tetramethylrhodamine and coumarin

To build on the last century's tremendous strides in understanding the workings of individual proteins in the test tube, we now face the challenge of understanding how macromolecular machines, signaling pathways, and other biological networks operate in the complex environment of the living cell. The fluorescent proteins (FPs) revolutionized our ability to study protein function directly in the cell by enabling individual proteins to be selectively labeled through genetic encoding of a fluorescent tag. Although FPs continue to be invaluable tools for cell biology, they show limitations in the face of the increasingly sophisticated dynamic measurements of protein interactions now called for to unravel cellular mechanisms. Therefore, just as chemical methods for selectively labeling proteins in the test tube significantly impacted in vitro biophysics in the last century, chemical tagging technologies are now poised to provide a breakthrough to meet this century's challenge of understanding protein function in the living cell. With chemical tags, the protein of interest is attached to a polypeptide rather than an FP. The polypeptide is subsequently modified with an organic fluorophore or another probe. The FlAsH peptide tag was first reported in 1998. Since then, more refined protein tags, exemplified by the TMP- and SNAP-tag, have improved selectivity and enabled imaging of intracellular proteins with high signal-to-noise ratios. Further improvement is still required to achieve direct incorporation of powerful fluorophores, but enzyme-mediated chemical tags show promise for overcoming the difficulty of selectively labeling a short peptide tag. In this Account, we focus on the development and application of chemical tags for studying protein function within living cells. Thus, in our overview of different chemical tagging strategies and technologies, we emphasize the challenge of rendering the labeling reaction sufficiently selective and the fluorophore probe sufficiently well behaved to image intracellular proteins with high signal-to-noise ratios. We highlight recent applications in which the chemical tags have enabled sophisticated biophysical measurements that would be difficult or even impossible with FPs. Finally, we conclude by looking forward to (i) the development of high-photon-output chemical tags compatible with living cells to enable high-resolution imaging, (ii) the realization of the potential of the chemical tags to significantly reduce tag s

Topics: Animals; Connexin 43; Coumarins; Fluorescein; Fluorescent Dyes; Histones; Mice; NIH 3T3 Cells; Peptides; Proteins; Rhodamines

Terminal deoxynucleotidyltransferase (terminal transferase, E.C. 2.7.7.31) has been used to add a single fluorescent ribonucleotide to the 3' terminus of DNA sequencing primers, thereby creating primers suitable for automated DNA sequence analysis. The previously introduced procedure using fluorescein-UTP for the postsynthetic labeling of primers can, under appropriate reaction conditions, now be extended to commercially available fluorescein-ATP and fluorescein-CTP permitting greater flexibility in primer design. The products of these addition reactions have been shown to provide sequence data qualitatively and quantitatively identical to those obtained with conventional 5'-terminally labeled primers using cycle sequencing conditions in conjunction with an automated sequencer. Ribonucleotide derivatives of four other dyes (coumarin, tetramethylrhodamine, lissamine and Texas Red) were also examined for their potential in the terminal transferase-catalyzed reaction. Whereas coumarin-UTP was efficiently incorporated giving a monoaddition product, the conjugates of all other dyes with ATP, CTP and UTP were extremely poor substrates under all conditions tested.

Topics: Coumarins; DNA Nucleotidylexotransferase; DNA Primers; Fluorescein; Fluoresceins; Fluorescent Dyes; Rhodamines; Ribonucleotides; Sequence Analysis, DNA; Substrate Specificity; Xanthenes

The utility of p-phenylenediamine, 1,4-di-azobicyclo-(2.2.2.)-octane, and the commercial products Citifluor, Slowfade, and Vectashield, antifading agents frequently used as mounting media for fluorescence in situ hybridization, was investigated. Fading curves for bound fluorochromes were recorded with digital microscopy, and relative fluorescence intensities of fluorochromes in solution were measured with an aperture defined measurement system. The three commonly used fluorochromes, fluorescein, tetramethyl rhodamine, and coumarin, were studied. Vectashield offered the best antifading properties for all three fluorochromes, although their relative fluorescence intensity was slightly less in Vectashield in comparison with other antifading agents. In Vectashield, fluorescein, tetramethyl rhodamine, and coumarin showed half-life times of 96, 330, and 106 s, respectively, whereas in 90% glycerol in PBS (pH 8.5), these half-life time values were 9, 7, and 25 s, respectively. Vectashield is particularly recommended as a mounting medium for quantitative digital imaging microscopy and for multicolor applications, where it is easy to have errors due to differences in fading rates of the fluorochromes.

Topics: Coumarins; Fluorescein; Fluoresceins; Fluorescent Dyes; In Situ Hybridization, Fluorescence; Indicators and Reagents; Microscopy, Fluorescence; Rhodamines