镧系元素标记核酸探针技术

镧系元素标记核酸探针技术是利用某些镧系元素及其螯合物作为标记物,通过多种标记方法合成镧系元素核酸探针,用时间分辨荧光测定法进行检测,可以代替放射性核素标记探针进行各种检测和分析。该方法具有灵敏、快速、安全、简便、经济等特点。     

镧系离子螯合物荧光免疫分析：非同位素标记免疫分析的新一代替代技术

镧系离子螯合物荧光免疫分析：非同位素标记免疫分析的新一代替代技术廖锦民（中国科学院上海细胞生物学研究所２０００３１）本文简要阐述了镧系离子螯合物荧光标记法研究５０年来的发展演变过程,特别对８０年代ＤＥＬＦＩＡ新技术这一重大突破进行分析,说明了它是ＲＩ...     

时间分辨荧光免疫分析仪的临床实验方法和评价方案

时间分辨荧光免疫分析技术是一种利用稀土离子及其螯合物作为示踪剂的灵敏度高、线性范围宽、应用范围广的非放射性标记免疫分析技术。研制了一种性能稳定的时间分辨荧光免疫分析仪,为了进一步将这一先进超微量物质检验技术推广于临床应用,根据美国国家临床实验室标准化委员会（NCCLS）制订的临床评价方案,选择放射免疫分析法、化学发光免疫分析法以及Perkin Eimer Life Sciences公司的Auto DFLFIA-1235全自动时间分辨荧光免疫分析仪作为比较方法,提出了三套检验时间分辨荧光免疫分析仪性能的临床实验方法和评价方案。并利用其中的一套方案进行了实验,结果表明这些方案可操作性强,结果可信,经济适用,可作为同类医疗检验仪器进行临床实验的参考。     

人体鼻咽组织的时间分辨自体荧光光谱研究

实验研究了在397 nm半导体脉冲激光激发下,人体离体鼻咽正常和癌变组织在600 nm荧光发射波长处的时间分辨自体荧光光谱特性。利用双指数衰减方程对时间分辨自体荧光光谱进行拟合后,获得相应的荧光强度随时间的指数衰减方程以及荧光平均寿命。人体鼻咽癌变和正常组织在600 nm处的自体荧光平均寿命分别为(2.94±0.51)ns和(4.29±0.71)ns,两者之间存在显著的差异。应用时间分辨光谱技术的诊断灵敏度和特异性分别为75%和100%。初步表明了时间分辨自体荧光光谱在早期鼻咽癌诊断的应用价值,该方法可望与传统的稳态荧光光谱结合起来,进一步提高早期鼻咽癌荧光诊断的准确率。     

双链探针实时荧光PCR核酸检测新技术研究*

目的:采用一种“双链探针”实时荧光PCR技术,提高HBV核酸检测灵敏度,并在同一反应管中实现代谢酶CYP2C19^*2基因型检测。方法:采用双链探针与TaqMan探针同时检测不同浓度HBV血清样本,使用上海宏石SLAN 96实时荧光PCR仪进行核酸Ct值检测和结果统计分析;采用双链探针检测代谢酶CYP2C19^*2不同基因型样本,使用上海宏石SLAN 96实时荧光PCR仪进行核酸Ct值检测和基因型确定。结果:不同浓度HBV血清样本检测,双链探针荧光本底低,检测灵敏度更高,与TaqMan探针检测结果相比,两者核酸检测Ct值存在显著性差异(P<0.05);双链探针检测36份样本的代谢酶CYP2C19^*2基因型,检测结果与Sanger测序结果完全一致。结论:双链探针实时荧光PCR检测技术可完成目的基因的高灵敏核酸检测,也可实现基因型分析。     

时间分辨荧光免疫分析技术研究现状及进展

时间分辨荧光免疫分析是一种新型的超微量的免疫标记分析方法,集酶标记免疫分析和放射免疫分析等优点于一身,且无放射性污染等.本文主要介绍了时间分辨荧光免疫分析的原理、优点,螯合剂的种类,以及各种分析技术及其应用现状和进展.     

非调制式荧光仪PEA测定叶绿素荧光参数的研究

为了利用非调制式荧光仪获得调制式荧光仪测定的叶绿素荧光动力学参数,采用植物效率(PEA)仪进行了叶绿素荧光参数测定程式的4要素(光化光强度及其照射时间、饱和激发光强度及其照射时间)以及节约测定时间和仪器内存的测定技术研究。结果表明,暗适应10min后,在设定180μmol·m-2·s-1光化光照射360s时间内,以连续2次1950μmol·m-2·s-1饱和激发光照射3s的测定程式,在7种植物的叶绿素荧光参数的测定中获得了较为满意的测定结果,而且与Strasser等测定程式相比,1次测定需时从600s缩短为360s、耗用仪器内存从76.9"减少为2.56"。     

荧光光谱分析法在地沟油鉴别中的应用研究

由于地沟油的成分含量复杂性和不定量性,导致了现有的单一检测方法不能同时满足快速和准确的辨认。荧光光谱具有高灵敏度和分辨率的特性,由此提出了一种利用荧光光谱快速检测食用油中是否掺有地沟油的新方法。将花生油分成7组,每组油所含的地沟油的比例不同,用220 nm到800 nm的激发和发射光检测各组样品油,收集其荧光数据后做归一化处理进行分析。在荧光实验中,特别是在365 nm和720 nm激发波长波段和434 nm发射波长波段,样品油的荧光强度与所含地沟油的体积分数大小明显成反比,当地沟油的体积分数大于5%时,荧光强度的衰减更为明显。结果证明了荧光光谱法检测地沟油的可行性,而且步骤更为简单。利用荧光光谱的非接触和高灵敏度的优势,能够更为简便地检测到加入了5%以上地沟油的花生油。     

时间分辨荧光免疫分析及其在临床检测中的应用

本文介绍了时间分辨荧光免疫分析法的检测原理、检测方法,分析了时间分辨荧光免疫分析仪的结构并介绍了其在临床检测方面的应用。     

基于荧光蛋白的荧光共振能量转移探针的构建及应用

荧光共振能量转移(fluorescence resonance energy transfer,FRET)是基于荧光基团供体和荧光基团受体间偶极子–偶极子耦合作用的非辐射方式的能量传递现象。基于荧光蛋白的FRET技术已被广泛用于研究细胞信号通路中蛋白质–蛋白质活体相互作用检测、蛋白质构象变化监测以及生物探针的研制中。基于荧光蛋白的荧光共振能量转移探针使得人们可以在时间和空间层面上研究细胞信号的转导过程。该文简要介绍了四大类基于荧光蛋白的FRET生物探针的设计、研制以及其在生物信号分子检测、活细胞成像以及药物筛选中的应用和进展情况。     

Steady‐state and time‐resolved fluorescence of tetramethylrhodamine attached to DNA: correlation with DNA sequences

Time‐resolved fluorescence as well as steady‐state absorption and fluorescence were detected in order to study the interactions between tetramethylrhodamine (TAMRA) and DNA when TAMRA was covalently labeled on single‐ and double‐stranded oligonucleotides. Fluorescence intensity quenching and lifetime changes were characterized and correlated with different DNA sequences. The results demonstrated that the photoinduced electron transfer interaction between guanosine residues and TAMRA introduced a short lifetime fluorescence component when guanosine residues were at the TAMRA‐attached terminal of the DNA sequences. The discrepancy of two‐state and three‐state models in previous studies was due to the DNA sequence selection and sensitivity of techniques used to detect the short lifetime component. The results will help the design of fluorescence‐based experiments related to a dye labeled probe. Copyright © 2012 John Wiley & Sons, Ltd.     

Spectroscopic probe analysis for exploring probe-protein interaction: a mapping of native, unfolding and refolding of protein bovine serum albumin by extrinsic fluorescence probe

Steady state and dynamic fluorescence measurements have been used to investigate interaction between Bovine Serum Albumin (BSA) and fluorescence probe para-N,N-dimethylamino orthohydroxy benzaldehyde (PDOHBA), a structurally important molecule exhibiting excited state coupled proton transfer (PT) and charge transfer (CT) reaction. Fluorescence anisotropy, acrylamide quenching, and time resolved fluorescence measurements corroborate the binding nature of the probe with protein. The binding constant between BSA and PDOHBA has been determined by using Benesi-Hildebrand and Stern-Volmer equations. The negative value of ΔG indicates the spontaneity of this probe-protein complexation process. Observations from synchronous, three dimensional fluorescence spectra and circular dichroism spectra point toward the fact that the hydrophobicity as well as α-helix content of BSA are altered in presence of probe PDOHBA. The PT band of PDOHBA is found to be an excellent reporter for the mapping of destructive and protective behavior of SDS with variation of chaotrope concentration.     

Solvatochromic study of 3‐N‐(N′‐methylacetamidino)benzanthrone and its interaction with dopamine by the fluorescence quenching mechanism

The change in photophysical properties of the organic molecule due to solvatochromic effect caused by different solvent environments at room temperature gives information about the dipole moments of 3‐N‐(N′‐methylacetamidino)benzanthrone (3‐MAB). The quantum yield, fluorescence lifetime of 3‐MAB was measured in different solvents to calculate radiative and non‐radiative rate constants. The results revealed that the excited state dipole moment (μ_e) is relatively larger compared to the ground state dipole moment (μ_g), indicating the excited state of the dye under study is more polar than the ground state and the same trend is noticed with theoretical calculations performed using the CAM‐B3LYP/6‐311+G(d,p) method. Further, the study on preferential solvation was carried out for 3‐MAB dye in ethyl acetate–methanol solvent mixture. The fluorescence quenching method has been employed for the detection of dopamine using 3‐MAB as fluorescent probe, using steady‐state and time resolved methods at room temperature. The method enables dopamine in the micro molar range to be detected. Also, an attempt to verify the quenching process by employing different models has been tried. Various rate parameters are measured using these models, our results indicates the quenching process is diffusion limited.     

Resolution of initially excited and relaxed states of tryptophan fluorescence by differential-wavelength deconvolution of time-resolved fluorescence decays

We describe a new procedure for the analysis of time-resolved decays of fluorescence intensity. This procedure was used to resolve the emission spectra of the initially excited and solvent relaxed states of a tryptophan derivative in viscous solution. Specifically, we examined N-acetyl-l-tryptophanamide (AcTrpNH₂) in viscous and nonviscous solutions of propylene glycol. Time-resolved decays of fluorescence intensity were collected at wavelengths across the emission spectra. Instead of the usual procedure of deconvolving these data with the time profile of the exciting pulse, we deconvolved these data using the response observed on the short-wavelength side of the emission. If one assumes that this emission results only from the initially excited state (F), then the nonzero decay time calculated using deconvolution is that of the solvent relaxed state (R). For our specific case of AcTrpNH₂ the emission spectra of the F and R states overlap at most wavelengths longer than the short-wavelength side of the emission (310 nm). As a result, differential-wavelength deconvolution yields two lifetimes and amplitudes, one pair representing the relaxed state and the other the initially excited state. The latter appears as a zero-decay-time component whose amplitude can be readily quantified. The wavelength-dependent amplitude of this zero-lifetime component can be used to calculate the emission spectrum of the F state and. by difference, the emission spectrum of the relaxed state. For AcTrpNH₂ in propylene glycol at ?20°C the emission maxima of the F and R states are near 320 and 350 nm, respectively, and the relative proportion of the emission from each state was near 50%. At lower temperatures the emission from the F state becomes dominant and at high temperatures the emission from the R state dominates. We note that this resolution of states is somewhat arbitrary because we assumed a two-state model and the absence of solvent relaxed emission at 310 nm. Nonetheless, differential-wavelength deconvolution simplifies and facilitates the analysis of time-resolved fluorescence data from samples which undergo excited state reactions. Moreover, this deconvolution procedure considerably simplifies the determination of the kinetic constants for reversible excited state reactions. The application of differential-wavelength deconvolution does not increase the time reqaired for data acquisition. This differential analysis procedure should enhance the usefulness and precision of pulse fluorometric methods in studies of nanosecond time scale processes in proteins and membranes.     

Amperometric immunosensor for carcinoembryonic antigen detection with carbon nanotube-based film decorated with gold nanoclusters

In a recent article, we described the application of phasor analysis to fluorescence intensity decay data on in vitro samples. As detailed in that article, this method provides researchers with a simple graphical method for viewing lifetime data that can be used to quantify individual components of a mixture as well as to identify excited state reactions. In the current article, we extend the use of in vitro phasor analysis to intrinsic protein fluorescence. We show how alterations in the excited state properties of tryptophan residues are easily visualized using the phasor method. Specifically, we demonstrate that protein–ligand and protein–protein interactions can result in unique shifts in the location of phasor points, indicative of protein conformational changes. Application of the method to a rapid kinetic experiment is also shown. Finally, we show that the unfolding of lysozyme with either urea or guanidine hydrochloride results in different phasor trajectories, indicative of unique denaturation pathways.     

Fluorimetric studies on the binding of 4-(dimethylamino)cinnamic acid with micelles and bovine serum albumin

The constrained photophysics of intramolecular charge transfer (ICT) probe 4-(dimethylamino)cinnamic acid (DMACA) was studied in different surfactant systems as well as in presence of model water soluble protein bovine serum albumin (BSA). Binding of the probe in ionic micelles like sodium dodecyl sulfate (SDS) and cetyl trimethyl ammonium bromide (CTAB) causes an increase in ICT fluorescence intensity, whereas, in non-ionic TritonX-100 (TX-100) the intensity decreases with a concomitant increase in emission from locally excited (LE) state. The observations were explained in terms of the different binding affinity, location of the probe and also the nature of specific hydrogen bonding interaction in the excited state nonradiative relaxation process of DMACA. The ICT fluorescence emission yield decreases in BSA due to the locking in of the probe buried in the hydrophobic pocket of the protein structure. SDS induced uncoiling of protein and massive cooperative binding between BSA and SDS is manifested by the release of probe molecules in relatively free aqueous environment.     

Use of synchronously excited fluorescence to assess the accumulation of membrane potential probes in yeast cells

Evaluation of emission spectra of fluorescent probes used for the monitoring of membrane potential in microbial cells can be greatly facilitated by using synchronously excited spectroscopy (SES). This method permits the suppression of undesirable spectrum components (contributions due to scattered light or cell autofluorescence) and leads to considerable increase in monitored emission intensity and to narrowing of spectral peaks. It allows an efficient fractional decomposition of the probe fluorescence spectra into their free and bound dye fluorescence components. The usefulness of the method was tested by monitoring the accumulation of the fluorescent membrane potential probe diS-C3(3) in yeast cells, which serves as a qualitative measure of the membrane potential.     

Fluorescence decay kinetics of chlorophyll in photosynthetic membranes

The absorption of light by the pigments of photosynthetic organisms results in electronic excitation that provides the energy to drive the energy-storing light reactions. A small fraction of this excitation gives rise to fluorescence emission, which serves as a sensitive probe of the energetics and kinetics of the excited states. The wavelength dependence of the excitation and emission spectra can be used to characterize the nature of the absorbing and fluorescing molecules and to monitor the process of sensitization of the excitation transfer from one pigment to another. This excitation transfer process can also be followed by the progressive depolarization of the emitted radiation. Using time-resolved fluorescence rise and decay kinetics, measurements of these processes can now be characterized to as short as a few picoseconds. Typically, excitation transfer among the antenna or light harvesting pigments occurs within 100 psec, whereupon the excitation has reached a photosynthetic reaction center capable of initiating electron transport. When this trap is functional and capable of charge separation, the fluorescence intensity is quenched and only rapidly decaying kinetic components resulting from the loss of excitation in transit in the antenna pigment bed are observed. When the reaction centers are blocked or saturated by high light intensities, the photochemical quenching is relieved, the fluorescence intensity rises severalfold, and an additional slower decay component appears and eventually dominates the decay kinetics. This slower (1-2 nsec) decay results from initial charge separation followed by recombination in the blocked reaction centers and repopulation of the excited electronic state, leading to a rapid delayed fluorescence component that is the origin of variable fluorescence. Recent growth in the literature in this area is reviewed here, with an emphasis on new information obtained on excitation transfer, trapping, and communication between different portions of the photosynthetic membranes.     

Fluorescence studies on concanavalin-A

Using the lectin-concanavalin-A, the tryptophan fluorescence as a function of pH was studied. The pH dependent, fluorescence intensity changes were significantly higher when excited at 305 nm, than when irradiated at 280nm. Only one tryptophanyl per monomer of concanavalin-A was available for oxidation by N-bromosuccinimide in the dimeric form at pH 4·9; no tryptophanyl could be oxidised in the demetallised dimer (pH 3·0) and native tetramer (pH 7·0). Based on this fluorescence data and the already known crystal structure data, it appears that tryptophanyl 88 in concanavalin-A may be selectively excited by 305 nm radiation     

A novel fluorescent probe for protein binding and folding studies: p-cyano-phenylalanine

Recently, it is has been shown that the C=N stretching vibration of a non-natural amino acid, p-cyano-phenylalanine (PheCN), could be used as an infrared reporter of local environment. Here, we further showed that the fluorescence emission of PheCN is also sensitive to solvent and, therefore, could be used as a novel optical probe for protein binding and folding studies. Moreover, we found that the fluorescence quantum yield of PheCN is nearly five times larger than that of phenylalanine and, more importantly, can be selectively excited even when other aromatic amino acids are present, thus making it a more versatile fluorophore. To test the feasibility of using PheCN as a practical fluorescent probe, we studied the binding of calmodulin (CaM) to a peptide derived from the CaM-binding domain of skeletal muscle myosin light chain kinase (MLCK). The peptide (MLCK3CN) contains a single PheCN residue and has been shown to bind to CaM with high affinity. As expected, addition of CaM into a MLCK3CN solution resulted in quenching of the PheCN fluorescence. A series of stochiometric titrations further allowed us to determine the binding affinity (Kd) of this peptide to CaM. Taken together, these results indicated that the PheCN fluorescence is sensitive to environment and could be applicable to a wide variety of biological problems.