Capturing the start point of the virus–cell interaction with high-speed 3D single-virus tracking

The early stages of the virus–cell interaction have long evaded observation by existing microscopy methods due to the rapid diffusion of virions in the extracellular space and the large three-dimensional cellular structures involved. Here we present an active-feedback single-particle tracking method...

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Veröffentlicht in:	Nature methods 2022-12, Vol.19 (12), p.1642-1652
Hauptverfasser:	Johnson, Courtney, Exell, Jack, Lin, Yuxin, Aguilar, Jonathan, Welsher, Kevin D.
Format:	Artikel
Sprache:	eng
Schlagworte:	631/1647/245/2227 631/1647/328 631/326/596 631/57/2265 Bioinformatics Biological activity Biological Microscopy Biological Techniques Biomedical and Life Sciences Biomedical Engineering/Biotechnology Cell Communication Cell culture Cellular structure Diffusion coefficient Epithelial cells Epithelium High speed Imaging, Three-Dimensional - methods Life Sciences Microenvironments Microscopy Microscopy - methods Particle tracking Proteomics Severe acute respiratory syndrome coronavirus 2 Single Molecule Imaging Tissue culture Viral infections Virions Viruses
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creator	Johnson, Courtney Exell, Jack Lin, Yuxin Aguilar, Jonathan Welsher, Kevin D.
description	The early stages of the virus–cell interaction have long evaded observation by existing microscopy methods due to the rapid diffusion of virions in the extracellular space and the large three-dimensional cellular structures involved. Here we present an active-feedback single-particle tracking method with simultaneous volumetric imaging of the live cell environment called 3D-TrIm to address this knowledge gap. 3D-TrIm captures the extracellular phase of the infectious cycle in what we believe is unprecedented detail. We report what are, to our knowledge, previously unobserved phenomena in the early stages of the virus–cell interaction, including skimming contact events at the millisecond timescale, orders of magnitude change in diffusion coefficient upon binding and cylindrical and linear diffusion modes along cellular protrusions. Finally, we demonstrate how this method can move single-particle tracking from simple monolayer culture toward more tissue-like conditions by tracking single virions in tightly packed epithelial cells. This multiresolution method presents opportunities for capturing fast, three-dimensional processes in biological systems. 3D-TrIm combines real-time, high-speed, single-virion tracking with volumetric imaging of cellular microenvironments.
doi_str_mv	10.1038/s41592-022-01672-3
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subjects	631/1647/245/2227 631/1647/328 631/326/596 631/57/2265 Bioinformatics Biological activity Biological Microscopy Biological Techniques Biomedical and Life Sciences Biomedical Engineering/Biotechnology Cell Communication Cell culture Cellular structure Diffusion coefficient Epithelial cells Epithelium High speed Imaging, Three-Dimensional - methods Life Sciences Microenvironments Microscopy Microscopy - methods Particle tracking Proteomics Severe acute respiratory syndrome coronavirus 2 Single Molecule Imaging Tissue culture Viral infections Virions Viruses
title	Capturing the start point of the virus–cell interaction with high-speed 3D single-virus tracking
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