Anticholinesterase Action of a Bromine Compound Isolated from Human Cerebrospinal Fluid

Abstract: L-l-Methylheptyl-γ-bromoacetoacetate was found to be a competitive inhibitor of the acetylcholines-terases (electric eel, K_i= 17.2 μM; rat brain, K_i= 32.6 μM) and of butyrylcholinesterase (horse serum, K_i= 1.2 μM). The L-isomer was a more effective inhibitor than the D-isomer. The bromine atom at the γ-position of the acidic moiety, the specific length of the carbon chain constituting the secondary alcohol moiety, and the presence of the ketone radical at the acidic moiety of the ester were necessary for the anticholinesterase action. 1-Methyl-heptyl-γ-bromoacetoacetate formed a complex with acetylcholinesterase or butyrylcholinesterase without hydrolysis of its own molecule.     

Action of the Organophosphorous Insecticide Parathion on the Free-Living Marine Dinoflagellate Prorocentrum micans Ehrbg.

Growth of cultures of the dinoflagellate Prorocentrum micans Ehrbg. was slowed by parathion >1 ppm. Parathion also decreased chlorophyll content and perturbed cellular ultrastructure, eliciting especially plastoglobuli in their chloroplasts. Toxicity of this organophosphorous insecticide is unlikely to be due to its anticholinesterase activity since P. micans appears not to contain cholinesterase. Fluorescence kinetics show that parathion affects the photosynthetic system, particularly photosystem II.     

On the Mechanism of Action of H2O2 in the Cellular Stress

We propose a hypothesis according to which the reactive and reduced species of oxygen could be the intracellular inducers of the stress (or “heat-shock”) response. This hypothesis is based on the following observations on Drosphila cells: -a) the return to normoxia after 24 h anaerobiosis is suficient to induce the synthesis of the ‘heat shock’ proteins without elevation of temperature together with a rapid increase of O₂ consumption; -b) hydrogen peroxide introduced in the culture medium induces the early transcrip-tional activation of the ‘heat shock’ genes (maximal after 5 minutes); -c) hydrogen peroxide added to cellular extracts in vitro (thus acting as an intracellular metabolite) activates instantaneously the binding capacity of a ‘heat shock’ factor to a DNA ‘heat shock’ regulatory element. Thus, hydrogen peroxide, and possibly other reactive reduced species ofoxygen, could trigger the onset of the stress (or ‘heat shock’) response.     

植物生长素的作用机制

介绍了生长素受体、生长素诱导基因以及生长素诱导ATPase活化,特别对近几年来生长素信号转导的研究进展进行了概述.     

Studies on the Mechanism of Interferon Action

Interferon does not inactivate viruses or viral RNA. Virus growth is inhibited in interferon-treated cells, but apart from conferring resistance to virus growth, no other effect of interferon on cells has been definitely shown to take place. Interferon binds to cells even in the cold, but a period of incubation at 37°C is required for development of antiviral activity. Cytoplasmic uptake of interferon has not been unequivocally demonstrated. Studies with antimetabolites indicate that the antiviral action of interferon requires host RNA and protein synthesis. Experiments with 2-mercapto-1(β-4-pyridethyl) benzimidazole (MPB) suggest that an additional step is required between the binding and the synthesis of macromolecules. Interferon does not affect the adsorption, penetration, or uncoating of RNA or DNA viruses, but viral RNA synthesis is inhibited in cells infected with RNA viruses. The main action of interferon appears to be the inhibition of the translation of virus genetic information probably by inhibiting the initiation of virus protein synthesis.     

Mechanism of Action of Showdomycin

The effect of showdomycin on the syntheses of deoxyribonucleotides from various pyrimidine and purine derivatives was studied in cell-free systems from E. coli.

The formations of deoxycytidine phosphates, deoxyuridine phosphates, deoxyguanosine phosphates and deoxyadenosine phosphates from the corresponding ribonucleoside diphosphates were all inhibited by low concentrations of showdomycin. The formation of deoxythymidine phosphates from dUMP was also very susceptible to the antibiotic. These inhibitory actions of showdomycin could be reversed by a sulfhydryl compound (mercaptoethanol) but not by nucleosides, in contrast to a previous finding that the inhibitory action of this antibiotic on the cell growth was reversed by compounds belonging to both of these groups.

N-Ethylmaleimide (NEM), a thiol reagent which has a structure related to the aglycone moiety of showdomycin, was also found to be a potent inhibitor of both the reduction of CDP and the methylation of dUMP as showdomycin. A mercurial thiol reagent, p-chloromercuribenzoic acid (PCMB), however, was found to be inactive against the methylation of dUMP although the salvage synthesis of dUMP was inhibited by low concentrations of this reagent.

The formations of deoxythymidine phosphates and of deoxyuridine phosphates from their respective pyrimidine bases and a deoxyribosyl donor were quite resistant to showdomycin.     

Mechanism of Action of Showdomycin

¹⁴C-Labelled showdomycin was rapidly taken up by Escherichia coli K-12 cells. The showdomycin uptake was highly temperature dependent, sensitive to azide and N-ethyl-maleimide, but was only partially inhibited by treatment with high concentration of iodoacetic acid.

The uptake of showdomycin was inhibited by a wide variety of nucleosides but not by purine and pyrimidine bases, nucleotides, ribose or ribose-5-phosphate. The inhibition of showdomycin uptake by adenosine was of a competitive type.

Since nucleosides inhibited the uptake of showdomycin but did not facilitate its efflux, they must play a role of inhibitors to the entry of the antibiotic into cells.

Removal of extracellular showdomycin by washing, or inhibition of its subsequent entry into cells by the addition of nucleosides or sulfhydryl compounds resulted in a rapid decrease in the intracellular level of the antibiotic during subsequent incubation.     

Mechanism of Action of Showdomycin

Among the syntheses of DNA, RNA and protein in Escherichia coli cells, the DNA synthesis was found to be preferentially inhibited at lower concentrations of showdomycin. At such lower concentrations of this antibiotic, serious decreases in the synthesis of deoxycytidine phosphates and in de novo synthesis of deoxythymidine phosphates were found in parallel with the decrease in the synthesis of DNA, although the syntheses of other pyrimidine nucleotides were not significantly diminished. The salvage synthesis of deoxythymidine phosphates was very resistant to this antibiotic. The inhibitory action of this antibiotic on DNA synthesis could be reversed by the concomitant addition of a thiol compound or a nucleoside. When a nucleoside was added after the completion of the inhibition by showdomycin, the recovery of the DNA synthesis from the inhibition was detected only after the recovery of the syntheses of pyrimidine ribotides, pyrimidine deoxyribotides and RNA have become distinct.     

Mechanism of Action of Showdomycin

Showdomycin, 2-β-d-ribofuranosylmaleimide, inhibited the incorporation of amino acids and purine and pyrimidine bases into macromolecules in E. coli K-12 cells at low concentrations. The inhibitory action of showdomycin could be reversed by the addition of a nucleoside or a sulfhydryl compound. In marked contrast to common nucleosides, the pseudouridine showed no such effect. This may indicate that the N-glycosyl linkage in the nucleoside is a structural requirement for its reversing activity on the inhibitory action of showdomycin.

N-Ethylmaleimide, which has structural similarity to showdomycin, inhibited the incorporation of amino acids and purine and pyrimidine bases as well as showdomycin. The inhibitory action of N-ethylmaleimide, however, was not reversed by the addition of a nucleoside. This may indicate that there may be difference in the mechanism of the inhibitory action between N-ethylmaleimide and showdomycin.     

胰岛素原C肽作用机制

Ｃ肽是胰岛素原中连接ＡＢ两条链的连接肽。在胰岛 β细胞分泌颗粒中 ,胰岛素原经蛋白酶裂解 ,形成等摩尔由ＡＢ链组成的胰岛素和Ｃ肽 ,然后分泌并进入血液。Ｃ肽的种族差异很大 ,其中人Ｃ肽含 31个氨基酸。在胰岛素原分子中Ｃ肽对胰岛素原分子的折叠、二硫键的正确配对等分子结构的形成起重要作用 ,而血液中游离Ｃ肽的生理功能却一直不清楚。近来的研究发现 ,给予Ｉ型糖尿病大鼠超生理剂量的人Ｃ肽配伍胰岛素治疗 ,能防止血管、神经机能障碍[1] ,长期 (3个月 )给予胰岛素配伍Ｃ肽 ,可使Ｉ型糖尿病病人减少尿白蛋白排泄率 ,改善肾功能和自主…     

Mechanism of Action of the Antifungal Antibiotic Pyrrolnitrin

Pyrrolnitrin at 10 mug/ml inhibited the growth of Saccharomyces cerevisiae, Penicillium atrovenetum, and P. oxalicum. The primary site of action of pyrrolnitrin on S. cerevisiae was the terminal electron transport system between succinate or reduced nicotinamide adenine dinucleotide (NADH) and coenzyme Q. At growth inhibitory concentrations, pyrrolnitrin inhibited endogenous and exogenous respiration immediately after its addition to the system. In mitochondrial preparations, the antibiotic inhibited succinate oxidase, NADH oxidase, succinate-cytochrome c reductase, NADH-cytochrome c reductase, and succinate-coenzyme Q(6) reductase. In addition, pyrrolnitrin inhibited the antimycin-insensitive reduction of dichlorophenolindophenol and of the tetrazolium dye 2,2'-di-p-nitrophenyl-(3,3'-dimethoxy-4,4'-bi-phenylene)5,5'-diphenylditetrazolium. The reduction of another tetrazolium dye, 2-p-iodophenyl-3-p-nitrophenyl-5-phenyltetrazolium chloride, that was antimycin-sensitive, was also inhibited by pyrrolnitrin. The antibiotic had no effect on the activity of cytochrome oxidase, and it did not appear to bind with flavine adenine dinucleotide, the coenzyme of succinic dehydrogenase. In whole cells of S. cerevisiae, pyrrolnitrin inhibited the incorporation of (14)C-glucose into nucleic acids and proteins. It also inhibited the incorporation of (14)C-uracil, (3)H-thymidine, and (14)C-amino acids into ribonucleic acid, deoxyribonucleic acid, and protein, respectively. The in vitro protein synthesis in Rhizoctonia solani and Escherichia coli was not affected by pyrrolnitrin. Pyrrolnitrin also inhibited the uptake of radioactive tracers, but there was no general damage to the cell membranes that would result in an increased leakage of cell metabolites. Apparently, pyrrolnitrin inhibits fungal growth by inhibiting the respiratory electron transport system.     

Biosensors for the Detection of Organophosphorous Pesticides

Cytokinins are master regulators of plant growth and development. They are involved in the regulation of many important physiological and metabolic processes. Recent progress in cytokinin research at the molecular level, including identification of related genes and cytokinin receptors, plus elucidation of signal transduction, has greatly increased our understanding of cytokinin actions. Although still in its infant stage, molecular breeding of crops with altered cytokinin metabolism, when combined with the transgenic approach, has shown very promising potential for application to agriculture. In this review we briefly introduce recent progress in cytokinin molecular biology, discuss applications of cytokinin genetic engineering to agriculture, and present implications and future research directions.     

Mechanism of Action of Luteinizing Hormone

WE have reported¹ studies on luteinized rat ovary in which we found that an approximate doubling of the rate of steroid synthesis following stimulation with luteinizing hormone was not associated with any change in the tissue NADPH/NADP⁺ concentration ratio. We concluded that it was unlikely that luteinizing hormone brought about the increase in steroid synthesis solely by increasing the production of NADPH by glucose 6-phosphate dehydrogenase or another cytoplasmic NADPH-linked dehydrogenase, as had been suggested^2,3.     

Mechanism of Action of Abscission Accelerators

Abscission zone explants of Gossypium hirsutum L., Cassia fistula L., and Coleus blumei Benth. were used to investigate correlations between endogenous rates of ethylene evolution and time of abscission. Additions of 0.1 nl/ml ethylene to the explants markedly accelerated abscission; continuous aeration of the explants, to prevent accumulation of small amounts of endogenously produced ethylene, inhibited abscission compared with that of sealed controls. Substances that stimulated abscission simultaneously accelerated ethylene evolution on all three species and at any position of application. The positional effects of auxin are explained as being due to differences in transport in the explant. Thus, distally applied auxin inhibits abscission, regardless of the accelerated rate of ethylene evolution, by being rapidly transported to the abscission zone. Auxin applied proximally stimulates abscission because it is unable to move as rapidly to the abscission zone and the ethylene effect becomes dominant. Ethylene was found to be most effective on aged tissues, and it is concluded that abscission rates are determined by an increase in sensitivity of the tissue to the ethylene that is already being produced.     

Aspects of the Mechanism of Action of Some Cephalosporins

Cephaloridine and cephalexin had no effect on ribonucleic acid (RNA), deoxyribonucleic acid (DNA), or protein synthesis in Escherichia coli. However, cephalosporin 7/30 [7-(S-benzylthioacetamido)-cephem-3-ylmethyl-N -dimethyldithiocarbamate-4-carboxylic acid] and dimethyldithiocarbamate (DMDT), which occupies the side chain at position 3 in the 7/30 molecule, inhibited protein synthesis (and, to a lesser extent, RNA and DNA syntheses) in E. coli and had an inhibitory effect on the growth of Saccharomyces carlsbergensis. A bioautograph technique showed that two inhibitory spots were obtained with 7/30 but only one such spot with cephaloridine. Release of DMDT onto or in the bacterial cell may be responsible for "unusual" mode of action of cephalosporin 7/30.