大型组合式机械通风玉米穗储粮仓的设计

本研究针对大农户玉米穗储藏的实际情况，研制了大型组合式机械通风玉米穗储粮仓，并对其进行了装粮试验。结果表明：该型储粮仓机械性能稳定，结构组装方便，降水、防霉、防鼠效果显著，可有效降低粮食产后损失，保证粮食品质。 [关键词] 粮仓|玉米穗|机械通风     

不同施氮水平下灌浆期高温对水稻贮藏蛋白积累及其合成代谢影响

【目的】 揭示不同施氮水平下灌浆结实期高温对稻米贮藏蛋白积累及其组分的影响,明确不同温氮处理组合下稻米贮藏蛋白合成积累过程与籽粒氮代谢关键酶及相关基因表达间关系。 【方法】 以2个主栽常规晚粳品种（秀水134和秀水09）为材料,利用盆栽土培试验,在水稻穗分化期设低氮（每盆0.5 g尿素）和高氮（每盆2.0 g尿素）2个氮水平,继而通过在水稻灌浆结实期的人工气候箱控温试验,设置高温（日均温度30℃,日最高温和最低温分别为34℃和26℃）和常温（日均温度23℃,日最高温和最低温分别为26℃和20℃）,构成低氮-常温（LN-NT）、低氮-高温（LN-HT）、高氮-常温（HN-NT）、高氮-高温（HN-HT）4个处理组合,并结合水稻籽粒灌浆不同时期取样,探讨氮素穗肥对水稻高温灌浆过程贮藏蛋白积累和主要蛋白组分含量影响及其与籽粒氮代谢关键酶及相关基因表达间关系。 【结果】 氮素穗肥和灌浆期高温均会导致稻米粗蛋白相对含量上升,但在高温处理下单位籽粒中粗蛋白的绝对量却呈降低趋势,以13 kD醇溶蛋白亚基组分在高温处理下的下降幅度最大,从而引起籽粒谷蛋白/醇溶蛋白质比值的上升,其原因主要是由于编码水稻13 kD醇溶蛋白合成基因（Pro13, Pro14和Pro17）在高温处理下的下调表达所致。与之相比,增施氮素穗肥（HN-NT和HN-HT）在引起稻米粗蛋白相对含量提升的同时,单位籽粒中的粗蛋白总量、谷蛋白和醇溶蛋白含量均显著增加,但对贮藏蛋白谷/醇比的影响不明显,且谷蛋白组分中的37 kD酸性亚基和22 kD碱性亚基在不同氮处理水平下的相对比例也基本保持稳定;氮素穗肥可增强灌浆籽粒中的谷氨酰胺合酶（GS）、谷草转氨酶（GOT）和谷丙转氨酶（GPT）活性,但HN-HT处理下的籽粒GS、GOT和GPT活性显著低于HN-NT处理,高温胁迫对水稻灌浆中后期籽粒器官中的氮转运代谢具有抑制作用。此外,在不同氮素水平下,灌浆期高温均可引起稻米整精米率的明显下降和垩白度的显著上升,但HN-HT处理的千粒重、结实率、产量水平、整精米率却高于LN-HT处理,且前者的稻米垩白度显著低于后者,氮素穗肥不足加剧了高温胁迫对千粒重、结实率、整精米率和垩白度等产量和品质性状的负面影响。 【结论】 氮素穗肥对水稻高温灌浆过程贮藏蛋白合成积累起重要调节作用,增施氮素穗肥虽然对水稻籽粒灌浆过程中的谷蛋白和醇溶蛋白质合成具有促进作用,并导致稻米贮藏蛋白相对量与绝对量增加,但对于高温灌浆下13kD醇溶蛋白亚基合成及其组分含量下降具有一定程度的缓解效应,有利于维持贮藏蛋白谷/醇比相对稳定。     

Maize harvest index and water use efficiency can be improved by inhibition of gibberellin biosynthesis

Possibilities to improve maize harvest index and nutrient utilization efficiency by application of plant growth regulators were investigated. In container experiments, the effects of different growth regulators on the development of the maize (Zea mays L.) cultivars Pioneer 3906 and Fabregas were tested. Paclobutrazol (PAC) and chlorocholine chloride (CCC), two inhibitors of gibberellin biosynthesis, as well as gibberellic acid (GA₃) were applied at growth stage V5. Three weeks after application of PAC, shoot growth of both maize cultivars was strongly affected with a significant decrease in plant height in the PAC treatment by 44% and 36% for Pioneer 3906 and Fabregas, respectively. The growth‐retarded plants had higher leaf areas and reduced transpiration rates. The higher shoot growth after GA₃ application was accompanied by a reduction in leaf area and an increase in transpiration rate during 1 week before anthesis. CCC treatment showed no significant effects on plant height, leaf area and transpiration rate. The PAC‐treated cultivar Pioneer 3906 produced several cobs per plant, which were mainly barren at maturity. However, PAC application to Fabregas resulted in just one cob per plant with good kernel development and a grain yield, which was not significantly reduced in comparison with the control. With this similar grain yield in combination with a straw yield decrease of 32%, the harvest index was significantly improved by 12%. In addition, with PAC‐treated Fabregas plants, a 19% increased water use efficiency of the grain (WUE_grain) during the critical period of kernel setting was achieved. In this maize cultivar, CCC application also improved harvest index by 5%, but no effect on WUE_grain occurred. GA₃ treatment decreased harvest index of both maize cultivars, and it either reduced WUE_grain (Pioneer 3906) or showed no effect (Fabregas). Utilization efficiencies of N, P and K were not increased with growth regulator application, even in the PAC‐treated Fabregas plants with a significantly improved allocation of assimilates to the grain, mirrored by the higher harvest index. The results indicate that fertilizer applications must be adjusted to the reduced demand of growth‐retarded plants, most likely leading to higher nutrient utilization efficiencies.     

灌浆温度和氮肥及其互作效应对稻米贮藏蛋白组分的影响

灌浆结实期温度与氮肥施用量是影响稻米品质的两个重要生态因子,尤其是与稻米蛋白含量及米饭食味关系密切。本文以多个水稻主栽品种为材料,通迆灌浆结实期的人工控温试验、大田长期定位点的施氮处理试验和盆栽条件下的温氮两因素复合处理试验,探讨了水稻灌浆结实期温度对稻米贮藏蛋白含量与组分影响及其有别于氮肥处理效应的差异觃律,幵分析了温度与氮肥两个因素对稻米贮藏蛋白及其组分影响的交互作用特点。结果表明,高温胁迫和增施氮肥均引起水稻籽粒总蛋白及其谷蛋白组分含量(%)的显著增加,但两者对稻米醇溶蛋白影响却存在明显差别。其中,高温处理引起醇溶蛋白含量显著下降,提高稻米谷蛋白/醇溶蛋白比值,而增施氮肥引起稻米谷蛋白和醇溶蛋白含量明显增加,但对谷蛋白/醇溶蛋白比值与贮藏蛋白各亚基的组成比例影响相对较小。在高温处理下,谷蛋白的57kD前体亚基组分含量有所提高,而37kD酸性亚基和22kD碱性亚基随温度处理的差异变化却因品种而异,且高温处理对水稻籽粒蛋白绝对含量(mg grain~(–1))的影响程度也进没有其对蛋白相对含量(%)的影响明显。高氮×高温处理组合对稻米总蛋白与谷蛋白含量的影响程度显著大于单一高温或高氮处理,但在高氮水平下由高温引起稻米醇溶蛋白含量的下降幅度却小于其低氮对照,有利于稻米醇溶蛋白含量在不同温度处理下的相对稳定。     

基于区块链的食用菌质量安全溯源系统设计

为了实现食用菌质量安全溯源,在食用菌质量安全溯源系统现状的基础上,利用区块链技术的去中心化分布式存储结构,保证了食用菌溯源数据的安全可靠。基于区块链技术设计了食用菌质量安全溯源系统,给出了追溯体系的总体架构和主要业务流程,有针对性地解决了食用菌溯源系统中存在问题。实现了食用菌全周期全流程的信息溯源,为消费者提供了真实、可靠的溯源信息。     

湖南省粮食产量波动的影响因素分析及预测

旨在维护国家稳定,为预判粮食生产前景、提高粮食生产效率、保障粮食安全提供理论依据。利用湖南省统计数据,运用灰色关联分析法筛选关联性较强的影响因素,并建立GM(1,N)预测模型预测粮食产量。2008—2017年与湖南省粮食产量关联度最大的影响因素是粮食作物播种面积和农业机械总动力;科技因素是影响2008—2017年湖南省粮食产量的主要因素,其次是自然因素,社会因素;2018—2027年湖南省粮食产量有较小波动,且农业机械总动力和财政农业支出影响较大;农业机械总动力在前后十年对粮食产量都有较重要的影响,越来越占据主导地位。粮食产量受国家政策的影响,受农业机械总动力影响最大,维持产量水平需高度重视农业机械化水平,稳步提高粮食作物播种面积。     

中国粮食进口安全综合评价研究——基于超效率DEA模型

在对粮食及粮食进口安全内涵加以界定的基础上,从粮食数量、粮食质量、粮食价格、粮食贸易、国家经济、生态环境6个方面分析中国粮食进口安全的影响因素,基于超效率DEA模型构建中国粮食进口安全评价模型。对1992—2015年中国粮食进口安全状况进行评价,结果表明,1992—2015年中国粮食进口处于安全状态,粮食进口对我国粮食价格安全和生态安全的影响程度较小,对数量安全、质量安全、贸易安全和经济安全的影响程度较大。     

不同类型水稻品种产量和氮素吸收利用对大气CO2浓度升高响应的差异

目的 探明不同类型水稻品种产量和氮素吸收利用对FACE(大气CO₂浓度增高)响应的差异。方法 以常规粳稻、杂交籼稻、常规籼稻共6个品种为供试材料,研究FACE对不同类型水稻产量、氮素吸收利用的影响。结果 1）FACE处理极显著提高了水稻产量,平均增加24.17%, 常规籼稻增幅最大,FACE和对照均以杂交籼稻最高;2）FACE处理显著增加了单位面积穗数,常规粳稻增幅最大,并显著增加了杂交籼稻和常规籼稻每穗粒数;3）FACE处理显著提高了成熟期吸氮量和氮素籽粒生产效率,成熟期吸氮量平均增加21.23%,杂交籼稻增幅最大, FACE和对照均以常规籼稻最高;氮素籽粒生产效率平均增加7.33%,杂交籼稻增幅最大,FACE和对照均以杂交籼稻最高。成熟期吸氮量对产量促进作用略大于成熟期氮素籽粒生产效率;4）FACE处理降低了植株含氮率,成熟期平均下降0.105个百分点,常规粳稻降幅最大。FACE处理极显著提高植株干物质量,成熟期平均增加23.95%,常规籼稻增幅最大;FACE处理显著提高常规籼稻和杂交籼稻成熟期单穗吸氮量,分别增加10.79%、13.93%,但常规粳稻下降了9.60%;FACE处理显著提高了成熟期群体吸氮强度,平均增加22.29%,杂交籼稻增幅最大。FACE处理对水稻全生育期天数无显著影响;FACE处理显著提高茎鞘、叶片、穗各器官吸氮量,叶片增幅最大,平均增加51.86%,杂交籼稻增幅最大;FACE处理显著提高了不同生育阶段吸氮量,抽穗-成熟阶段增幅最大,平均增加108.90%,杂交籼稻增幅最大;5）植株干物质量、单穗吸氮量、吸氮强度、穗吸氮量、抽穗-成熟阶段吸氮量对成熟期总吸氮量的促进作用分别大于植株含氮率、单位面积穗数、生育天数、茎鞘叶吸氮量、移栽-分蘖和分蘖-抽穗阶段吸氮量;6）FACE处理显著提高了氮肥偏生产力,降低了每百千克籽粒需氮量,前者平均增加24.16%,常规籼稻增加最多;后者平均降低4.7%,常规籼稻降幅最大。结论 FACE处理可显著提高水稻产量和氮素吸收利用效率,但品种间差异较大。     

Application of urease inhibitor improves protein composition and bread‐baking quality of urea fertilized winter wheat

Background: Nitrogen losses is an economic problem for wheat production and a high risk to the environment. Therefore, improved N fertilizer management is a key to increasing the N efficiency and minimizing N losses. To increase N efficiency, enhanced fertilizers such as urea combined with urease inhibitor can be used. Aims: The aim of present study was to evaluate the effects of different N forms on grain storage protein subunits in winter wheat and to examine whether the observed changes correlate with parameters of baking quality. Methods: The investigation was performed over two consecutive years at two locations in Germany. Protein subunits were analyzed by SDS‐PAGE. Results: Protein concentrations were similarly increased after fertilization with ammonium nitrate and urea + urease inhibitor. Analysis of the individual storage protein fractions indicated that both fertilizers specifically enhanced ω‐gliadins and HMW glutenins, but the effect was more pronounced in the ammonium nitrate treatment. Application of urea + urease inhibitor had greater influence on the protein composition and resulted in higher specific baking volume as well as the best fresh keeping ability, in comparison with urea treatment. Conclusion: Considering that the urea + urease inhibitor treatment resulted in almost comparable improvements of NUE and baking quality, with the additional benefit of reduced N losses in combination with easy handling, urea + urease inhibitor can be recommended as a viable alternative to both urea alone and ammonium nitrate treatments. This opens up an opportunity for the reduction of N loss in wheat production when use of urea is preferred.     

Tomato brown rugose fruit disease: current distribution,knowledge and future prospects

Tomato is the most economically important fruit/vegetable crop grown worldwide. However, viral diseases remain an important factor limiting its productivity, with estimated quantitative and qualitative yield losses in tomato crops often reaching up to 100%. Many viruses infecting tomato have been reported, while new viral diseases have also emerged. The climatic changes the world is experiencing can be a contributing factor to the successful spread of newly emerging viruses, as well as the establishment of disease in areas that were previously either unfavourable or where the disease was absent. Because antiviral products are not available, strategies to mitigate viral diseases rely on genetic resistance/tolerance to infection, control of vectors, improvement in crop hygiene, roguing of infected plants and seed certification. Tomato brown rugose fruit virus (ToBRFV) is an emerging viral threat to tomato productivity and is currently spreading into new areas, which is of great concern to the growing global production in the absence of mitigation measures. This review presents the current knowledge about ToBRFV and future prospects for an improved understanding of the virus, which will be needed to support effective control and mitigation of the impact it is likely to cause.