Effects of growth temperature on photosynthetic carbon metabolism in green plants II. Photsoynthetic 14CO2-incorporation in plants acclimatized to varied temperatures

During photosynthetic ¹⁴CO₂-fixation, leaves of plants suchas wheat, the broad bean and spinach, which had been acclimatizedto high temperature (20–25?C), incorporated much moreradioactivity into sucrose, and less into glycine and serinein comparison with similar plants grown in the cold (mean temperature,5–7?C). Radioactivities incorporated into glycine and serine greatlydescreased on the addition of -hydroxyethylsulfonate or on theremoval of oxygen from the atmosphere, indicating that thesecompounds are synthesized through the glycolate pathway. In leaves of wheat grown under low temperatures, relativelyhigh radioactivity was detected in ribulose 1,5-diphosphateamong the photosynthetic ¹⁴CO₂-fixation products, whereas practicallyno radioactivity was detected in this compound in leaves ofwheat which had been acclimatized to high temperatures. We assumedthat the carboxylation reaction of ribulose 1,5-diphosphateis suppressed in plants acclimatized to low temperatures. It was further inferred that the C-2 and C-2 moiety of ribulose1,5-diphosphate accumulating as a result of suppression of carboxylationis converted to glycine and serine through the glycolate pathway. The possibility was also discussed that during photosyntheticCO₂-fixation in wheat leaves at least a part of the C₆-compoundformed by the carboxylation of ribulose 1,5-diphosphate is directlyconverted to sugar phosphate. ¹Part of this investigation was reported at the 2nd InternationalCongress on Photosynthesis Research at Stresa, Italy, June 1971.This paper is based on a dissertation submitted by S.S. to theFaculty of Science, the University of Tokyo, in partial fulfilmentof the requirements for a Ph.D. degree. ²Present address: Department of Botany, Faculty of Science,University of Tokyo, Tokyo, Japan. (Received July 20, 1973; )     

Effects of growth temperature on photosynthetic carbon metabolism in green plants III. Differences in structure, photosynthetic activities and activities of ribulose diphosphate carboxylase and glycolate oxidase in leaves of wheat grown under varied temperatures

The rate of ferricyanide photoreduction in broken chloroplastsisolated from leaves of wheat acclimatized to a low temperature(mean temperature, 5–7?C) was similar to that in chloroplastsfrom wheat acclimatized to a high temperature (20–25?C). There was no practical difference in glycolate oxidase activityin leaf extracts of wheat plants grown at low and high temperatures.In contrast, the ribulose diphosphate carboxylase activity ofchloroplasts from low temperature sample was less than halfthat for the high temperature sample. Chloroplasts having a high rate of photosynthetic CO₂-fixationwere obtained from wheat acclimatized to a low temperature,whereas the CO₂-fixation activity in chloroplasts isolated fromhigh temperature-acclimatized wheat was very low. Electron microscopy revealed that chloroplasts in high temperature-acclimatizedwheat were ellipsoidal, electron dense and contained starchgranules. Those in low temperature-acclimatized leaves wereround and did not contain starch granule. ²Present address: Department of Botany, Faculty of Science,University of Tokyo, Tokyo, Japan (Received August 7, 1973; )     

Photosynthetic carbon assimilation and associated metabolism in relation to water deficits in higher plants

Experimental studies on CO2 assimilation of mesophytic C3 plants in relation to relative water content (RWC) are discussed. Decreasing RWC slows the actual rate of photosynthetic CO2 assimilation (A) and decreases the potential rate (Apot). Generally, as RWC falls from c. 100 to c. 75%, the stomatal conductance (gs) decreases, and with it A. However, there are two general types of relation of Apot to RWC, which are called Type 1 and Type 2. Type 1 has two main phases. As RWC decreases from 100 to c. 75%, Apot is unaffected, but decreasing stomatal conductance (gs) results in smaller A, and lower CO2 concentration inside the leaf (Ci) and in the chloroplast (Cc), the latter falling possibly to the compensation point. Down-regulation of electron transport occurs by energy quenching mechanisms, and changes in carbohydrate and nitrogen metabolism are considered acclimatory, caused by low Ci and reversible by elevated CO2. Below 75% RWC, there is metabolic inhibition of Apot, inhibition of A then being partly (but progressively less) reversible by elevated CO2; gs regulates A progressively less, and Ci and CO2 compensation point, Gamma rise. It is suggested that this is the true stress phase, where the decrease in Apot is caused by decreased ATP synthesis and a consequent decreased synthesis of RuBP. In the Type 2 response, Apot decreases progressively at RWC 100 to 75%, with A being progressively less restored to the unstressed value by elevated CO2. Decreased gs leads to a lower Ci and Cc but they probably do not reach compensation point: gs becomes progressively less important and metabolic limitations more important as RWC falls. The primary effect of low RWC on Apot is most probably caused by limited RuBP synthesis, as a result of decreased ATP synthesis, either through inhibition of Coupling Factor activity or amount due to increased ion concentration. Carbohydrate synthesis and accumulation decrease. Type 2 response is considered equivalent to Type 1 at RWC below c. 75%, with Apot inhibited by limited ATP and RuBP synthesis, respiratory metabolism dominates and Ci and Gamma rise. The importance of inhibited ATP synthesis as a primary cause of decreasing Apot is discussed. Factors determining the Type 1 and Type 2 responses are unknown. Electron transport is maintained (but down-regulated) in Types 1 and 2 over a wide range of RWC, and a large reduced/oxidized adenylate ratio results. Metabolic imbalance results in amino acid accumulation and decreased and altered protein synthesis. These conditions profoundly affect cell functions and ultimately cause cell death. Type 1 and 2 responses may reflect differences in gs and in sensitivity of metabolism to decreasing RWC.     

Studies on nitrogen metabolism in tobacco plants IX. Effect of various compounds on proline biosynthesis in the green leaves

In order to obtain information on the correlation between thebiosynthesis of proline from glutamate and photosynthesis ingreen leaves, the effects of various substances on proline formationfrom ¹⁴C-glutamate have been investigated using tobacco leafdisks in the light. Inhibitors of oxygen evolution in photosynthesis,such as CMU, strongly inhibited the proline formation. The inhibitioncould not be reversed by the addition of reduced NADP, ascorbateplus 2,6-dichlorophenol-indophenol or ATP. Uncouplers or inhibitorsof photophosphorylation such as DNP, arsenate, chlorpromazineand octyl guanidine suppressed the formation of proline fromglutamate. In old leaves, the addition of ADP or ATP markedlyaccelerated proline formation, while neither of these compoundswas effective in young leaves. It was inferred that the reductionof glutamate to ¹-pyrroline-5-carboxylate in green leaves isclosely associated with noncyclic photophosphorylation. (Received August 17, 1967; )     

Effects of ultraviolet-B radiation on plants during mild water stress. III. Effects on photosynthetic recovery and growth in soybean

Soybean { Glycine max (L.) Merr. ev. Essex} was grown from seed in a greenhouse under ultraviolet-B (UV-B, 280–320 nm) radiation supplied by filtered FS-40 sunlamps. On a weighted, total daily dose basis these plants received either 0 (control) or 2875 effective J m⁻² day⁻¹ UV-B_BE. When weighted with the generalized plant action spectrum (Caldwell 1971), this simulated the solar ultraviolet-B irradiance expected to occur at College Park, Maryland, USA (39°N) in the event the global stratospheric ozone column is reduced by 23%. The effects of ultraviolet radiation on the photosynthetic recovery from water stress were measured with an infrared gas analyzer. These effects were examined in plants which were either well-watered or previously preconditioned to water stress, during two distinct phenological stages of development. During the early stages of soybean growth, enhanced levels of UV-B reduced net photosynthesis by 25%, and water stress also reduced photosynthesis to nearly the same extent (by 20%). The combination of these two stresses resulted in smaller biomass than that produced by plants exposed to either stress independently. Photosynthesis in older, larger plants was much more sensitive to water stress and was reduced by as much as 50–60% in non-preconditioned plants. Although non-irradiated, non-preconditioned (control) plants recovered to only within 60% of their prestressed value, preconditioned plants recovered to within 70–80% during the 3 day recovery period. Both water stress and UV-B radiation affected non-stomatal conductance, while stomatal conductance was primarily affected by water stress.     

植物非叶绿色器官光合贡献研究进展

植物光合作用是生物界赖以生存的基础.长期以来,叶片被认为是植物进行光合作用的重要器官.然而在逆境条件下,植物非叶绿色器官的光合贡献也具有巨大的潜力.近年来,为了探究植物增产的新途径,科研工作者纷纷把目光投向了植物非叶绿色器官.本文简述了植物非叶绿色器官中能够进行光合作用的器官类型、非叶绿色器官光合贡献率及其光合贡献率的...     

Effects of free amino acids on the photosynthetic carbon metabolism of symbiotic dinoflagellates

Synthetic host factor (SHF) was used in parallel with crude cnidarian’s host factor (CHF) to investigate their effects on both photosynthetic carbon metabolism and the first step of lipid synthesis in the symbiotic dinoflagellates Symbiodium purchrorum of the sea anemone Aiptasia pulchella. Several species have been studied, namely, sea anemone A. pulchella, reef coral Pocillopora damicornis, and green alga Chlamydomonas reinhardii. Both short-term and long-term experiments with radioactive carbon have shown a higher rate of the alga ¹⁴C photoaccumulation with host factor(s) than of dinoflagellates located in artificial sea water (ASW) alone. In dinoflagellates incubated with both ASW and CHF, ¹⁴C-labeled glycerol was detectable after 15 s of alga illumination. In dinoflagellates isolated from P. damicornis and incubated in CHF and SHF and in dinoflagellates isolated from A. pulchella and incubated in CHF, a higher percentage of ¹⁴C was found in the glycerol as compared to the ASW trial. At the same time, in ASW trial the radioactive label was primarily located in ethanol-soluble lipid fraction. Similar results were observed when dinoflagellates isolated from P. damicornis were incubated with aspartate or glutamate. But there was no effect with taurine, serine, valine, glycine, or lysine. C. reinhardii, incubated in salt-free CHF, partitioned a greater percent of ¹⁴C into the glycerol and less into the ethanol-soluble lipids as compared to the corresponding control incubations. The amount of ¹⁴C in neutral and polar lipids was identical in that in A. pulchella dinoflagellates incubated in ASW or CHF. The arrays of neutral ¹⁴C-lipids produced under both ASW alone and ASW with CHF conditions, and over time were not significantly distinguishable. Host factors appeared to provide an optimum environment to sustain maximum metabolic efficiency. A biochemical model, based on the quantitative and qualitative assessment of carbon pathways in dinoflagellates incubated both in host factor and sea water alone, is presented. Published in Russian in Fiziologiya Rastenii, 2007, Vol. 54, No. 2, pp. 195–208. The text was submitted by the authors in English.     

Effects of high ambient temperatures on the metabolism of West African dwarf goats. I

Thirty-two West African dwarf goats were exposed to temperature treatments: 20, 25, 30, 35, 35, 35, 30, 25, 20°C each lasting three days.Sixteen goats were kept in individual pens (I), the others in two group pens (G). Heat production (HP) and activity were recorded during 48 hours in each temperature treatment.Mean HP and ME intake were similar for G and I animals, but I animals had lower values than G animals at low chamber temperatures and higher values than G animals at high temperatures. Upper critical temperature was between 25°C and 30°C under an increasing T and between 30 and 35°C under a decreasing T. Adaptation of heat production and ME intake to a change in temperature of 5°C required at least six and possibly more than nine days.Diurnal variation in HP was large, up to 44% between extremes. This was largely due to variation in activity.     

Influences of leaf temperature on photosynthetic carbon metabolism in wheat

Net photosynthetic assimilation rate (A), extractable activities of three photosynthetic enzymes, and the concentrations of six metabolites were determined for wheat (Tricum aestivum L.) leaves as leaf temperature was varied under photorespiring (350 microliters per liter CO₂ and 21% O₂) and under nonphotorespiring conditions (800 microliters per liter CO₂ and 2% O₂). The extractable activity of ribulose-1,5-bisphosphate carboxylase (Rubisco) and fructose-1,6-bisphosphatase declined with increasing leaf temperature from 15 to 45°C. Leaf concentrations of ribulose-1,5-bisphosphate (RuBP) declined slightly between 15 and 25°C but increased to a level which is 4 to 5 times the binding site concentration of Rubisco at leaf temperatures of 35 and 45°C. Leaf concentrations of 3-phosphoglycerate, fructose-6-phosphate, and glucose-6-phosphate all declined with increasing leaf temperature. Outside of the limitations imposed by photorespiration, it is proposed that under high light and at suboptimal temperatures, A is limited by rate of utilization of triose phosphate; at optimal temperatures, by the availability of substrate (CO₂ and RuBP) under photorespiring conditions or utilization of triose phosphate under nonphotorespiring conditions; and at supraoptimal temperatures, by the activation state of Rubisco.     

Photosynthetic acclimation of higher plants to growth in fluctuating light environments

This paper describes a study into the potential of plants to acclimate to light environments that fluctuate over time periods between 15 min and 3 h. Plants of Arabidopsis thaliana (L.) Heynh., Digitalis purpurea L. and Silene dioica (L.) Clairv. were grown at an irradiance 100 mol m^-2 s^-1. After 4–6 weeks, they were transferred to light regimes that fluctuated between 100 and either 475 or 810 mol m^-2 s^-1, in a regular cycle, for 7 days. Plants were shown, in most cases, to be able to undergo photosynthetic acclimation under such conditions, increasing maximum photosynthetic rate. The extent of acclimation varied between species. A more detailed study with S. dioica showed that this acclimation involved changes in both Rubisco protein and cytochrome f content, with only marginal changes in pigment content and composition. Acclimation to fluctuating light, at the protein level, did not fully reflect the acclimation to continuous high light - Rubisco protein increased more than would be expected from the mean irradiance, but less than expected from the high irradiance; cytochrome f increased when neither the mean nor the high irradiance would be expected to induce an increase.This revised version was published online in October 2005 with corrections to the Cover Date.     

光强对4种鸭跖草科植物生长和光合特性的影响

为探究4种鸭跖草科植物对不同光环境的适应能力,以紫鸭跖草、花叶水竹草、吊竹梅、绿叶水竹草4种植物为试验材料,利用遮光网设置5种光强梯度(分别为自然光强的100%、75%、50%、25%、5%),研究不同光强对4种植物生长和光合特性的影响。结果表明：随光强的减弱,4种植物的叶面积、比叶面积、株高、叶片夹角显著增加,但紫鸭跖草在5%自然光强下叶面积显著降低,同时降低的光强显著降低了4种植物叶片的上下表皮厚度和叶片厚度,以及紫鸭跖草、花叶水竹草和绿叶水竹草的栅栏组织厚度、花叶水竹草和绿叶水竹草的海绵组织厚度,但4种植物的栅栏组织和海绵组织比未发生显著变化。紫鸭跖草和花叶水竹草的Chl a、Chl b和Chl (a+b)含量随光强的降低呈先升后降趋势,而吊竹梅和绿叶水竹草的Chl a、Chl b和Chl (a+b)含量则显著升高。与100%自然光强和5%自然光强相比,4种植物在25%—75%自然光强下,能保持高的气孔开度、净光合速率、气孔导度、胞间二氧化碳浓度和蒸腾速率。研究表明,4种鸭跖草科植物具有较强的光适应性,可以通过调整植株形态、叶片解剖结构、光合色素含量、气孔开度和导度的方式在弱光环...     

Effects of carbon dioxide and oxygen on the regulation of photosynthetic carbon metabolism by ammonia in spinach mesophyll cells

Photosynthetic carbon metabolism of isolated spinach mesophyll cells was characterized under conditions favoring photorespiratory (PR; 0.04% CO₂ and 20% O₂) and nonphotorespiratory (NPR; 0.2% CO₂ and 2% O₂) metabolism, as well as intermediate conditions. Comparisons were made between the metabolic effects of extracellularly supplied NH₄⁺ and intracellular NH₄⁺, produced primarily via PR metabolism. The metabolic effects of ¹⁴CO₂ fixation under PR conditions were similar to perturbations of photosynthetic metabolism brought about by externally supplied NH₄⁺; both increased labeling and intracellular concentrations of glutamine at the expense of glutamate and increased anaplerotic synthesis through α-ketoglutarate. The metabolic effects of added NH₄⁺ during NPR fixation were greater than those during PR fixation, presumably due to lower initial NH₄⁺ levels during NPR fixation. During PR fixation, addition of ammonia caused decreased pools and labeling of glutamate and serine and increased glycolate, glyoxylate, and glycine labeling. The glycolate pathway was thus affected by increased rates of carbon flow and decreased glutamate availability for glyoxylate transamination, resulting in increased usage of serine for transamination. Sucrose labeling decreased with NH₄⁺ addition only during PR fixation, suggesting that higher photosynthetic rates under NPR conditions can accommodate the increased drain of carbon toward amino acid synthesis while maintaining sucrose synthesis.     

光合细菌对小麦生长和光合功能的影响

【目的】探明光合细菌对小麦生长、产量及光合功能的影响。【方法】以尧麦16为材料,在不同生长时期施用光合细菌,研究光合细菌对小麦生长、产量及光合功能的影响。【结果】光合细菌培养液的不同成分可提高小麦旗叶SPAD值、光合速率及干物质积累。拔节期施用后,混合菌液对叶片SPAD含量促进作用最大,较不施用对照提高33.6%,小麦干物质积累较对照增加25.7%,单株籽粒重量增效为14.3%。单菌株实验处理中沼泽红假单胞菌促进作用最强,干物质积累和单株籽粒重量较培养基稀释液对照增效均为13.1%。不同施用时期的结果表明沼泽红假单胞菌对灌浆期和拔节期小麦促进效应最强,其中静息细胞可延长叶片功能期,使光合产物持续增加;无细胞培养液通过促进小麦营养生长,进而提高小麦产量。【结论】光合细菌可促进小麦生长,有效提高小麦生育过程中相关光合功能;施用时期应为小麦拔节期和灌浆期;光合细菌对小麦生长和产量促进作用是静息细胞和代谢活性物质综合作用的结果。     

Control of diurnal variations in photosynthetic products: I. Carbon metabolism

It has been demonstrated previously that the synthesis of amino acids from photosynthetically fixed carbon in leaves of Capsicum annuum L. cv. California Wonder occurs in the middle of the photoperiod. This paper reports experiments which identify control points regulating the carbon flow in these leaves.     

陶粒覆盖对土壤水分、植物光合作用及生长状况的影响

以河北省廊涿高速公路中央隔离种植槽为研究地点,探讨陶粒覆盖对土壤水分、植物光合作用及生长状况的影响,结果表明:(1)陶粒覆盖有效地提高了土壤含水量,减弱了不同土层、不同月份之间的差距,两层覆盖(M2)效果要好于一层覆盖(M1)。从10-60 cm土层,陶粒覆盖对土壤含水量的影响逐渐降低,裸露地面的土壤含水量和陶粒覆盖下的土壤含水量的差距逐渐减弱。越是干旱季节,陶粒覆盖保水效果越明显;(2)陶粒覆盖对月季、大叶黄杨的净光合速率(P_n)、蒸腾速率(T_r)、水分利用效率(WUE)均产生了影响。两植物一天当中任何测量时刻的P_n均为M2>M1>MD(裸地)。陶粒覆盖也提高了月季、大叶黄杨的T_r日均值,使其日变化峰值出现时间发生变化。陶粒覆盖对WUE影响要远远小于对P_n、T_r的影响,相互之间差异均不显著。由于大叶黄杨的抗旱性较差,陶粒覆盖对大叶黄杨光合特性的影响大于对月季的影响。(3)陶粒覆盖大大提高了紫叶小檗、侧柏、小叶黄杨、大叶黄杨、月季5种植物的成活率,增加了植物的地径、株高增长量,M2的效果均好于M1。