脲酶/硝化抑制剂配施氮肥对春玉米农田氨排放的影响

通过两年田间定位试验,探讨脲酶/硝化抑制剂配施氮肥在黑土区玉米体系中的氨减排及氮素增效效果。设置两种耕作模式(条耕和旋耕)和3种氮肥类型(常规尿素、添加脲酶抑制剂尿素、添加硝化抑制剂尿素)。结果表明,条耕产量和氮素利用率分别为8 631 kg/hm2和33.4%,明显低于旋耕;氨挥发总量为20.6 kg/hm2,明显高于旋耕。脲酶/硝化抑制剂配施氮肥的产量和氮素利用率分别为10 737 kg/hm2和46.0%,较常规尿素分别提高25.6%和23.6%;土壤氨挥发累积量为18.6 kg/hm2,明显低于常规尿素。抑制剂类型显著影响氨排放,添加脲酶抑制剂尿素低于添加硝化抑制剂尿素。相同氮素投入条件下,添加脲酶/硝化抑制剂尿素在土壤条耕和旋耕模式下均可实现增产增效及氨减排效果,且添加脲酶抑制剂尿素具有较好的氨减排效果。     

Effects of preemergence and postemergence herbicides on urea hydrolysis and nitrification of urea nitrogen in soil

The influence of 5 and 50 mg active ingredient kg^-1 soil of nine preemergence and nine postemergence herbicides on transformations of urea N in soil was studied in samples of two coarse-textured and two fine-textured soils incubated aerobically at 20°C. The effects of each herbicide on soil urea transformations was measured by determining the amounts of urea hydrolyzed and the amounts of NO _inf3 ^sup- and NO _inf2 ^sup- produced at various times after treatment with urea. Applied at the rate of 5 mg active ingredient kg^-1 soil, none of the herbicides retarded urea hydrolysis in the four soils used, but four of the postemergence herbicides (acifluorfen, diclofop methyl, fenoxaprop ethyl) retarded urea hydrolysis in the two coarse-textured soils. All the herbicides tested except siduron retarded nitrification in the two coarse-textured soils when applied at 50 mg of urea N active ingredient kg^-1 soil, and fenoxaprop ethyl and tridiphane markedly retarded nitrification of urea N in all four of the soils when applied at this rate. One-way analysis of variance and correlation analyses indicated that the inhibitory effects of the 18 herbicides tested on nitrification of urea N in soil increased with a decrease in the organic-matter content and an increase in the sand content of the soil. Present address: Department of Soil and Environmental Sciences, University of California, Riverside, CA 92521, USA     

一类新型植物生长延缓剂的作用机理及其应用

含有降冰片烯二氮杂环丁烯、三唑、嘧啶、吡啶和咪唑类结构的一类新型植物生长延缓剂,其共同的特征是在分子内杂环中的 sp~2杂化 N 上具有一对孤对电子。这对孤对电子作为第六配体结合到细胞色素 P-450内血红素铁上,代替了催化反应中所需的氧,导致某些依赖细胞色素P-450的单氧酶失活,并因此影响与 GA,ABA 和甾醇等有关的代谢途径,进而调节植物的生长和发育过程。因此,这类植物生长延缓剂在农林和园艺等方面具有广泛的应用前景。     

The Effects of Different Fertilizing Methods on Nitrification and Denitrification in Black Soil in Songnen Plain

The paper compared the effects of application of farm manure with chemical fertilizers on nitrification and denitrification in black soil, the result showed that the numbers of nitrobacterias and denitrobacterias in farm manure treatment were both higher than that of other treatments. The intensity of denitrification in chemical treatment was higher than that of manure treatment. The content of organic matter in soil was correlated with the intensity of nitrification and denitrification, and the coefficients were resnectively 0.9981 and 0.8693.     

几丁质合成抑制剂类杀虫剂的发展和应用

本文重点介绍了苯酰基脲类、噻嗪酮这两类几丁质合成抑制剂类杀虫剂的发展概况和应用的有关杀虫特性及其目前在防治几类农作物害虫方面的应用情况,分析了其在应用方面的主要问题,并对其前景进行了讨论。     

生化抑制剂组合与施肥模式对黄泥田稻季氨挥发的影响

为探讨生化抑制剂组合与施肥模式对黄泥田稻季氨挥发的影响,采用二因素随机区组设计,研究生化抑制剂组合[N-丁基硫代磷酰三胺(NBPT)、N-丙基硫代磷酰三胺(NPPT)和2-氯-6-(三氯甲基)吡啶(CP)]与施肥模式(一次性和分次施肥)互作对黄泥田稻季氨(NH3)挥发动态变化的影响。结果表明:黄泥田稻季NH3挥发损失主要集中于施肥后1周,峰值发生在第1~3 d。生化抑制剂组合与施肥模式对黄泥田稻季NH3挥发损失量的效应显著。尿素分次施用处理稻季NH3挥发净损失率较一次性施用处理显著降低24.6%。不同施肥模式下,硝化抑制剂CP处理显著提高田面水NH+4-N峰值和NH3挥发速率峰值,增加稻田NH3挥发损失量;脲酶抑制剂NBPT/NPPT或配施CP处理明显延缓尿素水解,降低NH3挥发速率峰值,减少稻田NH3挥发损失量。新型脲酶抑制剂NPPT单独施用及与CP配施的稻田NH3挥发动态变化与NBPT相似。相关性分析表明,稻田NH3挥发速率与田面水NH+4-N浓度和pH值呈显著正相关,而与气温、土温和土壤相对湿度无显著相关性。总之,生化抑制剂组合与适宜的运筹相结合更能有效减少黄泥田稻季NH3挥发损失。     

植物源血管紧张素转换酶抑制剂的研究进展

血管紧张素转换酶抑制剂(Angiotensin converting enzyme inhibitors,ACEI)通过肾素-血管紧张素系统(RAS)和激肽释放酶-肽酶系统(KKS),抑制血管紧张素II的生成,减少缓激肽的降解,从而达到降血压的目的;植物来源的天然化合物具有来源广泛、结构多样、特异性高、毒性低等特点,因而从植物中筛选安全有效的ACEI成为研究热点。在此综述了血管紧张素转换酶(ACE)的活性测定方法以及植物来源的不同结构类型的ACEI研究进展。     

Effects of aromatase inhibitors on reproduction in male three-spined sticklebacks, Gasterosteus aculeatus, exposed to long and short photoperiods

Three-spined stickleback Gasterosteus aculeatus, males were implanted with Silastic capsules filled with different aromatase inhibitors; 1,4,6-androstatriene-3,17-dione or the non-steroidal CGS16949 A, 4-(5,6,7,8-tetrahydrimidazol [1,5-a]pyridin-5-yl) benzonitrile monohydrochloride or empty capsules. The fish were then exposed to long or short photoperiod. Under the long photoperiod most fish in all treatments displayed a hypertrophied kidney (a secondary sexual character in sticklebacks) and completed, quiescent spermatogenesis, similar as in the natural spawning period. Under the short photoperiod the controls had unstimulated kidneys and an active spermatogenesis, whereas the males implanted with both aromatase inhibitors had stimulated kidneys, though not to the extent as in the long photoperiod, and completed, quiescent spermatogenesis. These findings suggest that aromatization is of importance for the inhibitory effects of short photoperiod on reproduction in the stickleback. This revised version was published online in July 2006 with corrections to the Cover Date.     

氨氮质量浓度及附着基筛选对硝化细菌氨氮净化影响

将带有试验硝化细菌——食油假单胞菌X14-1-1的等面积陶粒、聚氯乙烯、纤维、火山岩、无纺布和流化床6种材料的附着基分别放入1 L的充气瓶内,在36℃、130 r/m in的摇床上混合培养48 h后,洗脱计数测定菌种附着数量.模拟氨氮去除率试验中氨氮初始质量浓度为0(不加硫酸铵)、10、20、30、40、50、60 m...     

Breaking seasonal limitation: year-round sporogenesis in the brown alga Laminaria saccharina by blocking the transport of putative sporulation inhibitors

Year-round induction of sporogenesis of Laminaria saccharina was performed by mechanically blocking the transport of the putative sporulation inhibitors produced by the blade meristem and culturing the plants in constant short days. Sporogenesis was successfully induced by removal of the blade meristem, either by cultivating distal blade fragments or by performing a transverse cut in the frond. The earliest sorus formation after artificial induction was 10 days. The age of the sporophytes used for induction was 6–11 months or 2 years in tank-grown or field-collected sporophytes, respectively. Zoospores were successfully released in all cases. Thus, by year-round artificial induction of sporogenesis, (1) sporeling production of L. saccharina and thereafter sporophyte cultivation could be achieved without seasonal limitation, and (2) the life cycle of L. saccharina (from spore to spore) could be completed within 8 months under controlled conditions.