辣椒单株结果数性状的主基因+多基因遗传分析

为探究辣椒单株结果数的遗传机制,以单株结果数差异较大的辣椒材料XHB(P₁)和B14-01(P₂)为亲本,构建四世代遗传家系即P₁、P₂、F₁、F₂。运用主基因+多基因多世代联合分析法,研究辣椒单株结果数的遗传规律。结果表明：辣椒单株结果数符合2对加性-显性-上位性主基因模型(2MG-ADI)。2对主基因的加性效应值d_a、d_b分别为-16.33、-13.05,2对主基因的显性效应值h_a、h_b分别为-10.02、-2.51。2对主基因间的加性×显性(j_ab)互作效应和显性×加性(j_ba)互作效应的效应值分别为8.69和12.93,加性×加性上位性(i)互作效应值为6.86,显性×显性(l)的互作效应值为7.23,主基因间的效应以加性效应为主,其次是加性×显性上位性互作效应。主基因遗传率为68.10%,环境引起的变异占比31.9%...     

番茄基因组DNA不同微量提取方法的比较及适用性分析

为了探究不同基因组DNA提取方法在生物学试验中适用性问题,采用5种方法提取番茄基因组DNA,并通过琼脂糖凝胶电泳、微量紫外分光光度计、聚合酶链式反应(PCR)比较提取的DNA浓度、质量及适用性。结果显示,碱裂解煮沸法成本低、操作简便,但所提取的DNA浓度最低,质量最差,只适合一般PCR检测试验;SDS冰浴法和改良的CTAB法操作步骤多、程序复杂,提取的DNA浓度和质量好,通用性最强,但所用试剂具有毒性;高盐低pH法和PVP-40法操作简单,提取的DNA浓度和质量较好,具有一定的通用性,且所用试剂无毒,建议一般性的生物学试验可优先考虑这两种方法。     

花魔芋响应软腐病菌侵染初期的转录组分析

为探讨花魔芋抵御软腐病害的分子机制,分别以染病初期和健康的花魔芋球茎为材料进行转录组测序。结果表明,健康和染病初期花魔芋两组出现3222个差异表达基因,其中2660个基因上调表达,562个基因下调表达,差异表达基因主要涉及细胞组分、生物学过程及分子功能等生理生化过程。表达量上调和下调最大的前10个基因包含编码MiAMP1抗菌蛋白、热激蛋白、胰蛋白酶与蛋白酶抑制剂、胰凝乳蛋白酶抑制剂等与抗病相关的基因。GO功能分类和KEGG通路分析表明,类黄酮和苯丙烷类物质在花魔芋抵御软腐病菌侵染初期发挥重要作用。值得关注的是,硒化合物代谢、维生素B6代谢、类黄酮生物合成、N-聚糖生物合成及链霉素生物合成通路等抗病相关的差异表达基因在花魔芋染病初期全部或大部分受诱导表达。利用高通量测序获得大量花魔芋转录组信息,有助于挖掘与花魔芋抗软腐病相关的关键基因,也为魔芋抗病分子育种提供理论参考。     

氮、钾用量对机采加工番茄果实成熟、产量及品质的影响

为探索适合新疆地区膜下滴灌机械采收加工番茄的施肥规律,研究不同氮肥(N)、钾肥(K)及交互作用(N×K)对机械采收加工番茄果实成熟、产量及品质的影响,设置氮肥和钾肥二因素随机区组试验,设计9个处理,3次重复。结果表明不同N、K用量及其互作对加工番茄果实物质积累量、单果质量、果实红熟率、产量、可溶性固形物含量、番茄红素含量影响显著,对果实叶绿素含量、β-胡萝卜素含量、L值影响不显著。N₂K₂、N₂K₃、N₃K₂条件下加工番茄产量≥16.12×10⁴kg·hm^-2、成熟度≥93.29%、果实固形物含量≥5.22%、番茄红素含量≥21.38mg·hg^-1,可满足机械采收对加工番茄的要求。通过经济效益分析推荐施肥量为N 152.1 kg·hm^-2,K₂O 118.2kg·hm^-2。     

设施番茄灰霉病气象指标及其生态防治措施

设施番茄灰霉病是由气象因子影响的一种重危害、高损失的真菌性病害。通过多年的观测调查发现：当连续10日及以上设施内日平均气温≥14.8℃、相对湿度≥90%、出现连阴或者连续多云寡照天气时,番茄就会出现灰霉病。番茄灰霉病不仅会导致番茄果实腐烂落果,造成减产甚至绝产,还会影响番茄品质。结合病虫害防治调查及农业气象试验,提出了选用抗病毒品种、改善设施内气象条件等减少番茄灰霉病发生的生态防控措施。     

基于液压加载的拖拉机PTO测试装置设计与试验

针对当前多数负荷车仅适用于拖拉机牵引试验测试,模拟完整田间作业状态不全面的现状,设计了一种可挂接负荷车的液压加载式拖拉机动力输出轴测试装置,在满足负荷车牵引试验国标要求的基础上可以进行拖拉机PTO测试试验。该装置采用的液压测功机与应用普遍的直流电力测功机经过试验对比,系统响应和稳定速度更快,综合加载性能更好。对该测试设备进行拖拉机PTO田间转矩载荷谱模拟动态加载试验,结果显示：实际加载转矩与转矩载荷谱试验数据相关性良好,拟合优度为0.83。通过数据分析计算实际液压加载系统响应时间约为2.1s,最大超调量为7.52%,均在可控范围内。说明该测试设备可以通过输入转矩载荷谱的形式有效模拟田间作业拖拉机PTO工作状态,为后续拖拉机牵引及转矩全面加载田间模拟试验提供参考。     

DMPP mitigates N2O and NO productions by inhibiting ammonia-oxidizing bacteria in an intensified vegetable field under different temperature and moisture regimes

Vegetable soils with high nitrogen input are major sources of nitrous oxide (N₂O) and nitric oxide (NO), and incorporation of the nitrification inhibitor 3, 4-dimethylpyrazole phosphate (DMPP) into soils has been documented to effectively reduce emissions. However, the efficiency of DMPP in terms of soil N₂O and NO mitigations varies greatly depending on soil temperature and moisture levels. Thus, further evaluations of DMPP efficiency in diverse environments are required to encourage widespread application. A laboratory incubation study (28 d) was established to investigate the interactive effects of DMPP, temperature (15, 25, and 35 ℃), and soil moisture (55% and 80% of water-holding capacity (WHC)) on net nitrification rate, N₂O and NO productions, and gene abundances of nitrifiers and denitrifiers in an intensive vegetable soil. Results showed that incubating soil with 1% DMPP led to partial inhibition of the net nitrification rate and N₂O and NO productions, and the reduction percentage of N₂O production was higher than that of NO production (69.3% vs. 38.2%) regardless of temperature and soil moisture conditions. The increased temperatures promoted the net nitrification rate but decreased soil N₂O and NO productions. Soil moisture influenced NO production more than N₂O production, decreasing with the increased moisture level (80%). The inhibitory effect of DMPP on cumulative N₂O and NO productions decreased with increased temperatures at 55% WHC. Conversely, the inhibitory effect of DMPP on cumulative N₂O production increased with increased temperatures at 80% WHC. Based on the correlation analyses and automatic linear modeling, the mitigation of both N₂O and NO productions from the soil induced by DMPP was attributed to the decreases in ammonia-oxidizing bacteria (AOB) amoA gene abundance and NO^-₂-N concentration. Overall, our study indicated that DMPP reduced both N₂O and NO productions by regulating the associated AOB amoA gene abundance and NO^-₂-N concentration. These findings improve our insights regarding the implications of DMPP for N₂O and NO mitigations in vegetable soils under various climate scenarios.     

Remediation of amide pesticide-polluted soils by combined solarization and ozonation treatment

Agriculture has a close relationship with nature, but it can also be the source of negative and permanent environmental effects. The use of pesticides in modern agriculture is a common practice, but their side effects on the environment cannot be disregarded. In this study, we evaluated a combination of solarization and ozonation techniques for the elimination of six amide pesticides (boscalid, chlorantraniliprole, cyflufenamid, fluopyram, napropamide, and propyzamide) in soil. Initial experiments were performed with four different soils to assess the efficiency of this methodology at different soil temperatures and ozone dosages under laboratory conditions, and then a greenhouse pot experiment was conducted under controlled conditions during summer. Fifty days after the onset of the experiments, higher degradation percentages of amide pesticides were observed in ozonized soils than in other treated soils, particularly when ozone was applied at 10 cm soil depth. The results show that the utilization of ozonation, along with solarization, represents a valid method for degrading residues of the studied pesticides and suggest that this combined technology may be a promising tool for remediating pesticide-polluted soils.     

Resistance and resilience of soil biological indicators: A case study with multi-walled carbon nanotube

Soil ecosystem is experiencing stresses due to climate change, and soil inhabitants try to demonstrate their inherent resistance and resilience against those stresses. Application of nanomaterials as agricultural inputs could bring shifts in resistance and resilience patterns of soil microbes and associated enzymes, especially under short-term heat stress. With this background, the impacts of multi-walled carbon nanotube (MWCNT) on the resistance and resilience of soil biological indicators were evaluated. An incubation experiment was conducted with varied MWCNT concentrations (0, 50, 100, 250, and 500 mg kg^-1 soil) for 90 d after 24-h heat stress at 48 ±2 ℃ to assess the impacts of MWCNT on soil enzyme activities and microbial populations vis-à-vis their resistance and resilience indices under short-term exposure to heat stress. Enzyme activities were reduced after exposure to heat stress. Resistance indices of enzyme activities were enhanced by MWCNT application on day 1 after heat stress, whereas there was no recovery of enzyme activities after 90-d incubation. Like soil enzyme activities, resistance index values of soil microbial populations followed the similar trend and were improved by MWCNT application. Multi-walled carbon nanotube has the potential to improve resistance indices of soil enzyme activities and microbial populations under heat stress, although they could not recover to their original state during periodical incubation after heat stress. This study helps to understand the relative changes of biological indicators under MWCNT and their ability to withstand heat stress.     

秸秆还田深度对春玉米农田土壤有机碳、氮含量和土壤酶活性的影响

为研究秸秆还田旋耕深度对土壤理化性质和酶活性的影响,明确不同秸秆还田深度条件下土壤理化性质与酶活性的关系,在3年（2016—2018年）田间微区定位试验条件下,研究秸秆旋耕还田10 cm（S₁D₁）、20 cm（S₁D₂）、30 cm（S₁D₃）和秸秆移除旋耕10 cm（S₂D₁）、20 cm（S₂D₂）、30 cm（S₂D₃） 6个处理对东北春玉米农田土壤理化性质和酶活性的影响。结果表明：旋耕深度（D）及其与秸秆处理（S）交互作用（S×D）显著影响土壤有机碳（SOC）含量,0~20 cm土层S₁D₁、S₁D₂处理SOC含量较S₁D₃处理高1.2%~16.0%,而20~40 cm土层S₂D₃处理SOC含量最高。旋耕深度、秸秆处理及两者交互作用对土壤硝态氮（NO₃^--N）和铵态氮（NH₄⁺-N）含量、蔗糖酶和过氧化氢酶活性影响显著。在0~40 cm土层,D₁、D₂旋耕深度下秸秆还田处理NO₃^--N含量比秸秆移除处理平均提高46.9%和34.9%,NH₄⁺-N含量平均降低31.6%和4.4%。在各旋耕深度下,S₁处理0~20 cm土层蔗糖酶和脲酶活性高于S₂处理,20~30 cm土层过氧化氢酶活性低于S₂处理。相关性分析表明,SOC、土壤全氮（TN）与NO₃^--N、NH₄⁺-N含量和蔗糖酶活性呈显著正相关,与pH、土壤含水量（SWC）呈显著负相关。主成分分析表明,与S₁D₁相比,S₁D₂对0~20土层蔗糖酶、脲酶、过氧化氢酶活性和0~40 cm土层SOC、TN含量影响更明显。综上所述,秸秆旋耕还田20 cm可改善0~40 cm土层养分水平,提高土壤酶活性,推荐为东北春玉米产区农田土壤培肥的合理秸秆还田方式。