Chelation therapy for methylmercury(II) poisoning. Synthesis and determination of solubility properties of MeHg(II) complexes of thiol and dithiol antidotes

Methylmercury(II) complexes of the most widely studied antidotes for mercury poisoning have been prepared, and both the water solubility and 1-octanol/water partition coefficients determined for these complexes and the L-cysteine complex. New complexes of N-acetyl-D,L-penicillamine, 2-mercaptosuccinic acid, meso-dimercaptosuccinic acid, and Unithiol have been synthesized and characterized, and are found to have the formulations MeHgSCMe2CH(NHCOMe)CO2H, MeHgSCH(CO2H)CH2CO2H, MeHgSCH(CO2H)CH(CO2H)SHgMe, and Na[MeHgSCH2CH-(SHgMe)CH2SO3], respectively. Trends in octanol/water partition coefficients are consistent with reported studies of the effectiveness of antidotes for MeHg(II) poisoning and redistribution of MeHg(II) on administration of antidotes, particularly for British anti-Lewisite, Unithiol, and meso-dimercaptosuccinic acid.     

Effect of lipophilic character on the biological activity of synthetic angiotensin peptides.

[Ile5]angiotensin II (angiotensin) derivatives bearing acetyl, propionyl, butyryl, pentanoyl or hexanoyl moieties at the N-terminal amino group were synthesized. The myotropic effects in vitro (on guinea-pig ileum and rat uterus) of desamino-angiotensin and of the above compounds did not correlate with their partition coefficients in butan-1-ol/acetic acid/water. The pressor effects in vivo in rats showed a negative correlation with the partition coefficients, discouraging further attempts to raise the pressor potency of angiotensin analogues by increasing their hydrophobicity. The half-times for onset and reversal of the biological responses also did not correlate with partition coefficients, but reversal was retarded by the presence of a free amino group. It is concluded that partition between aqueous medium and the lipophilic receptor environment is not a limiting factor for angiotensin activity.     

Chemicobiological interactions and the use of partition coefficients in their correlation

Using octanol/water partition coefficients as an operational definition of hydrophobicity, 70 examples are given in which the hydrophobic interactions of organic compounds with themselves (in micelles) with macromolecules or with biological systems can be quantitatively correlated by the expression: log RBR = a log P + b. In this expression RBR is a binding constant or a relative biological response, P is the octanol/water partition coefficient and a and b are constants obtained via the method of least squares. These results are strong support for the utility of log P in the correlation of hydrophobic interactions. They also illustrate the extremely wide range of processes in which hydrophobic bonding plays a critical role.     

Partition coefficients of quinones and hydroquinones and their relation to biochemical reactivity

Some major effects of ring substituents on the partition coefficients of quinone headgroups are described. Attention is drawn to the large differences in partition coefficients in cyclohexane/water of the two major freely diffusing redox forms, the quinone, Q, and the hydroquinone, QH2. Methoxy substituents cause a marked increase of the cyclohexane/water partition coefficient of the hydroquinone, but this effect is absent in the quinone and is also not seen in measurements in octanol/water. The relation between partition coefficients and biochemical specificity of quinone binding sites is explored.     

Interaction of 14C-labelled amphotericin B derivatives with human erythrocytes: relationship between binding and induced K+ leak

Four 14C-labelled amphotericin B (Am B) derivatives with different net electric charges were examined: zwitterionic N-fructosyl Am B, positively charged N-fructosyl Am B methyl ester, negatively charged N-acetyl Am B and neutral N-acetyl Am B methyl ester. The binding of these four derivatives to human red cells and their octanol-water partition coefficients were measured. Simple partitioning between red cells and buffer was found for the four compounds, regardless of concentration, within a range of 10(-8) and 10(-4) M. This indicates the absence of cooperativity and saturability of binding at least in this concentration range. The constant partition coefficients were found to be three to five times higher for the two methyl ester derivatives than for the two non-esterified compounds. All partition coefficients were proportional to those found for the octanol-water system. Efficiency in inducing K+ leak from red cells was measured during the binding experiments. Despite the higher partition coefficients of the two methyl ester derivatives, they were found to have much lower ionophoric efficiency than the two non-esterified compounds. These results are discussed in terms of the mechanism of permeability pathway formation by polyene antibiotics.     

Comparative QSAR studies on bibenzimidazoles and terbenzimidazoles inhibiting topoisomerase I

Terbenzimidazoles that inhibit topoisomerase are of interest as anticancer drugs. We have reviewed the literature and have developed 13 quantitative structure-activity relationships (QSARs) on cleaving DNA or inhibiting the growth of tumor cell cultures. The results are correlated with octanol/water partition coefficients or molecular refractivity. Suggestions have been made for the development of improved derivatives.     

Partition coefficients of plant cuticles for monoterpenes

Summary Cuticle/water partition coefficients (K_c/w) for d-limonene, -pinene and -pinene were determined by an extrapolation and a desorption method. The sorption experiments were carried out with isolated angiosperm and gymnosperm cuticles and with [¹⁴C]-labelled monoterpenes, which were obtained biosynthetically. Both methods were suitable for the determination of the K_c/w of volatile hydrophobic compounds. For the angiosperm cuticles the partition coefficients are of the order of 10⁴, which indicates a high accumulation of monoterpenes in the cuticle. The values of the conifer cuticles of Picea abies (L.) Karst. and Abies alba Mill., however, are lower due to their high lignin content. This is proved by the increase of the partition coefficients after removal of polar and phenolic components. The K_c/w can be estimated with good accuracy from the octanol/water partition coefficient, which was determined experimentally.     

Binding measurements of indolocarbazole derivatives to immobilised human serum albumin by high-performance liquid chromatography

The binding properties of six indolocarbazole derivatives have been measured using immobilised human serum albumin (HSA) in an HPLC column. The compounds showed very strong binding to HSA which necessitated the application of a 30 to 40% concentration of 2-propanol in the mobile phase. This represents a much higher concentration than is recommended by the column manufacturers. This HSA column had not changed its binding property when it was used again with 4% 2-propanol and 96% phosphate buffer. The binding parameters were estimated by extrapolation to 0% 2-propanol and were above 99% for each indolocarbazole derivative. The correlation analysis, including the calculated octanol/water partition coefficient (logP),pK_a values as well as measured reversed-phase retention data of the compounds, revealed that the extremely strong binding can be explained by the hydrophobic and acidic properties of the compounds.     

Synthesis and Cytotoxicity Assessment against Human Colorectal Cancer Cell Lines of Quaternary 8-Dichloromethyl Protoberberine Alkaloids

Twenty-two quaternary 8-dichloromethylprotoberberine alkaloids were synthesized from unmodified quaternary protoberberine alkaloids (QPAs) to improve their physical and chemical properties and to obtain selectively anticancer derivatives. The synthesized derivatives showed more appropriate octanol/water partition coefficients by up to values 3–4 compared to unmodified QPA substrates. In addition, these compounds exhibited significant antiproliferative activity against colorectal cancer cells and lower toxicity on normal cells, resulting in more significant selectivity indices than unmodified QPA compounds in vitro. The IC₅₀ values of antiproliferative activity of quaternary 8-dichloromethyl-pseudoberberine 4-chlorobenzenesulfonate and quaternary 8-dichloromethyl-pseudopalmatine methanesulfonate against colorectal cancer cells are 0.31 μM and 0.41 μM, respectively, significantly stronger than those of other compounds and positive control 5-fluorouracil. These findings suggest that 8-dichloromethylation can be used as one of the modification strategies to guide the structural modification and subsequent investigation of anticancer drugs for CRC based on QPAs.     

The permeation of organic acids through lecithin bilayers. Resemblance to diffusion in polymers.

1. The fluxes of aliphatic acids and their derivatives through black lipid membranes made of egg lecithin in decane were measured by means of a proton titration method. 2. Permeability coefficients were calculated and these were divided by the partition coefficient of the diffusing solute in different solvent systems: n-decane, olive oil, ether and octanol. The logarithms of the diffusion coefficients thus obtained were plotted against the logarithm of the molecular weight. The data could not be fitted to a single regression line in any solvent system. 3. When the logarithm of the diffusion coefficients were correlated to the logarithm of the molecular volume (equals molecular weight/ specific gravity) all the diffusants could be fitted to the same regression line, indicating that the molecular volume is a better index of molecular size and shape than the molecular weight. 4. Analysis of the experimental results assuming a model of diffusion through soft polymers (Lieb, W.R. and Stein, W. D. (1971) Current Topics in Membranes and Transport, vol. 2, pp. 1-39, Academic Press, New York) showed that decane and olive oil are not adequate model solvents for planar lecithin membranes but ether and octanol are good models. 5. The differential mass selectivity coefficient was found to be similar to that for soft polymers and biological membranes, i.e. greater than 3.0. 6. Water could be fitted by the same regression line, thus emphasizing the generality of passive transfer and implying that water crosses lipid membranes as single molecules.     

Theoretical calculation of partition coefficients of dimethoxypyrimidinylsalicylic acids

Despite their importance as herbicides, dimethoxypyrimidinylsalicylic acids has been poorly characterized from a physical-chemical point of view. This lack of information has prevented the assessment of their impact in the environment once they are released. In this study, environmentally important properties (free energy of solvation, Henry’s law constant, octanol/air, and octanol/water partition coefficients) of 39 dimethoxypyrimidinylsalicylic derived compounds are calculated by density functional theory (DFT) methods at B3LYP/6-31G(d,p) level of theory using the Poisson-Boltzmann solvation model. These properties have not been reported previously for this family of compounds, neither experimentally or theoretically.     

Design, synthesis, and evaluation of cyclofenil derivatives for potential SPECT imaging agents

To develop technetium- and rhenium-labeled nonsteroidal estrogen imaging agents for estrogen receptor (ER) positive breast tumors, two groups of rhenium and technetium cyclofenil derivatives were synthesized and characterized. The binding affinities of the rhenium complexes for ERs were determined. The tricarbonyl rhenium complex showed the highest binding affinity for ERs (81.2 for ERβ, 16.5 for ERα). Tricarbonyl technetium cyclofenil complexes were obtained in high radiochemical purity and radiochemical yields. The results of studies of their octanol/water partition and in vitro stability are presented. These results demonstrate that these radiolabeled cyclofenil derivatives may be considered as potential breast cancer imaging agents.     

Inhibition of phosphate uptake in barley roots by hydroxy-benzoic acids

The influence of 15 hydroxy-benzoic acids upon active inorganic phosphate absorption by barley roots was examined. For each compound an inhibition constant (k_i) was determined, i.e. the concentration of compound required to bring about a 50% inhibition of absorption. The k_i values of the benzoic acids were strongly correlated with their octanol—water partition coefficients and their pK_a values. This suggests that the inhibition of normal membrane functions, brought about by benzoic acids, results from a generalized increase in cell membrane permeability. Salicylate derivatives were generally more inhibitory than would be predicted from their partition coefficients; their pronounced toxicity probably arises from structural impediments to their detoxication.     

Inhibition of Butyrylcholinesterase by Phenothiazine Derivatives

The inhibition of horse serum butyrylcholinesterase (EC 3.1.1.8) by 10 phenothiazine or thioxanthene derivatives was studied with a purified enzyme. Most compounds were mixed inhibitors, but for some of them an apparent competitive inhibition was observed. The competitive inhibition constants (K i) were in the range 0.05 to 5 μM. The structures of the inhibitors were modeled by geometry optimization with the AM1 semi-empirical molecular orbital method and octanol/water partition coefficients were estimated with the CLOGP software. Quantitative structure-activity relationships identified lipophilicity, molecular volume, and electronic energies as the main determinants of inhibition. This quantitative model suggested hydrophobic and charge-transfer interactions of the phenothiazine ring with a tryptophan residue at the "anionic" site of the enzyme, and a hydrophobic interaction of the lateral chain with non-polar amino acids.     

Extracting hydrophobic free energies from experimental data: relationship to protein folding and theoretical models

Solubility and vapor pressure measurements of hydrocarbons in water are generally thought to provide estimates of the strength of the hydrophobic effect in the range 20-30 cal/(mol.A2). Our reassessment of the solubility data on the basis of new developments in solution thermodynamics suggests that the hydrophobic surface free energy for hydrocarbon solutes is 46-47 cal/(mol.A2), although the actual value depends strongly on curvature effects [Nicholls et al. (1991) Proteins (in press); Sharp et al. (1991) Science 252, 106-109]. The arguments to support such a significant increase in the estimate of the hydrophobic effect stem partly from theoretical considerations and partly from the experimental results of De Young and Dill [(1990) J. Phys. Chem. 94, 801-809] on benzene partition between water and alkane solvents. Previous estimates of the hydrophobic effect derive from an analysis of solute partition data, which does not fully account for changes in volume entropy. We show here how the ideal gas equations, combined with experimental molar volumes, can account for such changes. Revised solubility scales for the 20 amino acids, based on cyclohexane to water and octanol to water transfer energies, are derived. The agreement between these scales, particularly the octanol scale, and mutant protein stability measurements from Kellis et al. [(1989) Biochemistry 28, 4914-4922] and Shortle et al. [(1990) Biochemistry 29, 8033-8041] is good. The increased strength of the hydrophobic interaction has implications for the energetics of protein folding, substrate binding, and nucleic acid base stacking and the interpretation of computer simulations.     

Inhibition of butyrylcholinesterase by phenothiazine derivatives

The inhibition of horse serum butyrylcholinesterase (EC 3.1.1.8) by 10 phenothiazine or thioxanthene derivatives was studied with a purified enzyme. Most compounds were mixed inhibitors, but for some of them an apparent competitive inhibition was observed. The competitive inhibition constants (K) were in the range 0.05 to 5 microM. The structures of the inhibitors were modeled by geometry optimization with the AM1 semi-empirical molecular orbital method and octanol/water partition coefficients were estimated with the CLOGP software. Quantitative structure-activity relationships identified lipophilicity, molecular volume, and electronic energies as the main determinants of inhibition. This quantitative model suggested hydrophobic and charge-transfer interactions of the phenothiazine ring with a tryptophan residue at the "anionic" site of the enzyme, and a hydrophobic interaction of the lateral chain with nonpolar amino acids.     

Biosorption of dichlorodiphenyltrichloroethane and hexachlorobenzene in groundwater and its implications for facilitated transport.

The potential for enhanced mobility of hydrophobic pollutants by cotransport with bacteria in saturated soils was evaluated from measurements of biosorption of 14C-labeled hexachlorobenzene and dichlorodiphenyltrichloroethane (DDT) to five strains of soil and sewage bacteria. The sorption process could be described by a linear partition equation and appeared to be reversible, but desorption kinetics were slow and/or partly irreversible. The DDT partition coefficients varied with equilibration time, possibly reflecting DDT-induced changes in the physiology of the bacteria. The partition coefficients, normalized to the masses of the bacteria, ranged from 250 to 14,000 for live cells, but the largest coefficients were associated with autoclaved cells of a Pseudomonas sp. The sorptive capacity of the bacterial biomass was greater for DDT than for hexachlorobenzene but was not correlated to overall bacterial hydrophobicity, measured by hydrophobic interaction chromatography. In a column study, 1.2 x 10(9) cells of a Bacillus sp. strain per ml enhanced DDT transport about 8-fold, whereas an advective-dispersive-sorptive equilibrium model for two mobile phases, water and free-living bacteria, suggested a 14-fold enhancement, based on the DDT partition coefficient. The disagreement was in part due to a retarded nonequilibrium movement of the bacteria. Model calculations based on literature data covering a wide range of organisms and compounds suggested that 10(6) cells ml-1 would increase the mobility of very hydrophobic compounds (log octanol-water partition coefficient [K(ow) of greater than or equal to 6), whereas higher densities of bacteria (10(8) cells ml-1) would have a significant impact on compounds with a log K(ow) of greater than or equal to 4.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biosorption of dichlorodiphenyltrichloroethane and hexachlorobenzene in groundwater and its implications for facilitated transport.

The potential for enhanced mobility of hydrophobic pollutants by cotransport with bacteria in saturated soils was evaluated from measurements of biosorption of 14C-labeled hexachlorobenzene and dichlorodiphenyltrichloroethane (DDT) to five strains of soil and sewage bacteria. The sorption process could be described by a linear partition equation and appeared to be reversible, but desorption kinetics were slow and/or partly irreversible. The DDT partition coefficients varied with equilibration time, possibly reflecting DDT-induced changes in the physiology of the bacteria. The partition coefficients, normalized to the masses of the bacteria, ranged from 250 to 14,000 for live cells, but the largest coefficients were associated with autoclaved cells of a Pseudomonas sp. The sorptive capacity of the bacterial biomass was greater for DDT than for hexachlorobenzene but was not correlated to overall bacterial hydrophobicity, measured by hydrophobic interaction chromatography. In a column study, 1.2 x 10(9) cells of a Bacillus sp. strain per ml enhanced DDT transport about 8-fold, whereas an advective-dispersive-sorptive equilibrium model for two mobile phases, water and free-living bacteria, suggested a 14-fold enhancement, based on the DDT partition coefficient. The disagreement was in part due to a retarded nonequilibrium movement of the bacteria. Model calculations based on literature data covering a wide range of organisms and compounds suggested that 10(6) cells ml-1 would increase the mobility of very hydrophobic compounds (log octanol-water partition coefficient [K(ow) of greater than or equal to 6), whereas higher densities of bacteria (10(8) cells ml-1) would have a significant impact on compounds with a log K(ow) of greater than or equal to 4.(ABSTRACT TRUNCATED AT 250 WORDS)