Conformations of N-(2-fluorophenyl)-N-phenylcarbamoyl-alpha-chymotrypsin

N-(2-Fluorophenyl)-N-phenylcarbamoyl chloride is shown to react with alpha-chymotrypsin to give a catalytically inactive material. A crystal structure determination shows that the chloride exists in the solid state in two conformations. In both of these the aromatic rings are tilted substantially relative to the plane through the atoms of the carbamoyl chloride group; the structures differ by a 180 degrees rotation of the 2-fluorophenyl ring. Fluorine NMR studies of alpha-chymotrypsin modified with this carbamoyl chloride show that, when bound to the enzyme, one aromatic ring of the diphenylcarbamoyl group likely rotates slowly while the other rotates much more rapidly or else is frozen in one dominant conformation. In the denatured enzyme (8 M urea) at room temperature and above, both aromatic rings of the diphenylcarbamoyl group appear to be rapidly rotating although differential linewidth changes observed at lower sample temperatures suggest that rotation of one ring becomes slow under these conditions. Rotation about the carbamoyl carbon-nitrogen bond is detected in fluorine NMR spectra of both the native and the denatured modified enzymes as the sample temperature is increased. Rates of carbamoyl rotation in the chloride, in the native modified enzyme, and in the denatured enzyme at 25 degrees C are approximately 66, 10, and 200 s-1, respectively.     

NMR studies of carbonic anhydrase-fluorinated benzenesulfonamide complexes

Fluorine NMR has been used to examine complexes formed by 2-fluoro-, 3-fluoro-, and 2,5-difluorobenzenesulfonamide and human carbonic anhydrases I and II. The results show that all three inhibitors form complexes with both isozymes that have 2:1 inhibitor/enzyme stoichiometry. The fluorine spectra observed for all inhibitor-isozyme combinations are consistent either with rapid rotation of the aromatic ring of the inhibitor in the complexes or with preferential binding of only one of the two possible conformations of the inhibitors that are isomeric by virtue of rotation about the C1-C4 bond of the fluoro aromatic ring. Because ring rotation is slow in the case of the pentafluorobenzenesulfonamide-CA I complex, selective binding of rotamers is the explanation of these observations presently favored. A computer graphics study shows that formation of 2:1 complexes of CA I is feasible without appreciable distortion of the protein tertiary structure found in the crystalline state.     

Structure and dynamics of α-chymotrypsin-N-trifluoroacetyl-4-fluorophenylalanine complexes

Summary Fluorine NMR lineshape, relaxation and Overhauser effect data collected at 282 and 470 MHz have been used to obtain information about the nature of complexes formed betweenN-trifluoroacetyl-4-fluorophenylalanine and the enzyme chymotrypsin. Systems involving both enantiomers have been examined as well as derivatives of these in which the aromatic ring hydrogens have been replaced by deuterium. The enzyme-induced fluorine chemical shift effects and the dynamics of molecular motions of the fluorophenyl ring at the respective binding sites appear to be similar in both complexes and, where comparable, the results are in agreement with data obtained at lower frequencies that have been reported by other workers. The dynamics of the fluoroaromatic ring in these complexes are significantly different from those observed in a closely related acylated enzyme.     

Motion at the active site of [(4-fluorophenyl)sulfonyl]chymotrypsin

Fluorine and deuterium NMR relaxation studies have been used to examine the motion of the 4-fluorophenyl ring attached to the active site of [(4-fluorophenyl)sulfonyl]-alpha-chymotrypsin at pH 4. Analysis of the results indicates that rotation about the 2-fold axis of this ring is reasonably rapid, though not as fast as in tosylchymotrypsin. Two-dimensional (2D) nuclear Overhauser effects (NOEs) were used to suggest the shifts of those protons of the enzyme close enough to the fluorine nucleus to lead to relaxation; important proton-fluorine dipolar relaxation contributions arise from protons with shifts of 7.4 +/- 0.3 ppm and between 4.0 and 5.4 ppm. Specific deuteration permits the assignment of the first of these to the protons ortho to the fluorine while serine-189, cysteines-191 and -220, and methionine-192 are suggested as possible bearers of the other protons. The fluorine chemical shift effect observed for the native conformation of this protein is 9 ppm downfield of the shift observed with the denatured protein; this large shift may be the result of van der Waals interactions between the fluorine and one or more of the protons whose signals appear in the 2D NOE experiments.     

Side-chain dynamics of two aromatic amino acids in pancreatic phospholipase A2 as studied by deuterium nuclear magnetic resonance

The flexibility of individual amino acid side chains of pancreatic phospholipase A2 in aqueous and micellar solutions was studied with deuterium nuclear magnetic resonance (2H NMR). Bovine pancreatic phospholipase A2 was selectively deuterated at the aromatic ring systems of Trp-3 and Phe-5 and porcine pancreatic phospholipase A2 at Trp-3 only. Solid-state 2H NMR spectra of the lyophilized enzymes exhibited quadrupole splittings on the order of 130 kHz, indicating almost complete immobilization of the aromatic ring systems. Exposure to a water-saturated atmosphere did not remove these steric constraints. However, side-chain mobility could be induced for the tryptophyl residue of the bovine enzyme by dissolving this enzyme in aqueous buffer or micellar solution whereas the phenyl ring always remained immobile and served as a probe for the protein's overall rotation. Typical correlation times for the tryptophyl and phenyl aromatic ring systems in aqueous solution were 7 ps and 13 ns (at 20 degrees C), respectively. The correlation time of the phenyl ring was longer than expected for the monomeric protein (approximately 6 ns), suggesting some aggregation of the protein at the high concentrations used for the NMR measurements. Addition of a micellar solution of oleoylphosphocholine had no influence on the motional freedom of the tryptophyl residue but approximately doubled the correlation time of the phenyl ring, indicating an increase of the effective volume of the tumbling particle due to lipid-protein interaction. A different behavior was observed for the Trp-3 residue of porcine phospholipase A2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fluorine NMR studies of fluorocinnamoylchymotrypsins

Three monofluorocinnamoylchymotrypsins have been examined at pH 4 by fluorine NMR spectroscopy. Protein-induced fluorine chemical shifts are quite large (~7 ppm) when fluorine is present at the para position but nearly zero for ortho fluorine. The shifts roughly parallel those observed in complexes formed between the enzyme and the analogous N-acetylfluorophenylalanines, suggesting a similarity in molecular environment for the aromatic ring in both systems. Little correlation is found, however, between the shifts for the acylenzymes and those of the corresponding enzyme-cinnamate complexes, indicating that the environment for the aromatic ring in the complexes is dissimilar from that experienced by the aromatic group in the acylated enzyme. Solvent isotope effects ($\text{H}{}_2\text{O}\text{D}{}_2\text{O}$) on the fluorine chemical shifts for the fluorocinnamoylchymotrypsins are small and downfield. Fluorine NMR observations suggest that the presence of the fluorocinnamoyl group greatly stabilizes the enzyme toward denaturation in 8 m urea.     

NMR studies of multiple conformations in complexes of Lactobacillus casei dihydrofolate reductase with analogues of pyrimethamine

1H and 19F NMR signals from bound ligands have been assigned in one- and two-dimensional NMR spectra of complexes of Lactobacillus casei dihydrofolate reductase with various pyrimethamine analogues (including pyrimethamine [1, 2,4-diamino-5-(4'-chlorophenyl)-6-ethylpyrimidine], fluoropyrimethamine [2, 2,4-diamino-5-(4'-fluorophenyl)-6-ethylpyrimidine], fluoronitropyrimethamine [3, 2,4-diamino-5-(4'-fluoro-3'-nitrophenyl) -6-ethylpyrimidine], and methylbenzoprim [4, 2,4-diamino-5-[4'- (methylbenzylamino)-3'-nitrophenyl]-6-ethylpyrimidine]). The signals were identified mainly by correlating signals from bound and free ligands by using 2D exchange experiments. Analogues (such as 1 and 2) with symmetrically substituted phenyl rings give rise to 1H signals from four nonequivalent aromatic protons, clearly indicating the presence of hindered rotation about the pyrimidine-phenyl bond. Analogues containing asymmetrically substituted aromatic rings (such as 3 and 4) exist as mixtures of two rotational isomers (an enantiomeric pair) because of this hindered rotation and the NMR spectra revealed that both isomers (forms A and B) bind to the enzyme with comparable, though unequal, binding energies. In this case two complete sets of bound proton signals were observed. The phenyl ring protons in each of the two forms experience essentially the same protein environment (same shielding) as that experienced by the corresponding protons in bound pyrimethamine: this confirms that forms A and B correspond to two rotational isomers resulting from approximately 180 degrees rotation about the pyrimidine-phenyl bond, with the 2,4-diaminopyrimidine ring being bound similarly in both forms. The relative orientations of the two forms have been determined from NOE through-space connections between protons on the ligand and protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Benzofuran- and furan-2-yl-(phenyl)-3-pyridylmethanols: synthesis and inhibition of P450 aromatase

A series of benzofuran-2-yl-(phenyl)-3-pyridylmethanol derivatives were prepared using an efficient 1-step procedure in good yields. In addition furan-2-yl-(phenyl)-3-pyridylmethanol derivatives were also prepared to determine the effect of the benzene ring in benzofuran with respect to inhibitory activity. The pyridylmethanol derivatives were all evaluated in vitro for inhibitory activity against aromatase (P450(AROM), CYP19), using human placental microsomes. The benzofuran-2-yl-(phenyl)-3-pyridylmethanol derivatives showed good to moderate activity (IC50 = 1.3-25.1 microM), which was either better than or comparable with aminoglutethimide (IC50 = 18.5 microM) but lower than arimidex (IC50 = 0.6 microM), with the 4-methoxyphenyl substituted derivative displaying optimum activity. Molecular modelling of the benzofuran-2-yl-(4-fluorophenyl)-3-pyridylmethanol derivative suggested activity to reside with the (S)-enantiomer. The furan-2-yl-(phenyl)-3-pyridylmethanol derivatives were devoid of activity indicating the essential role of the benzene ring of the benzofuran component for enzyme binding.     

6-Hydrophobic aromatic substituent pyrimethamine analogues as potential antimalarials for pyrimethamine-resistant Plasmodium falciparum

The series of des-Cl (unsubstituted) and m-Cl phenyl analogues of PYR with various flexible 6-substituents were synthesized and studied for the binding affinities with highly resistant quadruple mutant (QM) DHFR. The derivatives carrying 4 atoms linker with a terminal carboxyl substituted on the aromatic ring exhibited good inhibition to the QM enzyme and also showed effective antimalarial activities against resistant P. falciparum bearing the mutant enzymes with relatively low cytotoxicity to mammalian cells. The X-ray crystallographic analysis of the enzyme-inhibitor complexes suggested that the hydrophobic substituent at 6-position was accommodated well in the hydrophobic pocket and the optimal length of the flexible linker could effectively promote the binding of the terminal carboxyl group to the key amino acid residues, Arg59 and Arg122.     

The influence of tetraphenylborates (hydrophobic anions) on yeast cell electro-rotation

The action of a series of tetraphenylborate ion (TPB) derivatives on yeast cells was studied by electro-rotation of the pre-treated cells. TPB derivatives in which all four phenyl groups were substituted with fluorine, chlorine or trifluoromethyl were much more toxic than the unsubstituted compound, the effect increasing dramatically with increasing size of substituents. These observations suggest that the toxicity of these hydrophobic ions is determined mainly by their size and possibly also by the chemical inductivity of their substituent groups. The order of the toxicities of these ions was in fair agreement with literature values for their translocation rates across artificial bilayers. Incubation times of 3 h were used as standard, longer incubations (up to 48 h) showed that the number of cells affected by low doses of TPB increased with the logarithm of time after the first hour of incubation. Although measurements of the percentage of cells showing co-field rotation showed that controls were not adversely affected by incubations as long as 9 h, rotation spectra showed that some cells suffer loss of internal conductivity during extended incubations. Decrease of the pH of the incubation medium, or inclusion of high concentrations of NaCl or KCl, potentiated the effects of these hydrophobic ions. The toxicity developed slowly, and the sensitivity of the assay was only very weakly dependent on the cell suspension density.     

Dynamics of the aromatic amino acid residues in the globular conformation of the basic pancreatic trypsin inhibitor (BPTI). II. Semi-empirical energy calculations.

The molecular conformation of the basic pancreatic trypsin inhibitor (BPTI) is known in considerable detail from both X-ray studies in single crystals and NMR studies in solution. The NMR experiments showed that the aromatic rings of the phenylalanyl and tyrosyl residues can undergo rapid rotational motions about the C beta--Cv bond. The present paper describes a model investigation of the mechanistic aspects of these intramolecular rotational motions. From calculations of the conformational energies for molecular species derived from the X-ray structure by rotations of individual aromatic rings, it was apparent that the rotational motions of the aromatics could only be understood in a flexible structure. Flexibility was simulated by allowing the protein to relax to an energetically favorable conformation for each of the different rotation states of the aromatic rings. It was then of particular interest to investigate how the perturbations caused by different rotation states of the aromatic rings were propagated in the protein structure. It was found that the rotation axes C beta--Cv were only slightly affected (delta X1 approximately less than 20 degrees. The most sizeable perturbations are caused by through space interactions with nearby atoms, which move away from the ring center and thus release the steric hindrance opposing the rotational motions. The values for the energy barriers obtained from the energy minimization are of the same order of magnitude as those measured by NMR.     

Synthesis and antiamoebic activities of 1-N-substituted cyclised pyrazoline analogues of thiosemicarbazones

A series of 21 new 1-N-substituted cyclised pyrazoline analogues of thiosemicarbazones were synthesised by cyclisation of Mannich bases with thiosemicarbazides of variegated nature. The chemical structures of the compounds were proved by UV, IR, (1)H NMR, (13)C NMR spectroscopic data and elemental analyses. The antiamoebic activities of these compounds were evaluated by microdilution method against HM1:1MSS strain of Entamoeba histolytica. It was found that 3-chloro and 3-bromo substituents on the phenyl ring at position 3 of the pyrazoline ring enhanced the antiamoebic activity as compared to unsubstituted phenyl ring. Compounds 15, 17, 18, 20 and 21 showed less IC(50) value than metronidazole. Moreover, compound 21 have shown the most promising antiamoebic activity (IC(50)=0.6 microM vs IC(50)=1.8 microM of metronidazole).     

Naphthylisopropylamine and N-benzylamphetamine derivatives as monoamine oxidase inhibitors

A series of naphthylisopropylamine and N-benzyl-4-methylthioamphetamine derivatives were evaluated as monoamine oxidase inhibitors. Their potencies were compared with those of a series of amphetamine derivatives, to test if the increase of electron richness of the aromatic ring and overall size of the molecule might improve their potency as enzyme inhibitors. Molecular dockings were performed to gain insight regarding the binding mode of these inhibitors and rationalize their different potencies. In the case of naphthylisopropylamine derivatives, the increased electron-donating capacity and size of the aromatic moiety resulting from replacement of the phenyl ring of amphetamine derivatives by a naphthalene system resulted in more potent compounds. In the other case, extension of the arylisopropylamine molecule by N-benzylation of the amino group led to a decrease in potency as monoamine oxidase inhibitors.     

Quantitative assessment of the noncovalent inhibition of sickle hemoglobin gelation by phenyl derivatives and other known agents.

The ability of a variety of phenyl derivatives to inhibit sickle cell hemoglobin gelation was placed on a quantitative scale by parallel equilibrium and kinetic assays. Modifications of the phenyl ring studied include polar, nonpolar, and charged substituents, added aromatic rings, and loss of aromaticity. Other noncovalent inhibitors previously reported to have high potency were measured and placed on the same quantitative scale. Some phenyl derivatives were found to be as effective an any other known noncovalent antigelling agent. The phenyl compounds penetrate easily into red cells, and their potency is tolerant to chemical modification, which holds out the possibility of designing low-toxicity derivatives. On the negative side, the level of potency obtainable appears to be inadequate for clinical use. The best phenyl inhibitors display a functionally defined inhibitory constant (K1) of 75 mM, and it can be estimated that inhibitor concentrations over 20 mM would be necessary to obtain minimal clinically significant benefit. Furthermore, with the variety of modifications tested here, no impressive increase in activity could be achieved over that found in the simplest phenyl compounds.     

The role of fluorine in stabilizing the bioactive conformation of dihydroorotate dehydrogenase inhibitors

Dihydroorotate dehydrogenase (DHODH) is an important drug target due to its prominent role in pyrimidine biosynthesis. Leflunomide and brequinar are two well-known DHODH inhibitors, which bind to the enzyme in the same pocket with different binding modes. We have recently realized a series of new inhibitors based on the 4-hydroxy-1,2,5-oxadiazole ring, whose activity profile was found to be closely dependent on the degree of fluorine substitution at the phenyl ring adjacent to the oxadiazole moiety; a positive influence of fluorine on the DHODH inhibitory potency was observed previously [Baumgartner et al. (2006) J Med Chem 49:1239–1247]. Potential energy surface scans showed that fluorine plays an important role in stabilizing the bioactive conformations; additionally, fluorine influences the balance between leflunomide-like and brequinar-like binding modes. These findings may serve as a guide to design more potent DHODH inhibitors.     

NMR studies of fluorinated serine protease inhibitors

Powers and co-workers have provided evidence that thiobenzyl N-heptafluorobutyrylanthranilate (I) is an extremely potent inhibitor of serine proteases, especially alpha-chymotrypsin (Teshima, T., Griffin, J. C., and Powers, J. C. (1982) J. Biol. Chem. 257, 5085-5091). We have prepared additional derivatives of this structure in which fluorine substitutions have been made on the aromatic rings and have attempted to carry out fluorine NMR studies of the interaction of Powers' compound and these new derivatives with chymotrypsin. The solubility of all inhibitors examined in solvent systems compatible with the retention of native enzyme structure is extremely low. While some nmr evidence for complex formation could be obtained, preparations of the complexes examined were metastable and precipitation of the inhibitor eventually limits the amount of complex that can be present in solution to such low levels that nmr experiments are impractical. An unusual effect of solvent composition on fluorine chemical shifts suggests that the conformation of the inhibitors in aqueous solution and when bound to the enzyme is different from that in organic solvents.     

Benzofuran- and furan-2-yl-(phenyl)-3-pyridylmethanols: Synthesis and inhibition of P450 aromatase

A series of benzofuran-2-yl-(phenyl)-3-pyridylmethanol derivatives were prepared using an efficient 1-step procedure in good yields. In addition furan-2-yl-(phenyl)-3-pyridylmethanol derivatives were also prepared to determine the effect of the benzene ring in benzofuran with respect to inhibitory activity. The pyridylmethanol derivatives were all evaluated in vitro for inhibitory activity against aromatase (P450_AROM, CYP19), using human placental microsomes. The benzofuran-2-yl-(phenyl)-3-pyridylmethanol derivatives showed good to moderate activity (IC₅₀=1.3–25.1?μM), which was either better than or comparable with aminoglutethimide (IC₅₀=18.5?μM) but lower than arimidex (IC₅₀=0.6?μM), with the 4-methoxyphenyl substituted derivative displaying optimum activity. Molecular modelling of the benzofuran-2-yl-(4-fluorophenyl)-3-pyridylmethanol derivative suggested activity to reside with the (S)-enantiomer. The furan-2-yl-(phenyl)-3-pyridylmethanol derivatives were devoid of activity indicating the essential role of the benzene ring of the benzofuran component for enzyme binding.     

Action of Plant Growth Regulators. IV. Adsorption of Unsubstituted and 2,6-Dichloro-aromatic Acids to Oat Monolayers

The adsorption of chloro-aromatic acids to monomolecular layers of oat squashes is reported in earlier papers but it was not possible by the technique used, to measure unambiguously the adsorption of unsubstituted and 2,6-dichloro-aromatic acids. This has now been achieved by a modification of the earlier method and involves assessments of competitive adsorption between the unknown acid and a standard acid, using measurements of surface potential.

Benzoic and phenoxyacetic acids were not adsorbed but phenylacetic acid was weakly adsorbed. The second ring in naphthalene and naphthoxyacetic acids greatly increased adsorption. Substitution of the 2 and 6 positions in the phenyl and phenoxyacetic acids resulted in low adsorption but 2,6-disubstituted phenoxybutyric and benzoic acids were more highly adsorbed.

The adsorption values from earlier work are combined and discussed in relation to the growth-regulating activity of the acids. It is conciuded that there is no direct relation embracing all acids between adsorption and activity, notable exceptions being those substituted by chlorine in the 3-position of the aromatic ring. However, for a number of acids it is suggested that activity is limited not only by their ability to interact at enzyme sites but also by the amount of acid immobilised by adsorption when moving to these sites. It is also concluded that the hydrophilic/lipophilic balance of a growth regulator sometimes used as a guide to its activity, is an unreliable indication of interfacial behaviour.

     

Novel diphenylalkyl piperazine derivatives with high affinities for the dopamine transporter

The novel diphenyl piperazine derivatives containing the phenyl substituted aminopropanol moiety, including 1-[4,4-bis(4-fluorophenyl)butyl]-4-[2-hydroxy-3-(phenylamino)propyl]piperazine 1, which were modified at the connective between the diphenyl and piperazine moieties, have been found to be potent dopamine uptake inhibitors. To study the further structure-activity relationship (SAR) of these compounds, a new series was synthesized, with modifications at the 2-hydroxy-3-phenylaminopropyl moiety of 1. The series was evaluated for dopamine transporter (DAT) binding affinity with [3H]GBR12935 in rat striatal membranes. Most of the compounds showed moderate to high DAT binding affinities and some were approximately equivalent in activity to compound 1 or GBR12909 as a dopamine uptake inhibitor, with IC(50) values of nanomolar range. The SAR suggested that on exhibiting a potent interaction with the DAT, there is probably a steric limitation around the benzene ring of the phenylamino moiety of 1, allowing only small-sized substituents with the exception of basic moieties at the 4-position. In addition, the SAR at the 3-amino-2-propanol moiety of 1 suggested that either the nitrogen atom with an electron donating substituent or the unsubstituted nitrogen atom and also the hydroxy group are desirable for elicitation of a potent DAT binding affinity.     

Very strong metal ligand aromatic cation-π interactions in transition metal complexes: intermolecular interaction in tetraphenylborate salts

Strong intermolecular interactions between ligands in cationic metal complexes and aromatic rings of tetraphenylborate anion, so-called metal ligand aromatic cation-π (MLACπ) interactions, were found by screening Cambridge Structural Database. Distances between phenyl ring and ligand are shorter in these structures than in previously reported MLACπ interactions by 0.2 Å.