不同供磷水平对胡麻磷素养分转运分配及其磷肥效率的影响简

 以“坝选３号”胡麻为材料，研究了不施磷、低磷、中磷和高磷４ 个不同施磷（Ｐ_２Ｏ_５）水平（０，３５，７０ 和１０５ｋｇ／ｈｍ^２）对胡麻植株中磷素累积、转运、分配和磷肥利用效率的影响。结果表明，低磷、中磷和高磷水平时，胡麻各器官不同生育阶段磷素养分吸收和累积量的基本趋势一致，但其变化量与施磷量有极大关系。胡麻地上茎、叶、非籽粒和籽粒中，磷素的日增量增幅因器官而异；胡麻只有叶片中有磷素转移，中磷处理比低磷和高磷处理磷转移量增加５４．９３％～７３．８３％和８．１９％～１０．００％（P＜０．０５），籽粒中２０．４６％～３５．９３％ 的磷素是靠叶片转运而来。胡麻植株磷素累积主要在生殖生长阶段，占整个生育期总累积量的７９．０２％～９２．１７％。施磷（Ｐ_２Ｏ_５）量为７０ｋｇ／ｈｍ^２时磷肥表观利用率和农学效率最高，分别为２０．２２％～２０．５３％和７．３０～７．４４ｋｇ／ｋｇ。胡麻产量随施磷量增加而增加，增幅最高达２８．９６％～３１．４６％。结合产量与磷肥表观利用率和农学效率，本实验区同等肥力土壤条件下，以施磷（Ｐ_２Ｏ_５）量为７０ｋｇ／ｈｍ^２（中磷）为宜。     

我国蔬菜肥料利用率现状与提高对策

我国露地蔬菜种植和设施蔬菜种植养分用量均超过蔬菜生长所需,导致土壤次生盐渍化、肥料利用率低,增加了面源污染风险,在分析这些现状的基础上,对造成蔬菜种植中氮、磷、钾肥料利用率低下的原因进行了分析,如有机肥与化肥施用配比随意性强,搭配不合理;氮、磷、钾肥配施比例不合理;大量元素与中微量元素配合施用不合理;肥料总施用量过大;土壤自身的原因等。并提出了提高肥料利用率的测土与科学配方施肥、有机肥与无机肥合理配合施用、采用水肥一体化技术和土壤调理剂等措施,有望提高我国蔬菜肥料利用率,节约资源,防止面源污染,实现蔬菜生产的可持续绿色发展。     

适用于转录组测序的大白菜小孢子总RNA提取方法筛选

为了找到适用于转录组测序要求的大白菜小孢子总RNA 提取方法，以出胚率较高的吉红82 为试材，以热激诱导处理后的小孢子为研究对象，比较分析了TRIzol 法、改良CTAB 法及超纯试剂盒法3 种方法的RNA 提取效果。结果表明：TRIzol法（磨样）和改良CTAB 法提取的RNA 浓度较高，但完整性较差；超纯RNA 提取试剂盒法提取的RNA 质量最高，且完整性好，能够满足转录组测序的要求。     

枯草芽孢杆菌在番茄病害防治上的应用与研究进展

综述了枯草芽孢杆菌在防治植物病害中的生防机制,包括竞争作用、拮抗作用、溶菌作用、诱导植物产生抗性和促进植物生长5个方面,介绍了枯草芽孢杆菌在6种番茄病害即灰霉病、青枯病、早疫病、立枯病、枯萎病、根腐病防治中的应用,并对其应用中存在的主要问题进行了总结、前景进行了展望。     

便携式XRF仪现场快速测定土壤中Pb的可行性研究

便携式XRF分析仪具有轻便、快速和可测对象较多与测量元素较广等特点而广泛应用于矿石、土壤等方面快速检测,但土壤的现场快速测定结果的准确性有待进一步研究与探讨。以安宁河谷平原土壤中Pb为研究对象,通过对便携式XRF仪现场快速检测结果与实验室分析结果的对比和影响因素的分析,建立基于安宁河谷平原表层土壤快速测定结果的线性函数为y=1.170 9x-17.326 0(R~2=0.992 9,x为现场检测结果),探讨其影响因素,为该区域表层土壤中Pb快速检测结果提供依据。     

胡萝卜根中主要类胡萝卜素含量相关QTL的精细定位

以白色的野生胡萝卜‘松滋野生’(Ws)和橘色的栽培胡萝卜品种‘Amsterdam’(Af)为亲本构建的回交重组自交系(BIL)为试材,基于低倍重测序技术开发SNP标记,构建了由1 976个Bin标记组成,包含29 435个SNP标记的遗传图谱。图谱总距离834.28 c M,平均图距0.42 c M。通过对胡萝卜肉质根中类胡萝卜素含量相关QTL分析,在连锁群LG04和LG08中检测到调控α–胡萝卜素、β–胡萝卜素、ζ–胡萝卜素、叶黄素、玉米黄质和总类胡萝卜素含量的主效QTL(M-QTL)2、2、3、2、2和2个,表型贡献率为11.47%~19.18%;另检测到调控α–胡萝卜素、β–胡萝卜素、ζ–胡萝卜素、玉米黄质和总类胡萝卜素含量的上位性QTL(E-QTL)1、1、2、1和1个,表型贡献率为2.50%~3.66%。在M-QTL显著区间内共检索到36个有功能注释的预测基因,其中Dck018297为ζ–胡萝卜素脱氢酶2基因,与调控β–胡萝卜素合成和总类胡萝卜素含量有关;Dck008006为乙烯响应因子2.2的同源基因,与调控α–胡萝卜素、ζ–胡萝卜素合成有关;Dck029898为转录因子b HLH135的同源基因,与调控玉米黄质合成有关。     

Analysis of the independent-and interactive-photo-thermal effects on soybean flowering

Soybean(Glycine max(L.) Merr.) is a typical short-day and warm season plant, and the interval between emergence and flowering has long been known to be regulated by environmental factors, primarily photoperiod and temperature. While the effects of photoperiod and temperature on soybean flowering have been extensively studied, a dissection of the component photo-thermal effects has not been documented for Chinese germplasm. Our objective of the current study was to evaluate the independent- and interactive-photo-thermal responses of 71 cultivars from 6 ecotypes spanning the soybean production regions in China. These cultivars were subjected in pot experiments to different temperature regimes by planting in spring(low temperature(LT)) and summer(high temperature(HT)), and integrating with short day(SD, 12 h), natural day(ND, variable day-length), and long day(LD, 16 h) treatments over two years. The duration of the vegetative phase from emergence to first bloom(R1) was recorded, and the photo-thermal response was calculated. The outcome of this characterization led to the following conclusions:(1) There were significant differences in photo-thermal response among the different ecotypes. High-latitude ecotypes were less sensitive to the independent- and interactive-photo-thermal effects than low-latitude ecotypes; and(2) there was an interaction between photoperiod and temperature, with the effect of photoperiod on thermal sensitivity being greater under the LD than the SD condition, and with the effect of temperature on photoperiodic sensitivity being greater under the LT than the HT condition. The strengths and limitations of this study are discussed in terms of implications for current knowledge and future research directions. The study provides better understanding of photo-thermal effects on flowering in soybean genotypes from different ecotypes throughout China and of the implications for their adaptation more broadly.