Intermediacy of iridodial in the biosynthesis of some iridoid glucosides

Administration of MVA-[2-¹⁴C] to Lamium applexicaule and Deutzia crenata as well as of 11-hydroxyiridodial glucoside-[10-³H] and 7-deoxyloganic acid-[10-³H] to the former plant suggested that, in contrast to secoiridoid-indole alkaloids, iridoid glucosides such as ipolamiide, lamiide, lamioside, deutzioside and scabroside in these plants are biosynthesized via iridodial. Iridodial as a precursor for the biosynthesis of asperuloside was also suggested from the results of the administration of MVA-[2-¹⁴C] to Galium spurium var. echinospermon.     

Purification of angiotensin I-converting enzyme from human lung.

Angiotensin I-converting enzyme (peptidyl dipeptide hydrolase, EC 3.4.15.1) was solubilized from the membrane fraction of human lung using trypsin treatment and purfied using columns of DE 52-cellulose, hydroxyapatite and Sephadex G-200. The purified enzyme was shown to convert angiotensin I to angiotensin II and also to inactivate bradykinin. The specific activity of the enzyme was 9.5 units/mg protein for Hippuryl-His-Leu-OH and 0.665 mumol/min per mg protein for angiotensin I. The enzymic activity obtained after trypsin treatment (1 mg/200 mg protein) for 2 h could be divided into three components: (i) an enzyme of molecular weight 290 000 (peak I), (ii) an enzyme of molecular weight 180 000 (peak II) and (iii) an enzyme of molecular weight 98 000 (peak III), by columns of DE 52-cellulose and Sephadex G-200. Km values of peak I, II and III fraction for Hippuryl-His-Leu-OH were identical at 1.1 mM. pH optimum of the enzyme was 8.3 for Hippuryl-His-Leu-OH.     

Hydrophobicity of biosurfaces as shown by chemoreceptive Thresholds inTetrahymena,Physarum andNitella

Summary Responses (chemotaxis and changes in membrane potential) ofTetrahymena, Physarum, andNitella against aqueous solution of homologous series ofn-alcohols,n-aldehydes andn-fatty acids were studied for clarifying the hydrophobic character of chemoreceptive membranes. Results were: (1) All organisms studied responded to homologous compounds examined when the concentration of these chemicals exceeded their respective threshold,C _th , and the response,R, were expressed approximately asR= log (C/C _th ) forC>C _th , (2) Increase of the length of hydrocarbon chain in homologues decreasedC _th . Plots of logC _th against the number of carbon atoms,n, inn-alcohols,n-aldehydes andn-fatty acids showed linear relationships as represented by logC _th =–An+B. A andB are positive constants for respective functional end groups of the chemicals and biological membranes used. The above empirical equation was interpreted in terms of the partition equilibrium of methylene groups between bulk solution and membrane phase. ParameterA was shown to be a measure of hydrophobicity of the membrane, andB represented the sensitivity of chemoreception of the membrane. (3) Thresholds,C _th , for various hydrophobic reagents were compared with those of human olfactory reception,T. Plots of logT against logC _th fell on straight lines for respective organisms with different slopes which were proportional to parameterA.     

Pentose metabolism in Mycobacterium smegmatis: comparison of L-arabinose isomerases induced by L-arabinose and D-galactose.

D-Galactose, which did not serve as a growth substrate, was found to induce an L-arabinose isomerase of similar properties to the L-arabinose-induced L-arabinose isomerase. In both cases the pH profiles, pH stability, optimum temperature, heat stability, substrate specificity, metal ion requirements, mobility on polyacrylamide gel electrophoresis, and kinetic properties of the induced isomerases were identical. It appears possible that D-galactose was incorporated into the cells by an L-arabinose permease system that was alos induced by D-galactose.     

Antagonism between high pressure and anesthetics in the thermal phase-transition of dipalmitoyl phosphatidylcholine bilayer

The antagonizing action of hydrostatic pressure against anesthesia is well known. The present study was undertaken to quantitate the effects of hydrostatic pressure and anesthetics upon the phase-transition temperature of dipalmitoyl phosphatidylcholine vesicles. The drugs used to anesthetize the phospholipid vesicles included an inhalation anesthetic, halothane, a dissociable local anesthetic, lidocaine and an undissociable local anesthetic, benzyl alcohol. All anesthetics decreased the phase-transition temperature dose-dependently. In the case of lidocaine, the depression was pH dependent and only uncharged molecules were effective. The application of hydrostatic pressure increased the phase-transition temperature both in the presence and the absence of anesthetics. The temperature-pressure relationship was linear over the entire pressure range studied up to 340 bars. Through the use of Clapeyron-Clausius equation, the volume change accompanying the phase-transition of the membrane was calculated to be 27.0 cm3/mol. Although the anesthetics decreased the phase-transition temperature, the molar volume change accompanying the phase-transition was not altered. The anesthetics displaced the temperature-pressure lines parallel to each other. The mole fraction of the anesthetics in the liquid crystalline membrane, calculated from the van't Hoff equation, was independent of pressure. This implies that pressure does not displace the anesthetics from the liquid membrane, and the partition of these agents remains constant. The volume change of the anesthetized phospholipid membranes is entirely dependent upon the phase-transition and not on the space occupied by the anesthetics.