Micronutrient availability alters Candida albicans growth and farnesol accumulation: implications for studies using RPMI-1640.

IF 3.7 2区生物学 Q2 MICROBIOLOGY

Microbiology spectrum Pub Date : 2024-11-05 Epub Date: 2024-09-24 DOI:10.1128/spectrum.01571-24

Cory H T Boone, Daniel J Gutzmann, Jaxon J Kramer, Shyanne D Urbin, Dhammika H Navarathna, Audrey L Atkin, Kenneth W Nickerson

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引用次数: 0

Abstract

Science is challenging because we do not know what we do not know. Commercial chemicals are often marketed with >99% purity, but 0.5-1% impurity can impact results and cloud data interpretation. We recently developed an assay for farnesol and aromatic fusel alcohols from Candida albicans. During proof-of-concept experiments using RPMI-1640 growth media, the buffering compound was switched from MOPS obtained from Acros Organics to MOPS obtained from Sigma-Aldrich, both labeled 99% + purity. We observed a twofold decrease in growth, along with a three- to fivefold increase in farnesol production per cell upon the switch. ICP-MS showed that trace Mn(II) was present in Acros MOPS but absent in Sigma MOPS. Optimal growth was achieved by the addition of Mn(II), Zn(II), and Fe(II). We established upper and lower limits for Fe(II), Zn(II), Cu(II), and Mn(II) that allowed similar growth and then assessed 16 different mineral combinations in RPMI-1640 base media. The results show an increased production of farnesol and the aromatic fusel alcohols when Zn(II) is abundant, and a further increase in the aromatic fusel alcohols when both Fe(II) and Zn(II) are abundant. Finally, antifungal susceptibility testing displayed no significant difference between RPMI/MOPS with and without mineral supplementation. Supplemental Mn(II) was most needed for cell growth, while supplemental Zn(II) was most needed for the production of farnesol and the aromatic fusel alcohols. To avoid these artifacts due to metal contamination, we now use a modified RPMI supplemented with 1 mg/ L of Cu(II), Zn(II), Mn(II), and Fe(II).

Importance: The dimorphic fungus Candida albicans is a major opportunistic pathogen of humans. RPMI-1640 is a chemically defined growth medium commonly used with C. albicans. We identified over 32,000 publications with keywords RPMI and C. albicans. Additionally, Antifungal Susceptibility Testing (AFST) protocols in the United States (CLSI) and Europe (EUCAST) utilize RPMI as a base media to assess drug efficacy against clinical fungal isolates. RPMI contains many nutrients but no added trace metals. We found that the growth characteristics with RPMI were dependent on which MOPS buffer was chosen and the contamination of that buffer by trace levels of Mn(II) and Zn(II). Added Mn(II) was most needed for cell growth while added Zn(II) was most needed for secretion of farnesol and other signaling molecules.

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微量营养素的可用性会改变白色念珠菌的生长和法尼醇的积累：对使用 RPMI-1640 进行研究的影响。

科学具有挑战性，因为我们不知道我们不知道什么。市场上销售的商业化学品通常纯度大于 99%，但 0.5-1% 的杂质会影响检测结果，给数据解释造成困扰。我们最近开发了一种检测方法，用于检测白色念珠菌中的法尼醇和芳香茴香醇。在使用 RPMI-1640 生长培养基进行概念验证实验期间，缓冲化合物从 Acros Organics 公司生产的 MOPS 换成了 Sigma-Aldrich 公司生产的 MOPS，两者的标签纯度均为 99%+。我们观察到，切换后生长速度降低了两倍，每个细胞产生的法尼醇增加了三到五倍。ICP-MS 显示，Acros MOPS 中含有痕量锰（II），而 Sigma MOPS 中则没有。通过添加 Mn（II）、Zn（II）和 Fe（II），实现了最佳生长。我们确定了铁(II)、锌(II)、铜(II)和锰(II)允许相似生长的上限和下限，然后在 RPMI-1640 基础培养基中评估了 16 种不同的矿物质组合。结果表明，当锌（II）含量丰富时，法呢醇和芳香茴香醇的产量增加；当铁（II）和锌（II）含量都丰富时，芳香茴香醇的产量进一步增加。最后，抗真菌敏感性测试表明，补充和不补充矿物质的 RPMI/MOPS 之间没有显著差异。细胞生长最需要补充锰（II），而生产法呢醇和芳香茴香醇最需要补充锌（II）。为了避免这些金属污染造成的假象，我们现在使用添加了 1 mg/ L 铜（II）、锌（II）、锰（II）和铁（II）的改良 RPMI：重要意义：二形真菌白色念珠菌是人类的主要机会性病原体。RPMI-1640 是白念珠菌常用的化学定义生长培养基。我们以 RPMI 和白念珠菌为关键字，找到了 32,000 多篇论文。此外，美国（CLSI）和欧洲（EUCAST）的抗真菌药敏试验（AFST）方案使用 RPMI 作为基础培养基，以评估药物对临床真菌分离物的疗效。RPMI 含有多种营养物质，但不添加微量金属。我们发现，RPMI 的生长特性取决于所选择的 MOPS 缓冲液以及该缓冲液中锰(II)和锌(II)的痕量含量。细胞生长最需要添加锰（II），而分泌法尼醇和其他信号分子最需要添加锌（II）。

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来源期刊

Microbiology spectrum Biochemistry, Genetics and Molecular Biology-Genetics

CiteScore

3.20

自引率

5.40%

发文量

1800

期刊介绍： Microbiology Spectrum publishes commissioned review articles on topics in microbiology representing ten content areas: Archaea; Food Microbiology; Bacterial Genetics, Cell Biology, and Physiology; Clinical Microbiology; Environmental Microbiology and Ecology; Eukaryotic Microbes; Genomics, Computational, and Synthetic Microbiology; Immunology; Pathogenesis; and Virology. Reviews are interrelated, with each review linking to other related content. A large board of Microbiology Spectrum editors aids in the development of topics for potential reviews and in the identification of an editor, or editors, who shepherd each collection.