Ageitos Lucía, Buedenbender Larissa, Escribano M Pilar, Forero Abel Mateo, Santos Beatriz, Balado Miguel, Lemos Manuel L, Magariños Beatriz, Rodríguez Jaime, Jiménez Carlos
Departmento de Química, Facultad de Ciencias and CICA - Centro Interdisciplinar de Química e Bioloxía, Universidade da Coruña, 15071 A Coruña, Spain.
Department of Microbiology and Parasitology, Aquatic One Health Research Center (iARCUS), Universidade de Santiago de Compostela, 15705 Santiago de Compostela, Spain.
Anal Chem. 2025 Jul 1;97(25):13376-13385. doi: 10.1021/acs.analchem.5c01687. Epub 2025 Jun 16.
Hydroxamate siderophores are key virulence factors in multiple pathogens, and their structures present interesting scaffolds for potential biotechnological applications such as the design of novel antimicrobials. However, their variable and scarce production, their low stability, and occurrence as complex mixtures in natural samples complicate their analysis. Herein, we present a new strategy, named XAD-LC/MS-FBMN-IMS, which enables the analysis of the -hydroxamate siderophore composition from microbial cultures by integrating traditional XAD resin extraction, modern Feature-Based Molecular Networking (FBMN) tools, and a novel direct infusion ion mobility mass spectrometry validation approach. Using ferrioxamine as a model, XAD resins demonstrated high efficiency in extracting hydroxamate siderophore metal complexes when compared to other sorbents. This strategy was applied for detecting the siderophores produced by , a relevant pathogenic bacterium in fish aquaculture. This analysis unveiled three families of hydroxamate siderophores, including three known desferrioxamine derivatives along with 17 new putative acyl-desferrioxamine-like structures. Overall, the XAD-LC/MS-FBMN-IMS strategy significantly enhances siderophore and metallophore investigation in microbial cultures, improving our understanding of their production and roles in bacteria and fungi, ultimately facilitating their biotechnological applications.
异羟肟酸型铁载体是多种病原体中的关键毒力因子,其结构为潜在的生物技术应用提供了有趣的支架,如新型抗菌剂的设计。然而,它们产量可变且稀少、稳定性低以及在天然样品中以复杂混合物形式存在,使得对其分析变得复杂。在此,我们提出了一种名为XAD-LC/MS-FBMN-IMS的新策略,该策略通过整合传统的XAD树脂提取、基于特征的现代分子网络(FBMN)工具以及一种新型的直接进样离子淌度质谱验证方法,能够分析微生物培养物中异羟肟酸型铁载体的组成。以铁胺素为模型,与其他吸附剂相比,XAD树脂在提取异羟肟酸型铁载体金属配合物方面表现出高效率。该策略用于检测鱼类水产养殖中一种相关病原菌产生的铁载体。该分析揭示了三个异羟肟酸型铁载体家族,包括三种已知的去铁胺衍生物以及17种新的推定酰基去铁胺样结构。总体而言,XAD-LC/MS-FBMN-IMS策略显著增强了对微生物培养物中铁载体和金属载体的研究,增进了我们对它们在细菌和真菌中的产生及作用的理解,最终促进了它们的生物技术应用。
