Birgit Hoffmann

Time-resolved autofluorescence imaging of human donor retina tissue from donors with significant extramacular drusen.

PURPOSE Time and spectrally resolved measurements of autofluorescence have the potential to monitor metabolism at the cellular level. Fluorophores that emit with the same fluorescence intensity can be discriminated from each other by decay time of fluorescence intensity after pulsed excitation. We performed time-resolved autofluorescence measurements on fundus samples from a donor with significant extramacular drusen. METHODS Tissue sections from two human donors were prepared and imaged with a laser scanning microscope. The sample was excited with a titanium-sapphire laser, which was tuned to 860 nm, and frequency doubled by a BBO crystal to 430 nm. The repetition rate was 76 MHz and the pulse width was 170 femtoseconds (fs). The time-resolved autofluorescence was recorded simultaneously in 16 spectral channels (445-605 nm) and bi-exponentially fitted. RESULTS RPE can be discriminated clearly from Bruchs membrane, drusen, and choroidal connective tissue by fluorescence lifetime. In RPE, bright fluorescence of lipofuscin could be detected with a maximum at 510 nm and extending beyond 600 nm. The lifetime was 385 ps. Different types of drusen were found. Most of them did not contain lipofuscin and exhibited a weak fluorescence, with a maximum at 470 nm. The lifetime was 1785 picoseconds (ps). Also, brightly emitting lesions, presumably representing basal laminar deposits, with fluorescence lifetimes longer than those recorded in RPE could be detected. CONCLUSIONS The demonstrated differentiation of fluorescent structures by their fluorescence decay time is important for interpretation of in vivo measurements by the new fluorescence lifetime imaging (FLIM) ophthalmoscopy on healthy subjects as well as on patients.

In Vivo Evidence for Lysosome Depletion and Impaired Autophagic Clearance in Hereditary Spastic Paraplegia Type SPG11.

Hereditary spastic paraplegia (HSP) is characterized by a dying back degeneration of corticospinal axons which leads to progressive weakness and spasticity of the legs. SPG11 is the most common autosomal-recessive form of HSPs and is caused by mutations in SPG11. A recent in vitro study suggested that Spatacsin, the respective gene product, is needed for the recycling of lysosomes from autolysosomes, a process known as autophagic lysosome reformation. The relevance of this observation for hereditary spastic paraplegia, however, has remained unclear. Here, we report that disruption of Spatacsin in mice indeed causes hereditary spastic paraplegia-like phenotypes with loss of cortical neurons and Purkinje cells. Degenerating neurons accumulate autofluorescent material, which stains for the lysosomal protein Lamp1 and for p62, a marker of substrate destined to be degraded by autophagy, and hence appears to be related to autolysosomes. Supporting a more generalized defect of autophagy, levels of lipidated LC3 are increased in Spatacsin knockout mouse embryonic fibrobasts (MEFs). Though distinct parameters of lysosomal function like processing of cathepsin D and lysosomal pH are preserved, lysosome numbers are reduced in knockout MEFs and the recovery of lysosomes during sustained starvation impaired consistent with a defect of autophagic lysosome reformation. Because lysosomes are reduced in cortical neurons and Purkinje cells in vivo, we propose that the decreased number of lysosomes available for fusion with autophagosomes impairs autolysosomal clearance, results in the accumulation of undegraded material and finally causes death of particularly sensitive neurons like cortical motoneurons and Purkinje cells in knockout mice.

Assembly of the Inner Kinetochore Proteins CENP-A and CENP-B in Living Human Cells

DNA segregation in mammalian cells during mitosis is an essential cellular process that is mediated by a specific subchromosomal protein complex, the kinetochore. Malfunction of this complex results in aneuploidy and can cause cancer. A subkinetochore complex, the “inner kinetochore”, is present at the centromere during the entire cell cycle. Its location seems to be defined by the settlement of CENP‐A (CENH3), which replaces histone H3 in centromeric nucleosomes. This suggests that CENP‐A can recruit further inner kinetochore proteins by direct binding. Surprisingly, intense in vitro studies could not identify an interaction of CENP‐A with any other inner kinetochore protein. Instead, centromere identity seems to be maintained by a unique nucleosome, which might have a modified structure or epigenetic state that serves to distinguish the centromere from the rest of the chromosome. We investigated the association of CENP‐A and CENP‐B by fluorescence intensity and lifetime‐based FRET measurements in living human HEp‐2 cells. We observed Förster resonance energy transfer (FRET) between CENP‐A and CENP‐B at centromere locations; this indicates that these proteins are in the molecular vicinity (<10 nm) of each other. In addition, we analysed protein–protein interactions within the centromeric nucleosome. We could detect energy transfer between CENP‐A and histone H4 as well as between CENP‐A molecules themselves. On the other hand, no FRET was detected between CENP‐A and H2A.1 or H3.1. Our data support the view that two CENP‐A molecules are packed with H4, but not with H3, in a single centromeric nucleosome.

Prolonged irradiation of enhanced cyan fluorescent protein or Cerulean can invalidate Förster resonance energy transfer measurements

Since its discovery, green fluorescent protein (GFP) and its variants have proven to be a good and convenient fluorescent label for proteins: GFP and other visible fluorescent proteins (VFPs) can be fused selectively to the protein of interest by simple cloning techniques and develop fluorescence without additional cofactors. Among the steadily growing collection of VFPs, several pairs can be chosen that can serve as donor and acceptor fluorophores in Forster resonance energy transfer (FRET) experiments. Among them, the cyan fluorescent proteins (ECFP/Cerulean) and the enhanced yellow fluorescent protein (EYFP) are most commonly used. We show that ECFP and Cerulean have some disadvantages despite their common use: Upon irradiation with light intensities that are commonly used for intensity- and lifetime-based FRET measurements, both the fluorescence intensity and the fluorescence lifetime of ECFP and Cerulean decrease. This can hamper both intensity- and lifetime-based FRET measurements and emphasizes the need for control measurements to exclude these artifacts.

New strategies to measure intracellular sodium concentrations

Fluorescent ion indicators are widely used to measure ion concentrations in living cells. However, despite considerable efforts in synthesizing new compounds, no ratiometric sodium indicator is available that can be excited at visible wavelengths. Ratiometric indicators have an advantage in that measured fluorescence intensities can be corrected for fluctuations of the indicator concentration and the illumination intensity, which is not possible when non-ratiometric indicators are used. One way to circumvent this problem is to measure fluorescence lifetimes, which are independent of these factors. Another way to overcome the disadvantages of a non-ratiometric indicator dye is to embed it, together with a reference dye, into nanoparticles. By relating the indicator fluorescence to the fluorescence of the reference dye, inhomogeneities in the nanosensor concentration or the illumination intensity can be cancelled out reliably. In this study we compare the benefits and drawbacks of these approaches.

Interleukin-17A is involved in mechanical hyperalgesia but not in the severity of murine antigen-induced arthritis

Interleukin-17A (IL-17A) is considered an important pro-inflammatory cytokine but its importance in joint diseases such as rheumatoid arthritis (RA) is unclear. It has also been reported that IL-17A may induce pain but it is unclear whether pro-inflammatory and pro-nociceptive effects are linked. Here we studied in wild type (WT) and IL-17A knockout (IL-17AKO) mice inflammation and hyperalgesia in antigen-induced arthritis (AIA). We found that the severity and time course of AIA were indistinguishable in WT and IL-17AKO mice. Furthermore, the reduction of inflammation by sympathectomy, usually observed in WT mice, was preserved in IL-17AKO mice. Both findings suggest that IL-17A is redundant in AIA pathology. However, in the course of AIA IL-17AKO mice showed less mechanical hyperalgesia than WT mice indicating that IL-17A contributes to pain even if it is not crucial for arthritis pathology. In support for a role of IL-17A and other members of the IL-17 family in the generation of pain we found that sensory neurones in the dorsal root ganglia (DRG) express all IL-17 receptor subtypes. Furthermore, in isolated DRG neurones most IL-17 isoforms increased tetrodotoxin- (TTX-) resistant sodium currents which indicate a role of IL-17 members in inflammation-evoked sensitization of sensory nociceptive neurones.

Imaging cytochrome C oxidase and FoF1-ATP synthase in mitochondrial cristae of living human cells by FLIM and superresolution microscopy

Cytochrome C oxidase and FoF1-ATP synthase constitute complex IV and V, respectively, of the five membrane-bound enzymes in mitochondria comprising the respiratory chain. These enzymes are located in the inner mitochondrial membrane (IMM), which exhibits large invaginations called cristae. According to recent electron cryotomography, FoF1-ATP synthases are located predominantly at the rim of the cristae, while cytochrome C oxidases are likely distributed in planar membrane areas of the cristae. Previous FLIM measurements (K. Busch and coworkers) of complex II and III unravelled differences in the local environment of the membrane enzymes in the cristae. Here, we tagged complex IV and V with mNeonGreen and investigated their mitochondrial nano-environment by FLIM and superresolution microscopy in living human cells. Different lifetimes and anisotropy values were found and will be discussed.

Spectrally resolved fluorescence lifetime and FRET measurements

We present two different approaches that allow multi-wavelength fluorescence lifetime measurements in the time domain in conjunction with a laser scanning microscope and a pulsed excitation source. One technique is based on a streak camera system, the other technique is based on a time-correlated-single-photon-counting (TCSPC) approach. When applied to Forster resonance energy transfer (FRET) measurements, these setups are capable to record time-resolved fluorescence decays for the donor and the acceptor simultaneously.

Adding new dimensions to fluorescence microscopy

Global analysis algorithms perform better than unconstrained data fitting and can improve the accuracy and precision of the experimental data. Here, we report on different strategies that can be pursued to improve the results derived from fluorescence measurements. We point out the benefits of acquiring fluorescence data in a temporally and spectrally resolved manner and show how these data sets can be used to evaluate FRET measurements. Fluorescence measurements can be also combined with other methods such as the patch-clamp technique. This combination allows to record simultaneously fluorescence signals and electrical currents of ion channels in membrane patches. Global analysis of the data can yield valuable information about the processes underlying channel activation. We used this approach to study the activation of homotetrameric CNGA2 channels in inside-out membrane patches. By using fluorescent analogues of cyclic nucleotides as ligands we were able to simultaneously determine ligand binding and channel activation.

Multi-dimensional fluorescence lifetime measurements

In this study, we present two different approaches that can be used for multi-wavelength fluorescence lifetime measurements in the time domain. One technique is based on a streak-camera system, the other technique is based on the time-correlated-single-photon-counting (TCSPC) approach. The setup consists of a confocal laser-scanning microscope and a Titanium:Sapphire-laser that is used for pulsed one- and two-photon excitation. Fluorescence light emitted by the sample is fed back through the scan head and guided to one of the confocal channels, where it is coupled into an optical fiber and directed to a polychromator. The polychromator disperses the emitted light according to its wavelength and focuses the resulting spectrum on the entrance slit of a streak camera or a 16 channel PMT array, which is connected to a TCSPC imaging module. With these techniques it is possible to acquire fluorescence decays in several wavelength regions simultaneously. We applied these methods to Förster resonance energy transfer (FRET) measurements and discuss the advantages and pitfalls of fluorescence lifetime measurements.