白粉菌侵染对小麦叶片显微及超微结构的影响白粉菌侵染对小麦叶片显微及超微结构的影响

通过半薄及超薄切片,比较了正常和受白粉菌感染的小麦叶片细胞的显微及超微结构的差异。观察结果发现(1)受感染小麦叶肉细胞的细胞壁上局部沉积大量团状电子致密颗粒;(2)叶绿体形状由原来的椭圆形转变成圆形,叶绿体膜破裂,类囊体膨大,基粒片层排列疏松,同时,叶绿体内嗜锇性颗粒数量增加;(3)线粒体膜解体,内含物分散到了细胞质中     

增温和升高CO2浓度对桑树幼苗的生长和叶片品质的影响

研究了增温(+2 ℃)、升高CO₂浓度(+300 ppm)及同时增温和升高CO₂浓度(+2 ℃和+300 ppm CO₂)处理60 d后1年生桑树幼苗的形态、生物量积累及叶片品质的变化.结果表明: 与对照相比,增温显著增加桑树的基径、叶片数、总叶面积、叶干质量、叶干质量分数和可溶性蛋白含量,分别增加了9.9%、17.4%、23.0%、9.2%、10.1%和23.1%;升高CO₂浓度显著增加了桑树幼苗的茎干质量、根干质量和总干质量,比对照分别增加10.7%、15.9%和9.2%,但对幼苗的形态和叶片品质无显著影响;同时增温和升高CO₂浓度条件下,叶片数、株高、基径、总叶面积、叶干质量、根干质量、总干质量、叶片可溶性糖和粗蛋白含量均显著升高,与对照相比分别增加28.8%、9.1%、19.4%、32.6%、12.4%、17.2%、10.1%、45.8%和11.9%,但粗纤维含量显著降低16.8%.短期增温和升高CO₂浓度对桑树幼苗的生长发育和叶片品质有促进作用.     

白粉菌侵染对小麦叶片显微及超微结构的影响

通过半薄及超薄切片,比较了正常和受白粉菌感染的小麦叶片细胞的显微及超微结构的差异。观察结果发现：（1）受感染小麦叶肉细胞的细胞壁上局部沉积大量团状电子致密颗粒;（2）叶绿体形状由原来的椭圆形转变成圆形,叶绿体膜破裂;类囊体膨大,基粒片层排列疏松,同时,叶绿体内嗜饿性颗粒数量增加;（3）线粒体膜解体,内含物分散到了细胞质中。     

CO2浓度升高对凤梨叶片生长和光合特性的影响

研究了CO2浓度升高对开顶式气室中凤梨叶片的生长与光合生理的影响。结果表明:高CO2浓度(1000±100μmolmol-1)下生长的凤梨植株的株高、叶面积、鲜重和干重均高于对照(360±30μmolmol-1),处理90d时分别为对照的120.19%、119.22%、177.91%和161.04%;凤梨叶片的净光合速率也增加了136%-259%,且促进了叶片中可溶性糖和淀粉的积累,但叶绿素含量则下降了33.91%。高CO2浓度处理的凤梨叶片中RuBP羧化酶活性没有明显变化,乙醇酸氧化酶活性则明显下降。     

土壤水分和光照对西葫芦生长和生理特性的影响

以西葫芦"晶莹一号"为试材,采用盆栽和人工遮光的方法研究土壤水分和光照强度对西葫芦生长发育和生理特性的影响.结果表明:遮光30%条件下各处理的植株生长较好,其中遮光30%和土壤相对含水量为70%～80%的处理植株生长最好,产量最高.遮光70%条件下,各处理的植株生长受到严重抑制,只开花,不结果,没有经济产量形成.不同处理西葫芦的耗水趋势一致,日耗水量和总耗水量都随遮光程度的增加和土壤含水量的降低而减少.遮光30%和土壤相对含水量为70%～80%的处理水分利用效率和水分产出率最高,分别为2.36和1.57 kg.mm-1·hm-2.西葫芦叶片的净光合速率、蒸腾速率、气孔导度及叶片叶绿素含量随着遮光程度的增加而减小,胞间CO2浓度随着遮光程度的增加而增加.叶片保护酶活性和脯氨酸含量随着遮光程度的增加而降低,丙二醛含量为遮光70%>自然光照>遮光30%.3种光照条件下,随着土壤含水量的增加,西葫芦叶片的光合特性、保护酶活性及脯氨酸和丙二醛含量的变化不同.     

温度和CO2浓度升高对荒漠藻结皮光合作用的影响

2007年,对腾格里沙漠东南缘沙坡头地区1956年(51龄)和1981年(26龄)人工植被区及自然植被区的藻结皮净光合速率(P_n)变化,及其与结皮含水量(>100%、40%～60%和<20%)、大气CO₂浓度(360和700 mg·L^-1)和温度(13 ℃、24 ℃ 和28 ℃)的关系进行研究.结果表明：51龄、26龄人工植被区和自然植被区的藻结皮P_n分别为3.4、4.4和3.2 μmol·m^-2·s^-1,且51龄人工植被区藻结皮的P_n显著高于26龄人工植被区和自然植被区;藻结皮含水量对其P_n影响显著,且中等含水量(40%～60%)藻结皮的P_n显著高于低含水量(<20%)和高含水量(>100%);CO₂倍增(700 mg·L^-1)后,中等和高含水量藻结皮的P_n增加了1.8～3.3倍,而低含水量时,藻结皮的P_n变化不明显;高含水量和中等含水量处理时,24 ℃和28 ℃条件下藻结皮的P_n较13 ℃时提高27%～66%,而在低含水量时,不同温度的藻结皮P_n值无显著差异.     

BTH和SA处理及白粉菌接种对甜瓜叶片光合特性的影响

以抗病品种Tam Dew和感病品种卡拉克赛为材料,研究了BTH和SA处理及白粉菌接种对甜瓜叶片叶面积、叶绿素含量、净光合速率、气孔导度、胞间CO2浓度的影响.结果表明,BTH和SA处理及白粉菌接种对甜瓜苗期叶面积扩展无显著影响;BTH和SA处理植株的叶片(第3叶)和新生叶片(第5叶)的净光合速率、叶绿素含量和气孔导度显著高于对照;白粉菌接种后,2个甜瓜叶片的叶绿素含量、净光合速率和气孔导度显著降低,而BTH和SA处理能缓解由白粉菌接种带来的叶绿素含量、净光合速率和气孔导度的下降趋势.说明BTH和SA处理能延长甜瓜叶片的光合寿命,延缓甜瓜叶片的叶绿素含量、净光合速率和气孔导度的下降趋势.     

CO2浓度和降水协同作用对短花针茅生长的影响

关于二氧化碳(CO2)浓度和降水等单因子变化对植物生长的影响研究已很多,但多因子协同作用的影响研究仍较少,制约着植物对全球变化响应的综合理解与预测.利用开顶式生长箱(OTC)模拟研究了CO2浓度升高(450和550 μmol/mol)和降水量变化(-30％、-15％、对照、+15％和+30％)的协同作用对荒漠草原优势植物短花针茅(Stipa breviflora)生长特性的影响.结果表明:550 μmol/mol CO2浓度下短花针茅植株的生物量和叶面积较对照显著增加,但450 μmol/mol CO2浓度下的变化不明显;降水增多导致植株生物量、叶面积、叶数和株高显著增加;CO2浓度与降水协同作用显著影响短花针茅植株生物量.CO2浓度升高在一定程度上缓解了降水减少对短花针茅的胁迫效应,但降水量减少3O％则明显抑制了CO2浓度升高带来的效应.研究结果有助于增进荒漠草原植物对未来气候变化的适应性理解,可为制定荒漠草原应对气候变化的对策提供依据.     

大气CO2升高和紫外辐射相互作用对羊栖菜生理特性的影响

为了研究经济海藻羊栖菜对大气CO2浓度增加与紫外辐射(UVR)相互作用的响应,设置两个CO2浓度(380μL/L和800μL/L)以及两种辐射处理,即PAR处理(滤除UV-A、UV-B,藻体仅接受可见光,400—700nm)和PAB处理(全波长辐射280—700nm)培养海藻,探讨了羊栖菜生长、光合作用、呼吸作用、光合色素含量、可溶性糖和蛋白以及硝酸还原酶活性的变化情况。结果表明高浓度CO2显著提高羊栖菜藻体的相对生长速率,并且紫外辐射的负面效应在高CO2处理下表现不显著。高CO2降低了藻体的光合作用速率,而UVR的负面效应和生长体现为一致性,但是羊栖菜的呼吸作用没有受到环境变化的明显影响。羊栖菜的光合色素叶绿素a和类胡萝卜素在高浓度CO2处理下明显降低,而UVR没有明显影响。环境因子对羊栖菜的可溶性糖没有影响,但是在高CO2和全波长辐射处理下,藻体可溶性蛋白的含量显著增加。同时高CO2明显提高了硝酸还原酶的活性,并且仅在高浓度CO2处理下藻体中UVR对其活性有抑制作用。CO2和UVR对羊栖菜的大多数生理特性存在明显的交互作用,在未来CO2浓度进一步增加的情况下,UVR的负面效应将会得到一定程度的缓解,这样有利于羊栖菜在养殖海区获得更高的产量。     

大气CO2浓度升高对土壤碳库稳定性的影响

工业革命以来,大气CO₂浓度持续上升,升高的CO₂浓度会改变植物光合产物积累、土壤碳库的碳输入和碳输出过程,进而通过影响有机碳组成和周转特征来调控土壤碳库动态变化。土壤碳库是陆地生态系统碳库的重要组成部分,其碳储量的微小变化都会对大气CO₂浓度和气候变化产生巨大影响。但目前关于CO₂浓度升高对土壤碳库动态和稳定性的影响还不清楚,很大程度上限制了预测陆地生态系统碳循环对气候变化的反馈。系统综述国内外大气CO₂浓度升高对植被生产力、植被碳输入和土壤碳库影响的研究进展,旨在揭示土壤碳库物理、化学组成以及周转特征对CO₂浓度升高的响应过程和机理,探讨CO₂升高情境下土壤微生物特征对土壤碳库稳定性的影响和驱动机制,为深入理解全球变化下的土壤碳循环特征提供理论支撑。     

Effects of elevated atmospheric CO2 and temperature on the management of powdery mildew of zucchini

The impact of combined environmental factors, such as temperature and CO₂, on the control of the powdery mildew of zucchini, caused by Podosphaera xanthii, and of different control measures has been studied on plants grown in phytotrons. Five experimental trials were conducted, and the powdery mildew severity of both treated and untreated zucchini plants was found to be significantly affected by the interaction between temperature (three different regimes: 16–18; 18–22; 22–26°C), CO₂ (two concentrations: 400–450 and 800–850 ppm) and the treatments. However, at the end of the trials, the efficacy of all the products was not affected by the different, tested environmental conditions. Sulphur consistently provided the highest disease control (75%–85% efficacy). Among the resistant inducers that were tested, calcium oxide was the most effective, in terms of powdery mildew control under all the conditions tested in phytotrons, reducing disease severity from 46% to 61%. Foliar applications of phosphite (14%–28% efficacy), Ampelomyces quisqualis (12%–23% efficacy) and potassium silicate (13%–24% efficacy) only slightly reduced the disease severity for all the tested temperature regimes and CO₂ concentrations, compared to the untreated control. The results obtained under our experimental conditions show that a possible increase in CO₂ concentration and temperature, which is expected for the next few years, should not influence the efficacy of the tested resistance inducers or of sulphur against powdery mildew on zucchini. Moreover, the suppressive effect of calcium oxide is in light of its possible use in greenhouses for zucchini powdery mildew control under 400–450 ppm of CO₂ and under enriched condition of 800–850 ppm of CO₂.     

大气CO2浓度及温度升高对高山灌木鬼箭锦鸡儿(Caragana jubata)生长及抗氧化系统的影响

以CO_2浓度及温度升高为主要标志的全球气候变化将对我国西北地区脆弱的生态系统产生重要影响。利用环境控制实验研究CO_2浓度倍增(eCO_2, C_1:400μmol/mol和C_2:800μmol/mol)和温度升高(eT, T_1:20℃/10℃和T_2:23℃/13℃)对高山灌木鬼箭锦鸡儿(Caragana jubata)生长及抗氧化系统的影响。结果表明:eCO_2和eT表现出相反的生长和生理效应,eT对幼苗生长的影响要大于eCO_2对其的影响。eT使幼苗的总生物量、净光合速率(NAR)和相对生长速率(RGR)降低;但可促进地上部分生长,叶生物量比及叶面积比增加。eCO_2可减缓或补偿由eT引起的总生物量、NAR和RGR的降低,并促进地下部分生长。对抗氧化系统来说,eT使得超氧化歧化酶(SOD)、过氧化物酶(POD)及抗坏血酸过氧化物酶(APX)活性降低,还原型谷胱甘肽(GSH)和抗坏血酸(ASA)含量降低;eCO_2只增加常温下SOD酶活性,并使GSH、ASA整体水平提高。结论:温度升高和CO_2浓度倍增没有协同促进鬼箭锦鸡儿幼苗的生长和光合能力。温度升高将对幼苗生长和抗氧化系统产生不利影响,eCO_2可促进生长并可能通过抗氧剂含量增加来缓解氧化胁迫。因此,未来气候变化,尤其是温度升高将会对高寒区植物产生较大影响,CO_2浓度增加可缓解增温的不利影响。     

大豆主要株型和产量指标对大气CO2和温度升高的响应

针对当前气候变暖和大气CO_2浓度升高同步发生现实,以高光效大豆品种黑农41(HN41)和3个常规对照品种周豆16号(ZD16)、中豆35号(ZD35)和桂黄豆2号(GHD2)为研究对象,通过开顶式气室模拟高CO_2浓度(650μL/L)和温度升高(±0.5—0.6℃)研究了大气CO_2和温度升高对大豆的生长发育与产量影响。结果表明,CO_2浓度升高对株高、茎粗、单株干重和单株籽粒重影响极显著;温度、CO_2与品种互作极显著地影响单株籽粒重。CO_2浓度升高有增加大豆株高、茎粗、干重和单株籽粒重的趋势,且高温下CO_2浓度升高对株高和茎粗的促进作用更大,而正常温度水平下高CO_2浓度升高更有利于干物质积累。与对照CO_2浓度比,高CO_2浓度显著促进了高温下HN41、ZD16和GHD2的株高,并显著提高了正常温度下HN41、ZD16、ZD35和GHD2的单株干重。与正常温度相比,高温仅显著提高了高CO_2处理下HN41的茎粗,并显著提高了对照CO_2处理下HN41的单株籽粒重。此外,同一CO_2浓度和温度处理下,高光效大豆HN41的茎粗、根冠比和单株籽粒重等都显著高于ZD16、ZD35和GHD2;而仅在正常温度与高CO_2浓度处理下HN41的单株干重显著高于ZD16和GHD2。CO_2浓度和温度升高显著影响了高光效大豆的生长,其中,高温下CO_2浓度升高有利于其生长势,正常温度下CO_2浓度升高有利于其光合产物积累。     

大气CO_2增加对不同生长光强下龙须菜光合生理特性的影响

为了探讨未来大气CO2升高对不同生长光强下大型海藻的影响,选取经济红藻龙须菜为实验材料,研究了其生长速率、光合作用、呼吸作用、叶绿素荧光参数以及光合色素对CO2和光强的响应。实验设置两个CO2浓度,正常空气水平CO2浓度(390μL/L)和高CO2浓度(1000μL/L);两个光强梯度,高光(300μmol m-2s-1)和低光(100μmol m-2s-1)。结果表明,CO2和光强对龙须菜的生长和光合作用有明显的交互作用。大气CO2升高并没有显著影响龙须菜的生长速率,但在不同CO2处理下,龙须菜对光强的响应不同。在空气水平下,光强的变化对其生长速率影响不显著。而在高CO2作用下,高光处理下的藻体有更高的生长速率。CO2显著促进高光生长下龙须菜的呼吸作用速率,但是在低光下作用不明显。而对于光合作用速率来说,低光培养下的藻体CO2表现为负面效应,但对高光下生长的藻体作用不明显。CO2增加没有改变龙须菜生长状态下的电子传递速率,但在高光下,CO2表现为一定的抑制作用。CO2显著降低了龙须菜天线色素藻红蛋白和叶绿素a的含量。这些CO2与光强的结合效应表明,大气CO2的升高对龙须菜光合生理特性的影响随着光强的变化而呈现不同的效应,在未来评估CO2的增加对大型海藻的影响时,要充分考虑其他环境因子的耦合效应。     

CO2浓度升高条件下内生真菌感染对宿主植物的生理生态影响

以内蒙古草原常见伴生种、感染内生真菌的天然禾草羽茅为研究对象,通过比较不同CO₂浓度和不同养分供应条件下,带内生真菌和不带菌植物在种子发芽和幼苗生长等方面的差异,探讨带内生真菌的天然禾草对CO₂浓度增加的响应。结果表明:CO₂浓度增加对带菌种子发芽率和发芽速度均无显著影响,但CO₂浓度增加显著降低了不带菌种子的发芽率和发芽速度,即CO₂浓度升高加大了带菌和不带菌种子发芽率之间的差异;内生真菌感染显著提高了宿主植物的最大净光合速率和水分利用效率;羽茅的营养生长受CO₂浓度和养分供应的交互影响,高CO₂浓度对生长的促进作用只出现在充足养分供应条件下;CO₂浓度升高和内生真菌感染对植物根系形态有显著的交互作用,在正常CO₂浓度下,带菌植株根径>1.05 mm的根系比例显著高于不带菌植株,随着CO₂浓度的升高,带菌植株上述根径根系所占比例无显著变化而不带菌植株所占比例显著升高,CO₂浓度升高导致带菌和不带菌不同根径根系分配之间的差异缩小。     

CO2浓度升高和模拟氮沉降对青川箭竹叶营养质量的影响

通过研究大熊猫主食竹之一的青川箭竹(Fargesia rufa Yi)叶营养质量对CO2浓度升高和模拟氮沉降的响应,预测在气候变化下箭竹和大熊猫之间的取食关系,以期为大熊猫的长久保护提供科学参考.利用人工环境控制生长室对青川箭竹幼苗进行了1个生长季节的大气CO2浓度和施氮处理:(1)CON(对照,不添加N和环境CO2浓度),(2)EC(环境CO2浓度+350μmol/mol、不添加N),(3)EN(添加5gNm-2a-1、环境CO2浓度),(4)ECN(环境CO2浓度+350 μmol/mol、添加5 g N m-2 a-1).结果表明:EC处理对青川箭竹叶片的C含量无显著影响,但降低了叶片中N和P含量,从而导致C:N增加,而N:P没显著变化.另外,EC处理增加了叶片中可溶性蛋白、可溶性糖、淀粉、蔗糖和果糖的含量,但降低了木质素和纤维素含量.同时,EC也明显增加了叶片中防御物质单宁的含量.另一方面,EN处理显著降低了叶片中C的含量,并增加了N的含量,但没有改变P的含量,从而C:N减小,而N:P增加.EN显著提高了箭竹叶片可溶性蛋白、可溶性糖和木质素含量,减少了淀粉和纤维素,但对单宁无明显影响.ECN减少了箭竹叶的单宁和N、P的含量,但显著增加了叶的可溶性蛋白、可溶性糖、果糖、蔗糖和淀粉含量.大气CO2浓度升高和氮沉降对叶的N、单宁、可溶性糖和淀粉含量具有显著的交互作用.在未来气候变化情景下,箭竹叶营养质量提高将可能影响叶的生物化学过程以及箭竹-大熊猫之间的取食关系.     

Effects of elevated CO2 and temperature on plant growth and herbivore defensive chemistry

Concentration of atmospheric CO₂ and temperature have both been rising for the last three decades. In this century, the temperature has been predicted to rise by 2–5 °C and the CO₂ concentration to double. These changes may affect the primary and secondary metabolism of plants and thus have implications for other trophic levels. However, the biotic interactions in changing climate conditions are poorly known. In this study, two questions were addressed: (i) How will climate change affect growth and the amounts of secondary compounds in flexible plant species? and (ii) How will this affect herbivores living on this species. Four clones of the dark‐leaved willow (Salix myrsinifolia (Salisb.)) seedlings were grown in closed‐top chambers with two controlled factors: concentration of atmospheric CO₂ and temperature (T). There were four combinations of these factors, each combination replicated four times (total of 16 chambers): (i) Control CO₂ (350 ppm) and control T, (ii) Elevated CO₂ (700 ppm) and control T, (iii) Control CO₂ and elevated T (2 °C), and (iv) Elevated CO₂ and elevated T. Stem growth and aerial biomass of the plants were determined; and the leaf phenolics, nitrogen and water concentrations were analysed. In addition the growth rate of larvae and feeding preference of adults of a specialist herbivore, the chrysomelid beetle Phratora vitellinae (L.), on the treated willow leaves were measured. Elevated temperature and CO₂ concentration increased the stem biomass and elevated CO₂ increased leaf biomass and total aerial biomass of the willows. Patterns of biomass allocation were different in different temperature treatments. At elevated temperature there was less branch and leaf material in relation to stems than at the control temperature. Moreover, patterns of biomass allocation differed among clones. CO₂ enhancement increased the specific leaf weight (SLW) and reduced both water and nitrogen content of the leaves, however, leaf area was unaffected by the treatments. Carbon dioxide (CO₂) and T enhancement reduced the concentrations of several phenolic compounds in the leaves. Phenolic compounds, nutrients, and water in the leaves might be diluted partly due to increased carbon allocation to different structures (e.g. thickening of cell wall and increase of trichomes, etc.). In some cases plant clones showed specific responses to treatments. The CO₂ enhancement reduced the relative growth rate (RGR) of the beetle larvae, and in contrast, temperature elevation increased it. Adult beetles did not clearly discriminate between willow leaves grown in different T and CO₂ environments, but tended to eat more leaf material from chambers with doubled CO₂ concentration. At elevated CO₂ adult beetles may need to eat more leaf material in order to reproduce, which may in turn prolong the life cycles, increasing the risk of being eaten and possibly affecting ability to overwinter successfully. Overall, climate change may significantly modify the dynamic interaction between willow and beetle populations.     

Interactions between increasing CO2 concentration and temperature on plant growth

The global environment is changing with increasing temperature and atmospheric carbon dioxide concentration, [CO₂]. Because these two factors are concomitant, and the global [CO₂] rise will affect all biomes across the full global range of temperatures, it is essential to review the theory and observations on effects of temperature and [CO₂] interactions on plant carbon balance, growth, development, biomass accumulation and yield. Although there are sound theoretical reasons for expecting a larger stimulation of net CO₂ assimilation rates by increased [CO₂] at higher temperatures, this does not necessarily mean that the pattern of biomass and yield responses to increasing [CO₂] and temperature is determined by this response. This paper reviews the interactions between the effects of [CO₂] and temperature on plants. There is little unequivocal evidence for large differences in response to [CO₂] at different temperatures, as studies are confounded by the different responses of species adapted and acclimated to different temperatures, and the interspecific differences in growth form and development pattern. We conclude by stressing the importance of initiation and expansion of meristems and organs and the balance between assimilate supply and sink activity in determining the growth response to increasing [CO₂] and temperature.