Your search keyword '"Amy N. Moores"' showing total 2 results

1. Super-resolution Microscopy at Cryogenic Temperatures Using Solid Immersion Lenses

Author

Daniel J. Rolfe, Sarah R. Needham, Marisa L. Martin-Fernandez, Laura C. Zanetti-Domingues, Amy N. Moores, Benji C. Bateman, Lin Wang, and David T. Clarke

Subjects

Brightness, Materials science, business.industry, Super-resolution microscopy, Strategy and Management, Mechanical Engineering, Metals and Alloys, Molecular resolution, Cell function, Industrial and Manufacturing Engineering, Fluorescence microscope, Methods Article, Optoelectronics, Cellular ultrastructure, High numerical aperture, business

Abstract

Our mechanistic understanding of cell function depends on imaging biological processes in cells with molecular resolution. Super-resolution fluorescence microscopy plays a crucial role by reporting cellular ultrastructure with 20-30 nm resolution. However, this resolution is insufficient to image macro-molecular machinery at work. A path to improve resolution is to image under cryogenic conditions, which substantially increases the brightness of most fluorophores and preserves native ultrastructure much better than chemical fixatives. Cryogenic conditions are, however, underutilized because of the lack of compatible high numerical aperture (NA) objectives. Here we describe a protocol for the use of super-hemispherical solid immersion lenses (superSILs) to achieve super-resolution imaging at cryogenic temperatures with an effective NA of 2.17 and resolution of ~10 nm.

Published

2019

2. Solid immersion microscopy images cells under cryogenic conditions with 12 nm resolution

Author

Daniel J. Rolfe, Marisa L. Martin-Fernandez, Sarah R. Needham, Konstantinos Beis, Michele C. Darrow, Maria Romano, Laura C. Zanetti-Domingues, Benji C. Bateman, Sam Astbury, C. Spindloe, Amy N. Moores, Lin Wang, David T. Clarke, and Medical Research Council (MRC)

Subjects

Brightness, Fluorescence-lifetime imaging microscopy, Materials science, animal structures, Cytological Techniques, Green Fluorescent Proteins, Medicine (miscellaneous), CHO Cells, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, 010309 optics, Maleimides, 03 medical and health sciences, Cricetulus, Solid immersion lens, Mammalian cell, Cricetinae, 0103 physical sciences, Microscopy, Fluorescence microscope, Escherichia coli, Animals, Image resolution, lcsh:QH301-705.5, 030304 developmental biology, Fluorescent Dyes, 0303 health sciences, business.industry, Escherichia coli Proteins, Cryoelectron Microscopy, Reproducibility of Results, ErbB Receptors, lcsh:Biology (General), Microscopy, Fluorescence, Optoelectronics, ATP-Binding Cassette Transporters, Cellular ultrastructure, General Agricultural and Biological Sciences, business

Abstract

Super-resolution fluorescence microscopy plays a crucial role in our understanding of cell structure and function by reporting cellular ultrastructure with 20–30 nm resolution. However, this resolution is insufficient to image macro-molecular machinery at work. A path to improve resolution is to image under cryogenic conditions. This substantially increases the brightness of most fluorophores and preserves native ultrastructure much better than chemical fixation. Cryogenic conditions are, however, underutilised because of the lack of compatible high numerical aperture objectives. Here, using a low-cost super-hemispherical solid immersion lens (superSIL) and a basic set-up we achieve 12 nm resolution under cryogenic conditions, to our knowledge the best yet attained in cells using simple set-ups and/or commercial systems. By also allowing multicolour imaging, and by paving the way to total-internal-reflection fluorescence imaging of mammalian cells under cryogenic conditions, superSIL microscopy opens a straightforward route to achieve unmatched resolution on bacterial and mammalian cell samples., Lin Wang et al. present a new super-resolution modality using a super-hemispherical immersion lens. They achieve a 12 nm spatial resolution in cells under cryogenic conditions, which offers the technical means to study bacterial and mammalian cell samples at molecule localisation length-scales.

Published

2019