超高效液相色谱串联质谱非衍生化法测定土壤中草甘膦及其代谢物氨甲基膦酸含量

为了建立土壤中草甘膦(Glyphosate）及其主要代谢物氨甲基膦酸(AMPA)残留的定量分析方法,采用固相萃取结合液相色谱串联质谱技术,样品以磷酸钠和柠檬酸三钠混合溶液提取,经固相萃取柱净化,采用正向亲水性液相色谱柱(Hilic)梯度洗脱,通过质谱的多反应监测(MRM)负离子模式扫描进行测定,外标法定量。结果表明:草甘膦、氨甲基膦酸的线性范围为0.02~0.2 μg/mL,相关系数(R²)分别为0.9995、0.9998,检出限分别为0.5 μg/kg和0.6 μg/kg,定量限分别为1.6 μg/kg和2.0 μg/kg;3个加标水平草甘膦的回收率在79.67%~96.17%之间,AMPA回收率在77.83%~99.47%之间,RSD值分别为3.95%~7.49%、1.96%~3.89%。与传统的柱前衍生方法相比,具有前处理简单、检出限低、灵敏度高的优点,完全可以适用于土壤中草甘膦的分析。     

Development and identification of glyphosate-tolerant transgenic soybean via direct selection with glyphosate

Glyphosate-tolerant soybean is the most widely planted genetically modified crop worldwide. However, soybean remains recalcitrant to routine transformation because of the low infection efficiency of Agrobacterium to soybean and lack of useful selectable markers. In this study, several Agrobacterium strains and cell densities were compared by transient expression of the GUS gene. The results showed that Agrobacterium strain Ag10 at cell densities of OD_(600) of 0.6–0.9 yielded the highest infection efficiency in Agrobacterium-mediated soybean cotyledonary node transformation system. Meanwhile, a simple and rapid method was developed for identification of glyphosate tolerance in putative T_0 transgenic plants, consisting of spotting plantlets with 1 μL Roundup~?. The whole cycle of genetic transformation could be shortened to about 3 mon by highly efficient selection with glyphosate during the transformation process and application of the spot assay in putative T_0 transgenic plantlets. The transformation frequency ranged from 2.9 to 5.6%. This study provides an improved protocol for development and identification of glyphosate-tolerant transgenic soybeans.     

超高效液相色谱-串联质谱法测定柑橘中的草甘膦及其代谢物残留

本研究首次建立了一种超高效液相色谱-串联质谱法(UHPLC-MS/MS)同时测定柑橘中草甘膦及其代谢物N-乙酰草甘膦?氨甲基磷酸(AMPA)和N-乙酰AMPA?样品经过0.5%甲酸水提取, 以十八烷基硅烷键合硅胶柱(C18)净化, 利用水和200 mmol/L碳酸氢铵溶液(含0.1%氨水)作为流动相梯度洗脱, 在多反应监测模式下定量分析?结果表明, 草甘膦及其代谢物在0.05~1 mg/kg范围内线性关系良好, 相关系数均大于0.99; 草甘膦及其3个代谢物在柑橘全果和果肉基质中3个加标水平下回收率为 70.5%~109.5%, 相对标准偏差(RSD)为0.6%~10.1%, 定量限为0.05 mg/kg?本方法的前处理样品无需衍生, 简便?快捷?高效?准确可靠, 可用于柑橘中草甘膦及其代谢物N-乙酰草甘膦?AMPA和N-乙酰AMPA的定量检测?     

马尾松防火道及果园化学除草试验初报

在马尾松的防火道上用5％森泰颗粒剂和25％森泰水剂、在桃树果园用65％草甘膦和41％春多多进行除草试验。结果表明：马尾松防火道用18．75kg／hm^2的森泰颗粒剂处理效果较好；桃树果园则以1500g／hm^2的草甘膦处理效果最好。     

施用草甘膦对转基因抗除草剂大豆田杂草防除、大豆安全性及杂草发生的影响

【目的】转GAT 和EPSPS 双价基因抗草甘膦大豆‘GE-J16’是我国具有自主知识产权的抗除草剂材料,喷施草甘膦后,评价草甘膦对杂草防除、大豆安全和杂草发生的影响,为其将来商业化种植后的安全监测与杂草治理提供数据支持。【方法】除草效果：每小区以对角线5点取样法取5个0.25 m ²样点并标记,施药后28 d调查禾本科和阔叶杂草株数,并剪取地上部分称取鲜重, 计算株防效和鲜重防效。对大豆安全性：每小区以对角线5点取样法,每点随机取4株大豆并标记,在喷药当天、药后7、14、21及28 d调查大豆株高和复叶数,观察药害,收获前每小区取50株大豆调查结荚数及产量。杂草发生情况：每小区以对角线5点取样法取5个0.25 m ²样点并标记（避开除草效果取样点）,调查并记录每种杂草种类、株数,计算每种杂草相对多度。【结果】转基因大豆喷施900、1 800和3 600 g a.i./hm ²草甘膦对禾本科杂草株防效2016年分别为84.30%、95.22%和83.62%,阔叶杂草株防效分别为49.80%、64.52%和61.93%,禾本科和阔叶杂草鲜重防效分别在95.36%和82.05%以上,2017年对禾本科和阔叶草株防效分别达94.93%和85.09%以上,对禾本科和阔叶杂草鲜重防效分别达98.00%和96.57%以上。转基因大豆喷施草甘膦对大豆生长没有不良影响,产量高于人工除草处理。两年研究结果表明转基因抗除草剂大豆喷施草甘膦后杂草群落发生改变,转基因抗除草剂大豆田不除草处理小区主要优势阔叶杂草为反枝苋（Amaranthus retroflexus）、打碗花（Calystegia hederacea）、马齿苋（Portulaca oleracea）,禾本科杂草为狗尾草（Setaria viridis）、马唐（Digitaria sanguinalis）和牛筋草（Eleusine indica）,共6种,喷施草甘膦900—3 600 g a.i./hm ²后转基因大豆田5种主要优势杂草为打碗花、夏至草（Lagopsis supina）、马齿苋、牛筋草和狗尾草。【结论】转基因抗草甘膦大豆‘GE-J16’喷施草甘膦900—3 600 g a.i./hm ²对杂草有很好的防除效果, 对大豆安全。因此,转基因抗草甘膦大豆‘GE-J16’将在我国有很好的商业化应用前景,喷施草甘膦影响杂草种群的发生,如今后商业化种植需长期密切监测种群变化。     

Review and analysis of the potential for glyphosate to interact with the estrogen,androgen and thyroid pathways

Glyphosate was recently evaluated for its potential to interact with the estrogen, androgen and thyroid (EAT) hormone pathways, including steroidogenesis, under the United States Environmental Protection Agency's (USEPA) Endocrine Disruptor Screening Program (EDSP), then by Germany, the rapporteur Member State who led the European Annex 1 renewal for glyphosate, and then by the European Food Protection Agency (EFSA) also as part of the Annex 1 renewal for glyphosate. Under the EDSP, 11 Tier 1 assays were run following the USEPA's validated 890‐series test guidelines and included five in vitro and six in vivo assays to evaluate the EAT pathways. Steroidogenesis was evaluated as part of the estrogen and androgen pathways. An up‐to‐date critical review has been conducted that considered results from the EDSP Tier 1 battery, guideline regulatory studies and an in‐depth analysis of the literature studies that informed an endocrine assessment. A strength of this evaluation was that it included data across multiple levels of biological organization, and mammalian and nonmammalian test systems. There was strong agreement across the in vitro and in vivo Tier 1 battery, guideline studies and relevant literature studies, demonstrating that glyphosate does not interact with EAT pathways including steroidogenesis. Based on an analysis of the comprehensive toxicology database for glyphosate and the literature, this review has concluded that glyphosate does not have endocrine‐disrupting properties through estrogen, androgen, thyroid and steroidogenic modes of action. © 2020 Society of Chemical Industry     

Effects of Glyphosate on Soil Salinization and Alkalization in Cotton Fields

We analyzed the effects of glyphosate to the index of salinization and alkalization by simulation in soils collected from cotton fields in Anyang, Henan and Anqing, Anhui, China, in 2014. The results showed that application of glyphosate changed electrical conductivity (EC), total alkalinity (TAL), exchangeable sodium percentage (ESP), sodium adsorption ratio (SAR) and pH of soil in both regions，compared with the blank control. With increased frequency of glyphosate application and increased concentration applied, all indices increased in the Anqing cotton fields soil which were treated with concentrations of 2.5-20 g·L^－1 . However, EC, TAL and ESP increased dynamically in Anyang soil to which high concentrations of 20 g·L^－1 were applied only four consecutive times. After different glyphosate treatments, the soil pH value showed an upward trend but smaller changes. Therefore, after repeated use of glyphosate to soils of two different region soils, although the changes of all indices were within the range of non-saline and non-sodic soils, the soils affected by salt in the glyphosate aqueous solution tended towards saline-sodic soils.     

转5-烯醇式丙酮酰莽草酸-3-磷酸合酶(EPSPS)基因抗草甘膦烟草和棉花的获得

以从抗草甘膦的荧光假单胞菌(Pseudomonas fluorescens)G2中克隆的、并按双子叶植物偏爱密码子改造的5-烯醇式丙酮酰莽草酸-3-磷酸合酶(EPSPS)基因aroAG2M为目的基因,用菊花Rubisco小亚基的启动子驱动,在基因的5'端加叶绿体定位信号肽,构建植物表达载体。用根癌农杆菌(Agrobacterium tumefaciens)介导的叶盘法转化烟草(Nicotiana tabacum)获得转基因植株,PCR检测表明,外源基因已整合到烟草基因组中。转基因和非转基因植株6～8叶龄苗的叶片涂抹不同浓度的草甘膦异丙胺盐,表明转基因植株可抗4‰浓度的草甘膦,而非转基因对照植株则在2‰草甘膦时即死亡。花粉管通道法转化棉花(Gossypium hirsutum),得到3株具有草甘膦抗性的转基因植株,PCR和Southern检测显示,外源基因已整合到棉花基因组中,田间喷洒草甘膦异丙胺盐水剂,表明T1代转基因植株具有草甘膦抗性。     

液相色谱串联质谱法检测草铵膦、草甘膦及其代谢物在水和土壤中的残留

利用超高效液相色谱-串联质谱仪(UHPLC-MS/MS),结合固相萃取净化建立了在水和土壤中同时快速测定草甘膦、草铵膦及其6种代谢物的多残留分析方法。前处理采用Oasis MCX和Oasis MAX固相萃取柱提取,2%甲酸甲醇-水(体积比为1∶1)洗脱,旋干后0.1%氨水定容,UHPLC-MS/MS检测。方法的线性范围为0.02～0.5 mg/L;在水中添加水平为0.000 1 mg/L和0.001 mg/L时,草甘膦、草铵膦及其代谢物的回收率为72.8%~94.2%,RSD为2.3%~16.1%;土壤中添加水平为0.001 mg/kg和0.01 mg/kg时,草甘膦、草铵膦及其代谢物的回收率为70.6%~88.5%,RSD为3.6%~12.8%。本方法准确、灵敏、全面,适用于草甘膦、草铵膦及其代谢物在水土环境中的残留检测及监测。