The Combined Nanoscopy Technique
Scientists develop a combined technique for studying cellular structures via high-resolution imaging
The turnover of subcellular organelles is one of the least understood aspects of modern cell biology, despite its widely recognized importance. In biology, these processes are studied by “feeding” cells with marker molecules such as amino acids labeled with stable isotopes. Over time these amino acids are metabolically incorporated into cellular proteins and the isotopic composition can then be imaged by secondary ion mass spectrometry (SIMS). This technique enables visualization of different organelles in cells and tissues. However, SIMS by itself cannot identify specific subcellular structures.
Therefore, the team of Prof. Rizzoli in collaboration with scientists of the Leibniz Institute for Baltic Sea Research in Warnemünde and the French company Cameca successfully correlated SIMS with a second technique. The combined method termed “correlated optical and isotopic nanoscopy (COIN)” is based on super-resolution stimulated emission depletion (STED) microscopy. COIN allows precise studies of the protein turnover in different single organelles from cultured hippocampal neurons. The new approach has been recently published in Nature Communications.
Each of the combined techniques alone provides a piece of information that is unavailable for the other: “SIMS yields the isotopic composition of the material investigated and even its turnover, while STED microscopy reveals the identities and the spatial distribution of organelles or organelle components.”, Prof. Rizzoli explains. The combination (COIN) for the first time allows precisely determining the turnover of proteins in various single organelles in cells. A special feature of the technique is the wide-range application to a variety of biological samples, which should therefore enable the investigation of the composition of many organelles and sub-cellular structures. Using COIN the scientists successfully yielded information about the protein turnover in different organelles of cultured hippocampal neurons. COIN can be applied to a variety of biological samples, and should therefore enable the investigation of the isotopic composition of many organelles and subcellular structures.
Original publication
Saka SK, Vogts A, Kröhnert K, Hillion F, Rizzoli SO*, Wessels J* (2014) Correlated optical and isotopic nanoscopy. NAT COMMUN, 5: 3664.
Original publication
Saka SK, Vogts A, Kröhnert K, Hillion F, Rizzoli SO*, Wessels J* (2014) Correlated optical and isotopic nanoscopy. NAT COMMUN, 5: 3664.
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