Cascade blue derivatives: water soluble, reactive, blue emission dyes evaluated as fluorescent labels and tracers.

Fluorescent dyes based on the pyrenyloxytrisulfonic acid (Cascade Blue) structure were prepared and evaluated. The dyes contain functional groups that react with amines, thiols, acids, aldehydes, and ketones, forming covalently bonded, fluorescent derivatives of molecules with broad biological interest. Reactive groups in the Cascade Blue dyes include carboxylic acids and activated esters, amines, hydrazides, alcohols, photoaffinity reagents, acrylamides, and haloacetamides. The dyes exhibited absorption maxima at 374-378 nm and 399-403 nm, with extinction coefficients in the range of 1.9 x 10(4)-2.4 x 10(4) M-1cm-1 and 2.3 x 10(4)-3.0 x 10(4) M-1cm-1, respectively. Emission maxima ranged from 422-430 nm. The spectral properties of the fluorescent dyes are sufficiently different from fluorescein to permit simultaneous use of both dyes with minimum spectral interference. The Cascade Blue derivatives have narrower spectral bandwidths and smaller Stokes' shifts than other reactive dyes with similar spectral properties, do not show appreciable sensitivity to pH, have higher solubilities in aqueous solution, and have good to excellent quantum yields. Cascade Blue conjugates of a number of histochemically and biologically useful molecules were prepared, including dextrans, albumins, Fc receptor binding proteins, antibodies, lectins, membrane receptor binding proteins, and biotin binding proteins, as well as biological particles and bacteria. Cascade Blue conjugates of secondary and tertiary labels yielded specific fluorescence localization in the indirect immunofluorescent staining of human epithelial cell (HEp-2) nuclei.     

Evaluation of fluorescent compound interference in 4 fluorescence polarization assays: 2 kinases, 1 protease,and 1 phosphatase

With the increasing use of fluorescence-based assays in high-throughput screening (HTS), the possibility of interference by fluorescent compounds needs to be considered. To investigate compound interference, a well-defined sample set of biologically active compounds, LOPAC, was evaluated using 4 fluorescein-based fluorescence polarization (FP) assays. Two kinase assays, a protease assay, and a phosphatase assay were studied. Fluorescent compound interference and light scattering were observed in both mixture- and single-compound testing under certain circumstances. In the kinase assays, which used low levels (1-3 nM) of fluorophore, an increase in total fluorescence, an abnormal decrease in mP readings, and negative inhibition values were attributed to compound fluorescence. Light scattering was observed by an increase in total fluorescence and minimal reduction in mP, leading to false positives. The protease and phosphatase assays, which used a higher concentration of fluorophore (20-1200 nM) than the kinase assays, showed minimal interference from fluorescent compounds, demonstrating that an increase in the concentration of the fluorophore minimized potential fluorescent compound interference. The data also suggests that mixtures containing fluorescent compounds can result in either false negatives that can mask a potential "hit" or false positives, depending on the assay format. Cy dyes (e.g., Cy3B and Cy5 ) excite and emit further into the red region than fluorescein and, when used in place of fluorescein in kinase 1, eliminate fluorescence interference and light scattering by LOPAC compounds. This work demonstrates that fluorescent compound and light scattering interferences can be overcome by increasing the fluorophore concentration in an assay or by using longer wavelength dyes.     

Direct measurement of phagolysosomal esterase activity

A new method of directly measuring esterase activity within phagolysosomes has been developed. Decanoyl fluorescein- binding microspheres were prepared and phagocytosed by human peripheral neutrophils. Within phagolysosomes lysosomal esterase hydrolyzed decanoyl fluorescein on the microspheres, causing the conversion of decanoyl fluorescein- binding microspheres (non-fluorescent) into fluorescein- binding microspheres (fluorescent). The activity of phagolysosomal esterase in intact neutrophils was assayed by the measurement of the fluorescence intensity without rupturing cells. By use of a flow cytometer, esterase activity within phagolysosomes in single cells was measured.     

Fluorescent rhodol derivatives: versatile, photostable labels and tracers.

A series of chemically reactive, fluorescent rhodol derivatives was prepared and evaluated. Reactive functional groups included activated esters, amines, haloacetamides, fixable hydrazide derivatives, acrylamides, and photoaffinity reagents. Depending on the choice of substituents, absorption maxima of the dyes varied from 490 to 550 nm with extinction coefficients that were generally greater than 50,000 M-1 cm-1 in aqueous solution and emission maxima from 520 to 580 nm. Most of the compounds investigated exhibited fluorescence lifetimes between 3 and 4 ns. Individual derivatives were suitable for excitation with the 488 and 514-nm lines of the argon ion laser and the 546-nm line of the mercury arc lamp and were compatible for use with standard fluorescein and rhodamine filter sets. The rhodol dyes were more photostable and less sensitive to pH changes in the physiological range than fluorescein derivatives. Some examples show absorption maxima at or near 514 nm, an excitation wavelength that is useful for multicolor fluorescence microscopy, flow cytometry, and DNA sequencing. Derivatives were also prepared that exhibit absorption and emission maxima similar to those of tetramethylrhodamine (TMR) analogs but with higher quantum yields in aqueous solution. A number of the dyes had higher solubilities in aqueous systems and were less quenched on conjugation to proteins than TMR derivatives. Appropriate substitution results in a wider range of solubilities in hydrophilic or lipophilic solvents than is easily accomplished with fluorescein or TMR derivatives. Conjugates of a number of the rhodol fluorophores were generally more photostable and less pH sensitive than fluorescein conjugates and more fluorescent than TMR conjugates.     

Dicarboxy-dichlorofluorescein: a new fluorescent probe for measuring acidic intracellular pH

Derivatives of fluorescein sensitive to pH are extensively utilized for the determination of intracellular pH (pHi). Available dyes have pKa values of approximately 7.0, and are not well suited for measuring acidic pHi. We examined the fluorescein derivative, 5 (and 6)-carboxy-2',7'-dichlorofluorescein (CDCF) for its potential in the microspectrofluorometric measurement of pHi during acidic conditions. CDCF showed intense fluorescence and pH sensitivity near its "effective" pKa value of 4.2, using a 495/440 nm dual excitation wave-length ratio method. Protein interactions caused fluorescence ratio deviations which were most pronounced at the extremes of pH, whereas calcium and magnesium concentrations had little effect on the fluorescent ratio intensity. Intracellular calibration performed using nigericin in the presence of high potassium eliminated the need to correct for protein interactions, and the ratio method minimized any variations due to dye concentration differences or instrument fluctuation. Intracellular retention of the dye was high, and 95% of the initial signal remained after 1 h. Fluorescence bleaching was 14.5% after 1 h of continuous excitation and cell survival was not affected by dye loading. We conclude that CDCF is an excellent intracellular pH indicator in the pH range of 4-5.     

Dissociation of the DNA polymerase III holoenzyme beta 2 subunits is accompanied by conformational change at distal cysteines 333

The beta subunit of DNA polymerase III holoenzyme is in a dimer-monomer equilibrium at physiological beta concentrations. Dissociation is accompanied by the fluorescence enhancement of a fluorophore attached to a unique sulfhydryl group of beta (Griep, M. A., and McHenry, C. S. (1988) Biochemistry 27, 5210-5215). Sequencing of the isolated tryptic peptides of beta revealed that the fluorescent maleimide group was attached to cysteine 333. The 2 residues, lysine 332 and glutamate 334, that flank this residue are hydrophilic and may place cysteine 333 on the surface of beta, explaining its high reactivity. Fluorescence energy transfer permitted us to locate the uniquely labeled cysteines 333 of beta at the distal ends of the beta dimer. When the beta dimer was dissociated to monomers, the accompanying alteration of the conformational state was reported by the fluorescein-5-maleimide (fluorescein)-labeled cysteines which were located far from the dimer interface. The carboxyl of fluorescein had a fluorescence pKa of 6.9 when beta was in its dimeric state. The pKa decreased by 0.3 pH unit upon dissociation to monomers and resulted in the fluorescence enhancement that was observed when the signal was monitored at constant pH. The adjacent glutamate 334 apparently increased the pKa of the attached fluorescein when beta was in its dimeric state. Movement of either the adjacent lysine 332 amino side chain to a closer position or glutamate 334 to a position further away could lower the pKa upon beta monomerization. Thus, beta undergoes a conformational change concomitant with dimer dissociation that was transmitted to the opposite ends of the beta dimer. The pKa of fluorescein attached to the distal cysteines was shifted, leading to greater ionization and enhanced fluorescence.     

Study on the inhibition of testicular polyadenylate polymerase stimulated by manganese]

Many different types of naturally occurring substances and of drugs were examined as potential inhibitors of a Mn++-stimulated and poly(A)-primed polyadenylate polymerase that was partially purified from rat testis. By far the most active inhibitors were anionic dyes that were either of the diazo naphthyl sulfonate category, such as Evans Blue, or were halogenated derivatives of fluorescein, like Rose Bengal. The characteristics of these in vitro inhibitions, which did not involve any photo-sensitized reactions, were examined in considerable detail.     

Purification and partial characterisation of a 1.57 kDa thermostable esterase from Bacillus stearothermophilus

The molecular mass of esterases usually falls in the range of 20–160 kDa, although an esterase of 5.7 kDa from Candida lipolytica has been described. Three other enzymes smaller than 10 kDa have been reported, all of which were more thermostable than their higher molecular mass counterparts. This paper describes the purification of an extracellular esterase hydrolysing fluorescein dibutyrate from Bacillus stearothermophilus NCIMB 13335. The esterase had a molecular mass of 1.57 kDa when analysed by SDS-PAGE, gel filtration and MALDI-TOF spectrometry. This enzyme retained more than 90% of its activity after incubation at 90°C for 2 h.     

Small enzymes with esterase activities from two thermophilic fungi, Emericella nidulans and Talaromyces emersonii

Extracellular esterase activities in Emericella nidulans and Talaromyces emersonii are attributed to small enzymes with molecular weights less than 10 kDa (microenzymes). A 1.6 kDa esterase accounted for most of the esterase activity observed in both organisms and one of them also contained a 4.1 kDa microenzyme with weaker esterase activity. These esterases were growth-associated and active towards fluorescein dibutyrate and -naphthyl acetate as well as tributyrin.     

The active site of thrombin is altered upon binding to thrombomodulin. Two distinct structural changes are detected by fluorescence, but only one correlates with protein C activation.

The association of thrombin with thrombomodulin, a non-enzymatic endothelial cell surface receptor, alters the substrate specificity of thrombin. Complex formation converts thrombin from a procoagulant to an anticoagulant enzyme. Structure-function analysis of this change in specificity is facilitated by the availability of two soluble proteolytic derivatives of thrombomodulin, one consisting of the six repeated growth factor-like domains of thrombomodulin (GF1-6) and the other containing only the fifth and sixth such domains (GF5-6). Both derivatives can bind to thrombin and block fibrinogen clotting activity, though only the larger GF1-6 can stimulate the activation of protein C. To ascertain whether the substrate specificity change from fibrinogen to protein C is accompanied by structural changes in the active site of the enzyme, fluorescent dyes were positioned at different locations within the active site. A 5-dimethylaminonaphthalene-1-sulfonyl (dansyl) dye was covalently attached to the active site serine to form dansyl-thrombin, while either a fluorescein or an anilinonaphthalene-6-sulfonic acid (ANS) dye was attached covalently to the active site histidine of thrombin via a D-Phe-Pro-Arg linkage. The environment of the dansyl dye was altered in a similar fashion when either GF1-6 or GF5-6 bound to thrombin, since a similar reduction in dansyl emission intensity was elicited by these two thrombomodulin derivatives (25 and 32%, respectively). These spectral changes, and all others in this study, were saturable and reached a maximum when the ratio of thrombomodulin derivative to thrombin was close to 1. The environments of the fluorescein and ANS dyes were also altered when GF1-6 bound to thrombin because binding resulted in emission intensity changes of -13% and +18%, respectively. In contrast, no fluorescence changes were observed when the fluorescein and ANS thrombin derivatives were titrated with GF5-6. Thus, the structure of the active site was altered by thrombomodulin both immediately adjacent to the active site serine and also more than 15 A away from it. However, the structural change far from Ser-195 was only elicited by thrombomodulin species that stimulate thrombin-dependent activation of protein C.     

Fluorescein conjugates of 9- and 10-hydroxystearic acids: synthetic strategies, photophysical characterization, and confocal microscopy applications

Different strategies are presented to conjugate a fluorescein moiety to 9- and 10-hydroxystearic acids (HSAs). 5-Amino-fluorescein (5-AF) was used as a starting reagent. When reacted with acyl-chloride-modified HSAs, 5-AF gave rise to stable amide derivatives with a 75% reaction yield. These products exhibited the typical steady-state and time-resolved fluorescence properties of the fluorescein chromophore with absorption at 494 nm and emission at 519 nm. Flow cytometry studies confirmed the distinct proapoptotic effect of underivatized 9-HSA on Jurkat cells and revealed a comparable ability of its amide derivative. Confocal microscopy imaging studies showed that green fluorescence could stain intracellular membranous structures. Moreover, dual-dye labeling with Mito Tracker Red, followed by colocalization analysis, revealed that HSA can move to the mitochondria. Thus, fluorescent derivatives of HSA can be used to monitor the localization of these biologically active molecules in living cells and can provide a useful tool for linking biochemical investigation with optical visualization methods. In contrast, when unmodified HSAs were used, the reaction gave monoesterified and diesterified fluorescein derivatives. These products exhibited unusual steady-state and time-resolved fluorescence properties with the excitation wavelength at 342 nm and the emission wavelength at 432 nm. It is shown that the synthesized HSA amides of fluorescein provide all of the typical photophysical and instrumental advantages of this popular dye, whereas the unusual luminescence and excitation properties of the monoester and diester of the 5-aminofluorescein would make these dyes interesting to explore as potential candidates for two photon excitation applications.     

Inter- and intramolecular fluorescence quenching of organic dyes by tryptophan

Steady-state and time-resolved fluorescence measurements were performed to elucidate the fluorescence quenching of oxazine, rhodamine, carbocyanine, and bora-diaza-indacene dyes by amino acids. Among the natural amino acids, tryptophan exhibits the most pronounced quenching efficiency. Especially, the red-absorbing dyes ATTO 655, ATTO 680, and the oxazine derivative MR 121 are strongly quenched almost exclusively by tryptophan due to the formation of weak or nonfluorescent ground-state complexes with association constants, K(ass.), ranging from 96 to 206 M(-1). Rhodamine, fluorescein, and bora-diaza-indacene derivatives that absorb at shorter wavelengths are also quenched substantially by tyrosine residues. The quenching of carbocyanine dyes, such as Cy5, and Alexa 647 by amino acids can be almost neglected. While quenching of ATTO 655, ATTO 680, and the oxazine derivative MR121 by tryptophan is dominated by static quenching, dynamic quenching is more efficient for the two bora-diaza-indacene dyes Bodipy-FL and Bodipy630/650. Labeling of the dyes to tryptophan, tryptophan-containing peptides, and proteins (streptavidin) demonstrates that knowledge of these fluorescence quenching processes is crucial for the development of fluorescence-based diagnostic assays. Changes in the fluorescence quantum yield of dye-labeled peptides and proteins might be used advantageously for the quantification of proteases and specific binding partners.     

Labeling of the cytoplasmic domain of the influenza virus hemagglutinin with fluorescein reveals sites of interaction with membrane lipid bilayers

The hemagglutinin (HA) glycoprotein of influenza virus was labeled in its cytoplasmic domain with fluorescein. Reactive amino groups in the external domain were blocked by modification of the intact virus with the membrane-impermeable reagent isethionyl acetimidate. The HA was then solubilized with the detergent octyl glucoside, and the single lysine in the cytoplasmic domain was reacted with fluorescein isothiocyanate. This protocol resulted in the incorporation of 1.3 mol of fluorescein/mol of HA. Using a virus strain lacking lysine in the cytoplasmic domain of HA, it was determined that 0.47 mol of fluorescein/mol of HA was located at an additional site(s). The fluorescein groups at both sites exist in an environment of reduced polarity as shown by a shift in excitation and emission maxima and a shift in the pKa of the fluorescein groups. The fluorescence polarization and the pKa of the fluorescein groups were greater when the HA was incorporated into liposomes than when in detergent solution. These data indicate that the fluorescein groups interact directly with the lipid bilayer, probably in the phospholipid head-group region. The fluorescence properties of the labeled HA were not responsive to the gel to liquid-crystal phase transition in the lipid bilayer. These results indicate that the boundary between the cytoplasmic domain and the hydrophobic sequence that anchors the protein to the lipid bilayer is located in the head-group region of the bilayer.     

Evaluation of ChemChrome V6 for bacterial viability assessment in waters

The efficiency of ChemChrome B (CB) and ChemChrome V6 (CV6) dyes to stain viable bacterial cells in water was compared. Both dyes are fluorogenic esters converted to free fluorescein by esterase activity. The dyes were applied to a wide variety of bacterial species, including those poorly stained by CB, and to natural waters. Some species tested gave unacceptable low fluorescence intensities by being inefficiently or non-labelled with the CB. In contrast, CV6-stained bacteria were easily detected by both flow cytometry and solid-phase cytometry. As a consequence, higher viable cell counts were found with CV6 compared with CB in natural waters. Viable counts determined by CV6 staining were always higher than cfu counts. In contrast, respiring cell counts (CTC) were always lower than CV6 counts and, in the case of tap and mineral waters, they were lower than cfu counts.     

A domain of membrane-bound blood coagulation factor Va is located far from the phospholipid surface. A fluorescence energy transfer measurement

The larger subunit of blood coagulation factor Va was covalently labeled with iodoacetamido derivatives of fluorescein and rhodamine without loss of functional activity, as measured by either the one-stage clotting assay or the ability to accelerate prothrombin activation in a purified system. The spectral properties of the dyes were not altered by the presence or absence of the smaller subunit of factor Va, Ca2+, prothrombin, factor Xa, or phosphatidylcholine/phosphatidylserine (PC/PS, 4:1) vesicles. When fluorescein-labeled protein (factor VaF) was titrated with PC/PS vesicles containing either octadecylrhodamine or 5-(N-hexadecanoylamino)eosin, fluorescence energy transfer was observed between the protein-bound donor dyes and the acceptor dyes at the outer surface of the phospholipid bilayer. The extent of energy transfer correlated directly with the extent of protein binding to the vesicles monitored by light scattering. The distance of closest approach between the fluorescein on factor Va and the bilayer surface averaged 90 A for the two different acceptors. Association of factor VaF with factor Xa on the phospholipid surface reduced this separation by 7 A, but association with prothrombin did not alter the distance between the labeled domain on factor VaF and the surface. The efficiency of diffusion-enhanced energy transfer between rhodamine-labeled factor Va and terbium dipicolinate entrapped inside PC/PS vesicles was less than 0.01, consistent with the location of the dye far above the inner surface of the vesicle. Thus, a domain of membrane-bound factor Va is located a minimum of 90 A above the phospholipid surface.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetic studies of wheat carboxypeptidase-catalyzed reaction: differences in pressure and temperature dependence of peptidase and esterase activities

A kinetic study of hydrolytic catalysis by wheat bran carboxypeptidase (carboxypeptidase W) was carried out using 3-(2-furyl)acryloyl-acylated (Fua-) synthetic substrates. This enzyme showed high esterase activity in addition to the intrinsic carboxypeptidase activity. The optimum pH for the peptidase activity (kcat/Km) was at pH 3.3 and the kcat/Km value decreased with increasing pH with an apparent pKa of 4.50, while the esterase activity increased with pH up to pH 8 with an apparent pKa of 6.04. Optimum pH's for kcat for the peptidase and esterase reactions were also very different and their apparent pKa values were 3.80 and 6.15, respectively. From a measurement of the pressure dependences of kcat and Km, the activation volumes (delta V not equal to) and reaction volumes (delta V), respectively, were determined. delta V not equal to for kcat was -7 to -8 ml/mol for peptidase and -2 to -3 ml/mol for esterase. These results lead us to propose that the peptidase and esterase activities of carboxypeptidase W are different not in the rate-determining steps in a common reaction pathway, but in the binding modes and/or catalytic site(s).     

Conversion of pyridylamino sugar chains to 1-amino-1-deoxy derivatives, intermediates for tagging with fluorescein and biotin.

Pyridylamino (PA) derivatives of sugar chains were converted to 1-amino-1-deoxy derivatives. PA-lactose as a model compound was reduced with hydrogen, then treated with hydrazine. The product obtained was identified as 1-amino-1-deoxylactitol by mass spectrometry and chromatography with 1-amino-1-deoxylactitol as standard. PA-N-acetylglucosamine was converted to 1-amino-1-deoxy-N-acetylglucosaminitol under the same conditions. As an application, Man alpha 1-6(Man alpha 1-3)Man alpha 1- 6(Man alpha 1-2Man alpha 1-3)-Man beta 1-4GlcNAc beta 1-4GlcNAc-PA was converted to the 1-amino-1-deoxy derivative, which was further derivatized with fluorescein isothiocyanate or biotin sulfo-N-hydroxy-succinimide ester. Binding of these derivatives to concanavalin A dot-blotted on a nitrocellulose membrane was confirmed by fluorescence and by streptavidin-peroxidase conjugate. This conversion allowed replacement of the PA-group in PA-sugar chains which can be easily purified from glycoconjugates.     

Comparison of spectrum-shifting intracellular pH probes 5'(and 6')-carboxy-10-dimethylamino-3-hydroxyspiro[7H-benzo[c]xanthene-7, 1'(3'H)-isobenzofuran]-3'-one and 2',7'-biscarboxyethyl-5(and 6)-carboxyfluorescein.

The dyes carboxy-SNARF-1 and BCECF are fluorescent probes of intracellular pH that exhibit changes in spectral shape upon proton binding which allow one to use measurements of fluorescence at two or more wavelengths in order to measure pH without artifacts associated with variability in dye loading, etc. In evaluating these dyes for this study, whole spectra, rather than measurements at two wavelengths, were analyzed. For BCECF, the effects of the intracellular milieu were minimal: both the pH-sensitive excitation spectrum and the pKa agreed closely with values found in extracellular solution. In contrast, both the spectra and the pKa for the emission spectrum-shifting carboxy-SNARF-1 showed significant differences between intracellular and extracellular dye. As a result, extremely misleading values for intracellular pH will be obtained if one attempts to use extracellular dye to calibrate intracellular carboxy-SNARF-1 measurements. Multiple origins were found for the discrepancy: (i) the intracellular dye was found to be significantly quenched, with the deprotonated form being more strongly quenched than the protonated form; and (ii) the pKa for the equilibrium with intracellular hydrogen ions was shifted by +0.2 pH units. These effects were readily reversed by disruption of the cell, but were not due to sequestering of dye in an acidic cell compartment.     

Fluorescein-based amino acids for solid phase synthesis of fluorogenic protease substrates

An efficient synthesis of new type fluorescent amino acids is described. The Fmoc-protected dyes can be prepared in a four-step procedure with approximately 30% overall yield from aminofluoresceins and other inexpensive commercially available precursors. The dyes are much more photostable compared to fluorescein and exhibit constant pH-independent fluorescence that is advantageous in biological applications. The Fmoc-protected fluorescent amino acids are ready for use in solid phase peptide synthesis. As a proof of concept, a fluorogenic papain substrate was synthesized and employed for on-bead detection of the protease activity. By using a novel technique for quantitative analysis of bead fluorescence, a approximately 2.7-fold increase in mean bead brightness was measured and was attributed to substrate cleavage by papain. The new type fluorescent amino acids seem to be a promising tool for the synthesis of fluorescent peptide ligands and fluorogenic protease substrates.     

The use of vital dyes to assess embryonic viability in the hamster, Mesocricetus auratus

Experiments were designed to assess the use of the vital dyes trypan blue and fluorescein diacetate as indicators of the viability of hamster ova and embryos. Exclusion of trypan blue and fluorescence with fluorescein diacetate showed high correlations with uptake of [3H]uridine by ova and further development of embryos in vitro. Ova killed by freezing and thawing incorporated [3H]uridine at background levels. Trypan blue exclusion and fluorescein diacetate uptake were highly correlated with each other (r = 0.99). Trypan blue and fluorescein diacetate serve as excellent indices of viability in ova and early embryos of hamsters.