Features of formation of phases of dual-phase polymeric system in the presence of collagen I, laminin I, and their mixtures

A study was made of the phase formation kinetics of a two-phase aqueous polymer system, consisting of 7.8% (w/w) dextran-500 and 4.6% (w/w) polyethylene glycol-6000, in the presence of various concentrations of collagen (0.07-0.20 mg/ml), laminin I (0.01-0.03 mg/ml) and their mixture. The phase formation was evaluated by registration of its optical density on a spectrophotometer. The obtained two-phase polymer system optical density curves and also the partitioning coefficients for the studied objects depend on surface properties of these objects. It has been shown that the surface properties of collagen I and laminin I differ according to differences in their molecules conformations, and that the phase formation kinetics points to their interaction during a mutual partitioning of these proteins in the system. The authors made a conclusion that collagen I and laminin I in the two-phase polymer system conditions could make complexes.     

Hydrophobic affinity partition of spinach chloroplasts in aqueous two-phase systems

The surface properties of spinach chloroplasts, both of intact chloroplasts with surrounding envelope and broken chloroplasts consisting of the inner lamellar system, have been studied by partitioning them between two aqueous phases, especially using counter-current distribution technique. The two-phase system consists of poly(ethyleneglycol), dextran and water. The two polymers are enriched in opposite phases and by binding deoxycholate or palmitate to one of the polymers the affinity of chloroplasts for the corresponding phase is strongly enhanced. The partition of the two classes of chloroplasts, however, is not affected to the same degree and the affinity of the chloroplast envelope for deoxycholate and palmitate is stronger than that of the lamellar system. This has been correlated to the chemical composition of the two types of membranes. By studying the effect of salts on the partition it has been found that the lamellar system bears a larger number of negative charges as compared to the envelope of the intact chloroplast.     

Inner and outer immobilization of chloroplasts]

The effects of glutaric aldehyde on pea leave chloroplasts and their inactivation kinetics were studied. Optimization of the chloroplasts fixation by glutaric aldehyde resulted in a 5-fold increase of stability of the chloroplasts. Immobilization of the chloroplasts in agar-agar gels was performed; the ability of chloroplasts for photooxidation of H2O was thereby retained. Immobilization did not actually affect the stability of chloroplasts. The inactivation kinetics of fixed and immobilized chloroplasts are in good agreement with the previously described model for inactivation of native chloroplasts.     

Light-Dark Regulation of Starch Metabolism in Chloroplasts: I. Levels of Metabolites in Chloroplasts and Medium during Light-Dark Transition

In Spinacia oleracea the kinetics of CO₂ fixation, of starch formation, and of changes in the levels of metabolites in chloroplasts and the surrounding medium has been investigated during light-dark and dark-light transitions with isolated intact chloroplasts.     

Precursors to microsecond delayed luminescence in oxygenevolving and inhibited chloroplasts

We have investigated submillisecond delayed luminescence in spinach chloroplasts under a variety of conditions. In Tris-washed chloroplasts, which are inhibited on the oxidizing side of P-680, the delayed light emission in the 7–200 μs time-range decayed with biphasic behavior. In fully dark-adapted samples illuminated by a single saturating laser pulse, the fast phase of delayed luminescence followed a nearly identical pH-dependent time-course as that observed optically and by ESR for P⁺-680 reduction, thus verifying the recombination hypothesis for the origin of delayed light. The observed slower phase of delayed luminescence was also pH dependent, but unlike the fast phase, could not be ascribed to specific electron transfer events of PS II. This phase could be rationalized by a heterogeneity in the population of P-680. While kinetic parameters were found to be insensitive to changes in ionic strength, the overall luminescence intensity was quite sensitive to the electrical parameters, thus indicating the role of ionic strength and local charges in delayed luminescence modulation. A similar series of experiments was performed on untreated chloroplasts. The pH-dependent delayed luminescence behavior in both untreated chloroplasts and Tris-washed chloroplasts was similar despite significantly faster kinetics associated with the reduction of P⁺-680 by the secondary PS II electron donor, Z, in the former preparation (e.g., Van Best, J.A. and Mathis, P. (1978) Biochim. Biophys. Acta 503, 178–188). Thus, it was concluded that, in untreated samples, microsecond delayed luminescence emanates primarily from centers which are not competent in oxygen evolution. The nearly identical delayed luminescence intensity in untreated chloroplasts and in Tris-washed chloroplasts was rationalized by a model which predicts modulations in delayed luminescence yield by the exciton-quenching effect of P⁺-680. Computer simulations demonstrate the feasibility of this model. The previously documented flash oscillations in microsecond delayed luminescence intensity in untreated chloroplasts (Bowes, J.M. and Crofts, A.R. (1979) Biochim. Biophys. Acta 547, 336–346), which we readily observed, were attributed to alterations in delayed luminescence yield (in nonfunctional centers) by variations in charge density stored at the oxygen-evolving complex of functional centers. Taken together, our results emphasize the dependence of delayed luminescence kinetics upon electron-transfer kinetics and the dependence of delayed luminescence amplitude upon the photochemical parameters, the exciton yield and the emission yield.     

Study of oxygen photoreduction in chloroplasts by the method of luminol and chlorophyll chemiluminescence]

The reduction of oxygen by irradiated chloroplasts was studied for elucidation of oxygen action site in the electron transport chain of photosynthesis. Chemiluminescence system, consisted of luminol and peroxidase, was used for registration of oxygen reduction products. In the first case chemiluminescence system was added to supernatant fraction after centrifugation of suspension of irradiated chloroplasts in order to determine H2O2 which was found to be the final product of oxygen photoreduction. In the second case when chloroplasts were illuminated in the presence of chemiluminescence system and oxygen the fact delayed luminescence of luminol was observed. This photoluminescence related also with the oxygen reduction in chloroplasts caused a possible formation of radicals HO2 (or -O2). The formation of this radicals and H2O2 was inhibited by DCMU, heating of chloroplasts at 45 degrees C for 5 min and by washing with EDTA and NH2OH. The rate of HO2 dissappearance was increased by methylviologen. The kinetics of photoluminescence of luminol and afterglow of chlorophyll in chloroplasts was identical in the interval from 20 msec to several seconds. It is suggested that oxygen reaction site is located near the reaction centre of chloroplasts.     

Light-dependence of paraquat-initiated membrane deterioration in bean plants. Evidence for the involvement of superoxide

Treatment of primary bean leaves with 10 mg/I paraquat induces the formation of gel phase lipid in microsomal and chloroplast membranes and enhances the activity of superoxide dismutase, but only if the leaves are exposed to light. These light-dependent changes in membrane lipid phase properties show a close temporal correlation with enhanced O₂⁷ production by illuminated chloroplasts and the onset of lipid peroxidation. Malondialdehyde and ethane, which are both formed during lipid peroxidation, are produced in large amounts by paraquat-treated leaves exposed to light, but not by those maintained in the dark. Electron spin resonance measurements indicate that production of O₂⁷ by illuminated chloroplasts is more than 2-fold greater in the presence of paraquat than in its absence. The identity of the radical formed by illuminated chloroplasts in the presence of paraquat was confirmed by using the diagnostic spin trap 5,5'-dimethyl-l-pyrroline-l-oxide and by establishing that its formation is sensitive to superoxide dismutase. The observations collectively indicate that paraquat-mediated membrane deterioration is light-dependent and attributable to enhanced O₂⁷-production.     

Kinetics of ATP formation and proton efflux by acid-base transition in chloroplasts

The relationship between the kinetics of ATP formation and proton release in chloroplast suspensions by acid-base transition were studied by means of a stopped-flow spectrophotometer. The time course of ATP synthesis shows two-phase kinetics, fast and slow, corresponding to the two-phase efflux of protons from the chloroplasts. Under certain conditions of the experiments, about 50% of the H⁺ gradient is constantly utilized for ATP formation in both phases. However, the ratio of ATP formed to the amount of protons leaked out, changes depending on the rate constants of proton efflux.     

Effect of dicyclohexylcarbodiimide on the proton conductance of thylakoid membranes in intact chloroplast

The effects of dicyclohexylcarbodiimide, a potent inhibitor of chloroplast ATPase, on the light-induced electric potential changes in intact chloroplasts of Peperomia metallica and of a hornwort Anthoceros sp. were investigated by means of glass microcapillary electrodes. The characteristics of potential changes induced by flashes or continuous light in chloroplasts of both species are similar except for the phase of potential rise in continuous light, which is clearly biphasic in Anthoceros chloroplasts. Dicyclohexylcarbodiimide at concentration 5 · 10⁻⁵ M completely abolishes the transient potential undershoot in the light-off reaction but has little effect on the peak value of the photoelectric response. The membrane conductance in the light and in the dark was tested by measuring the decay kinetics of flash-generated potential in dark-adapted and preilluminated chloroplasts. In the absence of dicyclohexylcarbodiimide, preillumination causes a significant acceleration of the potential decay. The light-induced changes in the decay kinetics of flash-induced responses were abolished in the presence of dicyclohexylcarbodiimide, whereas the rate of potential decay in dark-adapted chloroplasts was not altered by dicyclohexylcarbodiimide. The results are consistent with the notion that dicyclohexylcarbodiimide diminishes H⁺ conductance of energized thylakoid membranes by interacting with the H⁺ channel of ATPase. The occurrence of a lag (approx. 300 ms) on the plot of potential undershoot (diffusion potential) versus illumination time might suggest the increase in H⁺ permeability coefficient of thylakoid membrane during illumination.     

Separation of subchloroplast membrane particles by counter-current distribution

Counter-current distribution in an aqueous Dextran-polyethylene glycol two-phase system has been used to fractionate membrane fragments obtained by press treatment of Class II chloroplasts. By the counter-current distribution technique membrane particles are separated according to their surface properties such as charge and hydrophobicity.The fractions obtained were analysed with respect to photochemical activities, chlorophyll and P-700 contents. The Photosystem II enrichment after counter-current distribution was better than that obtained by differential centrifugation of the disrupted chloroplasts. However, the best separation of Photosystem I and II enriched particles could be achieved if differential centrifugation was combined with the counter-current distribution technique.Each centrifugal fraction could be further separated into Photosystems I and II enriched fractions since the Photosystem II particles preferred the dextran-rich bottom phase while the Photosystem I particles preferred the polyethylene glycol-rich top phase. By this procedure it was possible, without the use of detergents, to obtain vesicles which were more enriched in Photosystem II as compared to intact grana stacks.The partition behaviour of undisrupted Class II chloroplasts and the Photosystem I centrifugal fraction was the same. This similarity indicates that the membrane which is exposed to the surrounding polymers by the Class II chloroplasts is the Photosystem I rich membrane of the stroma lamellae.     

Separation of subchloroplast membrane particles by counter-current distribution.

Counter-current distribution in an aqueous Dextran-polyethylene glycol two-phase system has been used to fractionate membrane fragments obtained by press treatment of Class II chloroplasts. By the counter-current distribution technique membrane particles are separated according to their surface properties such as charge and hydrophobicity. The fractions obtained were analysed with respect to photochemical activities, chlorophyll and P-700 contents. The Photosystem II enrichment after counter-current distribution was better than that obtained by differential centrifugation of the disrupted chloroplasts. However, the best separation of Photosystem I and II enriched particles could be achieved if differential centrifugation was combined with the counter-current distribution technique. Each centrifugal fraction could be further separated into Photosystems I and II enriched fractions since the Photosystem II particles preferred the dextran-rich bottom phase while the Photosystem I particles preferred the polyethylene glycol-rich top phase. By this procedure it was possible, without the use of detergents, to obtain vesicles which were more enriched in Photosystem II as compared to intact grana stacks. The partition behaviour of undisrupted Class II chloroplasts and the Photosystem I centrifugal fraction was the same. This similarity indicated that the membrane which is exposed to the surrounding polymers by the Class II chloroplasts is the Photosystem I rich membrane of the stroma lamellae.     

A mechanism for the formation of inside-out membrane vesicles. Preparation of inside-out vesicles from membrane-paired randomized chloroplast lamellae

Inside-out thylakoid membrane vesicles can be isolated by aqueous polymer two-phase partition of Yeda press-fragmented spinach chloroplasts (Andersson, B. and Åkerlund, H.-E. (1978) Biochim. Biophys. Acta 503, 462–472). The mechanism for their formation has been investigated by studying the yield of inside-out vesicles after various treatments of the chloroplasts prior to fragmentation. No inside-out vesicles were isolated during phase partitioning if the chloroplasts had been destacked in a low-salt medium prior to the fragmentation. Only in those cases where the chloroplast lamellae had been stacked by cations or membrane-paired by acidic treatment did we get any yield of inside-out vesicles. Thus, the intrinsic properties of chloroplast thylakoids seem to be such that they seal into right-side out vesicles after disruption unless they are in an appressed state. This favours the following mechanism for the formation of inside-out thylakoids. After press treatment, a ruptured membrane still remains appressed with an adjacent membrane. Resealing of such an appressed membrane pair would result in an inside-out vesicle.If the compartmentation of chloroplast lamellae into appressed grana and unappressed stroma lamellae is preserved by cations before fragmentation, the inside-out vesicles are highly enriched in photosystem II. This indicates a granal origin which is consistent with the proposed model outlined. Inside-out vesicles possessing photosystem I and II properties in approximately equal proportions could be obtained by acid-induced membrane-pairing of chloroplasts which had been destacked and randomized prior to fragmentation. Since this new preparation of inside-out thylakoid vesicles also exposes components derived from the stroma lamellae it complements the previous preparation.It is suggested that fragmentation of paired membranes followed by phase partitioning should be a general method of obtaining inside-out vesicles from membranes of various biological sources.     

Primary and secondary electron donors in photosystem II of chloroplasts. Rates of electron transfer and location in the membrane.

Absorption changes at 820 or 515 nm after a short laser flash were studied comparatively in untreated chloroplasts and in chloroplasts in which oxygen evolution is inhibited. In chloroplasts pre-treated with Tris, the primary donor of Photosystem II (P-680) is oxidized by the flash it is re-reduced in a biphasic manner with half-times of 6 microseconds (major phase) and 22 microseconds. After the second flash, the 6 microseconds phase is nearly absent and P-680+ decays with half-times of 130 microseconds (major phase) and 22 microseconds. Exogenous electron donors (MnCl2 or reduced phenylenediamine) have no direct influence on the kinetics of P-680+. In untreated chloroplasts the 6 and 22 microseconds phases are of very small amplitude, either at the 1st, 2nd or 3rd flash given after dark-adaptation. They are observed, however, after incubation with 10 mM hydroxylamine. These results are interpreted in terms of multiple pathways for the reduction of P-680+: a rapid reduction (less than 1 microseconds) by the physiological donor D1; a slower reduction (6 and 22 microseconds) by donor D'1, operative when O2 evolution is inhibited; a back-reaction (130 microseconds) when D'1 is oxidized by the pre-illumination in inhibited chloroplasts. In Tris-treated chloroplasts the donor system to P-680+ has the capacity to deliver only one electron. The absorption change at 515 nm (electrochromic absorption shift) has been measured in parallel. It is shown that the change linked to Photosystem II activity has nearly the same magnitude in untreated chloroplasts or in chloroplasts treated with hydroxylamine or with Tris (first and subsequent flashes). Thus we conclude that all the donors (P-680, D1, D'1) are located at the internal side of the thylakoid membrane.     

Maternal inheritance,cytology and macromolecular composition of defective chloroplasts in a variegated mutant of Nicotiana tabacum

Summary By phase microscopy of living cells the cause of a maternally-inherited variegated, spontaneous mutation of Nicotiana tabacum L. cv. Turkish Samsun was shown to be the presence of defective chloroplasts. These were intermingled with normal chloroplasts in some of the cells of the mesophyll tissue. In young, expanding leaves, the defective chloroplasts contain traces of chlorophylls a and b in the same ratio as found in normal chloroplasts, but only one-thirtieth of the quantity. As the defective chloroplasts mature, the green pigments disappear. The defective chloroplasts thus appear to be greatly deficient in thylakoid membranes. From their dynamic changes in shape, the defective chloroplasts appear to consist almost entirely of mobile phase, the structure which surrounds the thylakoid system of membranes of normal chloroplasts of higher plants. Consistent with this idea, two constitutents located in the mobile phase of normal chloroplasts—70S ribosomes and Fraction I protein—were detected in defective chloroplasts. The Fraction I protein was unchanged in specific ribulose diphosphate carboxylase activity from enzyme isolated from normal chloroplasts. Speculations are presented that the mutation in chloroplast DNA responsible for the formation of defective chloroplasts cannot be attributed to cistrons coding for the protein of Photosystem II, chloroplast ribosomal RNA or proteins, Fraction I protein, or the DNA-dependent RNA polymerase of chloroplasts.     

Light-induced generation of membrane potential in intact chloroplasts suspended in H2O or D2O media

The membrane potential changes induced by short flashes and continuous light were investigated in isolated chloroplasts of Peperomia metallica suspended in H2O- or D2O media. The potential generated in H2O-suspended chloroplasts by a single turnover flash is approximately two times lower than the maximal level of potential induced by continuous light. The photoelectric response of D2O-suspended chloroplasts differs from that of H2O-suspended chloroplasts by an increased amplitude and a prolonged phase of the potential rise. Te dark decay of the potential proceeds 2-3 times slower in the D2O-suspended chloroplasts as compared to the H2O-suspended chloroplasts. The magnitude of the flash-induced potential is somewhat lower for the chloroplasts in D2O than for the chloroplasts in the H2O medium. The results obtained suggest that the substitution of H2O for D2O results in a decrease of the ionic conductance and an increase of stability of thylakoid membranes. It was shown that the rise of electrical potential under continuous illumination proceeds in two stages. The difference kinetics of membrane potential changes are observed under conditions of separate activity of two systems of photosynthesis.     

Membrane structure and function. II. Alterations in the photo-induced absorption changes after treatment of isolated chloroplasts with large pulses of the ruby laser

Treatment of isolated chloroplasts with high-energy pulses of the ruby laser causes graded structural changes in the chloroplast membranes and is here correlated with the biochemical changes produced. The laser treatment caused decreases in the photoinducible absorption changes of cytochromes b₅₅₉, b₅₆₃, and P₅₂₀ (the carotenoid shift), but smaller decreases in cytochrome f. The decreases correlated with the quantum efficiency alterations produced by the laser treatment. Ferricyanide photoreduction and O₂ evolution was only slightly affected by the laser treatment. The slow phase of the dark recovery kinetics of P₅₂₀ was increased maximally by the lowest laser input energies and NADP⁺ photoreduction induced by carbonylcyanide-P-trifluoromethoxyphenylhydrazone (FCCP) was decreased maximally by the lowest energies, suggesting that uncoupling of the chloroplasts was the most sensitive parameter. This was corroborated by our previous observation (5) that chloroplast membrane bound surface particles (coupling factor) was the ultrastructural change most sensitive to the laser pulses. Electron flow from photosystem II to photosystem I was not altered by the laser treatment. The laser treatments did not cause a detectable decrease in total chlorophyll in the chloroplasts, however, approximately 10% of the total chlorophyll was present in the solution phase after the treatment, whereas no detectable cytochromes were present in the solution phase.     

Kinetics of electron transport, proton transfer and photophosphorylation in chloroplasts and their relation to temperature-induced structural changes in the thylakoid membrane

Effects of various temperatures on the rates of electron transport between two photosystems, the light-induced uptake of protons, kinetics of proton efflux from the chloroplasts in the dark and photophosphorylation were studied in isolated chloroplasts. There are correlations between the physical state of thylakoid membrane and the rates of electron- and proton transport processes. The temperature dependence of "structural" parameter (fluidity of lipids in membrane) as well as the rates of electron- and proton transport processes reveal the breaks under the same temperatures. Stimulation of photophosphorylation by temperature increasing correlates with the heat activation of chloroplasts latent ATPase due to thermoinduced structural changes in the heat activation of chloroplasts latent ATPase due to thermoinduced structural changes in the protein part of CF0-CF1 complex. The rate of photophosphorylation also correlates with the physical state of membrane lipids. Thermoinduced "melting" of the thylakoid membrane inhibits the ATP formation because of a decrease in photosystem 2 photochemical activity and stimulation of membrane conductivity for protons.     

Different kinetics of membrane potential formation in dark-adapted and preilluminated chloroplasts

The effects of varying dark interval on the kinetics of light-induced formation of the membrane potential were studied on individual chloroplasts of Anthoceros with the use of capillary microelectrodes. Illumination of the chloroplast with 1 s light pulse after 3 min dark period induced the photoelectrical response with two peaks of the potential that were located at 20 and 500 ms after the onset of illumination. The position of the second peak was shifted along the time-scale depending on the preceding dark interval. The repeated illumination of the chloroplast with 1 s light pulse after 30 s dark interval induced the electrical response with only one maximum and a monotonous decay of the potential in the light. Distinctions in the electrical responses induced by the first and the second light pulses were eliminated by the addition of 50 μM dicyclohexylcarbodiimide (DCCD). The results show that the photoinduction kinetics of the membrane potential in chloroplasts is affected by functioning of H⁺-ATPase. The delayed peak of the membrane potential in the photoinduction kinetics is interpreted as a consequence of the photoactivated electron transport supported by Photosystem I.     

Interactions of thrombin with fibrinogen adsorbed on methyl-, hydroxyl-, amine-, and carboxyl-terminated self-assembled monolayers

We have examined the initial phase of fibrin formation, thrombin-catalyzed fibrinopeptide cleavage, from adsorbed fibrinogen using surface plasmon resonance and liquid chromatography-mass spectrometry. Fibrinogen adsorption impaired thrombin-fibrinogen interactions compared to the interactions of thrombin with fibrinogen in solution. The properties of the underlying substrate significantly affected the extent and kinetics of fibrinopeptide cleavage, and the conversion of adsorbed fibrinogen to fibrin. Fibrinogen adsorbed on negatively charged surfaces (carboxyl-terminated self-assembled monolayers) released a smaller amount of fibrinopeptides, at a reduced rate relative to those of hydrophobic, hydrophilic, and positively charged surfaces (methyl-, hydroxyl-, and amine-terminated self-assembled monolayers, respectively). Additionally, the conversion of adsorbed fibrinogen to fibrin was comparatively inefficient at the negatively charged surface. These data correlated well with trends previously reported for fibrin proliferation as a function of surface properties. We conclude that thrombin interactions with adsorbed fibrinogen determine the extent of subsequent fibrin proliferation on surfaces.     

Surface specific kinetics of lipid vesicle adsorption measured with a quartz crystal microbalance.

We have measured the kinetics of adsorption of small (12.5-nm radius) unilamellar vesicles onto SiO2, oxidized gold, and a self-assembled monolayer of methyl-terminated thiols, using a quartz crystal microbalance (QCM). Simultaneous measurements of the shift in resonant frequency and the change in energy dissipation as a function of time provide a simple way of characterizing the adsorption process. The measured parameters correspond, respectively, to adsorbed mass and to the mechanical properties of the adsorbed layer as it is formed. The adsorption kinetics are surface specific; different surfaces cause monolayer, bilayer, and intact vesicle adsorption. The formation of a lipid bilayer on SiO2 is a two-phase process in which adsorption of a layer of intact vesicles precedes the formation of the bilayer. This is, to our knowledge, the first direct evidence of intact vesicles as a precursor to bilayer formation on a planar substrate. On an oxidized gold surface, the vesicles adsorb intact. The intact adsorption of such small vesicles has not previously been demonstrated. Based on these results, we discuss the capacity of QCM measurements to provide information about the kinetics of formation and the properties of adsorbed layers.