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.
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 ligandinduced 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.
Single-molecule localization microscopy (SMLM) has the potential to quantify the diversity in spatial arrangements of molecules in intact cells. However, this requires that the single-molecule emitters are localized with ultrahigh precision irrespective of the sample format and the length of the data acquisition. We advance SMLM to enable direct distance measurements between molecules in intact cells on the scale between 1 and 20 nm. Our actively stabilized microscope combines three-dimensional real-time drift corrections and achieves a stabilization of <1 nm and localization precision of ~1 nm. To demonstrate the biological applicability of the new microscope, we show a 4-to 7-nm difference in spatial separations between signaling T cell receptors and phosphatases (CD45) in active and resting T cells. In summary, by overcoming the major bottlenecks in SMLM imaging, it is possible to generate molecular images with nanometer accuracy and conduct distance measurements on the biological relevant length scales. Ultraprecise single-molecule localization microscopy enables in situ distance measurements in intact cells. Sci. Adv. 6, eaay8271 (2020).
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