Sub-cellular chemical mapping in bacteria using correlated cryogenic electron and mass spectrometry imaging

Electron cryomicroscopy (cryo-EM) allows high-resolution spatial visualization of biological specimens, however, it is challenging to chemically identify densities observed in cryo-EM. To overcome this, we combined cryo-EM with chemical imaging using focused ion beam secondary ion mass spectrometry (FIB-SIMS) for integrated spatio-chemical analysis of untagged specimens. We show that our correlative workflow permits sub-cellular localisation of molecules inside bacterial cells and is compatible with cryogenic light microscopy and FIB-milled lamellae of multicellular specimens. To highlight biological insights enabled by the workflow, we studied the uptake of Bisphenol-AF, a widespread chemical pollutant, by environmental bacteria, revealing the storage of these chemicals within cytosolic phase-separated aggregates in pollutant-exposed cells, where they cannot be removed by the bacterial efflux machinery despite its robust upregulation. These mechanistic insights were directly facilitated by the versatile cryo-EM-FIB-SIMS technique, showing that it is an effective avenue to map elemental and molecular signatures in near-native biological samples, which can be extended in the future for multiple applications in cell biology and imaging.