Dual-Labeled Probes for Fluorescence and Electron Microscopy

Richard D. Powell, Carol M. R. Halsey, Edmund Gutierrez, James F. Hainfeld and Frederic R. Furuya

Nanoprobes, Incorporated, Stony Brook, NY 11790;

Robinson and Vandré's finding that the fluorescent signal obtained with combined Nanogold and fluorescein probes is still present after short periods of silver enhancement² suggests that larger, and hence more readily visualized metal clusters may still be compatible with fluorescent labels. Therefore, we have prepared new antibody probes in which both fluorophores and 2-3 nm platinum clusters are conjugated to antibody Fab' fragments and IgG molecules. The large clusters were prepared from platinum (II) acetate and stabilized with a mixture of hydorxylated and amino-derivatized 1,10-phenanthroline ligands as described previously,⁵ and converted to maleimides with sulfo-SMCC.¹ The maleimido- clusters were allowed to react overnight at 4°C with IgG molecules or Fab' fragments in which the hinge disulfide bonds had been slectively reduced to thiols.¹ Cluster conjugates were isolated by gel filtration (Superose-12 column), then then fluorescently labeled using fluorescein NHS ester (Molecular Probes) or Cy3 monofunctional NHS ester (Amersham Life Sciences) at pH 7.5; the dual-labeled conjugates were isolated by gel filtration (Superose-12).

Anti-rabbit IgG conjugates were used as secondary probes against a polyclonal rabbit anti-red blood cell antibody to label sheep red blood cells in suspension; labeling could be observed by fluorescence microscopy, as shown in Fig. 1a, although preliminary estimates indicate that fluorescence intensities were lower than with a fluorescein-labeled secondary IgG run as a control. Transmission electron microscopy showed approximately 2 nm platinum particles (Fig. 1b, c) which were readily visualized under conditions in which a comparable Nanogold conjugate was not. Immunoblot tests against a target IgG adsorbed to a nitrocellulose membrane also showed specific binding, with visualization of 0.1 ng of target IgG after silver enhancement.

The covalent attachment of metal cluster compounds has also enabled the preparation of combined fluorescent and Nanogold tracers by using starburst dendrimer macromolecules⁶ as carriers (Scheme 1). Mono-sulfo-NHS-Nanogold, prepared by the activation of monoamino Nanogold with bis (sulfo-succinimidyl) suberate, was coupled to eighth generation polyamidoamine dendrimers; After gel filtration to separate unbound Nanogold, 1 : 1 conjugates were separated from unconjugated dendrimer and from multiply gold-labeled derivatives by hydrophobic interaction chromatography, then labeled with Cy3 or Cy5 monofunctional NHS ester derivatives. The products were separated from excess dyes by repeated membrane centrifugation until the filtrate contained no fluorophore. Because of the high monodispersity of the dendrimer macromolecules, these new conjugates are highly regular in size. Although smaller than fluorescently labeled microspheres, they are sufficiently large that the gold cluster-fluorophore separation is greater than the Forster distance, and fluorescence is preserved.

References

1. R. D. Powell et al., J. Histochem. Cytochem. 45 (1997) 947.

2. J. M. Robinson and D. D. Vandré. J. Histochem. Cytochem. 45 (1997) 631.

3. P. Wu and L. Brand. Anal. Biochem. 218 (1994) 1.

4. Th. Forster., Ann. Physik., 2 (1948) 55.

5. R. D. Powell et al., Proc. Ann MSA Meeting, 54 (1996) 892.

6. D. A. Tomalia, A. M. Naylor and W. A. Goddard III, Angew. Chem. Int. Ed. Eng., 29, (1990), 138.

7. This work was supported by NIH grants 2R44 GM49564 and 1R44 GM56090.

FIG. 1: (a) Sheep red blood cells labeled with rabbit anti-red blood cell primary antibody followed by platinum / fluorescein anti-rabbit secondary IgG conjugate (original magnification X 1000).

(b) Electron micrograph of platinum cluster IgG conjugate (before fluorescein conjugation), negatively stained with methylamine vanadate on formvar-coated copper grid (original magnification: X 200,000. Bar = 20 nm) (UMIC, SUNY at Stony Brook).

(c) the same conjugate negatively stained with uranyl acetate (original magnification: X 200,000. Bar = 20 nm) (UMIC, SUNY at Stony Brook).

Other Applications:

Product Applications Special report: A very reliable pre-embedding immunogold method. Our 2002 paper: Nickel-NTA-Nanogold Binds his-Tagged Proteins. Our 2001 paper on DNA Nanowires. Our 1999 paper on Gold-Based Autometallography. Special report: In Situ Hybridization with Nanogold®-Streptavidin. Technical note: Nanogold® Staining on Gels. Our 1996 paper on Gold Liposomes. Special report: Nanogold® Labeling of Peptides. Technical note: RNA Labeling with Nanogold®. Our 1991 paper on A New 1.4 nm Gold-Fab' Probe. Our 1994 paper on Methylamine Vanadate (NanoVan) Negative Stain. Our 1990 paper on Conducting Polymer Films as EM Substrates. Research Applications Our 2005 paper: 5 nm Gold-Ni-NTA binds His Tags. Enzymatic Metallography: A Simple New Staining Method Our 2006 paper on Light and Electron Microscopy of Microsporida using Enzyme Metallography. Our 2004 paper on Enzymatic Metallography as a Correlative Light and Electron Microscopic Method. Our 2002 paper on Enzymatic Metallography: A Simple New Staining Method.

Research Applications (continued) Our 2007 paper on Correlative Enzymatic and Gold Probes for Light and Electron Microscopy. Our 1995 paper on Aldehyde Gold Clusters for Molecular Labeling. Our 2000 paper on Gold Cluster Crystals. Larger covalent gold probes: Our 2005 paper on Preparation of Covalent 3nm Gold – Fab’ Probes. Our 1999 paper on A Covalently Linked 10 nm Gold Immunoprobe. Combined fluorescent and gold probes: Our 2003 paper featuring Dextran-Texas Red®-Nanogold® Fluorescent Dyes for Use in Correlative Microscopy and Intravital Imaging. Our 2002 paper on Combined ALEXA-488 and Nanogold Antibody Probes. Our 1999 paper on Combined Cy3 / Nanogold Probes for Immunocytochemistry and In Situ Hybridization. Our 1998 paper on Dual-Labeled Probes for Fluorescence and Electron Microscopy. News: our original 1997 paper on Combined Fluorescent and Gold Immunoprobes. Our 1996 paper on Large Cluster and Combined Fluorescent and Gold Immunoprobes. Our 1994 paper on Combined Fluorescent and Gold Nucleic Acid Probes. Our 2005 paper on High Z Metal Carbonyls for Imaging and Microspectroscopy. Our 2005 paper on In Vivo Vascular Casting.