Mechanism of action of terrazol]

Higher concentrations of terrazol inhibit the growth of a large number of fungi, but oomycetes are most sensitive. At medium concentrations (ED50 = 10 ppm) in Mucor mucedor several alterations of ultrastructure are recognizable even after short incubation periods. Significant observations are vacuolization of the mitochondrial cristae, invagination of the cytoplasmic membrane, and thickening of the cell wall. Later on, numerous vacuoles in the cytoplasm are visible. Primary effects on the cell membrane (destructive effect), on O2-consumption, on fermentation, or on nucleic acid synthesis could not be demonstrated. Lipid synthesis under the influence of terrazol showed characteristic changes. The synthesis of triglycerides and sterolesters was inhibited while the synthesis of free fatty acids and phospholipids was stimulated. Addition of lipids, vitamines, amino acids, or nucleic acids did not counteract the effect of terrazol. Further investigations are necessary to elucidate the primary mechanism of action.     

Mechanism of action of serum globulin preparations]

Experiments on mice demonstrated that serum homologous globulin preparations containing normal autoantibodies caused induction of autoantibodies in subcutaneous injection to intact animals; this was recorded on the basis of increase of the blood autoantibody level and of the plaque-forming cells content in the spleen tissue. This activation was seen as soon as the first hours--24 hours after the administration of the preparation and failed to disappear in 7 days, persisting in repeated administration of the preparation.     

Mechanism of the antiexudative action of heparin]

The skin inflammation was induced by xylol application in experiments on rats. Exogenous and endogenous hyperheparinemia was found not to influence the dynamics of microcirculatory changes in the inflammatory area at the onset of its development, vascular permeability being significantly decreased. It is suggested that decreased vascular permeability plays an important role in the mechanism of antiexudative heparin action.     

Mechanism of action of antibiotics:some examples]

Antibiotics are very commonly used substances to eradicate bacterial infections by bacteriostatic or even bactericid effect. They act at a very specific stage (target), although other less important or secondary interactions can occur. We studied the interaction of three antibiotic families (beta-lactamins, aminosides, rifampicin) with bacterial cell. Penicillin disturbs the cell wall synthesis and more accurately the glycopeptide (or murein) formation, a substance giving rigidity or shape to bacteria. It acts in the late phase of murein-biosynthesis, when N-acetyl glucosamin -- N-acetyl muramic acid L ala -D glu M-DAP (L lys) -D ala -D ala are linked together by the peptide part, under the effect of several enzymes, particularly transpeptidase and DD-carboxy-peptidase. It would appear that beta-lactame-thiazolidine rings have a steric analogy with dipeptide D-alanyl D-alanine. The result would be that the enzyme would act on the antibiotic instead of peptide: the consequence would be inhibition of the peptidic link, giving an abnormal murein, and an incomplete cell wall i.e. fragile bacteria. Aminosides, particularly Streptomycin, link themselves to 30 S subunit of bacterial ribosome. In this case, it seems that it is a 3'OH function which reacts with lysine (from S 12 protein part of 30 S subunit). The consequence is an alteration in the RNA messager lecture, and a false traduction and consequently protein biosynthesis stops with a decrease of polyribosomes and of the formation of inert 70 S ribosome. Rifamycins, and particularly Rifampicin act by inhibition of RNA messager synthesis. One molecule of antibiotic links itself to one molecule of RNA messager : hydroxyl and cetone function in C1 Cs C21 C23 and "ansa" bridge link to beta subunit of RNA polymerase. This linkage gives a conformational change to the RNA polymerase-DNA complex, inhibiting the catalytic action of this enzyme, and consequently stopping RNA messager and protein synthesis. The study of the action mechanism of these antibiotics enables us to show the action specificity of these products in the bacteria. This specificity is more accurate when the target is not to be found in the eucaryotic cells : in this case the antibiotic may be considered as entirely atoxic. If the study of the action mechanism of antibiotics gives a better understanding of the use of these drugs, their action at a definite stage in bacterial metabolism is a valuable tool for scientists in their approach to cell functioning.     

Mechanism of amylase action on glucoside starch bonds]

Functional groups of glucoamylase and alpha-amylase from Asp. awamori, alpha-amylase from Asp. oryzae and alpha- and beta-amylases from barley malt are identified. Kinetic curves of the activity dependency on pH, values of ionization heats and photooxidative inactivation draw to the conclusion that carboxyl-imidazole system enters into the active site of the enzymes. A hypothetic mechanism of hydrolysis of alpha-1,4-glucoside bond in starch molecule by alpha- and beta-amylases and of alpha-1,4- and alpha-1,6-glucoside bonds by glucoamylase is given. A theory of induced correspondence of enzyme and substrate satisfactorily explains the specificity of the enzyme action and the cause of complete starch convertion into glucose under glucoamylase action and of terminal starch hydrolysis by alpha- and beta-amylases.     

Mechanism of action of T cell factors regulating antibody formation]

While the induction of antibody synthesis depends on antigen specific T cell factors, its magnitude is under control of non antigen specific T cell factors. In this respect, TRF ("T cell Replacing Factor") amplifies antibody responses while IBF ("Immunoglobulin Binding Factor") acts as a suppressor factor. Using cultures of spleen cells from nude mice, we show that both factors act sequentially, influencing the final differenciation of B cells to antibody producing cells. We have no evidence of direct interaction between TRF and IBF.     

Mechanism of the antistressor and antiradiation action of plant phenol compounds]

The article analyses critically the date from literature as well as own date concerning appropriateness and mechanisms of antiradiation, capillary strengthening and antistress effect of plant phenolic compounds. Knowledge on antioxidant effect as the most fundamental mechanism being in the basic of the above mentioned biologic effects of plant phenolic compounds is grounded.     

Mechanism of trace hyperpolarization of the action potential of snail giant neurons]

Depolarization current decreases and hyperpolarization current increases the amplitude of tracing hyperpolarization of the neuron action potential. Calcium-defficient solution supresses the tracing depolarization, and turns the rhythmical activity of the neuron into the flashlike one. An increase of outer concentration of potassium ions decreases the tracing depolarization. The latter is suppressed completely when the membrane behaves as a potassium electrode. The suppressing effect of the increase of potassium outer concentration on tracing hyperpolarization decreases with a decrease of calcium ions content in the medium. When an active release of sodium ions from the cell is inhibited with DNP and substitution of sodium ions by lithium ions the tracing hyperpolarization of the action potential is suppressed. The tracing hyperpolarization is also suppressed during the shunting of the electrogenic effect of potassium pump with the outcoming current of chlorine ions. It is suggested that the tracing hyperpolarization of the single action potential is due to the calcium-dependent fraction of electrogenic release of sodium ions from the cell.     

Mechanism of action of some quinoline alkaloids on respiratory chain of mitochondria]

The mechanism of action of some quinoline alkaloids and their derivatives on respiratory chain of rat liver and Candida lipolytica yeast mitochondria was studied. The alkaloids were shown to inhibit electron transfer in the respiratory chain. The site of their action is localized between b and c cytochromes. Besides their ability to inhibit electron transfer in the respiratory chain, alkaloids are shown to be specific inhibitors of "exogenous" NADH-dehydrogenase of C. lipolytica yeast mitochondria. In addition to their inhibiting properties alkaloids can stimulate ATPase activity of mitochondria. O-alkylation of pseudane-IX permits to differentiate the inhibiting and uncoupling properties of this alkaloid.     

Mechanism of the mutagenic action of the decay of incorporated phosphorus-32]

The experimental material concerning that physico-chemical consequences of 32P decay in the molecular structure of DNA, their reparation mechanism as well, and resulting mutagenic effects have been analysed. The reparation of the single-strand break of the DNA chain does not cause the changes of microdeletion and microinsertion type but instead of the changes observed are of the nucleic bases conversion type. It is concluded that the mutations caused by the decay of 32P incorporated appear as a result of errors in the selection of nucleic bases during the reparative replication of the non-conservative type.     

Mechanism of melatonin action

Melatonin transduces the effect of photoperiod on the neuroendocrine system. Synthesis of melatonin in the pineal gland is well described, but the location of its target(s) and the mechanism of its action are little known. In attempt to localize melatonin target(s), the presence of high affinity binding sites in rat brain was determined. Such sites were detected in discrete brain areas, including the hypothalamus and anterior pituitary. Subcellular analysis indicated these binding sites were on plasma membranes, which suggests that melatonin modulates cell functions through intracellular second messengers. The effects of melatonin on second messengers were studied using the neonatal anterior pituitary, in which melatonin is known to inhibit the LHRH-induced release of LH. Studies on the effects of melatonin on second messenger indicated [corrected] that melatonin inhibits accumulation of cAMP and cGMP as well as synthesis of diacylglycerol and release of arachidonic acid. Time-course analysis indicates that inhibition by melatonin of the LHRH-induced release of LH increases following long preincubation. Since the effect of melatonin on LHRH-induced release of LH is prevented by dibutyryl cAMP, we conclude that melatonin might act by inhibiting production of cAMP.     

Mechanism of prolactin action

Most experimental information regarding the mechanism of action of prolactin in its diverse array of target tissues has been discovered using mammary tissues. Evidence has recently been presented that suggests that prolactin may be "internalized" into its target cells and have intracellular actions. Accordingly, it has been reported that prolactin stimulates RNA synthesis in isolated nuclei from mammary tissues; and by immunoflorescent studies, prolactin has been located within its target cells. It has been further suggested from additional experimental studies that the primary action of prolactin may involve its initial interaction with fixed plasma membrane receptor sites. Subsequent actions of prolactin may involve the following: a) an increased intracellular concentration of potassium and a reduced level of sodium, b) an increased level of cGMP and a reduced level of cAMP, c) an enhanced rate of prostaglandin biosyntheesis mediated by a stimulation of phospholipase A2 activity, and d) a stimulation of polyamine synthesis. It has also been shown that the actions of prolactin require calcium ions in the extracellular environment. Laboratory studies have thus indicated that the actions of prolactin may be carried out by a number of processes; but a single, primary action of this hormone that accounts for all of its actions has not yet been proven.     

Mechanism of action of tetracycline on the functional state of the adrenal cortex]

The mechanism of stimulation of the adrenal cortex function by tetracycline was studied on albino rats. It was shown that tetracycline administered orally in a dose of 200 mg/kg regularly induced an increase in the corticosterone levels in the peripheral blood of the animals by the 15th day of the antibiotic use. It was shown on the animals with an experimentally suppressed function of the hypophysis by prolonged administration of hydrocortisone acetate that tetracycline primarily stimulated the hypophysis function resulting in production and excretion of increased amounts of the adrenocorticotropic hormone into the blood. The hormone increased the production of corticosterone in the adrenal glands which resulted in its higher levels in the peripheral blood.