硫黄素T对细菌伸长率的影响。
Effect of Thioflavin T on the Elongation Rate of Bacteria.
作者信息
Han Xu, Payne Christine K
机构信息
Department of Mechanical Engineering and Materials Science, Duke University, Durham, North Carolina, USA.
出版信息
Bioelectricity. 2022 Mar 15;4(1):12-17. doi: 10.1089/bioe.2021.0027. eCollection 2022 Mar.
BACKGROUND
The growing field of bacterial electrophysiology examines the relationship between bacterial membrane potential and cell division, growth, sporulation, and biofilm formation. These experiments require Nernstian fluorescent dyes to monitor membrane potential. Our research uses single cell imaging to determine if a common fluorescent dye, Thioflavin T (ThT), affects the growth of bacteria.
MATERIALS AND METHODS
We use a combination of standard growth curve measurements and single cell imaging, both brightfield and fluorescence microscopy, to monitor the growth of and as a function of ThT concentration. Increased membrane potential (hyperpolarization) leads to increased intracellular accumulation of ThT: High fluorescence intensity is an indicator of hyperpolarization. Blue light is used to hyperpolarize a subpopulation of cells to monitor cellular elongation in response to increased cellular internalization of ThT.
RESULTS
Single cell imaging shows that the elongation rates of and are decreased when these cells are incubated with ThT. At micromolar concentrations of ThT, this effect may be masked in standard growth curves, but is visible with single cell measurements on agarose pads.
CONCLUSIONS
The increased cellular accumulation of ThT is a standard measure of hyperpolarization in bacterial electrophysiology. Growth curves, a bulk measurement, are typically used to determine suitable concentrations of ThT for use in experiments. Single cell measurements show that cells incubated with ThT have decreased elongation rates. This creates a potential experimental artifact that could lead to misinterpretation of data. Hyperpolarized cells internalize more ThT. This increased intracellular concentration of ThT, rather than the change in membrane potential, could lead to decreased growth. These experiments point toward the importance of single cell measurements to detect subtle changes in cell growth. We hope this research will be useful for other researchers in their choice of dye for the detection of membrane potential.
背景
细菌电生理学这一不断发展的领域研究细菌膜电位与细胞分裂、生长、孢子形成和生物膜形成之间的关系。这些实验需要能斯特荧光染料来监测膜电位。我们的研究使用单细胞成像来确定一种常见的荧光染料硫黄素T(ThT)是否会影响细菌的生长。
材料与方法
我们结合标准生长曲线测量和单细胞成像,包括明场和荧光显微镜,来监测大肠杆菌和枯草芽孢杆菌的生长随ThT浓度的变化。膜电位增加(超极化)会导致ThT在细胞内的积累增加:高荧光强度是超极化的指标。使用蓝光使一部分细胞超极化,以监测细胞因ThT细胞内化增加而发生的伸长情况。
结果
单细胞成像显示,当大肠杆菌和枯草芽孢杆菌与ThT一起孵育时,它们的伸长率会降低。在微摩尔浓度的ThT下,这种效应在标准生长曲线中可能会被掩盖,但在琼脂糖垫上进行单细胞测量时是可见的。
结论
ThT在细胞内积累增加是细菌电生理学中超极化的标准测量方法。生长曲线是一种总体测量方法,通常用于确定实验中使用的合适ThT浓度。单细胞测量表明,与ThT一起孵育的细胞伸长率降低。这会产生潜在的实验假象,可能导致数据误读。超极化细胞会内化更多的ThT。ThT细胞内浓度的增加,而非膜电位的变化,可能导致生长减缓。这些实验表明单细胞测量对于检测细胞生长细微变化的重要性。我们希望这项研究能对其他研究人员选择用于检测膜电位的染料有所帮助。
Zotero 插件