Assessment of the role of TRH in the release of [3H]-dopamine from rat nucleus accumbens-lateral septum slices

We have studied [3H]-dopamine ([3H]-DA) release from rat nucleus accumbens lateral septum slices in response to various paradigms aimed at increasing endogenous or exogenous thyrotropin releasing hormone (TRH) concentrations in the extracellular space. High KCl concentrations significantly enhanced [3H]-DA release by fourfold. TRH (10(-4) or 5 x 10(-4) M) did not affect [3H]-DA release. The release of [3H]-DA was not stimulated by TRH either in the presence of N-1-carboxy-2-phenylethyl (N(im)benzyl)-histidyl-beta naphthylamide, a specific pyroglutamyl peptidase II inhibitor, or that of specific inhibitors of prolyl endopeptidase and pyroglutamyl peptidase I. None of the peptidase inhibitors modified the [3H]-DA release by themselves. These results suggest that the TRH stimulation of [3H]-DA release in vitro observed in previous studies is not due to peptide inactivation but may be due to a nonspecific effect. TRH enhancement of DA release in nucleus accumbens in vivo may not be the result of a direct effect of TRH on DA terminals.     

Hemodynamic and ventilatory effects associated with increasing inverse inspiratory-expiratory ventilation

Rational modification of an existing cationic alpha-helical antimicrobial peptide (ESF1) for improved activity by increasing amphipathicity was undertaken. ESF1 and two variants (GR7 and SA3) were synthesized and tested for activity range, minimum inhibitory concentration, and hemolytic activity. Biological activity was related to structure as determined by circular dichroism. The substitution of arginine for glycine in position seven was found to increase antimicrobial activity without effecting hemolysis. Increased activity was related to stronger alpha-helix formation in buffer. Increased beta-sheet formation in micellar SDS was observed and speculated to be due to a stronger ability of the variants to form multimolecule complexes, a feature consistent with existing models of cationic peptide activity.     

Stereoselective reversible ketone formation from 10-hydroxylated nortriptyline metabolites in human liver

1. E- and Z-10-hydroxynortriptyline are major metabolites of amitriptyline and nortriptyline in man. Upon incubation with human liver microsomes or cytosol, these metabolites were oxidized to the corresponding ketones, E- and Z-10-oxonortriptyline. (+)-E- and (+)-Z-10-hydroxynortriptyline were distinctly preferred over the (-)-isomers as substrates. NADP+ supported the oxidation in cytosol, whereas in microsomes NAD+ was the best cofactor. 2. Incubation of E- and Z-10-oxonortriptyline with NADPH and cytosol resulted in the nearly exclusive formation of (+)-E- and (+)-Z-10-hydroxynortriptyline. Kinetic analysis revealed high-affinity reduction (K(m) 1-2 microM) of the two ketones and an additional low-affinity component with the E-isomer. 10-Oxonortriptyline reduction was also catalysed by rabbit, but not by rat or guinea pig liver cytosol. 3. With [4-3H]NADPH as cosubstrate, tritium was incorporated into E- and Z-10-hydroxynortriptyline preferentially from the pro-4R position. Redox cycling of (+)-E- and (+)-Z-10-hydroxynortriptyline in cytosol in the presence of NAD- and NADPH was indicated by 3H incorporation from [pro-4R-3H]NADPH. 4. Recombinant human carbonyl reductase catalysed low-affinity reduction of E-10-oxonortriptyline with preferential transfer of the pro-4S-3H of labelled NADPH. 5. Ketone reduction in cytosol was strongly inhibited by 9,10-phenanthrenequinone and dehydrolithocholic acid and moderately by other 3-oxo steroids and some anti-inflammatory drugs. 6. The high-affinity reduction of E- and Z-10-oxonortriptyline and the oxidation of the alcohols in cytosol are probably mediated by a member of the aldo-keto reductase family of enzymes.     

p21WAF1/Cip1 expression is associated with cell differentiation but not with p53 mutations in squamous cell carcinomas of the larynx

The anti-metastatic effect of Z-100, an immunomodulatory arabinomannan extracted from Mycobacterium tuberculosis, was investigated in mice bearing B16 melanoma cells. Treatment of BF10 mice implanted with high metastatic B16F10 melanoma cells with a 10 mg/kg dose of Z-100 resulted in the reduction of experimental pulmonary metastasis as compared with that of BF10 mice treated with saline. The number of pulmonary metastatic colonies in BF1 mice (mice implanted with low metastatic B16F1 melanoma cells) was greatly increased after the inoculation of CD4+ CD11b+ CD281+ TCR alphabeta+ type 2 T cells (F10-Th2 cells) derived from BF10 mice, while only a few metastatic colonies were demonstrated in lungs of BF1 mice inoculated with naive CD4+ T cells. However, the numbers of metastatic colonies in BF1 mice were not increased when they were inoculated with the F10-Th2 cell fraction derived from Z-100-treated BF10 mice and the generation of F10-Th2 cells in BF10 mice was effectively suppressed by the Z-100 treatment. These results suggest that Z-100 inhibits pulmonary metastasis of B16 melanoma through the regulation of tumor-associated Th2 cells, which are a key cell in the acceleration of tumor metastasis.     

DNA ploidy analysis in breast carcinoma. Comparison of unfixed and fixed tissue analyzed by image and flow cytometry

We present here the isolation and characterization of four antimicrobial peptides produced by a European bumblebee Bombus pascuorum. A 51-residue insect defensin was characterized which, like the Apis mellifera defensins, had a highly conserved 12-residue extension to its C-terminal compared to defensins from other insects. Monoisotopic mass analysis of the C-terminal of B. pascuorum defensin confirmed that this molecule was C-terminally amidated. This defensin showed strong anti-Gram-positive activity and some anti-fungal activity; also, in contrast to other insect defensins, it showed anti-Gram-negative activity. A 17-residue apidaecin was characterized, showing anti-Gram-negative activity, and differing by a single amino acid substitution from the A. mellifera apidaecin. A 39-residue abaecin was isolated, the largest proline-rich antimicrobial peptide characterized to date, which showed activity against both Gram-negative and Gram-positive bacteria. Finally, we isolated an N-terminally blocked molecule, with a molecular mass of 10,122 Da, which showed activity against Gram-negative bacteria only. These characteristics are reminiscent of hymenoptaecin from the honeybee A. mellifera, but a definitive characterization of this molecule awaits further work. No evidence of lysozyme activity was found in the haemolymph of challenged or naive B. pascuorum.     

Alterations in cholesterol sulfate and its biosynthetic enzyme during multistage carcinogenesis in mouse skin

A novel series of nonpeptide angiotensin II antagonists containing the acrylamide group at the 4-position of the imidazole ring was synthesized and their antagonistic activity was examined by functional assay in rabbit aorta. The acrylamide group was selected as a large lipophilic surrogate for the chloro group of EXP3174. A structure-activity relationship study of the acrylamide moiety has shown that substitution at the 4-position with the N-methyl-3,3-dimethylacrylamide group resulted in the optimal compound, 2-butyl-4-[(3,3-dimethylacryloyl)methyl-amino]-1-[[2'-(1H-tetra zol-5- yl)biphenyl-4-yl]methyl]-1H-imidazole-5-carboxylic acid (1), which was superior to EXP3174 in vitro. Since 1 showed only poor activity against angiotensin II-induced pressor response in rats after oral administration, the carboxylic acid function of 1 was converted into prodrug esters (13). Among these, the 1-[(ethoxycarbonyl)oxy]ethyl ester (13a) showed the most potent and longest-lasting activity when given orally to rats. When administered orally to conscious furosemide-treated dogs, 13a showed an approximately 3-fold increased hypotensive activity in comparison with DuP 753. These data suggest that 13a may be an useful agent for the treatment of angiotensin II-dependent diseases, such as hypertension.     

N-acetylaspartylglutamate acetoxymethyl triester (NAAG.AM) as a tool for loading the neuropeptides NAAG and succinimidyl-NAAG into intact cells: effect on [3H]-dopamine exocytosis

Although N-acetylaspartylglutamate (NAAG) is one of the neuropeptides found in highest concentrations in the mammalian central nervous system, its functional role in neuronal signaling has not been definitively established. In some neuronal populations, NAAG is concentrated in nerve terminals and thus, it may play a role in the cytoplasmic events underlying neurotransmitter exocytosis. In the present study we have validated the use of the synthetic derivative NAAG-acetoxymethyl triester (NAAG.AM) as a tool to increase the intracellular levels of the peptide and assessed the ability of NAAG to regulate [3H]-dopamine ([3H]-DA) secretion in PC12 cells. Enzymatic degradation of NAAG.AM by nonspecific brain esterases resulted in the progressive formation of NAAG and succinimidyl-NAAG (Asu-NAAG). However, only 8% of NAAG.AM was converted to NAAG. Significant amounts of NAAG (1 nmol/mg protein) were demonstrable in cultures of the neuroblastoma cell line N2A following incubation with NAAG.AM for 2 h, with the concentration of (Asu)-NAAG being at least 100-fold higher. The pheochromocytoma cell line PC12 was used to assess the influence of loaded NAAG derivatives on [3H]-DA exocytosis. Incubation with 0.1-1 mM NAAG.AM did not affect the basal efflux or total content of [3H]-DA. However, it induced a dose-dependent decrease of [3H]-DA secretion in response to 56 mM KCl depolarization reaching an inhibition of 49% with 1 mM NAAG.AM. In contrast, NAAG.AM did not affect secretion induced by the calcium ionophore A23187 (100 microM). The present study validates the use of NAAG.AM as a tool to load NAAG derivatives into intact cells and provides preliminary evidence for an intracellular role of the peptide.     

Regioselectivity and substrate concentration-dependency of involvement of the CYP2D subfamily in oxidative metabolism of amitriptyline and nortriptyline in rat liver microsomes

Kinetic analysis of the metabolism of amitriptyline and nortriptyline using liver microsomes from Wister rats showed that more than one enzyme was involved in each reaction except for monophasic amitriptyline N-demethylation. The Vmax values particularly in the high-affinity sites for E-10-hydroxylation of both drugs were larger than those for Z-10-hydroxylations. Their E- and E-10-hydroxylase activities in Dark-Agouti rats, which are deficient for CYP2D1, were significantly lower than those in Wistar rats at a lower substrate concentration (5 microM). The strain difference was reduced at a higher substrate concentration (500 microM). A similar but a smaller strain difference was also observed in nortriptyline N-demethylase activity, and a pronounced sex difference (male > female) was observed in N-demethylation of both drugs in Wistar and Dark-Agouti rats. The reactions with the strain difference were inhibited concentration-dependently by sparteine, a substrate of the CYP2D subfamily, and an antibody against a CYP2D isoenzyme. The profiles of these decreased metabolic activities corresponded to that of the lower metabolic activities in Dark-Agouti rats. These results indicated that a cytochrome P450 isozyme in the CYP2D subfamily was involved in E- and Z-10-hydroxylations of amitriptyline and nortriptyline in rat liver microsomes as a major isozyme in a low substrate concentration range. It seems likely that the CYP2D enzyme contributes to nortriptyline N-demethylation.     

A single amino acid substitution in the antimicrobial defense protein cecropin B is associated with diminished degradation by leaf intercellular fluid

Degradation is one of several factors that may affect the level of accumulation of transgene products in plants. In plants engineered to secrete antimicrobial proteins to the intercellular compartment of leaves, the degenerative activity of proteases residing in leaf intercellular fluid (IF) could be critical to achieving the expected transgene function. We synthesized a structural analogue (MB39) of the antibacterial protein cecropin B and compared the susceptibility of both proteins to degradation in vitro by IF extracted from leaves of various crops. The half-life of the two proteins in the various IF extracts ranged from 3 min to 25.5 h, with the analogue MB39 displaying the longer half-life in IF from nine of 10 species. Overall, the half-life of MB39 averaged 2.9 times greater than that of cecropin B. Analysis of the peptides produced by endopeptidase activity in potato iF indicated that the 5.7-fold lower degradation rate of MB39 was associated with the substitution of valine for methionine at residue 11 of cecropin B. These findings point to the possibility of tailoring antimicrobial protein genes to reduce the rate of protein degradation in a particular target crop.     

Synthesis and ligand binding studies of 4'-iodobenzoyl esters of tropanes and piperidines at the dopamine transporter

Four analogs and two homologs of cocaine, designed as potent cocaine antagonists, were synthesized. The SN2 reaction between ecgonine methyl ester (13) or appropriately substituted piperidinol (19, 21) and appropriately substituted 4-iodobenzoyl chloride gave 4-iodobenzoyl esters of tropanes and piperidines (5-8). 2'-Hydroxycocaine (9) was obtained from 2'-acetoxycocaine (12) by selective transesterification with MeOH saturated with dry HCl gas. 2'-Acetoxycocaine (12) was synthesized from acetylsalicyloyl chloride (23) and ecgonine methyl ester (13). The binding affinities of these compounds were determined at the dopamine transporter for the displacement of [3H]WIN-35428. An iodo group substitution at the 4'-position of cocaine decreased dopamine transporter binding potency, while a hydroxy or acetoxy group at the 2'-position exhibited increased binding potency for the dopamine transporter compared to cocaine (10- and 3.58-fold, respectively). 2'-Hydroxylation also enhanced the bidning potency of 4'-iodococaine (5) by 10-fold. Replacement of the tropane ring with piperidine led to poor binding affinities.     

Function of Pro-185 in the ProCys of conserved motif IV in the EcoRII [cytosine-C5]-DNA methyltransferase

ProCys in the conserved sequence motif IV of [cytosine-C5]-DNA methyltransferases is known to be part of the catalytic site. The Cys residue is directly involved in forming a covalent bond with the C6 of the target cytosine. We have found that substitution of Pro-185 with either Ala or Ser resulted in a reduced rate of methyl group transfer by the EcoRII DNA methyltransferase. In addition, we observed an increase in the Km for substrate S-adenosyl-L-methionine (AdoMet), but a decrease in the Km for substrate DNA. This is reflected in minor changes in kcat/Km for DNA, but in 10- to 100-fold reductions in kcat/Km for AdoMet. This suggests that Pro-185 is important to properly orient the activated cytosine and AdoMet for methyl group transfer by direct interaction with AdoMet and indirectly via the Cys interaction with cytosine.     

Characterization of a human papillomavirus type 16 variant-dependent neutralizing epitope

We have determined that three type-specific and conformationally dependent monoclonal antibodies, H16.E70, H16.U4, and H16.V5, neutralize pseudotype human papillomavirus type 16 (HPV16) virions in vitro. H16.U4 and H16.V5 neutralized pseudotype virions derived from the German HPV16 variant 114K and the Zairian variant Z-1194 with equal efficiency. In contrast, neutralization of Z-1194 pseudotype virions by H16.E70 was two orders of magnitude weaker than neutralization of 114K pseudotype virions. This difference correlated with enzyme-linked immunosorbent assay reactivity of H16.E70 to L1 virus-like particles of the two variants. A substitution at residue 282 of L1 was responsible for this differential reactivity, suggesting that this residue constitutes part of the H16.E70 epitope.     

EcoRV-T94V: a mutant restriction endonuclease with an altered substrate specificity towards modified oligodeoxynucleotides

Synthetic oligodeoxynucleotides with single methyl phosphonate (mp) substitutions were used for an analysis of the contribution of phosphate contacts to the recognition of the cleavage site by the restriction endonuclease EcoRV. Only in the last position within the recognition sequence, is the methyl phosphonate substitution tolerated by the enzyme. The wild-type enzyme cleaves the Sp diastereomer of the oligodeoxynucleotide GACGATATmpCGTC and the unmodified sequence with equal rates, whereas the Rp diastereomer is cleaved much more slowly. Inspection of the crystal structure of an EcoRV-DNA complex revealed that the non-bridging oxygen atoms of the phosphodiester bond between the T and C bases are in hydrogen bonding distance of the hydroxyl group of the amino acid Thr94. We therefore tried to engineer a variant of EcoRV that would prefer a methyl phosphonate linkage over a normal phosphodiester bond and produced mutants with amino acid exchanges at position 94. One of them, Thr94Val, shows a dramatically reduced activity towards the unmodified DNA and does not accept the Rp diastereomer, but cleaves the Sp diastereomer with the same rate as wild-type EcoRV. Its selectivity, i.e. the ratio of cleavage rates determined for the unmodified and modified substrates, differs by three orders of magnitude from that of the wild-type enzyme.     

Enhancement of antimicrobial activity of neuropeptide Y by N-terminal truncation

The activity of neuropeptide Y (NPY) against Candida albicans, which was revealed to be fungicidal, was enhanced significantly by the truncation of amino acid residues at the N terminus. The most active peptides (MICs, approximately 1 microM) were about 10-fold more potent than the intact NPY (MIC, approximately 10 microM). The enhancement was weakened by the replacement of the N terminus by negatively charged residues and/or acylation of the alpha-amino group. These results suggest that only the alpha-helical region of NPY is necessary for the antimicrobial activity and that the net charge of the peptide is important for the activity.     

Potent inactivation of cathepsins S and L by peptidyl (acyloxy)methyl ketones

Peptidyl (acyloxy)methyl ketones (Z-Aa-Aa-CH2-O-CO-R), a new class of irreversible inhibitors whose chemical reactivity can be modulated by varying the substitution pattern of the carboxylate leaving group, are shown to be extremely potent inactivators of the lysosomal cysteine proteinases cathepsin L and cathepsin S. The highest k2/Ki values measured were found to exceed 10(6) M-1s-1 for both cathepsin L and cathepsin S. The rate of inactivation can be controlled by varying the dipeptidyl moiety or the carboxylate leaving group, with the second-order rate constants for both enzymes found to be strongly dependent on the pKa values of the leaving group. The specificities of the cathepsins S and L reveal a different selectivity towards the nature of substitution of the aryl P' leaving group of the inhibitor. This new inhibitor class opens the possibility of the design of selective and specific inhibitors for lysosomal cysteine proteinases.     

Study on major metabolites of 3H-1,2-dihydro-2-(4-methylphenylamino)-methyl-1-pyrrolizinone in rabbits]

The metabolites of a 750 mg oral dose of Z-47 [3H-1, 2-dihydro-2-(4-methylphenylamino) methyl-1-pyrrolizinone], a new anti-inflammatory and analgesic agent, in rabbit urine were separated and detected with high performance liquid chromatographic method. On basis of the chromatographic behavior of Z-47 metabolites and biotransformation pathways of drugs with partial structure of Z-47, the carboxylic derivative of Z-47 [4-(3H-1, 2-dihydro-1-pyrrolizinone-2-methylamino) benzoic acid] was proposed as a potential metabolite so that the compound was synthesized. The authentic substance was then compared with one of the metabolites by the chromatographic retention time and the ratio of their UV-absorbances at two wavelengths. The enzyme-hydrolyzed product of another metabolite was also analysed. It was consequently confirmed that the carboxylic derivative of Z-47 and its acyl beta-D-glucuronide are major metabolits of Z-47 in rabbits.     

Farnesyl diphosphate-based inhibitors of Ras farnesyl protein transferase

The rational design, synthesis, and biological activity of farnesyl diphosphate (FPP)-based inhibitors of the enzyme Ras farnesyl protein transferase (FPT) is described. Compound 3, wherein a beta-carboxylic phosphonic acid type pyrophosphate (PP) surrogate is connected to the hydrophobic farnesyl group by an amide linker, was found to be a potent (I50(FPT) = 75 nM) and selective inhibitor of FPT, as evidenced by its inferior activity against squalene synthetase (I50(SS) = 516 microM) and mevalonate kinase (I50(MK) = > 200 microM). A systematic structure-activity relationship study involving modifications of the farnesyl group, the amide linker, and the PP surrogate of 3 was undertaken. Both the carboxylic and phosphonic acid groups of the beta-carboxylic phosphonic acid PP surrogate are essential for activity, since deletion of either group results in 50-2600-fold loss in activity (6-9, I50 = 4.6-220 microM). The farnesyl group also displays very stringent requirements and does not tolerate one carbon homologation (12, I50 = 17.7 microM), substitution by a dodecyl fragment (14, I50 = 9 microM), or introduction of an extra methyl group at the allylic position (18, I50 = 55 microM). Modifications around the amide linker group of 3 were more forgiving, as evidenced by the activity of N-methyl analog (21, I50 = 0.53 microM), the one carbon atom shorter farnesoic acid-derived retroamide analog (32, I50 = 250 nM), and the exact retroamide analog (49, I50 = 50 nM). FPP analogs such as 3, 32, and 49 are novel, potent, selective, small-sized, nonpeptidic inhibitors of FPT that may find utility as antitumor agents.     

Broad spectrum matrix metalloproteinase inhibitors: an examination of succinamide hydroxamate inhibitors with P1 C alpha gem-disubstitution

A series of P1 C alpha gem-disubstituted succinamide hydroxamate matrix metalloproteinase inhibitors were prepared stereoselectively and evaluated in vitro for their ability to inhibit MMP-1, MMP-2, and MMP-3. It was found that while methyl/allyl substitution as in 2 and 18 provided compounds that were broad spectrum inhibitors and nearly equipotent with parent inhibitor 1, a larger group such as bis-allyl as in 13 or gem-cyclopentyl as in 14 significantly reduced enzyme inhibition.     

Pyrrolidine-3-carboxylic acids as endothelin antagonists. 3. Discovery of a potent, 2-nonaryl, highly selective ETA antagonist (A-216546)

Previously we have reported the discovery of ABT-627 (1, A-147627, active enantiomer of A-127722), a 2,4-diaryl substituted pyrrolidine-3-carboxylic acid based endothelin receptor-A antagonist. This compound binds to the ETA receptor with an affinity (Ki) of 0. 034 nM and with a 2000-fold selectivity for the ETA receptor versus the ETB receptor. We have expanded our structure-activity studies in this series, in an attempt to further increase the ETA selectivity. When the p-anisyl group of 1 was replaced by an n-pentyl group, the resultant antagonist 3 exhibited substantially increased ETB/ETA activity ratio, but a decreased ETA affinity. Structure-activity studies revealed that substitution and geometry of this alkyl group, and substitution on the benzodioxolyl ring, are important in optimizing this series of highly ETA selective antagonists. In particular, the combination of a (E)-2,2-dimethyl-3-pentenyl group and a 7-methoxy-1,3-benzodioxol-5-yl group provided hydrophobic compound 10b with subnanomolar affinity for human ETA receptor subtype and with an ETB/ETA activity ratio of over 130000. Meanwhile, synthetic efforts en route to olefinic compounds led to the discovery that 2-pyridylethyl (9o) and 2-(2-oxopyrrolidinyl)ethyl (9u) replacement of the p-anisyl group of 1yielded very hydrophilic ETA antagonists with potency and selectivity equal to those of 10b. On the basis of overall superior affinity, high selectivity for the ETA receptor (Ki, 0.46 nM for ETA and 13000 nM for ETB), and good oral bioavailability (48% in rats), A-216546 (10a) was selected as a potential clinical backup for 1.     

History and future of antimicrobial diaminopyrimidines

Numerous pyrimidine and purine analogs were synthesized in the late forties in G.H. Hitchings' group as potential nucleic acid antagonists. Several key observations finally led to the selection of pyrimethamine as an antimalarial and trimethoprim (TMP) as an antibacterial agent: i) 2,4-diamino-5-substituted pyrimidines interfered with folic acid utilization rather than being thymine antagonists as expected; ii) a large degree of selectivity could be obtained by suitable substitution and non-toxic diaminopyrimidines with preferential antimicrobial activity were found; iii) the identification of dihydrofolate reductase (DHFR) as the specific target for aminopterin and methotrexate in 1958 and for TMP in 1965, and the diversity of this enzyme in different species. Although several diaminopyrimidines were initially tested as monotherapies in clinical trials, the pronounced synergism between some of these new compounds and sulfonamides seen against Plasmodium was finally also applied in the development of TMP. Its combination with sulfamethoxazole later proved one of the most successful agents ever developed. Further milestones in the application of antimicrobial DHFR inhibitors were the introduction of TMP alone in 1972, the launch of a new combination of tetroxoprim, a close TMP-analog, with sulfadiazine, and the successful clinical trials with brodimoprim, which proved clinically efficacious and safe with once-daily low dose monotherapy. Efforts to discover new antimicrobial DHFR inhibitors have recently intensified. DHFRs from important gram-positive problem organisms such as S. aureus, S. epidermidis have been cloned and sequenced, as well as DHFRs from opportunistic pathogens such as P. carinii, T. gondii, and of mycobacteria. DHFR crystal structures from several of these organisms are available to aid rational inhibitor design.(ABSTRACT TRUNCATED AT 250 WORDS)