Behrens Sebastian, Lösekann Tina, Pett-Ridge Jennifer, Weber Peter K, Ng Wing-On, Stevenson Bradley S, Hutcheon Ian D, Relman David A, Spormann Alfred M
Department of Chemical Engineering and of Civil, Stanford University, Stanford, California 94305-5429, USA.
Appl Environ Microbiol. 2008 May;74(10):3143-50. doi: 10.1128/AEM.00191-08. Epub 2008 Mar 21.
To examine phylogenetic identity and metabolic activity of individual cells in complex microbial communities, we developed a method which combines rRNA-based in situ hybridization with stable isotope imaging based on nanometer-scale secondary-ion mass spectrometry (NanoSIMS). Fluorine or bromine atoms were introduced into cells via 16S rRNA-targeted probes, which enabled phylogenetic identification of individual cells by NanoSIMS imaging. To overcome the natural fluorine and bromine backgrounds, we modified the current catalyzed reporter deposition fluorescence in situ hybridization (FISH) technique by using halogen-containing fluorescently labeled tyramides as substrates for the enzymatic tyramide deposition. Thereby, we obtained an enhanced element labeling of microbial cells by FISH (EL-FISH). The relative cellular abundance of fluorine or bromine after EL-FISH exceeded natural background concentrations by up to 180-fold and allowed us to distinguish target from non-target cells in NanoSIMS fluorine or bromine images. The method was optimized on single cells of axenic Escherichia coli and Vibrio cholerae cultures. EL-FISH/NanoSIMS was then applied to study interrelationships in a dual-species consortium consisting of a filamentous cyanobacterium and a heterotrophic alphaproteobacterium. We also evaluated the method on complex microbial aggregates obtained from human oral biofilms. In both samples, we found evidence for metabolic interactions by visualizing the fate of substrates labeled with (13)C-carbon and (15)N-nitrogen, while individual cells were identified simultaneously by halogen labeling via EL-FISH. Our novel approach will facilitate further studies of the ecophysiology of known and uncultured microorganisms in complex environments and communities.
为了研究复杂微生物群落中单个细胞的系统发育特征和代谢活性,我们开发了一种方法,该方法将基于rRNA的原位杂交与基于纳米级二次离子质谱(NanoSIMS)的稳定同位素成像相结合。通过靶向16S rRNA的探针将氟或溴原子引入细胞,这使得能够通过NanoSIMS成像对单个细胞进行系统发育鉴定。为了克服天然氟和溴的背景干扰,我们通过使用含卤素的荧光标记酪胺作为酶促酪胺沉积的底物,对当前的催化报告沉积荧光原位杂交(FISH)技术进行了改进。由此,我们通过FISH获得了微生物细胞增强的元素标记(EL-FISH)。EL-FISH后氟或溴的相对细胞丰度比天然背景浓度高出多达180倍,使我们能够在NanoSIMS氟或溴图像中区分目标细胞和非目标细胞。该方法在无菌大肠杆菌和霍乱弧菌培养物的单个细胞上进行了优化。然后将EL-FISH/NanoSIMS应用于研究由丝状蓝细菌和异养α-变形菌组成的双物种聚生体中的相互关系。我们还对从人类口腔生物膜获得的复杂微生物聚集体评估了该方法。在这两个样本中,我们通过可视化用¹³C-碳和¹⁵N-氮标记的底物的命运,发现了代谢相互作用的证据,同时通过EL-FISH的卤素标记对单个细胞进行了鉴定。我们的新方法将有助于进一步研究复杂环境和群落中已知和未培养微生物的生态生理学。
