A fluorimetric method for the determination of tryptophan in animal tissues

Tryptophan, tryptamine and peptides containing N-terminal tryptophan give two highly fluorescent products on treatment with dithiothreitol and acid ninhydrin reagent 1 or 2. The first fluorescent product (product A) gives an emission at 500nm on activation at 390–400nm and is stable for 20min. The second product (product B), which gives an emission at 530nm on activation at 470nm, is detectable within 1h after the reaction. It gives almost maximum intensity in 4h and is stable for at least 48h. Except lysine, which in equimolar amounts gives less than 1% of a product similar to product B, no other naturally occurring amino compounds give fluorescent products. A procedure is given for the determination of 0.05–34nmol of tryptophan in tissue extracts. By using this procedure rat brain was found to contain 17.56±0.76 (s.e.m.) nmol/g wet wt.     

Comparison of fluorescence characteristics of products of peroxidation of membrane phospholipids with those of products derived from reaction of malonaldehyde with glycine as a model of lipofuscin fluorescent substances

The fluorescence characteristics of product (I), formed during the lipid peroxidation of rat liver phosphatidylcholine liposomes containing glycine, and fluorescent product (II), derived from the reaction of malonaldehyde with glycine, were examined to elucidate the mechanism of fluorescent chromophore formation. Fluorescent product (I) had a fluorescence emission maximum at 430 nm when excited at 360 nm; its fluorescence intensity decreases in alkaline medium, but is restored by readjustment of pH to neutrality. In contrast, fluorescent product (II) exhibited an emission maximum at 458 nm, and the fluorescence was quenched at acidic pH. The fluorescent substances formed during the lipid peroxidation of hemoglobin-free human erythrocyte ghost membranes had similar fluorescence characteristics to product (I). Gel filtration experiments showed that molecular size of fluorescent product (I) was larger than that of fluorescent product (II). The thiobarbituric acid-reactive substances released from peroxidizing liposomal phospholipids had a larger molecular size than malonaldehyde, and produced little or no fluorescence with glycine. It is concluded that the precursor of the fluorescent product formed during the lipid peroxidation of membrane phospholipids differs from malonaldehyde. The mechanism of the formation of blue emitting fluorescent material, believed to be a component of lipofuscin, seems to involve peroxidized phospholipids of the membrane.     

Fluorescent analogs of NAADP with calcium mobilizing activity

Nicotinic acid adenine dinucleotide phosphate (NAADP) mobilizes Ca²⁺ through a mechanism totally independent of cyclic ADP-ribose or inositol trisphosphate. Fluorescent analogs of NAADP were synthesized in this study to facilitate further characterization of this novel Ca²⁺ release mechanism. The base-exchange reaction catalyzed by ADP-ribosyl cyclase was utilized to convert nicotinamide 1,N⁶-ethenoadenine dinucleotide phosphate to a fluorescent product, nicotinic acid 1,N⁶-ethenoadenine dinucleotide phosphate (etheno-NAADP). The excitation spectrum of the product showed two maxima at 275 nm and 300 nm and an emission maximum at 410 nm. An aza derivative of etheno-NAADP was also synthesized by sequential treatments with NaOH and nitrite. The product, nicotinic acid 1,N⁶-etheno-2-aza-adenine dinucleotide phosphate (etheno-aza-NAADP) had excitation maxima at 280 nm and 360 nm and an emission maximum at 470 nm. The fluorescence of both analogs was sensitive to polarity and exhibited a 3–4-fold enhancement going from an aqueous buffer to an organic solvent. Proton-NMR measurements confirmed the presence of the etheno ring in both analogs. In the aza derivative the proton at the 2-position of the adenine ring was absent, consistent with the conversion of the 2-carbon to a nitrogen. Both analogs could activate Ca²⁺ release from sea urchin egg homogenates and the half-maximal concentrations for etheno-aza-NAADP and etheno-NAADP were at about 2.5 μM and 5 μM, respectively. At sub-threshold concentrations, both analogs could also function as antagonists, inactivating the NAADP-sensitive Ca²⁺ release with a half-maximal concentration of 60–80 nM. Microinjection of etheno-aza-NAADP into live eggs activated Ca²⁺ increase and triggered a cortical exocytotic reaction confirming its effectiveness in vivo. These fluorescent analogs are potentially useful for visualizing the novel Ca²⁺ stores that are sensitive to NAADP in live cells.     

A rapid,ideal, and eco-friendlier protocol for quantifying proline

Proline, a stress marker, is routinely quantified by a protocol that essentially uses hazardous toluene. Negative impacts of toluene on human health prompted us to develop a reliable alternate protocol for proline quantification. Absorbance of the proline-ninhydrin condensation product formed by reaction of proline with ninhydrin at 100 °C in the reaction mixture was significantly higher than that recorded after its transfer to toluene, revealing that toluene lowers sensitivity of this assay. λ _max of the proline-ninhydrin complex in the reaction mixture and toluene were 508 and 513 nm, respectively. Ninhydrin in glacial acetic acid yielded higher quantity of the proline-ninhydrin condensation product compared to ninhydrin in mixture of glacial acetic acid and H₃PO₄, indicating negative impact of H₃PO₄ on proline quantification. Further, maximum yield of the proline-ninhydrin complex with ninhydrin in glacial acetic acid and ninhydrin in mixture of glacial acetic acid and H₃PO₄ was achieved within 30 and 60 min, respectively. This revealed that H₃PO₄ has negative impact on the reaction rate and quantity of the proline-ninhydrin complex formed. In brief, our proline quantification protocol involves reaction of a 1-ml proline sample with 2 ml of 1.25 % ninhydrin in glacial acetic acid at 100 °C for 30 min, followed by recording absorbance of the proline-ninhydrin condensation product in the reaction mixture itself at 508 nm. Amongst proline quantification protocols known till date, our protocol is the most simple, rapid, reliable, cost-effective, and eco-friendlier.     

Chloroplast culture: The chlorophyll repair potential of mature chloroplasts incubated in a simple medium

The chlorophyll repair potential of mature Cucumis chloroplasts incubated in a simple Tris-HCI/sucrose medium is described. The chloroplasts were isolated from green, fully expanded Cucumis cotyledons which were capable of chlorophyll repair. This was evidenced by a functional chlorophyll biosynthetic pathway in the mature tissue. The biosynthesis of protochlorophyllide from exogenous δ-aminolevulinic acid was used as a marker for the operation of the chlorophyll biosynthetic chain between δ-aminolevulinic acid and protochlorophyllide. The conversion of exogenous protochlorophyllide into chlorophyll a was used as a marker for the operation of the chlorophyll pathway beyond protochlorophyllide. It appeared from these studies that contrary to published reports, unfortified fully developed Cucumis chloroplasts incubated in Tris-HCl/sucrose without the addition of cofactors exhibited a partial and limited chlorophyll repair capability. Their net tetrapyrrole biosynthetic competence from δ-aminolevulinic acid was confined to the accumulation of coproporphyrin. No net tetrapyrrole biosynthesis beyond coproporphyrin was observed. However, the plastids were capable of incorporating small amounts of δ-amino-[4-¹⁴C]levulinic acid into [¹⁴C] protochlorophyllide but were incapable of converting exogenous protochlorophyllide into chlorophyll. After prolonged incubation of the unfortified chloroplasts in the dark, a fluorescent protochlorophyllide-like compound accumulated. This compound [Cp (E₄₃₀-F₆₃₁)] exhibited a soret excitation maximum at 430 nm (E₄₃₀) and a fluorescence emission maximum at 631 nm (F₆₃₁) in methanol/acetone (4 : 1, v/v). Cp (E₄₃₀-F₆₃₁) was shown to be neither protochlorophyllide nor zinc-protochlorophyllide but an enzymatic degradation product of chlorophyll. The exact chemical identity of this compound has not yet been determined.     

Biogenesis of phycobiliproteins: II. CpcS-I and CpcU comprise the heterodimeric bilin lyase that attaches phycocyanobilin to CYS-82 OF beta-phycocyanin and CYS-81 of allophycocyanin subunits in Synechococcus sp. PCC 7002

The Synechococcus sp. PCC 7002 genome encodes three genes, denoted cpcS-I, cpcU, cpcV, with sequence similarity to cpeS. CpcS-I copurified with His(6)-tagged (HT) CpcU as a heterodimer, CpcSU. When CpcSU was assayed for bilin lyase activity in vitro with phycocyanobilin (PCB) and apophycocyanin, the reaction product had an absorbance maximum of 622 nm and was highly fluorescent (lambda(max) = 643 nm). In control reactions with PCB and apophycocyanin, the products had absorption maxima at 635 nm and very low fluorescence yields, indicating they contained the more oxidized mesobiliverdin (Arciero, D. M., Bryant, D. A., and Glazer, A. N. (1988) J. Biol. Chem. 263, 18343-18349). Tryptic peptide mapping showed that the CpcSU-dependent reaction product had one major PCB-containing peptide that contained the PCB binding site Cys-82. The CpcSU lyase was also tested with recombinant apoHT-allophycocyanin (aporHT-AP) and PCB in vitro. AporHT-AP formed an ApcA/ApcB heterodimer with an apparent mass of approximately 27 kDa. When aporHT-AP was incubated with PCB and CpcSU, the product had an absorbance maximum of 614 nm and a fluorescence emission maximum at 636 nm, the expected maxima for monomeric holo-AP. When no enzyme or CpcS-I or CpcU was added alone, the products had absorbance maxima between 645 and 647 nm and were not fluorescent. When these reaction products were analyzed by gel electrophoresis and zinc-enhanced fluorescence emission, only the reaction products from CpcSU had PCB attached to both AP subunits. Therefore, CpcSU is the bilin lyase-responsible for attachment of PCB to Cys-82 of CpcB and Cys-81 of ApcA and ApcB.     

Identification of the enol tautomer of imidazolone propionate as the urocanase reaction product

A fluorescent product was transiently formed during catalysis by urocanase from Pseudomonas putida. The fluorophore showed an emission maximum at 430 nm when excited at 330 nm, essentially identical to that exhibited by the enol tautomer of imidazolone propionate. The keto isomer was not fluorescent under these conditions. In aqueous acid solutions where imidazolone propionate is relatively stable, an equilibrium mixture of tautomeric forms contained approximately 1% of the enol isomer. In ethanolic solutions, the equilibrium concentration of enol tautomer increased to approximately 25%. The differing content of imidazolone propionate tautomers as a function of solvent conditions permitted a comparison of the keto and enol forms as substrates for the reverse reaction. This revealed an almost complete preference for the enol tautomer. These results are taken as direct proof that enol imidazolone propionate is the true urocanase reaction product.     

Possible involvement of the lipid-peroxidation product 4-hydroxynonenal in the formation of fluorescent chromolipids.

The effects of the lipid-peroxidation product 4-hydroxynonenal on the formation of fluorescent chromolipids from microsomes, mitochondria and phospholipids were studied. Incubation of freshly prepared rat liver microsomes or mitochondria with 4-hydroxynonenal results in a slow formation of a fluorophore with an excitation maximum at 360 nm and an emission maximum at 430 nm. The rate and extent of the development of the 430 nm fluorescence can be significantly enhanced by ADP-iron (Fe3+). With microsomes, yet not with mitochondria. NADPH has a catalytic effect similar to that of ADP-iron. Fluorescent chromolipids with maximum excitation and emission at 360/430 nm are also formed during the NADPH-linked ADP-iron-stimulated lipid peroxidation. Phosphatidylethanolamine and phosphatidylserine react with 4-hydroxynonenal revealing a fluorophore with the same spectral characteristics as that obtained in the microsomal and mitochondrial system. The findings suggest that the fluorescent chromolipids formed by lipid peroxidation are not derived from malonaldehyde, but are formed from 4-hydroxynonenal or similar reactive aldehydes via a NADPH and/or ADP-iron-catalysed reaction with phosphatidylethanolamine and phosphatidylserine contained in the membrane.     

A Short-lived Intermediate Form in the in Vivo Conversion of Protochlorophyllide 650 to Chlorophyllide 684

When dark-grown leaves of Phaseolus vulgaris, Hordeum vulgare, Zea mays and Pisum sativum were irradiated for 3 sec at 2° the first product of protochlorophyllide 650 conversion had an absorption maximum at 678 nm. This form was then converted in a dark reaction to chlorophyllide 684, the form generally observed and regarded as the in vivo product of the photoreaction. The dark conversion at 2° was complete in 6 to 10 min in the various plants. The time course of the dark reaction was followed at 690 nm near the maximum of the difference spectrum for the conversion. There was a constant relationship between the initial amount of chlorophyllide 678 and the final amount of chlorophyllide 684. The rates of the dark reaction at 2° varied 3-fold among the plants treated. The reaction was not first order. At 25° the reaction followed at 690 nm was complete in 20 to 60 sec. Q₁₀'s varied from 2.8 to 3.7 between 2° and 25°. Phytochrome absorbancy changes were shown to be too low to interfere with these measurements except in pea leaves. In a subsequent stage of greening newly regenerated protochlorophyllide went through the same sequence upon photoconversion. Chlorophyllide 678 probably corresponds to the product formed in vitro from the protochlorophyllide holochrome. The dark reaction appears to represent the first interaction between the photoconverted holochrome and other elements of the proplastid. The lack of this dark reaction could also account for the spectral properties of certain albino mutants.     

The oxidation product of molybdenum cofactor from milk xanthine oxidase

In extracts of acid treated molybdenum cofactor containing xanthine oxidase, fluorescence is maximally developed upon a three hours incubation. Analysis by means of reversed phase HPLC revealed the presence of several fluorescent compounds, the main one being a blue fluorescent compound with an emission maximum of 465 nm when maximal excited at 395 nm at a neutral pH. Definite proof is presented that this compound is the oxidation product of the molybdenum cofactor. The remaining fluorescent products are shown to be pterin-derivatives, yielding predominantly pterin-6-carboxylic acid upon permanganate oxidation. Purified oxidation product of molybdenum cofactor however, didn's yield a fluorescent derivative at all upon treatment with permanganate.     

Vector Alkaline Phosphatase Substrate Blue III: One Substrate for Brightfield Histochemistry and High-resolution Fluorescence Imaging by Confocal Laser Scanning Microscopy

A number of histochemical chromogenic substrates for alkaline phosphatase are commercially available and give reaction products with a range of colours for brightfield examination. Some of these reaction products are also fluorescent, exhibiting a wide excitation range and a broad emission peak. We report here that one of these substrates, Vector Blue III, yields a stable, strongly fluorescent reaction product with an excitation peak around 500 nm and a large Stokes shift to an emission peak at 680 nm. The reaction product can be excited using a mercury lamp with a fluorescein excitation filter or an argon ion laser at 488 nm or 568 nm, and the emission detected using a long-pass filter designed for Cy-5. Thus, a single substrate is suitable for brightfield imaging of tissue sections and high-resolution analysis of subcellular detail, using a confocal laser scanning microscope, in the same specimen.     

Prostaglandin H synthetase as a multisubstrate enzyme. Fluorimetric study of enzyme kinetics

The kinetics of a multisubstrate enzymatic reaction catalyzed by prostaglandin H synthase (PGH-synthase, EC 1.14.99.1) was studied, using homovanillic acid, a new electron donor for the given system. Homovanillic acid was shown to be a participant in a reaction with arachidonic acid/O2 stoichiometric ratios and is oxidized to a readily fluorescing product with an absorbance maximum (excitation) at 315 nm and fluorescence maximum at 425 nm. This allows for determination of the rate of enzymatic reaction with the sensitivity exceeding by one order of magnitude that of polarographic or spectrophotometric assays. Using fluorescent techniques, the dependence of the rate of PGH-synthase reaction on substrate (arachidonic acid, O2 and homovanillic acid) concentrations was studied, and the corresponding Km values were determined. The effect of Tween-20 and Lubrol PX concentrations on the reaction rate were examined. It was shown that with a decrease in the surfactant concentration the reaction rate increases.     

Development and validation of a spectrofluorimetric method for the quantification of ceftriaxone in pharmaceutical formulations and plasma

We describe the development and validation of a new, simple, sensitive and cost‐effective method for the determination of ceftriaxone in commercial formulations and spiked human plasma. The method proposes the conversion of ceftriaxone into a fluorescent product by reacting with ortho‐phthalaldehyde (OPA) in the presence of sulfite at room temperature. The reaction medium is buffered to pH 10 using borate buffer. The derivatized reaction product is highly fluorescent and exhibits maximum fluorescence intensity at λ_em = 386 nm after excitation at λ_ex = 324 nm. The experimental parameters affecting progress of the derivatization reaction were carefully studied and optimized. Under optimum experimental conditions, the method has an excellent correlation coefficient of 0.9984 with a broad linear range of 0.4?20 µg/mL. The limit of detection (LOD) and limit of quantification (LOQ) were found to be 1.30 × 10^?3 and 3.90 × 10^?3 µg/mL, respectively. The interference effects of common excipients on the quantification of drug were investigated and no interference effect was observed. The proposed method has been successfully applied to the determination of ceftriaxone in pharmaceutical formulations and spiked human plasma samples. The method has been validated statistically through percent recovery studies using standard addition and by comparison with a reference HPLC method. The developed method exhibits excellent inter‐ and intraday precision. Copyright © 2013 John Wiley & Sons, Ltd.     

High-performance liquid chromatography and sensitive detection of amino acids derivatized with 7-fluoro-4-nitrobenzo-2-oxa-1,3-diazole

7-Fluoro-4-nitrobenzo-2-oxa-1,3-diazole is used as a precolumn fluorescent labeling reagent for high-performance liquid chromatography of amino acids, including proline and hydroxyproline. The reaction is run at pH 8.0 at 60°C for 5 min. The fluorophors (Asp, Glu, Hyp, Ser, Gly, Thr, Ala, Pro) are separated on a reversed-phase column (μBondapak C₁₈) with 0.1 m phosphate buffer (pH 6.0) containing 6.75% methanol and 1.8% tetrahydrofuran, and are detected at the level of 10 fmol with excitation at 470 nm and emission at 530 nm.     

Continuous ATP Regeneration Using Immobilized Yeast Cells

Arthrobacter simplex was screened as an α-keto-δ-guanidinovalerate (ketoarginine) assimilating organism. A characteristic feature was its growth on ketoarginine as a carbon source; it began to grow after an extremely long lag. Its growth was stimulated by addition of 0.02% yeast extract to the medium.

The results indicated the transamination of arginine-α-ketoglutarate (α-KGA) and the hydrolyzing reaction of ketoarginine into α-keto-δ-aminovalerate and urea. Two intermediates, ketoarginine and α-keto-δ-aminovalerate, were isolated and identified by various procedures. Coupling of the two reactions was demonstrated in cell-free extracts of arginine-grown cells; ketoarginine formed from arginine by transamination with α-KGA was hydrolyzed directly to α-keto-δ-aminovalerate and urea. The metabolic routes of arginine in microorganisms were discussed.     

Fermentation of isoleucine and arginine by pure and syntrophic cultures of Clostridium sporogenes

Abstract The fermentation of isoleucine, arginine and isoleucine + arginine by pure and syntrophic cultures of Clostridium sporogenes was investigated. Growth of C. sporogenes on isoleucine, if any, was poor, but some isoleucine was fermented to 2-methylbutyrate and hydrogen. In syntrophic cultures with Methanobacterium formicicum or Methanosarcina barkeri growth was better, and isoleucine was completely fermented, the hydrogen being used for methane production. Pure cultures of C. sporogenes grew on arginine and produced 5-aminovalerate, ornithine and acetate. The reducing equivalents for 5-aminovalerate production from intermediarily formed proline were provided by oxidative conversion of arginine to acetate and by oxidative metabolism of some amino acids present in the yeast extract. However, when isoleucine was available together with arginine in syntrophic cultures of C. sporogenes and M. formicicum , the reducing equivalents for arginine fermentation came mainly from the oxidation of isoleucine (Stickland reaction), and the hydrogen produced in excess served for the reduction of CO₂ to methane.     

Δ1-Pyrroline-5-carboxylate: The product of proline dehydrogenase from Cucurbita moschata cotyledons

The product of oxidation of proline by pumpkin proline dehydrogenase reacted with o-aminobenzaldehyde to give a yellow compound that had an absorption spectrum similar to that obtained from chemically synthesized Δ¹-pyrroline-5-carboxylate. The product of the proline dehydrogenase reaction and synthetic Δ¹-pyrroline-5-carboxylate had identical R_f values. Both authentic Δ¹-pyrroline-5-carboxylate and the product of the enzyme gave a pink colour with acid ninhydrin on paper chromatograms and both had identical elution patterns on Dowex 50(H⁺) columns. Neither synthetic Δ¹-pyrroline-5-carboxylate nor the product of proline-dehydrogenase produced γ-amino butyrate with hydrogen peroxide.     

Novel validated spectrofluorimetric methods for the determination of taurine in energy drinks and human urine

Two sensitive, selective, economic and validated spectrofluorimetric methods were developed for the determination of taurine in energy drinks and spiked human urine. Method Ι is based on fluorimetric determination of the amino acid through its reaction with Hantzsch reagent to form a highly fluorescent product measured at 490 nm after excitation at 419 nm. Method ΙΙ is based on the reaction of taurine with tetracyanoethylene yielding a fluorescent charge transfer complex, which was measured at λ_ex/_em of (360 nm/450 nm). The proposed methods were subjected to detailed validation procedures, and were statistically compared with the reference method, where the results obtained were in good agreement. Method Ι was further applied to determine taurine in energy drinks and spiked human urine giving promising results. Moreover, the stoichiometry of the reactions was studied, and reaction mechanisms were postulated. Copyright © 2014 John Wiley & Sons, Ltd.     

Further observations on the chemistry of pararosaniline-Feulgen staining.

Pararosaniline-Feulgen staining of cells in suspension produces nucleus- and chromatin-specific fluorescence as well as color. Experiments were designed to test postulated reaction mechanisms responsible for the fluorescent staining with the nonfluorescent pararosaniline. The reduction in fluorescent-staining intensity by pretreatment of cells with 2.2 x 10-2M K2S2O5 tends to rule out the alkysulfonic acid pathway; conditions favoring the formation of this intermediate reduce staining intensity. The fluorescence enhancement, observed when cells stained in pararosaniline without K2S2O5 are post-treated with K2S2O5, suggests that there is an initial Schiff-base linkage between pararosaniline and an aldehyde of hydrolyzed DNA, and that this linkage is stabilized in the presence of K2S2O5. Microspectrofluorometer measurements of cells stained at various pararosaniline concentrations in 2.2x10-2M K2S2O5, show that the fluorescence emission maximum ranges from about 627 nm at 3.1x10-3 M pararosaniline to about 604 nm at 3.1x10-5M. All of the employed staining protocols appear to produce the same fluorescent product, perhaps a heterocyclic pyronin analog formed from pararosaniline. Flow microfluorometric analysis of cells stained in suspension verified that the relative fluorescence intensity represents relative DNA content. Staining at reduced pararosaniline concentration (3.1x10-4M) reduces the coefficient of variation of the flow microfluorometric histograms, showing that maximum quantitation does not necessarily correlate with maximum staining intensity.