Klaus Weisshart

FLIM and FCS detection in laser‐scanning microscopes: Increased efficiency by GaAsP hybrid detectors

Photon counting detectors currently used in fluorescence lifetime microscopy have a number of deficiencies that result in less‐than‐ideal signal‐to‐noise ratio of the lifetimes obtained: Either the quantum efficiency is unsatisfactory or the active area is too small, and afterpulsing or tails in the temporal response contribute to overall timing inaccuracy. We have therefore developed a new FLIM detector based on a GaAsP hybrid photomultiplier. Compared with conventional PMTs and SPADs, GaAsP hybrid detectors have a number of advantages: The detection quantum efficiency reaches or surpasses the efficiency of fast SPADs, and the active area is on the order of 5 mm2, compared with 2.5 10−3 mm2 for a SPAD. The TCSPC response is clean, without the bumps and the diffusion tails typical for PMTs and SPADs. Most important, the hybrid detector is intrinsically free of afterpulsing. FLIM results are therefore free of signal‐dependent background, and FCS curves are free of the known afterpulsing peak. We demonstrate the performance of the new detector for multiphoton NDD FLIM and for FCS. Microsc. Res. Tech., 2011.

Simultaneous Fluorescence and Phosphorescence Lifetime Imaging

We present a lifetime imaging technique that simultaneously records fluorescence and phosphorescence lifetime images in laser scanning systems. It is based on modulating a high-frequency pulsed laser by a signal synchronous with the pixel clock of the scanner, and recording the fluorescence and phosphorescence signals by multi-dimensional TCSPC. Fluorescence is recorded during the on-phase of the laser, phosphorescence during the off-phase. The technique does not require a reduction of the laser pulse repetition rate by a pulse picker, and eliminates the need of using excessively high pulse power for phosphorescence excitation. Laser modulation is achieved either by electrically modulating picosecond diode lasers, or be controlling the lasers via the AOM of a standard confocal or multiphoton laser scanning microscope.

Fluorescence correlation spectroscopy to assess the mobility of nuclear proteins.

Recent developments in cell biology and microscopy techniques enable us to observe macromolecular assemblies in their natural setting: the living cell. These emerging technologies have revealed novel concepts in nuclear cell biology. In order to further elucidate the biochemistry of gene expression, replication, and genome maintenance, the major challenge is now to precisely determine the dynamics of nuclear proteins in the context of the structural organization of the nucleus. Fluorescence correlation spectroscopy (FCS) is an attractive alternative to photobleaching and photoactivation techniques for the analysis of protein dynamics at single-molecule resolution. Here we describe how FCS can be applied to retrieve biophysical parameters of nuclear proteins in living cells.

Abundance and distribution of RNA polymerase II in Arabidopsis interphase nuclei

Highlight Super-resolution microscopy reveals the number of RNA polymerase II molecules in plant interphase nuclei. Both active and inactive polymerase variants aggregate in a range known from mammalian transcription factories.

Containment of Extended Length Polymorphisms in Silk Proteins

The spider silk gene family to the current date has been developed by gene duplication and homogenization events as well as conservation of crucial sequence parts. These evolutionary processes have created an amazing diversity of silk types each associated with specific properties and functions. In addition, they have led to allelic and gene variants within a species as exemplified by the major ampullate spidroin 1 gene of Nephila clavipes. Due to limited numbers of individuals screened to date little is known about the extent of these heterogeneities and how they are finally manifested in the proteins. Using expanded sample sizes, we show that sequence variations expressed as deletions or insertions of tri-nucleotides lead to different sized and structured repetitive units throughout a silk protein. Moreover, major ampullate spidroins 1 can quite dramatically differ in their overall lengths; however, extreme variants do not spread widely in a spider population. This suggests that a certain size range stabilized by purifying selection is important for spidroin 1 gene integrity and protein function. More than one locus for spidroin 1 genes possibly exist within one individual genome, which are homogenized in size, are differentially expressed and give a spider a certain degree of adaptation on silk’s composition and properties. Such mechanisms are shared to a lesser extent by the second major ampullate spidroin gene.

Fluorescence Fluctuation Microscopy to Reveal 3D Architecture and Function in the Cell Nucleus

The three-dimensional (3D) architecture of the cell nucleus is determined not only by the presence of subnuclear domains, such as the nuclear envelope, chromosome territories, and nuclear bodies, but also by smaller domains which form in response to specific functions, such as RNA transcription, DNA replication, and DNA repair. Since both stable and dynamic structures contribute to nuclear morphology, it is important to study the biophysical principles of the formation of macromolecular assemblies within the nucleus. For this purpose, a variety of fluorescence fluctuation microscopy techniques can be applied. Here, we summarize our current knowledge on the 3D architecture of the mammalian cell nucleus and describe in detail how the assembly of functional nuclear protein complexes can be analyzed in living cells using fluorescence bleaching techniques, fluorescence correlation spectroscopy, raster image correlation spectroscopy, and mathematical modeling. In conclusion, the application of all these techniques in combination is a powerful tool to assess the full spectrum of nuclear protein dynamics and to understand the biophysical principles underlying nuclear structure and function.

Super-resolution microscopy heads towards 3D dynamics

Abstract Resolving fine details of subcellular structures is key to understanding the organization and function of cellular networks. Recent advances in far-field fluorescence microscopy provide the necessary tools to analyze these structures with resolutions well below the classical diffraction limit in all three dimensions. Technical improvements go hand-in-hand with new versions of switchable fluorophores that allow nonlinear optical effects to be more efficiently used to push the resolution limit down further. High contrast combined with the wide spectrum of available colors currently endow these fluorescence-based super-resolution techniques with the power to study the complexity of subcellular organelles and the relation of their constituting components down to the molecular level and under physiological conditions. In this way, they give us a far better understanding of the assembly of macromolecular complexes and their functions within a cell than has been possible before employing conventional imaging methods. In this review, we give an overview of the technical state-of-the art of these technologies, their fundamental and technical trade-offs, and provide typical application examples in this exciting field.

Note: An easy way to enable total internal reflection-fluorescence correlation spectroscopy (TIR-FCS) by combining commercial devices for FCS and TIR microscopy.

Total internal reflection-fluorescence correlation spectroscopy (TIR-FCS) is a powerful method for studying dynamic processes at liquid-solid interfaces that may have numerous applications in biology, physics, and material science. Despite of its power and versatility, however, the use of TIR-FCS is still rather limited. The main reason for this is the need of a complex, in-house constructed optical setup whose assembly and adjustment is a quite difficult task. Clearly, the availability of ready to use, commercial TIR-FCS setups will strongly boost the application of this important method in many research areas. In this note we show that although such setups are still not available in the market, a proper combination of commercial devices for confocal fluorescence correlation spectroscopy and for total internal reflection microscopy may enable TIR-FCS in a way that do not require any special optical alignments. Furthermore, we demonstrate the capabilities of the setup by measuring the diffusion coefficient of single dye molecule and quantum dots in the very proximity of a water-glass interface.

Photon Counting Histogram Analysis for Two-Dimensional Systems

Photon counting statistics in 3D photon counting histogram analysis for one-photon excitation is a function of the number of molecules of particular brightness in the excitation-detection volume of a confocal microscope. In mathematical form that volume is approximated by a three-dimensional Gaussian function which is embedded in the PCH theoretical equations. PCH theory assumes that a molecule can be found anywhere inside the excitation-detection volume with equal probability. However, one can easily imagine systems in which this assumption is violated because molecules are constrained by the geometry of the sample. For example, molecules on a surface or in a membrane would be constrained to two dimensions. To enable the analysis of such systems by PCH, the theoretical framework requires modification. Herein, we present an extension of the PCH analysis to systems where molecules exist in thin structures that are effectively two-dimensional. The method, aptly called two-dimensional photon counting histogram (2D PCH), recovers the number of fluorescent particles per unit area and their molecular brightness. Both theoretical background and experimental results are presented. The theory was tested using computer-simulated and experimental 2D PCHs obtained from confocal experiments. We demonstrate that this modification of the theoretical framework provides a tool to extract data that reveal states of aggregation, surface photophysics, and reactivity.

SIM and PALM: high-resolution microscopy methods and their consequences for cell biology

The diffraction limit in traditional fluorescence microscopy (approximately 200 and 600 nanometers in lateral and axial directions, respectively) has restricted the applications in bio-medical research. However, over the last 10 years various techniques have emerged to overcome this limit. Each of these techniques has its own characteristics that influence its application in biology. This paper will show how two of the techniques, Structured Illumination Microscopy (SIM) and PhotoActivated Localization Microscopy (PALM), complement each other in imaging of biological samples beyond the resolution of classical widefield fluorescence microscopy. As a reference the properties of two well known standard imaging techniques in this field, confocal Laser Scanning Microscopy (LSM) and Total Internal Reflection (TIRF) microscopy, are compared to the properties of the two high resolution techniques. Combined SIM/PALM imaging allows the extremely accurate localization of individual molecules within the context of various fluorescent structures already resolved in 3D with a resolution of up to 100nm using SIM. Such a combined system provides the biologist with an unprecedented view of the sub-cellular organization of life.