北京山区典型暖温带落叶阔叶林大气CO_2浓度、草本层光合作用及土壤释放CO_2变化特点(英文)

为探讨森林生态系统植被、土壤等不同组分与大气CO_2交换特点,利用中型同化箱(40cm×40cm×2Ocm)及红外CO_2分析仪装置对北京山区典型暖温带森林生态系统辽东栎(Quercus liaotungensisKoidz.)林草本层净光合作用、土壤释放CO_2及林外(高出林冠2m)与林内(低于林冠2m)大气CO_2变化进行测定。结果表明:夏季及秋季大气CO_2浓度分别为(323±10)μmol·mol~(-1)和(330±1)μmol·mol~(-1);在一天内连续24h的测定中,大气与林内CO_2浓度的差值最大时可分别达-46和-61μmol·mol~(-1)。夏季草本层净光合强度为(2.59±1.05)μmol CO_2·m~(-2)·s~(-1),是秋季((1.31±0.39)μmol CO_2·m~(-2)·s~(-1))的2倍;夏季土壤呼吸释放CO_2的强度明显高于秋季,分别为(5.18±0.75)μmol CO_2·m~(-2)·s~(-1)和(1.96±0.57)μmol CO_2·m~(-2)·s~(-1)。土壤释放CO_2强度与地面温度之间存在显著相关,其关系式为Y=-0.8642 0.3101X(r=0.7164,P<0.001,n=117)。大气CO_2浓度的低值及草本层光合强度高值约出现在14:00左右;而在夜间土壤释放CO_2强度增加,表现为大气CO_2浓度升高。     

Changes in Stomatal Conductance,Transpiration and Water Use Efficiency of Ten Species Experienced in High CO2 Concentrations in Biosphere 2

The stomotal conductance, transpiration and water use efficiency (WUE) were measured using a LI-6400 portable photosynthesis system for 5 tropical rain forest species and 5 desert species in Biosphere 2, USA. All the species have experienced in very high CO2 ( > 2 200 μmol• mol- 1 ) for more than 4.5 years. The results showed that the stomatal conductance and transpiration of rain forest species decreased from ( 127.4 ± 65.6) and (2.04 ± 0.61 ) mmol• m- 2•s- 1 to (61.3 + 30.5) and ( 1.54 ± 0.65 ) mmol• m-2• s -1 respectively, while WUE increased from (2.90 ± 0.55) to (8.45 ± 2.71) μmol CO2 •mmo1-1 H2O, with CO2 increasing from 350 – 400 to 700 – 820 μmol• mol-l. For the desert species, stomatal conductance and transpiration decreased from respectively (142.8±94.6) and (2.09±0.71) mmol•m-2•s-1 to (57.7±35.8) and (1.36±0.52) mmolm-2•s-l, but WUE increased from (4.69 ± 1.39) to (9.68 ± 1.61) μmol CO2•mmo1-1 H2O, with the CO2 increase from 320 - 400 to 820 – 850 μtmol• mol- 1. The stomatal conductance, transpiration and WUE were less influenced by light intensity under high CO2 than low CO2 concentrations. Most rain forest species reached their light saturation points at light intensity of 500 μmol• m-2•s-1, while desert species at 1 000 μmol•m-2•s-1. Among different species, the desert C3 tree, Nicotiana glauca Grah., had the highest decrease in stomatal conductance and transpiration and the highest increase in WUE, by 78%, 69% and 310% respectively. The enhancement of increasing CO2 to the stomatal, transpiration and WUE of species with different photosynthesis pathway and life forms in Biosphere 2 could be concluded as: C3 species > C4 species, and desert C3 species > rain forest C3 species.     

胡杨不同叶形光合特性、水分利用效率及其对加富CO2的响应

 胡杨（Populus euphratica Oliv.）叶形多变化,大致归纳为杨树叶（卵圆形叶）和柳树叶（披针形叶）两大类。在内蒙古额济纳旗胡杨林自然保护区,选择成年树同时具有卵圆形叶和披针形叶的标准株,将枝条拉至同一高度,通过活体测定,比较了其光合特征、水分利用效率及对CO2加富的响应。结果表明：在目前大气CO2浓度下,当光强为1 000 μmol·m－2·s－1时,卵圆形叶（成年树主要叶片）（A）和披针形叶（成年树下部萌条叶片）(B)的净光合速率（Pn）分别为16.40 μmol CO2·m－2·s－1和9.38 μmol CO2·m－2·s－1;水分利用效率（WUE）分别为1.52 mmol CO2·mol－1 H2O和1.18 mmol CO2·mol－1 H2O;A的光饱和点和补偿点分别为1 600 μmol·m－2·s－1和79 μmol·m－2·s－1,B的相对应值则为1 500 μmol·m m－2·s－1和168 μmol·m－2·s－1。当CO2浓度加富到450 μmol·mol－1时,A的光饱和点升高了150 μmol·m－2·s－1,光补偿点降低了36 μmol·m－2·s－1;而B的光饱和点降低了272 μmol·m－2·s－1,光补偿点则升高了32 μmol·m－2·s－1。这表明,柳树叶的光合效率较低,以维持生长为主;随着树体长大,柳树叶难以维系其生长,出现杨树叶,杨树叶更能耐大气干旱,光合效率高,通过积累光合产物,使胡杨在极端逆境下得以生存并能达到较高的生长量,这就是胡杨从幼苗到成年树叶形变化的原因。随着CO2加富,两种叶片表现出截然相反的响应,柳树叶的光合时间缩短,光能利用率减小;而杨树叶的光合时间延长,光能利用率提高。如果地下水位下降,近地层空气变干燥,或随着大气CO2浓度升高,气候变暖,柳树叶可能会逐渐减少以至消失。     

亚热带常绿阔叶林冠层附生植物叶片形态结构及生理功能特征的适应性研究

以南亚热带常绿阔叶林林冠层不同部位的4种附生植物:瓜子金(Dischidia chinensis Champ.ex Benth.)、蔓九节(Psychotria serpens L.)、白背瓜馥木(Fissistigma glaucescens (Hance) Merr.)和山萎(Piper hancei Maxim.)为研究对象,比较其叶片解剖结构和光合、蒸腾等生理特性,探讨附生植物叶片形态结构、生理生态功能对冠层不同部位水、热和光资源的适应以及叶片形态结构与生理生态功能的联系.结果表明:着生在冠层上部的两种附生植物瓜子金和蔓九节叶片小而厚(厚度分别为3558±63 μm和217.1±33.1 μm),气孔面积小(分别为185.7±3.7 μm2和225 4±5.2 μm2)且覆盖角质膜,有利于降低蒸腾速率(两者分别为0.17±0.02 mmol H2O和0.34±0.05 mmol H2O),提高水分利用效率WUE(分别为11.35±0.87 μmol CO2/mmolH2O和7.88±1.31 μmol COJmmol H2O),更适应冠层顶部高温、低湿、强光照的生境.这些结构特征却不利于气体交换,会致使瓜子金和蔓九节的光合作用降低(二者最大净光合速率Pmax分别为2.2±0.1 μmol CO2 ·m-2·s-1和3.2±0 4 μmol CO2·m-2·s-1).冠层中下部的白背瓜馥木和山蒌叶片相对较薄(厚度分别为90.8±9.9 μm和114 9±18.2 μm),气孔面积较大(分别为260.6±6.3 μm2和362.5±8.7 μm2),叶肉细胞分化明显,海绵组织排列松散,有利于提高对弱光的利用,增强光合能力(二者Pmax分别为9.5±1.3 μmol CO2·m-2·s-1和7.1±0.8 μmol CO2·m-2·s-1,是瓜子金和蔓九节Pmax的3～4倍),更适应冠层中下部低温、高湿、弱光照环境.这些结构同时会导致白背瓜馥木和山蒌蒸腾速率提高(两者分别为0.67±0.10 mmol H2O和0.74 +0.13 mmol H2O),WUE下降(分别为4.4±1.01μmol CO2/mmol H2O和3.4±0.9 μmol CO2/mmol H2O,仅为瓜子金和蔓九节WUE的30％ -48％).这表明着生在林冠层不同部位的附生植物叶片形态结构特征随着光合有效辐射、温度、湿度等微环境因子的变化表现出显著的差异,并致使各自的生理生态功能发生了相应的适应,是植物适应环境条件的重要表现.     

Study on Leaf Anatomy and Photosynthesis of Cymbidium sinense

The leaf surface of Cymbidium sinense(Andr.) Willd was covered with cuticle and wax. The stomata were distributed in the dorsum of the leaf, the density being 100–130 mm-2 There was a stomatal cover on each stoma. The mesophyll was not differentiated into spongy tissue and palisade tissue. No chloroplast was observed in the vascular bundle sheath cells. The chloroplast in the mesophyll cells had well developed grana, with lightly stacked thylakoids and osmiophilic granules. The highest quantum yield of functional leaf was 0.082. The light compensation point of photosynthesis was about 5 μE·m-2·s-1, the light saturation point was about 200 μE·m-2·s-1. The photosynthetic ra,e of Cymbidium sinense was very low, generally 2.0–2.6 μmol CO2· m-2·s-1. The optimum temperature of photosynthesis of one-year-old leaf was 25℃. The photosynthe,ic rate of the three-year-old leaf declined with temperature rise. The ratio of chlorophyll a/b was about 2.7. The CO2 compensation point of photosynthesis was 105–220 ppm. All these data show that Cymbidium sinense belongs to the typical shade plants with low photosynthetic rate and high CO2 compensation point that explains that the growth of Cymbidium sinense is slow in nature.     

垄沟覆膜栽培冬小麦田的土壤呼吸

通过大田试验研究了垄沟覆膜栽培条件下冬小麦生长过程中土壤呼吸规律。结果表明,垄沟覆膜栽培条件下垄脊土壤呼吸速率高于平作栽培,而垄沟部土壤呼吸速率小于平作。冬小麦生育期内垄脊平均呼吸速率为(2.06±0.44)μmol CO2·m-2·s-1,垄沟为(0.75±0.11)μmol CO2·m-2·s-1,而平作栽培为(1.14±0.20)μmol CO2·m-2·s-1。土壤呼吸季节变化显著,越冬期低,夏季高。不同生育期土壤呼吸日变化规律不同,越冬前和返青期土壤呼吸与土壤温度成正相关,随着土壤温度的升高而增加,呈单峰曲线;拔节期后垄脊部的土壤呼吸日变化明显,呈现双峰曲线;而平作和垄沟的土壤呼吸速率平稳,没有明显峰值。5 cm土壤温度与土壤呼吸之间的相关性最好。在一定范围内(<24—31℃),土壤呼吸随着温度的增加而增加,温度过高反而会抑制土壤呼吸速率。土壤呼吸f(R)与5 cm土壤温度之间的关系可以用二次函数表示;5 cm土壤温度T和土壤含水量W的交互效应可用函数:f(R)=a(bT2+cT)(1+dln(2W)/T)+e表示。垄沟覆膜栽培显著改变了冬小麦田的土壤呼吸作用。     

光呼吸条件下栾树和辣椒光合电子流的分配研究

用Li-6400光合仪同时测定了栾树和辣椒在温度为30℃、CO2浓度为380μmol·mol-1下的气体交换和叶绿素荧光数据。结果表明,栾树在饱和光合有效辐射时光合电子用于碳同化、光呼吸和其他途径的量分别为72.68、45.68和29.40μmol·m-2.s-1;辣椒在光合有效辐射为2000μmol·m-2.s-1时光合电子用于碳同化、光呼吸和其他途径的量分别为142.24、40.24和131.52μmol·m-2.s-1。揭示了在光呼吸条件下用Valentini和Epron等方法高估了辣椒和栾树的光合电子用于光呼吸的量,同时也高估了光呼吸在辣椒和栾树中的保护作用。     

Study of Diurnal Changes in Photosynthetic Rate and Quantum Efficiency of Grapevine Leaves and Their Utilization in Canopy Management

Photosynthetic rate and quatum efficiency of grapevine (Vitis vinifera L. cv. Sauvignon blanc) leaves were measured under the field with ample soil water supply, and in phytotron with ample supply of water and mineral nutrients, constant air humidity and CO2 concentration, and optimum air temperature, respectively. Under field conditions CO2 assimilation quantum efficiency of leaves reached its maximum in the morning, which was followed by continuous decrease and midday depression. The leaves intercepting more light energy in the morning showed a higher quantum efficiency. Those leaves subjected continuously to strong irradiance exhibited a more obvious and longer midday depression. Reduction of leaf light interception around midday could reduce midday depression. Shaded leaves had a higher quantum efficiency than leaves under direct sunlight. The diurnal changes in photosynthetic rate and quantum efficiency of leaves were shown to be closely related to the variations in mesophyll resistance to CO2. In phytotron experiments the photosynthetic quantum efficiency of leaves was reduced after a certain period of illumination not only at 1200 μmol · m-2 · s-1 PFD, higher than the saturating light of vine leaves (≈1000 μmol · m-2 · s-1), which was caused by "photoinhibition”, but also at 800 and 200μmol · m-2 · s-1, which was similar to "photoinhibition”. But photosynthetic quantum efficiency of leaves exposed continuously to a very weak PFD (100 μmol · m -2 · s-1) remained contant. The diurnal changes in mesophyll resistance to CO2 of vine leaves could be partly related to photoinhibition. It is considered that, under field conditions without soil water limitation, midday depression of vine leaf photosynthesis could be a result of an increase of the mesophyll resistance induced by multiple effects of strong light, high temperature and low humidity. A higher light interception by canopy plane in the morning may be advantageous to exploit higher photosynthetic potentiality of leaves, but a lower light interception in the middle of day may reduce midday depression. The north-south orientation plane can provide optimum light regime and improve photosynthetic environment in vineyards.     

米瓦罐的光合特性研究

采用美国LI-COR生产的LI-6400便携式光合系统研究了米瓦罐的光合特性。结果表明,米瓦罐光 合速率的日变化呈单峰曲线,上午10:00时光合速率达到最大值;在大气CO2浓度下,米瓦罐的光饱和点为 1 800μmol·m-2·s-1,光补偿点为30μmol·m-2·s-1;在光饱和点的光强下,米瓦罐的CO2饱和点为1 200 μmolCO2·mol-1,CO2补偿点为40μmolCO2·mol-1。     

西双版纳山地三种土地利用方式的旱季土壤呼吸

为了解西双版纳山地不同土地利用方式土壤呼吸旱季变化特征,本研究对古树茶园、台地茶园和次生林中土壤呼吸速率及其相关因素进行定位观测。结论如下：三种土地利用方式土壤呼吸速率日变化有显著的差异性（P<0.05）;土壤呼吸速率日最高值大多出现在14∶00-16∶00;旱雨季交错期是土壤呼吸速率和土壤湿度变化最剧烈的阶段;土壤呼吸速率日均值表现为古树茶园（2.62μmol·m-2s-1）<台地茶园（2.73μmol·m-2s-1）<次生林（3.01μmol·m-2s-1）;土壤湿度过高和过低都会阻碍土壤呼吸的进行;三种土地利用方式土壤呼吸速率均与土壤湿度(0~10cm)和空气日均温具有相关关系;降水会引起土壤呼吸较大的波动。     

不同土地利用对土壤有机碳储量及土壤呼吸的影响

为了探讨土地利用方式对土壤碳储及土壤呼吸的影响,对安徽沿淮洼地杞柳纯林、杞柳-杨树混交林及杨树纯林3种不同土地利用方式下土壤有机碳储量及土壤呼吸特点进行了比较。结果表明:杞柳纯林、杞柳-杨树混交林、杨树纯林0～30cm土壤有机碳含量分别为6.80、8.50和7.71g·kg-1,土壤有机碳密度分别为2.88、3.26和2.95kg·m-2,土壤有机碳含量和土壤碳密度随土层深度的增加而降低。不同土地利用类型土壤呼吸年平均值分别为1.68μmol·m-2·s-1(杞柳纯林)、2.33μmol·m-2·s-1(杞柳-杨树混交林)、1.61μmol·m-2·s-1(杨树纯林),土壤呼吸日均值最高出现在夏季(6.64μmol·m-2·s-1),最低为冬季(0.13μmol·m-2·s-1)。相关分析表明,土壤呼吸速率与地表气温之间呈显著的指数关系,杞柳纯林、杞柳-杨树混交林、杨树纯林的相关系数R2分别为0.71、0.62、0.54。杞柳-杨树混交林较杞柳纯林有利于土壤有机碳的固定,杞柳纯林土壤有机碳储量偏低,与其粗放经营有关。在今后的栽植管理中,应采取合理的耕作施肥措施,在提高土壤肥力的同时增强土壤的碳固定。     

引种地被石竹光合特征与生理生态因子的关系

以上海地区引种的一年生地被石竹实生苗为材料,研究其苗高生长变化、生物量积累和分配、光合特性及其变化规律,并分析主要生理生态因子对其净光合速率的影响。结果表明:(1)3～6月份为地被石竹苗高生长速生期,生长量为年生长量的65.93%,实生苗各部分器官的生物量总体呈现上升的趋势;3～6月份苗木以地上部分生物量积累为主,其占总生物量的比例从46.89%升至65.60%,6月份以后地下部分生物量所占比例从34.40%升至53.11%。(2)地被石竹叶片净光合速率(Pn)日变化在春季和秋季呈单峰曲线型,而在夏季表现为双峰曲线,且具有典型的光合"午睡"现象。(3)影响光合变化的主要决定生理生态因子:春季为蒸腾速率和气温,夏季为气孔导度和大气CO2摩尔分数,秋季为胞间CO2摩尔分数和光合有效辐射;限制地被石竹Pn日变化生理生态因子:春季为胞间CO2摩尔分数和光合有效辐射,夏季为蒸腾速率和空气相对湿度,秋季为气孔导度和气温。(4)地被石竹具有较高水平的光补偿点(56.94μmol·m-2·s-1)和光饱和点(780.07μmol·m-2·s-1),应属于喜光植物。     

Soil CO2 efflux and its spatial variation in a Florida slash pine plantation

The efflux of CO2 from the soil surface can vary markedly in magnitude both in time and space and its correct determination is crucial in many ecological studies. In this paper, we report results of field measurements, using an open-top dynamic chamber, of soil CO2 efflux in a mature Florida slash pine (Pinus elliottii Engelm. var.elliottii) plantation. The daily average efflux was 0.217 mg CO2 m-2s-1 in the autumn and 0.087 mg CO2 m-2s-1 in the winter. Soil temperature, which accounts for most of the temporal variability in CO2 efflux, is by far the most influential factor controlling soil respiration rate and its temporal variation. The CO2 efflux in the slash pine plantation is highly spatially variable and effluxes from the soil under palmetto is significantly higher than that from the open floor. The CO2 efflux generally increases with increase in soil fine root biomass, litter and humus amount on the forest floor but is inversely related to the amount of organic matter in the mineral soil. The spatial variation in CO2 efflux can be well characterised by a simple multiple regression model incorporating live and dead biomass and soil total porosity as predictor variables. Understorey plants, mostly Serenoa repens, are an important component of the C cycle and the major contributor to the spatial heterogeneity of soil CO2 efflux. The influence of understorey plants on soil respiration is probably via two approaches: increasing litterfall and root metabolism, both consequently stimulating microbial activity in the mineral soil.     

10个秋菊品种的光合特性及净光合速率与部分生理生态因子的相关性分析

用CIRAS-2便携式光合测定系统测定了9月至10月10个秋菊[Dendranthema morifolium (Ramat.) Tvzel.]品种叶片的光合特征参数;在此基础上,对叶片光响应参数和CO2响应参数以及部分光合特征参数的日变化进行了比较分析;此外,还对净光合速率(Pn)与部分生理生态因子的相关性进行了分析.结果表明:10个秋菊品种的光补偿点(LCP)为92.83～167.37 μmol·m-2·s-1,光饱和点(LSP)为962.51～1 077.53 μmol·m-2·s-1,说明它们均为喜光植物;10个秋菊品种的CO2饱和点为1 060.46 ～1 485.48μmol·mol-1,CO2补偿点为77.62 ～ 133.16μmo1·mol-1,远大于一般的C3植物;各品种Pn的日变化呈典型的双峰型曲线,首峰(11～19μmol·m-2·s-1)出现在10:00左右,次峰出现在16:00左右,有明显的“午休”现象.相关分析结果表明:10个品种的Pn与气孔导度呈极显著正相关,与蒸腾速率呈显著或极显著正相关(品种‘关东新侠’、‘云龙凤舞’和‘日本黄’除外),与胞间CO2浓度呈显著或极显著负相关,与光合有效辐射强度和大气温度呈不显著正相关,与大气相对湿度和大气CO2浓度呈不显著负相关.早花品种‘太平的小鼓’和‘铜雀春深’具有较高的LSP以及较低的LCP和表观量子效率(AQY),对光照强度的适应范围较大,可栽培在光照较强的环境中;品种‘早粉盘’和‘檀香狮子’具有较高的LCP、AQY和LSP,对强光的利用能力较强;晚花品种‘关东新侠’、‘绿牡丹’和‘星光灿烂’具有较高的LCP和AQY以及较低的LSP,具有一定的耐阴能力,可种植在光照较弱的环境中.     

珠三角城市绿地CO2通量的季节特征

城市绿地是城市碳循环的重要组成部分,利用长期定位观测资料估算珠三角典型城市绿地的CO2通量,可以为应对气候变化、评价区域碳源汇提供参考。应用2009、2010年,东莞市植物园内的涡度相关法CO2通量定位观测资料,分析了净生态系统交换量(NEE)的年变化及其与气象要素的关系,结果表明:(1)年平均NEE总量为-104.2 gC.m-.2a-1,表明城市绿地生态系统具有固碳能力。(2)NEE随光温条件变化呈现明显的季节动态,12至3月表现为碳源,其他月份表现为碳汇。(3)根据白天NEE与光合有效辐射(PAR)逐月拟合Michaelis-Menten方程,得到年平均表观初始光能利用率(α)为(0.00134±0.00035)mgCO.2μmol-1光子,年平均光饱和生态系统生产力(Pmax)为(1.006±0.283)mgCO.2m-.2s-1。(4)利用夜间呼吸(Reco)与5 cm土壤温度(Ts)拟合指数方程,得到年平均Reco总量为1378.1 gC.m-.2a-1。(5)NEE与PAR、气温(Ta)和饱和水压差(VPD)的相关性分析显示,NEE与PAR偏相关系数的绝对值大于Ta和VPD,表明PAR对NEE的影响最大。     

NaCl胁迫对互花米草细胞膜和光响应曲线特征参数的影响

以大米草的互花米草为材料,研究了不同盐浓度对其细胞膜透性、丙二醛(MDA)含量和光响应曲线的特征参数的变化情况。结果表明:盐浓度低于300mmol·L-1时,互花米草细胞膜透性和MDA含量较对照组无显著差异;其较高的最大光合速率(>30μmol·m-2·s-1),表观量子效率(>0.05mol·mol-1Photons)以及较低的暗呼吸速率(<1.5μmolCO2·m-2·s-1)和光补偿点(<20μmol·m-2·s-1)为其有机物质积累、竞争、建立种群并扩散提供条件。盐浓度高于500mmol·L-1时,互花米草膜透性和MDA含量显著上升,最大光合速率(Amax)及表观量子效率(Q)显著下降,暗呼吸速率(Rday)和光补偿点(LCP)上升。表明细胞膜和光合作用有关酶受到迫害,抑制了其正常生长。盐胁迫下互花米草光合速率降低,但蒸腾速率的显著下降提高了单叶水分利用效率,从而部分缓解了渗透势变化对细胞的迫害,为其生存和生长提供条件。     

寒温带兴安落叶松林土壤温室气体通量的时间变异

采用静态箱/气相色谱(GC)法,对寒温带兴安落叶松林区6-9月生长季土壤CO2、CH4和N2O通量进行原位测定,研究了土壤温室气体通量的季节和昼夜变化及其与环境因子的关系.结果表明:在生长季,兴安落叶松林土壤为大气CH4的汇,吸收通量为22.3～107.8 μg CH4-C·m-2·h-1,6-9月月均甲烷吸收通量为(34.0±7.1)、(71.4±9.4)、(86.3±7.9)和(40.7-±6.2) μg·m-2·h-1;不同季节土壤CH4昼夜通量的变化规律相同,一天中均在10:00达到最大吸收高峰.土壤CO2日通量呈明显的双峰曲线,月均CO2通量大小顺序为7月＞8月＞6月＞9月.土壤N2O通量变异较大,在-9.1 ～31.7μg·m-2·h-1之间.土壤温度和湿度是影响CO2和CH4通量的重要因子,N2O通量主要受温度的影响.在兴安落叶松林区,10:00左右观测获得的温室气体地-气交换通量,经矫正后可以代表当日气体通量.     

光照强度对小麦苗期草酸氧化酶活性的影响

以小麦品种‘烟优361’(Triticum aestivum L.cv.Yanyou 361)萌发4 d幼苗为试验材料,分析了草酸氧化酶(OxO)在幼苗中的定位和表达,以及光照强度处理对小麦幼苗OxO活性的影响。实验结果显示,萌发后小麦幼苗的OxO分布在子叶与根的连接处和成熟的根中,其活性随光照强度的增加而下降;200μmol.m-2.s-1的强光显著抑制了OxO活性,该处理培养4 d幼苗的OxO活性仅为40μmol.m-2.s-1光照培养条件下的18.7%;强光还缩短OxO在苗期的表达时间,抑制了OxO的mRNA表达量。同时,光照强度还能影响小麦幼苗中H2O2的含量,200μmol.m-2.s-1处理幼苗的H2O2的含量显著下降,其培养4 d的幼苗H2O2含量仅为40μmol.m-2.s-1光照强度培养条件下的18.0%。研究发现,光照强度可通过调节OxO的活性和表达量来控制H2O2的产量,从而影响幼苗的生长发育。     

Below-ground respiratory responses of sugar maple and red maple saplings to atmospheric CO2 enrichment and elevated air temperature

The research described in this paper represents a part of a much broader research project with the general objective of describing the effects of elevated [CO2] and temperature on tree growth, physiological processes, and ecosystem-level processes. The specific objective of this research was to examine the below-ground respiratory responses of sugar maple (Acer saccharum Marsh.) and red maple (Acer rubrum L.) seedlings to elevated atmospheric [CO2] and temperature. Red maple and sugar maple seedlings were planted in the ground in each of 12 open-top chambers and exposed from 1994 through 1997 to ambient air or air enriched with 30 Pa CO2,< in combination with ambient or elevated (+4 °C) air temperatures. Carbon dioxide efflux was measured around the base of the seedlings and from root-exclusion zones at intervals during 1995 and 1996 and early 1997. The CO2 efflux rates averaged 0.4 μmol CO2 m-2 s-1 in the root-exclusion zones and 0.75 μmol CO2 m-2 s-1 around the base of the seedlings. Mineral soil respiration in root-exclusion zones averaged 12% higher in the high temperature treatments than at ambient temperature, but was not affected by CO2 treatments. The fraction of total efflux attributable to root + rhizosphere respiration ranged from 14 to 61% in measurements made around red maple plants, and from 35 to 62% around sugar maple plants. Root respiration rates ranged from 0 to 0.94 μmol CO2 s-1 m-2 of soil surface in red maple and from 0 to 1.02 in sugar maple. In both 1995 and 1996 root respiration rates of red maple were highest in high-CO2 treatments and lowest in high temperature treatments. Specific red maple root respiration rates of excised roots from near the soil surface in 1996 were also highest under CO2 enrichment and lowest in high temperature treatments. In sugar maple the highest rates of CO2 efflux were from around the base of plants exposed to both high temperature and high-CO2, even though specific respiration rates were< lowest for this species under the high temperature and CO2 enrichment regime. In both species, patterns of response to treatments were similar in root respiration and root mass, indicating that the root respiration responses were due in part to differences in root mass. The results underscore the need for separating the processes occurring in the roots from those in the forest floor and mineral soil in order to increase our understanding of the effects of global climate change on carbon sequestration and cycling in the below-ground systems of forests.     

珠三角城市绿地CO2通量的环境响应特征

城市绿地的净生态系统CO2交换量(NEE)受多种环境因素控制,定量分析NEE的环境响应机制对评估绿地生态系统固碳效益、优化城市绿地布局有重要意义。本文应用2009、2010年位于东莞市植物园内的涡度相关CO2通量定位观测资料,分析了光合有效辐射(PAR)、土壤温度(Ts)、饱和水汽压差(VPD)、降水及周边不同下垫面类型对NEE的影响。结果表明:NEE绝对值随PAR的升高而增加,PAR超过光饱和点(约为1500μmol photons·m-2·s-1)后,NEE绝对值呈回落趋势;生态系统呼吸(Reco)随Ts升高而增加,在温度较低时,Reco对Ts的敏感性较强(10℃时,Lloyd-Taylor方程的Q10=1.8),随着温度升高,敏感性下降(30℃时,Q10=1.43);VPD通过影响植物气孔导度对CO2交换产生作用,相同温度下,随着VPD升高,气孔导度增大,呼吸释放与光合固定的CO2量均增加;降水能增加土壤湿度进而使Reco增大,25℃时,降水后的Reco比降水前增加15.8%;测站东北和西南方的绿地范围较大,当东北和西南部是主要贡献区时,NEE绝对值较大,表明增加城市绿地能有效提高城市固碳效益。