Published by AAAS B. N. G. Giepmans et al., Science 312, 217 -224 (2006) Fig. 3. Parallel application of targeting methods and fluorophores.

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Published by AAAS B. N. G. Giepmans et al., Science 312, (2006) Fig. 3. Parallel application of targeting methods and fluorophores

Types of fluorochromes 1. organic molecules (polyphenolic) natural & synthetic 2. metal chelates (lanthanides) 3. semiconductor crystals (Q-dots) 4. fluorescent proteins natural & engineered 5. expressible affinity reagents

BODIPY fluorophores 4,4-difluoro-4-bora-3a,4a-diaza-s-indacene

BODIPY fluorophores Normalized fluorescence emission spectra of 1) BODIPY FL 2) BODIPY R6 3) BODIPY TMR 4) BODIPY 581/591 5) BODIPY TR 6) BODIPY 630/650 7) BODIPY 650/665 fluorophores in methanol

DiI Family 1,1'-dioctadecyl-3,3,3',3'- tetramethylindocarbocyanine perchlorate ('DiI'; DiIC 18 (3)) Tract tracing in fixed tissue Remarkably stable – up to 2 years in vitro

DiI images

Fluorescence Spectra for DiXs

DiI Family 3,3'- dioctadecyloxacarbocyanine perchlorate ('DiO'; DiOC 18 (3)) 1,1'-dioctadecyl-3,3,3',3'- tetramethylindodicarbocyanine perchlorate ('DiD' oil; DiIC 18 (5) oil) DiO DiD

DiA 4-(4-(dihexadecylamino)styryl) -N-methylpyridinium iodide (DiA; 4-Di-16- ASP)

DiA in mouse retina 3 days after optic nerve transection 10 days after optic nerve transection

Dextrans Substituted dextran polymers Poly-(  -D-1,6-glucose) linkages, which render them resistant to cleavage by most endogenous cellular glycosidases Wide molecular weight range (3000 – 300K) Multiple fluorophores Biotin Lysine Fluoro-Ruby

Fish spinal cord

Cell lineage with dextrans The image on the left shows a 13 µm-thick section of a stage 6 (32-cell) Xenopus embryo fixed right after injection; this section exhibits significant autofluorescence due to the presence of residual yolk. The image on the right is a stage 10 (early gastrula) embryo

Fluorescent Microspheres polystyrene microspheres 0.02 – 15  m diameter

Lucifer Yellow

Texas Red

End of tract tracers

Types of fluorochromes 1. organic molecules (polyphenolic) natural & synthetic 2. metal chelates (lanthanides) 3. semiconductor crystals (Q-dots) 4. fluorescent proteins natural & engineered 5. expressible affinity reagents

Published by AAAS G. Gaietta et al., Science 296, (2002) No Caption Found

Published by AAAS G. Gaietta et al., Science 296, (2002) No Caption Found

Published by AAAS G. Gaietta et al., Science 296, (2002) No Caption Found

Published by AAAS J. Lippincott-Schwartz et al., Science 300, (2003) FRAP FLIP &PhRAP

Published by AAAS T. Misteli Science 291, (2001) Fluorescence Recovery After Photobleaching (FRAP)

Published by AAAS A. B. Houtsmuller et al., Science 284, (1999) Fluorescence Recovery After Photobleaching (FRAP)

Published by AAAS J. Lippincott-Schwartz et al., Science 300, (2003) No Caption Found

Published by AAAS R. Ando et al., Science 306, (2004) Fig. 3. Monitoring the nuclear import and export of importin-{beta}-Dronpa in COS7 cells

Published by AAAS R. Ando et al., Science 306, (2004) Fig. 2. Monitoring the nuclear import and export of ERK1-Dronpa in COS7 cells during stimulation with 100 ng/ml EGF

Foerster Resonance Energy Transfer dipole - dipole interaction

Foerster Resonance Energy Transfer 1.Distance between fluors 2.Spectral overlap 3.Orientation of dipoles

Foerster Resonance Energy Transfer E = 1 1+ (r/R 0 ) 6 “donor” “acceptor”

Foerster Resonance Energy Transfer E = 1 1+ (r/R 0 ) 6 “donor” “acceptor” efficiency Foerster radius

Foerster Resonance Energy Transfer r < 50 A

Foerster Resonance Energy Transfer (FRET) R 0 6 = 8.8 x  2 n -4 Q 0 J E = 1 1+ (r/R 0 ) 6

Foerster Resonance Energy Transfer (FRET) R 0 6 = 8.8 x  2 n -4 Q 0 J E = 1 1+ (r/R 0 ) 6 dipole orientation factor  2 ~ 2/3

Foerster Resonance Energy Transfer (FRET) R 0 6 = 8.8 x  2 n -4 Q 0 J E = 1 1+ (r/R 0 ) 6 refractive index quantum yield of donor spectral overlap integral

Foerster Resonance Energy Transfer (FRET) J = f D ( )  A ( ) 4 d

Foerster Resonance Energy Transfer (FRET) J = f D ( )  A ( ) 4 d normalized donor spectrum molar extinction coef of acceptor wavelength

Foerster Resonance Energy Transfer (FRET) R 0 6 = 8.8 x  2 n -4 Q 0 J E = 1 1+ (r/R 0 ) 6 J = f D ( )  A( ) 4 d

Foerster Resonance Energy Transfer

CFP YFP FRET 433 nm 476 nm 433 nm 527 nm Ca 2+ CaM M13

Published by AAAS P. Niethammer et al., Science 303, (2004) Fig. 2. Phosphorylation-dependent patterns of stathmintubulin interaction in Xenopus A6 cells

Published by AAAS P. J. Verveer et al., Science 290, (2000) Fluorescence Lifetime Imaging

Foerster Resonance Energy Transfer

Total Internal Reflection Microscopy

Published by AAAS D. J. Stephens et al., Science 300, (2003) Total Internal Reflection Microscopy

Synapto-pHluorin Fusion protein comprised of VAMP- 2/synaptobrevin - GFP (luminal domain) Developed by Miesenbock et al (98) Vesicular uptake is powered by V-type H + - ATPase2; pH ~ 5.5 GFP is pH sensitive (pKa = 7.1) 97% of GFP fluorescence is quenched in SV Some forms permit ratiometric quantification

Synapto-pHluorin Hela Cells

Synapto-pHluorin Visualizing synaptic transmission in hippocampal neurons Miesenbock et al Nature 394: (1998)

Synapto-pHluorin Visualizing exocytosis in RBL-2H3 cells Miesenbock et al Nature 394: (1998)

Copyright ©2006 Society for Neuroscience Atluri, P. P. et al. J. Neurosci. 2006;26: Figure 1. Rapid acid quench of surface SpH fluorescence allows measurement of internal alkaline vesicle pool and postendocytic reacidification time course

Copyright ©2005 by the National Academy of Sciences Li, Zhiying et al. (2005) Proc. Natl. Acad. Sci. USA 102, Fig. 1. Characterizing transgenic mice expressing spH