Visualizing single molecules interacting with nuclear pore complexes by narrow-field epifluorescence microscopy

The utility of single molecule fluorescence (SMF) for understanding biological reactions has been amply demonstrated by a diverse series of studies over the last decade. In large part, the molecules of interest have been limited to those within a small focal volume or near a surface to achieve the high sensitivity required for detecting the inherently weak signals arising from individual molecules. Consequently, the investigation of molecular behavior with high time and spatial resolution deep within cells using SMF has remained challenging. Recently, we demonstrated that narrow-field epifluorescence microscopy allows visualization of nucleocytoplasmic transport at the single cargo level. We describe here the methodological approach that yields 2 ms and approximately 15 nm resolution for a stationary particle. The spatial resolution for a mobile particle is inherently worse, and depends on how fast the particle is moving. The signal-to-noise ratio is sufficiently high to directly measure the time a single cargo molecule spends interacting with the nuclear pore complex. Particle tracking analysis revealed that cargo molecules randomly diffuse within the nuclear pore complex, exiting as a result of a single rate-limiting step. We expect that narrow-field epifluorescence microscopy will be useful for elucidating other binding and trafficking events within cells.     

光学显微镜技术在活细胞单分子检测中的应用

单分子检测是一门以高度的时间以及空间分辨率研究生物单分子的技术。近来,科学技术的探索发展使我们可以观察、检测甚至操纵单个分子并且研究它们的构象变化和动力学行为。这一发展使得以前被传统系综研究体系平均化所隐藏的新信息被揭示出来。单分子检测技术的发展已经揭开了生命科学研究的新篇章。在本文中,我们将介绍有关活细胞中单分子检测技术的发展以及活细胞内单分子检测的现状。     

Single-molecule reader for proteomics and genomics

Recent developments in ultrasensitive fluorescence microscopy enabled the detection and detailed characterization of individual biomolecules in their native environment. New types of information can be obtained from studying individual molecules, which is not accessible from ensemble measurements. Moreover, this methodological advance matches the need of bioscience to downscale the sample amount required for screening devices. It is envisioned that concentrations as low as approximately 1000 molecules contained in a sample of 1 nl can be detected in a chip-based assay. In this review, we overview state-of-the-art single molecule microscopy with respect to its applicability to ultrasensitive screening. Quantitative estimations will be given, based on a novel apparatus designed for large area screening at single molecule sensitivity.     

A simple DNA stretching method for fluorescence imaging of single DNA molecules

Stretching or aligning DNA molecules onto a surface by means of molecular combing techniques is one of the critical steps in single DNA molecule analysis. However, many of the current studies have focused on λ-DNA, or other large DNA molecules. There are very few studies on stretching methodologies for DNA molecules generated via PCR (typically smaller than 20 kb). Here we describe a simple method of stretching DNA molecules up to 18 kb in size on a modified glass surface. The very low background fluorescence allows efficient detection of single fluorescent dye labels incorporated into the stretched DNA molecules.     

A quantile method for sizing optical maps.

Optical mapping is an integrated system for the analysis of single DNA molecules. It constructs restriction maps (noted as "optical map" ) from individual DNA molecules presented on surfaces after they are imaged by fluorescence microscopy. Because restriction digestion and fluorochrome staining are performed after molecules are mounted, resulting restriction fragments retain their order. Maps of fragment sizes and order are constructed by image processing techniques employing integrated fluorescence intensity measurements. Such analysis, in place of molecular length measurements, obviates need for uniformly elongated molecules, but requires samples containing small fluorescent reference molecules for accurate sizing. Although robust in practice, elimination of internal reference molecules would reduce errors and extend single molecule analysis to other platforms. In this paper, we introduce a new approach that does not use reference molecules for direct estimation of restriction fragment sizes, by the exploitation of the quantiles associated with their expected distribution. We show that this approach is comparable to the current reference-based method as evaluated by map alignment techniques in terms of the rate of placement of optical maps to published sequence.     

Tracking single molecules in the live cell plasma membrane-Do's and Don't's

In recent years, the development of fast and highly sensitive microscopy has changed the way of thinking of cell biologists: it became more and more important to study the structural origin for cellular function, and industry turned its attention to the improvement of the required instruments. Optical microscopy has now reached a milestone in sensitivity by resolving the signal of a single, fluorescence-labeled biomolecule within a living cell. First steps towards these pioneering studies were set by methods developed in the late eighties for tracking single biomolecules labeled with fluorescent latex spheres or gold-particles. Meanwhile, a time-resolution of milliseconds for imaging weakly fluorescent cellular structures like small organelles, vesicles, or even single molecules is state-of-the-art. The advances in the fields of microscopy brought new cell biological questions into reach. The investigation of a single fluorescent molecule-or simultaneously of an ensemble of individual molecules-provides principally new information, which is generally hidden in ensemble-averaged signals of molecules. In this paper we describe strategies how to make use of single molecule trajectories for deducing information about nanoscopic structures in a live cell context. In particular, we focus our discussion on elucidating the plasma membrane organization by single molecule tracking. A diffusing membrane constituent--e.g. a protein or a lipid--experiences a manifold of interactions on its path: the most rapid interactions represent the driving force for free diffusion; stronger or correlated interactions can be frequently observed as subdiffusive behavior. Correct interpretation of the data has the potential to shine light on this enigmatic organelle, where membrane rafts, protein microdomains, fences and pickets still frolic through the text-book sketches. We summarize available analytical models and point out potential pitfalls, which may result in quantitative or three even qualitative misinterpretations.     

零模波导原理、制备及其在单分子荧光检测中的应用

单分子荧光检测作为一种能够表征分子个体性质及行为的分析方法,有助于揭示利用传统荧光检测方法无法得到的信息,在近年来受到人们的广泛关注。利用传统光学检测设备进行单分子荧光检测时,由于受到衍射极限的限制,同时为了保证在观测体积内只有单个荧光分子,仅能采用无限稀释溶液的方法实现单分子荧光检测。虽然这种方法可以满足单分子检测的要求,但是由于大部分酶分子正常工作时底物的生理浓度都非常高,底物浓度的大幅度降低会对酶分子的反应机制等方面造成影响。零模波导作为一种新型的单分子检测器件,通过纳米微孔结构突破了光学衍射极限的限制将观测体积降至仄升量级（10-21L）,使得在生理浓度范围内检测单分子荧光成为可能,在单分子荧光检测领域得到了广泛应用。因此,就零模波导的原理、制备工艺及其在单分子DNA测序、生物膜、生物大分子之间的相互作用及单分子反应动力学方面的具体应用进行综述。     

Unraveling helicase mechanisms one molecule at a time

Recent years have seen an increasing number of biological applications of single molecule techniques, evolving from a proof of principle type to the more sophisticated studies. Here we compare the capabilities and limitations of different single molecule techniques in studying the activities of helicases. Helicases share a common catalytic activity but present a high variability in kinetic and phenomenological behavior, making their studies ideal in exemplifying the use of the new single molecule techniques to answer biological questions. Unexpected phenomena have also been observed from individual molecules suggesting extended or alternative functionality of helicases in vivo.     

荧光单分子检测技术在生命科学中的应用

荧光单分子检测技术是用荧光标记来显示和追踪单个分子的构象变化、动力学,单分子之间的相互作用以及单分子操纵的研究。过去对于生命科学分子机制的研究,都是对分子群体进行研究,然后平均化来进行单分子估测。因此,单个分子的动态性和独立性也被平均化掉而无法表现出来。荧光单分子检测技术真正实现了对单个分子的实时观测,将过去被平均化并隐藏在群体测量中不能获得的信息显示出来。近几年来,荧光单分子检测技术的飞速发展,为生命科学的发展,开辟了全新的研究领域。现就荧光单分子检测技术在研究动力蛋白、DNA转录、酶反应、蛋白质动态性和细胞信号转导方面的应用进展作一综述。     

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.     

Automatic detection of single fluorophores in live cells

Recent developments in light microscopy enable individual fluorophores to be observed in aqueous conditions. Biological molecules, labeled with a single fluorophore, can be localized as isolated spots of light when viewed by optical microscopy. Total internal reflection fluorescence microscopy greatly reduces background fluorescence and allows single fluorophores to be observed inside living cells. This advance in live-cell imaging means that the spatial and temporal dynamics of individual molecules can be measured directly. Because of the stochastic nature of single molecule behavior a statistically meaningful number of individual molecules must be detected and their separate trajectories in space and time stored and analyzed. Here, we describe digital image processing methods that we have devised for automatic detection and tracking of hundreds of molecules, observed simultaneously, in vitro and within living cells. Using this technique we have measured the diffusive behavior of pleckstrin homology domains bound to phosphoinositide phospholipids at the plasma membrane of live cultured mammalian cells. We found that mobility of these membrane-bound protein domains is dominated by mobility of the lipid molecule to which they are attached and is highly temperature dependent. Movement of PH domains isolated from the tail region of myosin-10 is consistent with a simple random walk, whereas, diffusion of intact PLC-delta1 shows behavior inconsistent with a simple random walk. Movement is rapid over short timescales but much slower at longer timescales. This anomalous behavior can be explained by movement being restricted to membrane regions of 0.7 microm diameter.     

Fluorescence imaging of single molecules in polymer microspheres.

We report on far-field fluorescence imaging of single molecules in spherical polymer microparticles produced from solution by using microdroplet techniques. The fluorescence photobleaching quantum yields of rhodamine 6G in a common water-soluble polymer (polyvinyl alcohol) are at least five times smaller, corresponding to proportionally larger average fluorescence signals, than those in ethanolic solvents. This allows for acquisition of multiple images from a single molecule on a time scale of several minutes. We also show that fluorescent images of single molecules in microspheres can be calculated from semiclassic electrodynamics, which may ultimately be useful in retrieving dynamical information from experimental images.     

Quantitative study of polymer conformation and dynamics by single-particle tracking

We present a new method for analyzing the dynamics of conformational fluctuations of individual flexible polymer molecules. In single-particle tracking (SPT), one end of the polymer molecule is tethered to an immobile substratum. A microsphere attached to the other end serves as an optical marker. The conformational fluctuations of the polymer molecule can be measured by optical microscopy via the motion of the microsphere. The bead-and-spring theory for polymer dynamics is further developed to account for the microsphere, and together the measurement and the theory yield quantitative information about molecular conformations and dynamics under nonperturbing conditions. Applying the method to measurements carried out on DNA molecules provides information complementary to recent studies of single DNA molecules under extensional force. Combining high precision measurements with the theoretical analysis presented here creates a powerful tool for studying conformational dynamics of biological and synthetic macromolecules at the single-molecule level.     

Single molecule microscopy of biomembranes (review)

Recent advances in the development of new microscopy techniques with a sensitivity of a single molecule have gained access to essentially new types of information obtainable from imaging biomolecular samples. These methodologies are analysed here in terms of their applicability to the in vivo visualization of cellular processes on the molecular scale, in particular of processes in cell membranes. First examples of single molecule microscopy on cell membranes revealed new basic insight into the lateral organization of the plasma membrane, providing the captivating perspective of an ultrasensitive methodology as a general tool to study local processes and heterogeneities in living cells.     

Single molecule microscopy of biomembranes (Review)

Recent advances in the development of new microscopy techniques with a sensitivity of a single molecule have gained access to essentially new types of information obtainable from imaging biomolecular samples. These methodologies are analysed here in terms of their applicability to the in vivo visualization of cellular processes on the molecular scale, in particular of processes in cell membranes. First examples of single molecule microscopy on cell membranes revealed new basic insight into the lateral organization of the plasma membrane, providing the captivating perspective of an ultrasensitive methodology as a general tool to study local processes and heterogeneities in living cells.     

Real-time observation of a single DNA digestion by lambda exonuclease under a fluorescence microscope field

A fluorescence microscopy technique has been developed to visualize the behavior of individual DNA and protein molecules. Real-time direct observation of a single DNA molecule can be used to investigate the dynamics of DNA-protein interactions, such as the DNA digestion reaction by lambda exonuclease. In conventional methods it is impossible to analyze the dynamics of an individual lambda exonuclease molecule on a DNA because they can only observe the average behavior of a number of exonuclease molecules. Observation of a single molecule, on the other hand, can reveal processivity and binding rate of an individual exonuclease molecule. To evaluate the dynamics of lambda exonuclease, a stained lambda DNA molecule with one biotinylated terminal was fixed on an avidin-coated coverslip and straightened using a d.c. electric field. Microscopic observation of digestion of a straightened DNA molecule by lambda exonuclease revealed that the DNA digestion rate was approximately 1000 bases/s and also demonstrated high processivity.     

Super-Resolution Imaging of Molecular Emission Spectra and Single Molecule Spectral Fluctuations

Localization microscopy can image nanoscale cellular details. To address biological questions, the ability to distinguish multiple molecular species simultaneously is invaluable. Here, we present a new version of fluorescence photoactivation localization microscopy (FPALM) which detects the emission spectrum of each localized molecule, and can quantify changes in emission spectrum of individual molecules over time. This information can allow for a dramatic increase in the number of different species simultaneously imaged in a sample, and can create super-resolution maps showing how single molecule emission spectra vary with position and time in a sample.     

Direct observation of ligand colocalization on individual receptor molecules.

We have exploited the novel methodology of far-field fluorescence microscopy at the single molecule level to study colocalization of two different ligand molecules on an individual receptor. The use of dual-wavelength single molecule imaging allows discrimination between isolated and colocalized ligands with an accuracy of 40 nm. In the case of very close proximity of the two ligands, below 7 nm, single pair Forster energy-transfer was observed. The latter finding unequivocally demonstrates colocalization of two ligands on an individual receptor.