Effects of cations on the adhesion between membrane vesicles obtained by digitonin fractionation of spinach chloroplasts

The heavy fraction obtained by digitonin treatment of stacked spinach chloroplasts, suspended in media with different ionic composition, was examined by electron microscopy. In the presence of 5 mM MgCl₂ the thylakoid fragments adhere to one another in a ‘stacked configuration,’ while, in the presence of 10 mM NaCl, mainly only single ‘unstacked’ vesicles are present, which, upon addition of 5 mM MgCl₂, completely revert to the stacked configuration. As previously reported (Chow, W.S. and Barber, J. (1980) Biochim. Biophys. Acta 593, 149–157), no difference in fractionation of chlorophyll between light and heavy fractions was seen after a second digitonin treatment of this fraction suspended in media containing different cation concentrations. From these results it was concluded: (1) that for the unstacking process the movement of proteins or complexes from the stromal to the granal lamellae is not required. Upon lowering the screening by cations of the surface negative charges, the membranes separate from one another; (2) that, under these conditions, as in others (Jennings, R.C., Gerola, P.D., Garlaschi, F.M. and Forti, G. (1980) FEBS Lett. 115, 39–42), digitonin fractionation is not a tool to investigate the degree of membrane stacking.     

The effects of digitonin on photochemical activities of isolated chloroplasts

The addition of digitonin to chloroplasts stimulated the rate of oxygen evolution followed by a gradual inhibition. The effect of digitonin was dependent on the digitonin to chlorophyll ratio and on temperature and time. The initial stimulation of oxygen evolution appeared to be a result of uncoupling as digitonin did not stimulate oxygen evolution by uncoupled chloroplasts. The stimulatory effect occurred more rapidly at high digitonin to chlorophyll ratios but the extent of stimulation was low and inhibition occurred soon after addition of the detergent. The inhibition of electron flow by digitonin was due to a site of action near photosystem II which resembled the inhibition reported for tris buffer and resulted in photobleaching. However, digitonin inhibition could not be recovered by washing with reducing agents and was only partially recovered by the addition of artificial electron donors to photosystem II. Electron flow mediated by photosystem I was unaffected by the addition of digitonin but was decreased when the chloroplasts were separated by subsequent centrifuging. This suggested that digitonin solubilizes photosystem I components which remain active in the soluble form.     

Improvement in separation of system I and system II particles of photosynthesis obtained by digitonin treatment

By a combined use of digitonin treatment and subsequent centrifugation on a linear sucrose density gradient, the whole green material of the chloroplast lamellae was separated into System I and System II particle fractions, leaving no other fractions of intermediate properties at the final step of separation.

Each of these particle fractions obtained had properties characteristic of System I or System II with respect to the molar ratio of chlorophyll a/chlorophyll b, the content of P700, the fluorescence emission spectrum at −196°;, photoreduction activities with ferricyanide and NADP⁺, and induction of fluorescence.

About 40 and 50% of the total chlorophyll in the original chloroplasts were recovered in System I and System II particles, respectively. Only small amounts of total chlorophyll (less than 10%) were found as free chlorophyll detached from the lamellae through the digitonin treatment.

These results support the view that the lamellae of chloroplasts are composed of about equal amounts of System I and System II particles on a chlorophyll basis.     

Separate action spectra for the two photochemical systems of photosynthesis

Action spectra have been obtained which are believed to represent the 2 photochemical systems in the marine green alga, Ulva lobata. Measurement of transient rates of O₂ uptake in the presence of DCMU furnished the data for the spectrum representing system I. The action spectrum for system II refers to O₂ evolution rates after the Ulva was pretreated in an atmosphere of high O₂ concentration. Tissue responses after high O₂ exposure suggests an inhibition of the photosynthetic functioning of system I.     

Effects of nonsteroidal anti-inflammatory drugs on the uptake of various cations by lymphoid cells.

Several acidic nonsteroidal anti-inflammatory drugs (NSAID) as well as their corresponding alcohol molecules which are known to induce swelling of isolated lymphocytes by changing cell membrane permeability to water, are demonstrated also to induce changes of membrane permeability of lymphoid cells to one divalent cation, calcium, and to three monovalent cations, rubidium, cesium and sodium. According to the cells ionic environment, they increase or decrease the cellular uptake of cation which is itself also closely dependent on the ionic composition of the incubation medium. This drug-effect is very rapid, directly related to the medium NSAID concentration and almost totally reversible except to the most potent drugs such as flufenamic acid. Changes in intracellular ionic balance could have important catalytic effects on the metabolism of normal as well as of pathological cells. This fact could explain side-effects of these drugs as well as some of their therapeutic effects.     

Inactivation and activation of various membranal enzymes of the cholesterol biosynthetic pathway by digitonin

The activity of rat liver microsomal squalene epoxidase is inhibited effectively by digitonin. Concentrations of 0.8 to 1.2 mg/ml of digitonin cause total inhibition of microsomal (0.75 mg protein/ml) squalene epoxidase either in microsomes that were pretreated with digitonin and subsequently washed and subjected to epoxidase assay or when digitonin was added directly to the assay. The inhibition of squalene epoxidase by digitonin is concentration-dependent and takes place rapidly within 5 min of exposure of the microsomes to digitonin. Octylglucoside, dimethylsulfoxide, CHAPS, as well as cholesterol or total microsomal lipid extract were ineffective in restoring the digitonin-inhibited squalene epoxidase activity. Epoxidase activity in digitonin-treated microsomes was fully restored by Triton X-100. The reactivation by Triton X-100 displays a concentration optimum with maximal reactivation of the epoxidase (0.7 mg protein/ml) occurring at 0.2% Triton X-100. Microsomal 2,3-oxidosqualene-lanosterol cyclase is also inhibited by digitonin. Higher concentrations of digitonin are required to obtain full inhibition of the cyclase activity and only 40% inhibition of cyclase activity is observed at 1 mg/ml of digitonin. Solubilized (subunit size 55 to 66 kDa) and microsomal (subunit size 97 kDa) 3-hydroxy-3-methylglutaryl CoA reductase are totally unaffected by the same concentration of digitonin. Squalene synthetase, another microsomal enzyme in the biosynthetic pathway of cholesterol, is activated by digitonin. A 2.2-fold activation of squalene synthetase is observed at 0.8 mg/ml of digitonin. The results agree with a model in which squalene, and to a lesser degree 2,3-oxidosqualene, are segregated by digitonin into separate intramembranal pools.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of monovalent cations on light energy distribution between two pigment systems of photosynthesis in isolated spinach chloroplasts

The effects of monovalent cations on the light energy distribution between two pigment systems of photosynthesis were studied in isolated spinach chloroplasts by measuring chlorophyll a fluorescence and photochemical reactions.

The addition of NaCl to the chloroplast suspension produced a 40–80% increase in fluorescence yield measured at 684 nm at room temperature. The fluorescence increase was completed about 5 min after the addition. The effect saturated at 100 mM NaCl. Low-temperature fluorescence spectra showed that NaCl increased the yields of two fluorescence bands of pigment system II at 684 and 695 nm but decreased that of pigment system I at 735 nm. Similar effects on chlorophyll a fluorescence at room and at low temperatures were obtained with NaBr, NaNO₃, Na₂SO₄, LiCl, KCl, RbCl, CsCl, NH₄Cl and CH₃NH₃Cl.

NaCl suppressed the quantum efficiency of NADP⁺ reduction supported by the ascorbate-2,6-dichlorophenolindophenol (DCIP) couple as an electron donor system in the presence of 3-(3′,4′-chlorophenyl)-1,1-dimethylurea (DCMU). On the other hand, NaCl only slightly enhanced the quantum yield of photoreaction II measured by the Hill reaction with DCIP.

It is concluded that the monovalent cations tested suppressed the excitation transfer from pigment system II to pigment system I; the effects were the same as those of alkaline earth metals and Mn²⁺ (refs. 1, 2).     

Effects of cations on dipalmitoyl phosphatidylcholine/cholesterol/water systems

X-ray diffraction studies have been made on the effects of cations upon the dipamitoyl phosphatidylcholine/water system, which originally consists of a lamellar phase with period of 64.5 Å and of excess water. Addition of 1 mM CaCl₂ destroys the lamellar structure and makes it swell into the excess water. the lamellar phase, however, reappears when the concentration of CaCl₂ increases: a partially disordered lamellar phase with the repeat distance of 150–200 Å comes out at the concentration of about 10 mM, the lamellar diffraction lines become sharp and the repeat distance decreases with increasing CaCl₂ concentration. A small amount of uranyl acetate destroys lamellar phase in pure water. MgCl₂ induces the lamellar phase of large repeat distance, whereas LiCl, NaCl, KCl, SrCl₂ and BaCl₂ exhibit practically no effect by themselves. Addition of cholesterol to the phosphatidylcholine bilayers tends to stabilize the lamellar phaseThe high-angle reflections indicate that molecular arrangements on phosphatidylcholine bilayers change at CaCl₂ concentrations around 0.5 M. The bilayers at high CaCl₂ concentration seem to consist of two phases of pure phosphatidylcholine and of equimolar mixture of phosphatidylcholine and cholesterol.     

Possible exposure of leucine aminopeptidase on the cell surface of rabbit blood neutrophils by digitonin treatment

The sensitivity of leucine aminopeptidase to diazotized sulfanilic acid (DSA) was compared between neutrophils from blood and peritoneal exudates of rabbit. The leucine aminopeptidase activity of peritoneal neutrophils was inhibited about 40% by DSA, whereas that of blood neutrophils was not inhibited at all by the reagent. However, pretreatment of blood neutrophils with digitonin in the presence and in the absence of divalent cations rendered leucine aminopeptidase sensitive to DSA to the same extent as peritoneal neutrophils, without affecting the cell viability and lactate dehydrogenase activity. These findings seem to indicate that the leucine aminopeptidase of blood neutrophils, which is normally inaccessible to DSA, was exposed on the cell surface by digitonin treatment.     

Effects of cations on dipalmitoyl phosphatidylcholine/cholesterol/water systems.

X-ray diffraction studies have been made on the effects of cations upon the dipalmitoyl phosphatidylcholine/water system, which originally consists of a lamellar phase with period of 64.5 A and of excess water. Addition of 1 mM CaCl2 destroys the lamellar structure and makes it swell into the excess water. The lamellar phase, however, reappears when the concentration of CaCl2 increases: a partially disordered lamellar phase with the repeat distance of 150-200 A comes out at the concentration of about 10 mM, the lamellar diffraction lines become sharp and the repeat distance decreases with increasing CaCl2 concentration. A small amount of uranyl acetate destroys the lameellar phase in pure water. MgCl2 induces the lamellar phase of large repeat distance, whereas LiCl, NaCl, KCl, SrCl2 and BaCl2 exhibit practically no effect by themselves. Addition of cholesterol to the phosphatidylcholine bilayers tends to stabilize the lamellar phase. The high-angle reflections indicate that molecular arrangements in phosphatidylcholine bilayers change at CaCl2 concentrations around 0.5 M. The bilayers at high CaCl2 concentration seem to consist of two phases of pure phosphatidylcholine and of equimolar mixture of phosphatidylcholine and cholesterol.     

Recognition of metal cations by biological systems.

Recognition of metal cations by biological systems can be compared with the geochemical criteria for isomorphous replacement. Biological systems are more highly selective and much more rapid. Methods of maintaining an optimum concentration, including storage and transfer for the essential trace elements, copper and iron, used in some organisms are in part reproducible by coordination chemists while other features have not been reporduced in models. Poisoning can result from a foreign metal taking part in a reaction irreversibly so that the recognition site or molecule is not released. For major nutrients, sodium, potassium, magnesium and calcium, there are similarities to the trace metals in selective uptake but differences qualitatively and quantitatively in biological activity. Compounds selective for potassium replace all the solvation sphere with a symmetrical arrangement of oxygen atoms; those selective for sodium give an asymmetrical environment with retention of a solvent molecule. Experiments with naturally occurring antibiotics and synthetic model compounds have shown that flexibility is an important feature of selectivity and that for transfer or carrier properties there is an optimum (as opposed to a maximum) metal-ligand stability constant. Thallium is taken up instead of potassium and will activate some enzymes; it is suggested that the poisonous characteristics arise because the thallium ion may bind more strongly than potassium to part of a site and then fail to bind additional atoms as required for the biological activity. Criteria for the design of selective complexing agents are given with indications of those which might transfer more than one metal at once.     

The influence of various cations on the catalytic properties of clays

Summary Polymerization of alanine adenylate in the presence of various clays in their Na form gave increasing degrees of polymerization in the following order: montmorillonite < nontronite < hectorite. With montmorillonite, presaturated with different cations the order was: Mg < Ca < Fe < Al < Na. From all these clays, hectorite was the only one to enable also some polymerization of lysine.