Ultrastructural Development of Chloroplasts in Sacred Lotus Embryo Bud under Invisible Light

The present paper reports that the development ultrastructural observations of chloroplasts from sacred lotus (Nelumbo nucifera) embryo buds under invisible light. Embryo bud of sacred lotus is enclosed by three layers of thick integument (pericap, seed coat and thick fleshy cotyledons). During the period of the formation of embryo bud, it remained in dark condition, but turned from pale yellow to bluish-green. It was noteworthy that chloroplasts of the embryo bud had well developed giant grana under invisible light. Their developmental pathway in sacred lotus, however, was different from those of other higher plants grown under sunlight, intermittent light, or even in dark conditions (Fig. 1). The chloroplast development of embryo buds in Sacred lotus seeds in invisible light underwent only in the following three stages: (1) In the first stage the development was similar to that from other higher plants, the inner envelope membranes of the proplastids were invaginating. (2) In the second stage, a proplastid centre composed of prolamellar bodies (PLB)with semicrystalline structure was formed, and was accompanied by one or two huge starch grains in almost each proplastid. In the meantime, prothylakoid membranes extended parallelly from the plastid centre in three forms: (a) One plastid centre extending parallelly prothylakoid membranes from itself in one direction; (b) The same to (a), but extending in two directions; (c) Two plastid centres extending parallelly prothylakoid membranes between the centres. (3) In the third stage, grana and stroma thylakoid membranes of chloroplasts were formed. It is to be noted that most of chloroplasts had only one or two giant grana which often extended across the entire chloroplast body, and the length of the grana thylakoid membranes of the chloroplasts from embryo bud in Sacred lotus is 3 to 5 times as many as that in other higher plants. However, their stromatic thylakoid membranes were rather rare and very short. The giant grana were squeezed to the margin of the chloroplast envelope by one or two huge starch grains.     

The Relation between Photophosphorylation and Delayed Light Emission in Chloroplasts

One millisecond delayed light emission has been studied in isolated coupled lettuce (Lactuca sativa var. romaine) chloroplasts. Delayed light emission was increased upon addition of ferricyanide or 2,3,5,6-tetramethyl-p-phenylene diamine. In the presence of ferricyanide, the magnitude of the signal was increased by the addition of ADP (in the absence of orthophosphate), ATP, DI0-9, or phlorizin. The signal was also increased by the addition of NaCl and by the addition of NH₄Cl in the presence of a high NaCl concentration. The signal of delayed light emission was decreased by the addition of gramicidin, valinomycin, and by the addition of NH₄Cl in the presence of a low NaCl concentration.     

Photosynthetic Characteristics of Chloroplasts of Primary Wheat Leaves Grown under Different Irradiance

The rate of accumulation of total chlorophyll (Chl) and carotenoids (Car) of leaves grown under high irradiance, HI (30 and 45 W m^–2) was faster than at moderate irradiance, MI (15 W m^–2). However, the senescence phase started earlier in the samples and proceeded at a faster rate. Chl a/b and Chl (a+b)/Car values showed faster loss of Chl a (compared to Chl b) and Chl (a+b) (compared to Car) in HI leaves. Protein accumulation and loss were also similar to that of Chl (a+b) content. Increase in Chl fluorescence during the development phase may suggest a gradual change in thylakoid organisation, however, the temporal kinetics were different in HI and MI samples. Increase in fluorescence polarisation during senescence of HI leaves compared to the control (MI) suggests conversion of thylakoid membranes to gel phase. Chloroplasts prepared from HI seedlings showed higher rate of photochemical activities, however, the activity declined earlier and at faster rate compared to the control.     

Light-controlled Leaf Expansion in Peas Grown under Different Light Conditions

Several photosystems control leaf expansion in Alaska peas (Pisum sativum). Phytochrome is known to control expansion in dark-grown peas. But plants exposed briefly to red light are insensitive to phytochrome, an insensitivity that is itself phytochrome-produced. Leaf expansion in these plants is promoted by 440 or 630 nm of light (probably mediated by protochlorophyll). Plants grown in white fluorescent light required simultaneous exposure to high intensity blue and yellow light for promotion of leaf expansion. Since these results parallel studies on light-controlled inhibition of stem elongation, shoot growth as a whole is coordinated by these photosystems. Such coordination might be a mechanism of plant competition for light.     

Effects of Azide on Photophosphorylation in Isolated Spinach Chloroplasts

The influence of sodium azide on open-chain and flavine mononucleotide mediated cyclic photophosphorylation in isolated spinach chloroplasts was investigated under anaerobic conditions. Open chain phosphorylation was completely inhibited with DCMU both in the presence and absence of sodium azide in the experimental medium. Flavine mononucleotide mediated photophosphorylation was only slightly inhibited by DCMU in the absence of sodium azide but inhibited in two steps by increasing amounts of DCMU when sodium azide was present in the medium. The first step can be explained as being mainly an effect of DCMU on an open chain electron transport, with water and H₂O₂ as electron donors and with flavine mononucleotide — kept in an oxidized state by sodium azide — as the electron acceptor. The second step, as well as the comparatively insensitivity to DCMU in the absence of sodium azide, depends on cyclic photophosphorylation mediated by flavine mononucleotide.     

Mortality of Sockeye Salmon Raised Under Light Backgrounds of Different Spectral Composition

Salmon from a 3 male×3 female sockeye salmon cross were raised under three different light regimes (UV: 300–850nm for 8 hoursday^-1, visible: 400–850nm for 8 hoursday^-1, and a control in which eggs were kept in darkness until hatching, followed by increasing amounts of light as the embryos approached swim-up) up to the parr interval (105 days from fertilization). The dose rates (Wm^-2), and total intensities per day (Jm^-2), for each treatment were less than 0.46 and 0.28 times of those measured in the shaded part of a stream, respectively. Egg mortality was higher for the UV and visible treatments compared to the control, and the number of alevins alive after day 83 was significantly different between treatments: highest for the control and lowest for the UV treatment. Eggs and hatched fish from female F2 suffered higher mortality than those from the other two females raising the possibility that sensitivity to UV-B in sockeye salmon may be either a maternally inherited trait or due to physiological or physical differences between egg groups. Alevins and parr from the control treatment transferred to the UV treatment suffered little mortality compared to animals raised in the UV and visible treatments from fertilization. These results, in conjunction with light measurements from streams, suggest that light and UV-B radiation could be a source of young salmon mortality in perturbed environments such as those resulting after forestry intervention.     

The Diffusion Controlled Mode of the Photophosphorylation Process in Chloroplasts

Biophysics - The effect of the rate of ADP supply as a feedback signal on the rate of ATP synthesis in chloroplasts has been analyzed on the basis of literature data and our research results....     

不同光温条件下紫背浮萍叶肉细胞和叶绿体超微结构的研究

以浮萍科紫萍属紫背浮萍为试验材料,利用透射电子显微镜研究了紫背浮萍叶肉细胞和叶绿体的超微结构。结果发现:强光下,紫背浮萍叶肉细胞内的叶绿体数明显增加;弱光时虽然叶绿体数减少,但叶绿体基粒片层结构变厚,增加了光合作用反应面积。与25℃适温条件相比,10℃低温和35℃高温下,紫背浮萍细胞均出现一定程度的逆境胁迫作用。表现在低温时部分叶绿体皱缩成带状,叶肉细胞之间出现较大空隙;高温时叶绿体外膜溶解,基质外渗,脂质小球数量增多。紫背浮萍通过改变细胞内部形态结构的方式来适应不同光强和温度环境条件,对逆境光温条件具有一定的耐受性。     

Oak Seedlings Grown in Different Light Qualities

Seedlings of oak (Quercus robur) were germinated in darkness for 3 weeks and then given continuous light or short pulses of light (5–8 min every day). The morphological development was followed during 25 days. In continuous white, blue, and red light the stem growth terminated after about 10 days by formation of a resting bud. At that time the seedlings were about 100 mm high. In con tinuous long wavelength farred light (wavelength longer than 700 nm) the stem growth including leaf formation was continuous without the formation of resting buds, and the stem length was about 270 mm after 25 days. The number of nodes developed became twice that of the seedlings grown in while light. The leaves became well developed in all light colours, but leaf areas were largest in plants cultivated in white light. Compared to dark grown seedlings the mean area per leaf was increased about five times in continuous long wavelength far red light. A supplement with short (5 min) pulses of red light each day increased the leaf area up to 20 times. The stem elongation showed a high energy reaction response, i.e. the stem length increased only in continuous long wavelength far-red light but was not influenced by short pulses of red light or far-red light. The leaf expansion, however, was increased by short pulses of red light with a partial reversion of the effect by a subsequent pulse of far-red light. The fraction of the plant covered with periderm was higher in plants given continuous light. In respect to periderm inhibition continuous long wavelength far red light was the most effective. The transfer of seedlings from darkness to continuous white light gave anthocyanin formation in the stem 10–20 mm below the apex. This formation took place in the cortex and was evident in plants grown in darkness or under short pulses of light. Plants grown in continuous red, blue or long wavelength Far red light showed only traces of anthocyanin.     

The Light Requirement for Different Steps in the Development of Chloroplasts in Excised Wheat Roots

For the formation of chloroplasts in excised wheat roots blue light is necessary, but red light enhances the blue light effect. Intensity-response relationships and action spectra have been determined for the specific blue light effect as well as for the effect of red light when given before or after blue light. The longest wave length giving a blue light effect is about 500 nm. The spectrum shows a peak at about 450 nm, and a considerable effect extends down to 368 nm, the shortest wave length tested. The photoreceptor mechanism for the “blue reaction” is thought to be related to that of certain phototropisms and chloroplast movements, and to that involved in carotenoid synthesis in certain fungi. The active pigment is thought to be either a carotenoid or a flavoprotein, probably the latter. The effect of red light shows similar action spectra whether the red light is given before or after the blue, and they are consistent with protochlorophyll absorption. However, much less light is needed to produce a detectable response when the red light is given before the blue light than after. Because of the similarity of the spectra phytochrome may also be involved in the response to red light when given before blue. Far-red reversal has not been tested. The results are discussed in relation to the development of chloroplasts in leaves.     

Changes in the Number and Size of Chloroplasts during Senescence of Primary Leaves of Wheat Grown under Different Conditions

Changes in the number and size of chloroplasts in mesophyllcells were investigated in primary leaves of wheat from fullexpansion to yellowing under different growth conditions. Thenumber of chloroplasts per cell decreased slowly, although thedecrease was steady and statistically significant, until thelast stage of leaf senescence, when rapid degradation of chloroplaststook place. Rates of leaf senescence, or the decline in thenumber of chloroplasts, varied greatly among plants grown atdifferent seasons of the year, but about 20% of chloroplastsalways disappeared during the phase when steady loss of chloroplastsoccurred. The area of chloroplast disks also decreased graduallybut significantly, with a rapid decrease late in senescence.Thus, the total quantity of chloroplasts per mesophyll celldecreased substantially during leaf senescence. Yellowed leavescontained numerous structures that resemble oil drops but nochloroplasts. Decreases in rates of photosynthesis that occurduring senescence may, therefore, be largely due to decreasesin the quantity of chloroplasts. However, a better correlationwas found between the decrease in the maximum capacity for photosynthesisand the degradation of RuBP carboxylase. When plants had beengrown with a sufficient supply of nutrients, the number of chloroplastsdecreased steadily but at a reduced rate and the reduction inthe area of chloroplast disks was strongly suppressed. Thus,the quantitative decrease in chloroplasts in senescing leavesappears to be regulated by the requirements for nutrients (nitrogen)of other part of the plant. ³Present address: Department of Biology, Faculty of Science,Toho University, Miyama, Funabashi, Chiba, 274 Japan     

Site-specific Inhibition of Photophosphorylation in Isolated Spinach Chloroplasts by Mercuric Chloride

Photophosphorylation associated with noncyclic electron transport in isolated spinach (Spinacia oleracea) chloroplasts is inhibited to approximately 50% by low concentrations of HgCl₂ (less than 1 μmole Hg²⁺/mg chlorophyll) when the electron transport pathway includes both sites of energy coupling. Reactions involving only a part of the electron transport system can give a functional isolation of at least two sites coupled to phosphorylation. Only one of these sites, located between the oxidation of plastoquinone and the reduction of cytochrome f, is sensitive to mercuric chloride. The energy conservation site located before plastoquinone and close to photosystem II is unaffected by HgCl₂ concentrations up to 10-fold those required to inhibit phosphorylation by the coupling site after plastoquinone. This site-specific inhibition may reflect a mechanistic difference in the mode of energy coupling at the two coupling sites or a variable accessibility of HgCl₂ to these sites.     

Photosynthetic Responses to Irradiance by the Grey Mangrove, Avicennia marina, Grown under Different Light Regimes

Photosynthetic responses to irradiance by the grey mangrove, Avicennia marina (Forstk.) Vierh var. australasica (Walp.) Moldenke, were studied using seedlings grown under natural understory shade and exposed conditions as well as in the laboratory under high and low light regimes, i.e. 100% and 6% sunlight, respectively. Leaves in exposed locations were subjected to daylight quantum flux densities greater than 1,000 microeinsteins per square meter per second from 0900 to 1700 hours, whereas those in understory shade experienced only 30 to 120 microeinsteins per square meter per second, interrupted for brief periods by sunflecks ranging in quantum flux density from 800 to 1,500 microeinsteins per square meter per second. The low light regime was similar in light intensity to that of the understory environment, but lacked sunflecks.

Leaves from the understory environment showed several properties of `shade' leaves; i.e. they contained more chlorophyll on both a leaf area and fresh weight basis but had a lower specific weight and greater area than exposed leaves, and were enriched in chlorophyll b relative to a. However, there were no significant differences in either the gas exchange or leaf chlorophyll fluorescence characteristics of the two populations, both being typical of `sun' leaves.

Leaves grown in the laboratory under low and high light regimes had similar properties. However, light saturated assimilation rates in the leaves from the low light treatment were 20% less and became light saturated at a lower quantum flux density than those of leaves grown under the high light regime. The ecological significance of these results is discussed.

     

Properties of Oligomeric Forms of Phosphofructokinase from Chlorella kessleri Grown under Different Light Conditions

Fast protein liquid chromatography on Superose 6 of crude extracts from Chlorella kessleri, Fott et Novákóva, grown autotrophically in blue or in red light yields three different oligomeric forms of phosphofructokinase (PFK, EC 2.7.1.11). Their substrate affinities and responses to homotropic and heterotropic effectors are different. In vitro, the degree of oligomerization of the enzyme can be influenced by specific intermediates or cofactors. Its substrate, MgATP (10 mM/5 mM), and the negative effector, phosphoenolpyruvate (5 mM), both lead to some dissociation, while the second substrate, fructose-6-phosphate (5 mM), and the positive effector, inorganic phosphate (50 mM), have no effect. It is discussed whether formation or dissociation of oligomeric PFK forms in vivo result from alterations in the levels or in the intracellular distribution of effector molecules and whether such processes are involved in the different regulation of cell metabolism in blue or in red light.     

Cyclic and Noncyclic Photophosphorylation in Isolated Guard Cell Chloroplasts from Vicia faba L

High rates of both cyclic and noncyclic photophosphorylation were measured in chloroplast lamellae isolated from purified guard cell protoplasts from Vicia faba L. Typical rates of light-dependent incorporation of ³²P into ATP were 100 and 190 micromoles ATP per milligram chlorophyll per hour for noncyclic (water to ferricyanide) and cyclic (phenazine methosulfate) photophosphorylation, respectively. These rates were 50 to 80% of those observed with mesophyll chloroplasts. Noncyclic photophosphorylation in guard cell chloroplasts was completely inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea supporting the notion that photophosphorylation is coupled to linear electron flow from photosystem II to photosystem I. Several lines of evidence indicated that contamination by mesophyll chloroplasts cannot account for the observed photophosphorylation rates.

A comparison of the photon fluence dependence of noncyclic photophosphorylation in mesophyll and guard cell chloroplasts showed significant differences between the two preparations, with half saturation at 0.04 and 0.08 millimole per square meter per second, respectively.

     

Clotrimazole对菠菜叶绿体光合磷酸化和电子传递的抑制作用

10μmol/的clotrimazole不仅抑制光合磷酸化活力,而且抑制各种类型的电子传递,是一个典型的电子传递抑制剂。经过它对叶绿体放氧,荧光和毫秒延迟发光影响的比较研究表明:clotri—mazole在光合电子传递链上的作用部位在Q与PQ之间,即与DGMU的作用部位相同或相近。     

Accumulation and Disintegration of Starch in the Chloroplasts of Stellaria media Grown under Constant Illumination

The persent paper contains a study un the starch content of the chloroplasts of the leaves of Stellaria media, performed by hsitochemical methods. Three leaves were collected at short intervals, fixed and cut in 10 μ sections, and stained according to the PAS-procedure. The starch content of single chloroplasts was measured by a microscope photometer. The chemical composition of the stainable material was demonstrated by enzyme specific experiments. At the end of a 12 hours' dark period the chloroplasts contained only traces of starch. Light caused the starch accumulation to begin and after a time chloroplasts seemed to be filled with starch. Subsequently, however, a sudden decrease in the starch content of the chloroplasts took place, in spite of constant illumination. A rather high level of starch content was restored in a few hours. The author puts forward some ideas about the nature of the factors causing the transitory disintegration of starch in illuminated leaves. The induction or the activation of certain enzymes seems to be the most probable explanalion.     

金霉素促进光合磷酸化机理的再探

在叶绿体经TPCK—trypsin光下修饰后,电子传递加速、磷酸化解联、膜上偶联因子Mg~(2+)—ATP酶活力促进的条件下,用金霉素处理叶绿体,能降低TPCK—trypsin 对磷酸化的解联程度,部分降低膜上Mg~(2+)—ATP酶的激活。在NEM及TPCK—trypsin共同存在时,金霉素处理仍能部分恢复磷酸化活力。进一步证明了金霉素是作用在偶联因子上的γ亚单位或其邻近部位,使之减少能量耗散而提高磷酸化活力.     

Comparative Analysis of Chloroplasts and Mitochondria in Leaf Chlorenchyma from Mountain Plants Grown at Different Altitudes

Plants showing natural adaptation to growth in mountainous conditionswere collected from different elevations representing both forestand subrival belt ecosystems Mid-regions of leaves were preparedfor electron microscopy where morphometric observations wererecorded regarding the frequency of occurrence of chloroplastsand mitochondria, and their mean dimensions. The results showedthat both organelles, especially mitochondria are more abundantin plants growing at the higher elevation Oxytropis lapponica, O chionobia, Poa alpina, P pratensis, Geranium collinum, high elevation, mitochondria, chloroplasts, forest belt, subnival belt