DELAYED-LIGHT STUDIES ON PHOTOSYNTHETIC ENERGY CONVERSION-III. EFFECT OF 3-(3,4-DICHLOROPHENYL)-1,1 -DIMETHYL UREA ON THE MILLISECOND EMISSION FROM CHLOROPLASTS PERFORMING PHOTOREDUCTION OF FERRICYANIDE*

Abstract— How does a plant convert electronic excitation of chlorophyll into stable chemical potential? The time scales of fluorescence (10^--⁹ sec) and steady-state enzymatic turnover (10–² sec) indicate that energy storage must be involved. Millisecond delayed singlet emission from chlorophyll allows measurement of metastable energy storage at Photoreaction II. Activation of noncyclic electron transport results in more rapid decay and in increase of emission at 10^--³ sec, both effects being inhibited by the poison DCMU. These results can be explained by at least three different models of the reaction center: the oxidized chlorophyll model, the chlorophyll triplet model, and the two-quantum electron-hole model.     

THE EFFECT OF INHIBITORS AND UNCOUPLERS OF PHOTOSYNTHETIC PHOSPHORYLATION ON THE DELAYED LIGHT EMISSION OF CHLOROPLASTS*

Abstract— Measurements were made of the 3.7 msec delayed light emission of chloroplasts treated with a variety of agents which affect the rate of electron transport (Hill reaction) or photosynthetic phosphorylation. The presence of the electron acceptors ferricyanide or pyocyanine increased delayed light emission. Inhibitors of electron transport (3-(3,4-dichlorophenyl)-1, -1-dimethylurea or 1,10(ortho)-penanthroline) inhibited delayed light emission. The addition of a phosphate acceptor system inhibited delayed light emission. This inhibition was reversed by inhibitors of the phosphorylation reaction, e.g. Dio-9 or phlorizin. From these results it was concluded that the 3.7 msec delayed light emission probably occurs as a result of back reactions of intermediates in the coupled electron transport and photosynthetic phosphorylation systems.     

PHOTOSYNTHETIC NITRITE REDUCTION BY DITHIOERYTHRITOL AND THE EFFECT OF NITRITE ON ELECTRON TRANSPORT IN ISOLATED CHLOROPLASTS

Abstract. Photosynthetic reduction of nitrite to ammonia with type C chloroplasts from the heterocont alga Bumilleriopsis filiformis was investigated using 3,6-diaminodurene/ascorbate and 3,6-diaminodurene/dithioerythritol (DAD/DTE) as electron donor couple. Rates approach 6–10 μmol NO^-₂ reduced/mg chlorophyll/h and are steady for up to 30 min. The presence of oxygen or NADP⁺ only slightly diminished the rates of nitrite reduction obtained with DAD/DTE. Illuminated chloroplasts reduce oxygen in the presence of DAD/DTE at 135 μmol/mg chlorophyll/h without acceptor supplied. Photosynthetic oxygen uptake by this system in the presence of ferredoxin and NO^-₂, however, is inhibited to 42% by nitrite reductase with concurrent nitrite reduction. NO^-₃ and NO^-₂ have no effect on photosystem I-mediated NADP⁺ reduction, NO^-₂ (10 m M ) inhibits ferricyanide-mediated oxygen evolution to 72%. Also photosystem II reactions assayed e.g. with silicomolybdate are inhibited significantly by NO^-₂ (1 m M ), but only slightly by NO^-₃. Nitrite reductase is inhibited by p -chloromercuribenzoate ( p CMB), and this inhibition is prevented by DTE. Results suggest that photosynthetic nitrite reduction can cope with low concentrations of either compound, provided relevant thiol groups are protected.     

从钛铁矿粉制备FeTi及其吸氢性能的研究

氢能源是一种理想的新能源。储氢材料的研制是开发氢能的关键之一。FeTi是性能优良的储氢材料之一^[1-3],为目前常温储氢最便宜的一种材料^[4]。     

EFFECT OF CHLORIDE AND BENZOATE ANIONS ON THE DELAYED LIGHT EMISSION IN DCMU-TREATED SPINACH CHLOROPLASTS

Abstract —Chloride anions, when added to DCMU [3-(3,4-dichlorophenyl)-1,1-dimethylurea]-treated spinach chloroplasts, change the rate of decay of the delayed light emission in the seconds region but do not change the shape or the temperature dependence of the decay. Benzoate anions, on the other hand, change both the rate and the shape of the decay of the delayed light emission. These results are consistent with a model in which the membrane potential and the structure of the reaction center affect the decay kinetics of the delayed light emission in the seconds region.     

PHOTOOXIDATIVE DESTRUCTION OF CHLOROPLASTS AND ITS EFFECT ON NUCLEAR GENE EXPRESSION AND EXTRAPLASTIDIC ENZYME LEVELS *

Abstract The cooperation between the nuclear and plastidic genome has been investigated extensively and it is generally accepted that plastidic development is controlled by the genetic information encoded in the nucleus (Ellis, 1981). It was discovered only recently that plastids are also involved in controlling extraplastidic events. If carotenoid-free plastids are destroyed by photooxidation. expression of plastidic proteins which are encoded in the nucleus is reduced or prevented. Thus is has been postulated that a signal which derives from the plastids controls the expression of these genes in the nucleus. Moreover, extraplastidic enzymes with functions related to intact plastids (such as nitrate reductase and peroxisomal enzymes) are also affected by this treatment, while (photo)morphogenesis and extraplastidic compounds not directly related to plastidic functions seem to be unaffected. Since the damage is restricted exclusively to the plastids and even the outer envelope membrane appears to be unimpaired, photooxidative destruction of carotenoid-free plastids is often used as a tool to investigate nuclear plastid interaction. This review briefly describes the events occurring during photodamage, analyzes the consequences for extraplastidic events, and discusses the implication of a plastidic signal(s) in controlling the expression of nuclear genes which code for plastidic proteins.     

THE MECHANISM OF DELAYED LIGHT PRODUCTION BY PHOTOSYNTHETIC ORGANISMS AND A NEW EFFECT OF ELECTRIC FIELDS ON CHLOROPLASTS*,‡

Abstract— Green plants, after illumination, emit light at times far too long to be fluorescence. This delayed light is closely connected with the process of photosynthesis and seems to be one of the few ways of studying the first steps in that process. In this paper we argue that there are at least 3 or maybe 4 mechanisms producing delayed light. (1) The delayed light in the range of 1–100 msec seems to come from the recombination of electrons and holes. The photosynthetic unit must absorb 2 quanta for this process. (2) At longer times the delayed light can come from thermal fluctuations lifting an electron from the level of ferredoxin to that of chlorophyll. The unit need only absorb 1 light quantum for this kind of delayed light. (3) Similarly, a part of the long-time delayed light comes from the untrapping of holes. (4) A part of the delayed light emitted at times longer than a few minutes seems to involve molecular oxygen. Finally, we shall describe a new phenomenon involving the effect of electric fields on chloroplasts, that we feel will be helpful in understanding the untrapping mechanisms of delayed light production.     

CONTROL OF PHOTOSYNTHETIC REDUCTANT: THE ROLE OF LIGHT AND TEMPERATURE ON SUSTAINED HYDROGEN PHOTOEVOLUTION BY Chlamydomonas sp. IN AN ANOXIC,CARBON DIOXIDE-CONTAINING ATMOSPHERE*

–Sustained hydrogen photoevolution from Chlamy domonas reinhardtii and C. Moewusii was measured under an anoxic, CO₂-containing atmosphere. It has been discovered that light intensity and temperature influence the partitioning of reductant between the hydrogen photoevolution pathway and the Calvin cycle. Under low incident light intensity (1-3 W m^-2) or low temperature (approx. 0°C), the flow of photosynthetic reductant to the Calvin cycle was reduced, and reductant was partitioned to the hydrogen pathway as evidenced by sustained H₂ photoevolution. Under saturating light (25 W m^-2) and moderate temperature (20±5°C), the Calvin cycle became the absolute sink for reductant with the exception of a burst of H₂ occurring at light on. This burst of H₂ corresponded to the expression of about 450 electrons for each photosynthetic electron transport chain. These results suggest that the hydrogen pathway and the Calvin cycle compete for reductant under anoxic conditions and that partioning between the two pathways can, to a certain extent, be controlled by the appropriate choice of experimental conditions.     

BIOCHEMICAL FACTORS AFFECTING THE QUANTUM EFFICIENCY OF HYDROGEN PRODUCTION BY MEMBRANES OF GREEN PHOTOSYNTHETIC BACTERIA*

Abstract— Photohydrogen production, 200-700 μmol H₂ h^?1 (mg bacteriochlorophyll a)^?1 has been obtained in a system containing unit membrane vesicles (Complex I) from the green photosynthetic bacterium Chiorobium limicola f. thiosulfatophilum, ascorbate, N,N,N′,N′-tetramethyl-p-phenylene-diamine, dithioerythritol, an oxygen scavenging mixture, either methyl viologen (MV) or clostridial ferredoxin (CPS Fd) as electron carrier, and either CPS hydrogenase or platinum asbestos as catalyst. All components are necessary for maximum activity, and spinach Fd cannot be substituted for CPS Fd. Higher rates of photohydrogen production are obtained using MV or CPS Fd with hydrogenase than with MV and Pt asbestos. The highest quantum efficiencies (7–10% at 0.2–0.9 mW absorbed light and over 20% at lower light) were obtained with CPS Fd, hydrogenase and non-saturating 812 nm light. With saturating white light, however, rates of photohydrogen production varied relatively little among the various combinations of electron carrier and catalyst tested. The reaction rate is unaffected by 0.03% Triton X-100, and is insensitive to treatment with antimycin a or m-chloro-carbonyl cyanide phenylhydrazone. This indicates that neither electron flow through an endogenous cyclic chain, nor maintenance of a proton gradient are involved in this process.     

STUDIES OF SYSTEM II PHOTOCENTERS BY COMPARATIVE MEASUREMENTS OF LUMINESCENCE,FLUORESCENCE, AND OXYGEN EMISSION*

Abstract— New results are presented on the emission of oxygen by algae and chloroplasts illuminated by a sequence of short saturating flashes. These results favor the four-state hypothesis of Kok and co-workers, in which formation of oxygen requires the accumulation of four oxidants produced by four successive photoreactions. Deactivation of the more oxidized precursor states in the dark is studied under different conditions of preillumination. Our results suggest that both a one step and a two step mechanism of deactivation exist. In order to understand the biological significance of Kok's parameter α—the fraction of photochemical centers unable to react on each flash (“misses”)-we study reoxidation of acceptor Q after one flash by fluorescence techniques. It appears that a fraction of Q^- is reoxidized by a back reaction which cancels the effect of the preilluminating flash and is probably responsible for the misses. The results of some luminescence experiments are also reported. These experiments demonstrate that delayed emission of light is associated with the deactivation of states S₂ and S₃. It is possible that excitons produced by deactivation can be reabsorbed by active photochemical centers, which can modify considerably the deactivation process.     

STUDIES ON THE INTERRELATIONSHIP AMONG THE INTENSITY OF A RAMAN MARKER BAND OF CAROTENOIDS, POLYENE CHAIN STRUCTURE, AND EFFICIENCY OF THE ENERGY TRANSFER FROM CAROTENOIDS TO BACTERIOCHLOROPHYLL IN PHOTOSYNTHETIC BACTERIA

Abstract Resonance Raman spectroscopy was used to study the polyene-chain structure of carotenoids in light-harvesting pigment-protein complexes from purple photosynthetic bacteria. When major carotenoids of Rhodobacter sphaeroides were incorporated into the light-harvesting complexes of Chromatium vinosum , they showed a relatively intense Raman band at 965 cm^-1 arising from the CH out-of-plane wagging modes of the polyene chain. This result was almost the same as that for the intrinsic carotenoids in Chromatium vinosum , but completely different from that for the intrinsic carotenoids in Rhodobacter sphaeroides . On the other hand, the intrinsic carotenoids of Chromatium vinosum lost the intensity of the 965 cm^-1 Raman band upon protein denaturation. These results support the view that the intensity of the 965 cm^-1 Raman band reflects distortion of the polyene chain, independent of its chemical structure. The polyene-chain distortion is affected by the apoprotein to which carotenoids are bound. The distortion of the polyene chain is correlated with a decrease in the efficiency of the energy transfer from carotenoids to bacteriochlorophyll.     

PHOTOSYNTHETIC ACTIVITY AND CHLOROPHYLL ABSORPTION SPECTRA OF FRACTIONS FROM THE ALGA,DUNALIELLA*

Abstract— Dunaliella chloroplasts were fractionated according to C. Arntzen et al, Biochim. Biophys. Acta 256 , 85–107, 1972. The initial French-press treatment and differential centrifugation produced Fraction 1 (Fr 1) enriched in photosystem I activity and a heavier Fraction 2 (Fr 2). When Fr 2 was treated with digitonin followed by either gradient or differential centrifugation, two more fractions were recovered: Fr 1 g with a photosystem 1 activity similar to that of Fr 1, and Fr 2 g with very low photosystem II activity. Photosystem II activity was considerably lower in these Dunaliella chloroplasts and fractions than in spinach particles measured under the same conditions, but the relative activities between the fractions were similar to those for spinach. Fr 2 always had greater photosystem II activity than Fr 1, but the digitonin fractions were low and similar in photosystem II activity. Photosystem II activity was measured as the reduction of 2, 6–dichlorophenol indophenol (DCIP) with H₂O, diphenylcarbazide (DPC) or Mn²⁺ as electron donor. The results indicated that exogenous manganous ion competed with H₂O as an electron donor to photosystem II in broken chloroplasts initially, but after 10–15 s of illumination, the Mn³⁺ formed began to reoxidize DCIP and a cyclic reaction ensued. DPC and Mn²⁺ appeared to react at different sites. Computer-assisted curve analysis of the absorption spectrum of each fraction revealed four major component curves representing the absorbing forms of chlorophyll a at 663, 670, 679 and 684 nm seen in numerous other in vivo chlorophyll spectra (C. S. French et al., Plant Physiol. 49 , 421–429, 1972). However, Fr 2g had approx. 20 percent more of Ca663 and Ca670 and 10% more absorption by chl b than Fr 1 which correlated with the difference in photosystem II activity. On the long wavelength side, Fr 2 g had no Ca694 and almost no photosystem I activity. The results are not sufficient to answer the question of whether the photosystem I particle obtained from the original homogenate is significantly similar to or different from the corresponding fraction obtained from Fr 2 with digitonin.     

十二钼磷酸及其盐在氢气中热分解过程的研究

本文以气相色谱为主要手段,配合红外光谱、X—射线粉末衍射分析及电子顺磁共振技术,研究了十二钼磷酸及其盐在氢气中的还原热稳定性。从对上述化合物在氢气中热解过程的气相产物和各中间固相产物的分析可知,在实验的温度范围内(40～640℃),这些化合物的热分解过程通常分为三或四个阶段。实验发现,Keggin阴离子热解以及Mo~(6 )被还原的难易程度,取决于与Keggin阴离子结合的阳离子的种类。在同一实验条件下,如果阳离子本身难以还原,那么,Keggin阴离子的破坏以及Keggin阴离子中Mo~(6 )还原为金属相的过程,都将变得困难。     

ELECTRON SPIN ECHO ENVELOPE MODULATION OF THE TRANSIENT EPR SIGNALS OBSERVED IN PHOTOSYNTHETIC ALGAE AND CHLOROPLASTS*

Phase memory decays were obtained from the transient signals sampled within 50 ns of laser excitation by time resolved electron spin echo (ese) spectroscopy in normal protonated, deuterated, deuterated ¹⁵N photosynthetic algae and broken chloroplasts. Previously, it has been shown that application of time resolved ese to study these systems, in particular, gives rise to two kinds of signals (standard and special ese). The standard ese signal at g = 2.0023 and the special ese signal exhibit similar electron spin echo envelope modulation (eseem). The modulation frequency and pattern can be identified with that obtained from stable oxidized P₇₀₀ in the same system. The two lower field resonances of the standard ese signal do not show eseem. The results support the proposed mechanism for formation of special ese and the notion that the standard ese is due to at least two radicals. It is also demonstrated that we can observe eseem of P⁺₇₀₀ under ambient temperature conditions.     

THE EFFECT OF PHOSPHORYLATION UNCOUPLERS AND ELECTRON TRANSPORT INHIBITORS UPON SPECTRAL SHIFTS AND DELAYED LIGHT EMISSION OF PHOTOSYNTHETIC BACTERIA

Abstract— Delayed light emission (measured 4 msec after excitation) and the light-induced red shifts of the bacteriochlorophyll and carotenoid absorption bands of chromatophores of Rhodopseudomonas spheroides were inhibited by a variety of reagents. These included anti-mycin A, NQNO, CCCP, desaspidin, quinacrine, chlorpromazine, 2,4-dinitrophenol, gramicidin D, Triton X-100 and valinomycin in the presence of potassium, cesium or ammonium ions. Delayed light emission was enhanced by orthophenanthroline, ethanol, succinate and glutathione.
Delayed light emission from chromatophores of Rhodospirillum rubrum was attenuated during photophosphorylation but restored approximately to its initial value in the presence of oligomycin. Since the delayed light and band shifts are inhibited under conditions which tend to deplete or block the formation of high energy phosphorylation intermediate, it is suggested that the presence of a high energy intermediate is a prerequisite for the appearance of each of the three phenomena.     

STUDIES ON ENERGY DISSIPATION IN PHYCOBILISOMES USING THE KENNARD-STEPANOV RELATION BETWEEN ABSORPTION AND FLUORESCENCE EMISSION SPECTRA

Absorption and fluorescence emission spectra were measured at room temperature ( ca. 22°C) for solutions of phycocyanin-1, phycocyanin-2 and allophycocyanin from Phormidium luridum , and also for phycobilisome preparations from various blue-green algae ( Anabaena variabilis, Nostoc muscorum strain A, Nostoc sp. strain Mac, Phormidium luridum ). Kennard-Stepanov (KS) temperatures ( T ) were computed using the Kennard-Stepanov relationship F () = b A () ^-5 exp(-h/ kT ), where F () stands for fluorescence (energy per wavelength interval) as a function of wavelength (), A () is absorbance as a function of wavelength, b a proportionality factor, and h, c and k are Planck's constant, the velocity of light and Boltzmann's constant, respectively.
In most cases experimenta/ data followed the expected relationship, but at low ionic strength allophycocyanin gave a clearly biphasic KS plot, i.e. In ⁵ F ()/ A () vs 1/. This could be due to the presence of both monomers and trimers in the sample at low ionic strength.
For purified allophycocyanin and phycocyanins (PC-1 and PC-2) as well as phycobilisomes from Phormidium luridum , the KS temperatures were only slightly (insignificantly) elevated above the sample temperature. Thus, after absorption of a photon, vibrational and configurational equilibration is essentially completed before emission of the fluorescence photon takes place.
For phycobilisomes from Anabaena variabilis and the two Nostoc species the KS temperatures were moderately elevated. Since there was no correlation between radiation temperature and excitation wavelength, the elevation is not due to excess (undissipated) vibrational energy, but rather to incomplete configurational equilibration.     

含硒杂环化合物的合成和对超氧阴离子作用的ESR研究

引言硒作为人体必需的微量元素,其主要生化作用与谷胱甘肽过氧化物酶密切相关.在体内,该酶可以催化许多过氧化物的分解,并且与谷胱甘肽一起组成一个强有力的细胞防御体系,发挥其抗氧化作用.近几年来,人们发现了一种小分子有机硒化物2-苯基-1,2-苯并异硒唑酮-3(简称Ebselen)具有类似谷胱甘肽过氧化物酶的活性.它能有效地抑制活性氧自由基的产生而引起的细胞损伤,具有良好的抗炎活性,且毒性极低(大鼠LD_(50)>6180mg/os).因而,普遍认为Ebselen及其类似物是一类具有广谱抗炎活性的潜在药物,在医药领域具有广阔的应用前景.     

热分析与气相色谱联用研究一水合草酸氢钾

用热分析与气相色谱联用技术(TA-GC)研究KHC₂O₄·H₂O的热分解表明,在空气和氦气当中,开始时缓慢分解,放出结晶水。接着KHC₂O₄快速分解成K₂C₂O₄,并释放出一些气体产物：O₂(分解初期)、CO、CO₂和H₂O。讨论了KHC₂O₄的分解机理。     

高密度聚乙烯在等离子体作用下的表面交联及其性质

本文研究了高密度聚乙烯(HDPE)在非聚合性气体等离子体作用下的表面交联过程,结合接触角测定,SEM,DSC,X射线衍射及元素分析等手段,研究了交联的结构以及表面交联与HDPE表面性质的相互关系,探讨了等离子体表面改性的机理以及处理效果在存放过程中发生衰减的原因。     

MOLECULAR HYDROGEN PRODUCTION BY UROPORPHYRIN AND COPROPORPHYRIN: A MODEL FOR THE ORIGIN OF PHOTOSYNTHETIC FUNCTION

Abstract— Since life originated when the earth's atmosphere was still chemically reducing, the photooxidation of the prevalent reduced organic compounds and the emission of molecular hydrogen would have been a useful form of photosynthesis. If the biosynthetic pathway to chlorophyll recapitulates the evolutionary history of photosynthesis, then uroporphyrin served an early photosynthetic function. In the present study, ethylenediamine tetraacetic acid was oxidized by photoexcited uroporphyrin and coproporphyrin to produce molecular hydrogen in aqueous solution in the presence of colloidal platinum catalyst. In the presence of methyl viologen, a one-electron carrier, the reaction is cyclic and hydrogen gas is produced at a constant rate. The evidence suggests that porphyrin radical intermediates rather than hydroporphyrin are active in the formation of molecular hydrogen. A coproporphyrin-polyvinyl alcohol-colloidal platinum polymer was used as a model for the evolving biological system for photosynthesis in which reactants are held in close proximity.