不同氮素形态及水分胁迫对水稻苗期水分吸收、光合作用及生长的影响

采用室内营养液培养, 聚乙二醇(PEG6000)模拟水分胁迫处理、HgCl2抑制水通道蛋白活性的方法, 在3种供氮形态下(NH4+-N/ NO 3--N为100/0、50/50和0/100), 研究了水稻苗期水分吸收、光合及生长的状况。结果表明, 在非水分胁迫下, 水稻单位干重吸水量以单一供NO3--N处理最高, 加HgCl2抑制水通道蛋白活性后, 单一供NO3--N、NH4+-N和NH4+-N/ NO3--N为50/50处理的水稻水分吸收分别下降了9.6%、20.7%和16.0%; 但在水分胁迫下, 单一供NO3--N的处理水分吸收量显著降低, 低于其它2个处理, 加HgCl2抑制水通道蛋白活性后, 水分吸收量分别降低了1.0%、18.8%和23.5%。在2种水分条件(水分胁迫与非水分胁迫)下, 净光合速率、气孔导度、蒸腾速率和细胞间隙CO2浓度等指标均以单一供NH4+-N处理最大,NH4+-N/ NO3--N为50/50处理次之, 单一供NO3--N处理最小。HgCl2处理结果表明, 不同形态氮素营养能够影响水稻幼苗根系水通道蛋白活性。在2种水分条件下, NH4+-N/ NO3--N为50/50处理的生物量(干重)均最大。本研究为水稻苗期合理施肥以壮苗提供了理论依据。     

HgCl2胁迫对小麦幼苗水分利用效率和叶绿素含量的影响

水通道蛋白(aquaporin,AQP)是植物体内水分吸收和运输的通道.以小麦品种石4185的幼苗为材料,在正常供水供养条件下,采用不同浓度的AQP抑制剂HgCl2对其根部进行胁迫处理,研究植株水分利用效率等性状的变化,以明确水通道蛋白与水分利用效率(WUE)的关系.结果表明:(1)小麦水通道蛋白在受到HgCl2抑制后,其幼苗的单株生物量和单株WUE(生物学产量干重/耗水量)显著低于对照处理,并且随着HgCl2浓度的增加呈逐渐下降趋势.(2)处理后植株24 h5、d和14 d的单株耗水量均显著低于对照组.(3)HgCl2胁迫处理后5 min内小麦叶片叶绿素含量持续下降,处理24 h的含量均远低于初始值,并且随胁迫时间延长处理叶片逐渐变黄.研究发现,HgCl2在抑制小麦幼苗水通道蛋白的同时,也对其光合作用相关酶和蛋白质体在短时间内产生一定影响,从而阻碍幼苗正常生长.     

氮素形态对黄檗幼苗生长及氮代谢相关酶类的影响

通过改变水培溶液中NH4^＋-N和NO3^--N的比例,研究了不同氮素形态对黄檗（Phellodendron amurense）幼苗生长及氮代谢相关酶类的影响。结果表明,硝态氮比例较高的营养供给比铵态氮比例较高的营养供给有利于黄檗幼苗的生长,叶片叶绿素含量和可溶性蛋白含量也高。在NH4^＋-N／NO3^--N为25／75时黄檗幼苗具有最大生物量。在铵态氮比例大的营养供给下,黄檗幼苗的谷氨酰胺合成酶（GS）活性增强,而在硝态氮比例大的营养供给下幼苗的硝酸还原酶（NR）活性则较高,叶片中的硝态氮较低。营养液的氮素形态及其组成通过影响GS与NR的活性而调控黄檗幼苗的氮素代谢。     

太湖地区氮素湿沉降动态及生态学意义：以常熟生态站为例

在常熟生态站2001年6月至2003年5月连续两年定位收集湿沉降,对太湖地区氮素湿沉降动态进行研究．结果表明,湿沉降氮输入量季节变化显著,夏、春季高,秋、冬季低．在湿沉降输入氮中NH4^+-N、NO3^--N和DON的比例分别为47．6％、35．1％和17．4％．湿沉降中NH4^+-N主要来自当地农田的氨挥发,湿沉降NH4^+-N月输入量随月降雨量增加而增加(R0=0．3178^**)．该地区空气中NO3^--N浓度相对比较稳定,湿沉降中NO3^--N浓度与降雨量呈负相关(R^2=0．4205^***)．湿沉降NO33^--N月输入量与月降雨次数呈直线正相关(R^2=0．6757***),而与月降雨量相关性较差(R^2=0．1985^*)．湿沉降TN年输入量为27．0kg·hm^-2,并在所有降雨中,氮浓度均超过水体富营养化阈值(0．2mg·L^-1)．     

太湖地区稻田土壤养分淋洗特征

通过排水采集器(Lysimeter)模拟试验,研究了太湖地区不同施肥水平下稻季农田养分淋洗特点。结果表明,施肥后田面水NH4^+-N浓度升高很快,2～3d达到峰值,最高值达26．2mg·L^-1,随后下降很快,这一周期约7～10d,渗漏水中NH4^+-N浓度很低,稻季NH4^+-N淋洗的氮仅占施肥量的0．008％～0．074％,渗漏液中NO3^--N含量随着氮肥用量的增加而增加,其浓度范围在0～7．14mg·L^-1,在土壤剖面中呈上低下高的趋势,稻季氮素的淋洗仍以NO3^--N为主,净淋洗量在3．2～8．3kg·hm^-2之间,占总施肥量的1．40％～2．78％,田面水磷浓度在施磷肥后1d即达最高值,随后下降,下层渗漏液中T-P含量很低,几乎不受施肥量的影响,猪粪能促进磷的迁移。     

红树植物人工湿地对生活污水的净化效果

研究了潜流型海桑（Sonneratia caseolaris）人工湿地、桐花树（Aegiceras corniculatum）人工湿地和木榄（Bruguiera gymnorrhiza）人工湿地对生活污水的净化效果。一年来,3种红树植物人工湿地对BOD5、CODCr、TP、TN、NH4^＋-N和NO2^--N的平均去除率分别达到83%、71%、41%、55%、50%和84%以上。人工湿地各处理周期之间,BOD5和CODCr去除率波动较小,而TP、TN、NH4^＋-N和NO2^--N去除率波动较大。3种红树植物人工湿地对各种污染物的净化效果存在一定的差异。海桑人工湿地和桐花树人工湿地对BOD5、CODCr、TP、TN和NH4^＋-N去除率明显高于木榄人工湿地,而海桑人工湿地和桐花树人工湿地相比较,除TP外,BOD5、CODCr、TN和NH4^＋-N去除率没有显著差异。人工湿地单一处理周期内,去除率随水力停留时间（HRT）的延长而增加。BOD5、CODCr、TN和NH4^＋-N在HRT为1d和2d的去除率分别为HRT为3d去除率的54%-65%和73%-84%,NO2^--N在HRT为1d和2d的去除率分别达到了HRT为3d的70%-81%和85%-94%,而TP在HRT为1d和2d的去除率分别只有HRT为3d的39%-50%和65%-74%。另外,红树植物人工湿地与风车草（Cyperus alternifoliu）人工湿地相比,前者的BOD5、CODCr、TP、TN和NH4^＋-N去除率明显小于后者（P〈0.05）。总体上看,3种红树植物人工湿地对生活污水的净化效果呈现海桑人工湿地≈桐花树人工湿地〉木榄人工湿地。     

水曲柳幼苗根系在不同浓度NH4NO3溶液中水流导度的变化

 水分吸收过程是根系重要的生理过程。水孔蛋白在根系水分径向运输中起着重要的作用,根系水流导度（Lp）的测定是研究水孔蛋白的重要途径。该研究采用压力流的方法,对相同生长条件下的水曲柳(Fraxinus mandshurica)幼苗根系进行研究,测定了根系在去离子水和不同浓度NH4NO3溶液中的Lp。结果表明：未经处理的水曲柳幼苗根系,Lp随NH4NO3浓度的增加而上升,而且NH4NO3 溶液中的Lp比去离子水中的Lp平均高77％;经HgCl2处理后,水曲柳幼苗根系的Lp仍然随NH4NO3浓度的增加而增大,但是根系Lp在去离子水下降了22％,而在NH4NO3溶液中下降了68％,与以前的研究相比发现,经HgCl2处理后,以营养液为吸水基质的根系Lp的降低值普遍高于以去离子水为基质的试验。因此,基质中养分离子的存在对根系中水孔蛋白活性产生了重要的影响,进而影响根系水分的吸收过程。     

两种微生物菌剂对西番莲果渣高温堆肥腐熟进程的影响

研究了在西番莲果渣堆肥体系中加入两种微生物菌剂（福贝和榕风）后的温度、C／N、NH4^＋ -N和NO3^- -N的动态变化及对西番莲果渣堆肥产品品质的影响．结果表明，在西番莲果渣中加入微生物菌剂能增加高温分解持续时间，加快物料C／N降低的速率，促进NH4^＋ -N向NO3^- -N转化，加快西番莲果渣堆肥腐熟化进程．添加福贝和榕风菌剂后，堆肥高温持续时间分别比对照（4d）增加7d和8d；腐熟后堆肥的NO3^- -N浓度分别比对照增加58．0％和64．2％．添加菌种显著增加了西番莲果渣堆肥的N、P、K养分含量，降低了堆肥容重，提高了堆肥总孔隙度和持水孔隙度，改善了堆肥产品的品质．两种菌剂间对西番莲果渣高温腐熟进程的影响没有显著差异，但福贝菌剂更有利于改善堆肥品质．     

PS1沼泽红假单胞菌对集约化对虾养殖废水的净化作用

应用光合细菌PS1——沼泽红假单胞菌（Rhodopseudomonas palustris）净化集约化对虾养殖废水,探讨不同温度、不同菌浓度下PS1对养殖废水的净化效果。研究结果表明：PS1可有效降低对虾养殖废水中的COD、NH4^＋-N、NO3^-N、PO4^3--P,但对NO2^--N无降解效果,反而使之持续升高;PS1对养殖废水96h的降解率受温度和添加菌浓度的影响显著（P〈0．05）。当温度为26℃时,PS1对废水的降解活性较好;不同菌浓度组间的净化效果差异明显（P〈0．05）,综合净化效果,以12．5×10^5 CFU／ml的菌浓度为宜。     

控释肥料对稻田氧化亚氮排放的影响

采用静态箱法研究了控释肥料和常规肥料处理对华南赤红壤发育的稻田N2O排放的影响．结果表明,施用控释肥处理与非包膜复合肥处理,在水稻移栽后10d内水层中NH4^+-N和NO3^--N浓度问差异达极显著水平,各处理水层中NO3^--N浓度与2d后或当天N2O排放量间的偏相关系数达极显著水平．包膜型控释肥比未包膜复合肥能极显著地降低稻田N2O的排放量．在施肥后100d内,控释肥的N2O累积排放量仅为未包膜型复合肥料的13．45％～21．26％,是尿素处理的71．17％～112．47％．复合肥处理的N2O排放主要集中在施肥后1～25d和水稻晒田期间,控释肥在此时期的排放量显著降低,尿素处理则延缓并减小了N2O排放峰．控释肥一次施用和尿素分次施用都能减少N2O排放．     

Drought-induced root aerenchyma formation restricts water uptake in rice seedlings supplied with nitrate

Previous studies demonstrated that ammonium nutrition results in higher water uptake rate than does nitrate nutrition under water stress, and thus enhances the tolerance of rice plants to water stress. However, the process by which water uptake is related to nitrogen form under water stress remains unknown. A hydroponic experiment with simulated water stress induced by polyethylene glycol (PEG6000) was conducted in a greenhouse to study the relationship between root aerenchyma formation and water uptake rate, such as xylem sap flow rate and hydraulic conductance, in two different rice cultivars (cv. 'Shanyou 63' hybrid indica and cv. 'Yangdao 6' indica, China). The results showed that root aerenchyma tissue increased in water-stressed plants of both cultivars fed by nitrate. No significant difference was found in root hydraulic conductivity and/or xylem sap flow rate between the two rice cultivars fed by ammonium regardless of water status, whereas these parameters decreased significantly in water-stressed plants fed by nitrate. It was concluded that aerenchyma that formed in the root cortex impeded the radial transport of water in the root cylinder and decreased water uptake in water-stressed rice plants fed by nitrate. Water transport occurred mainly through Hg-sensitive water channels in rice roots supplied with ammonium.     

Effects of Local Nitrogen Supply on Water Uptake of Bean Plants in a Split Root System

To study the effects of local nitrogen supply on water and nutrient absorption, French bean （Phaseolus vulgaris L.） plants were grown in a split root system. Five treatments supplied with different nitrogen forms were compared： homogeneous nitrate （NN） and homogenous ammonium （AA） supply, spatially separated supply of nitrate and ammonium （NA）, half of the root system supplied with N-free nutrient solution, the other half with either nitrate （NO） or ammonium （AO）. The results showed that 10 d after onset of treatments, root dry matter （DM） in the nitratesupplied vessels treated with NA was more than two times higher than that in the ammonium-supplied vessels. Water uptake from the nitrate-supplied vessels treated with NA was 281% higher than under ammonium supply. In treatments NO and AO, the local supply of N resulted in clearly higher root DM, and water uptake from the nitratesupplied vessels was 82% higher than in the -N vessels. However, in AO plants, water uptake from the -N nutrient solution was 129% higher than from the ammonium-supplied vessels. This indicates a compensatory effect, which resulted in almost identical rates of total water uptake of treatments AA and AO, which had comparable shoot DM and leaf area. Ammonium supply reduced potassium and magnesium absorption. Water uptake was positively correlated with N, Mg and K uptake.     

Influence of low air humidity and low root temperature on water uptake, growth and aquaporin expression in rice plants

The effects of low air humidity and low root temperature (LRT) on water uptake, growth and aquaporin gene expression were investigated in rice plants. The daily transpiration of the plants grown at low humidity was 1.5- to 2-fold higher than that at high humidity. LRT at 13°C reduced transpiration, and the extent was larger at lower humidity. LRT also reduced total dry matter production and leaf area expansion, and the extent was again larger at lower humidity. These observations suggest that the suppression of plant growth by LRT is associated with water stress due to decreased water uptake ability of the root. On the other hand, the net assimilation rate was not affected by low humidity and LRT, and water use efficiency was larger for LRT. We found that low humidity induced coordinated up-regulation of many PIP and TIP aquaporin genes in both the leaves and the roots. Expression levels of two root-specific aquaporin genes, OsPIP2;4 and OsPIP2;5, were increased significantly after 6 and 13 d of LRT exposure. Taken together, we discuss the possibility that aquaporins are part of an integrated response of this crop to low air humidity and LRT.     

Cold Stress-Induced Acclimation in Rice is Mediated by Root-Specific Aquaporins

Cold acclimation process plays a vital role in the survival of chilling- and freezing-tolerant plants subjected to cold temperature stress. However, it remains elusive whether a cold acclimation process enhances root water uptake (a component of chilling tolerance) in chilling-sensitive crops such as rice. By analyzing the root hydraulic conductivity under cold stress for a prolonged time, we found that cold stress induced a gradual increase in root osmotic hydraulic conductivity [Lp(r(os))]. Compared with the control treatment (roots and shoots at 25°C), low root temperature (LRT) treatment (roots at 10°C; shoots at 25°C) dramatically reduced Lp(r(os)) within 1 h. However, Lp(r(os)) gradually increased during prolonged LRT treatment and it reached 10-fold higher values at day 5. Moreover, a coordinated up-regulation of root aquaporin gene expression, particularly OsPIP2;5, was observed during LRT treatment. Further, comparison of aquaporin gene expression under root-only chilling (LRT) and whole-plant chilling conditions, and in the roots of intact plants vs. shootless plants, suggests that a shoot to root signal is necessary for inducing the expression of aquaporin genes in the root. Collectively, these results demonstrate that a cold acclimation process for root water uptake functions in rice and is possibly regulated through aquaporins.     

Nitrate Uptake by Manganese-Deficient Lemon Plants

The uptake of nitrate and water was followed in Eureka lemon (Citrus limon (L.) Burm. f.) plants grown in solution culture in a greenhouse under short (3–6 months) and long-term (22–24 months) Mn-nutrition stress. Uptake was determined from depletion in the nutrient solution. Under short-term stress, manganese-deficient plants absorbed 14.5% more nitrate and 3.4% more water than the control plants, on a weight basis. Under long-term stress there was a three-fold increase in nitrate and a two-fold increase in water uptake in the Mn-deficient plants. The intensive nitrate uptake under Mn-deficiency stress was more spectacularly demonstrated in plants which were exposed also to low nitrogen supply. The low-nitrogen Mn-deficient plants absorbed more nitrate, had less stunted growth and developed fewer visible symptoms of both N and Mn deficiencies than high-nitrogen Mn-deficient plants.     

Upland rice and lowland rice exhibited different PIP expression under water deficit and ABA treatment

Aquaporins play a significant role in plant water relations. To further understand the aquaporin function in plants under water stress, the expression of a subgroup of aquaporins, plasma membrane intrinsic proteins （PIPs）, was studied at both the protein and mRNA level in upland rice （Oryza sativa L. cv. Zhonghan 3） and lowland rice （Oryza sativa L. cv. Xiushui 63） when they were water stressed by treatment with 20% polyethylene glycol （PEG）. Plants responded differently to 20% PEG treatment. Leaf water content of upland rice leaves was reduced rapidly. PIP protein level increased markedly in roots of both types, but only in leaves of upland rice after 10 h of PEG treatment. At the mRNA level, OsPIP1,2, OsPIP1,3, OsPIP2;1 and OsPIP2;5 in roots as well as OsPIP1,2 and OsPIP1;3 in leaves were significantly up-regulated in upland rice, whereas the corresponding genes remained unchanged or down-regulated in lowland rice. Meanwhile, we observed a significant increase in the endogenous abscisic acid （ABA） level in upland rice but not in lowland rice under water deficit. Treatment with 60 μM ABA enhanced the expression of OsPIP1;2, OsPIP2;5 and OsPIP2;6 in roots and OsPIP1;2, OsPIP2;4 and OsPIP2;6 in leaves of upland rice. The responsiveness of PIP genes to water stress and ABA were different, implying that the regulation of PIP genes involves both ABA-dependent and ABA-independent signaling oathways during water deficit.     

硅和干旱胁迫对水稻叶片光合特性和矿质养分吸收的影响

硅被认为是植物生长的有益元素,它能增强植物对非生物逆境和生物逆境胁迫的抗性。以抗旱性不同的一对水稻近等基因系w-14-和w-20为实验材料,采用盆栽实验,研究了干旱胁迫下硅处理对水稻生长性状、光合生理特性和矿质养分吸收的影响。结果表明,在正常水分条件下硅处理对水稻的生长及生理特性没有明显影响。干旱胁迫显著降低水稻植株的生长,叶绿素含量、叶绿素荧光参数Fv/Fm及Fv/F0值显著降低,光合作用受到明显抑制。加硅能提高干旱胁迫条件下水稻植株的生物量、水分利用效率、叶片叶绿素含量、净光合速率和蒸腾速率,而气孔导度和细胞间隙CO2浓度则下降。无论干旱与否,施硅后水稻的叶片硅含量均显著上升。两个水稻品系叶片的无机离子含量在干旱胁迫条件下均呈显著增加的趋势,而硅处理后材料w-14的叶片K+、Na+、Ca2+、Mg2+、Fe3+含量分别降低16.38%,24.50%,19.70%,21.52%,18.58%,w-20则分别降低11.64%,12.11%,16.06%,11.11%和19.15%,并使之回复到与对照更接近的水平。研究结果表明了硅提高水稻植株的抗旱性与光合作用的改善和矿质养分的调节有关。     

丛枝菌根真菌通过上调根系及自身水孔蛋白基因表达提高玉米抗旱性

 在模拟干旱条件下, 研究了接种丛枝菌根(AM)真菌Glomus intraradices对玉米(Zea mays)根部13种质膜水孔蛋白基因表达的影响, 同时观测了AM真菌自身水孔蛋白基因的表达情况。结果表明, 干旱条件下, 除Zm PIP1;3、Zm PIP1;4、Zm PIP1;5和Zm PIP2;2之外的接种处理能显著提高根部其他8种质膜水孔蛋白基因的表达(Zm PIP2;7表达量未检测出), 并且AM真菌菌丝中水孔蛋白基因GintAQP1表达也显著增强。与此同时, 接种处理明显改善了植物水分状况, 提高了叶片水势。AM真菌增强宿主植物根部及自身的水孔蛋白基因的表达对于提高植物抗旱性具有潜在的重要贡献。     

Expression and inhibition of aquaporins in germinating Arabidopsis seeds

Extensive and kinetically well-defined water exchanges occur during germination of seeds. A putative role for aquaporins in this process was investigated in Arabidopsis. Macro-arrays carrying aquaporin gene-specific tags and antibodies raised against aquaporin subclasses revealed two distinct aquaporin expression programs between dry seeds and young seedlings. High expression levels of a restricted number of tonoplast intrinsic protein (TIP) isoforms (TIP3;1 and/or TIP3;2, and TIP5;1) together with a low expression of all 13 plasma membrane aquaporin (PIP) isoforms was observed in dry and germinating materials. In contrast, prevalent expression of aquaporins of the TIP1, TIP2 and PIP subgroups was induced during seedling establishment. Mercury (5 microM HgCl(2)), a general blocker of aquaporins in various organisms, reduced the speed of seed germination and induced a true delay in maternal seed coat (testa) rupture and radicle emergence, by 8-9 and 25-30 h, respectively. Most importantly, mercury did not alter seed lot homogeneity nor the seed germination developmental sequence, and its effects were largely reversed by addition of 2 mM dithiothreitol, suggesting that these effects were primarily due to oxidation of cell components, possibly aquaporins, without irreversible alteration of cell integrity. Measurements of water uptake in control and mercury-treated seeds suggested that aquaporin functions are not involved in early seed imbibition (phase I) but would rather be associated with a delayed initiation of phase III, i.e. water uptake accompanying expansion and growth of the embryo. A possible role for aquaporins in germinating seeds and more generally in plant tissue growth is discussed.