Cationic cyanine as a near-infrared fluorescent probe for the determination of nucleic acids

A new method with a cationic near-IR cyanine as fluorescent probe was developed for the determination of nucleic acids. The near-IR cyanine shows maximum excitation and emission wavelengths at 765 and 790 nm, respectively, in aqueous solution. The method is based on the fluorescence decrease of near-IR cyanine in the presence of nucleic acids. Under optimal conditions, the ratio of fluorescence intensity in the absence and presence of nucleic acids was proportional to the concentration of ¶nucleic acids over the range 0.10–1.2 μg/mL for CT (calf thymus) DNA or SM (salmon sperm) DNA, and 0.10–¶1.6 μg/mL for yeast RNA. The detection limits were ¶30 ng/mL for CT DNA, 25 ng/mL for SM DNA and ¶70 ng/mL for yeast RNA. The relative standard deviation (n = 6) was 2.1% for 500 ng/mL CT DNA, 2.4% for ¶500 ng/mL SM DNA and 2.7% for 500 ng/mL yeast RNA, respectively.     

Application of magdala red as a fluorescence probe in the determination of nucleic acids

A fluorescence quenching method was developed for the rapid determination of DNA and RNA using magdala red as fluorescence probe. In weakly acidic ¶medium, the fluorescence of magdala red (λex>lem = 54055 nm) can be largely quenched by DNA or RNA. The calibration graphs are linear over the range 0.01–¶1.2 μg/mL for both calf thymus DNA (CT DNA) and salmon DNA (SM DNA), and 0.015–1.0 μg/mL for yeast RNA, respectively. The corresponding detection limits are ¶6.0 ng/mL for CT DNA, 7.0 ng/mL for SM DNA and ¶15.0 ng/mL for yeast RNA, respectively. CT DNA could be determined in the presence of 20% (w/w) yeast RNA, and the relative standard deviation of six replicate measurements is 3.18% for 400 ng/mL of CT DNA. Interference from coexisting substances in the determination of DNA was also examined. Real samples were determined with satisfactory results.     

Brilliant cresyl blue as a new red region fluorescent probe for determination of nucleic acids

A fluorescence quenching method was developed for determination of microamounts of nucleic acids by using brilliant cresyl blue (BCB) as a new red region fluorescent probe. In aqueous hexylmethylene tetramine solution, BCB showed maximum excitation and emission wavelengths at 626 and 670 nm, respectively, and the fluorescence of BCB could be greatly quenched by DNA (or RNA). Under optimal conditions, the calibration graphs are linear over the range of 0.02–0.80 μg/ml for SM DNA and 0.25–1.5 μg/ml for yeast RNA. The corresponding detection limits are 7 ng/ml for SM DNA and 25 ng/ml for yeast RNA, respectively. SM DNA can be determinated in the presence of 40% (w/w) RNA, and the relative standard deviation of six measurements is 2.5% for 500 ng/ml SM DNA. The result of the determination of golden staphylococcus DNA by this method was satisfactory.     

Cationic cyanine as a near-infrared fluorescent probe for the determination of nucleic acids

A new method with a cationic near-IR cyanine as fluorescent probe was developed for the determination of nucleic acids. The near-IR cyanine shows maximum excitation and emission wavelengths at 765 and 790 nm, respectively, in aqueous solution. The method is based on the fluorescence decrease of near-IR cyanine in the presence of nucleic acids. Under optimal conditions, the ratio of fluorescence intensity in the absence and presence of nucleic acids was proportional to the concentration of nucleic acids over the range 0.10-1.2 microg/mL for CT (calf thymus) DNA or SM (salmon sperm) DNA, and 0.10-1.6 microg/mL for yeast RNA. The detection limits were 30 ng/mL for CT DNA, 25 ng/mL for SM DNA and 70 ng/mL for yeast RNA. The relative standard deviation (n = 6) was 2.1% for 500 ng/mL CT DNA, 2.4% for 500 ng/mL SM DNA and 2.7% for 500 ng/mL yeast RNA, respectively.     

Fluorescent Complexes of Nucleic Acids/8-Hydroxyquinoline/Lanthanum(III) and the Fluorometry of Nucleic Acids

Abstract

The ternary fluorescent complexes of nucleic acids/8-hydroxyquinoline/ lanthanum (III) were studied. Nucleic acids in the study involve natured and thermally denatured calf thymus DNA, fish sperm DNA and yeast RNA. In the range of pH 8.0–8.4 (controlled by NH₃-NH₄Cl buffer) ternary fluorescent complexes are formed which emit at 485.0 nm for calf thymus DNA and at 480.0 nm for yeast RNA (when excited at 267.0 nm) and emits at 483.0 nm for fish sperm DNA when excited at 265.0 nm. Based on the fluorescence reactions sensitive fluorometric methods for nucleic acids were proposed. Using optimal conditions, the calibration curves were linear in the range of 0.4–3.6 μg˙ml^?1 for calf thymus DNA, 0.4–4.0 μg-ml^?1 for fish sperm DNA and 0.4–4.0 μg˙ml^?1 for yeast RNA, respectively. The limits of determination (3σ) were 0.076 μg˙ml^?1 for calf thymus DNA, 0.068 μg˙ml^?1 for fish sperm DNA and 0.329 μg˙ml^?1 for yeast RNA, respectively. Five synthetic samples were determined with satisfaction.

     

Highly Sensitive Spectrofluorometric Determination of Nucleic Acid Based on the Aggregation of two Oppositely Charged Kinds of Water-Soluble Porphyrins

Abstract

When cationic 5, 10, 15, 20-tetrakis(4-N-trimethylaminophenyl)porphine (TTMAPP) and anionic 5, 10, 15, 20-tetrakis(4-sulfophenyl)porphine (TSPP) were mixed in aqueous solution, these compounds were rapidly aggregated due mainly to their electrostatic interaction. The fluorescences of both porphyrins were quenched. However, if small amounts of a bulky molecule such as a polymer electrolyte coexisted in this reaction system, the aggregation of TTMAPP and TSPP was inhibited and their fluorescences reappeared. Based on these findings, a new highly sensitive spectrofluorometric determination of nucleic acids (DNA, RNA) was developed. Each calibration curve was linear in the concentration range of 0.03–0.4 μg/ml (DNA) and 0–05–0.6 μg/ml (RNA). Further, the detection limit (S/N = 3) was 0.016 μg/ml for DNA and for RNA, 0.020 μg/ml. The relative standard deviations were DNA: 1.70% and RNA: 1.83% (5 determinations). When the proposed method was applied to the determination of DNA originating from a bacteriophage, the results were satisfactory.     

Interactions of Nile Blue Sulphate with Nucleic Acids as Studied by Resonance Light-Scattering Measurements and Determination of Nucleic Acids at Nanogram Levels

ABSTRACT

The interactions of nile blue sulphate (NBS) with nucleic acids, including calf thymus DNA, fish sperm DNA and yeast RNA, were characterized with resonance light-scattering (RLS) measurements by using a common spectrofluorometer. Accordingly a method for the determination of nucleic acids at nanogram levels was established. At pH's of 7.20～7.60 and ionic strengths lower than 0.012, the interactions of NBS with nucleic acids result in three characteristic RLS peaks at 293.4 nm, 349.4 nm and 560.4 nm. Mechanism study shows that these peaks are ascribed to the long range assembly of NBS on the molecular surface of nucleic acids, which depends on pH, ionic strength and the stranded structure of nucleic acids. A Scatchard plot was constructed by using the RLS data, yielding the assembly number and assembly constant being 6.4 and 7.13x10⁶ mol^?1 1 for NBS assembly on the molecular surface of calf thymus DNA. The same parameters are 6.6 and 4.58x10⁶ mol^?1 1 for the assembly on that of fish sperm DNA, 3.9 and 1.67x10⁶ mol^?1 1 on that of yeast RNA, respectively. Linear relationships were found between the enhanced RLS intensity at 293.4 nm and nucleic acid concentration. If 1.2x10^?5 mol I^?1 NBS was employed, 0～0.80 μg ml^?1 calf thymus DNA and fish sperm DNA, 0.20～0.60 μg ml^?1 yeast RNA can be determined with the determination limits being 3.2 ng ml^?1 for calf thymus DNA, 11.5 ng ml^?1 for fish sperm DNA and 38.3 ng ml^?1 for yeast RNA, respectively. Four synthetic samples were determined with satisfaction.     

Interaction of morin-cetyltrimethylammonium bromide with nucleic acids and determination of nucleic acids at nanograms per milliliter levels based on the enhancement of preresonance light scattering

A new preresonance light scattering (PRLS) assay of nucleic acids is presented. At pH 7.30, the weak PRLS of morin-cetyltrimethylammonium bromide (CTMAB) can be greatly enhanced by the addition of nucleic acids, owing to the interaction between the nucleic acid and morin-CTMAB. After the addition of morin and CTMAB to DNA, the zeta potential of DNA decreases and changes from negative to positive, which is due to the formation of an associate, the aggregation of morin on nucleic acids and the electric neutralization between DNA and the cationic surfactant CTMAB. Mechanism studies showed that the enhanced PRLS comes from the aggregation of morin in the presence of nucleic acids and CTMAB. The enhanced intensity of PRLS is in proportion to the concentration of nucleic acids in the range 7.5 x 10(-9)-1.0 x 10(-5) g ml(-1) for calf thymus DNA, 7.5 x 10(-9)-1.0 x 10(-6) g ml(-1) for salmon sperm DNA and 1.0 x 10(-8)-1.0 x 10(-6) g ml(-1) for yeast RNA. The detection limits are 3.4, 6.2 and 4.1 ng ml(-1) for calf thymus DNA, salmon sperm DNA and yeast RNA, respectively. Synthetic samples were analyzed satisfactorily.     

Determination of nucleic acids in acidic medium by enhanced light scattering of large particles

The large particle light scattering technique was first developed as a sensitive and convenient analysis method for microdetermination of nucleic acids by using a common spectrofluorometer. In 0.1 mol l(-1) HCl, H(2)SO(4), or HNO(3) solution, the nucleic acids can aggregate to form large particles whose dimensions are comparable to the wavelength of UV-Vis light. The large particles can result in very strong light scattering which is well proportional to the concentration of nucleic acids in the range of 0.06-100.0 mug ml(-1) for calf thymus DNA, 0.05-60.0 mug ml(-1) for fish sperm DNA, and 0.6-90.0 mug ml(-1) for yeast RNA. The detection limits (3sigma) are 18.0 ng ml(-1) for calf thymus DNA, 16.0 ng ml(-1) for fish sperm DNA, and 57.6 ng ml(-1) for yeast RNA, respectively. Six synthetic samples were determined with satisfactory results.     

Resonance Rayleigh scattering study of the reaction of nucleic acids with thionine and its analytical application

Resonance Rayleigh scattering (RRS) of the thionine (TH)-nucleic acids system and its analytical application have been studied. In pH 2.2 acidic buffer medium, some nucleic acids can react with TH to form TH-nucleic acids complex. This results in a great enhancement of RRS and the appearance of new RRS spectra. The RRS spectral characteristics of TH-ctDNA system, the affecting factors and the optimum conditions of the reaction have been investigated. The enhancement of the RRS signal is directly proportional to the concentration of nucleic acids in the range 0-10.0 microg/ml for calf thymus DNA and 0-15.0 microg/ml for yeast RNA, and its detection limits (3sigma) are 3.5 ng/ml for calf thymus DNA and 4.9 ng/ml for yeast RNA, respectively. The method shows a wide linear range and high sensitivity, and was applied to the determination of trace amounts of nucleic acid in synthetic samples and practical samples with satisfactory results. The bind properties for the interactions of TH with ctDNA were investigated using a Scatchard plot based on the measurement of the enhanced RRS data at 340 nm, and the binding number and intrinsic binding constant are 4.9 and 2.6 x 10(5) mol/dm(3), respectively.     

Application of magdala red as a fluorescence probe in the determination of nucleic acids

A fluorescence quenching method was developed for the rapid determination of DNA and RNA using magdala red as fluorescence probe. In weakly acidic medium, the fluorescence of magdala red (lambdaex/lambdaem = 540/555 nm) can be largely quenched by DNA or RNA. The calibration graphs are linear over the range 0.01-1.2 microg/mL for both calf thymus DNA (CT DNA) and salmon DNA (SM DNA), and 0.015-1.0 microg/mL for yeast RNA, respectively. The corresponding detection limits are 6.0 ng/mL for CT DNA, 7.0 ng/mL for SM DNA and 15.0 ng/mL for yeast RNA, respectively. CT DNA could be determined in the presence of 20% (w/w) yeast RNA, and the relative standard deviation of six replicate measurements is 3.18% for 400 ng/mL of CT DNA. Interference from coexisting substances in the determination of DNA was also examined. Real samples were determined with satisfactory results.     

Determination of nucleic acids using calcein-neodymium complex as a fluorescence probe.

A novel fluorometric method has been developed for rapid determination of DNA and RNA with calcein-neodymium complex as a fluorescence probe. The method is based on the fluorescence enhancement of calcein-Nd(III) complex in the presence of DNA or RNA, with maximum excitation and emission wavelength at 489 nm and 514 nm, respectively. Under optimal conditions, the calibration graphs are linear over the range 0.5 - 3.0 microg/ml for both DNA and yeast RNA, 0.4 - 2.0 microg/ml for fish sperm DNA (FS DNA) and 0 - 3.0 microg/ml for calf thymus DNA (CT DNA). The corresponding detection limits are 15.1 ng/ml for DNA, 21.2 ng/ml for yeast RNA, 10.5 ng/ml for FS DNA and 8.9 ng/ml for CT DNA. The interaction mechanism for the binding of calcein-Nd(III) complex to DNA is also studied. The results of absorption spectra, fluorescence polarization measurements and thermal denaturation experiments, suggested that the interaction between calcein-Nd(III) complex and DNA is an electrostatic interaction.     

基于酶催化反应的核酸定量新方法

近年来 ,将染料自缔合或诱导缔合用于核酸定量测定备受关注 [1～ 3 ] .但是将酶与染料的缔合用于核酸定量测定尚未见报道 .氯化血红素 (hemin)可作为辣根过氧化物酶 (HRP)的模拟酶 ,能催化 H2 O2氧化对 -羟基苯乙酸 (p- HPA)生成荧光产物——联二对 -羟基苯乙酸的反应 [4 ,5] .由于 hemin在碱性介质中是阴离子化合物 ,能与阳离子化合物如阿尔新蓝 (Alcian Blue 8GX)发生缔合作用 ,从而使自身的催化性质被抑制 .当加入带负电荷的脱氧核糖核酸 (DNA)时 ,由于阿尔新蓝与 DNA的强烈作用使hemin与阿尔新蓝的缔合物被破坏 ,hemin的催化活…     

Study on the resonance light scattering spectrum of berberine-cetyltrimethylammonium bromide system and the determination of nucleic acids at nanogram levels

The interaction of berberine with nucleic acid in the presence of cetyltrimethylammonium bromide (CTMAB) in aqueous solution has been studied by spectrophotometry and resonance light scattering (RLS) spectroscopy. At pH 7.30, the RLS signals of berberine were greatly enhanced by nucleic acid in the region of 300-600 nm characterized by four peaks at 324.0, 386.5, 416.5 and 465.0 nm. The binding properties were examined by using a Scatchard plot based on the measurement of enhanced RLS data at 416.5 nm. Under optimum conditions, the increase of RLS intensity of this system at 416.5 nm is proportional to the concentration of nucleic acid. The linear range is 7.5 x 10(-9)-7.5 x 10(-5) g ml(-1) for calf thymus DNA, 7.5 x 10(-9)-2.5 x 10(-5) g ml(-1) for herring sperm DNA, and 5.0 x 10(-9)-2.5 x 10(-5) g ml(-1) for yeast RNA. The detection limits (S/N = 3) are 2.1 ng ml(-1) for calf thymus DNA, 6.5 ng ml(-1) for herring sperm DNA and 3.5 ng ml(-1) for yeast RNA, respectively. Three synthetic samples were analyzed satisfactorily.     

Spectrophotometric Studies on the Proton Transfer from the Protonated DNA to 5,10,15,20-Tetrakis[4-(trimethyammonio)-phenyl]porphine

Abstract

The interaction of nucleic acids with 5, 10, 15, 20-tetrakis[4-trimethy-ammonio)phenyl]porpine (TAPP) were investigated on the basis of a mechanistic discussion, and a spectrophotometric method for DNAs was accordingly proposed in the present paper. Depending on the acidity of the solution, TAPP can interact with nucleic acids, producing different absorption features. When the pH of the solution is higher than 6.39, TAPP can interact with both DNAs and RNA, giving a new absorption band at 420.3 nm. If the pH is lower than 6.39, however, the interactions with DNAs (but not RNA) can give an absorption band centered at 436.3 nm. It was found that the absorption band at 436.3 nm originates from the proton transfer from the protonated double-stranded structure of DNA to TAPP. At optimal conditions, the absorbance at 436.3 nm is in proportion to the concentration of the DNAs. Calibration curves were linear in the range of 0±3.0 μg.ml^?1 for calf thymus and 0±3.2 μg.ml^?1 for fish sperm DNA. No interference of 4-fold of RNA was found for the determination of DNAs. The limits of determination (3[sgrave]) were 34.6 ng.ml^?1 for calf thymus DNA and 33.2 ng.ml^?1 for fish sperm DNA, respectively. Four synthetic samples were determined with satisfaction.     

Determination of nucleic acids with crystal violet by a resonance light-scattering technique

For the first time, Crystal Violet (CV) was used to determine nucleic acid concentrations using the resonance light-scattering (RLS) technique. Based on the enhancement of the RLS of CV by nucleic acids, a new quantitative determination method for nucleic acids in aqueous solutions has been developed. At pH 5.03 and ionic strength 0.005 mol kg-1, the interaction of CV with nucleic acids results in three characteristic RLS peaks at 344.0, 483.0 and 666.0 nm. With 4.0 x 10(-5) mol l-1 of CV, linear relationships were found between the enhanced intensity of RLS at 666.0 nm and the concentration of nucleic acids in the range 0-2.5 micrograms ml-1 for herring sperm DNA, 0-4.0 micrograms ml-1 for calf thymus DNA and 0-4.5 micrograms ml-1 for yeast RNA. The limits of determination were 13.8 ng ml-1 for herring sperm DNA, 36.8 ng ml-1 for calf thymus DNA and 69.0 ng ml-1 for yeast RNA. The assay is convenient, rapid, inexpensive and simple.     

用四氨基铝酞菁共振光散射技术测定纳克级核酸

痕量核酸对四氨基铝酞菁的共振散射光产生增强作用,且增强程度与核酸浓度之间有良好的线性关系.据此建立了测定核酸的高灵敏共振散射光增强分析方法.在pH=6.0、最大散射波长400nm处,测定小牛胸腺DNA(CTDNA)、鲑鱼精子DNA(SMDNA)和酵母RNA(YeastRNA)的线性范围分别是0～250ng/mL,0～200ng/mL和0～400ng/mL,检测限分别为1.4ng/mL,1.4ng/mL和2.7ng/mL.该法简单,灵敏度高,用于实际样品中核酸含量的测定,所得结果与紫外吸收法一致.     

Determination for micro amounts of nucleic acids by a resonance light scattering technique with dequalinium chloride

Based on the strong enhancement effect of nucleic acids on resonance light scattering of dequalinium chloride, the determination method for micro amounts of nucleic acids has been developed. Under the experimental conditions (5.0x10(-5) mol l(-1) dequalinium, pH 7.0, at room temperature) the linear range of this assay is 0.04-10.0 mug ml(-1) for calf thymus DNA and fish sperm DNA, and 0.04-35.0 mug ml(-1) for yeast RNA. The detection limits (3sigma) are 6.2 ng ml(-1) for calf thymus DNA, 7.4 ng ml(-1) for fish sperm DNA, and 7.0 ng ml(-1) for yeast RNA, respectively. Almost no interference can be observed from ionic strength, proteins, nucleoside, and most of the metal ions. Six synthetic samples were determined satisfactorily.     

Determination of nucleic acids with a near infrared cyanine dye using resonance light scattering technique

A new method for the determination of nucleic acids has been developed based on the enhancement effect of resonance light scattering (RLS) with a cationic near infrared (NIR) cyanine dye. Under the optimal conditions, the enhanced RLS intensity at 823 nm is proportional to the concentration of nucleic acids in the range of 0-400 ng mL-1 for both calf thymus DNA (CT DNA) and fish sperm DNA (FS DNA), 0-600 ng mL-1 for snake ovum RNA (SO RNA). The detection limits are 3.5 ng mL-1, 3.4 ng mL-1 and 2.9 ng mL-1 for CT DNA, FS DNA and SO RNA, respectively. Owing to performing in near infrared region, this method not only has high sensitivity endowed by RLS technique but also avoids possible spectral interference from background. It has been applied to the determination of nucleic acids in synthetic and real samples and satisfactory results were obtained.     

中性红荧光探针法测定生物大分子核酸

中性红 (NR)是一种吩嗪染料 ,至今已有许多关于 NR与 DNA相互作用的报道[1～ 5] .李克安[4 ] 和黄承志等 [5]利用共振光散射技术分别在酸性 (p H=2 .3 )和中性 (p H=7.6～ 7.8)条件下 ,建立了以 NR为探针测定痕量 DNA的方法 .我们 [2 ,3]曾利用荧光光谱方法研究了在 p H=7.4条件下 NR与 DNA之间的相互作用 ,发现利用吖啶橙和 NR之间的能量转移现象可以测定 DNA,但检出限偏高 ,且由于使用两种染料试剂 ,操作较繁琐 .为了克服吖啶橙、NR能量转移分析法的不足 ,本文建立了在 p H=4.5的条件下以单一染料 NR为荧光探针测定痕量核酸的…