Staying Alive: Measuring Intact Viable Microbes with Electrospray Ionization Mass Spectrometry
| Autor: | Erica M. Forsberg, Mingliang Fang, Gary Siuzdak |
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| Rok vydání: | 2016 |
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Molecular Spectrometry Mass Electrospray Ionization Electrospray ionization 010402 general chemistry Proteomics Mass spectrometry 01 natural sciences Article Charge detection Structural Biology Humans Quadrupole mass analyzer Spectroscopy chemistry.chemical_classification Microbial Viability Chromatography Bacteria Active medium Chemistry Biomolecule 010401 analytical chemistry Bacterial Infections Small molecule 0104 chemical sciences Virus Diseases Viruses Equipment Failure |
| Zdroj: | Journal of the American Society for Mass Spectrometry. 28:14-20 |
| ISSN: | 1044-0305 |
| Popis: | Mass spectrometry has traditionally been the technology of choice for small molecule analysis, making significant inroads into metabolism, clinical diagnostics, and pharmacodynamics since the 1960s. In the mid-1980s, with the discovery of electrospray ionization (ESI) for biomolecule analysis, a new door opened for applications beyond small molecules. Initially, proteins were widely examined, followed by oligonucleotides and other nonvolatile molecules. Then in 1991, three intriguing studies reported using mass spectrometry to examine noncovalent protein complexes, results that have been expanded on for the last 25 years. Those experiments also raised the questions: How soft is ESI, and can it be used to examine even more complex interactions? Our lab addressed these questions with the analyses of viruses, which were initially tested for viability following electrospray ionization and their passage through a quadrupole mass analyzer by placing them on an active medium that would allow them to propagate. This observation has been replicated on multiple different systems, including experiments on an even bigger microbe, a spore. The question of analysis was also addressed in the early 2000s with charge detection mass spectrometry. This unique technology could simultaneously measure mass-to-charge and charge, allowing for the direct determination of the mass of a virus. More recent experiments on spores and enveloped viruses have given us insight into the range of mass spectrometry's capabilities (reaching 100 trillion Da), beginning to answer fundamental questions regarding the complexity of these organisms beyond proteins and genes, and how small molecules are integral to these supramolecular living structures. Graphical Abstract ᅟ. |
| Databáze: | OpenAIRE |
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