紫花苜蓿不同种植布局对苹果害虫及其天敌的影响

为探究紫花苜蓿不同种植布局对苹果园害虫及天敌的影响,在山东省沂水市苹果园设置了紫花苜蓿逐行、隔1行和隔2行种植的布局方式,以自然生草区为对照,系统调查了4种生草方式苹果园果树上和生草上害虫及天敌的发生动态。结果表明:害虫的调查总量,紫花苜蓿逐行种植区最少,比隔1行种植区少20.29%,比隔2行种植区少48.53%,比自然生草区少49.91%;苹果树上天敌的调查总量,紫花苜蓿隔1行种植区最多,是逐行种植区的1.13倍、隔2行种植区的1.29倍、自然生草区的1.78倍;生草上天敌的调查总量,紫花苜蓿逐行种植区最多,是隔1行种植区的1.05倍、隔2行种植区的1.19倍、自然生草区的1.66倍;益害比方面,紫花苜蓿逐行种植区和隔1行种植区的益害比明显高于其他生草区。综合防治效果和种植成本,紫花苜蓿隔1行种植的布局方式更合理。     

外源lea3基因转化紫花苜蓿的研究

将来源于大麦的lea3基因通过基因枪法导入紫花苜蓿栽培品种“中苜一号”的胚性愈伤组织中,经过膦丝菌素类除草剂(PPT)的4次筛选获得抗性愈伤组织,诱导分化后共获得21株抗性再生植株。经叶片涂抹除草剂试验和lea3基因的PCR分子检测证明,lea3基因已整合到紫花苜蓿的基因组中。与对照植株相比,获得的转基因植株具有显著增强的耐盐能力,表明遗传转化lea3基因可用于苜蓿抗旱耐盐新品种的选育。     

水稻ygl80黄绿叶突变体的遗传分析与目标基因精细定位

通过化学诱变获得遗传稳定的水稻黄绿叶突变体ygl80。与野生型亲本10079相比,ygl80突变体在苗期和孕穗期叶片叶绿素分别下降76.64%和54.59%,类胡萝卜素含量分别下降53.85%和41.18%,成熟期株高、每株有效穗数、每穗着粒数、穗长和千粒重分别减少14.8%、16.5%、21.3%、9.1%和7.4%。遗传分析表明,ygl80的突变性状由1对隐性核基因控制。利用(ygl80/浙辐802) F₂作为定位群体, 将突变基因定位在第5染色体长臂InDel标记C2和C3之间,遗传距离分别为0.24 cM 和0.39 cM,两标记之间的物理距离约为90 kb,此区间内包含11个预测基因。基因组序列分析发现,ygl80突变体在编码叶绿素合酶的YGL1(LOC_Os05g28200)基因编码区第5027碱基处(位于第14外显子),碱基C突变为碱基T,使编码蛋白序列第348位的脯氨酸(Pro)突变成亮氨酸(Leu)。该基因是已报道的水稻ygl1黄绿叶突变基因的等位基因。ygl80突变体在整个生育期都表现为黄绿叶,而ygl1突变体在苗期叶片黄化,中期慢慢转绿,后期叶色以及总叶绿素和类胡萝卜素的含量接近野生型,这可能是YGL1基因编码的叶绿素合酶蛋白的氨基酸不同突变位点造成的。     

剪根稻苗移栽后叶鞘3H-同化物的运转分配特点

用3H同位素示踪方法研究了剪根稻苗移栽后叶鞘同化物的运转分配特点。结果表明,剪根处理稻苗各器官干重均低于对照,而3H-同化物的比活度却高于对照,标记后10d多数器官高出对照1倍左右,分蘖高2倍,新根高4倍。剪根处理发根节和新根的放射性总活度和3H-同化物的分配比例均高于对照,意味着其新根的发生更加依赖于主茎叶鞘物质输出。     

Methane emission from two Indian soils planted with different rice cultivars

In a greenhouse study, methane emissions were measured from two diverse Indian rice-growing soils planted to five rice cultivars under similar water regimes, fertilizer applications and environmental conditions. Significant variations were observed in methane emitted from soils growing different cultivars. Total methane emission varied between 8.04 and 20.92gm^–2 from IARI soil (Inceptisol) and between 1.47 and 10.91gm^–2 from Raipur soil (Vertisol) planted to rice. In all the cultivars, emissions from IARI soil were higher than from Raipur soil. The first methane flux peak was noticed during the reproductive phase and the second peak coincided with the grain-ripening stage of the rice cultivars. Received: July 7, 1996     

Evolution of dinitrogen and nitrous oxide from the soil to the atmosphere through rice plants

Summary It is commonly assumed that a large fraction of fertilizer N applied to a rice (Oryza sativa L.) field is lost from the soil-water-plant system as a result of denitrification. Direct evidence to support this view, however, is limited. The few direct field, denitrification gas measurements that have been made indicate less N loss than that determined by ¹⁵N balance after the growing season. One explanation for this discrepancy is that the N₂ produced during denitrification in a flooded soil remains trapped in the soil system and does not evolve to the atmosphere until the soil dries or is otherwise disturbed. It seems likely, however, that N₂ produced in the soil uses the rice plants as a conduit to the atmosphere, as does methane. Methane evolution from a rice field has been demonstrated to occur almost exclusively through the rice plants themselves. A field study in Cuttack, India, and a greenhouse study in Fort Collins, Colorado, were conducted to determine the influence of rice plants on the transport of N₂ and N₂O from the soil to the atmosphere. In these studies, plots were fertilized with 75 or 99 atom % ¹⁵N-urea and ¹⁵N techniques were used to monitor the daily evolution of N₂ and N₂O. At weekly intervals the amount of N₂+N₂O trapped in the flooded soil and the total-N and fertilized-N content of the soil and plants were measured in the greenhouse plots. Direct measurement of N₂+N₂O emission from field and greenhouse plots indicated that the young rice plant facilitates the efflux of N₂ and N₂O from the soil to the atmosphere. Little N gas was trapped in the rice-planted soils while large quantities were trapped in the unplanted soils. N losses due to denitrification accounted for only up to 10% of the loss of added N in planted soils in the field or greenhouse. The major losses of fertilizer N from both the field and greenhouse soils appear to have been the result of NH₃ volatilization.     

覆膜旱作稻N、P、K养分利用特征

在田间试验条件下对覆膜旱作稻体内N、P、K养分浓度、吸收动态及N肥利用率作了研究。结果表明,相同施肥处理条件下不同生育期覆膜旱作稻N、P、K养分浓度及吸收量均高于水作稻,尤以生育中后期较为明显;覆膜旱作稻全生育期N、P、K养分吸收量明显高于水作稻,分布在籽粒中的N、P、K养分含量也有所提高,而在整株中的占有率差异不大,N肥利用率提高12%左右。     

Genotypic variation in grain cadmium concentration of lowland rice

Cadmium (Cd) contamination of paddy rice soils is commonly observed in the Yangtse River Delta, China. Large Cd uptake by rice plants and its translocation into the grains can entail human‐health risks. Genotypic variations in Cd uptake and a differential Cd partitioning into grains will be the basis for developing a rice screening or breeding tool for low grain Cd. A field experiment, conducted at the experimental farm of Jiaxing, Zhejiang province from 2002 to 2004, compared 38 rice genotypes of different types (indica vs. japonica) collected from the Yangtse River Delta. The results showed large differences in Cd concentrations in straw, brown rice, and grain chaff among the rice genotypes grown on Cd‐contaminated soil. Concentrations in brown rice ranged from 0.06 to 0.99 mg Cd kg^–1. The total Cd uptake in brown rice varied between 0.96 and 28.58 μg plant ^{– 1}. In general, indica‐type cultivars accumulated significantly more Cd than the japonica‐type cultivars. The Cd concentration in straw was highly correlated with that in brown rice. While significant differences in the Cd‐partitioning ratio (% share of total Cd uptake found in brown rice) among rice genotypes were observed, these were not correlated with Cd concentration of brown rice. This indicates that the Cd accumulation in rice grains appears to be governed mainly by the Cd uptake by the plant and probably not by differential Cd partitioning. The large genotypic variation suggests the possibility to lower the Cd content of rice by genotype selection. The development of such breeding tools should focus on low Cd uptake rather than Cd partitioning between straw and grain.     

缺钾对水稻不同品种光合和能量耗散的影响

试验测定了钾敏感型(二九丰)和钾钝感型(原丰早)两个水稻品种在缺钾处理41.d后其剑叶的生长、光合光响应曲线、叶绿素荧光参数光响应曲线和暗弛豫动力学曲线。结果表明,缺钾降低了水稻剑叶的光合作用,显著抑制了生长。但是缺钾条件下导致两个水稻品种净光合速率(Pn)下降的主导因子并不相同。在缺钾条件下,原丰早(YFZ)剑叶的Pn随气孔导度(Gs)和胞间CO2浓度(Ci)的下降而下降,但叶绿素荧光参数和叶绿素含量几乎没有变化,说明其Pn下降主要归于气孔的限制。缺钾处理41.d后,二九丰(EJF)在低光强下[500mol/(m2.s)],Pn随Gs和Ci下降,但在更强的光强下,Pn和Gs继续下降,而Ci开始上升,并在1200mol/(m2.s)处超越了对照,说明此时主导因子不单受气孔限制,还受非气孔因子限制;它的光饱和点从1200mol/(m2.s)下降到大约500mol/(m2.s);同时,其荧光参数Fv/Fm、ФPSII、qP和ETR随光强上升而迅速下降,而L(PFD)、E和PP迅速增加,NPQ在1200mol/(m2.s)光强下上升,但是在高光强下却迅速降低,甚至低于对照,而且Fm、Fv/Fm下降,Fo上升,均说明缺钾处理可能使光合机构受到了伤害,发生了光抑制。对非光化学猝灭的分析得到其中间组分qNm可能起了更大的能量耗散作用,部分激发能从PSⅡ转移到PSⅠ,降低了PSⅡ耗散能量的压力。以上结果表明,两品种对钾敏感性不同极可能也与缺钾条件下光保护能力的差异有关。     

稻米功能性成分的生理活性及其产品开发

本文就稻谷主副产品如淀粉、碎米、米糠、米胚和稻壳等中的主要功能性成分,包括抗性淀粉、γ氨基丁酸、多磷酸肌醇、谷维素、维生素E和二十八烷醇等的生理功能及富含特定功能因子产品的开发研究进展进行了简要综述,以期为开发与研制新型功能食品提供思路。