Resolving morphology and antibody labeling over large distances in tissue sections

Protein expression patterns are a primary determinant of tissue function and in this study we developed methods to study protein expression over macroscopic distances at subcellular levels of detail. Using the mammalian lens as a model tissue system, we show that by combining two‐photon microscopy with novel image montage methods (fast beam blanking coupled with mathematical alignment tools) we have extended the limited field of view of laser scanning microscopes. To illustrate the utility of our approach, the distribution of connexin‐46 was visualized across equatorial sections of the rat mammalian lens. By optimizing fixation protocols, good morphological preservation could be achieved over the thickness of the lens (∼4 mm) while preserving antigenicity of lens proteins. Using the same image data, changes in lens fiber cell morphology were mapped quantitatively by automatic image analysis routines. The methods presented should be generally applicable to any tissue system where changes in antibody labeling and tissue structure occur over large and small distances. Microsc. Res. Tech. 62:83–91, 2003. © 2003 Wiley‐Liss, Inc.

[1]  D. Paul,et al.  Targeted Ablation of Connexin50 in Mice Results in Microphthalmia and Zonular Pulverulent Cataracts , 1998, The Journal of cell biology.

[2]  K. König,et al.  Multiphoton microscopy in life sciences , 2000, Journal of microscopy.

[3]  C. Green,et al.  Liquefaction of cortical tissue in diabetic and galactosemic rat lenses defined by confocal laser scanning microscopy. , 1996, Investigative ophthalmology & visual science.

[4]  John C. Russ,et al.  The image processing handbook (3. ed.) , 1995 .

[5]  David L. Milgram,et al.  Computer Methods for Creating Photomosaics , 1975, IEEE Transactions on Computers.

[6]  S. Bassnett The fate of the Golgi apparatus and the endoplasmic reticulum during lens fiber cell differentiation. , 1995, Investigative ophthalmology & visual science.

[7]  M. Costello,et al.  Light microscopic variation of fiber cell size, shape and ordering in the equatorial plane of bovine and human lenses. , 1997, Molecular vision.

[8]  J N Turner,et al.  Automated 3-D montage synthesis from laser-scanning confocal images: application to quantitative tissue-level cytological analysis. , 1996, Cytometry.

[9]  P. Donaldson,et al.  Molecular solutions to mammalian lens transparency. , 2001, News in physiological sciences : an international journal of physiology produced jointly by the International Union of Physiological Sciences and the American Physiological Society.

[10]  M. Steinitz,et al.  The effects of digitalis-like compounds on rat lenses. , 1999, Investigative ophthalmology & visual science.

[11]  J. Kuszak,et al.  Scanning electron microscopy of the frog lens. , 1982, Experimental eye research.

[12]  C. Soeller,et al.  Two‐photon microscopy: Imaging in scattering samples and three‐dimensionally resolved flash photolysis , 1999, Microscopy research and technique.

[13]  M. Tunstall,et al.  Blocking chloride channels in the rat lens: localized changes in tissue hydration support the existence of a circulating chloride flux. , 2000, Investigative ophthalmology & visual science.

[14]  G. Zampighi,et al.  Epithelial organization of the mammalian lens. , 2000, Experimental eye research.

[15]  J. Kuszak,et al.  The ultrastructure of epithelial and fiber cells in the crystalline lens. , 1995, International review of cytology.

[16]  A. O. Dennis Willows,et al.  Computer-assisted visualizations of neural networks: expanding the field of view using seamless confocal montaging , 2000, Journal of Neuroscience Methods.

[17]  J. Pawley,et al.  Handbook of Biological Confocal Microscopy , 1990, Springer US.

[18]  W. Webb,et al.  Multiphoton fluorescence excitation: new spectral windows for biological nonlinear microscopy. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[19]  P. Thompson,et al.  Der p 1 facilitates transepithelial allergen delivery by disruption of tight junctions. , 1999, The Journal of clinical investigation.

[20]  N. Gilula,et al.  Disruption of α3 Connexin Gene Leads to Proteolysis and Cataractogenesis in Mice , 1997, Cell.

[21]  Da-Ting Lin,et al.  Multi-photon laser scanning microscopy using an acoustic optical deflector. , 2002, Biophysical journal.

[22]  B R Masters,et al.  Two-photon excitation fluorescence microscopy. , 2000, Annual review of biomedical engineering.

[23]  S R Ott,et al.  Acquisition of high‐resolution digital images in video microscopy: Automated image mosaicking on a desktop microcomputer , 1997, Microscopy research and technique.

[24]  C. Soeller,et al.  High Resolution Imaging Using Confocal and 2-photon Molecular Excitation Microscopy , 2000, Microscopy Today.

[25]  Subhasis Chaudhuri,et al.  Automated assembling of images: image montage preparation , 1995, Pattern Recognit..

[26]  T. Gonen,et al.  MP20, the second most abundant lens membrane protein and member of the tetraspanin superfamily, joins the list of ligands of galectin-3 , 2001, BMC Cell Biology.

[27]  Azriel Rosenfeld,et al.  Digital topology: Introduction and survey , 1989, Comput. Vis. Graph. Image Process..

[28]  C. Soeller,et al.  Quantifying Changes in Gap Junction Structure as a Function of Lens Fiber Cell Differentiation , 2001, Cell communication & adhesion.