Immunophotoelectron microscopy: the electron optical analog of immunofluorescence microscopy.

Birrell, G. Bruce; Habliston, D.L.; Nadakavukaren, Karen K.; Griffith, O. Hayes

doi:10.1073/pnas.82.1.109

Cited by 16 publications

(4 citation statements)

References 22 publications

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“…Previous studies demonstrated that when fluorophores (fluorescein or rhodamine) and cAu 30 are attached to the same molecule (such as IgG or ligand), the fluorescence signal was quenched (Goodman, et al , 1991;Birrell, et al , 1985).…”

Section: Discussionmentioning

confidence: 98%

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Fluorescence Quenching by Colloidal Heavy Metals Nanoparticles: Implications for Correlative Fluorescence and Electron Microscopy Studies

Kandela

Albrecht

2007

Scanning

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Labels for correlative immunolabeling in light (LM) and electron microscopy (EM) employing colloidal metal nanoparticles (gold or palladium) and fluorescent dyes (Alexa Fluor, AF) were investigated. The fluorescence signals from direct conjugates (cAu-IgG-AF) and from an indirect label system (cAu-IgG-anti IgG-AF) were studied using scanning spectrofluorometry and fluorescence light microscopy. Direct conjugation of protein--AF, IgG-AF or FGN-AF to 18 and 5 nm colloidal gold (cAu18 and cAu5) or 12 nm colloidal palladium particles (cPd12) resulted in nearly completely quenched fluorescence signals (>99 %) at excitation wavelengths of 488, 546 and 594 nm. In contrast, indirect conjugation, when colloidal metal particles and AF were conjugated to primary or secondary antibody, respectively (cAu-IgG-antiIgG-AF), sufficient fluorescence signal was detected. Commercially available conjugates, consisting of IgG-AF-cAu5 and IgG-AF-cAu10, were also tested and proved to be a mixture of IgG-AF (unbound to cAu) and cAu-IgG-AF.

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Section: Discussionmentioning

confidence: 98%

“…Most fluorophores are small, compatible with biological samples and easily conjugated to different proteins or ligands. However, resolution attainable with LM is limited (Birrell et al , 1985). Therefore, subsequent EM imaging may be beneficial to obtain higher spatial resolution for structural studies (Nisman et al , 2004;Albrecht et al , 1993).…”

mentioning

confidence: 96%

Fluorescence Quenching by Colloidal Heavy Metals Nanoparticles: Implications for Correlative Fluorescence and Electron Microscopy Studies

Kandela

Albrecht

2007

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“…The Oregon photoelectron microscope has been described (Griffith and Rempfer, 1987) and has been used to image a variety of biological specimens (Griffith and Birrell, 1985;Hedberg and Griffith, 1986;Habliston et al, 1986). In short, the microscope is an oil-free ultrahigh vacuum instrument utilizing liquid nitrogen temperature sorbtion prepumps and an ion pump for attaining final vacuum.…”

Section: Photoelectron Microscopymentioning

confidence: 99%

Protein kinase C inhibitor H‐7 alters the actin cytoskeleton of cultured cells

Birrell

Hedberg

Habliston

et al. 1989

Journal Cellular Physiology

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The effects of the protein kinase C inhibitor H-7 on the actin cytoskeleton of cultured cells (Swiss 3T3 and PTK2) are described. As documented by fluorescence microscopy and the higher-resolution technique of photoelectron microscopy, the effects are rapid and dramatic; exposure to 30 microM H-7 in culture medium for less than 6 min is sufficient to induce a significant reduction in the numbers and thickness of actin microfilament bundles and alterations in the morphology of cell-cell boundaries in PTK2 cells. One-hour exposure to 30 microM H-7 results in nearly complete depletion of normal actin microfilament bundles from all of the cell types examined, without dramatic changes in overall cell shape. The intermediate filament and microtubule cytoskeletal networks did not appear to be affected to any extent over the times and doses examined. Forty-five minutes of exposure of Swiss 3T3 cells to 200 microM of either HA1004 (which is comparable to H-7 with respect to inhibition of cyclic nucleotide dependent kinases) or to the protein kinase C inhibitor sangivamycin did not induce the actin alterations characteristic of H-7. In addition, depletion of protein kinase C from Swiss 3T3 cells by means of phorbol ester-induced down-regulation did not prevent the effects of H-7 on the actin cytoskeleton. These results demonstrate that the protein kinase C inhibitor H-7 has a specific and rapid effect on the actin cytoskeleton, and furthermore H-7 may have biochemical effects beyond those mediated by inhibition of protein kinase C or the cyclic nucleotide dependent kinases.

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“…From a historical perspective, O. Hayes Griffith (4) was one of the pioneers of PEEM technology and applied the technique to biological samples in 1972 (4), reporting first PEEM images of rat epididymis. Griffith and his group realized the capabilities of PEEM as the electron-optics analog of fluorescence microscopy and used colloidal gold and silver enhanced colloidal gold particles to selectively label portions of a biologic with a higher spatial resolution (5)(6)(7). PEEM images for cells (8)(9)(10), viruses (11,12) and DNA (11,(13)(14)(15), among others (16)(17)(18), were reported using both labeling and nonlabeling techniques.…”

Section: Introductionmentioning

confidence: 99%

Challenges in Applying Photoemission Electron Microscopy to Biological Systems^†

Peles

Simon²

2009

Photochem & Photobiology

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Photoemission electron microscopy (PEEM) is a unique surface-sensitive instrument capable of providing real-time images with high spatial resolution. While similar to the more common electron microscopies, scanning electron microscopy and transmission electron microscopy, the imaging technology relies on the photogeneration of electrons emitted from a sample through light excitation. This imaging technique has found prominence in surface and materials sciences, being well suited for imaging flat surfaces, and changes that occur to that surface as various parameters are changed (e.g. temperature, exposure to reactive gases). Biologically focused PEEM received significant attention in the 1970s, but was not aggressively advanced since that pioneering work. PEEM is capable of providing important insights into biological systems that extend beyond simple imaging. In this article, we identify and establish important issues that affect the acquisition and analysis of biological samples with PEEM. We will briefly review the biological impact and importance of PEEM with respect to our work. The article also concludes with a discussion of some of the current challenges that must be addressed to enable PEEM to achieve its maximum potential with biological samples.

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Immunophotoelectron microscopy: the electron optical analog of immunofluorescence microscopy.

Cited by 16 publications

References 22 publications

Fluorescence Quenching by Colloidal Heavy Metals Nanoparticles: Implications for Correlative Fluorescence and Electron Microscopy Studies

Fluorescence Quenching by Colloidal Heavy Metals Nanoparticles: Implications for Correlative Fluorescence and Electron Microscopy Studies

Protein kinase C inhibitor H‐7 alters the actin cytoskeleton of cultured cells

Challenges in Applying Photoemission Electron Microscopy to Biological Systems^†

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Immunophotoelectron microscopy: the electron optical analog of immunofluorescence microscopy.

Cited by 16 publications

References 22 publications

Fluorescence Quenching by Colloidal Heavy Metals Nanoparticles: Implications for Correlative Fluorescence and Electron Microscopy Studies

Fluorescence Quenching by Colloidal Heavy Metals Nanoparticles: Implications for Correlative Fluorescence and Electron Microscopy Studies

Protein kinase C inhibitor H‐7 alters the actin cytoskeleton of cultured cells

Challenges in Applying Photoemission Electron Microscopy to Biological Systems†

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Product

Resources

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Challenges in Applying Photoemission Electron Microscopy to Biological Systems^†