Ionic surfactants-Glossoscolex paulistus hemoglobin interactions: Characterization of species in the solution.

Glossoscolex paulistus hemoglobin (HbGp) is an oligomeric multisubunit protein with molecular mass of 3600kDa. In the current study, the interaction of sodium dodecyl sulfate (SDS) and cetyl trimethylammonium chloride (CTAC) surfactants with the monomer d and the whole oxy-HbGp, at pH 7.0, was investigated. For pure monomer d solution, SDS promotes the dimerization of subunit d, and the monomeric and dimeric forms have sedimentation coefficient values, s20,w, around 2.1-2.4 S and 2.9-3.2 S, respectively. Analytical ultracentrifugation (AUC) and isothermal titration calorimetry (ITC) data suggest that up to 26 DS- anions are bound to the monomer. In the presence of CTAC, only the monomeric form is observed in solution for subunit d. For the oxy-HbGp, SDS induces the dissociation into smaller subunits, such as, monomer d, trimer abc, and tetramer abcd, and unfolding without promoting the protein aggregation. On the other hand, lower CTAC concentration promotes protein aggregation, mainly of trimer, while higher concentration induces the unfolding of dissociated species. Our study provides strong evidence that surfactant effects upon the HbGp-subunits are different, and depend on the surfactant: protein concentration ratio and the charges of surfactant headgroups.

Characterization of Rhinodrilus alatus hemoglobin (HbRa) and its subunits: evidence for strong interaction with cationic surfactants DTAB and CTAC.

Rhinodrilus alatus is an annelid and its giant extracellular hemoglobin (HbRa) has a molecular mass (MM) of 3500kDa. In the current study, the characterization of MM values of the HbRa subunits, and the effects of surfactants and alkaline pH upon HbRa stability were monitored. Electrophoresis, MALDI-TOF-MS and AUC show that the MM values of HbRa subunits are very close, but not identical to the Glossoscolex paulistus hemoglobin (HbGp). The monomer d is found to exist in, at least, two isoforms: the main one, d1, displays a MM of 16,166±16Da, and the second one, d2, is less intense with MM of 16,490±20Da. For the trimer abc and tetramer abcd, single contributions around 51,470Da and 67,690Da were observed, respectively. Finally, the monomers a, b, and c, present MM values of 17,133, 17,290 and 15,506Da, respectively. Both CTAC and DTAB interact strongly with HbRa, and up to seven surfactant molecules are bound to the protein. On the other hand, spectroscopic studies show that HbRa is more stable at alkaline pH, as compared to HbGp. Thus, our data suggest that alkaline medium, up to pH10.0, induces the oligomeric dissociation, without promoting the subunits unfolding and heme iron oxidation. Our results suggest that the MM of the annelid hemoglobin subunits is conserved to a great extent in the evolution process of these species.

Discovery of a sensitive, selective, and tightly binding fluorogenic substrate of bovine plasma amine oxidase.

We report a novel fluorogenic substrate of bovine plasma amine oxidase (BPAO), namely, (2-(6-(aminomethyl)naphthalen-2-yloxy)ethyl)trimethylammonium (ANETA), which displays extremely tight binding to BPAO (K(m) 183 +/- 14 nM) and yet is metabolized fairly quickly (k(cat) 0.690 +/- 0.010 s(-1)), with the aldehyde turnover product (2-(6-formylnaphthalen-2-yloxy)ethyl)trimethylammonium serving as a real time reporting fluorophore of the enzyme activity. This allowed for the development of a fluorometric noncoupled assay that is 2 orders of magnitude more sensitive than the spectrophotometric benzylamine assay. The discovery of ANETA involved elaboration of the lead compound 6-methoxy-2-naphthalenemethaneamine by structure-based design, which recognized the ancillary cation binding site of BPAO as the most significant structural features controlling binding affinity. Structure-based design further ensured a high level of selectivity: ANETA is a good substrate of BPAO but is not a substrate of either porcine kidney diamine oxidase (pkDAO) or rat liver monoamine oxidase (MAO-B). ANETA represents the first highly sensitive, selective, and tight binding fluorogenic substrate of a copper amine oxidase that is able to respond directly to the enzyme activity in real time.

Interactions of agonists with an allosteric antagonist at muscarinic acetylcholine M2 receptors.

The interaction of heptane-1,7-bis(dimethyl-3'-phthalimidopropylammonium bromide) (C7/3'-phth), with several agonists, was investigated at the muscarinic M2 receptor in guinea-pig left atria. C7/3'-phth shifted concentration-response curves for the agonists, carbachol, oxotremorine-M and (+)-cis-dioxolane, to the right in a parallel fashion. Arunlakshana-Schild regressions of the data yielded slopes significantly different to unity, suggesting non-competitive antagonism. Non-linear regression analysis, using an equation based on allosteric modulation, gave quantitative estimates of co-operativity (alpha values) and the dissociation constant of C7/3'-phth (KB). In all cases, the KB estimates for C7/3'-phth were not significantly different. Increasing the carbachol contact time 10-fold did not significantly influence the KB or the alpha value obtained with C7/3'-phth. Changing from Krebs to Tyrode solution did not significantly alter the KB for C7/3'-phth, although alpha values obtained were consistently lower in Tyrode solution, suggesting that the allosteric action may be sensitive to buffer composition. A 4-fold higher degree of negative, heterotropic co-operativity between C7/3'-phth and agonists than between C7/3'-phth and competitive antagonists was also found.

Architecture of the neuronal nicotinic acetylcholine receptor ion channel at the binding site of bis-ammonium blockers.

Structure-activity relationships of 56 pentamethylenbis-ammonium compounds, the blockers of the neuronal nicotinic acetylcholine receptor (nAChR) ion channel, have been studied to estimate the cross-sectional dimensions of the channel pore. The cat superior cervical sympathetic ganglion in situ and isolated guinea pig ileum were used to evaluate the potency of the compounds to block ganglionic transmission. Minimum-energy conformations of each compound were calculated by the molecular mechanics method. A topographic model of the binding site of the blockers was proposed. It incorporates two narrowings, a large and a small one. The small narrowing is located between the large one and the cytoplasmic end of the pore. The cross-sectional dimensions of the large and small narrowings estimated from the dimensions of the blockers are 6.1 x 8.3 A and 5.5 x 6.4 A, respectively, the distance between the narrowings along the pore being approximately 7 A. Most potent blockers would occlude the pore via binding to the channel at the levels of both narrowings. Less potent blockers are either too large or too small to bind to both narrowings simultaneously: large blockers would occlude the pore at the level of large narrowing, while small blockers would pass the large narrowing and occlude the pore at the level of small narrowing only. A comparison of the topographic model with a molecular five-helix bundle model of nAChR pore predicts Serine and Threonine rings to be the most probable candidates for the large and small narrowings, respectively.

Assessment of the allosteric interactions of the bisquaternary heptane-1,7-bis(dimethyl-3'-phthalimidopropyl)ammonium bromide at M1 and M2 muscarine receptors.

The interaction of the allosteric muscarine receptor antagonist heptane-1,7-bis(dimethyl-3'-phthalimidopropyl)ammonium bromide (C7/3-phth) with M1 muscarine receptors in rat cerebral cortex and rabbit vas deferens and M2 muscarine receptors in guinea pig atria was investigated. In atria, C7/3-phth completely inhibited the dissociation of N-[3H]methylscopolamine ([3H]NMS) in the presence of excess unlabeled NMS and slowed the washout of NMS in functional experiments. C7/3-phth also produced supra-additive inhibition of the negative inotropic effects of carbachol when combined with NMS. This latter phenomenon was less pronounced when pirenzepine (PZP) was used in place of NMS. Cooperativity factors for the interaction of C7/3-phth with other antagonists were obtained by fitting the data to a theoretical model for interaction between an agonist, a competitive antagonist, and an allosteric antagonist. The values obtained indicate that C7/3-phth exhibits a greater degree of negative heterotropic cooperativity with PZP than with NMS at the M2 muscarine receptor. In the rat cerebral cortex, C7/3-phth slowed the dissociation of [3H]NMS and [3H]quinuclidinyl benzilate from the M1 receptor to the same extent but appeared not to affect the dissociation of [3H]PZP. In rabbit vas deferens, the inhibitory effect of the combination of C7/3-phth and atropine on the responses to McN-A-343 at the M1 receptor was more pronounced than that of the combination of C7/3-phth and PZP. Comparison of the findings for both central and peripheral M1 receptors with those obtained for the cardiac M2 receptor suggests that the allosteric interaction of C7/3-phth is less evident at the M1 receptor, particularly in the case of PZP.

Binding of the muscarine receptor antagonist heptane-1,7-bis(dimethyl-3'-phthalimidopropyl)ammonium bromide at cholinoceptor sites.

The binding of the bisquaternary muscarine receptor antagonist heptane-1,7-bis(dimethyl-3'-phthalimidopropyl)-ammonium bromide (C7/3-phth) was investigated at a number of cholinergic binding sites using (-)-[3H]nicotine, [3H]pirenzepine and (-)-[3H]quinuclidinyl benzilate ([3H]QNB) in both central and peripheral tissues. C7/3-phth displayed an affinity for muscarine M2 receptors in rat atria (70.1 nM) which was 1.6-fold greater than for putative M4 receptors in rabbit lung, and 4- to 5-fold greater than for M1 receptors in rat cerebral cortex. Its affinity for nicotine receptors in the cortex was low, being 808-fold lower than its affinity for the M2 receptor. Although the displacement of (-)-[3H]nicotine and [3H]pirenzepine binding in rat cortex by C7/3-phth was best described in terms of one-site modelling, low Hill coefficients were observed with C7/3-phth in displacement studies using [3H]QNB in this tissue. The possibility of allosteric interactions or multiple receptor subtype interactions is discussed.

Relative affinities of divalent polyamines and of their N-methylated analogues for helical DNA determined by 23Na NMR.

Interactions of divalent polyamines with double-helical DNA in aqueous solution are investigated by monitoring the decrease in 23Na NMR relaxation rates as NaDNA is titrated with H3N(+)-(CH2)m-+NH3, where m = 3, 4, 5, or 6. Analogous measurements are made for the same homologous series of methylated polyamines (methonium ions). The dependence of the 23Na relaxation rates on the amount of added divalent cation (M2+) is analyzed quantitatively in terms of a two-state model. The sodium ions are assumed to be in rapid exchange between a "bound" state, where they are close enough to DNA so that it affects their relaxation rate, and a "free" state in bulk solution, where their relaxation rate is the same as in solutions containing no DNA. The distribution of Na+ and M2+ between these states is described quantitatively in terms of an ion-exchange parameter: DM = (pMB)(1-pNaB)n/(pNaB)n(1-pMB), where pNaB and pMB are the fractions of Na+ and M2+ that are close enough to DNA to be considered bound (by the NMR criterion), and n is the number of sodium ions displaced from DNA by the binding of one M2+ ion. For each of the polyamines and methonium ions investigated here, equations derived from this two-state model yield acceptable fittings of the titration curves if roNa, the number of sodium ions bound per DNA phosphate when no competing cations are present, is assigned a value between 0.6 and 1.00. Within this range, changing the value assigned to roNa does change the best-fitted values of DM determined for these polyamines (DH) and for the methonium ions (DMe) but does not alter the following conclusions about the trends in these parameters. (1) For polyamines and methonium ions of the same m, DH exceeds DMe by factors that are significantly larger for m = 3 and 4 than for m = 5 and 6. (2) DH for m = 3 and 4 is larger than DH for m = 5 and 6. (3) DMe for m = 3 and 4 is smaller than DMe for m = 5 and 6.

The role of electrostatic forces in the interaction between the membrane and cytoskeleton of human erythrocytes.

Evidence is presented that electrostatic forces play a major role in the interaction between the cell membrane and cytoskeleton of human erythrocytes. Experiments were carried out on the effects of ionic strength variation, Ca2+ and Mg2+ ions, dimethonium ion and lipophilic ions on the release of spectrin from the erythrocyte ghost. In addition it was shown that the release of spectrin for fixed Ca2+ or Mg2+ concentration shows a maximum as a function of Na+ concentration. All results are consistent with the existence of a repulsive electrostatic force between membrane and cytoskeleton.

Bis-quaternary ammonium blockers as structural probes of the sarcoplasmic reticulum K+ channel.

A series of n-alkyl-bis-alpha,omega-trimethylammonium (bisQn) compounds was synthesized, and their ability to block K+ currents through a K+ channel from sarcoplasmic reticulum was studied. K+ channels were inserted into planar phospholipid membranes, and single-channel K+ currents were measured in the presence of the blocking cations. These bisQn compounds block K+ currents only from the side of the membrane opposite to the addition of SR vesicles (the trans side). The block is dependent on transmembrane voltage, and the effective valence of the block (a measure of this voltage dependence) varies with the methylene chain length. For short chains (bisQ2-bisQ5), the effective valence decreases with chain length from 1.1 to 0.65; it then remains constant at approximately 0.65 for bisQ5 to bisQ8; the effective valence abruptly increases to 1.2-1.3 for chains of nine carbons and longer. For the compounds of nine carbons and longer, the discrete nature of the block can be observed directly as 'flickering noise" on the open channel. The kinetics of the block were studied for these long-chain blockers. Both blocking and unblocking rates of the blockers vary with chain length, with the blocking rate showing the strongest variation--an increase of 2.8-fold per added methylene group. All of the voltage dependence of the binding equilibrium resides in the blocking rate, and none in the unblocking rate. The results imply that 65% of the voltage drop within the channel occurs over a distance of 6-7A, and that the short-chain blockers bind in a bent-over conformation with both charges deeply inside the channel.

The site of action of 2,4-dinitrophenol and salicylic acid upon the uncoupler-induced K+ efflux from non-metabolizing yeast.

Stimulation of K+ efflux from non-metabolizing yeast cells by 2,4-dinitrophenol or by salicylic acid occurs only after accumulation of the compounds into the cells, indicating that the site of action of the uncouplers is inside the cells. A correlation is found between the partition ratio of the lipophilic cation dibenzyldimethylammonium between cells and medium and the rate of K+ efflux.

First-pass effect after rectal administration of thiazinamium methylsulfate.

The absorption and metabolism of the quaternary ammonium compound thiazinamium methylsulfate were studied in humans using plasma concentration data and urinary excretion measurements. After giving a dose of 150 mg in suppositories, the relative bioavailability was 5.8 +/- 3.2 (SD) % of the dose, comparable to the values obtained following oral administration. The degree of first-pass effect observed after rectal administration was comparable with that after oral administration.

Variations in the bioavailability of thiazinamium methylsulfate.

Bioavailability after oral administration of the anticholinergic drug thiazinamium methylsulfate (Multergan), a phenothiazine derivative with a quaternary ammonium group in the molecule, has been studied in patients and volunteers by measuring the drug concentrations in plasma or the excretion of the parent drug in urine. The relative bioavailability as compared to intramuscular injection seems to be of the order of 10%. Much more of the drug is absorbed, however, but is metabolized during the first liver passage. Moreover, there seems to be a substantial interindividual variation in the bioavailability of the drug. Studies in a group of eight volunteers showed that there is also a substantial intraindividual variation, but its magnitude is smaller than that of the interindividual variation.

Binding of ampholine to transfer RNA.

The melting temperature of isoaccepting tRNAfMet is affected by Ampholine. The plot of Tm versus the logarithm of Ampholine concentration shows clearly an increasing effect of Ampholine when the pH changes from 7.4 to 4.2. This result is interpreted as binding of Ampholine to the nucleic acid. The effects of Ampholine have been compared with those of soidum, magnesium and tetraethylene pentamine. Ampholine carrier ampholytes at pH 4.2 bind to tRNA with the same affinity as magnesium; at higher pH values they are less active. An hypothesis for the mechanism of action of Ampholine on nucleic acids during isoelectric focusing is proposed.