Angelika Rueck

Advanced time-correlated single photon counting techniques for spectroscopy and imaging in biomedical systems

Time-correlated single photon counting (TCSPC) is based on the detection of single photons of a periodic light signal, measurement of the detection time of the photons, and the build-up of the photon distribution versus the time in the signal period. TCSPC achieves a near ideal counting efficiency and transit-time-spread-limited time resolution for a given detector. The drawback of traditional TCSPC is the low count rate, long acquisition time, and the fact that the technique is one-dimensional, i.e. limited to the recording of the pulse shape of light signals. We present an advanced TCSPC technique featuring multi-dimensional photon acquisition and a count rate close to the capability of currently available detectors. The technique is able to acquire photon distributions versus wavelength, spatial coordinates, and the time on the ps scale, and to record fast changes in the fluorescence lifetime and fluorescence intensity of a sample. Biomedical applications of advanced TCSPC techniques are time-domain optical tomography, recording of transient phenomena in biological systems, spectrally resolved fluorescence lifetime imaging, FRET experiments in living cells, and the investigation of dye-protein complexes by fluorescence correlation spectroscopy. We demonstrate the potential of the technique for selected applications.

Spectrally resolved fluorescence lifetime imaging microscopy: Förster resonant energy transfer global analysis with a one- and two-exponential donor model

In many fields of life science, visualization of spatial proximity, as an indicator of protein interactions in living cells, is of outstanding interest. A method to accomplish this is the measurement of Förster resonant energy transfer (FRET) by means of spectrally resolved fluorescence lifetime imaging microscopy. The fluorescence lifetime is calculated using a multiple-wavelength fitting routine. The donor profile is assumed first to have a monoexponential time-dependent behavior, and the acceptor decay profile is solved analytically. Later, the donor profile is assumed to have a two-exponential time-dependent behavior and the acceptor decay profile is derived analytically. We develop and apply a multispectral fluorescence lifetime imaging microscopy analysis system for FRET global analysis with time-resolved and spectrally resolved techniques, including information from donor and acceptor channels in contrast to using just a limited spectral data set from one detector only and a model accounting only for the donor signal. This analysis is used to demonstrate close vicinity of β-secretase (BACE) and GGA1, two proteins involved in Alzheimers disease pathology. We attempt to verify if an improvement in calculating the donor lifetimes could be achieved when time-resolved and spectrally resolved techniques are simultaneously incorporated.

The Golgi-Localized γ-Ear-Containing ARF-Binding (GGA) Proteins Alter Amyloid-β Precursor Protein (APP) Processing through Interaction of Their GAE Domain with the Beta-Site APP Cleaving Enzyme 1 (BACE1).

Proteolytic processing of amyloid-β precursor protein (APP) by beta-site APP cleaving enzyme 1 (BACE1) is the initial step in the production of amyloid beta (Aβ), which accumulates in senile plaques in Alzheimer’s disease (AD). Essential for this cleavage is the transport and sorting of both proteins through endosomal/Golgi compartments. Golgi-localized γ-ear-containing ARF-binding (GGA) proteins have striking cargo-sorting functions in these pathways. Recently, GGA1 and GGA3 were shown to interact with BACE1, to be expressed in neurons, and to be decreased in AD brain, whereas little is known about GGA2. Since GGA1 impacts Aβ generation by confining APP to the Golgi and perinuclear compartments, we tested whether all GGAs modulate BACE1 and APP transport and processing. We observed decreased levels of secreted APP alpha (sAPPα), sAPPβ, and Aβ upon GGA overexpression, which could be reverted by knockdown. GGA-BACE1 co-immunoprecipitation was impaired upon GGA-GAE but not VHS domain deletion. Autoinhibition of the GGA1-VHS domain was irrelevant for BACE1 interaction. Our data suggest that all three GGAs affect APP processing via the GGA-GAE domain.

Mitochondrial matrix pH as a decisive factor in neurometabolic imaging

Abstract. Alterations of cellular bioenergetics are a common feature in most neurodegenerative disorders. However, there is a selective vulnerability of different brain regions, cell types, and even mitochondrial populations to these metabolic disturbances. Thus, the aim of our study was to establish and validate an in vivo metabolic imaging technique to screen for mitochondrial function on the subcellular level. Based on nicotinamide adenine dinucleotide (phosphate) fluorescence lifetime imaging microscopy [NAD(P)H FLIM], we performed a quantitative correlation to high-resolution respirometry. Thereby, we revealed mitochondrial matrix pH as a decisive factor in imaging NAD(P)H redox state. By combining both parameters, we illustrate a quantitative, high-resolution assessment of mitochondrial function in metabolically modified cells as well as in an amyloid precursor protein-overexpressing model of Alzheimer’s disease. Our metabolic imaging technique provides the basis for dissecting mitochondrial deficits not only in a range of neurodegenerative diseases, shedding light onto bioenergetic failures of cells remaining in their metabolic microenvironment.

Oxygen sensing PLIM together with FLIM of intrinsic cellular fluorophores for metabolic mapping

Otical imaging techniques based on time correlated single photon counting (TCSPC) has found wide applications in medicine and biology. Non-invasive and information-rich fluorescence lifetime imaging microscopy (FLIM) is successfully used for monitoring fluorescent intrinsic metabolic coenzymes as NAD(P)H (nicotinamide adenine dinucleotide (phosphate)) and FAD+ (flavin adenine dinucleotide) in living cells and tissues. The ratio between proteinbound and free coenzymes gives an information about the balance between oxidative phosphorylation and glycolysis in the cells. The changes of the ratio reflects major cellular disorders. A correlation exists between metabolic activity, redox ratio and fluorescence lifetime during stem cell differentiation, neurodegenerative diseases, and carcinogenesis. A multichannel FLIM detection system was designed for monitoring the redox state of NAD(P)H and FAD+ and other intrinsic fluorophores as protoporphyrin IX. In addition, the unique upgrade is useful to perform FLIM and PLIM (phosphorescence lifetime imaging microscopy) simultaneously. PLIM is a promising method to investigate oxygen sensing in biomedical samples. In detail, the oxygen-dependent quenching of phosphorescence of some compounds as transition metal complexes enables measuring of oxygen partial pressure (pO2). Using a two-channel FLIM/PLIM system we monitored intrinsic pO2 by PLIM simultaneously with NAD(P)H by FLIM providing complex metabolic and redox imaging of living cells. Physico-chemical properties of oxygen sensitive probes define certain parameters including their localisation. We present results of some ruthenium based complexes including those specifically bound to mitochondria.

NADH Autofluorescence-A Marker on its Way to Boost Bioenergetic Research: NADH Autofluorescence

More than 60 years ago, the idea was introduced that NADH autofluorescence could be used as a marker of cellular redox state and indirectly also of cellular energy metabolism. Fluorescence lifetime imaging microscopy of NADH autofluorescence offers a marker‐free readout of the mitochondrial function of cells in their natural microenvironment and allows different pools of NADH to be distinguished within a cell. Despite its many advantages in terms of spatial resolution and in vivo applicability, this technique still requires improvement in order to be fully useful in bioenergetics research. In the present review, we give a summary of technical and biological challenges that have so far limited the spread of this powerful technology. To help overcome these challenges, we provide a comprehensible overview of biological applications of NADH imaging, along with a detailed summary of valid imaging approaches that may be used to tackle many biological questions. This review is meant to provide all scientists interested in bioenergetics with support on how to embed successfully NADH imaging in their research.

Investigation of alternative binding events between the Golgi-localized, gamma ear-containing, ARF-binding (GGA) protein family and BACE1 and its influence on the processing of amyloid precursor protein (APP)

the microarray analysis, we surveyed the binding sites of transcription factors, using the database produced by UCSC Genome Bioinformatics. Results: The increase in the DNA-binding activity of NF-kappa B and AP-1 after exposure to Abeta fibrils was suppressed by PARP-1 inhibitor, 1,5-dihydroxyisoquinoline (DHIQ), and also PARP-1 siRNA. The microarray analysis demonstrated that among 31,042 probes used, 345 and 224 probe sets showed up-regulation and down-regulation, respectively, in the astrocytes after exposure to Abeta fibrils. Furthermore, 87 probe sets showed down-regulation, while only three probe sets showed up-regulation, after addition of DHIQ. Upstream and downstream of the genes detected by these probe sets, the DNA-binding sites of other transcription factors than NF-kappa B and AP-1 were identified. Conclusions: PARP-1 plays an important role in the change of gene expression profile of astrocytes after exposure to A beta fibrils through the activation of a variety of transcription factors. By regulation of these factors, PARP-1 inhibitors could be new therapeutic and/or neuroprotective agents for Alzheimer’s disease.

Imaging time-resolved fluorescence characteristics of organelle specific fluorophores and photosensitizers using ps pulsed diode lasers and TCSPC techniques

A time-correlated single photon counting (TCSPC) module (SPC-730, Becker & Hickl, Germany) was connected to a laser scanning microscope (Zeiss, Germany) equipped with an ultrafast photomultiplier. Short pulse excitation was achieved with two laser diodes emitting at 398nm and 434nm with a pulse duration of 70ps and 60 ps (PicoQuant, Germany) to allow intracellular fluorescence lifetime imaging (FLIM). With this setup, fluorescence lifetime of the mitochondrial marker Rhodamine 123 could be studied in solution under the same instrumental conditions as used for fluorescence lifetime imaging of cell monolayers. With the same set of parameters, fluorescence lifetime of Rhodamine 123 was calculated with good reproducibility in mitochondria of living cells. We present here a comparison of different fitting routines, including a multiexponential fitting based on the method of Laplace transformation. Fluorescence lifetimes calculated with the multiexponential fitting routine proved to be particularly useful to study the distribution of 5-ALA metabolites in cell monolayers.