The solubility of sickle and non-sickle hemoglobins in concentrated phosphate buffer.

A new turbidimetric method for the direct measurement of the solubility of oxy- and deoxyhemoglobins (Hb) in concentrated phosphate buffer has been established. The principle of the method is the formation of a homogeneous emulsion when hemoglobin is introduced in concentrated phosphate buffer. The solubility of the oxy and deoxy forms of Hb A, Hb S, Hb C, Hb F, and Hb CHarlem (beta 6Glu leads to Val, beta 73Asp leads to Asn) has been studied. The solubility of deoxy-Hb S was the lowest and the solubility curve was broader than those of the other hemoglobins indicating that the aggregates of deoxy Hb S require more water to be dissolved. The solubility of oxy- and deoxyhemoglobins depends on temperature and pH. The solubility of hemoglobins is increased as the temperature is lowered and the pH is raised. The pH dependency of the solubility of deoxy-Hb S in high phosphate buffer was opposite to that of the minimum gelling concentration of deoxy-Hb S. The order of the solubility of Hb CHarlem, Hb FS, Hb AS, Hb CS, and Hb S in concentrated phosphate buffer corresponds to the order of minimum gelling concentration of these hemoglobins or hemoglobin mixtures. Solubility studies of a 1:1 mixture of deoxy-Hb A and deoxy-Hb S show that deoxy-Hb A aggregates in 2.42 M phosphate buffer in which pure deoxy-Hb A is totally soluble. This result indicates that deoxy-Hb S interacts with deoxy-Hb A and decreases its solubility.     

Effect of amino acid at the beta 6 position on surface hydrophobicity, stability, solubility, and the kinetics of polymerization of hemoglobin. Comparisons among Hb A (Glu beta 6), Hb C (Lys beta 6), Hb Machida (Gln beta 6), and Hb S (Val beta 6)

Surface hydrophobicity, stability, solubility, and kinetics of polymerization were studied using hemoglobins with four different amino acids at the beta 6 position: Hb A (Glu beta 6), Hb C (Lys beta 6), Hb Machida (Gln beta 6), and Hb S (Val beta 6). The surface hydrophobicity increased in the order of Hb C, Hb A, Hb Machida, and Hb S, coinciding with the hydrophobicity of the amino acid at the beta 6 position. Solubility of the oxy-form of these hemoglobins decreased in relation to increases in their surface hydrophobicity, suggesting that the solubility is controlled by the strength of hydrophobicity of the amino acid at the beta 6 position. The solubility of the oxy-form of these hemoglobins is always higher than that of the deoxy-form. There is a similar linear relationship between the solubility and surface hydrophobicity among deoxyhemoglobins A, C, and Machida. However, the solubility of deoxy-Hb S deviated significantly from the expected value, indicating that the extremely low solubility of deoxy-Hb S is not directly related to the hydrophobicity of the beta 6 valine. Kinetic studies on the polymerization of deoxy-Hb Machida revealed a distinct delay time prior to polymerization. This confirms our previous hypothesis that beta 6 valine is not responsible for the delay time prior to gelation. The kinetics of the polymerization of 1:1 mixtures of sickle and non-sickle hemoglobins were similar to those of pure Hb S, suggesting that only one of the two beta 6 valines is involved in an intermolecular contact. In mixtures of equal amounts of Hb S and Hb A, Hb C, or Hb Machida, half of the asymmetrical AS, SC, and S-Machida hybrid hemoglobins behaved like Hb S during nucleation, while the other half behaved like the non-sickle hemoglobin.     

Effect of the beta 73 amino acid on the hydrophobicity, solubility, and the kinetics of polymerization of deoxyhemoglobin S

The role of Asp-beta 73 on the surface hydrophobicity and solubility of hemoglobin was studied using Hb A, Hb S, Hb C Harlem (alpha 2 beta 2Val-6,Asn-73), and Hb Korle Bu (alpha 2 beta 2Asn-73). The surface hydrophobicity of the oxy form of these hemoglobins increased in the order of Hb A, Hb Korle Bu, Hb S, and Hb C Harlem, coinciding with the change in solubility. The same is not true for deoxyhemoglobins. The solubilities of deoxy-Hb S and deoxy-Hb C Harlem were much lower than that expected from their surface hydrophobicity. Although the hydrophobicity of deoxy-Hb C Harlem is greater than that of deoxy-Hb S, the solubility of deoxy-Hb S is only one-third that of deoxy-Hb C Harlem. This deviation must be caused by the substitution of Asn for Asp at the beta 73 position and its inhibitory effect on hydrogen bonding in Hb S polymers. The kinetics of the polymerization of 1:1 mixtures of the deoxy form of S-C Harlem, A-C Harlem, Korle Bu-S, and Korle Bu-C Harlem were studied in comparison with that of deoxy-Hb S and deoxy-Hb C Harlem alone. All of these binary mixtures polymerized with a distinct delay time prior to polymerization. Based on the results of kinetic studies, the probability factors for nucleation of S-C Harlem, A-S, A-C Harlem, S-Korle Bu, and Korle Bu-C Harlem hybrid hemoglobins were calculated as 0.65, 0.5, 0.5, 0.15, and 0.17, respectively, in comparison with that of Hb S (1.0). The probability factor for Hb C Harlem alone was 0.3. These data suggest that the Asp-beta 73 is directly involved in nucleation during Hb S polymerization and that the beta 73 is always trans to the active Val-beta 6 in the formation of nuclei.     

Kinetics of the polymerization of hemoglobin in high and low phosphate buffers

Diluted solutions of deoxyhemoglobin S in concentrated phosphate buffer form aggregates or gels with a clear exhibition of a delay time. The aggregates can be liquified by cooling, bubbling with O2 or CO gas, or the dilution of phosphate buffer with water. These properties can be used as a simple method for studying the mechanism of polymerization and depolymerization of hemoglobins. The advantages of this method are: 1) The amount of hemoglobin sample required is only 1% to 5% of that required for the gelation of deoxy-Hb S in low phosphate buffer. 2) The kinetics can be measured turbidimetrically using an ordinary spectrophotometer. 3) The solubility of hemoglobin can be directly determined by taking the absorption spectrum of the supernatant solution after polymerization. 4) The polymer phase can be easily separated from the solution so that the amount and composition of the polymers can be analyzed. 5) The volume of the polymer phase is so small that excluded volume effect can be neglected. 6) The method can be applied to the study of polymerization of non-sickle hemoglobins and that of mixtures of sickle and non-sickle hemoglobins. The major question is whether the polymerization of hemoglobin in concentrated phosphate buffer is the same as that of deoxy-Hb S in low phosphate buffer. To answer this question, we studied the polymerization of Hb S, Hb A, Hb C Harlem, and Hb C in phosphate buffers of different molarities. We also studied the mechanism of the conversion of gels of these hemoglobins into crystals.     

Separation of asymmetrical hybrid containing hemoglobin F by anaerobic anion-exchange high-performance liquid chromatography

Asymmetrical hybrid hemoglobins formed from mixtures of oxyhemoglobins S and F and A and F were separated by high-performance liquid chromatography on a 4.6 X 250 mm wide-pore polyethyleneimine-silica gel column under anaerobic conditions. The resulting HPLC chromatogram showed three peaks, with the middle peak representing the hybrid hemoglobin. The areas of these three peaks were quantified and the amount of hybrids formed was less than that predicted theoretically. We found that the deviation was due to the equilibrium constant of the FS hybrid hemoglobin differing from that of the parent hemoglobins. In this report, we introduce the anaerobic recycle ion-exchange HPLC method to determine the rate of dissociation of AS and FS hybrid hemoglobins at constant pH buffer conditions. The results obtained by this method demonstrate that FS hybrid hemoglobin is more unstable than AS hybrid hemoglobin. The free energy of association for asymmetrical hybrids containing hemoglobin F is approximately 0.6 Kcal/mol greater than that of the symmetrical parent hemoglobins.     

Isolation of a trypsin inhibitor from Echinodorus paniculatus seeds by affinity chromatography on immobilized Cratylia mollis isolectins

A highly purified trypsin inhibitor was obtained from Echinodorus paniculatus when an extract prepared from E. paniculatus seed flour (25 gl(-1), with 0.1 M ammonium acetate buffer, pH 8.3, under agitation for 6 min at 28 degrees C) was chromatographed on Sephadex G-25 (12 mlh(-1)), followed by affinity chromatography on immobilized Cratylia mollis isolectins (Cra Iso 1,2,3-Sepharose). The column chromatography was performed at 24 degrees C; the matrix was washed (30 mlh(-1)) with 0.1 M sodium phosphate buffer, pH 7.4 or with the same buffer containing 0.2 M glucose, followed by application of inhibitor sample and elution with 0.015 M sodium borate buffer, pH 7.4, or 1.0 M NaCl. A purified fraction of inhibitor was obtained by gel filtration chromatography (GF-450/HPLC column). Trypsin inhibitory activity was eliminated when the inhibitor was treated with metaperiodate showing that the carbohydrate moiety was important for trypsin inhibition. Binding of inhibitor was also evaluated on immobilized concanavalin A (Con A-Sepharose) using previously described chromatographic conditions with results similar to Cra Iso 1,2,3-Sepharose chromatography.     

Relative hydrophobicity of amino acid residues in homooligopeptides as measured by aqueous two-phase partitioning.

Partitioning of 17 amino acids and their homooligopeptides of different lengths in an aqueous dextran-PEG two-phase system containing 0.15 m NaCl in 0.01 M sodium phosphate buffer, pH 7.4 and 0.11 m sodium phosphate buffer, pH 7.4 was examined. The relative hydrophobicity of the amino acid residues was estimated and expressed in equivalent numbers of methylene units. Analysis of the data shows that the additivity principle does hold for the hydrophobicity of homooligopeptides. The relative hydrophobicity of essentially all amino acid residues is noticeably affected by the ionic composition of aqueous media.     

Hemoglobin Tarrant: alpha126(H9) Asp leads to Asn. A new hemoglobin variant in the alpha1beta1 contact region showing high oxygen affinity and reduced cooperativity.

Hemoglobin (Hb) Tarrant was detected by its electrophoretic mobility on cellulose acetate (pH 8.4) and citrate agar (pH 6.2). On cellulose acetate it moved as a band between hemoglobins F and S, and on citrate agar as a band at hemoglobin S. The test for solubility in 2 M phosphate buffer with Na2S2O4 was negative. The new variant has a substitution of asparagine for aspartic acid in position 126 of the alpha-chain, one of the sites involved in the alpha1beta1 contact. Furthermore, in deoxyhemoglobin aspartic acid 126 of each alpha chain also forms a non-covalent electrostatic salt bridge with arginine 141 of the corresponding alpha chain (Perutz, M. F. and Ten Eyck, L. F. (1972) Cold Spring Harbor Symp. Quant. Biol. 36, 295-310 and Perutz, M. F. (1970) Nature 228, 726-739). As a consequence of this substitution in hemoglobin Tarrant, the deoxy conformation or T state is destabilized because these two bridges cannot be formed. This condition is reflected in high oxygen affinity and low cooperativity.     

Aggregation of normal and sickle hemoglobin in high concentration phosphate buffer

Sickle cell disease is caused by a mutant form of hemoglobin, hemoglobin S, that polymerizes under hypoxic conditions. The extent and mechanism of polymerization are thus the subject of many studies of the pathophysiology of the disease and potential treatment strategies. To facilitate such studies, a model system using high concentration phosphate buffer (1.5 M-1.8 M) has been developed. To properly interpret results from studies using this model it is important to understand the similarities and differences in hemoglobin S polymerization in the model compared to polymerization under physiological conditions. In this article, we show that hemoglobin S and normal adult hemoglobin, hemoglobin A, aggregate in high concentration phosphate buffer even when the concentration of hemoglobin is below the solubility defined for polymerization. This phenomenon was not observed using 0.05 M phosphate buffer or in another model system we studied that uses dextran to enhance polymerization. We have used static light scattering, dynamic light scattering, and differential interference contrast microscopy to confirm aggregation of deoxygenated and oxygenated hemoglobins below their solubility and have shown that this aggregation is not observable using turbidity measurements, a common technique for assessing polymerization. We have also shown that the aggregation increases with increasing temperature in the range of 15 degrees -37 degrees C and that it increases as the concentration of phosphate increases. These studies contribute to the working knowledge of how to properly apply studies of hemoglobin S polymerization that are conducted using the high phosphate model.     

Aggregation of deoxyhemoglobin S at low concentrations.

The self-association of deoxyhemoglobin S was measured in dilute solutions (0 to 5 g/dl) by Rayleigh light scattering at 630 nm and osmometry in 0.05 M potassium phosphate buffer (pH 7.35). Weight and number average molecular weights (Mw and Mn, respectively) and the second or higher virial coefficients, B' were determined. No experimentally significant differences were observed between oxy- and deoxy-Hb S up to the concentration of 2 g/dl; their apparent average molecular weights were within experimental error. Above that concentration, both Mn and Mw of deoxy-Hb S were significantly different from that of oxy-Hb S. The negative second viral coefficent of deoxy-Hb S, observed by both techniques, is consistent with the self-association of this protein. The lack of effect of 0.4 M propylurea on the state of aggregation and the significant influence of 0.1 M NaCl suggests that polar interactions are involved in formation of these aggregates.     

DETECTION OF LISTERIA MONOCYTOGENES BY ADSORPTION AND ELUTION FROM HYDROPHOBIC MATRICES

The binding of L. monocytogenes Scott A strain to three hydrophobic matrices, octyl, phenyl and butyl Sepharose, was investigated. Optimal adsorption of L. monocytogenes to octyl Sepharose was obtained at pH 3.5 and 4 M NaCl. However, it was difficult to elute the bacteria from octyl Sepharose, even after changing the pH and lowering the salt concentration. Good adsorption of L. monocytogenes to phenyl Sepharose at pH 3.5 and 4 M NaCl was also observed. L. monocytogenes was found to adsorb weakly to butyl Sepharose, which is less hydrophobic than phenyl Sepharose. Bacteria were eluted under various conditions. The best elution was obtained with 10 mM sodium phosphate, followed by an increasing gradient of ethylene glycol. To test the potential application of hydrophobic chromatography for separating L. monocytogenes from food matrices, milk was inoculated with L. monocytogenes and then passed through a column of phenyl Sepharose at pH 3.5 and 4 M NaCl. Nearly all L. monocytogenes were bound to the hydrophobic gel and were eluted in a pure and viable form by changing the pH and lowering the salt concentration, and by using a polar reducing agent, ethylene glycol. This study shows that hydrophobic interaction chromatography can be used to separate L. monocytogenes from milk and may be applicable to other food suspensions. It is a gentle method that makes use of the hydrophobic surface properties of Listeria for attachment to hydrophobic gels, as well as using mild elution conditions to avoid inactivation of the organism.     

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.     

Unfolding and release of heme from human hemoglobins A,S and F

• 1.1. Analysis of the Soret spectra of hemoglobins A, S and F has been used to determine the extent of heme exposure and release from these hemoglobins in the presence of several solvent perturbants.
• 2.2. Oxyhemoglobin S unfolding in the presence of either urea or propyl urea resulted in greater heme exposure and release than either oxyhemoglobins A or F.
• 3.3. Methemoglobin formation resulted in lower denaturation midpoints for each hemoglobin compared to the reduced oxyhemoglobin state; methemoglobin F had the lowest denaturation midpoint under isothermal denaturing conditions.
• 4.4. Rate of heme exposure was greater for oxyhemoglobin S than oxyhemoglobin A in the presence of 200 μM the anionic detergent sodium dodecyl sulfate.
• 5.5. Evidence for increased levels of heme release in hemoglobin S may be related to the greater tendency of sickled red cell membranes to undergo lipid oxidation.

     

蛋白质表面疏水性的研究

用Ｐｈｅｎｙｌ－ＳｕｐｅｒｏｓｅＨＲ５／５疏水柱在ＦＰＬＣ仪上测定了一些蛋白的表面疏水性。在被测量的蛋白样品中,细胞色素Ｃ的亲水性最强,胰凝乳蛋白酶的疏水性最强。说明蛋白质的疏水性与其表面性质密切相关,而与蛋白质的分子量、疏水残基总数并不直接相关;去辅基细胞色素Ｃ和Ｃ端缩短的金黄色葡萄球菌核酸酶与天然态比较疏水性变化很大。疏水柱层析还用于监测在低浓度胍的作用下蛋白质的构象变化。以Ｎ－乙酰酪氨酸为模型化合物探测盐酸胍对疏水柱结合能力的影响,在０４Ｍ胍存在时,Ｎ－乙酰酪氨酸在疏水柱上的结合能力略有减弱,但核糖核酸酶Ａ的变化较大,表明胍引起的蛋白质的微小构象变化有效地引起其表面性质的变化;在０．１—０．３Ｍ盐酸胍存在时,甘油醛－３－磷酸脱氢酶表面疏水性明显增大,并伴随聚合态的出现。说明在低胍作用下,酶分子发生的构象变化,导致天然态内埋疏水面的暴露,暴露的疏水面间的相互作用是形成聚合的主要原因。     

The effect of structure and conformation on the relative hydrophobicity of dinucleosidephosphates and their analogs

Partition of a number of dinucleosidephosphates, their (2'-5')-isomers and a series of their analogues, in which the ribose ring was replaced by acyclic hydroxyalkyl substituents, in an aqueous biphasic ficoll--dextran system has been studied. Effect of the ionic composition of the biphasic system on partitioning of the compounds was examined. The relative hydrophobicity of the compounds in the presence of 0.11 M phosphate buffer, pH 7.4, and in the presence of 0.15 M NaCl in 0.01 M buffer, pH 7.4, was estimated. The results obtained are considered in regard to the effect of structure and conformation of a molecule on its affinity for an aqueous environment.     

Fractionation of plasma proteins using dye-ligand chromatography: elution profiles on immobilized green TSK-AF

The fractionation of human plasma by chromatography on immobilized Green TSK-AF was assessed by immunological analysis of the elution profiles of 27 different plasma proteins. A three-step procedure was used to elute proteins from the column. First a low-molarity buffer (30 mM sodium phosphate, pH 7.0, I = 0.053) was applied; then a linear salt gradient (0-1.0 M NaCl in the above buffer) was followed by an additional wash with four bed volumes of 1.0 M NaCl. Tightly bound proteins were finally stripped with 0.5 M NH4SCN. The elution profile of the proteins using this procedure appears to be very reproducible. Comparison with the profile obtained upon chromatography on Cibacron Blue 3GA [Gianazza, E. and Arnaud, P. (1982) Biochem. J. 201, 129-136] indicates significant differences between the binding properties of the two gels. These differences can be used to design a "tandem-chromatography" system which provides an efficient means for the separation of several plasma proteins.     

Relative hydrophobicity of surfaces of erythrocytes from different species as measured by partition in aqueous two-polymer phase systems

Erythrocytes from different species were subjected to partition in an aqueous, buffered Ficoll/Dextran two-phase system. The effects of different salt composition of the phase system on the distribution of erythrocytes was examined. Different ratios of sodium chloride to sodium phosphate buffer (pH 7.4) with the ionic strength varying from 0.176 to 0.288 M were used in the systems and similar relationship between the partition coefficients of the cells under study and the ionic strength were established. The relationships were treated according to a general equation previously established (Zaslavsky, B.Y., Miheeva, L.M., Metechkina, N.M., Pogorelov, V.M. and Rogozhin, S.V. (1978) FEBS Lett. 94, 77-80) and the results obtained were used to evaluate the relative hydrophobicity of the cells' surface.     

Aggregation of hemoglobin S modified by bifunctional imidoesters

Sickle hemoglobin (Hb S) was cross-linked by two types of bifunctional imidoesters, dimethyladipimidate (DMA) and dimethyl-3,3'-dithiobispropionimidate (DTBP). These modified hemoglobins were separated into monomer, dimer and polymer fractions by gel filtration. All of these modified hemoglobins showed extremely left-shifted oxygen equilibrium curves with no cooperativity. The stabilities of these hemoglobins were also decreased. The solubilities of these modified hemoglobins in high-phosphate buffers were lower than those of native Hb S. Studies on the kinetics of the aggregation of these modified hemoglobins showed that intracross-linked Hb S with DMA and DTBP (DMA- and DTBP-modified monomeric Hb S) still retained the capability of aggregation with a delay time, while intercross-linked Hb S with DMA and DTBP (DMA- and DTBP-modified oligomeric Hb S) aggregated without a delay time. When the kinetics of aggregation was measured for mixtures of modified and native deoxy-Hb S, DMA-modified monomeric deoxy-Hb S shortened the delay time prior to aggregation of native deoxy-Hb S. The other modified deoxy-Hb S did not affect the delay time, suggesting that these modified oligomeric hemoglobins neither participate in the formation of nuclei nor copolymerize with native deoxy-Hb S.     

Reversible solubility of deoxyhemoglobin S

The solubility of deoxyhemoglobin S in 1.96 M phosphate is sensitive to changes in oxygenation and temperature in a manner similar to the widely used $\text{in vitro}$ gelation assay. In addition, the pH of the phosphate buffer used in the solubility determination has a profound effect on deoxyhemoglobin S solubility. It is suggested that solubility in 1.96 M phosphate may be a sensitive method of monitoring the aggregation phenomenon of deoxyhemoglobin S.     

Solubility of palmitoyl-coenzyme A in acyltransferase assay buffers containing magnesium ions

The solubility of palmitoyl-CoA is strongly affected by Mg2+ concentrations commonly used in acyltransferase reactions. In 0.10 M Tris-HCl buffer at pH 7.4 or 8.5, all of the palmitoyl-CoA in 10 microM solutions and 90% of the palmitoyl-CoA in 100 microM solutions are precipitated by 1 mM Mg2+. In 0.05 M phosphate at pH 7.4, and in 0.10 M Tris-HCl containing 0.4 M KCl, the substrate remains soluble at Mg2+ concentrations below 4-5 mM. Above 5 mM Mg2+, palmitoyl-CoA is insoluble in all of these buffers. Substrate solubility could therefore be a limiting factor when free Mg2+ and fatty acyl-CoAs are present together during acyltransferase assays.