竹红菌乙素对膜蛋白荧光猝灭研究

竹红菌乙素作为膜蛋白荧光猝灭剂,研究了乙素从水相进入膜体系过程中基本物理现象.包括了:膜与水分配系数(P);进入速度;以及膜与水相的体积比(α),并对其猝灭机理进行深入探讨.结果表明,乙素对膜蛋白质荧光的猝灭服从动态猝灭原理;用ESR技术直接观察到:激发态的色氨酸可以将电子转移给乙素并形成乙素自由基,因此用电子转移方程:K_et=K₀exp(-R)处理猝灭反应过程中的K_q值,可以方便地得到Trp-HB分子间距离(R)信息.     

荧光共振能量转移效率的实时定量测量

荧光共振能量转移（FRET）广泛用于研究分子间的距离及其相互作用,与荧光显微镜结合,可定量获取有关生物活体内蛋白质、脂类、DNA和RNA的时空信息。随着绿色荧光蛋白（GFP）的发展,FRET荧光显微镜有可能实时测量活体细胞内分子的动态性质。提出了一种定量测量FRET效率以及供体与受体间距离的简单方法,仅需使用一组滤光片和测量一个比值,利用供体和受体的发射谱肖除光谱间的串扰。该方法简单快速,可实时定量测量FRET的效率和供体与受体间的距离,尤其适用于基于GFP的供体－受体对。     

双分子荧光互补技术

双分子荧光互补（bimolecular fluorescence complementation, BiFC）是近年发展起来的用于体内或体外检测蛋白质相互作用的一项新技术.该技术是将荧光蛋白在合适的位点切开形成不发荧光的2个片段,这2个片段借助融合于其上的目标蛋白的相互作用,彼此靠近,重新形成能具有活性的荧光蛋白.BiFC方法简单直观,既可以检测蛋白之间的相互作用,也可以定位相互作用蛋白质的位点.多色BiFC系统共用或与荧光共振能量转移（FRET）技术联用,还可以检测细胞内多个蛋白质的相互作用.     

一种改进的荧光共振能量转移方法分析同质二聚体内蛋白质-蛋白质相互作用

荧光共振能量转移(fluorescence resonance energy transfer, FRET)技术日益广泛的应用于检测活细胞中分子内和分子间的相互作用. 由于FRET仅发生于相互作用的供体和受体,即供体-受体复合物之间,所以检测的FRET信号必须经标准化处理以去除供体受体比例和浓度的影响然后才能够进行FRET的比较研究. 由于供体和受体的比例相同,分子内FRET的检测较为简单;而分子间FRET的检测存在更多的不确定因素,导致现有的方法很难精确定量.根据1类特殊的分子间相互作用,同质二聚体的独特特征,推导出供体 受体复合物的含量,进而开发了1种同质二聚体分子间FRET的精确定量的方法,以1种同质二聚体,雌激素受体α(estrogen receptor alpha, ERα)为供体和受体对,通过和其它的方法比较,证实了该方法用于FRET检测可获得更可靠的结果.     

光谱法研究单硝酸异山梨酯与牛血清白蛋白的相互作用

为研究单硝酸异山梨酯(IM)与牛血清白蛋白(BSA)之间的相互作用,用紫外-可见光谱法和荧光光谱法在优化的实验条件下进行研究。结果表明:IM与BSA形成基态复合物从而猝灭BSA的内源性荧光,猝灭机理为静态猝灭。通过计算得出IM与BSA的结合常数Kb及结合为点数n。根据热力学参数确定了IM和BSA之间的作用力类型主要为静电引力。生成自由能变驻G为负值,表明IM与BSA的作用过程是一个自发过程。同步荧光光谱表明IM对BSA构象产生很微弱的影响,使BSA腔内疏水环境的极性减弱。同步荧光光谱显示两者的结合位点更接近于酪氨酸,两者的结合部位主要位于亚螺旋域ⅢA中。Hill系数nH1,表明IM有正协同作用。为后续硝酸脂类药物的研发和进一步探讨IM在生物体内与蛋白质的作用机制和生物学效应提供了理论依据。     

双分子荧光互补技术及其在蛋白质相互作用研究中的应用

双分子荧光互补(bimolecularfluorescencecomplementation,BiFC)分析技术,是由Hu等在2002年最先报道的一种直观、快速地判断目标蛋白在活细胞中的定位和相互作用的新技术.该技术巧妙地将荧光蛋白分子的两个互补片段分别与目标蛋白融合表达,如果荧光蛋白活性恢复则表明两目标蛋白发生了相互作用.其后发展出的多色荧光互补技术(multicolorBiFC),不仅能同时检测到多种蛋白质复合体的形成,还能够对不同蛋白质间产生相互作用的强弱进行比较.目前,该技术已用于转录因子,G蛋白βγ亚基的二聚体形式,不同蛋白质间产生相互作用强弱的比较以及蛋白质泛素化等方面的研究工作上.     

竹红菌乙素对菌紫质荧光的影响

用荧光光谱方法研究了竹红菌乙素与菌紫质的相互作用。通过竹红菌乙素对菌紫质吸收光谱,对菌紫质荧光猝死的浓度和温度的依赖性以及竹红菌乙素对明暗适应菌紫质的荧光猝灭等研究表明,竹红菌乙素是一种新型的荧光猝灭剂,它对菌紫质的荧光猝灭属于动态猝死过程。竹红菌乙素对明暗适应菌紫质荧光猝灭的差别,说明这种猝灭剂可用于生物膜体系的蛋白质构象变化的研究。     

基于GFP的FRET应用

绿色荧光蛋白（GFP）是一种活性荧光标记,已被用来研究基因表达、分子定位,蛋白质折叠和转运;荧光共振能量转移（FRET）是一种无损伤的光学检测方法,能检测到小于纳米的距离变化。将GFP的活性定位标记功能与FRET的高分辨率相结合。为活体研究生物分子的功能和命运开创了新的篇章。作者在介绍GFP和FRET原理的基础上,综述了基于GFP的FRET在蛋白酶活性,蛋白质间相互作用 构象改变研究中的应用。     

小波变换及滚球算法在单分子荧光能量共振转移图像分析中的应用

单分子荧光共振能量转移技术是通过检测单个分子内的荧光供体及受体间荧光能量转移的效率来研究分子构象的变化．要得到这些生物大分子的信息就需要对大量的单分子信号进行统计分析,人工分析这些信息,既费时费力又不具备客观性和可重复性,因此本文将小波变换及滚球算法应用到单分子荧光能量共振转移图像中对单分子信号进行统计分析．在保证准确检测到单分子信号的前提下,文章对滚球算法和小波变换算法处理图像后的线性进行了分析,结果表明,滚球算法和小波变换算法不但能够很好地去除单分子FRET图像的背景噪声,同时还能很好地保持单分子荧光信号的线性．最后本文还利用滚球算法处理单分子FRET图像及统计15 bp DNA的FRET效率的直方图,通过计算得到了15 bp DNA的FRET效率值．     

PAMP和脂双层相互作用的荧光光谱和付立叶变换红外光谱研究

本文用荧光光谱技术和付立叶变换红外光谱研究了ＰＡＭＰ和脂质体的相互作用。ＰＡＭＰ与带负电磷脂作用后,其内源性荧光光谱峰位兰移,其荧光强度更不易被碘离子猝灭,提示ＰＡＭＰ和脂作用后其发荧光的色氨酸可能由水相移至疏水相。我们用自旋标记磷脂的猝灭实验测量了ＰＡＭＰ的插膜深度。ＦＴＩＲ实验表明,ＰＡＭＰ和带负电磷脂双层作用后将诱导ＰＡＭＰ的结构改变。     

FRET microscopy in the living cell: different approaches, strengths and weaknesses

New imaging methodologies in quantitative fluorescence microscopy, such as F?rster resonance energy transfer (FRET), have been developed in the last few years and are beginning to be extensively applied to biological problems. FRET is employed for the detection and quantification of protein interactions, and of biochemical activities. Herein, we review the different methods to measure FRET in microscopy, and more importantly, their strengths and weaknesses. In our opinion, fluorescence lifetime imaging microscopy (FLIM) is advantageous for detecting inter-molecular interactions quantitatively, the intensity ratio approach representing a valid and straightforward option for detecting intra-molecular FRET. Promising approaches in single molecule techniques and data analysis for quantitative and fast spatio-temporal protein-protein interaction studies open new avenues for FRET in biological research.     

Quantitative time domain analysis of lifetime‐based Förster resonant energy transfer measurements with fluorescent proteins: Static random isotropic fluorophore orientation distributions

Förster resonant energy transfer (FRET) measurements are widely used to obtain information about molecular interactions and conformations through the dependence of FRET efficiency on the proximity of donor and acceptor fluorophores. Fluorescence lifetime measurements can provide quantitative analysis of FRET efficiency and interacting population fraction. Many FRET experiments exploit the highly specific labelling of genetically expressed fluorescent proteins, applicable in live cells and organisms. Unfortunately, the typical assumption of fast randomization of fluorophore orientations in the analysis of fluorescence lifetime‐based FRET readouts is not valid for fluorescent proteins due to their slow rotational mobility compared to their upper state lifetime. Here, previous analysis of effectively static isotropic distributions of fluorophore dipoles on FRET measurements is incorporated into new software for fitting donor emission decay profiles. Calculated FRET parameters, including molar population fractions, are compared for the analysis of simulated and experimental FRET data under the assumption of static and dynamic fluorophores and the intermediate regimes between fully dynamic and static fluorophores, and mixtures within FRET pairs, is explored. Finally, a method to correct the artefact resulting from fitting the emission from static FRET pairs with isotropic angular distributions to the (incorrect) typically assumed dynamic FRET decay model is presented.      

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.     

Imaging protein-protein interactions in living cells

The complex organization of plant cells makes it likely that the molecular behaviour of proteins in the test tube and the cell is different. For this reason, it is essential though a challenge to study proteins in their natural environment. Several innovative microspectroscopic approaches provide such possibilities, combining the high spatial resolution of microscopy with spectroscopic techniques to obtain information about the dynamical behaviour of molecules. Methods to visualize interaction can be based on FRET (fluorescence detected resonance energy transfer), for example in fluorescence lifetime imaging microscopy (FLIM). Another method is based on fluorescence correlation spectroscopy (FCS) by which the diffusion rate of single molecules can be determined, giving insight into whether a protein is part of a larger complex or not. Here, both FRET- and FCS-based approaches to study protein-protein interactions in vivo are reviewed.     

Pore-forming protein structure analysis in membranes using multiple independent fluorescence techniques

A large number of transmembrane proteins form aqueous pores or channels in the phospholipid bilayer, but the structural bases of pore formation and assembly have been determined experimentally for only a few of the proteins and protein complexes. The polypeptide segments that form the transmembrane pore and the secondary structure that creates the aqueous-lipid interface can be identified using multiple independent fluorescence techniques (MIFT). The information obtained from several different, but complementary, fluorescence analyses, including measurements of emission intensity, fluorescence lifetime, accessibility to aqueous and to lipophilic quenching agents, and fluorescence resonance energy transfer (FRET) can be combined to characterize the nature of the protein-membrane interaction directly and unambiguously. The assembly pathway can also be determined by measuring the kinetics of the spectral changes that occur upon pore formation. The MIFT approach therefore allows one to obtain structural information that cannot be obtained easily using alternative techniques such as crystallography. This review briefly outlines how MIFT can reveal the identity, location, conformation, and topography of the polypeptide sequences that interact with the membrane.     

Direct measurement of protein–protein interactions by FLIM-FRET at UV laser-induced DNA damage sites in living cells

Protein–protein interactions are essential to ensure timely and precise recruitment of chromatin remodellers and repair factors to DNA damage sites. Conventional analyses of protein–protein interactions at a population level may mask the complexity of interaction dynamics, highlighting the need for a method that enables quantification of DNA damage-dependent interactions at a single-cell level. To this end, we integrated a pulsed UV laser on a confocal fluorescence lifetime imaging (FLIM) microscope to induce localized DNA damage. To quantify protein–protein interactions in live cells, we measured Förster resonance energy transfer (FRET) between mEGFP- and mCherry-tagged proteins, based on the fluorescence lifetime reduction of the mEGFP donor protein. The UV-FLIM-FRET system offers a unique combination of real-time and single-cell quantification of DNA damage-dependent interactions, and can distinguish between direct protein–protein interactions, as opposed to those mediated by chromatin proximity. Using the UV-FLIM-FRET system, we show the dynamic changes in the interaction between poly(ADP-ribose) polymerase 1, amplified in liver cancer 1, X-ray repair cross-complementing protein 1 and tripartite motif containing 33 after DNA damage. This new set-up complements the toolset for studying DNA damage response by providing single-cell quantitative and dynamic information about protein–protein interactions at DNA damage sites.     

Binding of two PriA-PriB complexes to the primosome assembly site initiates primosome formation

A direct quantitative analysis of the initial steps in primosome assembly, involving PriA and PriB proteins and the minimal primosome assembly site (PAS) of phage ?X174, has been performed using fluorescence intensity, fluorescence anisotropy titration, and fluorescence resonance energy transfer techniques. We show that two PriA molecules bind to the PAS at both strong and weak binding sites on the DNA, respectively, without detectable cooperative interactions. Binding of the PriB dimer to the PriA-PAS complex dramatically increases PriA's affinity for the strong site, but only slightly affects its affinity for the weak site. Associations with the strong and weak sites are driven by apparent entropy changes, with binding to the strong site accompanied by a large unfavorable enthalpy change. The PriA-PriB complex, formed independently of the DNA, is able to directly recognize the PAS without the preceding the binding of PriA to the PAS. Thus, the high-affinity state of PriA for PAS is generated through PriA-PriB interactions. The effect of PriB is specific for PriA-PAS association, but not for PriA-double-stranded DNA or PriA-single-stranded DNA interactions. Only complexes containing two PriA molecules can generate a profound change in the PAS structure in the presence of ATP. The obtained results provide a quantitative framework for the elucidation of further steps in primosome assembly and for quantitative analyses of other molecular machines of cellular metabolism.     

Fluorescence lifetime analysis of DNA intercalated ethidium bromide and quenching by free dye

The fluorescence characteristics of ethidium bromide (Eb) complexed to calf thymus DNA have been examined using fluorescence lifetime analysis for a range of DNA (effective nucleotide concentration) to Eb molar ratios. Control of both temperature and ion concentration is necessary for reproducible analyses. Eb complexed to double stranded DNA has a maximum fluorescence lifetime of 23 ns and is easily distinguishable from a fluorescence lifetime value of 1.67 ns corresponding to unbound Eb. In a solution of calf thymus DNA containing excess Eb a binding equilibrium is reached, and this corresponds to one Eb molecule for every five nucleotides. With increasing amounts of unbound Eb, the fluorescence lifetime of the DNA-Eb complex decreases with a concomitant drop in the steady state fluorescence intensity, without a change in the amount of Eb bound to DNA. It is concluded that unbound Eb, acting via a quenching mechanism, shortens the fluorescence lifetime of bound Eb and consequently decreases the overall fluorescence intensity. This means that a different approach is necessary: time-resolved fluorescence spectroscopy directly distinguishes between a decrease in fluorescence intensity due to quenching by an excess of unbound Eb from that due to a decrease in Eb binding to double-stranded DNA. These studies suggest that techniques which measure total steady state fluorescence intensity of bound Eb in order to infer relative amounts of double-stranded DNA must be interpreted with caution. For such assays to be valid it is essential that no unbound Eb be present; otherwise a variable correction factor is required to account for unbound Eb.     

Non fitting based FRET–FLIM analysis approaches applied to quantify protein–protein interactions in live cells

New imaging methodologies in quantitative fluorescence microscopy and nanoscopy have been developed in the last few years and are beginning to be extensively applied to biological problems, such as the localization and quantification of protein interactions. Fluorescence resonance energy transfer (FRET) detected by fluorescence lifetime imaging microscopy (FLIM) is currently employed not only in biophysics or chemistry but also in bio-medicine, thanks to new advancements in technology and also new developments in data treatment. FRET–FLIM can be a very useful tool to ascertain protein interactions occurring in single living cells. In this review, we stress the importance of increasing the acquisition speed when working in vivo employing Time-Domain FLIM. The development of the new mathematical-based non-fitting methods allows the determining of the fraction of interacting donor without the requirement of high count statistics, and thus allows the performing of high speed acquisitions in FRET–FLIM to still be quantitative.