High-precision structural analysis of subnuclear complexes in fixed and live cells via spatially modulated illumination (SMI) microscopy

Spatially modulated illumination (SMI) microscopy is a method of wide field fluorescence microscopy featuring interferometric illumination, which delivers structural information about nanoscale architecture in fluorescently labelled cells. The first prototype of the SMI microscope proved its applicability to a wide range of biological questions. For the SMI live cell imaging this system was enhanced in terms of the development of a completely new upright configuration. This so called Vertico-SMI transfers the advantages of SMI nanoscaling to vital biological systems, and is shown to work consistently at different temperatures using both oil- and water-immersion objective lenses. Furthermore, we increased the speed of data acquisition to minimize errors in the detection signal resulting from cellular or object movement. By performing accurate characterization, the present Vertico-SMI now offers a fully-fledged microscope enabling a complete three-dimensional (3D) SMI data stack to be acquired in less than 2 seconds. We have performed live cell measurements of a tet-operator repeat insert in U2OS cells, which provided the first in vivo signatures of subnuclear complexes. Furthermore, we have successfully implemented an optional optical configuration allowing the generation of high-resolution localization microscopy images of a nuclear pore complex distribution.

[1]  A. Stemmer,et al.  Three-dimensional resolution enhancement in fluorescence microscopy by harmonic excitation. , 2001, Optics letters.

[2]  A. Coleman,et al.  Conformational differences in the 3-D nanostructure of the immunoglobulin heavy-chain locus, a hotspot of chromosomal translocations in B lymphocytes. , 2001, Cancer genetics and cytogenetics.

[3]  Rainer Heintzmann,et al.  High-resolution colocalization of single dye molecules by fluorescence lifetime imaging microscopy. , 2002, Analytical chemistry.

[4]  C Cremer,et al.  Three‐dimensional spectral precision distance microscopy of chromatin nanostructures after triple‐colour DNA labelling: a study of the BCR region on chromosome 22 and the Philadelphia chromosome , 2000, Journal of microscopy.

[5]  Samuel T. Hess,et al.  Dynamic clustered distribution of hemagglutinin resolved at 40 nm in living cell membranes discriminates between raft theories , 2007, Proceedings of the National Academy of Sciences.

[6]  M. Gustafsson Nonlinear structured-illumination microscopy: wide-field fluorescence imaging with theoretically unlimited resolution. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[7]  Michael J Rust,et al.  Sub-diffraction-limit imaging by stochastic optical reconstruction microscopy (STORM) , 2006, Nature Methods.

[8]  Christoph Cremer,et al.  Spatially modulated illumination microscopy allows axial distance resolution in the nanometer range. , 2002, Applied optics.

[9]  Stefan W. Hell,et al.  Measurement of the 4Pi‐confocal point spread function proves 75 nm axial resolution , 1994 .

[10]  Alexander Egner,et al.  Fast 100-nm resolution three-dimensional microscope reveals structural plasticity of mitochondria in live yeast , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[11]  David A. Agard,et al.  Sevenfold improvement of axial resolution in 3D wide-field microscopy using two objective lenses , 1995, Electronic Imaging.

[12]  David Baddeley,et al.  Nanostructure analysis using spatially modulated illumination microscopy , 2003, Nature Protocols.

[13]  J. Lippincott-Schwartz,et al.  Imaging Intracellular Fluorescent Proteins at Nanometer Resolution , 2006, Science.

[14]  Thomas Cremer,et al.  Light optical precision measurements of the active and inactive Prader-Willi syndrome imprinted regions in human cell nuclei. , 2008, Differentiation; research in biological diversity.

[15]  H. Mathée,et al.  Nanostructure of specific chromatin regions and nuclear complexes , 2005, Histochemistry and Cell Biology.

[16]  Christoph Cremer,et al.  Nano-sizing of specific gene domains in intact human cell nuclei by spatially modulated illumination light microscopy. , 2005, Biophysical journal.

[17]  A. Egner,et al.  Resolution of λ /10 in fluorescence microscopy using fast single molecule photo-switching , 2007 .

[18]  Christoph Cremer,et al.  Superresolution size determination in fluorescence microscopy: A comparison between spatially modulated illumination and confocal laser scanning microscopy , 2004 .

[19]  Mike Heilemann,et al.  Multistep energy transfer in single molecular photonic wires. , 2004, Journal of the American Chemical Society.

[20]  Christoph Cremer,et al.  Spectral precision distance confocal microscopy for the analysis of molecular nuclear structure , 1999 .

[21]  Daniel L. Farkas,et al.  Enhancement of axial resolution in fluorescence microscopy by standing-wave excitation , 1993, Nature.

[22]  Christoph Cremer,et al.  Measuring the size of biological nanostructures with spatially modulated illumination microscopy. , 2004, Molecular biology of the cell.

[23]  Christoph Cremer,et al.  Subwavelength size determination by spatially modulated illumination virtual microscopy. , 2002, Applied optics.

[24]  Christian Eggeling,et al.  Macromolecular-scale resolution in biological fluorescence microscopy. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[25]  Mark Bates,et al.  Three-Dimensional Super-Resolution Imaging by Stochastic Optical Reconstruction Microscopy , 2008, Science.

[26]  S. Hell,et al.  Fluorescence microscopy with diffraction resolution barrier broken by stimulated emission. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[27]  David A. Agard,et al.  3D widefield microscopy with two objective lenses: experimental verification of improved axial resolution , 1996, Electronic Imaging.

[28]  Christoph Cremer,et al.  Nanosizing of fluorescent objects by spatially modulated illumination microscopy. , 2002, Applied optics.

[29]  Jürgen Köhler,et al.  3-Dimensional super-resolution by spectrally selective imaging , 1998 .

[30]  Michael D. Mason,et al.  Ultra-high resolution imaging by fluorescence photoactivation localization microscopy. , 2006, Biophysical journal.

[31]  M. Kozubek,et al.  Influence of cell fixation on chromatin topography. , 2000, Analytical biochemistry.

[32]  R. Heintzmann,et al.  Saturated patterned excitation microscopy--a concept for optical resolution improvement. , 2002, Journal of the Optical Society of America. A, Optics, image science, and vision.

[33]  R Heintzmann,et al.  Spatially modulated illumination microscopy: online visualization of intensity distribution and prediction of nanometer precision of axial distance measurements by computer simulations. , 2001, Journal of biomedical optics.

[34]  D. Bazett-Jones,et al.  Fixation-dependent organization of core histones following DNA fluorescent in situ hybridization , 1997, Chromosoma.

[35]  R Eils,et al.  The 3D positioning of ANT2 and ANT3 genes within female X chromosome territories correlates with gene activity. , 1999, Experimental cell research.

[36]  A. Stemmer,et al.  True optical resolution beyond the Rayleigh limit achieved by standing wave illumination. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[37]  Cremer,et al.  High‐precision distance measurements and volume‐conserving segmentation of objects near and below the resolution limit in three‐dimensional confocal fluorescence microscopy , 1998 .

[38]  S. Hell,et al.  Focal spots of size lambda/23 open up far-field fluorescence microscopy at 33 nm axial resolution. , 2002, Physical review letters.

[39]  R. Heintzmann,et al.  Superresolution by localization of quantum dots using blinking statistics. , 2005, Optics express.