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Genetically encoded barcodes for correlative volume electron microscopy.

Felix SigmundOleksandr BerezinSofia BeliakovaBernhard MagerlMartin DrawitschAlberto PiovesanFilipa GonçalvesSilviu-Vasile BodeaStefanie WinklerZoe BousraouMartin GrosshauserEleni SamaraJesús Pujol-MartíSebastian SchädlerChun SoStephan IrsenAxel WalchFlorian KoflerMarie PiraudJoergen KornfeldKevin BriggmanGil Gregor Westmeyer
Published in: Nature biotechnology (2023)
While genetically encoded reporters are common for fluorescence microscopy, equivalent multiplexable gene reporters for electron microscopy (EM) are still scarce. Here, by installing a variable number of fixation-stable metal-interacting moieties in the lumen of encapsulin nanocompartments of different sizes, we developed a suite of spherically symmetric and concentric barcodes (EMcapsulins) that are readable by standard EM techniques. Six classes of EMcapsulins could be automatically segmented and differentiated. The coding capacity was further increased by arranging several EMcapsulins into distinct patterns via a set of rigid spacers of variable length. Fluorescent EMcapsulins were expressed to monitor subcellular structures in light and EM. Neuronal expression in Drosophila and mouse brains enabled the automatic identification of genetically defined cells in EM. EMcapsulins are compatible with transmission EM, scanning EM and focused ion beam scanning EM. The expandable palette of genetically controlled EM-readable barcodes can augment anatomical EM images with multiplexed gene expression maps.
Keyphrases
  • electron microscopy
  • gene expression
  • high resolution
  • deep learning
  • poor prognosis
  • dna methylation
  • genome wide
  • minimally invasive
  • high throughput
  • transcription factor
  • cerebral ischemia