苜蓿原生质培养及体细胞杂交技术的应用

阐述了植物原生质体培养和体细胞杂交技术以及苜蓿Medicago spp.体细胞胚胎发生特性,综述了该技术在苜蓿育种研究中的应用状况,同时介绍了我国苜蓿研究领域原生质体培养和体细胞杂交技术的研究进展.     

Yield performance of spring wheat improved by regulated deficit irrigation in an arid area

A field experiment was conducted in 2003 and 2004 growing seasons to evaluate the effects of regulated deficit irrigation on yield performance in spring wheat (Triticum aestivum) in an arid area. Three regulated deficit irrigation treatments designed to subject the crops to various degrees of soil water deficit at different stages of crop development and a no-soil-water-deficit control was established. Soil moisture was measured gravimetrically in the increment of 0–20 cm every five to seven days in the given growth periods, while that in 20 increments to 40, 40–60, 60–80, and 80–100 cm depth measured by neutron probe. Compared to the no-soil-water-deficit treatment, grain yield, biomass, harvest index, water use efficiency (WUE), and water supply use efficiency (WsUE) in spring wheat were all greatly improved by 16.6–25.0, 12.4–19.2, 23.5–27.3, 32.7–39.9, and 44.6–58.8% under regulated deficit irrigation, and better yield components such as thousand-grain weight, grain weight per spike, number of grain, length of spike, and fertile spikelet number were also obtained, but irrigation water was substantially decreased by 14.0–22.9%. The patterns of soil moisture were similar in the regulated deficit treatments, and the soil moisture contents were greatly decreased by regulated deficit irrigation during wheat growing seasons. Significant differences were found between the no-soil-water-deficit treatment and the regulated soil water deficit treatments in grain yield, yield components, biomass, harvest index, WUE, and WsUE, but no significant differences occurred within the regulated soil water deficit treatments. Yield performance proved that regulated deficit irrigation treatment subjected to medium soil water deficit both during the middle vegetative stage (jointing) and the late reproductive stages (filling and maturity or filling) while subjected to no-soil-water-deficit both during the late vegetative stage (booting) and the early reproductive stage (heading) (MNNM) had the highest yield increase of 25.0 and 14.0% of significant water-saving, therefore, the optimum controlled soil water deficit levels in this study should range 50–60% of field water capacity (FWC) at the middle vegetative growth period (jointing), and 65–70% of FWC at both of the late vegetative period (booting) and early reproductive period (heading) followed by 50–60% of FWC at the late reproductive periods (the end of filling or filling and maturity) in treatment MNNM, with the corresponding optimum total irrigation water of 338 mm. In addition, the relationships among grain yield, biomass, and harvest index, the relationship between grain yield and WUE, WsUE, and the relationship between harvest index and WUE, WsUE under regulated deficit irrigation were also estimated through linear or non-linear regression models, which indicate that the highest grain yield was associated with the maximum biomass, harvest index, and water supply use efficiency, but not with the highest water use efficiency, which was reached by appropriate controlling soil moisture content and water consumption. The relations also indicate that the harvest index was associated with the maximum biomass and water supply use efficiency, but not with the highest water use efficiency.     

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.     

Parsimoniously modelling perennial vegetation suitability and identifying priority areas to support China's re-vegetation program in the Loess Plateau: Matching model complexity to data availability

The Chinese Central government's policy to re-vegetate large areas of the Loess Plateau is currently being rapidly implemented at the provincial, prefecture, county, township, and village levels of government. Managers at these five levels of government need access to information to assist them to plan the land use change prior to performing on-ground activities. To this end, the suitability of 38 predominately native species in the 113,000 km² Coarse Sandy Hilly Catchments (CSHC) has been mapped at a 100 m resolution. In this data-sparse region, this was achieved by using a five-variable spatial overlay approach as we were able to readily access the required environmental variables and rule-set defining the species’ requirements (or tolerances). As the rules did not consider optimal growth they were possibly ‘too inclusive’, so the spatial extent of areas suggested for re-planting was refined by defining ‘target areas’ for trees, shrubs and grasses based on precipitation, aspect, landform, and slope. In the land-use planning criteria developed here we suggest that hill-slopes and gullies with slopes greater than or equal to 15° (defined from a 100 m resolution DEM) be left for natural succession. Due to lateral flow of water, sediment and nutrients from these steep slope and gullies, further prioritising re-vegetation target areas to the zone adjacent to and down slope from these steep portions of the landscape reduces sediment entering the river network with a minimal decrease of regional stream flow. These two functions (mapping species suitability and locating where priority and target re-vegetation activities should be undertaken) are available at a 100 m resolution for the entire CSHC by accessing a bilingual decision support tool called ReVegIH (Re-Vegetation Impacts on Hydrology). Finally, an ecohydrological model was used to simulate changes in average annual stream flow originating from the CSHC based on implementing the ‘target’ and ‘priority’ area re-vegetation activities within the constraints of two land limits.     

Yield and water consumption characteristics of wheat/maize intercropping with reduced tillage in an Oasis region

Higher irrigation quota for conventional farming causes substantial conflicts between water supply and demand in agriculture, and wind erosion near soil surface is one of the major causes of farmland degradation and desertification in arid areas. This research investigated the effect of the amounts of irrigation in combination with tillage practices on soil evaporation (E), water consumption (ET) characteristics, and grain yield performance and water use efficiency (WUE) for wheat (Triticum aestivum L.) intercropped with maize (Zea mays L.) in strip planting in an Oasis region. The field experiment, conducted at Wuwei station during 2008–2010, had two tillage systems (reduced tillage with wheat stubble retention vs. conventional tillage without stubble retention), and three (low, medium, and high) levels of irrigation, in a randomized complete block design. Averaged across three years, soil evaporation with medium and high levels of irrigation was 6.8% and 5.4% greater than that with low level of irrigation, respectively. Total water consumption of wheat/maize crops under the medium and high irrigation levels was 8.5% and 18.5% greater, respectively, than that under low irrigation. However, grain yields were similar under the medium and high levels of irrigation, so was WUE. The effect of tillage on the wheat/maize intercropping was inconsistent across years or among treatments: soil moisture at harvest was 3.0–7.6% greater in the fields with reduced tillage compared with those with conventional tillage in 2008 and 2009, but no difference was found in 2010; the E/ET ratio of reduced tillage was 9% lower than the ratio under conventional tillage in 2008, 3% higher in 2010, but no difference between the two tillage systems in 2009. Across three years, there was a general trend that the WUE of the wheat/maize intercropping system with reduced tillage was greater (by 4–11%) than that with conventional tillage. We conclude that a medium level of irrigation is sufficient to achieve crop yields and WUE equivalent to those under high level of irrigation, provided that a reduced tillage practice is applied to the wheat/maize intercropping in Oasis areas.     

芹菜叶斑病病原菌细极链格孢药剂筛选

【目的】研究筛选对芹菜叶斑病(病菌为:细极链格孢Alternaria tenuissima)具有良好防治作用的药剂。【方法】采用菌丝生长速率法和琼脂片法分别用14种杀菌剂对细极链格孢(A.tenuissima)菌丝和孢子萌发做室内毒力测定并进行田间药效试验。【结果】14种杀菌剂中对病原菌菌丝抑制效果最好的分别为3%甲霜恶霉灵、5%香芹酚、10%苯醚甲环唑、其EC₅₀分别为10.8、19.9、26.2 μg/mL;对孢子萌发抑制效果最好的分别为3%甲霜恶霉灵、25%嘧菌酯、43%戊唑醇,其EC₅₀分别为15.7、29.5、38.7 μg/mL。只有3%甲霜恶霉灵具有最佳的防治效果。防效最好的药剂为3%甲霜恶霉灵和5%香芹酚,其防效分别为96.3%和83.9%。【结论】3%甲霜恶霉灵最适用于田间芹菜叶斑病的防治。     

Simulating the canopy photosynthesis of Qinghai spruce (Picea crassifolia Kom.) in the Qilian Mountains,Northwestern China

New Forests - Qinghai spruce (Picea crassifolia Kom.) forests play a key role in the carbon sequestration in the Qilian Mountains, Northwestern China. Carbon sequestration is closely related to...     

经济政策不确定性对中国粮食安全的影响

为探究经济政策不确定性对中国粮食安全的影响,基于2000—2018年中国31个省(市、自治区,统计数据未含港澳台地区)的面板数据,采用PVAR模型,研究经济政策不确定性对中国粮食供给安全、获取安全、稳定性安全和资源安全的影响及区域差异。结果表明:1)总体上,经济政策不确定性对中国粮食安全具有负向影响。2)分区域看,粮食主产区的供给安全受经济政策不确定性负向影响最大,粮食主销区的获取安全受经济政策不确定性冲击最为明显,经济政策不确定性对粮食产销平衡区的冲击最小。3)从粮食安全衡量维度看,经济政策不确定性对供给安全、获取安全和资源安全具有抑制影响,对稳定性安全呈现正向冲击作用。为确保粮食安全,中国应继续加强对粮食生产政策支持、稳定国内粮食价格和健全保障粮食安全的制度机制。     

灌丛化对高寒草甸土壤水力性质的影响

全球气候变化背景下,青藏高原高寒草甸灌丛化已经成为青藏高原植被景观的主要变化趋势。为了更好地认识和理解灌丛化与高寒草甸生态系统的关系,以青藏高原东缘川西锦鸡儿(Caragana Erinacea Kom)和金露梅(Potentilla Fruticosa)灌丛化高寒草甸为对象,采用环刀浸泡法和双环入渗法研究了其在未灌丛化、轻度灌丛化、中度灌丛化和重度灌丛化阶段土壤持水和入渗能力特征。结果表明:(1)2种灌丛化草甸土壤容重在中度灌丛化阶段最低,总孔隙度在中度灌丛化阶段最高。(2)随着灌丛化程度的增加,2种灌丛化草甸土壤含水量呈增加趋势,表现为在重度灌丛化阶段最高;土壤毛管持水量、田间持水量和最大持水量呈抛物线变化趋势,在中度灌丛化阶段最大。(3)2种灌丛化草甸土壤的初渗率、稳渗率和入渗速度随灌丛化程度的增加总体表现为增加趋势,其中在中度和重度灌丛化阶段显著高于未灌丛化阶段。(4)相关性分析表明,灌丛化草甸土壤的入渗指标与土壤含水量、非毛管孔隙度有显著相关关系。因此,高寒草甸灌丛化过程中,土壤水力性质的改变通常发生在中度和重度灌丛化阶段。