稗草阴蔽对大豆根瘤固氮速率的影响

在自控人工气候室内系统研究了稗草阴蔽对大豆根瘤固氮速度的影响，结果表明：在每盆6，12和24株稗草的阴蔽作用下，,播后44－101天期间大豆单株根瘤的平均固氮速率分别比无阴蔽对照下降了31．5，39．5和44．5％，稗草阴蔽引起大豆根瘤固氮速率下降的原因与其通过降低大豆植株的受光量及其叶片的CO2传导速率从而降低其叶片的净光合速率有关，播后43－75天期间在每盆6，12和24株稗草的阴蔽作用下，由于大豆植物的受光量分别比无阴蔽对照平均减少了32．1，39．1和43．4％，叶片的CO2传导速率分别比无阴蔽对照平均下降了14．0，16．7和19．3％，导致大豆叶片的净光合速率分别比无阴蔽对照降低了25．4，32．7和37．3％。     

大豆-根瘤菌共生体系光合与固氮关系研究

水培大豆和田间生长的大豆,接种根瘤菌 Rhizobium B16-11C 后植株全氮含量、叶片叶绿素含量和净光合速率及种子产量都明显增加。比较 Clark 大豆的结瘤品系和不结瘤品系获类似结果。摘除根瘤后3天内叶片净光合速率无明显变化。大豆植株遮阴、去叶或切掉地上部导致根瘤活性明显下降。但去豆荚不能提高根瘤固氮的比活性。根瘤活性的日变化不能用根瘤蔗糖、淀粉含量或周围温度的变化来解释,其控制因子尚待深入研究。     

水稻田稗草叶片光合作用对开放式空气CO2浓度增高(FACE)的适应

于分蘖、拔节和抽穗 3个时期在空气CO2 浓度 (380 μmol·mol-1)下测定稻田中稗草叶片的净光合速率 (Pn) ,发现在开放式CO2 浓度增高 (FACE)条件下生长的稗草叶片后 2个时期的Pn显著低于普通空气中生长的对照 ,比对照下降约 2 0 % ,说明FACE条件下稗草叶片光合作用对高CO2 浓度发生了明显的适应 .同时 ,叶片的气孔导度 (Gs)和胞间CO2 浓度 (Ci)的下降更为明显 .与对照相比 ,叶片可溶性蛋白含量明显降低 ,拔节期只有对照的 6 2 .4 % ;高CO2 浓度下生长的稗草叶片Rubisco含量也降低 ,分蘖期和拔节期分别为对照的 87%和 84 % ,但其差异未达到显著水平 .可以认为 ,长期生长在高CO2 浓度下的C4植物稗草叶片光合作用的适应是叶片气孔部分关闭和可溶性蛋白含量下降的结果 .     

CO2倍增及UV-B增强对大豆植株生长和根际微生物的影响

以大豆'齐黄27'为研究材料,采用人工气候室模拟大气CO2浓度倍增(350～700 μmol*mol-1)及紫外线B(UV-B,280～320 nm)辐射增强(4～15 μW*cm-2)的环境条件,研究了CO2浓度增加及UV-B辐射增强对大豆生育前期的生长及根瘤、根际微生物数量的影响.结果表明:(1)增强UV-B能显著减少大豆植株地上部生物量,而对株高的抑制作用不显著;CO2浓度倍增促使大豆株高和地上生物量显著增加,对根系生物量的促进作用不显著,但能够减轻UV-B辐射增强对地上及根系生物量的抑制作用;CO2浓度增加、UV-B辐射增强及其复合胁迫均导致大豆植株根冠比下降,且复合胁迫对根冠比的抑制作用更明显.(2)CO2浓度倍增降低了大豆叶片叶绿素、类胡萝卜素及花青素含量,提高了净光合速率;UV-B辐射增强导致叶绿素含量减少,光合速率下降,却增加了类胡萝卜素及花青素含量;CO2浓度增加、UV-B辐射增强复合处理对叶片色素含量及光合速率的影响具有复合效应.(3)CO2浓度倍增能够促进根瘤数量及根际真菌数量的增加,而UV-B增强处理则显著降低细菌和放线菌的数量;CO2浓度倍增能够缓解UV-B增强处理对放线菌的抑制作用,却导致根际细菌数量进一步减少.研究发现,CO2浓度增加及UV-B辐射增强对大豆生育前期植株生长、叶片色素含量及根际微生物数量存在抑制或促进效应,而且在某些性状上存在复合效应,它们可能主要是通过调节大豆植株的干物质分配及根系的代谢间接影响根瘤数量及根际微生物数量.     

缺磷条件下低分子量有机酸对大豆氮积累和结瘤固氮的影响

采用砂培方法在温室条件下研究了低分子量有机酸柠檬酸、草酸、苹果酸及3种酸的混合物对大豆植株氮素积累、结瘤和固氮的影响.结果表明：低分子量有机酸对大豆植株氮素积累有显著的抑制作用,使大豆地上部各时期氮素积累量的降低幅度分别为：苗期17.6%～44.9%,花期29.8%～88.4%,鼓粒期9.18%～69.6%,成熟期2.21%～41.7%;低分子量有机酸对大豆根瘤生长和固氮能力也有显著影响,表现为使根瘤数量、根瘤固氮酶活性和豆血红蛋白含量显著降低,降低幅度分别为11.4%～59.6%,80.5%～91.7%和11.9%～59.9%,从而使大豆的固氮效率降低,最终导致大豆的固氮量较对照显著降低(降低幅度9.71%～64.5%).低分子量有机酸对大豆氮积累、根瘤生长和固氮能力的抑制作用随浓度的增加而增加.3种有机酸中,草酸的抑制作用相对大于柠檬酸和苹果酸,3种有机酸混合后,抑制作用加强.     

高CO2浓度对红掌的生长和光合作用的影响

以开顶式塑料薄膜温室为设施,研究了红掌叶片光合速率、植株生长和光合酶活性对高CO2浓度的响应.结果表明处理30d时,处理组T1(700±100 μmol CO2 mol-1)的株高、单叶面积、株鲜重分别比对照组(大气CO2浓度360±30 μmol CO2 mol-1)增加了12.8%、2.39%、29.2%,而处理组T2(1 000±100 μmol CO2 mol-1)的株高、单叶面积、株鲜重分别比对照增加了8.7%、1.81%、27.2%.在各自处理条件下测定的T1和T2的净光合速率分别比对照增加27.0%和33.8%,且在对照条件下测定的各处理组的净光合速率也均高于对照.处理组的气孔导度与蒸腾速率下降,但却促进了叶片中可溶性糖和淀粉积累,而叶绿素含量并没有明显变化.高浓度CO2能促进Rubisco活性增加,而乙醇酸氧化酶活性则明显下降.     

水稻田稗草叶片光合作用对开放式空气CO2浓度增高(FACE)的适应

于分蘖、拔节和抽穗3个时期在空气CO₂浓度(380μmol·mol^-1)下测定稻田中稗草叶片的净光合速率(Pn),发现在开放式CO₂浓度增高(FACE)条件下生长的稗草叶片后2个时期的Pn显著低于普通空气中生长的对照,比对照下降约20%,说明FACE条件下稗草叶片光合作用对高CO₂浓度发生了明显的适应.同时,叶片的气孔导度(Gs)和胞间CO₂浓度(Ci)的下降更为明显.与对照相比,叶片可溶性蛋白含量明显降低,拔节期只有对照的62.4%;高CO₂浓度下生长的稗草叶片Rubisco含量也降低,分蘖期和拔节期分别为对照的87%和84%,但其差异未达到显著水平.可以认为,长期生长在高CO₂浓度下的C₄植物稗草叶片光合作用的适应是叶片气孔部分关闭和可溶性蛋白含量下降的结果.     

水分和光照对厚皮甜瓜苗期植株生理生态特性的影响

以厚皮甜瓜‘西博洛托’为试材,研究了温室内育苗基质含水量和光照强度对厚皮甜瓜苗期植株生长发育和生理生态特性的影响.结果表明:不同基质含水量和光照强度对厚皮甜瓜苗期植株生长发育影响显著,随基质含水量的降低,苗期植株叶绿素a、叶绿素b和总叶绿素含量升高,叶片相对含水量和比叶面积下降,基质含水量为60%～80%时,幼苗净光合速率最高;随着光照强度的减弱,幼苗的叶绿素a、叶绿素b、总叶绿素含量以及叶片相对含水量、比叶面积和胞间CO2浓度升高,叶绿素a/b和净光合速率下降.在不同处理中,以80%基质含水量 100%温室光照处理的幼苗生长最健壮,壮苗指数、净光合速率等指标最高.     

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.     

结荚期短期干旱和复水对大豆（Glycine max）叶片光合和产量的影响

以大豆为研究对象,研究结荚期土壤水分的短期变动对大豆叶片光合生理生态以及最后产量形成的影响.研究发现,与叶片的水分状况相比,大豆的叶片气孔对土壤水分的匮缺更加敏感,在实验的第2天,处理组叶片气孔导度降为对照的24.9%(P＜0.01),但是叶片水势和对照相差不显著(P＞0.05);随着土壤干旱的进行,处理组叶片的净光合速率、蒸腾速率等都显著下降,但ФPSⅡ只有在第3天才出现显著的下降.复水后第3天,净光合速率比对照高24.3%(P＜0.01),表现出了明显的旱后超补偿效应;研究发现,结荚期即使短期的土壤水分干旱,也会对大豆后期的生物量的分配产生较大的影响,使处理组的豆干重降低13.9%(P＜0.01),根茎比增加35.3%(P＜0.05),收获指数减少17.4%(P＜0.05).     

应用差异蛋白质组学方法分析作物化感作用的分子机理

试验旨在分析运用分子标记技术(QTL)和差异蛋白组学技术研究作物化感作用分子机理的差异性。首先运用差异蛋白组学技术探讨在生物胁迫(稗草)下水稻化感作用潜力变化的内在分子机理。分别用稗草和水稻的根系分泌物培养切自一株5叶龄化感水稻P I312777植株并经恢复的2个分蘖。7d后,提取处理和对照相同叶位叶片的全蛋白质并进行双向电泳,每张电泳胶片上获得800多个电泳胶点,其中差异表达的蛋白质点有4个。采用M ALD I-TOF-M S对各差异蛋白质点进行肽质量指纹图谱分析,经过SW ISS-PROT数据库查询,结果表明化感水稻P I312777在稗草胁迫下的特异蛋白分别与苯丙氨酸氨解酶(PAL)、硫还原型蛋白(T rx-m)、3-羟基-3-甲基戊二酰辅酶A还原酶(HM GR)和过氧化物酶(POD)相匹配。根据编码以上4个差异蛋白质的DNA序列,发现编码以上4个差异蛋白的基因分别位于水稻染色体4、7、8和12上的特定克隆位点,这就是与化感作用相关基因。前人也运用QTL方法开展作物化感作用的分子机理研究,但由于所采用的供体材料、受体植物及对表型性状的评价方法等的不同,定位结果存在较大的差异。综合比较两种方法后认为,运用差异蛋白组学技术分析水稻化感作用的分子机理,比QTL技术更加直接和深入。因为比较胁迫处理和对照植物组织的2-DE图谱将能鉴定出由表达候选基因编码的胁迫蛋白质,氨基酸残基序列的测定将揭示那些功能与胁迫性状密切相关的蛋白质,这种编码的基因就是兼具功能与表达的候选基因。     

Soybean leaf growth and gas exchange response to drought under carbon dioxide enrichment

This study was conducted to determine the response in leaf growth and gas exchange of soybean (Glycine max Merr.) to the combined effects of water deficits and carbon dioxide (CO₂) enrichment. Plants grown in pots were allowed to develop initially in a glasshouse under ambient CO₂ and well-watered conditions. Four-week old plants were transferred into two different glasshouses with either ambient (360 μmol mol^-1) or elevated (700 μmol mol^-1) CO₂. Following a 2-day acclimation period, the soil of the drought-stressed pots was allowed to dry slowly over a 2-week period. The stressed pots were watered daily so that the soil dried at an equivalent rate under the two CO₂ levels. Elevated [CO₂] decreased water loss rate and increased leaf area development and photosynthetic rate under both well-watered and drought-stressed conditions. There was, however, no significant effect of [CO₂] in the response relative to soil water content of normalized leaf gas exchange and leaf area. The drought response based on soil water content for transpiration, leaf area, and photosynthesis provide an effective method for describing the responses of soybean physiological processes to the available soil water, independent of [CO₂].     

开放式空气CO2浓度增高条件下C3作物(水稻)与C4杂草(稗草)的竞争关系

通过田间试验,研究了FACE(开放式空气CO₂浓度升高)条件下C₃作物水稻(Oryza sativa)和C₄杂草稗草(Echinochloa crusgalli)的生长和竞争关系.结果表明,FACE条件下C₃植物水稻生物量和产量增加,叶片数增加,分蘖数增加,叶面积系数(LAI)增大;而C₄植物稗草相反.FACE条件下水稻和稗草叶面积均减少,而净同化率(NAR)均增加.FACE条件下水稻稗草比例为1:1时,水稻与稗草的生物量比率、产量比率、LAI比率、茎蘖比率和NAR比率均增加,水稻稗草的竞争关系发生变化,水稻(C₃植物)竞争能力增加,稗草(C₄植物)竞争能力下降.     

Effects of doubled atmospheric carbon dioxide concentration on the responses of assimilation and conductance to humidity

Experiments were performed to determine if growth at elevated partial pressure of CO₂ altered the sensitivity of leaf water vapour conductance and rate of CO₂ assimilation to the leaf-to-air difference in the partial pressure of water vapour (Δw). Comparisons were made between plants grown and measured at 350 and 700 μPa Pa^?1 partial pressures of CO₂ for amaranth, soybean and sunflower grown in controlled environment chambers, soybean grown outdoors in pots, and orchard grass grown in field plots. In amaranth, soybean and orchard grass, both the absolute and the relative sensitivity of conductance to Δw at the leaf surface were less in plants grown and measured at the elevated CO₂. In sunflower, there was no change in the sensitivity of conductance to Δw for the two CO₂ partial pressures. Tests in soybeans and amaranth showed that the change in sensitivity resulted from elevated CO₂ during the measurement of the Δw response. Assimilation rate of CO₂ was not altered by Δw in amaranth, which has C₄ metabolism. In sunflower, the assimilation rate of plants grown and measured at elevated CO₂ was insensitive to Δw, consistent with the response of assimilation rate to intercellular CO₂ partial pressure in the prevailing range. In soybean, the sensitivity of assimilation rate to Δw was not different between CO₂ treatments, in contrast to what would be expected from the response of assimilation rate to intercellular CO₂ partial pressure.     

Root restriction as a factor in photosynthetic acclimation of cotton seedlings grown in elevated carbon dioxide

Interactive effects of root restriction and atmospheric CO₂ enrichment on plant growth, photosynthetic capacity, and carbohydrate partitioning were studied in cotton seedlings (Gossypium hirsutum L.) grown for 28 days in three atmospheric CO₂ partial pressures (270, 350, and 650 microbars) and two pot sizes (0.38 and 1.75 liters). Some plants were transplanted from small pots into large pots after 20 days. Reduction of root biomass resulting from growth in small pots was accompanied by decreased shoot biomass and leaf area. When root growth was less restricted, plants exposed to higher CO₂ partial pressures produced more shoot and root biomass than plants exposed to lower levels of CO₂. In small pots, whole plant biomass and leaf area of plants grown in 270 and 350 microbars of CO₂ were not significantly different. Plants grown in small pots in 650 microbars of CO₂ produced greater total biomass than plants grown in 350 microbars, but the dry weight gain was found to be primarily an accumulation of leaf starch. Reduced photosynthetic capacity of plants grown at elevated levels of CO₂ was clearly associated with inadequate rooting volume. Reductions in net photosynthesis were not associated with decreased stomatal conductance. Reduced carboxylation efficiency in response to CO₂ enrichment occurred only when root growth was restricted suggesting that ribulose-1,5-bisphosphate carboxylase/oxygenase activity may be responsive to plant source-sink balance rather than to CO₂ concentration as a single factor. When root-restricted plants were transplanted into large pots, carboxylation efficiency and ribulose-1,5-bisphosphate regeneration capacity increased indicating that acclimation of photosynthesis was reversible. Reductions in photosynthetic capacity as root growth was progressively restricted suggest sink-limited feedback inhibition as a possible mechanism for regulating net photosynthesis of plants grown in elevated CO₂.     

开放式空气CO2浓度增高条件下C3作物(水稻)与C4杂草(稗草)的竞争关系

通过田间试验,研究了FACE（开放式空气CO2浓度升高）条件下C3作物水稻（Oryza sativa）和C4杂草稗草（Echinochloa crusgalli）的生长和竞争关系,结果表明,FACE条件下C3植物水稻生物量和产量增加,吉片数增加,分蘖数增加,叶面积系数（LAI）增大;而C4植物稗草相反,FACE条件下水稻和稗草中面积均减少,而净同化率（NAR）均增加;FACE条件下水稻-稗草比例为1：1时,水稻与稗草的生物量比率、产量比率、LAI比率、茎蘖比率和NAR比率均增加,水稻-稗草的竞争关系发生变化,水稻（C3植物）竞争能力增加,稗草（C4植物）竞争能力下降。     

Identifying soybean lines differing in gas exchange sensitivity to humidity

The ratios of root length and root weight to leaf area differed within and between cultivars of soybean. Plants with low ratios of root length or weight to leaf area had leaf conductances and net photosynthetic rates more reduced by a given increase in the leaf to air water vapour pressure difference around a single leaf than plants with high ratios. Plant and root system conductances to water were estimated as transpiration rate per unit leaf area divided by the difference between substrate and leaf water potentials, and by the rate of water flow through pressurised root systems. These conductances were greater in plants with large, as compared with small, root systems per unit leaf area. Cultivar rankings in sensitivity of gas exchange to humidity were consistent in controlled environment chambers and in field tests.     

Enhanced N-Transfer from a Soybean to Maize by Vesicular Arbuscular Mycorrhizal (VAM) Fungi

Using a split-root technique, roots of soybean plants were divided between two pots. In one of the two pots, two maize plants were grown and half of those pots were inoculated with the vesicular arbuscular mycorrhizal (VAM) fungus, Glomus fasciculatus. Fifty-two days after planting, ¹⁵N-labeled ammonium sulfate was applied to the pots which contained only soybean roots. Forty-eight hours after application, significantly higher values for atom per cent ¹⁵N excess were found in roots and leaves of VAM-infected maize plants as compared with the non-VAM-infected maize plants. Results indicated that VAM fungi did enhance N transfer from one plant to another.     

四倍体稗草的组织培养与快速繁殖

以筛选得到的四倍体稗草成熟胚作为外植体,进行了组织培养与快速繁殖技术的研究。结果表明:最佳外植体消毒方式为70%乙醇浸泡30 s+0.1%(w/v)的升汞消毒15 min。最佳诱导培养基为MS盐、DL维生素+2.5 mg/L 2,4-D+300 mg/L谷氨酰胺+500 mg/L脯氨酸+3%麦芽糖。将愈伤组织转入分化培养基(MS+50 mg/L肌醇+1.0 mg/L 6-BA+0.2 mg/L KT+0.5 mg/L NAA+0.25 mg/L IAA+3%麦芽糖)上,培养20 d后超过70%的愈伤组织分化成苗。将3-5 cm长的分化苗转入1/2 MS生根培养基进行生根培养。炼苗后,移入营养土与珍珠岩(2∶1)的基质中,移栽成活率高达90%以上。该体系的建立为稗草抗除草剂基因的功能验证提供了前提条件。     

稗属杂草对水稻生长发育和产量的影响

以新两优6号(籼稻)和南粳46(粳稻)为材料,自水稻移栽至成熟分别与无芒稗(T₁)、稗(T₂)、西来稗(T₃)和光头稗(T₄)共生,稗草密度为6株·m^-2,以无稗草水稻处理为对照,研究不同稗草对水稻生长发育和产量的影响.结果表明：与对照相比,不同稗草对水稻的干扰表现不同,T₁、T₂、T₃处理使籼稻产量分别下降19.2%、10.8%、21.9%,使粳稻产量分别下降39.7%、25.3%、47.3%,但T₄处理对2个水稻品种的产量均无显著影响.水稻和稗草共生过程中,T₁、T₂和T₃处理显著降低了水稻成熟期的干物质积累量及灌浆期的剑叶光合速率、根系氧化力和籽粒ATP酶活性,降低幅度为T₃>T₁>T₂,T₄处理与对照差异不显著;各处理对水稻最终分蘖数和株高均无显著影响.表明4种稗草对水稻生长的影响由强到弱表现为：T₃>T₁>T₂>T₄,稻 稗共生时水稻剑叶光合速率、根系氧化力和籽粒ATP酶活性降低是导致水稻生产力下降的重要原因.