土壤含水量对三种阔叶树苗光合作用的影响

研究了在温室内用盆栽法,其土壤含水量对茶条槭、山梨和山桃三种阔叶树苗光合作用的影响,以及各树种在土壤相对含水量为75.0%时光合作用的日变化.     

Simultaneous measurements of quantum yield and CO2 uptake for the assessment of non-assimilative electron flow in tree leaves

Using attached and detached leaves ofAcer palmatum Thunb. andRhaphiolepsis umbellata Makino, pulse-modulated chlorophyll fluorescence and CO₂ exchange were measured. Quantum yield of photosynthesis was determined from the fluorescence parameter(Fm′−Fs)/Fm′, where (Fm′−Fs) was defined as the difference between steady state chlorophyll fluorescence (Fs) and maximum fluorescence (Fm′) elicited by a saturating light pulse. The rate of electron transport through photosystem II (total electron flow) was calculated from the product of quantum yield andA (PFD), whereA is the rate of absorbed photons as given by leaf absorptance, and PFD is the photon flux density at the leaf surface. The rate of electron transport dependant on CO₂ uptake (assimilative electron flow) was calculated from the gross photosynthetic rate in a leaf. The difference between the rates of total and assimilative electron transport was denoted as the rate of non-assimilative electron transport which depends on photorespiration and oxygen reduction. Available data provided quantitative information on the rate of non-assimilative electron flow in intact leaves. When leaf photosynthesis ofA. palmatum was measured under sunlight, the rates of total and assimilative electron transport were determined to be approximately 900 and 150 μmol equiv. e/mg Chl·h, respectively. The difference (750 μmol equiv. e/mg Chl·h) was attributed to the activity of non-assimilative electron flow. The ratio of total to assimilative electron flow was found to increase gradually with rising in irradiance. The results suggest that non-assimilative electron flow occurred at much higher rate than assimilative electron flow at high irradiance. Implications of the results are briefly discussed in relation to photosynthesis limitation in tree leaves.     

Carbon, water and nutrient flux in Maya homegardens in the Yucatán peninsula of México

The Yucatán Peninsula of México has shallow soils and receives low amounts of precipitation, and has therefore low agricultural potential. Lacking large-scale irrigation from rivers and adequate rainfall, the indigenous Maya groups maintain agricultural productivity by adapting a variety of practices. Multistrata homegardens, one of their agricultural systems, have provided goods for trade, sale and personal consumption for many centuries. Nevertheless, an understanding of the controlling biological factors and interactions within these systems can lead to yield improvements. Photosynthetic rates, water use and litter production for a variety of species have been studied in these gardens to determine how Maya management impacts resource flow, productivity and diversity. When irrigated, diurnal photosynthetic rates nearly doubled for Manilkara zapota and water use increased two fold for M. zapota and Cordia dodecandra. Total litter production in traditional homegardens varied from 1,000 to 4,000 kg ha⁻¹ yr⁻¹ and ten arboreal species were found to contribute more than 33% of total litterfall biomass. Nutrient concentrations in the leaves of the predominant species were analyzed; Meliococcusbijugatus and Spondias purpurea were found to contribute the largest quantities of N, P and C. Our research indicates that species and structural diversity are critical to sustainability of homegardens, allowing efficient use and transfer of carbon, nutrients and water. This revised version was published online in June 2006 with corrections to the Cover Date.     

不同立地长白落叶松净光合特征的研究

本文通过对不同立地、不同年龄段长白落叶松净光合速率与呼吸速率的测定 ,测定出了长白落叶松净光合速率和呼吸速率 ,以及长白落叶松净光合速率的日进程与季节进程。通过对比试验测定 ,得出长白落叶松以 10年生净同化率最高 ,值为 :0 .30 51mgCO2 m- 2 s- 1,四大林场中以哈尔滨林场的长白落叶松净同化率最高 ,值为 0 .1335mgCO2 m- 2 s- 1。长白落叶松CO2 补偿点为 130vpm ,光呼吸值为 4 0vpm     

Structural characteristics of cell walls of kenaf (<Emphasis Type="Italic">Hibiscus cannabinus </Emphasis>L.) and fixation of carbon dioxide

 Kenaf (Hibiscus cannabinus) plants are widely known for their contribution to the global and regional environment because of their ability to fix CO₂. On the other hand, some scientists have doubts about CO₂ fixation by kenaf and have misgivings about the effect of kenaf on the ecosystem. We have characterized the structural characteristics of cell walls of bast fibers, cores, roots, and leaves of kenaf during the maturation of plants and investigated the rate of photosynthesis. During maturation of the kenaf plant the cellulose (bast fiber 52–59%, core 44–46%) and lignin (bast fiber 9.3–13.2%, core 18.3–23.2%) contents increased significantly. The aromatic composition of the lignin of bast fiber was significantly different from that of the core lignin and of other plants. The lignin of bast fiber appears similar to pure syringyl lignin. Fixation of CO₂ by kenaf plants and their contribution to the global environment are discussed. A significatly high rate of photosynthesis of kenaf plants was observed compared to that of woody plants in Japan, but the amount of CO₂ fixation depends on the characteristics of the plantation. If the kenaf was planted in high density, about twice as much CO₂ was fixed as was fixed by trees in a tropical rain forest. Received: April 22, 2002 / Accepted: July 24, 2002 Acknowledgments This project was supported by the Science and Technology Agency (STA) fellowship of the Japan International Science and Technology Exchange Center (JISTEC), which has been successfully applied by Dr. Shuji Hosoya, Forestry and Forest Products Research Institute. We thank Dr. Toshio Sumizono and Mr. Masao Sakurai, Forestry and Forest Products Research Institute, for their kind help in determining the rate of photosynthesis and cultivating the kenaf plants, respectively. We also express our appreciation to Dr. Quang Hung Le, College of Agriculture and Forestry, Ho Chi Minh City, Vietnam for offering information about the cultivation of kenaf at Thu Duc District, Ho Chi Minh City.     

荒漠植物白刺对模拟增雨的光合响应机制

【目的】研究不同增雨条件下白刺叶片的光合作用和叶绿素荧光特性,从光合生理角度探讨白刺对增雨的响应机制。【方法】以乌兰布和沙漠东缘地区典型荒漠植物白刺为研究对象,设置不同的增雨梯度(增加年均降水量的0,25%,50%,75%和100%),对自然生长的白刺沙包进行人工模拟增雨,利用 Li－6400xt便携式光合测定系统分析仪(USA,LI-COR)测定不同增雨条件下白刺叶片净光合速率(Pn)日动态变化、光响应曲线、CO2响应曲线以及叶绿素荧光参数,并根据 Pn 日变化曲线和响应曲线计算叶片日光合总量(∑Pn )以及各光合生理参数。【结果】1)75%和100%增雨对日均 Pn 和∑Pn 影响显著,日均 Pn 比 CK分别高32.74%和37.64%,∑Pn 比 CK 分别高32.01%和38.43%,说明增雨使白刺光合能力增强,日光合产物的积累增加。2)增雨使白刺表观量子效率( AQY)和光饱和点( LSP)升高,25%,50%,75%和100%增雨的 AQY 比 CK 分别高17.24%,31.03%,37.93%和24.14%,LSP比 CK分别高14.6%,6.0%,3.0%,26.1%,说明白刺叶片利用弱光的能力增强,对强光的利用范围增加,光能转化效率提高,有利于光合作用的高效进行。3)随着增雨量的增加,羧化效率(CE)呈现出逐渐增加的趋势,其中,100%增雨的 CE比 CK高5.73%;增雨使 CO2饱和点( CSP)升高,50%,75%和100%增雨的 CSP 显著高于 CK,分别比 CK高23.67%,28.35%和29.13%,说明白刺叶片 RuBP羧化酶和光合碳循环酶的活性增强,对高CO2浓度的利用范围增加。4)增雨使白刺叶片的原初光化学量子效率( Fv/Fm )、实际光化学量子效率(ФPSⅡ)、电子传递速率( ETR)和光化学猝灭系数( qP )提高,说明增雨有利于白刺叶片PSⅡ反应中心活性增强、开放比例提高,有利于叶片把所捕获的光能转化为生物化学能,并将更多的光能用于推动光合电子传递。【结论】白刺能够调节光合机构的功能、改变自身生理特性、增强对环境资源的利用能力来适应增雨的变化。     

5个油茶优良无性系光合及叶片解剖特征比较分析

为给进一步筛选高光效、优良的油茶无性系提供参考依据,选择5个油茶优良无性系(‘湘林’系列XL210、XL82、XL190、XL81、XL14)9年生植株,于2013年7月观测了其光合参数及叶片解剖特征。结果表明:净光合速率(Pn)的日变化曲线,XL14呈"单峰型",其他无性系均为"双峰型",不同无性系峰值出现的时间及峰值大小不完全相同,各无性系的Pn日均值从大到小依次为XL14XL81XL82XL210XL190,各无性系的单位面积产油量均值都随Pn值的增大而增大,Pn与叶绿素a、叶绿素(a+b)和叶绿素a/b之间均存在显著的正相关关系;5个无性系的叶片解剖特征值之间差异明显,栅栏组织/叶片厚度、栅栏组织/海绵组织的比值与Pn及单位面积产油量间均呈显著正相关。     

日光温室无花果生长和叶片光合性能分析

【目的】筛选出适合新疆和田引种的无花果优势品种。【方法】在和田地区日光温室内,以引进的5个2年生无花果品种和1个当地品种为研究对象,调查枝叶生长指标,采用PP-Systerm公司的TPS-2光合仪测定叶片光合作用,运用直角双曲线修正模型对叶片光合作用和光合有效辐射强度进行拟合分析。【结果】金傲芬品种在上午时的净光合速率最大,达到23.4 μmol/(m²·s);新疆早黄、布兰瑞克、金傲芬3个品种的光补偿点较低,分别为30.0、27.5和30.0 μmol/(m²·s);布兰瑞克、日本紫果、金傲芬、新疆早黄4个品种的饱和光强较大,分别为2 277.2、1 939.4、1 929.4和1 899.4 μmol/(m²·s);在上午时金傲芬和美娜亚具有较高的内禀量子效率,为0.062和0.054 μmol/(m²·s);表观量子产额也相对较高,为0.126和0.049 μmol/(m²·s);在下午时金傲芬和日本紫果有较高的内禀量子效率,为0.051和0.048 μmol/(m²·s);日本紫果的表观量子效率也较高,为0.040 μmol/(m²·s);上午时新疆早黄的暗呼吸速率最低,为0.86 μmol/(m²·s),下午时布兰瑞克的暗呼吸速率最低,为0.57 μmol/(m²·s)。【结论】布兰瑞克、青皮枝条节间较短、叶片较小、生长势中庸,较适宜温室栽培;金傲芬光合性能最优;美娜亚、青皮、布兰瑞克、新疆早黄4个品种光合性能次之;日本紫果的综合光合性能较差;布兰瑞克、金傲芬较耐弱光。综合比较,金傲芬、布兰瑞克较适宜和田日光温室栽培。     

硅对燕麦幼苗秆锈病抗病能力的作用

为探究硅在燕麦抗秆锈病过程中的生理功能,以易感秆锈病的燕麦品种‘ 坝莜1号’为试验材料,采用盆栽方法,分别浇灌含不同浓度(0、0.5、1.0、1.5、2.0、2.5和3.0 mmol/L)K₂SiO₃的营养液,测定燕麦幼苗秆锈病抗性,叶片光合性能,抗氧化酶活性及渗透调节物质的含量等指标。结果表明:接种秆锈菌条件下,施用1.5 mmol/L K₂SiO₃可显著提高燕麦幼苗抗秆锈病能力及叶片的光合特性、抗氧化酶活性和渗透调节能力。与0 mmol/L(CK)相比,燕麦幼苗干和鲜重分别提高90.91%和74.71%,叶片叶绿素含量提高18.67%,净光合速率(P_n)、蒸腾速率(T_r)、气孔导度(G_s)和胞间CO₂浓度(C_i)分别提高51.47%、285.71%、285.71%和27.78%,最大荧光(F_m)、光化学效率(F_v/F_m)和光合性能指数(PI_ABS)分别提高19.62%、7.69%和5.84%,超氧化物歧化酶(SOD)和过氧化物酶(POD)活性分别提高35.66%和28.88%,丙二醛(MDA)、可溶性蛋白及脯氨酸含量分别降低50.00%、27.45%和16.62%。总之,外源施用K₂SiO₃能提高燕麦抗秆锈病的能力,且以1.5 mmol/L为最佳浓度。     

Improvement in winter wheat productivity through regulating PSII photochemistry,photosynthesis and chlorophyll fluorescence under deficit irrigation conditions

Deficit irrigation is critical to global food production, particularly in arid and semi-arid regions with low precipitation. Given water shortage has threatened agricultural sustainability under the dry-land farming system in China, there is an urgent need to develop effective water-saving technologies. We carried out a field study under two cultivation techniques: (1) the ridge and furrow cultivation model (R); and (2) the conventional flat farming model (F), and three simulated precipitation levels (1, 275 mm; 2, 200 mm; 3, 125 mm) with two deficit irrigation levels (150 and 75 mm). We demonstrated that under the ridge furrow (R) model, rainfall harvesting planting under 150 mm deficit irrigation combined with 200 mm simulated precipitation can considerably increase net photosynthesis rate (P_n), quantum yield of PSII (ΦPSII), electron transport rate (ETR), performance index of photosynthetic PSII (F_v/F_m′), and transformation energy potential of PSII (F_v/F_o). In addition, during the jointing, anthesis and grain-filling stages, the grain and biomass yield in the R model are 18.9 and 11.1% higher than those in the flat cultivation model, respectively, primarily due to improved soil water contents. The winter wheat fluorescence parameters were significantly positively associated with the photosynthesis, biomass and wheat production. The result suggests that the R cultivation model with irrigation of 150 mm and simulated precipitation of 200 mm is an effective planting method for enhancing P_n, biomass, wheat production, and chlorophyll fluorescence parameters in dry-land farming areas.