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中关村NMT联盟“一带一路”全国测试服务网络测试服务信息

4月8日,某研究所将NMT技术应用于钙信号研究,测试样品为小麦,测试指标为Ca2+,在旭月研究院完成实验。| 5月9号,某研究院将NMT技术应用于逆境生理领域,测试样品为黄瓜幼苗,测试指标为NO3-、NH4+,在旭月研究院完成实验。| 6月2号,某研究院将NMT技术应用于逆境胁迫领域,测试样品为棉花苗,测试指标为Ca2+、H+、K+、Na+、IAA,在旭月研究院完成实验。| 6月5号,某研究院将NMT技术应用于植物逆境领域,测试样品为苜蓿,测试指标为K+,在旭月研究院完成实验。| 6月9号,某研究所将NMT技术应用于水稻逆境领域,测试样品为水稻,测试指标为Na+、Ca2+,在中国科学院植物研究所完成实验。| 6月11号,某研究院将NMT技术应用于植物抗逆领域,测试样品为酵母细胞,测试指标为IAA,在旭月研究院完成实验。| 6月16号,某高校将NMT技术应用于昆虫研究,测试样品为昆虫,测试指标为Ca2+、K+,在旭月研究院完成实验。| 6月19号,某研究院将NMT技术应用于植物抗逆领域,测试样品为拟南芥,测试指标为Ca2+,在旭月研究院完成实验。|

NMT历史上的今天丨AGR ECOSYST ENVIRON、Ecotoxicol Environ Saf 文章发表


NMT历史上的今天

2018年10月22日,福建农林大学林文雄、林生利用NMT在Agriculture, Ecosystems and Environment上发表了标题为Rhizosphere responses to environmental conditions in Radix pseudostellariae under continuous monoculture regimes的研究成果。

 

 

  • 期刊:Agriculture, Ecosystems and Environment
  • 主题:连续单培养条件下假星豆根际对环境条件的响应
  • 标题:Rhizosphere responses to environmental conditions in Radix pseudostellariae under continuous monoculture regimes
  • 影响因子:3.541
  • 检测指标:H+流速
  • 作者:福建农林大学林文雄、林生

英文摘要

The root exudates of Radix pseudostellariae, working as a rhizospheric intermediary between plants and microbes, can deteriorate the microbial community in the rhizosphere in a consecutive monoculture system.

We assessed the effects of artificially applied R. pseudostellariae root exudates on R. pseudostellariae seedling growth, rhizo-sphere soil microbial communities, and soil physicochemical properties. We found that phenolic acids and or-ganic acids acted as a driver of changes in the microbial community. High-throughput sequencing and qRT-PCR analysis demonstrated that treatment with phenolic acids significantly decreased the relative abundance of Trichoderma, Penicillium, Pseudomonadales, Xanthomonadales, and Streptomycetales.

Organic acids had a sig-nificant negative effect on the relative abundance of Pseudomonadales and Streptomycetales and significantly increased the abundance of Fusarium, Xanthomonadales, Micrococcales, and Gemmatimonadales. Analysis based on the noninvasive microtest technique indicated that root exudates increased H+ efflux and plasma membrane H+-ATPase activity in the pathogenic fungi and decreased them in the beneficial fungi.

These phenomena created an acidic environment for the inhibition of beneficial bacteria and accumulation of specialized plant pathogens. This study explains the mechanisms underlying the shift in microflora and structural disorder caused by root exudates in continuously monocultured R. pseudostellariae rhizosphere soil through responses to en-vironmental conditions.

 

中文摘要(谷歌机翻)

在植物和微生物之间作为根际中介体工作的伪星根的根系分泌物会在连续的单培养系统中破坏根际微生物群落。

我们评估了人工施用的拟星果根分泌物对拟星果幼苗生长,根际土壤微生物群落和土壤理化特性的影响。我们发现酚酸和有机酸是微生物群落变化的驱动力。高通量测序和qRT-PCR分析表明,用酚酸处理可显着降低木霉菌,青霉菌,假单胞菌,黄单胞菌和链霉菌的相对丰度。

有机酸对假单胞菌和链霉菌的相对丰度有明显的负面影响,并显着增加了镰刀菌,黄单胞菌,微球藻和Gemmatimonadales的丰度。基于非侵入性微测试技术的分析表明,根系分泌物增加了病原真菌中的H +流动和质膜H+ -ATPase活性,而减少了其有益真菌中的H+酶和质膜H+ -ATPase活性。

这些现象为抑制有益细菌和特殊植物病原体的积累创造了酸性环境。这项研究解释了通过对环境条件的响应,在连续单培养的假星菌根际土壤中根系分泌物引起的微孔和结构紊乱转变的潜在机制。

Fig. 7. Effect of Fusarium oxysporum on steady H+ fluxes in R. pseudostellariae roots. CK represents roots without F. oxysporum stimulation;F. oxysporum re-presents roots stimulated with F. oxysporum.

文章链接:https://linkinghub.elsevier.com/retrieve/pii/S0167880918304377

2018年10月22日,华中农业大学孙学成、史凯丽利用NMT在Ecotoxicology and Environmental Safety 上发表了标题为Non-invasive microelectrode cadmium flux measurements reveal the decrease of cadmium uptake by zinc supply in pakchoi root (Brassica chinensis L.)的研究成果。

 

  • 期刊:Ecotoxicology and Environmental Safety
  • 主题:非侵入式微电极镉通量测量显示小菜根(甘蓝)中锌供应对镉吸收的减少
  • 标题:Non-invasive microelectrode cadmium flux measurements reveal the decrease of cadmium uptake by zinc supply in pakchoi root (Brassica chinensis L.)
  • 影响因子:3.974
  • 检测指标:Cd2+流速
  • 检测部位:小白菜根部(距离静止中心200μm)
  • 作者:华中农业大学孙学成、史凯丽

英文摘要

Zinc (Zn) possesses similar properties to cadmium (Cd) and inhibits Cd uptake in plants. To get more detailed mechanisms of Zn-inhibited Cd uptake in pakchoi, a hydroponic experiment was conducted to investigate the effects of various Zn levels on Cd concentrations, real time flux of Cd, expressions of genes related to Cd uptake under Cd exposure.

The results showed that the Cd concentrations and Cd accumulations in pakchoi root de-creased with increasing Zn levels, which were coincident with that real time Cd influx and net Cd influx of pakchoi root decreased with increasing Zn levels by non-invasive micro-test technology (NMT). Additionally, the expressions of Cd-related transporters including BcNRAMP5, BcIRT1 and BcMGT1 decreased with the increase of Zn levels under Cd exposure, especially BcIRT1 with the highest decreased rates. Furthermore, the expressions of these genes decreased gradually with the prolongation of Zn treated time under Cd toxicity.

The results indicate that Zn inhibits Cd uptake by inhibition of the expressions of Cd-related transporters, especially BcIRT1 in pakchoi root.

 

中文摘要(谷歌机翻)

锌(Zn)具有与镉(Cd)相似的特性,并抑制植物中Cd的吸收。为了更详细地了解小白菜中Zn抑制Cd吸收的机理,进行了水培试验,研究了各种Zn水平对Cd浓度,Cd实时通量以及Cd暴露下与Cd吸收有关的基因表达的影响。

结果表明,通过无创微试验技术,小白菜根中的Cd浓度和Cd积累量随Zn水平的升高而降低,这与小菜根的实时Cd输入量和Cd净含量随Zn含量的增加而降低。 (NMT)。另外,随着镉暴露下锌水平的升高,包括BcNRAMP5,BcIRT1和BcMGT1在内的Cd相关转运蛋白的表达下降,尤其是下降率最高的BcIRT1。此外,随着镉对镉的毒害作用时间的延长,这些基因的表达逐渐降低。

结果表明,Zn通过抑制小白菜根中Cd相关转运蛋白特别是BcIRT1的表达来抑制Cd的吸收。

NMT历史上的今天丨AGR ECOSYST ENVIRON、Ecotoxicol Environ Saf 文章发表

Fig. 3. Effects of Zn on net Cd2+ influxes in root of pak-choi by Non-invasive micro-test technology. The 10 d pakchoi seedlings treated with Zn deficiency Hoagland solution were used to analyze the Cd influx. The Zn con-centrations of 0 (Zn 0), 1 (Zn 1), 5 (Zn 5) and 10 μM (Zn 10) represented that the concentrations of Zn were added the basic solution containing 9 μM Cd. (A) The steady-state Cd2+ influx before and after the Zn supply into the basic solution. (B) Mean rates of Cd2+ influx of the time in A. Each point represents the mean of six roots from six in-dividual plants. Data are the means of 6 replicates ± standard error. Different lowercase represents significant differences between treatments (p < 0.05).

文章链接:https://doi.org/10.1016/j.ecoenv.2018.10.081