Multi-temperature effects on Hill reaction activity of barley chloroplasts

1. 1. The relationship between temperature and Hill reaction activity has been investigated in chloroplasts isolated from barley (Hordeum vulgare L. cv. Abyssinian).

2. 2. An Arrhenius plot of the photoreduction of 2,6-dichlorophenolindophenol (DCIP) showed no change in slope over the temperature range 2–38 °C. The apparent Arrhenius activation energy (E_a) for the reaction was 48.1 kJ/mol.

3. 3. In the presence of an uncoupler of photophosphorylation, methylamine, the E_a for DCIP photoreduction went through a series of changes as the temperature was increased. Changes were found at 9, 20, 29 and 36 °C. The E_a was highest below 9 °C at 63.7 kJ/mol. Between 9 and 20 °C the E_a decreased to 40.4 kJ/mol and again to 20.2 kJ/mol between 20 and 29 °C. Between 29 and 36 °C there was no further increase in activity with increasing temperature. The temperature-induced changes at 9, 20 and 29 °C were reversible. At temperatures above 36 °C (2 min) a thermal and largely irreversible inactivation of the Hill reaction occurred.

4. 4. Temperature-induced changes in E_a were also found when ferricyanide was substituted for DCIP or gramicidin D for methylamine. The addition of an uncoupler of photophosphorylation was not required to demonstrate temperature-induced changes in DCIP photoreduction following the exposure of the chloroplasts to a low concentration of cations.

5. 5. The photoreduction of the lipophilic acceptor, oxidized 2, 3, 5, 6-tetramethyl-p-phenylenediamine, also showed changes in E_a in the absence of an uncoupler.

6. 6. The temperature-induced changes in Hill activity at 9 and 29 °C coincided with temperature-induced changes in the fluidity of chloroplast thylakoid membranes as detected by measurements of electron spin resonance spectra. It is suggested that the temperature-induced changes in the properties and activity of chloroplast membranes are part of a control mechanism for regulation of chloroplast development and photosynthesis by temperature.

Inorganic pyrophosphatase and photosynthesis by isolated chloroplasts. II. The controlling influence of orthophosphate

1. 1. It has been proposed that Mg²⁺, inorganic pyrophosphate and a protein fraction which exhibits fructose-1,6-diphosphatase activity may interact to regulate photosynthesis by isolated chloroplasts.

2. 2. Evidence is presented which confirms the interaction and regulation but shows that these effects are indirectly attributable to pyrophosphatase activity rather than fructose-1,6-diphosphatase.

3. 3. When provided with Mg²⁺ and PP_i the pyrophosphatase simply alters the proportions of orthophosphate and PP_i in the reaction mixture. As the P_i concentration is increased, it first stimulates and then inhibits, the degree of inhibition being enhanced by additional Mg²⁺. PP_i ameliorates the inhibition, possibly by chelation of Mg²⁺.

4. 4. It is concluded that the proposed regulation is ultimately governed by the P_i concentration and the known relationship between P_i uptake and triose phosphate export across the chloroplast envelope.

The high-energy state of the thylakoid system as indicated by chlorophyll fluorescence and chloroplast shrinkage

Certain long-term fluorescence phenomena observed in intact leaves of higher plants and in isolated chloroplasts show a reverse relationship to light-induced absorbance changes at 535 nm (“chloroplast shrinkage”).

1. 1. In isolated chloroplasts with intact envelopes strong fluorescence quenching upon prolonged illumination with red light is accompanied by an absorbance increase. Both effects are reversed by uncoupling with cyclohexylammonium chloride.

2. 2. The fluorescence quenching is reversed in the dark with kinetics very similar to those of the dark decay of chloroplast shrinkage.

3. 3. In intact leaves under strong illumination with red light in CO₂-free air a low level of variable fluorescence and a strong shrinkage response are observed. Carbon dioxide was found to increase fluorescence and to inhibit shrinkage.

4. 4. Under nitrogen, CO₂ caused fluorescence quenching and shrinkage increase at low concentrations. At higher CO₂ levels fluorescence was increased and shrinkage decreased.

5. 5. In the presence of CO₂, the steady-state yield of fluorescence was lower under nitrogen than under air, whereas chloroplast shrinkage was stimulated in nitrogen and suppressed in air.

6. 6. These results demonstrate that the fluorescence yield does not only depend on the redox state of the quencher Q, but to a large degree also on the high-energy state of the thylakoid system associated with photophosphorylation.

Effect of lincomycin on the chlorophyll protein complex I content and Photosystem I activity of greening leaves

1. 1. Greening barley and pea leaves treated with lincomycin have a reduced chlorophyll content. Lincomycin does not alter the proportion of chlorophyll in chlorophyll-protein complex II (CPII) but greatly reduces that in chlorophyll-protein complex I (CPI).

2. 2. Difference spectra show that chloroplasts from lincomycin-treated leaves are deficient in at least two long wavelength forms of chlorophyll a. These have maxima at 77 K of 683 and 690 nm.

3. 3. The chemically determined P-700/chlorophyll ratio of chloroplasts is unaffected by lincomycin but the photochemical P-700/chlorophyll ratio is less than half of that of the control. It is less affected than the chlorophyll-protein complex I content.

4. 4. Photosystem I activity expressed on a chlorophyll basis is unaffected by lincomycin but the light intensity for half saturation is increased 8-fold.

5. 5. Chlorophyll-protein complex I apoprotein content is reduced by lincomycin. No evidence was found for an accumulation of its precursor(s). The relative abundance of major peptides of 18 000, 15 000 and 12 000 daltons in lincomycin-treated chloroplasts is attributed to a general inhibition of greening and associated membrane formation.

Interaction of oxidized and reduced N-methylphenazonium methosulfate (PMS) with Photosystem II

In 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) poisoned chloroplasts, the restoration of the fluorescence induction is presumed to be due to a back reaction of the reduced primary acceptor (Q⁻) and the oxidized primary donor (Z⁺) of Photosystem II. Carbonylcyanide m-chlorophenylhydrazone (CCCP) is known to inhibit this back reaction. The influence of reduced N-methylphenazonium methosulfate (PMS) in the absence of CCCP and of oxidized PMS in the presence of CCCP on the back reaction was investigated and the following results were obtained:

1. (1) Reduced PMS at the concentration of 1 μM inhibits the back reaction as effectively as hydroxylamine, suggesting an electron donating function of reduced PMS for System II.

2. (2) The inhibition of the back reaction by CCCP is regenerated to a high degree by oxidized PMS which led to assume a cyclic System II electron flow catalysed by PMS.

3. (3) At concentrations of reduced PMS higher than 1 μM it is shown that both the fast initial emission and more significantly the variable emission are quenched.

A study on exposure to ultraviolet rays during outdoor sports activity

1. 1. Intensities of ultraviolet rays (UV) from every direction and the amount of UV absorbed by each body part was measured in four situations (track, beach, golf course and skiing slope).

2. 2. The intensity of UV was measured by a portable UV meter and the amount of UV absorbed by every body part was measured with a UV irradiation energy measurement label.

3. 3. The intensity of UV was strong from S45° and SE45° in all cases. On snow, the intensity of UV from every direction was stronger than in other situations, it was especially strong in reflection from below and from the north. The UV reflection from the sand was slightly larger than that from mud and grass.

4. 4. The experimental day's weather was fine and occasionally cloudy during golf, beach activity and gate-ball, and clear during skiing.

5. 5. The UV deal of a horizontal plane was 135, 98, 156 and 120 kJ/m²/h at golf, beach activity, gate-ball and skiing, respectively.

6. 6. This study suggests that players should be concerned with the prevention of UV radiation during sporting activity.

Lactoperoxidase-catalyzed iodination of chloroplast membranes. I. Analysis of surface-localized proteins

Lactoperoxidase-catalyzed iodination of chloroplast membranes has been employed to characterize the vectorial distribution of lamellar proteins. The enzymatic reaction is highly specific for only the outermost membrane components (Phillips, D. R. and Morrison, M. (1971) Biochemistry 10, 1766–1771); we have determined the distribution of ¹²⁵I label and changes in photochemical activities after iodination in an effort to identify these components. Three major conclusions are evident:

1. 1. The coupling factor for photophosphorylation is highly exposed and is selectively and rapidly inhibited by the iodination reaction.

2. 2. A loss of Photosystem I activity (NADP reduction) resulted from iodination. Partial reactions indicated the effect was on electron-transport components on the reducing side of Photosystem I. There was also a limited inhibition of methyl viologen reduction.

3. 3. Iodination of intact membranes caused a reduction in rates of Photosystem II-dependent Hill reaction activity. This inhibition could not be explained solely on the basis of iodination effects on electron-transport components involved in the oxidation of water. The implications of these data with respect to previous chloroplast-membrane models are discussed.

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.

Inorganic pyrophosphatase and photosynthesis by isolated chloroplasts. I. Characterisation of chloroplast pyrophosphatase and its relation to the response to exogenous pyrophosphate

1. 1. A soluble, alkaline, Mg²⁺-dependent inorganic pyrophosphatase (EC 3.6.1.1) has been isolated from the stroma of intact spinach and pea chloroplasts and purified some 100-fold. The enzyme has a high specificity for inorganic pyrophosphate and Mg²⁺, and exhibits maximal activity at pH 8.2–8.6. The enzyme shows allosteric characteristics with Mg²⁺ as activator and optimal rates are obtained with a ratio of Mg²⁺ to PP_i of approximately 4 to 1. The enzyme is inhibited by anionic PP_i and by its own reaction product, orthophosphate.

2. 2. If Mg²⁺ is excluded from the medium in which isolated chloroplasts are assayed, active photosynthetic oxygen evolution can still be observed. The addition of P_i, but not PP_i, will then offset a phosphate deficiency. If external Mg²⁺ is present PP_i will also offset a phosphate deficiency and in these circumstances the rapidity and nature of the response is related to the external pyrophosphatase activity.

3. 3. Evidence is presented that the chloroplast envelope is relatively impermeable to PP_i and that the response to added PP_i is due to external hydrolysis followed by entry of P_i to the chloroplast. These results have significance concerning proposed mechanisms for control of photosynthesis.

Studies on the ADRY agent-induced mechanism of the discharge of the holes trapped in the photosynthetic waterspliting enzyme system Y

The effect of 2-(3-chloro-4-trifluoromethyl)anilino-3,5-dinitrothiophene (ANT 2p) on the oxygen evolution, fluorescence and delayed light emission of spinach chloroplasts has been investigated. It was found that;

1. 1. ANT 2p strongly accelerates the deactivation of states S₂ and S₃ of the water-splitting enzyme system Y.

2. 2. In DCMU-poisoned chloroplasts ANT 2p prevents the back reaction of the electrons located at the primary acceptor, Q, with the holes (positive charges) stored in the water-splitting enzyme system Y.

3. 3. In chloroplast suspensions without artificial electron acceptors, the fluorescence rise in weak actinic light vanishes in the presence of ANT 2p. The fluorescence yield in DCMU-inhibited chloroplasts is not significantly changed by ANT 2p.

4. 4. The intensity of the delayed light emitted after excitation with one short flash is remarkably decreased by ANT 2p.

5. 5. In weak actinic light the reduction rate of the artificial electron acceptor methyl viologen is suppressed in the presence of ANT 2p.

From these experimental results it is concluded that ANT 2p induces a cycle within the electron transport chain, leading to a dissipative recombination of the holes stored in the water-splitting enzyme Y with the electrons of an as yet unknown donor.

Two possibilities for the mode of action of this cycle are discussed.     

Ethanol effects on temperature-sensitive hypothalamic neurons in rat brain slices

1. We recorded impulse activity of thermosensitive hypothalamic neurons in rat brain slices during superfusion with ethanol at constant temperatures and during slow sinusoidal temperature changes.

2. At constant temperatures of 37 °C, ethanol application typically induced a triphasic change of the firing rate: An initial excitation turned into complete inhibition followed by spontaneous recovery to higher firing rates.

3. Ethanol application increased the neurons’ temperature sensitivity remarkably.

4. Our data indicate complex neuromodulatory effects of ethanol with different time delays which interfere with basic mechanisms of temperature transduction.

Effect of low temperature (−30 to −60°C) on the reoxidation of the Photosystem II primary electron acceptor in the presence and absence of 3(3,4-dichlorophenyl)-1,1-dimethylurea

The fluorescence yield has been measured on spinach chloroplasts at low temperature (−30 to −60°C) for various dark times following a short saturating flash. A decrease in the fluorescence yield linked to the reoxidation of the Photosystem II electron acceptor Q is still observed at −60°C. Two reactions participate in this reoxidation: a back reaction or charge recombination and the transfer of an electron from Q⁻ to Pool A. The relative competition between these two reactions at low temperature depends upon the oxidation state of the donor side of the Photosystem II center:

1. (1) In dark-adapted chloroplasts (i.e. in States S₀+S₁ according to Kok, B., Forbush, B. and McGloin, M. (1970) Photochem. Photobiol. 11, 457–475), Q, reduced by a flash at low temperature, is reoxidized by a secondary acceptor and the positive charge is stabilized on the Photosystem II donor Z. Although this reaction is strongly temperature dependent, it still occurs very slowly at −60°C.

2. (2) When chloroplasts are placed in the S₂+S₃ states by a two-flash preillumination at room temperature, the reoxidation of Q⁻ after a flash at low temperature is mainly due to a temperature-independent back reaction which occurs with non-exponential kinetics.

3. (3) Long continuous illumination of a frozen sample at −30°C causes 6–7 reducing equivalents to be transferred to the pool. Thus, a sufficient number of oxidizing equivalents should have been generated to produce at least one O₂ molecule.

4. (4) A study of the back reaction in the presence of 3(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) shows the superposition of two distinct non-exponential reactions one temperature dependent, the other temperature independent.

Some effects of hydrolytic enzymes on coupled and uncoupled electron flow in chloroplasts

Digestion of spinach chloroplasts with pancreatic lipase or trypsin effectively uncoupled electron transport. Continued digestion led to inhibition of saturated rates of Hill reaction activity and a decrease in quantum yield. Irradiation with ultraviolet light decreased the quantum yield and inhibited Hill activity, but did not uncouple. Ascorbate-dichlorophenol-indophenol-mediated reduction of nicotinamide adenine dinucleotide phosphate was not appreciably inhibited by treatment with either of the enzymes or by ultraviolet irradiation.     

The mechanism of the oxidation of ascorbate and Mn by chloroplasts: The role of the radical superoxide

1. 1. The mechanism of the photooxidation of ascorbate and of Mn²⁺ by isolated chloroplasts was reinvestigated.

2. 2. Our results suggest that ascorbate or Mn²⁺ oxidation is the result of the Photosystem I-mediated production of the radical superoxide, and that neither ascorbate nor Mn²⁺ compete with water as electron donors to Photosystem II nor affect the rate of electron transport through the two photosystems: The radical superoxide is formed as a result of the autooxidation of the reduced forms of low potential electron acceptors, such as methylviologen, diquat, napthaquinone, or ferredoxin.

3. 3. In the absence of ascorbate or Mn²⁺ the superoxide formed dismutases either spontaneously or enzymatically producing O₂ and H₂O₂. In the presence of ascorbate or Mn²⁺, however, the superoxide is reduced to H₂O₂ with no formation of O₂. Consequently, in the absence of reducing compounds, in the reaction H₂O to low potential acceptor one O₂ (net) is taken up per four electrons transported where as in the presence of ascorbate, Mn²⁺ or other suitable reductants up to three molecules O₂ can be taken up per four electrons transported.

4. 4. This interpretation is supported by the following observations: (a) in a chloroplast-free model system containing NADPH and ferredoxin-NADP reductase, methylviologen can be reduced to a free radical which is autooxidizable in the presence of O₂; the addition of ascorbate or Mn²⁺ to this system results in a two fold stimulation of O₂ uptake, with no stimulation of NADPH oxidation. The stimulation of O₂ uptake is inhibited by the enzyme superoxide dismutase; (b) the stimulation of light-dependent O₂ uptake in the system H₂O → methylviologen in chloroplasts is likewise inhibited by the enzyme superoxide dismutase.

5. 5. In Class II chloroplasts in the system H₂O → NADP upon the addition of ascorbate or Mn²⁺ an apparent inhibition of O₂ evolution is observed. This is explained by the interaction of these reductants with the superoxide formed by the autooxidation of ferredoxin, a reaction which proceeds simultaneously with the photoreduction of NADP. Such an effect usually does not occur in Class I chloroplasts in which the enzyme superoxide dismutase is presumably more active than in Class II chloroplasts.

6. 6. It is proposed that since in the Photosystem I-mediated reaction from reduced 2,4-dichlorophenolindophenol to such low potential electron acceptor as methylviologen, superoxide is formed and results in the oxidation of the ascorbate present in the system, the ratio ATP/2e in this system (when the rate of electron flow is based on the rate of O₂ uptake) should be revised in the upward direction.

Analysis of light-induced proton uptake in isolated chloroplasts

1. 1. A simple kinetic analysis of light-induced proton uptake into chloroplasts is presented. It is derived from a model of the reaction in which the incoming proton is obligatorily bound by an intra-chloroplast component, and allows quantitative analysis of the effect into parameters of light and dark rate constants and the availability of the chloroplast component.

2. 2. The effect of the following agents on the derived parameters has been measured: electron and energy transfer inhibitors, uncouplers, NaCl concentration, light intensity and pH.

3. 3. A maximal ratio of 4 protons taken up per electron transported has been observed, using ferricyanide as an electron acceptor.

4. 4. A stimulation of light-induced proton uptake by phosphate or arsenate, ADP and Mg has been observed. It was not sensitive to concentrations of Dio-9, which eliminated ATP synthesis.

5. 5. The results are seen as inconsistent with the chemiosmotic theory of energy coupling as presently presented. It is suggested that they may be interpreted in terms of a model in which the function of the proton pump is to enable co-transport into the chloroplasts of the negatively charged complex of phosphate, ADP and Mg.

Sites of function of manganese within photosystem II. Roles in O2 evolution and system II

The Mn content of spinach chloroplasts has been decreased by growth deficiency, extraction and by ageing at 35°. We studied the effect of subnormal Mn content upon the chloroplasts capacity to evolve O₂ and to photooxidize electron donors other than water via Photosystem II. We observed the following:

1. 1. In fresh chloroplasts ascorbate and other reducing agents, if present in sufficient concentration, fully replace water as the System II oxidant and can sustain maximum rates of 1000–1200 equiv/chlorophyll per h.

2. 2. None of the studied donors proved entirely specific for System II; to a variable extent all could react with the oxidant of System I. We therefore considered only the 3-(3,4-dichlorophenyl)-1,1-dimethylurea-(DCMU)-sensitive fraction of the observed rates as pertinent.

3. 3. Normal fresh chloroplasts contained 3 Mn/200 chlorophylls_II and showed flash yields of approx. 1 O₂/1600 chlorophylls. This indicates that each System II trapping and O₂-evolving center contains three Mn atoms.

4. 4. O₂ evolution capacity is abolished when about 2/3 of the total Mn pool is removed by way of Tris or hydroxylamine extraction, i.e. upon removal of two of the three Mn atoms normally present per reaction center. Between the limits of 1 Mn per trap and 3 Mn per trap O₂ evolution capacity is linear with Mn content.

5. 5. Mn removal affects the rates of O₂ evolution in strong light and in weak light (quantum yield) in the same fashion. This indicates that complete O₂ reaction centers are inactivated.

6. 6. With Mn removal the capacity for donor (ascorbate or p-phenylenediamine) photooxidation in strong light declines in a very similar fashion as the O₂ evolving capacity. However, after removal of 2/3 of the Mn pool (by Tris or hydroxylamine extraction) 15–20% of the maximum rate remains (100–250 equiv/chlorophyll per h) as previously noticed by other workers. Secondly, the rate in weak light (quantum yield) of these photooxidations remains unaffected by Mn removal. This shows that for donor photooxidation the larger of the two Mn pools is not essential.

7. 7. Complete removal of Mn (< 1 Mn/4000 chlorophylls) led to 90–95% loss of donor photooxidation in strong light.

8. 8. Removal of 2/3 of the Mn left a low fluorescence yield (variable fraction = 0) which could be fully restored by adding DCMU. After complete removal of Mn (< 1 Mn/4000 chlorophylls) DCMU enhanced the yield of the variable fluorescence to only 1/2 the maximum level but the full maximum could be restored by chemical reduction. This indicates that fluorescence quencher of System II, Q, is not affected by Mn removal.

9. 9. Of the three Mn associated with each trapping center, one is linked more closely to the center than the other two. While all three are essential for O₂ evolution, artificial donors can enter with various rate constants at several loci on the oxidant side of System II.

Relative stability of chlorophyll complexes in vivo

The time course of aerobic photobleaching of various chlorophyll-protein complexes in vivo at high light intensities was studied with isolated Aspidistra elatior chloroplasts.

1. 1. C_a680 bleaching starts with the onset of irradiation and, initially, proceeds linearly with time. Washing the chloroplasts causes a nearly constant increase of the bleaching rate throughout the experiment.

2. 2. C_a670 does not appreciably, if at all, bleach initially; subsequently, bleaching proceeds linearly with time and at a slightly higher rate than that for C_a680. Washing makes C_a670 bleach concomitantly with the onset of illumination, and at a nearly constant rate.

3. 3. Bleaching at 665 nm is likely to start only after a relatively long period of illumination. Washing shows no effects during this period. Once bleaching has started, washing causes its rate to increase.

4. 4. No indication of the occurrence of “short-wave” chlorophyll a forms other than C_a670 and C_a665 was obtained.

5. 5. C_b bleaching starts concomitantly with illumination at a low rate. The rate increases more or less exponentially with time. Washing enhances bleaching in two steps.

6. 6. The importance of the results is discussed.

Fluorescence and oxygen evolution from Chlorella pyrenoidosa

The process of photosynthetic energy conversion in Chlorella pyrenoidosa was investigated by simultaneous measurement of transient and steady-state rates of O₂ evolution and fluorescence.

1. 1. Alternation or superimposition of light 1 and light 2 illumination induces both fast and slow changes in fluorescence and rate of O₂ evolution. The fast changes are ascribed to changes in conditions of the reaction centers in the context of the ¹ model and the kinetic analysis of ². The slow changes are interpreted as adaptations to the intensity and wavelength of illumination. The adaptive mechanism is described in terms of slow variation in fraction () of total absorbed quanta delivered to System 2. At low intensities, the calculated value of for cells adapted to light 2 illumination (light 2 state) is approx. 0.9 of for cells adapted to light 1 illumination (light 1 state).

2. 2. An increase in fluorescence yield was found to accompany the decrease in O₂ yield at the onset of light saturation with either light 1 or light 2 excitation. Variation in is proposed to account for the differences between the maximum fluorescence yield observed in steady-state conditions and the 1.5 times higher maximum yield observed in transient conditions or in cells inhibited by 3(3,4-dichlorophenyl)-1,1-dimethylurea. Variation in can also explain the observation of a higher rate of fluorescence emission with light 1 excitation than with light 2 excitation for a given steady-state rate of O₂ evolution.

3. 3. A model for energy conversion by System 2 is proposed to account for our observations. The model proposes competitive dissipation of absorbed energy by photochemical trapping at reaction centers and by fluorescence and radiationless de-excitation from both the pigment bed and reaction centers of System 2.

Rapid delayed luminescence from chloroplasts: Kinetic analysis of components; The relationship to the O2 evolving system

Delayed luminescence from saturating flashes given to isolated chloroplasts was measured in the time range of 65–800 μsec with the following results:

1. 1. Three distinct components having decay half times of approx. 10, 35 and 200 μsec could be detected.

2. 2. The yields of both the 35- and 200-μsec delayed luminescence components oscillate with a period of four, in phase with oscillations of O₂ yield; no large oscillations of fluorescence paralleling those of luminescence or O₂ were observed.

3. 3. 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) abolished the 10- and 200-μsec components and the oscillatory behavior of the 35-μsec component.

4. 4. The 35- and 200-μsec components are not directly influenced by System I.

The DCMU isolated 35-μsec component showed the following properties:

1. 1. The decay is first order and the emission spectrum is essentially identical to that of chloroplast fluorescence;

2. 2. The yield saturates with a total emission of about 10^-4 quanta/trap.

3. 3. The temperature dependence indicates an activation energy of about 250 mV for the yield and 200 mV for the decay.

4. 4. Maximal emission was obtained when Q, the acceptor of System II, was oxidized prior to the flash.

The results are discussed in terms of possible mechanisms concerning the production and behavior of the luminescence.     

Studies on the mechanism of destabilization of the positive charges trapped in the photosynthetic water-splitting enzyme system Y by a deactivation-accelerating agent

The mechanism of the 2-(3,4,5-trichloro)anilino-3,5 dinitrothiophene (ANT 2S)-induced cyclic electron flow leading to the discharge of the higher-trapped-hole accumulation states S₂ and S₃ in the photosynthetic water-splitting enzyme system Y of chloroplasts has been investigated. It was found:

1. 1. Under normal conditions the ANT 2s-catalyzed cycle includes both light reactions.

2. 2. By selective kinetical inhibition of the electron flow through P700—either by histone treatment or by 2,5-dibromo-3-methyl-6-isopropyl-1,4-benzoquinone blockage—the ANT 2s-induced deactivation of S₂ and S₃ is not significantly changed. Hence, System I activity is not a functional prerequisite for the ANT 2s-catalyzed discharge of S₂ and S₃.

3. 3. The reciprocal half time of the ANT 2s-induced decay of the relative average oxygen yield per flash, as a function of the time t_d between the flashes representing the degree of the Acceleration of the Deactivation Reactions of the water-splitting enzyme system (ADRY) effect, is nearly linearly related to the ANT 2s concentration within the range of 10⁻⁷–10⁻⁶ M.

4. 4. In respect to the mode of action of ANT 2s two different types of mechanism have been discussed: fixed-place mechanism and mobile-catalyst mechanism.

5. 5. Based on the experimental data the conclusion has been drawn that the ADRY agent ANT 2s probably acts as a mobile catalyst.