Excited states and primary charge separation in the pigment system of the green photosynthetic bacterium Prosthecochloris aestuarii as studied by picosecond absorbance difference spectroscopy

Picosecond absorbance difference spectra at a number of delay times after a 35 ps excitation flash and kinetics of absorbance changes were measured of the membrane vesicle preparation Complex I from the photosynthetic green sulfur bacterium Prosthecochloris aestuarii. After chemical oxidation of the primary donor the excitation pulse produced singlet and triplet excited states of carotenoid and bacteriochlorophyll a. With active reaction centers present also the flash-induced primary charge separation and subsequent electron transfer were observed. The singlet excited state of the carotenoid, formed by direct excitation at 532 nm, is characterized by an absorbance band peaking at 590 nm. Its average lifetime was calculated to be about 1 ps. Excited singlet states of bacteriochlorophyll a were characterized by a bleaching of their ground state Q_y absorption bands. Singlet excited states, localized on the so-called core complex, were produced by energy transfer from excited carotenoid. Their lifetime was about 70 ps. A decay component of about 280 ps was ascribed to singlet excited bacteriochlorophyll a in the bacteriochlorophyll a protein. These singlet excitations were partly converted to the triplet state. With active reaction centers, oxidation of the primary donor, P-840, characterized by the bleaching of its Q_y and Q_x absorption bands, was observed. This oxidation was accompanied by a bleaching between 650 and 680 nm and an absorbance increase between 680 and 750 nm. These changes, presumably due to reduction of bacteriopheophytin c (Van Bochove, A.C., Swarthoff, T., Kingma, H., Hof, R.M., Van Grondelle, R., Duysens, L.N.M. and Amesz, J. (1984) Biochim. Biophys. Acta 764, 343–346), were attributed to the reduction of the primary electron acceptor. Electron transfer to a secondary acceptor occurred with a time-constant of 550 ± 50 ps. Since no absorbance changes due to reduction of this acceptor were observed in the red or infrared region, we tentatively assume that this acceptor is an iron-sulfur center.     

Dynamics of energy conversion in reaction center core complexes of the green sulfur bacterium Prosthecochloris aestuarii at low temperature.

Excited-state and electron-transfer dynamics at cryogenic temperature in reaction center core (RCC) complexes of the photosynthetic green sulfur bacterium Prosthecochloris aestuarii were studied by means of time-resolved absorption spectroscopy, using selective excitaton of bacteriochlorophyll (BChl) a and of chlorophyll (Chl) a 670. The results indicate that the BChls a of the RCC complex form an excitonically coupled system. Relaxation of the excitation energy within the ensemble of BChl a molecules occurred within 2 ps. A time constant of about 25 ps was ascribed to charge separation. Absorption changes in the 670 nm region, where Chl a 670 absorbs, were fairly complicated. They showed various time constants and were dependent on the wavelength of excitation and they did not lead to a simple picture of the electron acceptor reaction. Energy transfer from Chl a 670 to BChl a occurred with a time constant of 1.5 ps. However, upon excitation of Chl a 670 the amount of oxidized primary electron donor, P840(+), formed relative to that of excited BChl a was considerably larger than upon direct excitation of BChl a. This indicates the existence of an alternative pathway for charge separation which does not involve excited BChl a.     

Absorption spectra of highly purified liver microsomal cytochrome P-450 in non-equilibrium conformational states at low temperatures

Absorption spectra of highly purified liver microsomal cytochrome P-450 in non-equilibrium states were obtained at 77 K by reduction with trapped electrons, formed by gamma-irradiation of the water-glycerol matrix. In contrast to the equilibrium form of ferrous cytochrome P-450 with the heme iron in the high-spin state the non-equilibrium ferrous state has a low-spin heme iron. The absorption spectrum of the non-equilibrium ferrous cytochrome P-450 is characterized by two bands at 564 (-band) and 530 nm (-band). When the temperature is increased to about 278 K this non-equilibrium form of the reduced enzyme is relaxed to the corresponding equilibrium form with a single absorption band at 548 nm in the visible region characteristic for a high-spin heme iron.     

Factors influencing the capacity for photosynthetic carbon assimilation in barley leaves at low temperatures

The aim of this work was to examine the effect upon photosynthetic capacity of short-term exposure (up to 10 h) to low temperatures (5° C) of darkened leaves of barley (Hordeum vulgare L.) plants. The carbohydrate content, metabolite status and the photosynthetic rate of leaves were measured at low temperature, high light and higher than ambient CO₂. Under these conditions we could detect whether previous exposure of leaves to low temperature overcame the limitation by phosphate which occurs in leaves of plants not previously exposed to low temperatures. The rates of CO₂ assimilation measured at 8° C differed by as much as twofold, depending upon the pretreatment. (i) Leaves from plants which had previously been darkened for 24 h had a low content of carbohydrate, had the lowest CO₂-assimilation rates at low temperature, and photosynthesis was limited by carbohydrate, as shown by a large stimulation of photosynthesis by feeding glucose, (ii) Leaves from plants which had previously been illuminated for 24 h and which contained large carbohydrate reserves showed an accumulation of phosphorylated intermediates and higher CO₂-assimilation rates at low temperature, but nevertheless remained limited by phosphate, (iii) Maximum rates of CO₂ assimilation at low temperature were observed in leaves which had intermediate reserves of carbohydrate or in leaves which were rich in carbohydrate and which were also fed phosphate. It is suggested that carbohydrate reserves potentiate the system for the achievement of high rates of photosynthesis at low temperatures by accumulation of photosynthetic intermediates such as hexose phosphates, but that this potential cannot be realised if, at the same time, carbohydrate accumulation is itself leading to feedback inhibition of photosynthesis. This work was supported by the Agricultural and Food Research Council, UK (Research grant PG50/67) and by the Science and Engineering Reserach Council, UK. C.A.L. was supported by the British Council, by an Overseas Research Student Award and by the Conselho Nacional de Desenvolvimento Cientifico e Tecnologico (CNPq), Brazil.     

Studies on excitation energy flow in the photosynthetic pigment system; Structure and energy transfer mechanism

Excitation energy flow in photosynthetic pigment systems is discussed in relation to structure of the system and transfer mechanism for each elementary process. Three typical examples for actual transfer processes are shown for the phycobilin system in cyanobacteria, the antenna system of photosynthetic bacteria and the Chla/c antenna system of brown algae. The main analytical method was the time-resolved fluorescence spectroscopy in the picosecond time range. In general, static optical charactersitics are not the main reason for the transfer efficiency, but the structure of the system is a prerequisite for the transfer process. On the phycobilin system, theoretical investigation was compared with experimental analysis, which leads to the essential understanding of the transfer process in terms of quantum mechanics. Recipient of the Botanical Society Award for Young Scientists, 1989.     

In vivo states and functions of carotenoids in an aerobic photosynthetic bacterium,Erythrobacter longus

In vivo states and functions of carotenoids in the membranes and the isolated RC-B865 pigment-protein complexes from an aerobic photosynthetic bacterium, Erythrobacter longus, are investigated by means of fluorescence excitation and resonance Raman (RR) spectra. Erythroxanthin sulfate, a dominant carotenoid species in the membranes (>70%), is found not to transfer the absorbed light energy to bacteriochlorophyll (Bchl), and its RR spectra are similar between the in vivo and in vitro states. These observations indicate that erythroxanthin sulfate does not interact with either Bchl or proteins in the membranes, and suggest that its function may be limited to photoprotection by quenching the harmful singlet oxygen. On the other hand, two other carotenoid species contained in the isolated RC-B865 complexes, zeaxanthin and bacteriorubixanthinal, have a high efficiency of energy transfer to Bchl (88±5%). The RR spectra of these two carotenoids, each of which can be selectively obtained by choosing the excitation wavelength, show some characteristics of interactions with proteins or Bchl.Abbreviations Bchl bacteriochlorophyll a - FWHM full width at half maximum - PAGE polyacrylamide gel electrophoresis - RC reaction center - RR resonance Raman - SDS sodium dodecyl sulfate     

Effect of light quality on sulfide photo-oxidation and growth in an artificial biofilm of the green sulfur bacterium Prosthecochloris aestuarii

We have succeeded in culturing an axenic biofilm of the green sulfur bacterium Prosthecochloris aestuarii strain CE 2404 in an artificial sandy sediment under visible light (400–700 nm). This simulates the conditions of deep submerged sediments. A five-week incubation period, using a 16-hour light / 8-hour dark regime, was applied in the benthic gradient chamber (BGC). The biofilm was located below the oxygen penetration depth of 1.2 mm, namely between 1.5 and 2.5 mm and the biomass peak was at 2.1 mm depth. This is much shallower compared to previously described artificial mats of P. aestuarii, which were grown in the BGC under near infrared (NIR)-rich light. High resolution time courses of photosynthesis were measured as sulfide photo-oxidation rates and studied under visible light and visible light amended with NIR to assess the effect of light quality. Sulfide photo-oxidation rates were rather low under visible light and strongly stimulated at most depths under full light conditions. However, under the latter conditions the rates decelerated after a maximum rate was reached at 8–10 min, apparently due to diffusional limitation of sulfide supply. It was concluded that the top of the mat was not limited by the photon flux density, while the biomass peak and the bottom of the biofilm were severely light limited under the culture conditions. These results support the hypothesis that a biofilm of P. aestuarii can develop in deep submerged sediments, when the oxygen penetration depth is very shallow. Nevertheless, the addition of NIR light strongly enhances the potential of P. aestuarii to grow deeper in the sediment.This revised version was published online in October 2005 with corrections to the Cover Date.     

Electronic excitation transfer in the photosynthetic unit: Reflections on work of William Arnold

Among his many contributions to photosynthesis, William Arnold made critical suggestions about the mechanism of the initial stages of excitation energy transfer and its measurement. Thus he helped found not only the general concept of the photosynthetic unit but also the key idea behind the detailed functional aspects of its chlorophyll antenna. We review the development of these ideas and the modern form in which they have emerged.Abbreviations Chl chlorophyll - Pc phycocyanin - PSU photosynthetic unit - RC reaction center     

On the aggregational states of protochlorophyllide and its protein complexes in wheat etioplasts

The inner membranes from wheat ( Triticum aestivum L. cv. Walde) etioplasts were separated into membrane fractions representative of prolamellar bodies and prothylakoids by differential and gradient centrifugations. The isolated fractions were characterized by absorption-, low-temperature fluorescence-, and circular dichroism (CD) spectroscopy, by high performancy liquid chromatography and by sodium dodecyl sulphate polyacrylamide gel electrophoresis.
The prolamellar body fraction was enriched in NADPH-protochlorophyllide oxidoreductase (E.C. 1.6.99.1), and in protochlorophyllide showing an absorption maximum at 650 nm and a fluorescence emission maximum at 657 nm. Esterified protochlorophyllide was mainly found in the prothylakoid fraction. The carotenoid content was qualitatively the same in the two fractions. On a protein basis the carotenoid content was about three times higher in the prolamellar body fraction than in the prothylakoid fraction. The CD spectra of the membrane fractions showed a CD couplet with a positive band at 655 nm, a zero crossing at 643–644 nm and a negative band at 623–636 nm. These results differ from earlier CD measurements on protochlorophyllide holochrome preparations. The results support the interpretation that protochlorophyllide is present as large aggregates in combination with NADPH and NADPH-protochlorophyllide oxidoreductase in the prolamellar bodies.     

Spectral heterogeneity and time-resolved spectroscopy of excitation energy transfer in membranes of Heliobacillus mobilis at low temperatures.

Transient absorption difference spectra in the Qy absorption band from membranes of Heliobacillus mobilis were recorded at 140 and 20 K upon 200 fs laser pulse excitation at 590 nm. Excitation transfer from short wavelength absorbing forms of bacteriochlorophyll g to long wavelength bacteriochlorophyll g occurred within 1-2 ps at both long wavelength bacteriochlorophyll g occurred within 1-2 ps at both temperatures. In addition, a slower energy transfer process with a time constant of 15 ps was observed at 20 K within the pool of long wavelength-absorbing bacteriochlorophyll g. Energy transfer from long wavelength antenna pigments to the primary electron donor P798 was observed, yielding the primary charge-separated state P798+A0-. The time constant for this process was 30 ps at 140 K and about 70 ps at 20 K. A decay component with smaller amplitude and a lifetime of up to hundreds of picoseconds was observed that was centered around 814 nm at 20 K. Kinetic simulations using simple lattice models reproduce the observed decay kinetics at 295 and 140 K, but not at 20 K. The kinetics of energy redistribution within the spectrally heterogeneous antenna system at low temperature argue against a simple "funnel" model for the organization of the antenna of Heliobacillus mobilis and favor a more random spatial distribution of spectral forms. However, the relatively high rate of energy transfer from long wavelength antenna bacteriochlorophyll g to the primary electron donor P798 at low temperature is difficult to explain with either of these models.     

Presence and significance of minor antenna components in the energy transfer sequence of the green photosynthetic bacterium Chloroflexus aurantiacus

Antenna components in the energy transfer processes of a green photosynthetic bacterium Chloroflexus aurantiacus were spectrally investigated by time-resolved fluorescence spectroscopy at −196°C on intact cells. Besides major antenna components so far reported, three minor components were resolved; those were Bchl c located at 785 nm, the baseplate Bchl a at 819 nm and Bchl a in the B808-866 complex at 910 nm. The last component was assigned to a longer wavelength antenna closely associated with a reaction center. An additional Bchl c fluorescence component was kinetically suggested to be present, which can be an energy donor to a major Bchl c. Presence of these minor components was signified in terms of (1) increase in the spectral overlap integral and (2) adjustment of the direction of dipole moments in the energy transfer sequence of intact cells.     

Application of low temperatures during photoinhibition allows characterization of individual steps in photodamage and the repair of photosystem II

Recent investigations of photoinhibition have revealed that photodamage to photosystem II (PSII) involves two temporally separated steps: the first is the inactivation of the oxygen-evolving complex by light that has been absorbed by the manganese cluster and the second is the impairment of the photochemical reaction center by light that has been absorbed by chlorophyll. Our studies of photoinhibition in Synechocystis sp. PCC 6803 at various temperatures demonstrated that the first step in photodamage is not completed at low temperatures, such as 10°C. Further investigations suggested that an intermediate state, which is stabilized at low temperatures, might exist at the first stage of photodamage. The repair of PSII involves many steps, including degradation and removal of the D1 protein, synthesis de novo of the precursor to the D1 protein, assembly of the PSII complex, and processing of the precursor to the D1 protein. Detailed analysis of photodamage and repair at various temperatures has demonstrated that, among these steps, only the synthesis of the precursor to D1 appears to proceed at low temperatures. Investigations of photoinhibition at low temperatures have also indicated that prolonged exposure of cyanobacterial cells or plant leaves to strong light diminishes their ability to repair PSII. Such non-repairable photoinhibition is caused by inhibition of the processing of the precursor to the D1 protein after prolonged illumination with strong light at low temperatures.     

Effects of changes in the capacity for photosynthetic electron transfer and photophosphorylation on the kinetics of fluorescence induction in isolated chloroplasts

Chlorophyll fluorescence, 9-aminoacridine fluorescence and O₂ evolution have been measured in a chloroplast system reconstituted to simulate the induction kinetics observed in leaves. Transients in redox state and energy state, both of which control the yield of fluorescence, were seen to depend upon (a) light intensity, (b) electron-transfer rate as controlled by ferredoxin level, (c) the initial levels of ADP and phosphate and (d) the initial level of NADP. These factors were shown to interact to produce a range of fluorescence patterns. It is suggested that in vivo fluorescence transients in part are due to reduction and phoshorylation of the finite NADP and ADP pools that exist in the chloroplast prior to illumination.     

Characteristic temperature dependences of respiratory and photosynthetic electron-transport activities in membrane preparations from Anacystis nidulans grown at different temperatures

Electron-transport activities supported by seven different electron donor/acceptor couples in the light and in the dark, respectively, were measured in particle preparations of the cyanobacterium (blue-green alga) Anacystis nidulans after growth at 40, 30 and 25°C. The Arrhenius plots of the photosynthetic electron-transport reactions between ascorbate (plus 2,6-dichlorophenolindophenol (DCIP)) and NADP⁺, diphenylcarbazide and DCIP, diaminodurene and benzyl viologen (O₂), and the plot of the photooxidation of reduced horse heart cytochrome c showed a single discontinuity at approx. 24–25, 15–17 and 10–13°C in membranes derived from cells grown at 40, 30 and 25°C, respectively. By contrast, the dark respiratory electron-transport reactions between NADPH, ascorbate (plus DCIP) or reduced horse heart cytochrome c and oxygen, and the reduction by horse heart cytochrome c of the aa₃-type terminal oxidase as followed directly by dual-wavelength spectrophotometry, all gave Arrhenius plots distinguished by two distinct breaks: The break at the higher temperature corresponded to the break also found in the Arrhenius plots of the photosynthetic reactions while an additional discontinuity was observed at 17–18, 8–9 and 5–6°C in membranes prepared from cells grown at 40, 30 and 25°C, respectively. The temperatures at which the discontinuities in the Arrhenius plots occurred depended on the temperature at which the cells had been grown; they were independent, however, of the specific electron donors and acceptors employed. The characteristic features in the Arrhenius plots of respiratory and photosynthetic electron-transport reactions are discussed in terms of lipid-phase transitions in the cytoplasmic and the intracytoplasmic (thylakoid) membranes of A. nidulans. Implications for possibly distinct sites of the respiratory and photosynthetic electron-transport systems in A. nidulans will be mentioned.     

The role of electron transport in determining the temperature dependence of the photosynthetic rate in spinach leaves grown at contrasting temperatures

The temperature response of the uncoupled whole-chain electron transport rate (ETR) in thylakoid membranes differs depending on the growth temperature. However, the steps that limit whole-chain ETR are still unclear and the question of whether the temperature dependence of whole-chain ETR reflects that of the photosynthetic rate remains unresolved. Here, we determined the whole-chain, PSI and PSII ETR in thylakoid membranes isolated from spinach leaves grown at 30 degrees C [high temperature (HT)] and 15 degrees C [low temperature (LT)]. We measured temperature dependencies of the light-saturated photosynthetic rate at 360 microl l(-1) CO2 (A360) in HT and LT leaves. Both of the temperature dependences of whole-chain ETR and of A360 were different depending on the growth temperature. Whole-chain ETR was less than the rates of PSI ETR and PSII ETR in the broad temperature range, indicating that the process was limited by diffusion processes between the PSI and PSII. However, at high temperatures, whole-chain ETR appeared to be limited by not only the diffusion processes but also PSII ETR. The C3 photosynthesis model was used to evaluate the limitations of A360 by whole-chain ETR (Pr) and ribulose bisphosphate carboxylation (Pc). In HT leaves, A360 was co-limited by Pc and Pr at low temperatures, whereas at high temperatures, A360 was limited by Pc. On the other hand, in LT leaves, A360 was solely limited by Pc over the entire temperature range. The optimum temperature for A360 was determined by Pc in both HT and LT leaves. Thus, this study showed that, at low temperatures, the limiting step of A360 was different depending on the growth temperature, but was limited by Pc at high temperatures regardless of the growth temperatures.     

Transient intermediary states with high and low folding probabilities in the apparent two-state folding equilibrium of ACBP at low pH

Measurements of the stability as a function of pH for the acyl-coenzyme A binding protein (ACBP) has shown a significant difference in the pH transition midpoint measured by NMR spectroscopy at pH 3.12 and the transition midpoint measured at pH 2.92 and 2.97 by circular dichroism and by fluorescence spectroscopy, respectively. A similar behavior has not been observed in other proteins. It is suggested that these differences arise because the population of the unfolded molecules still contains significant amounts of native like secondary and tertiary structure. NMR spectroscopy measures the concentration of the two components of the folding unfolding equilibrium individually, whereas circular dichroism and fluorescence measure the concentration of the conformations of the light-absorbing chromophores present in both the folded and the unfolded molecules. In the narrow pH range, nascent structure can be detected as the average amount of secondary structure per unfolded molecule and hydrophobic interactions in the population of unfolded molecules. These structures are not observable immediately by NMR spectroscopy; however, a chemical shift analysis of the peptide backbone (13)C chemical shift indicates strongly the existence of short-lived and transient helical structures at pH 2.3. Magnetization transfer studies have been applied to study the equilibrium between folded and unfolded ACBP near the pH transition point measured by NMR. This study has shown that there are two categories of subpopulations in the population of unfolded ACBP. One for which magnetization can be transferred to the folded form during the folding process, and one for which transfer is not observed. The molecules of the latter population of unfolded protein apparently, do not fold within the time-frame of the magnetization transfer experiment. This result suggests the existence of a subpopulation of the acid-unfolded protein molecules with a high propensity for folding. It is suggested that in this subpopulation, a particular set of native like interactions in the peptide backbone and between side-chains in the peptide chain have to be formed.     

Frost hardening and photosynthetic performance of Scots pine (Pinus sylvestris L.) needles. I. Seasonal changes in the photosynthetic apparatus and its function

Photosynthetic CO₂ uptake, the photochemical efficiency of photosystem II, the contents of chlorophyll and chlorophyll-binding proteins, and the degree of frost hardiness were determined in three-year-old Scots pine (Pinus sylvestris L.) trees growing in the open air but under controlled daylength. The following conditions were compared: 9-h light period (short day), 16-h light period (long day), and natural daylength. Irrespective of induction by short-day photoperiods or by subfreezing temperatures, frost hardening of the trees was accompanied by a long-lasting pronounced decrease in the photosynthetic rates of one-year-old needles. Under moderate winter conditions, trees adapted to a long-day photoperiod, assimilated CO₂ with higher rates than the short-day-treated trees. In the absence of strong frost, photochemical efficiency was lower under short-day conditions than under a long-day photoperiod. Under the impact of strong frost, photochemical efficiency was strongly inhibited in both sets of plants. The reduction in photosynthetic performance during winter was accompanied by a pronounced decrease in the content of chlorophyll and of several chlorophyll-binding proteins [light-harvesting complex (LHC)IIb, LHC Ib, and a chlorophyll-binding protein with MW 43 kDa (CP 43)]. This observed seasonal decrease in photosynthetic pigments and in pigment-binding proteins was irrespective of the degree of frost hardiness and was apparantly under the control of the length of the daily photoperiod. Under a constant 9-h daily photoperiod the chlorophyll content of the needles was considerably lower than under long-day conditions. Transfer of the trees from short-day to long-day conditions resulted in a significantly increased chlorophyll content, whereas the chlorophyll content decreased when trees were transferred from a long-day to a short-day photoperiod. The observed changes in photosynthetic pigments and pigment-binding proteins in Scots pine needles are interpreted as a reduction in the number of photosynthetic units induced by shortening of the daily light period during autumn. This results in a reduction in the absorbing capacity during the frost-hardened state. Received: 3 March 1997 / Accepted: 16 July 1997     

Efficient transformation and expression of Vitreoscilla haemoglobin in the biological control bacterium Collimonas pratensis ZL261

Collimonas species are soil bacteria characterised by their ability to attach to and utilise fungi as a food source (mycophagy), as well as their chitin-degrading capacity (via chitinase production). These attributes, alongside volatile compounds, are thought to contribute to their function as fungal antagonists, including economically important plant pathogens. Despite this, studies have found no relationship between antifungal activity and chitinase production, or volatile compounds in Collimonas pratensis isolate ZL261, and there have been no studies on genetic control and regulatory biosynthesis of antifungal substances in Collimonas species. In this study, we showed that low concentrations of dissolved oxygen were unfavourable for growth and antifungal activity. We successfully introduced the gene vgb encoding Vitreoscilla haemoglobin (VHb) into isolate ZL261. The heterologous expression of VHb not only enhanced cell growth, but also improved antifungal activity against the brown rot fungus Monilinia fructicola under oxygen-restricted conditions; 18.6% of untreated peach fruits were infected (average lesion diameter: 9.2?mm), while only 10.8% of fruit treated with the transformed isolate, ZV261, were infected (average lesion diameter: 5.4?mm). These results suggest that the antagonism have been due to the secreted secondary metabolites, which are sensitive to the oxygen-restricted conditions.