Determination of glycosylated haemoglobin by isoelectric focusing in non-linear pH gradients

Capillary isoelectric focusing of proteins and microorganisms in dynamically modified fused silica with UV detection

We suggest a method for the reproducible and efficient capillary isoelectric focusing of proteins and microorganisms in the pH gradient 3-10. The method involves the segmental injection of the simple ampholytes, the solution of the selected electrolytes, and the sample mixture of bioanalytes and carrier ampholytes to the fused silica capillaries dynamically modified by poly(ethylene glycol), PEG 4000, which is added to the catholyte, the anolyte and injected solutions. In order to receive the reproducible results, the capillaries were rinsed by the mixture of acetone/ethanol between analyses. For the tracing of the pH gradients the low-molecular-mass pI markers were used. The simple proteins and the mixed cultures of microorganisms, Saccharomyces cerevisiae CCM 8191, Escherichia coli CCM 3954, Candida albicans CCM 8180, Candida parapsilosis, Candida krusei, Staphylococcus aureus, Streptococcus agalactiae CCM 6187, Enterococcus faecalis CCM 4224, Staphylococcus epidermidis CCM 4418 and Stenotrophomonas maltophilia, were focused and separated by the method suggested. The minimum detectable number of microbial cells was 5x10(2) to 1x10(3) with on-column UV detection at 280 nm.

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.

Detection of neutral and charged mutations in alpha- and beta-human globin chains by capillary zone electrophoresis in isoelectric, acidic buffers

A simple and reliable method, for screening for point mutations in alpha- and beta-human globin chains, is reported here, utilizing capillary zone electrophoresis in isoelectric, acidic buffers. A solution of 50 mM iminodiacetic acid (pI 2.23) containing 7 M urea and 0.5% hydroxyethylcellulose (apparent pH 3.2) is used as background electrolyte for fast separation of heme-free, denatured globin (alpha and beta) chains. Due to the low conductivity of such buffers, high voltage gradients (600 V/cm) can be applied, thus reducing the separation time to only a few minutes. In presence of neutral to neutral amino acid substitutions, it is additionally shown that the inclusion of 3% surfactant (Tween 20) in the sample and background electrolyte induces the separation of the wild-type and mutant chains, probably by a mechanism of hydrophobic interaction of the more hydrophobic mutant with the detergent micelle, via a mechanism similar to "micellar electrokinetic chromatography". At this low operative pH, however, charged mutants, involving substitutions of acidic amino acids (Glu and Asp) are not detected, since these residues are extensively protonated. Curiously, however, they are still separated in presence of detergent, due to the large variation in hydrophobicity involved in such mutations. Of the 19 mutants analyzed, all but one were resolved: Hb St Nazaire (beta 103 Phe-->Ile). This is due to the fact that the delta G (in kcal/mol) in the substitution Phe-->Ile is zero, thus no separation can possibly take place between two chains exhibiting the same hydrophobicity parameter.

Quantitation of glycated hemoglobins in human adult blood by capillary isoelectric focusing

A precise and reproducible method for assessment of glycated hemoglobin in human adult red blood cells is reported, based on capillary isoelectric focusing (IEF). In order to obtain baseline resolution between adult hemoglobin (Hb A) and its glycated form (Hb A1c), two species which differ by minute delta pI values, < 0.03 pH units, the following procedure was adopted: the focusing mixture consisted of 5% Ampholine, pH 6-8, 0.5% Pharmalyte, pH 3-10, 3% short-chain liquid polyacrylamide and an equimolar mixture of two "separators", 0.33 M beta-alanine and 0.33 M 6-aminocaproic acid. The last two compounds flatten the pH gradient in the pI region of the two Hbs, thus allowing full separation. Additionally, the Hb samples, instead of being pulse-loaded, are uniformly distributed in the background electrolyte. A longer capillary life-time is obtained if all nonbuffering ions are eliminated; thus, as catholyte, 50 mM Lys (pH 9.7) is utilized and as anolyte 50 mM acetic acid (pH 3.5) is adopted. The percentages of Hb A1c, as obtained by capillary IEF, are in good agreement (+/- 6%) with data obtained by one of the standard zone electrophoretic methods in clinical chemistry, i.e., the Helena REP Glyco gel system.

Protein analysis by isoelectric focusing in a capillary array with an absorption imaging detector

Isoelectric focusing (IEF) was successfully performed in capillary arrays with up to four capillaries. Separated proteins in the capillary array were detected by an UV absorption imaging detector. The whole analysis time for all samples in the capillary array was only 3 min due to the real-time imaging detector. The instrument was applied to analyse several protein samples including different human hemoglobin variants, myoglobin, transferrin, carbonic anhydrase and a monoclonal antibody to fluorescein. Because of good reproducibility of the focused pattern, unknown samples can be run simultaneously with a standard in the multichannel instrument and the components of unknown samples can be identified by comparing their zone positions to those of the standard. Minor components can be determined by the instrument in the presence of major components with 100 times higher concentrations in human hemoglobin samples. This instrument could be a powerful analytical tool for clinical analysis and for quality control in pharmaceutical companies.

An isoelectricfocusing method to detect hemoglobin variants in newborn blood samples including the beta-thalassemias

An isoelectricfocusing method has been developed to enable large scale screening of newborn blood for hemoglobinopathies. The method utilizes a thin layer agarose gel containing carrier ampholytes in the pH range 6-8. The gradient is non linear allowing increased resolution in the pH region 6.8-7.8 where most hemoglobin variants are isoelectric. The increased resolution between Hb A and Hb Fac enables screening for beta-thalassemia by densitometric analysis. By calculating the ratio of Hb A/Hb Fac or Hb F/Hb A it is possible to detect newborns heterozygous for beta(+)- or beta(0)-thalassemia. Structural variants, unresolved by other electrophoretic methods, are easily detected. Seventy-two samples can be analyzed on a single gel in 90 minutes. Traces of hemoglobin variants can be detected by a heme-specific stain requiring no destain step.

Cysteine adducts of human haemoglobin measured by isoelectric focusing in polyacrylamide gels with a non-linear pH gradient

The in vitro formation of adducts from human haemoglobin formed by alkylation with methyl-methanesulphonate, dimethyl sulphate and iodoacetamide was determined with isoelectric focusing in ultra-thin polyacrylamide gels with a non-linear pH gradient. The most important adduct seen in the gels was identified as HbA alkylated at the beta-93 cysteine. Influences of the chemical nature of the alkylating agents and of the biological environment are discussed. The method is suggested to be applicable to monitoring the biological effects of low, long-term exposure to mixtures of alkylating agents or of exposure to unknown compounds.

Nonenzymatically glycosylated proteins

Nonenzymatic glycosylation takes place in all proteins with a free-reacting lysine or valine in the presence of glucose. The formation of glycosylated plasma albumin, hemoglobin (Hb A1c), and skin collagen provides a diagnostic index of short- to long-term time-concentration of glucose in vivo. A wide range of assay methods are available, with affinity chromatographic, isoelectric focusing, and spectrophotometric methods providing the best accuracy and versatility. Glycosylated hemoglobin assays indicate glucose pressure over the previous 2 to 3 months and are of diagnostic value in general diabetic control, while glycosylated plasma albumin determinations are preferable in acute episodes in the life of a diabetic (e.g., pregnancy, infection, stress, trauma, surgery), since they provide an overview of changing blood glucose values of the previous 2 to 4 weeks. Glycosylated collagen estimations reflect tissue aging and are relevant in healing processes. Glycosylation alters the biologic activity of proteins, and these may relate to the manifold complications concomitant on the lifelong elevation of blood and tissue glucose in the diabetic (C6a). Assays for glycosylated hemoglobin have been routinely performed in clinical chemistry laboratories for a decade, and convenient determination for other nonenzymatically glycosylated proteins is proceeding apace.

Antenatal diagnosis of beta-thalassemia by isoelectric focusing in immobilized ph gradients

A new method for antenatal diagnosis of thalassemias is reported based on the analysis of the major Hb components of fetal cord blood, sampled at week 18 of pregnancy under ultrasonic guidance, by isoelectric focusing in immobilized pH gradients (IPG). In an IPG gel encompassing a pH 6.7-7.6 span, HbA and HbFac are separated by a distance nine times greater than in a conventional carrier ampholyte pH 6-8 gel and three times greater than in an ampholine gel with separators (an equimolar mixture of beta-alanine and 6-amino caproic acid). Band evenness (in terms of uniform protein concentration within a zone) and straightness (in terms of parallel alignment of the bands to the electrodes), because of insensitivity of IPG gels to salt distortions, allows for accurate and reproducible quantitation of HbF, -A, and -Fac levels. The possibility of greatly overloading IPG matrices in total Hbs increases the sensitivity of the technique to the detection of only 0.5% HbA in the total Hb mixture, the lower limit of conventional IEF being only 2.5% HbA. Of 15 fetuses from couples at risk analyzed in the region of Ozieri, three were found to be homozygous beta-thalassemic, eight heterozygous, and four normal with no false-positives or -negatives.

Detection of electrophoretically silent mutations by immobilized pH gradients

The detection of neutral amino acid mutants, by isoelectric focusing in immobilized pH gradients (IPGs), is exemplified by the separation of hemoglobin (Hb) Beirut (126 beta Val----Ala) from Hb A in a shallow pH 7.2-7.6 IPG gradient with 2% Ampholine pH 6-8. The mechanism of these separations appears to involve minute alterations in the pK values of ionizable groups bordering the mutation site, which are in turn reflected in tiny alterations in the net surface charge, delta pI. The delta pI values are of the order of 0.01 to 0.001 pH units, outside the resolving limits of conventional isoelectric focusing, and correspond to changes of the order of 0.1-0.01 unit charge (a proton or an electron).

Electrophoretic and chromatographic techniques for the differential diagnosis of a haemoglobin abnormality: Hb E heterozygosity

A method is described for separating haemoglobin (Hb) E (beta 26 Gly----Lys) from Hb A2 (a normal minor Hb component in adult blood). The technique allows the distinction between subjects carrying beta-thalassaemia trait and patients who are simultaneously alpha-thalassaemic and heterozygous for Hb E, the standard electrophoretic pattern often being similar in these two circumstances. Complete separation between Hb E and Hb A2 (2 mm empty space in between) is obtained by isoelectric focusing in immobilized pH gradients in an ultra-narrow pH 7.55-7.65 gradient. The apparent pI values of the two species (at 10 degrees C and at an average ionic strength of 5.6 mequiv. l-1) have been calculated to be 7.603 for Hb E and 7.607 for Hb A2. Thus, the system reported here affords a resolution of at least 0.004 pH unit.