Abstract
Raman microspectroscopy offers microbiologists a rapid and non-destructive technique to assess the chemical composition of individual live microorganisms in near real time. In this Primer, we outline the methodology and potential for its application to microbiology. We describe the technical aspects of Raman analyses and practical approaches to apply this method to microbiological questions. We discuss recent and potential future applications to determine the composition and distribution of microbial metabolites down to subcellular scale; to investigate the host–microorganism, cell–cell and cell–environment molecular exchanges that underlie the structure of microbial ecosystems from the ocean to the human gut microbiomes; and to interrogate the microbial diversity of functional roles in environmental and industrial processes — key themes in modern microbiology. We describe the current technical limitations of Raman microspectroscopy for investigation of microorganisms and approaches to minimize or address them. Recent technological innovations in Raman microspectroscopy will further reinforce the power and capacity of this method for broader adoptions in microbiology, allowing microbiologists to deepen their understanding of the microbial ecology of complex communities at nearly any scale of interest.
| Originalsprog | Engelsk |
|---|---|
| Artikelnummer | 80 |
| Tidsskrift | Nature Reviews Methods Primers |
| Vol/bind | 1 |
| Udgave nummer | 1 |
| DOI | |
| Status | Udgivet - dec. 2021 |
Bibliografisk note
Funding Information:R.S. acknowledges support from a Gordon and Betty Moore Foundation Symbiosis in Aquatic Systems Initiative Investigator Award (GBMF9197; https://doi.org/10.37807/GBMF9197 ), a grant from the Simons Foundation (542395) as part of the Principles of Microbial Ecosystems (PriME) Collaborative, a grant (315230_176189) from the Swiss National Science Foundation and support from the National Centre of Competence in Research (NCCR) Microbiomes (51NF40_180575). F.C.P. was supported by a Young Independent Research Group grant from the Austrian Science Fund (FWF; ZK-57). D.B. was supported by the Austrian Science Fund (FWF; P26127-B20 and P27831-B28), the United States Department of Energy (DE-SC0019012) and the European Research Council (ERC; Starting Grant: FunKeyGut 741623). Research in the lab of M.W. on Raman microspectroscopy and its application in microbial ecology was supported by an ERC Advanced Grant (Nitricare; 294343) and the Wittgenstein Award of the FWF (Z-383-B). W.E.H. acknowledges financial and instrumentational support from EPSRC (EP/M002403/1, EP/M02833X/1) and NERC (NE/M002934/1). G.T.T. acknowledges support from NSF-MRI grant OCE-1336724 and a Gordon and Betty Moore Foundation Grant no. 5064. J.K. acknowledges funding by ERC Starting Grant 259432 Multibiophot . J.-X.C. acknowledges support from NIH (R35 GM136223 and R01AI141439). The Stocker group thanks R. Naisbit for scientific editing.
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