臭氧胁迫对冬小麦光响应能力及PSⅡ光能吸收与利用的影响

为准确评价O3胁迫对冬小麦光响应能力和PSⅡ光能吸收、分配与利用的影响,通过OTC设置了活性碳过滤空气(CF,4—28 nL/L)、不通风(5H,15—68 nL/L)、环境空气(NF,7—78 nL/L)、100nL/L O3 (CF100,96—108 nL/L)和150nL/L O3 (CF150,145—160nL/L) 等5种O3熏蒸处理,用IMAGING-PAM测量了冬小麦（丰抗13）扬花期的Fo、Fm及自然光下的快速光曲线。结果表明,O3胁迫显著降低了冬小麦PSⅡ的最大量子效率(Fv/Fm)、最大光合速率(Pm)、半饱和光强(Pm/α)、吸光系数(IA)、调节性热耗散的量子产额(Y(NPQ))和非光化学淬灭系数(NPQ),显著提高了冬小麦的初始光能利用效率(α)、非调节性热耗散的量子产额(Y(NO))和PSⅡ吸收光能的日累计损失（Daily ∑Y(NO)+ Daily ∑Y(NPQ)）;CF处理显著提高了冬小麦的Pm、α、Y(NPQ)、NPQ及PSⅡ日累计利用的光能（Daily ∑Y(Ⅱ)）;当其余4组的Y(NPQ)和NPQ趋于饱和时,NF仍在以较快的速率上升。O3胁迫显著降低了冬小麦吸收、利用光能的能力和光保护能力,改变了PSⅡ吸收光能的分配结构,提高了冬小麦对光强变化的敏感性,加剧了光抑制,致使冬小麦受到O3和过剩光能的双重伤害;CF处理下冬小麦的光合能力和光保护能力显著提高,但对强光的潜在耐受能力低于NF;固城的空气质量已对冬小麦造成一定影响,极可能导致产量损失。     

AlA对冬小麦不同粒位籽粒灌浆影响的动态模拟及特征分析

以百农矮抗58为材料,采用大田试验的方法,研究了在始穗期喷施不同浓度(10mg/L、30 mg、50 mg/L)的5-氨基乙酰戊酸(5-Aminolevulinic acid,ALA)对冬小麦不同粒位籽粒灌浆特性的影响.应用Richards方程对10～50 mg/L ALA处理下冬小麦3个粒位(第Ⅰ、Ⅱ、Ⅲ粒位)的籽粒灌浆过程进行了模拟.建立在Richards方程基础上的籽粒生长分析显示:与对照相比,10～50 mg/L ALA处理使第Ⅰ和第Ⅲ粒位的千粒重分别增加了1.3～2.4g、3.4～4.7,较对照差异显著,第Ⅱ粒位的粒重与对照差异不显著;10～50 mg/L ALA处理使冬小麦3个粒位籽粒的平均灌浆速率和最大灌浆速率增大,灌浆活跃持续期延长,到达最大灌浆速率的时间提前.阶段灌浆特征参数的比较表明,在籽粒灌浆的渐增期,10～50 mg/L ALA处理使冬小麦3个粒位籽粒的平均灌浆速率增加,灌浆持续期缩短;在籽粒灌浆的快增期,使3个粒位籽粒的平均灌浆速率增加,灌浆持续期延长.在籽粒灌浆的缓增期,使强势粒(第Ⅰ、第Ⅱ粒位)的平均灌浆速率减小,灌浆持续期延长,但使弱势粒(第Ⅲ粒位)的平均灌浆速率增加,灌浆持续期延长.表明在灌浆的前期和中期,10～50 mg/L ALA处理可促进各粒位籽粒提早启动灌浆,并提高其灌浆速率,在灌浆后期减弱了强势粒对弱势粒籽粒灌浆充实的优势,从而有利于弱势粒的灌浆充实.从总体上讲,10～50 mg/L ALA对弱势粒(第Ⅲ粒位)粒重的影响程度大于强势粒(第Ⅰ和第Ⅱ粒位),其中30 mg/L ALA促进籽粒增重的效果最明显.     

氮肥后移对抽穗后水分胁迫下冬小麦光合特性及产量的影响

采用子母桶栽土培法模拟冬小麦抽穗后不同的水分胁迫状态,研究了氮肥后移对冬小麦光合特性及产量的影响.设置3个氮肥处理,分别为N₁(基肥∶拔节肥∶开花肥=10∶0∶0)、N₂(6∶4∶0)和N₃(4∶3∶3),模拟冬小麦抽穗后2种水分胁迫(渍水胁迫、干旱胁迫),设正常供水为对照.结果表明：相同供水条件下,N₂和N₃处理较N₁处理显著提高冬小麦灌浆期旗叶的SPAD和光合速率,确保了收获时较高的穗数、穗粒数和地上部分生物量;氮肥后移处理显著提高了冬小麦的耗水量,但其籽粒产量和水分利用效率也显著提高.相同氮肥条件下,干旱胁迫和渍水胁迫处理较正常供水显著降低了冬小麦开花期和灌浆期旗叶的光合速率、千粒重、穗粒数和产量.与正常供水相比,各氮肥条件下干旱胁迫和渍水胁迫处理花后旗叶光合速率及籽粒产量的减小幅度均表现为N₁＞N₂＞N₃.表明氮肥后移通过提高旗叶SPAD、减缓花后旗叶光合速率的下降幅度、增加地上部分干物质积累量,调控产量及其构成要素,以减轻逆境灾害(干旱和渍水胁迫)对产量的影响.     

冬小麦气孔臭氧通量拟合及通量产量关系的比较分析

基于田间原位开顶箱(Open-Top Chambers,OTCs)实验,研究了不同浓度臭氧(O3)处理下(自然大气处理,AA;箱内大气处理,NF;箱内低浓度O3处理,NF+40 nL/L;箱内中等浓度O3处理,NF+80 nL/L;箱内高浓度O3处理,NF+120 nL/L),冬小麦(Triticum aestivum L.)旗叶气孔运动对不同环境因子的响应,并通过剂量反应分析,比较了冬小麦产量损失与累积气孔O3吸收通量(AFstX)和累积O3暴露浓度(AOT40和SUM06)的相关性差异。结果表明:冬小麦旗叶气孔运动的光饱和点和最适温度分别约为400μmol.m-.2s-1和27℃,水汽压差、土壤含水量和O3剂量的气孔限制临界值分别约为1.4 kPa、-100 kPa和20μL.L-.1h-1,超过此临界值时,气孔导度会明显下降。利用Jarvis气孔导度模型对冬小麦旗叶气孔导度和气孔O3吸收通量进行了预测,结果表明Jarvis模型解释了冬小麦实测气孔导度60%的变异性。由于不同时期植物体气孔导度的差异,冬小麦旗叶生长期内累积气孔O3吸收通量(AFstX)呈非线性增加趋势。O3吸收速率临界值(X)为4 nmol.m-.2s-1时,累积O3吸收通量(AFst4)与冬小麦产量的相关性最高(R2=0.76),该数值介于O3暴露指标AOT40和SUM06的剂量反应决定系数(0.74和0.81)之间。与O3浓度指标(AOT40和SUM06)相比,O3通量指标(AFstX)在本试验冬小麦产量损失评价中未表现出明显优势。     

灌溉对干旱区冬小麦干物质积累、分配和产量的影响

为探明灌溉对干旱区冬小麦(Triticum aestivum)产量、水分利用效率(WUE)、干物质积累及分配等的影响, 以甘肃河西走廊冬小麦适宜种植品种‘临抗2号’为材料进行了研究。在冬季灌水180 mm的条件下, 生育期以灌水量和灌水次数等共设置5个处理, 分别为: 拔节期灌水量165 mm (W1)、拔节期灌水量120 mm +抽穗期灌水量105 mm (W2)、拔节期灌水量105 mm +抽穗期灌水量105 mm +灌浆期灌水量105 mm (W3)、拔节期灌水量75 mm +抽穗期灌水量75 mm +灌浆期灌水量75 mm (W4)、拔节期灌水量105 mm +抽穗期灌水量75 mm +灌浆期灌水量45 mm (W5)。结果表明: 随着生育期的推进, 土壤有效含水量(AWC)受灌水次数及灌水量影响更加明显; W3、W4处理的土壤各层AWC在灌浆期均较高; 叶面积指数(LAI)下降慢, 延缓了生育后期的衰老; 生育后期干物质积累增加, 提高了穗粒数、千粒重和籽粒产量。籽粒产量以W3处理最高, 但W4具有最高的WUE, 且籽粒产量与W3无显著差异, 但W4较灌溉总量相同的W2和W5以及灌水量最少的W1具有明显的指标优势。W1、W2、W5处理灌浆期各层土壤AWC均较低, 花后LAI下降快, 干物质积累减少, 灌浆持续期缩短, 穗粒数和千粒重减少, 最终表现为籽粒产量和WUE下降。灌浆期水分胁迫可促进花前储存碳库向籽粒的再转运, 并随着干旱胁迫的加重而提高, 对籽粒产量起补偿作用; 水分胁迫提高了灌浆速率, 但缩短了灌浆持续期。相关性分析表明, 灌浆持续期、有效灌浆持续期、有效灌浆期粒重增加值和最大籽粒灌浆速率出现时间与千粒重和籽粒产量均呈正相关。综合考虑, 拔节、抽穗及灌浆期各灌溉75 mm是高产高WUE的最佳灌水方案。     

臭氧胁迫下冬小麦物质生产与分配的数值模拟

利用ML9810B型臭氧监测分析仪,测定了浙江嘉兴麦田空气O3浓度,并通过改进的开顶式气室实验确定O3浓度变化对冬小麦叶片光合速率的影响函数.在此基础上,加入O3对叶片生长和穗部光合影响的模拟函数,建立反映O3对冬小麦生长和产量形成影响的作物模型.模型的检验结果表明,该模型较好地反映了O3对冬小麦生长的影响,生物量平均相对误差为10.3%.对冬小麦春后生育期(3—5月)的研究表明,水肥适宜时,由O3影响造成的该地区冬小麦干物质累积总损失量为11.4%,产量损失为17.8%.     

不同产量水平旱地冬小麦品种干物质累积和转移的差异分析

旱地小麦高产栽培中品种起着重要作用,研究不同产量水平旱地冬小麦品种干物质累积和转移的差异,对黄土高原旱区作物高产稳产有重要意义。以9个旱地冬小麦品种为材料,通过田间试验研究了不同产量水平旱地冬小麦品种的生物量、花前花后干物质累积量、干物质转移量、转移率及转移干物质对籽粒的贡献率、叶面积、SPAD值以及光合速率的差异。结果表明,不同小麦品种的生物量、花前花后干物质累积量、干物质转移量、转移率及转移干物质对籽粒的贡献率均存在明显差异。与不施肥相比,高、中、低3个产量水平小麦品种在低养分投入时,成熟期生物量分别提高29%,22%和6%,高水平时分别提高46%,39%和23%,高产品种的生物量及其对养分投入的敏感程度明显高于低产品种。不同品种的花后干物质累积量随养分投入水平提高而增加,但花前营养器官中储存物质的转移量、转移率和对籽粒的贡献率却明显随之下降。功能叶(旗叶)在灌浆期高、中、低3个产量水平品种的SPAD值在低养分投入条件下分别为20.7、17.5和13.7;高养分投入时,分别为35、26.1和16.8。高产品种西农88的光合速率为6.0μmolCO.2m-.2s-1),中产和低产品种的平均光合速率分别为4.3μmolCO.2m-.2s-1和4.0μmolCO.2m-.2s-1,高产品种功能叶(旗叶)在灌浆期能保持较高的SPAD值和光合速率,因而花后能生产较多的干物质,但其花前干物质转移量、转移率及转移干物质对籽粒的贡献率均没有明显优势。可见,花后较高的叶绿素水平、光合速率和干物质累积是旱地小麦品种高产的重要原因。选择优良品种,采取合理的栽培措施,特别是通过养分调控保持花后具较高的干物质累积量是西北旱地进一步提高冬小麦产量的重要途径。     

植物多糖类复合制剂对冬小麦产量及物质转运的影响

在大田栽培条件下,采用生物质多糖(P₁)、生物质多糖和5 氨基乙酰丙酸复配(P₂),以及生物质多糖、5-氨基乙酰丙酸和缩节胺为有效成分复配(P₃)的3种不同制剂,研究在冬小麦始花期叶面喷施制剂对其产量构成、蔗糖、可溶性总糖、干物质贮运以及氮磷养分累积与转移的影响.结果表明: 喷施3种制剂使冬小麦穗粒数和千粒重增加,增产8.5%以上;喷施20 d内,小麦旗叶蔗糖含量较对照明显增加;喷施P₁和P₃使小麦籽粒可溶性糖含量分别比对照增加4.5%和11.0%.P₃增加了小麦花后干物质及氮磷养分累积量,分别较对照增加48.5%、116.9%和18.1%,P₃还显著提高了小麦花后干物质及养分累积对产量的贡献,但花前养分向籽粒转移对产量的贡献小于其他处理.小麦增产与植物多糖类复合制剂有效调控营养器官光合产物输出、籽粒可溶性糖积累,以及促进花后干物质和氮磷养分累积有关.     

分期施氮与CO2浓度升高对小麦光合及其物质积累和产量的互作效应

采用开顶式气室和盆栽方法,以冬小麦品种‘小偃22’为材料,探讨了分期施氮与CO2浓度升高对小麦抽穗期和灌浆中期旗叶光合、地上部物质积累和产量的互作效应.结果显示:(1)不施氮条件下CO2浓度升高对小麦旗叶叶绿素含量(SPAD)和可溶性蛋白含量、光合能力、地上部花后干物质和氮素累积量、籽粒产量的影响不明显(P>0.05)或产生显著负效应;在施氮(300mg/kg土)条件下各指标均不同程度增加,且大多数达到显著水平.(2)与氮肥全部基施相比,分期施氮时CO2浓度升高使灌浆期旗叶光合能力、地上部花后干物质和氮素累积以及产量增加的幅度较大,其中以播前、返青期和孕穗期施氮比例为5∶3∶2时最明显.研究表明,适当分期施氮可能更有利于发挥CO2浓度升高对冬小麦的增产作用.     

西北绿洲种植密度对冬小麦产量及生理指标的影响

合理密度是群体高产的基础.在西北绿洲生态条件下,研究了密度对冬小麦产量及相关指标的影响.以冬小麦品种临抗2号为材料,在播种量225～450kg.hm-2范围内设6个处理,处理间对应的密度范围为275～516基本苗·m-2.处理间单位面积籽粒产量、单位面积穗数、穗粒数、千粒重、水分利用效率(WUE)、单株穗数、单株茎数、叶面积指数、株高、光合速率(Pn)、蒸腾速率(Tr)、气孔导度(Gs)以及群体光合速率(CAP)存在着显著或极显著的差异,以密度390·m-2的处理籽粒产量最高(8650kg·hm-2).籽粒产量与单位面积穗数高度正相关(r=O.89**),而与穗粒数和千粒重相关不显著.籽粒产量与生育期分5次测定的单叶Pn、Tr、Ga之间均没有显著相关,而与开花期测定的CAP、灌浆前期和中期的叶面积指数显著正相关.不同密度处理的Pn、Tr、Gs在生育期间的变化都呈双峰曲线,三者的高峰值分别出现在抽穗期和灌浆前期,Pn的最大峰值出现在抽穗期,而Tr、Gs的最大峰值出现在灌浆前期.虽然Pn、Tr、Gs的5次测定平均值之间高度正相关(r=0.94**～0.97**),但它们间的相关程度随生育阶段的不同仍有较大差异(r=0.53～0.99**).各时期测定的Pn、Tr、Gs与CAP没有显著相关.     

臭氧胁迫对水稻生长以及C、N、S元素分配的影响

采用开顶式气室(Open-top Chamber, OTC),对水稻"3694繁"(Oryza sativa L., 3694 Fan)在浙江嘉兴进行田间原位臭氧(O₃)熏气实验,研究不同臭氧浓度熏气对水稻生长以及C、N,S元素分配的影响。实验设置分4个水平:过滤大气组(CF,10 nL/L)、自然大气组(NF,40 nL/L)和两个不同浓度的臭氧处理组(O₃-1:100 nL/L; O₃-2:150 nL/L)。主要结果表明:(1)开始臭氧熏气时,各个处理组单茎水稻各组分生物量没有差异. 在熏气后期(水稻成熟期),臭氧处理使单茎水稻根、茎和穗生物量显著下降,根冠比降低,株高显著降低,表明臭氧胁迫增加水稻地上部分的干物质分配,且对株高的影响可能大于对地上生物量的影响;(2)臭氧处理使水稻根和茎C元素含量下降,叶C元素含量上升,表明臭氧胁迫提高了叶片中碳分配,而降低了根和茎的碳分配;(3)各个组分N元素含量上升和碳氮比下降;(4)茎、叶和穗S元素含量上升,可能会增强水稻抗氧化系统的作用,从而抵抗臭氧胁迫。所有实验结果表明臭氧浓度升高会对水稻生长产生严重不利影响,从而导致水稻各个组分的C、N、S元素分配格局发生改变。     

Interactions of tropospheric CO2 and O3 enrichments and moisture variations on microbial biomass and respiration in soil

Soil microbial biomass C (C_mic) is a sensitive indicator of trends in organic matter dynamics in terrestrial ecosystems. This study was conducted to determine the effects of tropospheric CO₂ or O₃ enrichments and moisture variations on total soil organic C (C_org), mineralizable C fraction (C_Min), C_mic, maintenance respiratory (qCO₂) or C_mic death (qD) quotients, and their relationship with basal respiration (BR) rates and field respiration (FR) fluxes in wheat‐soybean agroecosystems. Wheat (Triticum aestivum L.) and soybean (Glycine max. L. Merr) plants were grown to maturity in 3‐m dia open‐top field chambers and exposed to charcoal‐filtered (CF) air at 350 μL CO₂ L^?1; CF air + 150 μL CO₂ L^?1; nonfiltered (NF) air + 35 nL O₃ L^?1; and NF air + 35 nL O₃ L^?1 + 150 μL CO₂ L^?1 at optimum (? 0.05 MPa) and restricted soil moisture (? 1.0 ± 0.05 MPa) regimes. The + 150 μL CO₂ L^?1 additions were 18 h d^?1 and the + 35 nL O₃ L^?1 treatments were 7 h d^?1 from April until late October. While C_org did not vary consistently, C_Min, C_mic and C_mic fractions increased in soils under tropospheric CO₂ enrichment (500 μL CO₂ L^?1) and decreased under high O₃ exposures (55 ± 6 nL O₃ L^?1 for wheat; 60 ± 5 nL O₃ L^?1 for soybean) compared to the CF treatments (25 ± 5 nL O₃ L^?1). The qCO₂ or qD quotients of C_mic were also significantly decreased in soils under high CO₂ but increased under high O₃ exposures compared to the CF control. The BR rates did not vary consistently but they were higher in well‐watered soils. The FR fluxes were lower under high O₃ exposures compared to soils under the CF control. An increase in C_mic or C_mic fractions and decrease in qCO₂ or qD observed under high CO₂ treatment suggest that these soils were acting as C sinks whereas, reductions in C_mic or C_mic fractions and increase in qCO₂ or qD in soils under elevated tropospheric O₃ exposures suggest the soils were serving as a source of CO₂.     

Response of gas exchange and yield components of field-grown Triticum aestivum L. to elevated ozone in China

To assess photosynthesis and yield components’ response of field-grown wheat to increasing ozone (O₃) concentration (based on diurnal pattern of ambient O₃) in China, winter wheat (Triticum aestivum L.) cv. Jia 403 was planted in open top chambers and exposed to three different O₃ concentrations: O₃-free air (CF), ambient air (NF), and O₃-free air with additional O₃ (CF+O₃). Diurnal changes of gas exchange and net photosynthetic rate (P _N) in response to photosynthetic photon flux density (PPFD) of flag leaves were measured at the filling grain stage, and yield components were investigated at harvest. High O₃ concentration altered diurnal course of gas exchange [P _N, stomatal conductance (g _s), and intercellular CO₂ concentration (C _i)] and decreased significantly their values except for C _i. Apparent quantum yield (AQY), compensation irradiance (CI), and saturation irradiance (SI) were significantly decreased, suggesting photosynthetic capacity was also altered, characterized as reduced photon-saturated photosynthetic rate (P _Nmax). The limit of photosynthetic activity was probably dominated by non-stomatal factors in combination with stomatal closure. The significant reduction in yield was observed in CF+O₃ treatment as a result of a marked decrease in the ear length and the number of grains per ear, and a significant increase in the number of infertile florets per ear. Even though similar responses were also observed in plants exposed to ambient O₃ concentration, no statistical difference was observed at current ambient O₃ concentration in China.     

The role of volumetric power input in the growth,morphology, and production of a recombinant glycoprotein by Streptomyces lividans in shake flasks

The impact of flask geometry on Streptomyces lividans growth and morphology, production and O-mannosylation of a recombinant O-glycoprotein (APA from Mycobacterium tuberculosis) was described and associated to the evolution of the volumetric power input (P/V) in three shake flask geometries. During the exponential growth, the highest P/V was found in baffled flasks (BF) with 0.51 kW/m³, followed by coiled flasks (CF) with 0.44 kW/m³ and normal Erlenmeyer flasks (NF) with 0.20 kW/m³ (flasks volume of 250 mL, filling with 50 mL and agitated at 150 rpm). During the stationary phase, P/V decreased 20% in BF and CF, but increased two times in NF, surely due to changes in mycelial morphology and its effects on rheology. Also, NF cultures were carried out at a filling volume and agitation of 15 mL, 150 rpm (15 mL-NF), and 25 mL, 168 rpm (25 mL-NF), in order to raise P/V closely to the values obtained in CF. However, different growth, morphology and recombinant protein productivity were obtained. These data indicate that P/V is not a definitive parameter that can determine bacteria growth and morphology, not even glycoprotein production. But it can be proposed that the oxygen transfer in the center of the pellets and hydromechanical stress might be the more relevant parameters than P/V.     

Effects of elevated CO2 and O3 on the rate and duration of grain growth and harvest index in spring wheat (Triticum aestivum L.)

Wheat (Triticum aestivum L.) cv. Minaret was grown in open-top chambers (OTCs) in 1995 and 1996 under three carbon dioxide (CO₂) and two ozone (O₃) levels. Plants were harvested regularly between anthesis and maturity to examine the rate of grain growth (dG/dt; mg d^–1) and the rate of increase in harvest index (dHI/dt;% d^–1). The duration of grain filling was not affected by elevated CO₂ or O₃, but was 12 days shorter in 1995, when the daily mean temperature was over 3 °C higher than in 1996. Season-long exposure to elevated CO₂ (680 μmol mol^–1) significantly increased the rate of grain growth in both years and mean grain weight at maturity (MGW) was up to 11% higher than in the chambered ambient air control (chAA; 383 μmol mol^–1). However, the increase in final yield obtained under elevated CO₂ relative to the chAA control in 1996 resulted primarily from a 27% increase in grain number per unit ground area. dG/dt was significantly reduced by elevated O₃ under ambient CO₂ conditions in 1995, but final grain yield was not affected because of a concurrent increase in grain number. Neither dG/dt nor dHI/dt were affected by the higher mean O₃ concentrations applied in 1996 (77 vs. 66 nmol mol^–1); the differing effects of O₃ on grain growth in 1995 and 1996 observed in both the ambient and elevated CO₂ treatments may reflect the contrasting temperature environments experienced. Grain yield was nevetheless reduced under elevated O₃ in 1996, primarily because of a substantial decrease in grain number. The data obtained show that, although exposure to elevated CO₂ and O₃ individually or in combination may affect both dG/dt and dHI/dt, the presence of elevated CO₂ does not protect against substantial O₃-induced yield losses resulting from its direct deleterious impact on reproductive processes. The implications of these results for food production under future climatic conditions are considered.     

Impact of elevated ozone concentration on growth,physiology, and yield of wheat (Triticum aestivum L.): a meta‐analysis

We quantitatively evaluated the effects of elevated concentration of ozone (O₃) on growth, leaf chemistry, gas exchange, grain yield, and grain quality relative to carbon‐filtered air (CF) by means of meta‐analysis of published data. Our database consisted of 53 peer‐reviewed studies published between 1980 and 2007, taking into account wheat type, O₃ fumigation method, rooting environment, O₃ concentration ([O₃]), developmental stage, and additional treatments such as drought and elevated carbon dioxide concentration ([CO₂]). The results suggested that elevated [O₃] decreased wheat grain yield by 29% (CI: 24–34%) and aboveground biomass by 18% (CI: 13–24%), where CI is the 95% confidence interval. Even in studies where the [O₃] range was between 31 and 59 ppb (average 43 ppb), there was a significant decrease in the grain yield (18%) and biomass (16%) relative to CF. Despite the increase in the grain protein content (6.8%), elevated [O₃] significantly decreased the grain protein yield (?18%). Relative to CF, elevated [O₃] significantly decreased photosynthetic rates (?20%), Rubisco activity (?19%), stomatal conductance (?22%), and chlorophyll content (?40%). For the whole plant, rising [O₃] induced a larger decrease in belowground (?27%) biomass than in aboveground (?18%) biomass. There was no significant response difference between spring wheat and winter wheat. Wheat grown in the field showed larger decreases in leaf photosynthesis parameters than wheat grown in < 5 L pots. Open‐top chamber fumigation induced a larger reduction than indoor growth chambers, when plants were exposed to elevated [O₃]. The detrimental effect was progressively greater as the average daily [O₃] increased, with very few exceptions. The impact of O₃ increased with developmental stages, with the largest detrimental impact during grain filling. Both drought and elevated [CO₂] significantly ameliorated the detrimental effects of elevated [O₃], which could be explained by a significant decrease in O₃ uptake resulting from decreased stomatal conductance.     

近地层臭氧对小麦抗氧化酶活性变化动态的影响

摘要:利用开顶式气室（TOCs）模拟了地表O3浓度升高的大田试验条件,测定了小麦各生长期(返青期、拔节期、孕穗期、抽穗期、灌浆期、成熟期)叶片抗氧化酶的活性。通过两年的重复试验,得到相似结果。试验表明,过氧化氢酶（CAT）和过氧化物酶（POD）活性在小麦的生长进程中,先升高后降低。O3浓度升高使CAT酶和POD酶活性的峰值期提前,POD酶峰值期明显提前所需的O3浓度比CAT酶高,O3诱导小麦生长前期的CAT、POD酶活性升高,后期则起抑制作用。POD酶对低浓度O3的胁迫响应时间较晚。当O3浓度提高到150 nL?L-1时,超氧化物歧化酶（SOD）活性随小麦生长期的变化,由原来的双峰曲线变为单峰曲线,高浓度O3使SOD酶活性在抽穗期后持续显著降低。O3不明显改变抗坏血酸过氧化物酶（APX）对胁迫的响应时间,但一定浓度范围内O3能诱导APX酶活性升高。不同浓度的O3对SOD酶和APX酶的作用效应和强度显著不同, CAT酶和POD酶对O3比较敏感。 因此,近地层O3浓度增加,改变了CAT、POD和SOD酶活性变化的时序特征,抗氧化酶对O3胁迫的响应特征取决于小麦的生育期、O3的浓度和薰气时间。     

Effects of stocking density during live transportation on haematological parameters of Siberian sturgeon (Acipenser baerii,Brandt, 1869)

In this study, we investigated the effects of different stocking densities water quality and blood parameters during the transportation of the Siberian sturgeon (Acipenser baerii). Experiments were carried out in high-density polyethylene tank with three different stocking densities (50, 100 and 150 kg/m³) for 20 h. Ammonium nitrogen (NH₄-N) and nitrite nitrogen (NO₂-N) were measured in the water samples. The erythrocyte, leucocyte, haematocrit (HCT), haemoglobin (Hb), cortisol, and sodium ion (Na⁺) were measured in blood samples. Ammonium nitrogen and nitrite nitrogen concentrations in the water have increased in parallel with the stocking density depending on the time. In the highest stocking density, the maximum levels of NH₄-N and NO₂-N at the 16^th h reached 2.64 mg/L and 4.74 mg/L, respectively. Erythrocyte, leucocyte, HCT, and Hb values did not differ significantly between the experimental groups (p > .05). The results showed that fish could be transported safely for 20 h in 15℃ water temperature at 50 kg/m³ stocking density; however, stocking density of 100 kg/m³ and over could threaten fish welfare and health as from 16^th h.     

O3浓度升高和太阳辐射减弱对小麦根际土壤微生物功能多样性的影响

采用开顶箱(OTC)法和遮光网技术,设置100 n L/L臭氧熏气与3个辐射减弱梯度结合,模拟臭氧浓度升高和太阳辐射减弱的复合大气背景。用BIOLOG生态测试板,采用孔平均颜色变化率法(AWCD)测定冬小麦根际土壤微生物利用不同碳源的能力,计算微生物群落多样性指数,对不同碳源的利用率进行了主成分分析。两年试验结果显示,臭氧熏气与太阳辐射减弱复合作用,降低了土壤微生物对碳源的利用速度和利用总量;除了聚合物以外其它碳源利用率显著降低;对土壤微生物多样性没有直接的影响;对碳源降解的抑制效应大于增强的O3与减弱的太阳辐射两因素各自的单独作用。太阳辐射减弱20%,一定程度上增加了对聚合物类的分解。O3熏气条件下太阳辐射减弱,糖类、胺类代谢变异度较高,受环境影响较大。     

Changes in Activities of Antioxidant Enzymes in Sunflower Leaves of Different Ages

Role of superoxide dismutase isozymes and other antioxidant enzymes was studied in relation to leaf age in sunflower (Helianthus annuus L. cv. ACC 1508) at pre-flowering and grain filling stages. Relative water content (RWC) did not change much in leaves of different age and at the two stages. Protein content declined continuously from the youngest to the oldest leaf, while chlorophyll (Chl) and carotenoids (Car) contents increased down to 7^th/9^th leaf and declined in subsequent older leaves. Protein, Chl and Car contents were higher at pre-flowering than at seed filling stage. Superoxide dismutase (SOD), its isozymes, and ascorbate peroxidase (APO) and catalase (CAT) activities were highest in the 9^th leaf and declined in subsequent older leaves. SOD and APO activities were higher at seed filling, except in oldest senescent (13^th, 15^th) leaves. Among SOD isozymes, Cu/Zn-SOD and Mn-SOD activities accounted for most of the total SOD, and only marginal activity was observed for Fe-SOD. Peroxidase activity increased from youngest to the oldest leaf at pre-flowering stage and down to 13^th leaf at seed filling stage. This revised version was published online in July 2006 with corrections to the Cover Date.