Photosynthetic electron transport and electrochromic effects at sub-zero temperatures

Spinach chloroplasts, suspended in a liquid medium containing ethyleneglycol, showed reversible absorbance changes near 700 and 518 nm due to P-700 and “P-518” in the region from ?35 to ?50 °C upon illumination. The kinetics were the same at both wavelengths, provided absorbance changes due to Photosystem II were suppressed. At both wavelengths, the decay was slowed down considerably, not only by the System I electron acceptor methyl viologen, but also by silicomolybdate. The effect of the latter compound is probably not due to the oxidation of the reduced acceptor of Photosystem I by silicomolybdate, but to the enhanced accessibility of the acceptor to some other oxidant.In the presence of both an electron donor and acceptor for System I, a strong stimulation of the extent of the light-induced absorbance increase at 518 nm was observed. The most effective donor tested was reduced N-methylphenazonium methosulphate (PMS). The light-induced difference spectrum was similar to spectra obtained earlier at room temperature, and indicated electrochromic band shifts of chlorophylls a and b and carotenoid, due to a large potential over the thylakoid membrane, caused by sustained electron transport. It was estimated that steady-state potentials of up to nearly 500 mV were obtained in this way; the potentials reversed only slowly in the dark, indicating a low conductance of the membrane. This decay was accelerated by gramicidin D. The absorbance changes were linearly proportional to the membrane potential.     

Photosynthetic electron transport and electrochromic effects at sub-zero temperatures.

Spinach chloroplasts, suspended in a liquid medium containing ethyleneglycol, showed reversible absorbance changes near 700 and 518 nm due to P-700 and "P-518" in the region from -35 to -50 degrees C upon illumination. The kinetics were the same at both wavelengths, provided absorbance changes due to Photosystem II were suppressed. At both wavelengths, the decay was slowed down considerably, not only by the System I electron acceptor methyl viologen, but also by silicomolybdate. The effect of the latter compound is probably not due to the oxidation of the reduced acceptor of Photosystem I by silicomolybdate, but to the enhanced accessibility of the acceptor to some other oxidant. In the presence of both an electron donor and acceptor for System I, a strong stimulation of the extent of the light-induced absorbance increase at 518 nm was observed. The most effective donor tested was reduced N-methylphenazonium methosulphate (PMS). The light-induced difference spectrum was similar to spectra obtained earlier at room temperature, and indicated electrochromic band shifts of chlorophylls a and b and carotenoid, due to a large potential over the thylakoid membrane, caused by sustained electron transport. It was estimated that steady-state potentials of up to nearly 500 mV were obtained in this way; the potentials reversed only slowly in the dark, indicating a low conductance of the membrane. This decay was accelerated by gramicidin D. The absorbance changes were linearly proportional to the membrane potential.     

Ascorbate-independent carotenoid de-epoxidation in intact spinach chloroplasts

Slow (> 1 s) light-induced absorbance changes in the 475–530 nm spectral region were examined in Type A chloroplasts from spinach. The most prominent absorption change occurred at 505 nm. The difference spectrum for this light-induced increase, its absence in osmotically shocked chloroplasts and restoration by ascorbate, and its sensitivity to dithiothreitol indicate that the absorption change is due to carotenoid de-epoxidation. The reaction in intact chloroplasts is characterized by its independence of exogenous ascorbate and a rate constant 3- to 8-fold higher than that reported previously for chloroplasts supplemented with ascorbate.The relevance of carotenoid de-epoxidation to other photosynthetic processes was examined by comparing their sensitivities to dithiothreitol. Levels of dithiothreitol that eliminate the 505 nm shift are without effect on saturated rates of CO₂ fixation and do not appreciably inhibit fluorescence quenching. We conclude that carotenoid de-epoxidation is not directly involved in the reactions of photosynthesis or in the regulation of excitation allocation between the photosystems.     

Light-induced absorbance changes due to Photosystems 1 and 2 in spinach chloroplasts at −50 °C

Absorbance changes in the region 500–565 nm and at 702 nm, brought about by excitation of Photosystems 1 and 2, respectively, were measured in spinach chloroplasts at ?50 °C. Either dark-adapted chloroplasts were used or chloroplasts preilluminated with a number of short saturating flashes just before cooling.Both photosystems were found to cause a light-induced increase of absorbance at 518 nm (due to “P518”). The System 1-induced change was not affected by preillumination. It decayed within 1 s in the dark and showed similar kinetics as P700. Experiments in the presence of external electron acceptors (methylviologen or Fe(CN)₆^3?) suggested that P518 was not affected by the redox state of the primary electron acceptor of System 1. The absorbance increase at 518 nm due to System 2 decayed in the dark with a half-time of several min. The kinetics were similar to those of C-550, the presumed indicator of the primary electron acceptor of System 2. After two flashes preillumination the changes due to P518 and C-550 were reduced by about 40%, and a relatively slow, System 2-induced oxidation of cytochrome b₅₅₉ occurred which proceeded at a similar rate as the increase in yield of chlorophyll a fluorescence. The results indicate that at ?50°C two different photoreactions of System 2 occur. One consists of a photoreduction of the primary electron acceptor associated with C-550, accompanied by the oxidation of an unknown electron donor; the other is less efficient and results in the photooxidation of cytochrome b₅₅₉.     

Melittin: An inhibitor of chloroplast photochemical reactions

Melittin, a polypeptide component of bee venom, is an inhibitor of photochemical reactions in chloroplasts isolated from higher plants. At concentrations around 5 μM, melittin acts as an uncoupler of photophosphorylation and abolishes the 518 nm light induced absorbance changes. At higher concentrations (30–50 μM), melittin abolishes both the light-induced photooxidation of cytochrome $\text{f}$, and partially inhibits other reactions of photosynthetic electron transfer, without causing lysis of the membrane. The observed inhibitions appear to be due to changes in the properties of the membrane lipid bilayer, caused by penetration of melittin molecules.     

Light-induced absorbance changes at 475-515 nm, and electron flow close to photosystem II in Tris-washed chloroplast fragments

Rapid, reversible light-induced absorbance changes at 475 and515 nm in chloroplast fragments were diminished by washing thefragments with Tris. These diminished absorbance changes wererestoredby the donation of electrons to photosystem II by hydrogen peroxide (Received November 17, 1970; )     

Extraction and Reconstitution of Photosystem II

Hill activity (oxygen evolution with ferricyanide as the electron acceptor), light-induced absorbance changes at liquid nitrogen temperature associated with the primary activity of photosystem II, and fluorescence yield changes at both low temperature and room temperature were measured with lyophilized spinach chloroplasts before and after extraction with hexane and reconstitution with β-carotene and plastoquinone A. Extraction eliminated the Hill activity, and both β-carotene and plastoquinone A were required for maximal restoration of activity to the reconstituted chloroplasts.     

Light-induced changes of fluorescence and absorbance in spinach chloroplasts at −40 °C

1. 1. Spinach chloroplasts were stored in the dark for at least 1 h, rapidly cooled to −40 °C, and illuminated with continuous light or short saturating flashes. In agreement with the measurements of Joliot and Joliot, chloroplasts that had been preilluminated with one or two flashes just before cooling showed a less efficient increase in the yield of chlorophyll a fluorescence upon illumination at −40 °C than dark-adapted chloroplasts. The effect disappeared below −150 °C, but reappeared again upon warming to −40 °C. Little effect was seen at room temperature in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), added after the preillumination.

2. 2. Light-induced absorbance difference spectra at −40 °C in the region 500–560 nm indicated the participation of two components, the socalled 518-nm change (P518) and C-550. After preillumination with two flashes the absorbance change at 518 nm was smaller, and almost no C-550 was observed. After four flashes, the bands of C-550 were clearly visible again.

3. 3. The fluorescence increase and the absorbance change at 518 nm showed the same type of flash pattern with a minimum after the second and a maximum at the fourth flash. In the presence of 100 μM hydroxylamine, the fluorescence response was low after the fourth and high again after the sixth flash, which confirmed the hypothesis that the flash effect was related to the so-called S-state of the electron transport pathway from water to Photosystem 2.

4. 4. The kinetics of the light-induced absorbance changes were the same at each wavelength, and, apart from the size of the deflection, they were independent of preillumination. Flash experiments indicated that the absorbance changes were a one-quantum reaction. This was also true for the fluorescence increase in dark-adapted chloroplasts, but with preilluminated chloroplasts several flashes were needed to approximately saturate the fluorescence yield.

5. 5. The results are discussed in terms of a mechanism involving two electron donors and two electron acceptors for System 2 of photosynthesis.

Characteristics of the Flash-induced 515 Nanometer Absorbance Change of Intact Isolated Chloroplasts

In intact (type A) chloroplasts isolated from mesophyll protoplasts of maize (Zea mays L. convar. KSC 360) the flash-induced 515 nanometer absorbance change was much higher than in conventionally prepared (types B and C) chloroplasts. The 515 nanometer signal of type A chloroplasts exhibited a biphasic rise: the initial very fast rise (rise time «1 millisecond) was followed by a slow increase of absorbance (rise time 10 to 20 milliseconds). With decreasing degree of envelope retention the slow phase disappeared. Thus the biphasic rise of the flash-induced 515 nanometer absorbance change can be regarded as an attribute of intact chloroplasts.     

Photoinduced changes in adsorption at 800 nm related to photosystem I functioning]

The spectra and kinetics of light-induced absorbance changes in the near-infrared region of subchloroplast fragments enriched by P700 were studied. An increase in absorbancy within the region of 725--900 nm upon illumination was characterized by a maximum around 810 nm and by "shoulders" around 760 and 870 nm. Similar effects of thermal inactivation and low temperatures on the duration of dark recovery of light-induced absorbance changes at 700 nm and within the region of 725--900 nm suggest that the absorbance changes in the near-infrared region are due to photooxidation of P700. The values of P700 differential extinction coefficients at 810 nm are 8,2.10(3) M-1.cm-1 for digitonin fragments and 7,7.10(3) M-1.cm-1 for fragments prepared with the use of diethyl ester. It was shown that the value of midpoint oxidation-reduction potential measured for the absorbance changes at 810 nm (+492 mv) is higher than that measured at 700 nm (+475 mv).     

Modified Light-Induced Absorbance Changes in dim Y Photoresponse Mutants of Trichoderma

A brief pulse of blue light induces the common soil fungus Trichoderma harzianum to sporulate. Photoresponse mutants with higher light requirements than the wild type are available, including one class, dim Y, with modified absorption spectra. We found blue-light-induced absorbance changes in the blue region of the spectrum, in wild-type and dim Y mutant strains. The light-minus-dark difference spectra of the wild type and of several other strains indicate photoreduction of flavins and cytochromes, as reported for other fungi and plants. The difference spectra in strains with normal photoinduced sporulation have a prominent peak at 440 nm. After actinic irradiation, this 440 nanometer difference peak decays rapidly in the dark. In two dim Y photoresponse mutants, the difference spectra were modified; in one of these, LS44, the 440 nanometer peak was undetectable in difference spectra. Detailed study of the dark-decay kinetics in LS44 and the corresponding control indicated that the 440 nanometer difference peak escaped detection in LS44 because it decays faster than in the control. The action spectrum of the 440 nm difference peak is quite different from that of photoinduced sporulation. The light-induced absorbance changes are thus unlikely to be identical to the primary photochemical reaction triggering sporulation. Nevertheless, these results constitute genetic evidence that physiologically relevant pigments participate in these light-induced absorbance changes in Trichoderma.     

Moderate heat stress of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> leaves causes chloroplast swelling and plastoglobule formation

Photosynthesis is inhibited by heat stress. This inhibition is rapidly reversible when heat stress is moderate but irreversible at higher temperature. Absorbance changes can be used to detect a variety of biophysical parameters in intact leaves. We found that moderate heat stress caused a large reduction of the apparent absorbance of green light in light-adapted, intact Arabidopsis thaliana leaves. Three mechanisms that can affect green light absorbance of leaves, namely, zeaxanthin accumulation (absorbance peak at 505 nm), the electrochromic shift (ECS) of carotenoid absorption spectra (peak at 518 nm), and light scattering (peak at 535 nm) were investigated. The change of green light absorbance caused by heat treatment was not caused by changes of zeaxanthin content nor by the ECS. The formation of non-photochemical quenching (NPQ), chloroplast movements, and chloroplast swelling and shrinkage can all affect light scattering inside leaves. The formation of NPQ under high temperature was not well correlated with the heat-induced absorbance change, and light microscopy revealed no appreciable changes of chloroplast location because of heat treatment. Transmission electron microscopy results showed swollen chloroplasts and increased number of plastoglobules in heat-treated leaves, indicating that the structural changes of chloroplasts and thylakoids are significant results of moderate heat stress and may explain the reduced apparent absorbance of green light under moderately high temperature.     

Salt-induced absorbance changes of P-515 in broken chloroplasts

Absorbance changes, caused by adding KCl to a suspension of broken chloroplasts in the presence of a low concentration of MgCl₂, have been measured in the wavelength region 460–540 nm. The magnitude of the KCl-induced absorbance changes is shown to be proportional to the logarithm of the KCl concentration gradient initially induced across the thylakoid membrane. The difference spectrum of these absorbance changes is shown to be identical with the spectrum of the light-induced absorbance changes, which has been attributed to an electrochromic shift of P-515. This is interpreted as evidence that under these conditions salt-induced absorbance changes of P-515 occur in response to a membrane diffusion potential. The results indicate that the electrogenic potential across the thylakoid membrane, generated by a single turnover light flash, is in the range between 15 and 35 mV.     

Oxidation-reduction potential dependence of low-temperature photoreactions of chloroplast Photosystem II

The light-induced free-radical signal of Photosystem II (observed after illumination at 77 °K) has been studied in chloroplasts as a function of the oxidation-reduction potential established prior to freezing. The intensity of the light-induced signal is unchanged in the potential region of +590 mV to +760 mV. At higher potential (+850 mV), there is a 30% decrease in signal intensity. The light-induced signal decreases to zero in the low-potential region, with a midpoint potential of +475 mV. These results are considered in terms of a Photosystem II reaction-center complex in which the light-induced free-radical signal arises from the oxidized form of the reaction-center chlorophyll, and this chlorophyll molecule is capable of being reduced at liquid-nitrogen temperature by a secondary electron donor which has a midpoint oxidation-reduction potential of +475 mV.     

Exposure of Leaves of Cucumis sativus L. to Low Temperatures in the Light Causes Uncoupling of Thylakoids II. Non-Destructive Measurements with Intact Leaves

To examine the effects of chilling of leaves of cucumber (Cucumissativus L.) in moderate light on the coupling state of thylakoidsin situ, changes in fluorescence, changes in light scatteringand flash-induced changes in absorbance at 518 nm were examinedin intact leaves. After chilling of leaves at 5?C in the lightfor 5 h, the non-photochemical quenching of fluorescence, ameasure of energisation of thylakoids, was largely suppressed.The treatment also caused a suppression of light-induced changesin the light scattering by leaves, which depends on the formationof a pH gradient across thylakoid membranes. When thylakoidswere prepared by very gentle methods from the leaves chilledin the light, through a step of preparation of intact chloro-plasts,the transport of electrons from H₂O to ferricyanide was uncoupled,being insensitive to an uncoupler, methylamine. These data provide consistent evidence that the thylakoids areuncoupled in situ by the chilling of leaves in the light and,as a consequence of the uncoupling, the energisation of themembranes is suppressed. However, the decay of the flash-inducedchange in absorbance at 518 nm in leaves was not markedly acceleratedby the treatment. The thylakoids isolated from leaves chilledin the light, which were in the uncoupled state, also did notshow a rapid decay, unless an efficient uncoupler such as gramicidinwas added. These results suggest that even a considerable uncouplingof thylakoids, brought about by chilling of leaves in the light,is not sufficient to cause a marked acceleration of the decayof the flash-induced change in absorbance at 518 nm. Therefore,analysis at 518 nm is not always a sensitive method for assessingthe coupling state of thylakoids. (Received July 1, 1991; Accepted October 4, 1991)     

Salt-induced absorbance changes of P-515 in broken chloroplasts

Absorbance changes, caused by adding KCl to a suspension of broken chloroplasts in the presence of a low concentration of MgCl2, have been measured in the wavelength region 460-540 nm. The magnitude of the KCl-induced absorbance changes is shown to be proportional to the logarithm of the KCL concentration gradient initially induced across the thylakoid membrane. The difference spectrum of these absorbance changes is shown to be identical with the spectrum of the light-induced absorbance changes, which has been attributed to an electrochromic shift of p-515. This is interpreted as evidence that under these conditions salt-induced absorbance changes of P-515 occur in response to a membrane diffusion potential. The results indicate that the electrogenic potential across the thylakoid membrane, generated by a single turnover light flash, is in the range between 15 and 35 mV.     

Light-induced absorbance changes of carotenoids in brown algae

Light-induced absorbance changes were studied for brown algae with 23 species and a pronounced absorbance change around 563 nm was found in all algae examined. 3-(3,4-dichlorophenyl)-1,1-dimethylurea and gramicidin J suppressed the initial rate and the magnitude of the absorbance change. Carbonylcyanidem-chlorophenylhydrazone did not affect the initial rate but decreased the maximum level of the change. All thalli and the chloroplasts tested had an absorption band at around 540 nm due to fucoxanthin which accounted for about 70–90% of the total carotenoids in brown algae. It is proposed that the 563 nm-change is caused by the red shift of fucoxanthin responding to the light-induced change in the membrane potential of the thylakoid system.     

The effects of dithiothreitol on violaxanthin de-epoxidation and absorbance changes in the 500-nm region

The effects of dithiothreitol on absorbance changes at 505 and 515 nm in isolated lettuce chloroplasts were investigated. Dithiothreitol inhibited the ascorbate-dependent 505-nm change that is due to the de-epoxidation of violaxanthin to zeaxanthin. Dithiothreitol was effective for both light-induced de-epoxidation at pH 7 and dark de-epoxidation at pH 5. Titration of de-epoxidase activity with dithiothreitol resulted in complete inhibition at about 5 μmoles dithiothreitol per mg chlorophyll. Removal of dithiothreitol restored de-epoxidase activity. These results are consistent with the view that dithiothreitol inhibits violaxanthin de-epoxidation and the corresponding 505-nm change by reducing a disulfide that is required for de-epoxidase activity.

Dithiothreitol was effective in resolving absorbance changes due to violaxanthin de-epoxidation and other changes that were superimposed under some conditions. At 515 nm and in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), phenazine methosulfate, and ascorbate, dithiothreitol inhibited the large, slow and irreversible change which was due to de-epoxidation but not the fast and reversible so-called 515-nm change. At 505 nm and under similar conditions, dithiothreitol revealed the presence of a slow reversible change in addition to the one from de-epoxidation. Results with dithiothreitol showed that the absorbance change at 505 nm in the presence of DCMU, 2,6-dichlorophenolindophenol and ascorbate was due entirely to de-epoxidation. Similarly, absorbance changes at 515 nm also appeared to be mainly from de-epoxidation but with the presence of a small transient change due to some other components. It is suggested that dithiothreitol may be useful in resolving complex light-induced absorbance changes in other photosynthetic systems as well as in enabling new studies on reversible absorbance changes in the 500-nm region.     

Light-induced movement of magnesium ions in intact chloroplasts. Spectroscopic determination with Eriochrome Blue SE

The metallochromic indicator Eriochrome Blue SE was used to measure light-induced internal movement of Mg²⁺ in intact chloroplasts. By dual-wavelength spectroscopy (measuring wavelength 554 nm, reference 592 nm) a light-induced, dark-reversible absorbance increase of Eriochrome Blue in samples of isolated intact chloroplasts was observed. The light/dark difference spectrum of Eriochrome Blue between 550 and 590 nm (reference wavelength 562 nm) indicated that this absorbance increase was caused by an increased concentration of free Mg²⁺ in a neutral or slightly alkaline chloroplast compartment.

The signal was seen only with intact, but not with broken, envelope-free chloroplasts, which had lost most of their divalent cations. This is interpreted to show that the indicator responds to an increase of Mg²⁺ concentration in the chloroplast stroma, which represents an efflux of Mg²⁺ from the intra-thylakoid space caused by light-dependent proton pumping.

As calculated from corrected values of the absorbance increase of Eriochrome Blue, the light-induced internal release of Mg²⁺ was close to 100 nequiv per mg chlorophyll at pH 7.6 and 250 nequiv at pH 7.1. This corresponds to a light-dependent increase in the concentration of free Mg²⁺ in the stroma of about 2 and 5 mM, respectively.