Thomas Weidemann

Analyzing Intracellular Binding and Diffusion with Continuous Fluorescence Photobleaching

Transport and binding of molecules to specific sites are necessary for the assembly and function of ordered supramolecular structures in cells. For analyzing these processes in vivo, we have developed a confocal fluorescence fluctuation microscope that allows both imaging of the spatial distribution of fluorescent molecules with confocal laser scanning microscopy and probing their mobility at specific positions in the cell with fluorescence correlation spectroscopy and continuous fluorescence photobleaching (CP). Because fluorescence correlation spectroscopy is restricted to rapidly diffusing particles and CP to slower processes, these two methods complement each other. For the analysis of binding-related contributions to mobility we have derived analytical expressions for the temporal behavior of CP curves from which the bound fraction and/or the dissociation rate or residence time at binding sites, respectively, can be obtained. In experiments, we investigated HeLa cells expressing different fluorescent proteins: Although enhanced green fluorescent protein (EGFP) shows high mobility, fusions of histone H2B with the yellow fluorescent protein are incorporated into chromatin, and these nuclei exhibit the presence of a stably bound and a freely diffusing species. Nonpermanent binding was found for mTTF-I, a transcription termination factor for RNA polymerase I, fused with EGFP. The cells show fluorescent nucleoli, and binding is transient. CP yields residence times for mTTF-I-EGFP of approximately 13 s.

Loss-of-function mutations in the IL-21 receptor gene cause a primary immunodeficiency syndrome

A primary immunodeficiency syndrome caused by loss-of-function mutations in the IL-21 receptor exhibits impaired B, T, and NK cell function.

Analysis of ligand binding by two-colour fluorescence cross-correlation spectroscopy

Fluorescence correlation spectroscopy (FCS) is a well-established method for the analysis of freely diffusing fluorescent particles in solution. In a two-colour setup, simultaneous detection of two different dyes allows the acquisition of both the autocorrelation of the signal of each channel and the cross-correlation of the two channels (fluorescence cross-correlation spectroscopy, FCCS). The cross-correlation function is related to the amount of diffusing particles carrying both dyes and can be used for monitoring a binding reaction. Here we develop a formalism for a quantitative analysis of ligand binding from a combination of the auto- and the cross-correlation amplitudes. Technical constraints, like the focal geometry, background signal and cross-talk between the detection channels as well as photophysical and biochemical effects which modulate the brightness of the particles are included in the analysis. Based on this framework a comprehensive treatment for the determination of two-component binding equilibria by FCS/FCCS is presented.

Single bead labeling method for combining confocal fluorescence on-bead screening and solution validation of tagged one-bead one-compound libraries.

Screening of one-bead one-compound libraries by incubating beads with fluorescently labeled target protein requires isolation and structure elucidation of a large number of primary hit beads. However, the potency of the identified ligands is only revealed after time consuming and expensive larger scale resynthesis and testing in solution. Often, many of the resynthesized compounds turn out to be weak target binders in solution due to large differences between surface and solution binding affinities. For an industry style high-throughput screening (HTS) process a high false positive rate is detrimental. We have therefore combined single bead and single molecule/single cell techniques into an integrated HTS process in which the picomole amount of substance contained on one isolated hit bead is sufficient for quality control, structure determination, and precise affinity determination to the target protein in solution.

Focus on composition and interaction potential of single-pass transmembrane domains

Transmembrane domains (TMD) connect the inner with the outer world of a living cell. Single TMD containing (bitopic) receptors are of particular interest, because their oligomerization seems to be a common activation mechanism in cell signaling. We analyzed the composition of TMDs in bitopic proteins within the proteomes of 12 model organisms. The average number of strongly polar and charged residues decreases during evolution, while the occurrence of a dimerization motif, GxxxG, remains unchanged. This may reflect the avoidance of unspecific binding within a growing receptor interaction network. In addition, we propose a new experimental approach for studying helix–helix interactions in giant plasma membrane vesicles using scanning fluorescence cross‐correlation spectroscopy. Measuring eGFP/mRFP tagged versions of cytokine receptors confirms the homotypic interactions of the erythropoietin receptor in contrast to the Interleukin‐4 receptor chains. As a proof of principle, by swapping the TMDs, the interaction potential of erythropoietin receptor was partially transferred to Interleukin‐4 receptor α and vice versa. Non‐interacting receptors can therefore serve as host molecules for TMDs whose oligomerization capability must be assessed. Computational analysis of the free energy gain resulting from TMD dimer formation strongly corroborates the experimental findings, potentially allowing in silico pre‐screening of interacting pairs.

PyCorrFit—generic data evaluation for fluorescence correlation spectroscopy

Summary: We present a graphical user interface (PyCorrFit) for the fitting of theoretical model functions to experimental data obtained by fluorescence correlation spectroscopy (FCS). The program supports many data file formats and features a set of tools specialized in FCS data evaluation. Availability and implementation: The Python source code is freely available for download from the PyCorrFit web page at http://pycorrfit.craban.de. We offer binaries for Ubuntu Linux, Mac OS X and Microsoft Windows. Contact: paul.mueller@biotec.tu-dresden.de and weidemann@biochem.mpg.de

Covalent fluorescence labeling of His-tagged proteins on the surface of living cells

Mechanistic studies in living cells require fluorescent labeling of the proteins of interest. The widespread application of GFP variants in combination with fluorescence microscopy has had an immense impact on our understanding of the dynamic processes in living cells. Due to the recent progress in detection technologies and microspectroscopy, the expansion of the available labeling strategies to more photostable, smaller, multicolor reagents has become an active field of research. The majority of these new fluorescent tags are small chemical entities that bind with various affinities to genetically fused peptide stretches in the protein of interest. Confocal images provide snapshots of dynamic molecular rearrangements. However, the observation of such processes by medium to highaffinity fluorescent ligands can be complicated because of a floating background inherent to the limited stability of the complex. Thus, covalent, site-selective protein-labeling techniques offer improvements in separating cellular from tag-specific biochemical events. Up to now much emphasis has been given to covalent-labeling strategies that rely on enzymatic couplings; only recently has a novel nonenzymatic protein-labeling concept been described. Herein we present an alternative strategy that combines the reversible binding of a medium affinity probe with a photoreactive moiety to generate a covalent linkage in the proximity of the tag. Substituted arylazides have been widely used in protein-interaction studies for photoaffinity labeling. Photoactivation is well suited for generating covalent bonds because of the simplicity of the activation procedure, good efficiencies, and short timescales of the reaction. The combination of a photocrosslinking moiety and an oligohistidine directing Ni-NTA group has previously been exploited for in vitro protein functionalization to build self-assembling protein arrays. Reasoning that this method could provide a simple means of covalently tagging proteins on living cells, we synthesized a trifunctional labeling tag that consists of a fluorophore, a Ni-NTA moiety, and a photoactivatable arylazide. Our labeling strategy comprises two steps: reversible binding at the His-tag of a target protein followed by irreversible photolinkage at the binding site (Figure 1). Irreversible crosslinking to a recombinant His-tagged GFP was demonstrated in vitro

Single cell analysis of ligand binding and complex formation of interleukin-4 receptor subunits.

Interleukin-4 (IL-4) is an important class I cytokine involved in adaptive immunity. IL-4 binds with high affinity to the single-pass transmembrane receptor IL-4Rα. Subsequently, IL-4Rα/IL-4 is believed to engage a second receptor chain, either IL-2Rγ or IL-13Rα1, to form type I or II receptor complexes, respectively. This ternary complex formation then triggers downstream signaling via intracellular Janus kinases bound to the cytoplasmic receptor tails. Here, we study the successive steps of complex formation at the single cell level with confocal fluorescence imaging and correlation spectroscopy. We characterize binding and signaling of fluorescently labeled IL-4 by flow cytometry of IL-4-dependent BaF3 cells. The affinity to ectopically expressed IL-4Rα was then measured by single-color fluorescence correlation spectroscopy in adherent HEK293T cells that express the components of the type II IL-4R but not type I. Finally, IL-4-induced complex formation was tested by dual-color fluorescence cross-correlation spectroscopy. The data provide evidence for codiffusion of IL-4-A647 bound IL-4Rα and the type II subunit IL-13Rα1 fused to enhanced green fluorescent protein, whereas type I complexes containing IL-2Rγ and JAK3 were not detected at the cell surface. This behavior may reflect hitherto undefined differences in the mode of receptor activation between type I (lymphoid) and type II (epithelial) receptor expressing cells.

Essential role of endocytosis for interleukin-4-receptor-mediated JAK/STAT signalling

ABSTRACT Many important signalling cascades operate through specialized signalling endosomes, but a corresponding mechanism has as yet not been described for hematopoietic cytokine receptors. Based on live-cell affinity measurements, we recently proposed that ligand-induced interleukin-4 receptor (IL-4R) complex formation and thus JAK/STAT pathway activation requires a local subcellular increase in receptor density. Here, we show that this concentration step is provided by the internalization of IL-4R subunits through a constitutive, Rac1-, Pak- and actin-mediated endocytosis route that causes IL-4R subunits to become enriched by about two orders of magnitude within a population of cortical endosomes. Consistently, ligand-induced receptor dimers are preferentially detected within these endosomes. IL-4 signalling can be blocked by pharmacological inhibitors targeting the actin polymerization machinery driving receptor internalization, placing endocytosis unambigously upstream of receptor activation. Taken together, these observations demonstrate a role for endocytosis that is mechanistically distinct from the scaffolding function of signalling endosomes in other pathways. Summary: Constitutive receptor internalization is required for IL-4R signalling. Increased endosomal concentrations allow receptor dimerization that is disfavoured at endogenous plasma membrane densities.

Dynamics and Interaction of Interleukin-4 Receptor Subunits in Living Cells

It has long been established that dimerization of Interleukin-4 receptor (IL-4R) subunits is a pivotal step for JAK/STAT signal transduction. However, ligand-induced complex formation at the surface of living cells has been challenging to observe. Here we report an experimental assay employing trisNTA dyes for orthogonal, external labeling of eGFP-tagged receptor constructs that allows the quantification of receptor heterodimerization by dual-color fluorescence cross-correlation spectroscopy. Fluorescence cross-correlation spectroscopy analysis at the plasma membrane shows that IL-4R subunit dimerization is indeed a strictly ligand-induced process. Under conditions of saturating cytokine occupancy, we determined intramembrane dissociation constants (K(d,2D)) of 180 and 480 receptors per μm(2) for the type-2 complexes IL-4:IL-4Rα/IL-13Rα1 and IL-13:IL-13Rα1/IL-4Rα, respectively. For the lower affinity type-1 complex IL-4:IL-4Rα/IL-2Rγ, we estimated a K(d,2D) of ∼1000 receptors per μm(2). The receptor densities required for effective dimerization thus exceed the typical, average expression levels by several orders of magnitude. In addition, we find that all three receptor subunits accumulate rapidly within a subpopulation of early sorting and recycling endosomes stably anchored just beneath the plasma membrane (cortical endosomes, CEs). The receptors, as well as labeled IL-4 and trisNTA ligands are specifically trafficked into CEs by a constitutive internalization mechanism. This may compensate for the inherent weak affinities that govern ligand-induced receptor dimerization at the plasma membrane. Consistently, activated receptors are also concentrated at the CEs. Our observations thus suggest that receptor trafficking may play an important role for the regulation of IL-4R-mediated JAK/STAT signaling.