iii) bovine beta-lactoglobulin A is chosen as internal standard, (iv) anolyte consisting of 91 mM H3PO4 in cIEF gel is made by weight and catholyte is prepared by titrating 20 mM NaOH with H3PO4 to pH 11.85-11.90, (v) sample is completely depleted of excipients and sodium chloride 10 mM final concentration is added, and (v) t(n)/t(I.S.) and (A(n) - A(I.S.))/A(I.S.), n being the recombinant EPO glycoform considered and I.S. the internal standard, are chosen as indexes to express migration time and area. As a result, a precise method to analyze erythropoietin by capillary isoelectric focusing is achieved with intra-assay RSD < or = 0.5% for index time and < or = 1.5% for index area and inter-sample, inter-anolyte, and inter-catholyte precision better than 3.4% for index time and RSD lower than 2.2% for index area.     

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.     

A high-resolution capillary isoelectric focusing method for the determination of therapeutic recombinant monoclonal antibody

Capillary isoelectric focusing (CIEF) is a common choice for separation and analysis of the charge variants and impurities of therapeutic proteins. In this study, we developed a sensitive CIEF analysis method for determining the charge heterogeneity of therapeutic monoclonal antibody (mAb) using Beckman PA800 plus platform. The mixture of 5% Pharmalyte 8-10.5 and 1% Pharmalyte 3-10 was used to overcome the limitation of using single Pharmalyte 3-10 in detecting charge heterogeneity of basic mAb. This approach largely improved the resolution of the heterogeneous peaks. In addition, 3 M urea and 50 mM arginine (Arg) were used to improve the separation as solubilizer and cathodic stabilizer, respectively. Under optimized condition, both acidic and basic peaks of the mAb were separated well. Method qualification results showed good specificity, precision, and linearity within the concentration range of 0.03-0.20 mg/mL for mAb R1. The method was then used for C-terminal lysine (Lys) variants characterization and glycosylation profiles analysis. Furthermore, it also had a wide application in the clone screening process. The highly sensitive and repeatable results highlighted the wide application prospects of this method in biopharmaceutical industry.     

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.     

Use of full-column imaging capillary isoelectric focusing for the rapid determination of the operating conditions in the preparative-scale continuous free-flow isoelectric focusing separation of enantiomers

A rapid, simple method is proposed here for the identification of the experimental conditions that lead to satisfactory preparative-scale isoelectric focusing enantiomer separations in continuous free-flow electrophoretic units. The method first calls for the use of a commercially available, full-column imaging capillary electrophoretic system to find the background electrolyte composition that generates the largest pI difference between the bands of the enantiomers. The method then calls for the finding of the minimum residence time that permits full development of the pH gradient across the separation chamber of the continuous free-flow electrophoretic unit by measuring the pH in the sample-free carrier electrolyte fractions collected during these runs. Finally, the quality of the predicted preparative-scale separation is verified by analyzing the enantiomer-containing collected fractions by capillary electrophoresis using a 14-sulfated, single-isomer cyclodextrin as resolving agent. The pI difference values and production rate values observed in this work agree well with the literature values that were obtained by much more time-consuming methods.     

Recent applications of capillary isoelectric focusing

After the advent of capillary isoelectric focusing (CIEF) in the 80's several approaches have been developed in order to use the technique in routine analyses. The recent years showed an extensive increase in the applications of this technique employing its exceptionally high-resolution power. Methodological improvements, as well as hyphenation with other electrophoretic and chromatographic separation procedures, proved the versatility of CIEF in studies of clinically important proteins, recombinant product, cell lysates and other complex mixtures. The combination of CIEF with mass spectrometry detection is one of the major challenges for studying proteomics. This review collected the recent applications of CIEF including innovations in the experimental setup, remedies for the presence of salts in samples, calibration of the pH gradient, carrier ampholyte-free isoelectric focusing, the progress in micropreparation, two-dimensional separations, etc.     

Miniaturization of capillary isoelectric focusing.

Miniaturization of whole-column imaging capillary isoelectric focusing (CIEF) is discussed. A 1.2 cm capillary was used as a separation column for CIEF. The experimental results for the analysis of two pI markers and the protein myoglobin showed that good CIEF separation results could be obtained. Secondly, a light-emitting diode (LED) was used as the light source for the whole-column absorbance imaging detection. The focusing of both the pI markers and myoglobin were observed with the LED light source. The whole-column imaging CIEF instrument was simplified and miniaturized by the use of the LED. Further developments are also discussed.     

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.     

Fractionation of glycoforms of recombinant human erythropoietin by preparative capillary isotachophoresis

This feasibility study deals with the use of preparative capillary isotachophoresis (CITP), operating in a discontinuous fractionation mode, to the separations and isolations of glycoforms of recombinant human erythropoietin (rhEPO). The preparative CITP separations were monitored by capillary zone electrophoresis (CZE) with a hydrodynamically closed separation unit. Such a CZE system, suppressing fluctuations of the migration data linked with fluctuations of EOF and hydrodynamic flow, made possible to evaluate and compare the preparative CITP separations performed within a longer time frame. Preparative CITP, carried out in the separation unit with coupled columns of enhanced sample loadability, separating 100 microg of rhEPO in a run lasting ca. 30 min, gave the production rate higher than 55 ng/s for the rhEPO glycoforms. The preparative separations included valve isolations of the glycoforms from the ITP stack into four or six fractions. Such numbers of the fractions corresponded to typical numbers of the major glycoform peaks as resolved in CZE of rhEPO. With respect to close effective mobilities of the glycoforms and a multicomponent nature of rhEPO, the fractions contained mixtures of glycoforms with the dominant glycoforms enriched 10-100-fold, relative to the original rhEPO sample.     

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.     

Validation of a capillary isoelectric focusing method for the recombinant monoclonal antibody C2B8

A capillary isoelectric focusing (cIEF) method has been developed for the purpose of determining the identity and charge distribution of mouse/human chimeric antibody to human CD20 antigen (C2B8). The assay was validated in accordance with ICH guidelines in order to demonstrate that it is suitable for its intended purpose and so that it may be performed as a lot release test for bulk and final product. As a result of the validation process the assay was found to be linear over the concentration range of 2–356 μg ml⁻¹ with recovery of ¹²⁵I-labeled C2B8 at the target sample concentration of 125 μg ml⁻¹ equal to 99%. The repeatability and intermediate precision relative standard deviations of the four major peaks for migration time, peak area, and peak area percent ranged from 0.9–4.4%. The specificity of the assay was demonstrated by baseline resolution of the C2B8 main peak from product excipients, and other Genentech monoclonal antibodies. The results of this validation demonstrate that the cIEF assay for the determination of identity and charge distribution of C2B8 is accurate, precise, linear, and highly specific. The assay is rapid and suitably rugged.     

One-step capillary isoelectric focusing of the proteins in cerebrospinal fluid and serum of patients with neurological disorders

One-step capillary isoelectric focusing (cIEF), which uses reduced but non-zero electroosmosis flow to mobilize the focused proteins, was applied to the analysis of proteins in cerebrospinal fluid (CSF) and serum of patients with various neurological disorders. Under the conditions employed, pathological changes in the CSF proteins were clearly detected on the electropherograms within 25 min, although the serum proteins did not vary significantly between samples. The present one-step cIEF system seems to be useful in routine laboratory examinations of a large number of CSF samples as an aid in neurological diagnosis.     

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.     

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.     

Preparation of a capillary isoelectric focusing column with monolithic immobilized pH gradient and its application on protein separation based on an online capillary isoelectric focusing platform

In the presence of methanol and n‐decanol as porogens, a partially filled capillary monolithic column was prepared by in situ reaction of glycidyl methacrylate and poly (ethylene glycol) diacrylate. Then, Pharmalyte 3–10 was immobilized on this column in order to obtain a capillary isoelectric focusing (cIEF) column with monolithic immobilized pH gradient (M‐IPG). In addition, an online self‐built platform for protein separation was established on account of the introduction of a cross‐shaped unit and two short‐off valves. In this platform, a cross‐shaped unit was not only used to join the M‐IPG column and a six‐way injection valve (1.5 μL sample loop), but also to supply a volume pool of anode buffer so that the process of injection, focusing and mobilization of samples could be sequentially performed. The short‐off valve in the tee unit or cross‐shaped unit could be used to control the direction of the fluid flow. Using this online cIEF platform and under the optimized conditions, 7‐proteins mixture could be separated and a good linear correlation between pI values and migration times was obtained by the M‐IPG column. Meanwhile, based on the online cIEF platform, human serum proteins and a mixture of Hb A and Hb A_1c have been successfully resolved with the newly developed M‐IPG column.     

Two-dimensional separation system by on-line hyphenation of capillary isoelectric focusing with pressurized capillary electrochromatography for peptide and protein mapping

A novel on-line 2-D system was developed for peptide and protein mapping. The system combines capillary IEF (cIEF) with pressurized CEC (pCEC) using a micro-injection valve as the interface. Sample fractions, which were focused and separated in the first-dimension cIEF based on their differences in pIs, were electrically mobilized and further successively resolved by their differences in size, hydrophobicity, and electrophoretic mobility in the second-dimension pCEC. In the presented system, the valve interface was free of the external electric field in two dimensions for the purpose of stabilization, safety, and facilitating manipulation. In the first dimension, cIEF separation was executed by a one-step method to simplify the operation procedure. Moreover, a home-made electrical decoupler was introduced to isolate the micro-injection valve from the cIEF electric field. For the second dimension, taking advantage of the combination of hydrodynamic flow with EOF, reversed-phase pCEC not only offers on-column refocusing the effluent fractions, but also brings enhanced separation resolution and elution speed. Separation effectiveness of this 2-D system was demonstrated by the analysis of tryptic digest of BSA and human red blood cell lysate. A theoretical peak capacity of approximately 24,000 has been achieved for BSA digest, which proves its promising potential for the application in proteomics.