Gruseck Richard, Palatinszky Marton, Wagner Michael, Hofmann Thilo, Zumstein Michael
Centre for Microbiology and Environmental Systems Science, Department of Environmental Geosciences, University of Vienna, Josef-Holaubeck-Platz 2, 1090 Vienna, Austria.
Doctoral School in Microbiology and Environmental Science, University of Vienna, Djerassiplatz 1, 1030 Vienna, Austria.
MethodsX. 2024 Sep 24;13:102972. doi: 10.1016/j.mex.2024.102972. eCollection 2024 Dec.
The recent discovery of guanidine-dependent riboswitches in many microbes raised interest in the biological function and metabolism of this nitrogen-rich compound. However, very little is known about the concentrations of guanidine in the environment. Several methods have been published for quantifying guanidine and guanidino compounds in human urine and blood, often relying on derivatization followed by fluorescence detection. We adapted this analytical approach using benzoin as the derivatization agent to sensitively and selectively quantify guanidine in environmental samples, thereby facilitating future research on the biological and environmental roles of guanidine. This adapted method was applied to human urine, raw wastewater, and biological growth media as relevant matrices. Our liquid chromatography-tandem mass spectrometry analyses of the derivatized solutions identified a different major derivatization product than previously reported. This product was consistently observed across various substrates (guanidine, methylguanidine, and arginine) and derivatization agents (benzoin and anisoin). We observed a constant background signal, restricting our analyses to a lower limit of quantification of 50 nM. Despite this limitation, our method allowed for the quantification of guanidine concentrations significantly lower than those reported in previous derivatization-based studies.•Selective and sensitive detection of guanidine by LC-MS.•Method development and validation for robust detection of guanidine in environmental samples.•Reduction of sample preparation steps and reduced usage of toxic chemicals compared to previous methods.
最近在许多微生物中发现了依赖胍的核糖开关,这引发了人们对这种富含氮的化合物的生物学功能和代谢的兴趣。然而,人们对环境中胍的浓度知之甚少。已经发表了几种用于定量人尿液和血液中胍和胍基化合物的方法,这些方法通常依赖于衍生化后进行荧光检测。我们采用苯偶姻作为衍生化剂对这种分析方法进行了改进,以灵敏且选择性地定量环境样品中的胍,从而促进未来对胍的生物学和环境作用的研究。这种改进后的方法应用于人类尿液、原废水和生物生长培养基等相关基质。我们对衍生化溶液进行的液相色谱 - 串联质谱分析确定了一种与先前报道不同的主要衍生化产物。在各种底物(胍、甲基胍和精氨酸)和衍生化剂(苯偶姻和茴香偶姻)中均一致观察到该产物。我们观察到一个恒定的背景信号,这将我们的分析定量下限限制在50 nM。尽管有此限制,但我们的方法能够定量的胍浓度显著低于先前基于衍生化的研究所报道的浓度。
•通过液相色谱 - 质谱选择性和灵敏地检测胍。
•开发并验证用于在环境样品中可靠检测胍的方法。
•与先前方法相比,减少了样品制备步骤并减少了有毒化学品的使用。
