Study on stability mechanism of immobilized pH gradient in isoelectric focusing via the Svensson-Tiselius differential equation and moving reaction boundary.

An immobilized pH gradient (IPG) has strong power against instability (e.g., drifting and plateau) existing in classic isoelectric focusing (IEF). However, the relevant mechanism against the instability of pH gradient is still unclear. In this work, the theories of diffusional current and water products in IEF were developed based on the Svensson-Tiselius's differential equation and concept of moving reaction boundary (MRB). Two novel methods of pH gradient mobilization in IPG-IEF and non-IPG-IEF (opposite to IPG-IEF) were developed to unveil stability mechanism of IPG-IEF. The theoretical and experimental results indicated that (i) the drifting of pH gradient in non-IPG-IEF could be effectively controlled by IPG technique due to the existence of equal-fluxes of hydroxyl and hydrogen ions in the IPG-IEF system, (ii) there existed high diffusional current in non-IPG-IEF because of the existence of free carrier ampholyte (CA), but weak current in the IPG-IEF due to the immobilization of CA species in gel matrix, and (iii) the high diffusional current resulted in a great amount of water formation in neutral zone of pH gradient that led to distinct plateau in non-IPG-IEF, conversely the weak diffusional current caused little of water formation and weak plateau of pH gradient in IPG-IEF. These studies have considerable significance to the understanding of mechanism and development of protein IEF separation technique.

Phase separation and crystallization of hemoglobin C in transgenic mouse and human erythrocytes.

Individuals expressing hemoglobin C (beta6 Glu-->Lys) present red blood cells (RBC) with intraerythrocytic crystals that form when hemoglobin (Hb) is oxygenated. Our earlier in vitro liquid-liquid (L-L) phase separation studies demonstrated that liganded HbC exhibits a stronger net intermolecular attraction with a longer range than liganded HbS or HbA, and that L-L phase separation preceded and enhanced crystallization. We now present evidence for the role of phase separation in HbC crystallization in the RBC, and the role of the RBC membrane as a nucleation center. RBC obtained from both human homozygous HbC patients and transgenic mice expressing only human HbC were studied by bright-field and differential interference contrast video-enhanced microscopy. RBC were exposed to hypertonic NaCl solution (1.5-3%) to induce crystallization within an appropriate experimental time frame. L-L phase separation occurred inside the RBC, which in turn enhanced the formation of intraerythrocytic crystals. RBC L-L phase separation and crystallization comply with the thermodynamic and kinetics laws established through in vitro studies of phase transformations. This is the first report, to the best of our knowledge, to capture a temporal view of intraerythrocytic HbC phase separation, crystal formation, and dissolution.

Separation of hemoglobin variants with similar charge by capillary isoelectric focusing: value of isoelectric point for identification of common and uncommon hemoglobin variants.

Clinical assays for the primary evaluation of congenital hemoglobin (Hb) disorders must detect and identify a variety of Hb variants. We analyzed hemolysates containing Hb variants with similar charge to evaluate the diagnostic sensitivity and specificity of automated capillary isoelectric focusing (CIEF). Peak separation was observed for each variant in samples containing Hb S, D, and G. The calculated isoelectric points (pI) of these variants were significantly different such that each could be identified in a single run with pI as the sole criterion of identification. The pI of Hb C was significantly different from that of Hb E, C-Harlem, and O-Arab. Hb E, C-Harlem, and O-Arab had similar pI and were not readily differentiated. Hb Koln, M-Saskatoon, Aida, and S/Aida hybrid were readily separated from common Hb variants and detected by CIEF. We conclude that CIEF exhibits both diagnostic sensitivity and specificity, and that pI is an objective and specific criterion of Hb variant identification.

Crystallization of recombinant hemoglobins with basic amino acid substitutions (Lys and Arg) at the beta 6 position.

We have produced recombinant hemoglobins (rHbs) alpha 2 beta 2(6Glu-->Lys) (rHb beta E6K) and alpha 2 beta 2(6Glu-->Arg) (rHb beta E6R) using a yeast expression system coupled with a polymerase chain reaction (PCR)-based mutagenesis strategy for studies focused on defining determinants that facilitate crystallization of Hb C (alpha 2 beta 2(6Lys)). rHb beta E6K had the same electrophoretic mobility as native human Hb C, whereas rHb beta E6R migrated slightly slower than Hb C on cellulose acetate electrophoresis. The carbonmonoxy (CO) forms of rHb beta E6K and rHb beta E6R formed tetrahedral crystals in vitro in 2.3 mol/L phosphate buffer just like native Hb C. The Hb concentration required for crystallization of CO-rHb beta E6R was lower than that of CO-rHb beta E6K, suggesting that stronger basic amino acids at the beta 6 position accelerate crystallization of Hb. However, the size of rHb beta E6R crystals was smaller than that of rHb beta E6K. Crystallization of native Hb C and both rHbs was inhibited by Hb F. These results suggest that alpha 2 beta gamma-heterohybrids that have basic amino acids at the beta 6 position behave similarly and are unable to crystallize like Hb C.

[Separation of hemoglobins F, Fac, S, C, A1c and determination of hemoglobin F using high performance liquid chromatography]. / Séparation des hémoglobines F, Fac, S, C, A1c et dosage de l'hémoglobine F par chromatographie liquide haute performance.

Separation of hemoglobins F, Fac, S, C and A1c was performed using high performance liquid chromatography with a cation exchange Polycat A column in a 15-minute assay. HbF titration results were well correlated with those of the reference alkali denaturation technique for values below 12% (r = 0.95; P < 0.001). This technique may be used as a confirmation test for neonatal screening of sickle cell disease.

Rapid analysis of hemoglobin variants by cation-exchange HPLC.

We investigated the use of a 3.5 x 0.46 cm HPLC column packed with 5-microns particles of porous (100 nm) silica coated with polyaspartic acid for hemoglobin analysis. A 13-min gradient was produced between two mobile phases. The method is capable of separating more than 35 commonly encountered hemoglobin variants within 12 min. Hemoglobin variants identified include Bart's, acetyl F, H, A1c, F, Camden, N-Baltimore, J-Baltimore, N-Seattle, Grady, Fannin-Lubbock, A G-Georgia, Lepore-Baltimore, P-Galveston, G-Coushatta, Lepore-Boston, E, Osu Christiansborg, A2, G-Philadelphia, Korle Bu, Russ, Richmond, D-Los Angeles, Deer Lodge, Montgomery, S, Q-Thailand, G-San Jose, A2', Hasharon, Q-India, Tampa, GS hybrid, C-Harlem, O-Arab, British Columbia, and C. Between-run precision of an in-house pooled hemoglobin control material, AFSCA2, gave CVs of 2-5% for the A, F, S, and C and 8% for the A2 over a 6-month period. The simplicity of sample preparation, high resolution of the system, and high accuracy of the method, combined with complete automation, make this an ideal methodology for the routine diagnosis of hemoglobin disorders in a clinical laboratory.

Acceleration of hemoglobin C crystallization by hemoglobin S.

We previously reported that circulating hemoglobin (Hb) CC erythrocytes contain oxygenated HbC crystals with little or no HbF and that HbF inhibits in vitro crystallization of HbC. We now report that HbS accelerates in vitro crystallization of HbC. Crystals were formed in 1.8 mol/L potassium phosphate buffer, pH 7.4, at 30 degrees C and were counted in several time intervals with a hematocytometer. The hemoglobin composition of Millipore-isolated crystals and supernatant were also analyzed. Under the conditions selected, 100% HbS formed needle-shaped crystals only after two hours. Pure HbC does not form crystals within 15 minutes, whereas a ratio of 10% HbS:90% HbC forms 1,100 crystals/mm3, 20% HbS:80% HbC forms 370 crystals/mm3, and 30% HbS:70% HbC forms 5 crystals/mm3. Crystals formed in the presence of HbS are tetragonal, as are pure HbC crystals. As compared with 100% HbC, HbA or albumin mixed with HbC showed a decreased number of crystals as a result of dilution. Analysis of the Hb content of isolated crystals by citrate agar gel electrophoresis showed that HbS was rapidly incorporated into the crystal in the same ratio over time. These results demonstrate that HbS accelerates crystallization of HbC with respect to the rates of crystallization of any of these two Hbs separately, through a mechanism that involves cocrystallization. These results may be significant in understanding SC disease.

Rapid cation-exchange high-performance liquid chromatographic procedure for the separation and quantitation of hemoglobins S, C, and O Arab in cord blood samples.

A rapid method for separating and quantitating hemoglobin (Hb) variants in cord blood samples using cation high-performance liquid chromatography (HPLC) is described. The procedure is a modification of a previously published method, and uses a weak cation-exchange Brownlee-3CM column and Bis-Tris-KCN-Na acetate developers. A chromatogram can be completed in 10 minutes. The slow-moving variants, Hbs S, C, and O Arab, can be completely separated from each other and are identified by their elution times relative to Hb A. Hb E elutes as a shoulder on the descending side of Hb A, which is characteristic for this variant in this procedure. Differentiation between heterozygous, homozygous, and Hb X-beta+-thalassemia conditions is easily made.

The estimation of Hb A2 in the presence of Hb C or Hb E by reverse phase high performance liquid chromatography.

Although Hb-C may be separated from Hb A2 by some ion exchange methods, most will not separate Hb E and Hb A2. The delta chain can be readily separated from the beta C, beta E and beta O-Arab chains by reverse phase HPLC. Hence, reverse phase HPLC provides a means of quantitatively determining Hb A2 in the presence of Hb C, Hb E, and Hb O-Arab. The procedure, although not highly accurate, does permit the detection of increased Hb A2, for example, in beta-thal heterozygotes and, therefore, is applicable to other conditions (Hb C, Hb E, Hb O-Arab).

[Abnormal hemoglobins identified in Martinique]. / Hémoglobines anormales identifiées à la Martinique.

Epidemiologic programs in Martinique during the last 10 years and particularly the last 5, have allowed the determination of the Hb S, Hb C, beta thalassemia traits frequencies. A number of rare variants have been detected during the course of these screening programs. Many of these Hb variants have been analysed at the structural level. For some of them a pathologic interaction with Hb S is observed (Hb D Punjab, Hb O Arab...), and the use of electrophoretic mobilities obtained with the reference samples provides the basis of a rapid, highly probable presumptive identification and then, a useful tool, when for example genetic counselling is necessary.

Separation of asymmetrical hybrid hemoglobins by anaerobic cation-exchange high-performance liquid chromatography.

Asymmetrical hybrid hemoglobins formed from mixtures of two structurally different hemoglobins were found to be readily separated by cation-exchange high-performance liquid chromatography under anaerobic conditions. When oxyhemoglobins A and S were mixed and deoxygenated, the resulting HPLC chromatogram showed three peaks. The distribution of the three components follow the binomial expansion a2 + 2 ab + b2 = 1, where a and b are the initial fractions of parent hemoglobins. The middle peak was collected in a test tube saturated with CO gas and reanalyzed under the same experimental conditions. This middle component gave two peaks of equal areas with retention times identical to those of the CO-form of the parent hemoglobins without the appearance of the hybrid hemoglobin band. No intermediate peak was observed in solutions of mixtures of liganded hemoglobins under aerobic conditions. Hybrid hemoglobins AC and SC were also formed when oxyhemoglobins A and C,S and C were mixed, respectively. The separation and the identification of hemoglobins and hybrid hemoglobin employing cation-exchange HPLC can be achieved within 30 min by gradient elution. In addition, the ability to isolate hybrid hemoglobins may be a valuable tool for the study of physical and chemical properties of hybrid hemoglobins.

High-performance liquid chromatography of human hemoglobins on a new cation exchanger.

We have investigated the use of a high-performance liquid chromatographic (HPLC) column packed with a unique weak cation exchanger prepared by coating silica with poly(aspartic acid) for hemoglobin analysis. The complete separation of hemoglobin Bart's F, A0, A2, S, C, D, E, G, SG, Winnipeg and Sealy was achieved by gradient elution within 30 min. The high resolution made it possible to distinguish hemoglobin variants such as Bart's, AC, AD, AE, AG, AS, ASG, CC, SC, SS, Winnipeg, Sealy and beta-chain variants with thalassemia such as S/beta +, S/beta 0 and S(C)-beta + thalassemia. Comparison of DEAE-cellulose column chromatography and our HPLC method for the quantitation of hemoglobin A2 yielded a good correlation. Hemoglobins A2, C and E are completely resolved on PolyCAT A columns in contrast to both cellulose acetate electrophoresis and DEAE-cellulose column chromatography. The high resolution of the system and the accuracy of the method combined with complete automation make this procedure useful for diagnosis of hemoglobin disorders in both a research and clinical laboratory environment.

Automated zone electrophoresis--experiments and new concepts.

I have investigated various modalities of automation of zone electrophoresis. One system has already been previously described (U.S. Pat. No. 3,896,021). Other systems investigated can be divided into batch systems and one random-access system; the former involve separation on cellulose acetate that is supported on 0.127 mm thick polyester (Mylar) film in the form of tape, cards, or discs. Systems in which the separation is in a direction transverse to the long axis of the tape use a typical tape width of 7.5 cm; systems in which separation is longitudinal make use of supports of various widths, depending upon the assay rate desired. Concepts were also developed for a random-access systems for automated electrophoresis, which requires no start-up time. Small Lucite cassettes are used, one for each sample. Each cassette has one surface of either cellulose acetate or any of several gels used for electrophoretic separation. There are further small wells for sample and calibrator. The loaded cassette is inserted into an input queue that allows serial processing. The cassettes move sequentially through prewetting (if needed), sample application, electrophoretic separation, staining, and scanning. This system should also be suitable for automated isoelectric focusing.

Use of specific fluorescent antibodies for the identification of hemoglobin C in erythrocytes.

Antibodies against hemoglobulin C (alpha2beta2 6Glu leads to Lys) were produced by immunizing horses and were purified by affinity chromatography. As expected from the bivalency of both the antibody and the antigen, the purified antibodies failed to produce immunoprecipitates upon reaction with the corresponding antigens. Identification of hemoglobin C in individual erythrocytes was achieved by reacting the fluorescein isothiocyanate-conjugated antibodies with the hemoglobin antigen in fixed smears of peripheral blood. Red cells from persons having a hemoglobin C gene were labeled strongly upon reaction with anti-Hb C-FITC; there was no labeling of red cells containing normal hemoglobins or Hb S, suggesting that the anti-Hb C antibodies recognize only the amino-terminal segment of the beta chains that contain lysine in position beta6.

Activation of hemoglobin C synthesis in sheep marrow culture.

Erythropoietin preferentially stimulates hemoglobin C synthesis in suspension cultures of marrow cells from sheep homozygous for hemoglobin A; the amount of synthesis is dependent on the dose of erythropoietin and is blocked by antiserum to erythropoietin. The results provide the first in vitro evidence that erythropoietin mediates the hemoglobin A --> C "switch" in sheep and indicate that bone marrow cultures may be used to investigate the mechanisms involved in the preferential gene activation characteristic of the hemoglobin A --> C system.