低温和诱导时间对小麦小孢子培养的影响

为了优化小麦小孢子培养体系,研究了低温处理花药、幼穗及诱导培养时间对小孢子形态、胚胎发生和植株再生的影响。结果表明,经低温处理后,有活力的小孢子体积增大、形态变化明显,据其液泡大小、数目及其与细胞核位置的关系,可分为4种类型。低温处理可显著提高胚状体数和绿苗数,其中处理花药3 d、幼穗7 d的效果最好,平均每皿的绿苗数分别为59株和57株。胚状体发育速度显著影响绿苗分化能力,小孢子诱导培养28-29 d、直径约2 mm的胚状体数目较少,但绿苗分化率高;诱导培养32-38 d、直径为2 mm的胚状体数目达到了峰值,而绿苗分化率极低。在小麦小孢子培养中,应选择诱导28-29 d、直径2 mm的胚状体进行分化培养。     

低聚木糖的制备及其对益生菌体外增殖的作用

针对玉米芯微波消解-内切木聚糖酶水解制备低聚木糖的工艺,以低聚木糖的得率为主体评价指标,通过单因素实验时影响低聚木糖得率的微波消解过程和内切木聚糖酶水解过程的因素与水平进行研究,并考察获得的低聚木糖对益生菌的体外增殖作用.结果表明:玉米芯酶法制备低聚木糖的最佳工艺条件为微波处理压力1.6 MPa,微波处理时间5 min,内切木聚糖酶用量140 U·g-1,酶解时间6 h;在最适条件下,玉米芯酶解液中低聚木糖的得率为82.5%,质量浓度为11.02 g·L-1;低聚木糖对益生菌的体外增殖实验表明,低聚木糖添加量在0.2%和0.4%时,分别可以对乳酸杆菌和枯草芽孢杆菌起到最好的增殖作用,分别达到311%和183%,添加量进一步提高反而会抑制这2种菌的生长.     

Effects of different soil conservation tillage approaches on soil nutrients,water use and wheat-maize yield in rainfed dry-land regions of North China

Excessive tillage compromises soil quality by causing severe water shortages that can lead to crop failure. Reports on the effects of conservation tillage on major soil nutrients, water use efficiency and gain yield in wheat (Triticum aestivum L.) and maize (Zea mays L.) in rainfed regions in the North China Plain are relatively scarce. In this work, four tillage approaches were tested from 2004 to 2012 in a randomized study performed in triplicate: one conventional tillage and three conservation tillage experiments with straw mulching (no tillage during wheat and maize seasons, subsoiling during the maize season but no tillage during the wheat season, and ridge planting during both wheat and maize seasons). Compared with conventional tillage, by 2012, eight years of conservation tillage treatments (no tillage, subsoiling and ridge planting) resulted in a significant increase in available phosphorus in topsoil (0–0.20 m), by 3.8%, 37.8% and 36.9%, respectively. Soil available potassium was also increased following conservation tillage, by 13.6%, 37.5% and 25.0%, and soil organic matter by 0.17%, 5.65% and 4.77%, while soil total nitrogen was altered by −2.33%, 4.21% and 1.74%, respectively. Meanwhile, all three conservation tillage approaches increased water use efficiency, by 19.1–28.4% (average 24.6%), 10.1–23.8% (average 15.9%) and 11.2–20.7% (average 15.7%) in wheat, maize and annual, respectively. Additionally, wheat yield was increased by 7.9–12.0% (average 10.3%), maize yield by 13.4–24.6% (average 17.4%) and rotation annual yield by 12.3–16.9% (average 14.1%). Overall, our findings demonstrate that subsoiling and ridge planting with straw mulching performed better than conventional tillage for enhancing major soil nutrients and improving grain yield and water use efficiency in rainfed regions in the North China Plain.     

Unequal salt distribution in the root zone increases growth and yield of cotton

Soil salinity is often heterogeneous, yet plant response to unequal salt distribution (USD) in the root zone is seldom studied in cotton (Gossypium hirsutum L.). Our objective was to evaluate the effects of USD on growth and yield, as well as its potential application for increasing cotton production. To achieve this objective, greenhouse and field experiments were conducted. In the first experiment, potted cotton plants were grown in a split-root system in the greenhouse. Each root half was irrigated with either the same or two concentrations of NaCl. Plant biomass, leaf chlorophyll (Chl), photosynthesis (Pn) and transpiration (Tr), Na⁺ and K⁺ accumulation, as well as biological and economic yields were determined. In the second experiment, plants were grown in furrow-beds in saline fields with those grown on flat beds as controls. Root-zone salinity, yield and yield components and earliness (the percentage of the first two harvests to total harvests) were monitored. When the entire root system was exposed to the same concentration of NaCl, shoot dry weight, leaf area, plant biomass, leaf Chl, Pn and Tr were markedly reduced relative to the NaCl-free control at 2 weeks after salinity stress (WAS). Significant reductions in biological (23.6–73.8%) and economic yields (38.1–79.7%) were noticed at harvest. However, when only half of the root system was exposed to low-salinity, the inhibition effect of salinity on growth and yield was significantly reduced. Plant biomass and seed cotton yield were increased by 13 and 23.9% with 50/150 mM/mM NaCl, 40 and 44.5% with 100/300 mM/mM NaCl, and 85.7 and 127.8% with 100/500 mM/mM NaCl relative to their respective equal salt distribution (ESD) controls (100/100, 200/200, and 300/300). Unequal salt distribution also decreased concentrations of Na⁺ and increased leaf K⁺ and Chl content, K⁺/Na⁺ ratio, Pn and Tr, compared with ESD. Furrow-bed seeding induced unequal distribution of salts in the surface soil during the field experiment. Under furrow planting, soil salinity was much higher, but soil osmotic potential was much lower on the ridged part than the furrows. Yield and earliness were increased 20.8 and 5.1% by furrow seeding relative to flat seeding. These enhancements were mainly attributed to unequal distribution of salts in the root zone. Thus, specific cultural practices that induce unequal salt distribution such as furrow-bed seeding can be used to improve cotton production in saline fields.     

Adsorption kinetics of 17α-ethinyl estradiol and bisphenol A on carbon nanomaterials. II. Concentration-dependence

Purpose  

Carbon nanomaterials (CNMs) have attracted a great deal of research interest for their potential environmental applications because of their unique properties. Adsorption of organic chemicals on CNMs was reported to be important in controlling their environmental risks. However, the kinetics of the adsorption is hardly investigated in literature. The objective of this work was, therefore, to quantitatively describe the sorption kinetics of 17 α-ethinyl estradiol (EE2) and bisphenol A (BPA) on CNMs as compared to activated carbon (AC).     

Impact of coleopteran targeting toxin (Cry3Bb1) of Bt corn on microbially mediated decomposition

Genetically engineered corn expressing crystalline proteins for insect control and encoded by genes derived from soil bacterium Bacillus thuringiensis (Bt) are widely adopted in the United States. Among the seven different events of Bt corn available commercially, YieldGard^® Rootworm (MON863) expresses a variant of the cry3Bb1 protein in the root tissue to control corn rootworm larvae. Although numerous laboratory and field studies show no unexpected ecological risks at the insect community-level above-ground, few studies have addressed the possible impact of cry proteins released from living or decaying roots of Bt corn on soil microbial communities. Here, we test the hypothesis that coleopteran-active Bt corn does not affect nontarget ecological processes, such as decomposition or the function of the associated saprophytic microbial community. Experimental treatments were: (1) a Bt hybrid; (2) a non-Bt, isogenic hybrid treated with a conventional soil insecticide; and (3) a non-Bt, isogenic hybrid without insecticide. Soil and root samples were collected at various times throughout 2 years from experimental plots to estimate microbial community function by quantifying activity of extracellular enzymes on 10 substrates. Decomposition was measured as mass loss by root decay in litter bags. Bt corn (MON863) exuding the cry3Bb1 toxin does not appear to have adverse effects on saprophytic microbial communities of soil and decaying roots or on decomposition. The addition of the soil insecticide had greater effects on microbial function in soil and decaying roots than Bt corn. Our results are similar to those found previously for the cry3Bb1 protein that showed no adverse effects on microbial community composition in controlled and natural environments. This field study is one of the first to report the use of extracellular enzyme assays to examine the effect of transgenic crops on the functional activity of microbes in soil and decaying roots.     

Effects of liming on survival and reproduction of two potentially invasive earthworm species in a northern forest Podzol

During the last several decades, colonization of soil by exotic earthworms and their effects on soil properties and biodiversity have been reported in forests of North America. In some northern hardwood stands, acid soils or harsh climate may have prevented earthworm colonization. However, climatic change and the increasing use of liming to restore the vigor of declining sugar maple (Acer saccharum Marsh.) stands, situated on base-poor soils in USA and Canada, could make many of these sites more suitable for earthworm colonization. We tested survival and reproduction of two exotic earthworm species (Lumbricus terrestris and Amynthas hawayanus) in unlimed and limed soils at the northern limit of the northern hardwood forest distribution in Canada. Improving soil parameters of base-poor, acidic soils by liming positively influenced activity, survivability and reproductive output of L. terrestris in this northern hardwood forest. In contrast, the high mortality and low vigor of L. terrestris observed in the unlimed plots show that soils in this area with a pH of 4.3 are not favorable to this species. Our results suggest that A. hawayanus was very active prior to winter at both soil pHs, but was not able to complete its life cycle during one year at this latitude. Both earthworm species significantly reduced organic C and total N, and increased the C/N ratio of the forest floor. Given that forest liming activities are increasing in proximity to human activities, there is high probability that some earthworm species, such as L. terrestris, will invade limed northern hardwood forests in the next decades, with possible consequences for soil organic matter turnover, nutrient cycling and forest biodiversity and dynamics.     

几个萝卜品种在南疆阿拉尔地区的引种表现

以“春雪剑”、“新大青皮萝卜”、“中国心”等8个萝卜品种为试材,对不同品种间内在品质、外观品质及植物学性状进行比较,旨在引种后筛选出适宜在阿拉尔地区种植的优良萝卜品种.结果表明:根据其产量、口味以及果皮、果肉颜色和消费者习惯等综合因素,“春雪剑”、“北京满堂红”、“金秋红帅”、“春不老”更适宜阿拉尔地区栽培,但“春不老”较易抽薹,应注意播期.     

Different roles of rhizosphere effect and long-term fertilization in the activity and community structure of ammonia oxidizers in a calcareous fluvo-aquic soil

Ammonia oxidation is a critical step in the soil nitrogen (N) cycle and can be affected by the application of mineral fertilizers or organic manure. However, little is known about the rhizosphere effect on the function and structure of ammonia-oxidizing bacterial (AOB) and archaeal (AOA) communities, the most important organisms responsible for ammonia oxidation in agricultural ecosystems. Here, the potential nitrification activity (PNA), population size and composition of AOB and AOA communities in both the rhizosphere and bulk soil from a long-term (31-year) fertilizer field experiment conducted during two seasons (wheat and maize) were investigated using the shaken slurry method, quantitative real-time polymerase chain reaction and denaturing gradient gel electrophoresis. N fertilization greatly enhanced PNA and AOB abundance, while manure application increased AOA abundance. The community structure of AOB exhibited more obvious shifts than that of AOA after long-term fertilization, resulting in more abundant AOB phylotypes similar to Nitrosospira clusters 3 and 4 in the N-fertilized treatments. Moreover, PNA was closely correlated with the abundance and community structure of AOB rather than that of AOA among soils during both seasons, indicating that AOB play an active role in ammonia oxidation. Conversely, the PNA and population sizes of AOB and AOA were typically higher in the rhizosphere than the bulk soil, implying a significant rhizosphere effect on ammonia oxidation. Cluster and redundancy analyses further showed that this rhizosphere effect played a more important role in shaping AOA community structure than long-term fertilization. Overall, the results indicate that AOB rather than AOA functionally dominate ammonia oxidation in the calcareous fluvo-aquic soil, and that rhizosphere effect and fertilization regime play different roles in the activity and community structures of AOB and AOA.     

Biocontrol of rice blast by the phenaminomethylacetic acid producer of Bacillus methylotrophicus strain BC79

Strain BC79, isolated from primeval forest soil in Qinling, Mountains, China, was identified as Bacillus methylotrophicus based on morphological, biochemical, physiological and chemotaxonomic analyses as well as phylogenetic 16S rDNA sequencing data. This strain was able to suppress mycelial growth and conidial germination of numerous plant pathogenic fungi in dual cultures on solid media. For exploring potential biocontrol activity, we assessed fermentation conditions for studying B. meth1ylotrophicus BC79. The active substance of BC79, phenaminomethylacetic acid, was extracted by TLC and HPLC, and identified as the strongest inhibitory substance described in B. methylotrophicus. Experiments in a greenhouse showed that application of BC79 culture filtrates 24 h before inoculation of Magnaporthe oryzae, the causal agent of rice blast, had 89.87% biocontrol efficiency. B. methylotrophicus BC79 colonized rice plant tissues and at 10 days after filtrate application, its population in leaves (1.65 × 10⁸ CFU/g) was much larger than in stems (6.78 × 10⁷ CFU/g) or roots (3.56 × 10⁷ CFU/g). Field trials indicated that BC79 culture filtrate (4000 g/667 m²) showed the highest efficiency for M. oryzae, with 84.8% biocontrol effect, followed by of 15% phenaminomethylacetic acid extract (75.5%) and 20% tricyclazole (76.1%). Seedling and post-transplant stages were the best periods to apply BC79 for control of rice blast. The B. methylotrophicus BC79 strain hence has enormous potential as an agricultural agent for biocontrol of rice blast.