农业绿色高效节水领域研究现状与思考

节水农业是水资源高效利用和农业可持续发展的重大问题，对于节约水资源具有极其重要的意义。为了解当前绿色农业高效节水领域的最新研究热点和发展趋势，本文梳理总结了我国现代化节水农业领域的基础背景、研究现状以及发展态势。结果表明，“灌溉设备与技术开发”、“农业用水精量调配与控制”、“作物高效用水机理”及“农业用水对环境变化的响应”等是近年来的研究热点，并建议开展水肥一体化智能技术与管理及其对作物、土壤、环境、社会等综合效应等的相关研究，以期为我国农业绿色高质量发展提供帮助。     

维生素A对肉牛脂肪沉积及其调控的研究进展

维生素A是肉牛维持正常生理功能、生化代谢及生长发育所必需的一类脂溶性维生素，机体自身不能合成，必须由饲粮供给。饲粮中维生素A不仅影响肉牛视觉和骨骼发育，也对肉牛脂肪沉积和肌肉大理石花纹形成等发挥着重要调控作用。在生产中，肉牛处在不同生理阶段对维生素A的需要量也不同，胎牛和犊牛阶段补充维生素A可增强肌内脂肪细胞发育和脂肪细胞增生，促进肌内脂肪沉积；育肥期限饲维生素A可提高肉牛的肌内脂肪沉积和大理石花纹等级。大理石花纹与牛肉的嫩度和风味密切相关，是衡量牛肉品质的重要指标。维生素A在肉牛体内通过其活性代谢产物视黄醇、视黄醛和视黄酸促进脂肪的形成，并在成脂定型、成脂分化和脂质蓄积的每个阶段都发挥重要作用。脂肪沉积过程受转录因子过氧化物酶体增殖物激活受体（peroxisome proliferator-activated receptors，PPARs）、CCAAT增强子结合蛋白（CCAAT-enhancer binding proteins，C/EBPs）和Janus激酶-信号转导及转录激活因子（JAK-STAT）信号转导通路等调控。表观遗传修饰的DNA甲基化和去甲基化也可通过调控脂肪形成过程中相关基因的表达参与脂肪细胞的分化和脂肪组织的生长发育，从而影响肉牛的脂肪沉积。作者主要介绍了脂肪组织不同阶段的形成过程和维生素A的生物学功能；重点阐述了肉牛在不同生理阶段补充和限饲维生素A，通过转录因子的表达、表观遗传修饰等途径来影响成脂相关信号通路调控脂肪沉积的机理，以期为促进维生素A改善肉牛品质和高档牛肉生产提供参考。     

温度传感器在大功率采煤机摇臂故障诊断技术中的应用

为了减少大功率采煤机的故障率,在典型部件摇臂上安装了温度传感器,及时准确的获取摇臂温度信息,首先通过故障预警使采煤机故障达到防患于未然,然后通过故障信号简便的判断故障产生原因,大大的减少故障率和故障排查与维修时间。此方法结构简单,使用方便,对以后的推广奠定了一定的基础。     

High night-time temperature during flowering and pod filling affects flower opening,yield and seed fatty acid composition in canola

Winter canola (Brassica napus L.) is highly sensitive to increasing temperatures during the reproductive and pod-filling stages. Although the impact of high day-time temperature stress on yield and quality has been documented in canola, similar information under high night-time temperature (HNT) stress is not available. Using six hybrids and four open-pollinated cultivars, we observed a marked shift in peak flowering towards earlier, cooler hours of the morning under HNT. Averaged across two independent experiments, the photochemical efficiency of photosystem II was significantly decreased (3%), with a significant increase in thylakoid membrane damage (13%) in the leaves of susceptible cultivars under HNT stress. Similarly, the susceptible cultivars also recorded significant reduction in biomass (34%), pod number (22%), pod weight (37%) and total seed weight (40%) per plant while the same set of agronomic traits were not affected among the tolerant cultivars. Quantitative impact of heat stress was confirmed with increased sensitivity to HNT exposure from gametogenesis until maturity resulting in a significantly higher yield loss compared to stress exposure from post-flowering till maturity. HNT significantly decreased oil concentration, but increased protein concentration and saturated fatty acid levels in seeds of the susceptible cultivars. However, HNT had no impact on the unsaturated fatty acids in both hybrids and the open-pollinated cultivars. Breeding targets based on fatty acid composition for enhancing canola seed quality may not be easily amenable due to the inconsistency documented with the compositional changes under heat stress. In summary, our findings conclude that canola hybrids are better suited to regions experiencing heat stress, compared to open-pollinated cultivars, indicating the possibility of a complete shift to hybrid canola cultivation under predicted hotter climates in the future.     

不同裂解温度的污泥生物质炭理化特性分析

研究裂解温度对污泥生物质炭基础理化性质的影响,为安全、合理、高效处置污泥提供理论依据。将干燥污泥分别在200、300、500、700℃下进行热裂解处理(SBC200、SBC300、SBC500、SBC700),获得污泥生物质炭,测定其基础理化特性。结果表明：不同温度制备的污泥生物质炭表面颗粒结构完好,孔径范围均集中在10~50 μm,其中低温生物质炭SBC200表面较光滑,最可几孔径和中值孔径最大,分别为20.1 μm和14.8 μm,高温生物质炭SBC700表面较粗糙,比表面积最大,为5.98 m²/g。随裂解温度的提高,污泥生物质炭的产率、含水量、电导率、挥发分、阳离子交换量显著下降,全碳、氧、全氮、氢含量、有效磷和铵态氮均逐渐降低,pH和灰分含量显著增加。将污泥制备成生物质炭,是安全处置污泥的有效途径,低温制得的污泥生物质炭具有更大的提高土壤肥力的潜力,而高温制得的生物质炭在改良土壤酸性的应用上具有更大的潜力。     

光对园艺植物花青素生物合成的调控作用

花青素是植物中一类重要的类黄酮化合物,在植物花朵、果实等器官色泽形成和抗氧化过程中起着重要作用。植物组织中花青素的形成依赖于光信号,但是光信号对花青素生物合成的调控机制及信号网络很大程度上还不清晰。本文简述了花青素生物合成及运转过程的研究进展,简要归纳了MYB、bHLH、WDR三类主要因子对花青素合成的转录调控作用,重点阐释光信号（光强、光质、光照时长）对植物花青素合成的调控作用。研究表明,光环境（光强、光质、光照时长）主要通过不同的光受体（UVR8、CRYs、PHOTs、PHYs）影响光信号通路重要因子COP1的泛素化能力和HY5的稳定性,以及其他光信号转录因子如光敏色素互作因子PIFs的稳定性,进而调控花青素的生物合成过程。这些光信号因子一方面直接结合到调控花青素合成的MYB、bHLH、WDR三大类转录因子上,转录激活或抑制它们的表达进而调控花青素的合成;另一方面,这些光信号因子通过与MYB、bHLH、WDR三大类转录因子蛋白互作,影响它们形成的MBW复合体稳定性,进而调控花青素的合成。此外,这些光信号因子还可以通过不依赖于MBW复合体的通路调控花青素的合成,如HY5通过调控miR858影响花青素的生物合成;另外,一些未知的光响应因子可能以不依赖MBW通路的方式直接或间接地调控花青素合成基因和液泡膜上的运转蛋白,改变液泡酸化,调节花青素的合成。同时,光信号会影响光合电子传递,光合电子传递链中的一些因子也会通过依赖和不依赖MBW的途径影响植物花青素的合成。这些途径如何协调以及哪些信号因子优先受光环境（光强、光质、光照时间）调控?本文为深入研究光信号对花青素生物合成的调控机理提供参考,以探索光调控花青素积累的有效途径及靶标分子,为利用基因工程、代谢工程和光环境调控手段改良园艺植物花青素积累提供理论基础。     

Soil physical changes and maize growth in a structurally fragile tropical soil due to mulching and duration between irrigation intervals

Under tropical meteorological conditions, the volume of soil explored by plant roots is crucial for crop growth as it allows increased water and nutrient use efficiency. We hypothesized that, under different irrigation intervals, leguminous mulch can extend the duration between irrigation events but maintain crop performance, because decreased evaporative fluxes also reduce constraints to root exploration imposed by mechanical stress. We evaluated the combined effects of leguminous mulch and irrigation intervals on soil physical properties to determine whether the growth and productivity of maize were modified in a structurally fragile tropical soil. The experiment involved the following treatments: 4‐day irrigation intervals with soil mulched (4C) or bare (4S), 6‐day irrigation intervals with soil mulched (6C) or bare (6S), 8‐day irrigation intervals with soil mulched (8C) or bare (8S) and 10‐day irrigation intervals with soil mulched (10C) or bare (10S). Mulch decreased soil penetration resistance and increased to 4 days the favourable time for root development in drying soil. Relative to bare soil, mulch with a 6‐day irrigation interval almost doubled nitrogen uptake post‐tasselling, which decreased nitrogen remobilization and increased the crop growth rate during this stage. These conditions had a positive effect on the transpiration rate and stomatal conductance as well as on the growth and yield of maize. A 6‐day irrigation interval with mulch compared to 4 days with bare soil resulted in similar conditions for root development, but greater uptake of nitrogen (102.73–78.70 kg/ha) and better yield (6.2–5.3 t/ha), which means greater efficiency in nitrogen and water use.     

高温闷棚技术在大棚辣椒连作生产上的应用

为研究大棚辣椒土传病害绿色防控技术,选择不同的高温闷棚杀菌方法,以本地传统的高温炕地杀菌方法为对照,调查不同处理对地温和土壤pH值的影响,调查不同处理大棚辣椒的根结线虫、疫病、枯萎病、青枯病和根腐病的发生为害情况,测量大棚辣椒产量。结果表明,应用石灰氮、覆盖地膜和大棚膜进行高温闷棚对大棚辣椒土传病害有较好的防治效果。     

Azospirillum brasilense mitigates water stress imposed by a vascular disease by increasing xylem vessel area and stem hydraulic conductivity in tomato

Water stress, with its negative consequences on plant growth and survival, can be mitigated by Azospirillum brasilense inoculation. In tomato, A. brasilense delays wilting caused by a vascular pathogen, Clavibacter michiganensis subsp. michiganensis, by yet unknown mechanisms. We studied morphological, anatomical and physiological changes induced by A. brasilense in tomato that relate to water stress tolerance, which could explain the deferral in symptom expression. For this purpose, tomato seeds were treated or not with A. brasilense BNM65, and 5 weeks later plants were challenged with C. michiganensis subsp. michiganensis or mock inoculated with water. There was a large growth promotion associated to Azospirillum: treated plants had higher total biomass and leaf area. In relation to water stress tolerance, Azospirillum treated plants had larger xylem vessel area, higher stem specific hydraulic conductivity, thicker stems, and lower shoot/root dry matter and specific leaf area. These changes were opposite to those induced by C. michiganensis subsp. michiganensis. We conclude that A. brasilense favoured a better adjustment of plant-water relations by several mechanisms, and thus, transitorily alleviated symptoms expression of a vascular disease.     

Variations of SOC and MBC observed in an incubated brown loam soil managed under different tillage systems for 12 years

To assess changes in organic carbon pools, an incubation experiment was conducted under different temperatures and field moisture capacity (FMC) on a brown loam soil from three tillage practices used for 12 years: no‐till (NT), subsoiling (ST) and conventional tillage (CT). Total microbial respiration was measured for incubated soil with and without the input of straw. Results indicated that soil organic carbon (SOC) and microbial biomass carbon (MBC) under ST, NT and CT was higher in soil with straw input than that without, while the microbial quotient (MQ or MBC: SOC) and metabolic quotient (qCO₂) content under CT followed the opposite trend. Lower temperature, lower moisture and with straw input contributed to the increases in SOC concentration, especially under NT and ST systems. The SOC concentrations under ST, with temperatures of 30 and 35°C after incubation at 55% FMC, were greater than those under CT by 28.4% and 30.6%, respectively. The increase in MBC was highest at 35°C for 55%, 65% and 75% FMC; in soil under ST, MBC was greater than that under CT by 199.3%, 50.7% and 23.8%, respectively. At 30°C, the lower qCO₂ was obtained in soil incubated under NT and ST. The highest MQ among three tillage practices was measured under ST at 55% FMC, NT at 65% FMC and CT at 75% FMC with straw input. These data indicate the benefits of enhancing the MQ; the low FMC was beneficial to ST treatment. Under higher temperature and drought stress conditions, the adaptive capacity of ST and NT is better than that of CT.