Binding of norgestrel to human plasma proteins.

Binding of [14, 15-3H](+/-)-norgestrel to human plasma proteins has been investigated. Norgestrel showed greater affinity to plasma than to human serum albumin indicating specific norgestrel binding protein(s) in the plasma. alpha1-acid glycoprotein showed high affinity for norgestrel when compared with human serum albumin. The binding protein was eluted at pH 5.8 by step by step elution on a DEAE-cellulose column. Norgestrel binding to plasma proteins was not affected at 60 degrees C. The optimal binding occurred between pH 7 and 8. Ligand specificity of the binding protein revealed that progesterone was able to compete for the norgestrel binding sites, whereas corticosterone, testosterone, oestradiol, and norethindrone acetate did not show much competition. The molecular weight of the binding protein was found to be approximately 43 000. Sucrose density gradient analysis indicated that norgestrel bound to a macromolecular component of sedimentation coefficient 2.9 S. The association constant (Kass) and dissociation constant (Kdiss) of norgestrel-binding plasma protein was found to be 1.4-10(6) M-1 and 0.7-10(-6) M respectively. The number of binding sites was 0.5-10(-9) mol/mg protein. Norgestrel-binding protein in the plasma appeared to be a protein different from human serum albumin, corticosteroid-binding globulin and sex-steroid-binding protein. This binding protein showed some similarities to alpha1-acid glycoprotein.     

Stability, pKa and plasma protein binding of roscovitine

In the present investigation, the binding of roscovitine (100, 500 and 1500 ng/mL) to plasma proteins was studied at 25 and 37 degrees C by ultrafiltration and equilibrium dialysis methods. Drug stability in plasma was assessed during a 48 h at 4, 25 and 37 degrees C. The effect of thawing and freezing on drug stability was studied. The pKa of roscovitine was measured using capillary electrophoresis coupled with mass spectrometry. Roscovitine was quantified utilizing liquid chromatography and tandem mass spectrometry. Roscovitine is highly bound to plasma proteins (90%). Binding of roscovitine to human serum albumin was constant (about 90%) within concentration range studied while the binding to alpha1-acid glycoprotein decreased with increasing drug concentration indicating that albumin is more important in clinical settings. However, alpha1-acid glycoprotein might be important when plasma proteins change with disease. Protein binding was higher at 25 degrees C compared to 37 degrees C. The results obtained by equilibrium dialysis were in good agreement with those obtained by ultrafiltration. Roscovitine was stable at all temperatures studied during 48 h. Roscovitine has a pKa of 4.4 showing that the drug mainly acts like a weak mono-base. The results obtained in our studies are important prior to clinical trials and to perform pharmacokinetic studies.     

The binding of silica to proteins from plasma and lungs of rat: in vitro

Silica dissolving out from the slate dust was found to bind with plasma protein and purified bovine serum albumin. At 24 h of incubation at 37 degrees C binding affinity of silica (microgram of silica bound/mg of protein) with plasma protein and bovine serum albumin was found to be 0.59 and 0.44, respectively. By molecular exclusion chromatography using Sephadex G-200, silica binding protein of plasma was determined to be of mol. wt. around 67000. Similar proteins having silica binding capacity (mol. wt. 70000 and 85000) were also found in rat lung but these proteins unlike their plasma counterpart were glycoprotein in nature. Polyacrylamide gel electrophoresis of plasma and protein rich lung fraction show that proteins upon binding with silica undergo mobility changes. Significance of the existence of silica binding protein in plasma and lung of rat in relation to silica toxicity is discussed.     

Protein binding and stability of norepinephrine in human blood plasma. Involvement of prealbumin, alpha 1-acid glycoprotein and albumin

The binding of norepinephrine (NE) to plasma proteins of fresh human blood obtained from healthy volunteers was studied by ultrafiltration at different NE concentrations and incubation times at 37 degrees C. At 1.7 nM L-[3H]-NE binding was approximately 25%. The binding was rapid and was not influenced by the incubation time. [3H]-NE could be dissociated from its binding sites by acid precipitation and, after HPLC, showed to be unchanged NE. No difference in NE binding was found between plasma collected in EGTA-GSH or heparin solution. There was no degradation of NE when incubated in plasma at 37 degrees C for 10 h, even without the addition of antioxidants. Therefore, in the present study, binding represented interaction of unchanged NE with plasma proteins. The whole plasma binding was saturable over the range of 0.66 nM to 0.59 mM of NE. Scatchard plot of specific binding revealed high-affinity sites with a Kd of 5.4 nM and a Bmax of 3.9 fmoles.mg-1 protein, and low-affinity sites with a Kd of 2.7 microM and a Bmax of 3.3 pmoles.mg-1 protein. Electrophoretic characterization of NE-binding proteins showed that about 60% of bound NE was associated to albumin, and 20% to prealbumin. NE binding to pure human plasma proteins was also studied using ultrafiltration. Scatchard analyses revealed a single class of very high-affinity binding sites for prealbumin (Kd 4.9 nM), a single class of binding sites for alpha 1-acid glycoprotein (Kd 54 microM) and two classes of binding sites for albumin with high (Kd 1.7 microM) and low (Kd 0.8 mM) affinities respectively. The main results obtained in this study - a) reversibility of NE binding, b) stability of free and bound NE in plasma, c) involvement of the prealbumin as a specific binding protein - point out to a specific transport for NE in human blood plasma.     

Chromatographic analysis of carbamazepine binding to human serum albumin

In this study, high-performance affinity chromatography was used to characterize the binding of carbamazepine to an immobilized human serum albumin (HSA) column. Frontal analysis was first used to determine the association equilibrium constant and binding capacity for carbamazepine on this column at various temperatures. The non-specific binding of carbamazepine within the column was also considered. The results indicated that carbamazepine had a single binding site on HSA with an association equilibrium constant of 5.3 x 10(3)M(-1) at pH 7.4 and 37 degrees C. This was confirmed through zonal elution self-competition studies. The value of DeltaG for this reaction was -5.35 kcal/mol at 37 degrees C, with an associated change in enthalpy (DeltaH) of -6.45 kcal/mol and a change in entropy (DeltaS) of -3.56 cal/molK. The location of this binding region was examined by competitive zonal elution experiments using probe compounds with known sites on HSA. It was found that carbamazepine had direct competition with l-tryptophan, a probe for the indole-benzodiazepine site of HSA, but allosteric interactions with probes for the warfarin, tamoxifen and digitoxin sites. Changes in the pH, ionic strength, and organic modifier content of the mobile phase were used to identify the predominant forces in the carbamazepine-HSA interaction.     

Thermotropic behavior of dipalmitoylphosphatidylcholine vesicles reconstituted with the glycoprotein of vesicular stomatitis virus

The vesicular stomatitis virus glycoprotein reconstituted into dipalmitoylphosphatidylcholine (DPPC) vesicles exerts a profound effect upon the DPPC gel to liquid-crystalline phase transition. The glycoprotein was reconstituted into DPPC vesicles by octyl glucoside dialysis. The gel to liquid-crystalline phase transition of these vesicles was monitored by differential scanning calorimetry. Vesicles formed in the absence of glycoprotein (600--2100-A diameter) underwent the phase transition at 41.0 degrees C and had an associated enthalpy change of 8.0 +/- 1.6 kcal/mol. Increasing the mole ratio of glycoprotein to DPPC in the vesicles to 0.15 mol % reduced both the transition temperature and the transition enthalpy change. The enthalpy change as a function of the mole percent glycoprotein could be fit to a straight line by a least-squares procedure. Extrapolation of the results to the glycoprotein concentration where the enthalpy change was zero indicated one glycoprotein molecule bound 270 +/- 150 molecules of DPPC.     

Binding and endocytosis of glycoproteins and neoglycoproteins by isolated rabbit hepatocytes.

Rabbit hepatocytes were isolated by a collagenase perfusion technique, and used to study the binding and endocytosis of the glycoprotein, asialo-orosomucoid, and the neoglycoprotein, Gal39-bovine serum albumin. Both of these proteins contain exposed galactosyl residues, and were avidly bound by the lectin on the hepatic parenchymal cell surface. Steady state and kinetic experiments performed at 2 degrees C and at 37 degrees C revealed the presence of two apparent classes of binding sites totalling 4.7 X 10(5) sites/cell at 2 degrees C, and 6.3 X 10(5) sites/cell at 37 degrees C. At 37 degrees C, both classes of sites participated in internalization of bound ligand. The cells were capable of internalizing about 60 000 molecules/min per cell. The process appeared to be first-order, with a rate constant k = 0.098 min-1 and t1/2 = 7.1 +/- 0.6 min. Binding could be inhibited by galactose-containing compounds, EGTA, and by anti-(hepatic lectin) immunoglobulin G. The inhibition by antibody appeared to be reversible upon removal of antibody-containing medium.     

Formation of a stable complex of thrombin and the secreted platelet protein glycoprotein G (thrombin-sensitive protein, thrombospondin) by thiol-disulfide exchange

When 125I-labeled thrombin was incubated with washed human platelets or with the supernatant solution of activated platelets, it formed a NaDodSO4-stable complex of apparent mass greater than 450 000 daltons. Formation of the complex was temperature dependent; with 20 nM thrombin incubated with the supernatant solution of ionophore-activated platelets, the initial rate of formation of the stable complex was 1 nM thrombin/min at 37 degrees C, 50 times the rate at 22 degrees C. Thrombin with all free amino groups methylated was still reactive. Active-site-blocked thrombin formed the complex only slowly. The complex that formed with active thrombin was not dissociated by hydroxylamine in urea. Reduction with 2-mercaptoethanol dissociated the complex, and its formation was blocked by the sulfhydryl-blocking agents iodoacetamide and 4,4'-dithiodipyridine. The complex was thus unlike those of thrombin and alpha 2-macroglobulin or antithrombin III, but it had characteristics of a disulfide-linked complex. Of the secreted proteins, albumin and glycoprotein G adhered to an activated thiol-Sepharose column, indicating that they contained free thiol groups. Purified glycoprotein G and thrombin formed a complex similar to the complex formed when thrombin was incubated with the supernatant solution of activated platelets. The purified glycoprotein bound 2.6 mol of radioactive N-ethylmaleimide/mol of protein, indicating three sulfhydryl groups per mole. After reacting with purified glycoprotein G, thrombin developed a new sulfhydryl group. It is concluded that glycoprotein G (thrombin-sensitive protein, thrombospondin) and thrombin form a dissociable complex that leads to a covalent complex by thiol-disulfide exchange of a thiol group on glycoprotein G and a disulfide on thrombin.     

Albumin inhibition of transferrin low-affinity binding to K562 cells

Several reports have suggested that variations of albumin concentration in the incubation medium can modulate the magnitude of transferrin binding to the cells. We have investigated this problem further using K562 cells. In the absence of human serum albumin, transferrin binding demonstrated a non-saturable curve which, upon Scatchard analysis, showed two components with high and low affinities. In the presence of 0.5% human serum albumin, the low-affinity but not the high-affinity component was totally inhibited and, thus, the binding showed a saturation plateau at transferrin concentration of 6 micrograms/ml. Increasing concentrations of human serum albumin in the incubation medium led to progressive inhibition of transferrin binding, reaching a plateau at 0.2% human serum albumin. At this concentration transferrin binding was about 12 ng/10(6) cells, corresponding to the saturation plateau for high-affinity binding. Low-affinity transferrin binding in the absence of human serum albumin could readily be displaced by subsequent addition of albumin. Similar inhibition was obtained by another serum protein, ceruloplasmin, suggesting that this inhibition is not unique to albumin and may be a common property of all proteins. Incubation at 37 degrees C with 59Fe-labeled transferrin indicated that all iron uptake occurs through high-affinity binding. We conclude that the reported variations in magnitude of transferrin binding by the cell due to variations in albumin concentration are the result of inhibition of low-affinity binding of transferrin by albumin.     

Binding of Clostridium botulinum type C neurotoxin to rat brain synaptosomes

The binding of Clostridium botulinum type C neurotoxin to rat brain synaptosomes was determined by the use of 125I-neurotoxin. The binding was independent of the incubation temperature (0 degrees C and 37 degrees C) and was equilibrated in 10 min. The dose dependent of 125I-toxin binding to synaptosomes at 0 degrees C showed that there were two kinds of toxin receptors on the synaptosomal membrane; the association constants and maximum binding values were 1.05 x 10(10 M-1, 5.25 x 10(-13) mol/mg of synaptosomal protein and 5.00 x 10(6) M-1, 5.00 x 10(-12) mol/mg of synaptosomal protein, respectively. When the incubation of toxin with synaptosomes was continued at 37 degrees C after 125I-toxin had been pre-incubated with synaptosomes at 0 degrees C for 10 min, the displacement of labeled toxin by the addition of excess amounts of unlabeled toxin decreased slightly with increasing incubation time, and finally 0.4% of the bound 125I-toxin was not displaced from synaptosomes. The binding of 125I-toxin to synaptosomes was inhibited by anti-heavy chain IgG and a monoclonal antibody which neutralized toxin and recognized heavy chain. These results suggest that the binding sites of toxin to synaptosomes are localized on heavy chain and a small amount of the bound toxin is incorporated into the synaptosomal membrane or synaptosomes.     

Thermal stability and ligand-binding properties of human plasma alpha 1-acid glycoprotein (orosomucoid) as determined with fluorescent probes

The fluorescence of 1,8-anilinonaphthalene sulfonate is enhanced and blue-shifted upon binding to alpha 1-acid glycoprotein, a human plasma protein of uncertain function. Fluorescence titrations of delipidated protein indicate at least two classes of binding sites having dissociation constants of 0.33 microM and 12 microM at 25 degrees C in 0.02 M potassium phosphate/0.15 M NaCl, pH 7.4. Exclusion chromatography measurements indicate only 1 binding site per mol protein, suggesting that the heterogeneity is due to differences between protein molecules, the origin of which remains unclear. The fluorescence of a mixture of dye and protein is progressively diminished upon addition of ethanol and other organic solvents whose presence could be detected at concentrations as low as 100 mM. Addition of the adrenergic drug propranolol to a mixture of alpha 1-acid glycoprotein (2.5 microM) and 1,8-anilinonaphthalene sulfonate (4 microM) caused a hyperbolic decrease in dye fluorescence to 30% of the initial value, with half-maximal response near 1 microM propranolol. When the protein-dye mixture was heated, the fluorescence of the dye exhibited a reversible downward transition with midpoint near 65 degrees C, compared to a midpoint of 58.5 degrees C obtained by intrinsic fluorescence in the absence of dye. This stabilization was confirmed with fluorescein-labeled protein, whose fluorescence polarization revealed a melting transition at 58.8 degrees C in the absence of ligands which increased by 5-6 Cdeg in the presence of 1,8-anilinonaphthalene sulfonate or propranolol. The sensitivity of 1,8-anilinonaphthalene sulfonate fluorescence to changes in the conformation and ligand environment of alpha 1-acid glycoprotein should facilitate efforts to understand the structure and function of this acute-phase reactant.     

Remodeling of a rat hepatocyte plasma membrane glycoprotein. De- and reglycosylation of dipeptidyl peptidase IV

The present paper demonstrates the terminal de- and reglycosylation of a rat hepatocyte plasma membrane glycoprotein, dipeptidyl peptidase IV (DPP IV). Cultured hepatocytes were used in pulse-chase experiments with [3H]L-fucose and [14C]N-acetyl-D-mannosamine as markers for terminal carbohydrates, [3H]D-mannose as marker of a core-sugar, and [35S]L-methionine for labeling the protein backbone. Membrane DPP IV was immunoprecipitated with a polyclonal antibody which bound selectively at 4 degrees C to the cell-surface glycoprotein. The times of maximal labeling of hepatocyte plasma membrane DPP IV were 6-9 min for [3H]L-fucose, 20 min for [3H]D-mannose, and 25 min for [35S]L-methionine. When antibodies were bound to cell-surface DPP IV at 4 degrees C, the immune complex remained stable for more than 1 h after rewarming to 37 degrees C, despite ongoing metabolic and membrane transport processes. This was shown by pulse labeling with [35S]L-methionine at 37 degrees C, followed by cooling to 4 degrees C, and addition of antibody against plasma membrane DPP IV. During rewarming, the radioactivity in the complex remained constant. In a similar experiment with [3H]L-fucose, the radioactivity in the immune complex declined rapidly, indicating a defucosylation of the plasma membrane glycoprotein. Using the same experimental design with [3H]D-mannose, the radioactivity in the immune complex remained constant, showing that the core-sugar D-mannose is not cleaved from the membrane glycoprotein. Terminal reglycosylation (refucosylation and resialylation) was demonstrated as follows. Hepatocytes were maintained at 37 degrees C in a medium supplemented with tunicamycin in order to block the de novo synthesis of N-glycosidically bound carbohydrate chains. At 4 degrees C the antibody against DPP IV bound only to cell surface glycoprotein. During the rewarming period at 37 degrees C, radioactivity from [3H]L-fucose and [14C]N-acetyl-D-mannosamine became incorporated into the immune complex. This indicates a fucosylation and sialylation of the glycoprotein originally present at the cell surface. The mechanisms whereby terminal de- and reglycosylation of plasma membrane glycoproteins may occur during membrane recycling are discussed.     

Plasma protein binding study of oxybutynin by high-performance frontal analysis

Plasma protein binding of oxybutynin (OXY) was investigated quantitatively and enantioselectively using high-performance frontal analysis (HPFA). An on-line HPLC system which consists of HPFA column, extraction column and analytical column was developed to determine the unbound concentrations of OXY enantiomers in human plasma, in human serum albumin (HSA) solutions, and in human alpha1-acid glycoprotein (AGP) solutions. OXY is bound in human plasma strongly and enantioselectively. The bound drug fraction in human plasma containing 2-10 microM (R)- or (S)-OXY was higher than 99%, and the unbound fraction of (R)-OXY was 1.56 times higher than that of (S)-isomer. AGP plays the dominant role in this strong and enantioselective plasma protein binding. The total binding affinities (nK) of (R)- and (S)-OXY to AGP were 6.86 x 10(6) and 1.53 x 10(7) M(-1), respectively, while the nK values of (R)- and (S)-OXY to HSA were 2.64 x 10(4) and 2.19 x 10(-4) M(-1), respectively. The binding affinity of OXY to AGP is much higher than that to HSA, and shows high enantioselectivity (SIR ratio of nK values is 2.2). It was found that both enantiomers are bound competitively at the same binding site on an AGP molecule. The binding property between OXY and low density lipoprotein (LDL) was investigated by using the frontal analysis method incorporated in high-performance capillary electrophoresis (HPCE/FA). It was found the binding is non-saturable and non-enantioselective.     

In vitro plasma protein binding and aqueous aggregation behavior of astaxanthin dilysinate tetrahydrochloride

The tetrahydrochloride salt of astaxanthin di-L-lysinate (lys(2)AST) is a highly water-dispersible astaxanthin-amino acid conjugate, with an aqueous dispersibility of > or = 181.6 mg/mL. The statistical mixture of stereoisomers has been well characterized as an aqueous-phase superoxide anion scavenger, effective at micromolar (microM) concentrations. In the current study, the aqueous aggregation behavior and in vitro plasma protein binding [with fatty-acid-free human serum albumin (HSA) and alpha(1)-acid glycoprotein (AGP)] were investigated with a suite of techniques, including circular dichroism (CD) and UV-vis spectroscopy, ultrafiltration, competitive ligand displacement, and fluorescence quenching. Induced CD bands obtained in Ringer buffer solution of HSA demonstrated high affinity monomeric binding of the compound at low ligand per protein (L/P) ratios (in aqueous solution alone the carotenoid molecules formed card-pack aggregates). The binding constant ( approximately 10(6)M(-1)) and the binding stoichiometry (approximately 0.2 per albumin molecule) were calculated from CD titration data. CD displacement and ultrafiltration experiments performed with marker ligands of HSA indicated that the ligand binding occurred at a site distinct from the main drug binding sites of HSA (i.e., Sites I and II). At intermediate L/P ratios, both monomeric and aggregated ("chirally complexed") binding occurred simultaneously at distinct sites of the protein. At high L/P ratios, chiral complexation predominantly occurred on the asymmetric protein template. The tentative location of the chirally-complexed aggregation on the HSA template was identified as the large interdomain cleft of HSA, where carotenoid derivatives have been found to bind previously. Only weak binding to AGP was observed. These results suggest that parenteral use of this highly potent, water-dispersible astaxanthin-amino acid conjugate will result in plasma protein association, and plasma protein binding at sites unlikely to displace fatty acids and drugs bound at well-characterized binding sites on the albumin molecule.     

Detection of carrier heterogeneity by rate of ligand dialysis: medium-chain fatty acid interaction with human serum albumin and competition with chloride

Binding equilibria for decanoate, octanoate, and hexanoate to defatted human serum albumin were investigated by dialysis exchange rate determinations in 66 mM sodium phosphate buffer, pH 7.4, 37 degrees C. The binding isotherms for decanoate and octanoate could not be fitted by the general binding equation. It was necessary to assume the presence of two albumin components, one with high affinity and one with low affinity, about 0.65 of the albumin having high binding affinity. The first stoichiometric binding constants for the high- and low-affinity albumin components were 1.1 X 10(7) and 1.4 X 10(5) M-1, respectively, for decanoate; 1.6 X 10(6) and 3.5 X 10(4) for octanoate; and 7.1 X 10(4) and 8.0 X 10(2) M-1 for hexanoate. The high-affinity albumin component binds 1 mol decanoate, 1 mol octanoate, or 2 mol hexanoate more than is bound to the low-affinity component. Chloride ions compete with the high-affinity binding of all three ligands. Albumin dimer, present in the commercial human serum albumin, has approximately the same binding properties as the monomer. Mercaptalbumin, isolated from the preparation, also consists of two proteins, with first stoichiometric binding constants 8.0 X 10(6) and 1.4 X 10(5) M-1 for decanoate, approximately 0.5 of the mercaptalbumin having high affinity.     

Characterization of insulin binding sites in cultured smooth muscle cells of rat aorta

Insulin receptors could be demonstrated in cultured smooth muscle cells of rat aorta. The specific binding of 125I-insulin was time-, temperature- and pH-dependent. The optimal temperature for our studies was 12 degrees C. At this temperature maximal specific binding was 0.5% of total counts at 120 min incubation. The pH-optimum for the binding process was between 7.5 and 8. Degradation of 125I-insulin at 12 degrees C was 14%, no degradation of binding sites could be measured at this temperature. Dissociation of 125I-insulin was rapid. 50% of the labeled hormone remained associated with the cells. Half-maximal inhibition of 125I-insulin binding was produced by insulin at 4 X 10(-11) mol/l. Scatchard-analysis gave curvilinear plots, that may suggest negative cooperativity. Specificity of binding was studied in competition experiments between 125I-insulin, insulin, proinsulin, insulin-like growth factors and human growth hormone. Half-maximal inhibition of 125I-insulin binding was produced by proinsulin at 2 X 10(-9) mol/l and by insulin-like growth factors at 9 X 10(-9) mol/l. Human growth hormone had no significant effect on the insulin binding.     

Effect of IDA and TREN chelating agents and buffer systems on the purification of human IgG with immobilized nickel affinity membranes

The purification of IgG from human plasma was studied by comparing two affinity membranes complexed with Ni(II), prepared by coupling iminodiacetic acid (IDA) and Tris(2-aminoethyl)amine (TREN) to poly(ethylenevinyl alcohol), PEVA, hollow fiber membranes. The Ni(II)-TREN-PEVA hollow fiber membrane had lower capacity for human IgG than the complex Ni(II)-IDA-PEVA, but with similar selectivity. The IgG in peak fractions eluted from the Ni(II)-IDA-PEVA with a stepwise concentration gradient of Tris-HCl pH 7.0 (100-700 mM) reached a purity of 98% (based on IgG, IgM, IgA, albumin, and transferrin nephelometric analysis). Adsorption IgG data at different temperatures (4-37 degrees C) were analyzed using Langmuir model resulting in a calculated maximum capacity at 25 degrees C of 204.6 mg of IgG/g of dry membrane. Decrease in Kd with increasing temperature (1.7x10(-5) to 5.3x10(-6) M) indicated an increase in affinity with increased temperature. The positive value of enthalpy change (26.2 kJ/mol) indicated that the adsorption of IgG in affinity membrane is endothermic. Therefore, lower temperature induces adsorption as verified experimentally.     

Characterization of norepinephrine binding to plasma proteins of the dog and the rabbit

The binding of 3H-norepinephrine (L-3H-NE, 1.0 X 10(-9) M) to plasma proteins of the dog and the rabbit was studied under controlled conditions. Destruction of NE occurred less rapidly at 22 degrees than at 37 degrees. Binding measured at 22 degrees was equivalent to that at 37 degrees, while binding measured at 0 degree was greater than that at 37 degrees. Therefore, losses of plasma NE were minimized by incubation of samples at 22 degrees for no longer than 30 minutes. L-3H-NE binding was examined in the absence and presence of 10(-9) to 10(-2) M non-labeled L-NE, DL-NE, DL-normetanephrine (NM), DL-epinephrine (E), dopamine (DA), and catechol (C). Specific binding of L-3H-NE varied in the range of NE concentrations (L-3H-NE + non-labeled NE) from 10(-9) M (18.7 +/- 3.1%, rabbit; 25.6 +/- 4.8%, dog) to 10(-6) M (10.8 +/- 3.1%, rabbit; 15.2 +/- 3.6%, dog). Calculated binding constants (KD) were consistent with binding to circulating proteins such as globulins or albumin (4.2 +/- 1.2 X 10(-5) M, rabbit; 5.4 +/- 1.7 X 10(-5) M, dog). In plasma from both species, non-labeled DL-NE, L-NE, E, DA, and C, but not NM (from 10(-9) to 10(-2) M) each significantly displaced L-3H-NE from its binding site in a manner similar to displacement produced by non-labeled NE. The results demonstrate that 1) NE is bound to plasma proteins, although to a lesser extent than had been reported by other investigators; and 2) the binding of catecholamines to plasma proteins may be mediated by the catechol ring.     

2-Iodoestradiol binds with high affinity to human sex hormone binding globulin (SHBG)

Human sex hormone binding globulin (SHBG) binds a set of steroids that differ slightly from each other in structure. Dihydrotestosterone and testosterone are bound with high affinity by SHBG whereas estradiol is bound with a lower affinity. In this work we have studied the binding to human SHBG of the derivatives obtained by substituting iodine in the aromatic A-ring of estradiol. Three A-ring iodinated estradiol derivatives, 2-iodoestradiol, 4-iodoestradiol and 2,4-di-iodoestradiol, were obtained by treating 17 beta-estradiol with NaI and Chloramine T and separating the reaction products by HPLC. Their structures were confirmed by mass spectrometry and 1H-NMR. The corresponding radioactive compounds were obtained with use of Na[125I] in the same synthesizing procedure. Incubation of whole serum, serum albumin and purified SHBG with each of the three [125I]iodoestradiols followed by agarose gel electrophoresis showed only 2-iodoestradiol to have a strong binding to SHBG. This steroid was also bound to albumin, but with a lower affinity. Besides SHBG and albumin, there were no other binders of 2-iodoestradiol in human serum. The affinity constant for the binding of 2-iodoestradiol to purified human SHBG at 37 degrees C and physiological pH was determined by a dextran-coated charcoal method to be 2.4 x 10(9) M-1 (i.e. exceeding that of dihydrotestosterone). It was found that 0.9 mol of 2-iodoestradiol was bound per mol of SHBG dimer (93 kDa) at saturation, and that 2-iodoestradiol competed with dihydrotestosterone for the same binding site of SHBG. It was concluded that 2-iodoestradiol has a remarkably high affinity for human SHBG, and that its gamma-emitting 125I-analog is useful for binding studies of human SHBG.     

Binding of cardiotoxin analogue III from Formosan cobra venom to FL cells

The binding equilibrium at 37 or 0 degrees C of 125I-cardiotoxin analogue III (CT III) to fetal lung (FL) cells (cultured human amnion cells) was achieved within 1 h, and the binding at 37 degrees C was irreversible. The Scatchard analysis at 37 degrees C on the binding of 125I-CT III indicated that FL cells had two types of binding sites with different association constants. The association constant and the number of high-affinity sites was 1.1 X 10(10) mol-1 or 2.8 X 10(6) per FL cell, respectively. At 37 or 0 degrees C, the cytotoxicity of CT III paralleled the amount of bound CT III to FL cells, and at 37 degrees C was inhibited by the presence of acidic phospholipids.