Technologies that visualize multiple biomolecules at the nanometer scale in cells will enable deeper understanding of biological processes that proceed at the molecular scale. Current fluorescence-based methods for microscopy are constrained by a combination of spatial 5 resolution limitations, limited parameters per experiment, and detector systems for the wide variety of biomolecules found in cells. We present here super-resolution ion beam imaging (srIBI), a secondary ion mass spectrometry approach capable of high-parameter imaging in 3D of targeted biological entities and exogenously added small molecules. Uniquely, the atomic constituents of the biomolecules themselves can often be used in our system as the "tag". We 10 visualized the subcellular localization of the chemotherapy drug cisplatin simultaneously with localization of five other nuclear structures, with further carbon elemental mapping and secondary electron visualization, down to ~30 nm lateral resolution. Cisplatin was preferentially enriched in nuclear speckles and excluded from closed-chromatin regions, indicative of a role for cisplatin in active regions of chromatin. These data highlight how multiplexed super-resolution 15 techniques, such as srIBI, will enable studies of biomolecule distributions in biologically relevant subcellular microenvironments.
One Sentence Summary:Three-dimensional multiplexed mass spectrometry-based imaging revealed the 20 subcellular localization of proteins and small molecules at super-resolution.3
Main Text:Form drives function in cells and tissues. This is especially true when researchers attempt deciphering of the complex interplay of molecular components that drive the biology of cells.Currently, biochemical approaches decipher meaning and mechanism from inferential experiments 5 that allow researchers to abstract a picture of how the molecular machines of a cell function. This begs the question-would it not be more useful to image these machines in their natural contexts?Fluorescence microscopy is currently the de-facto choice for biomolecular imaging, although multiplexing is often challenging due to the spectral overlap of fluorophores. Recent advancements partially overcome this limitation by using cyclic-hybridization protocols to enable multi-10 parameter visualization of proteins, RNA, and DNA (1-4). These techniques allow a range of studies from single-cells at super-resolution (5) to whole tissues (6) and have revealed a rich interplay between nucleic acids (5,7, 8). There remain challenges however, such as acquisition time for imaging and sample positional shifts between cycles, which become more pronounced at super-resolution scales (9). In addition, imaging of small molecules, such as drugs, metabolites, or 15 lipids, is also complicated since tags, such as fluorophores conjugated to biomolecules, can affect biological activities (10). The ability to directly image atomic components as labels would, with higher resolution, allow for a three-dimensional (3D) reconstruction of the distribution of mu...
