Björn F. Lillemeier

TCR and Lat are expressed on separate protein islands on T cell membranes and concatenate during activation

The organization and dynamics of receptors and other molecules in the plasma membrane are not well understood. Here we analyzed the spatio-temporal dynamics of T cell antigen receptor (TCR) complexes and linker for activation of T cells (Lat), a key adaptor molecule in the TCR signaling pathway, in T cell membranes using high-speed photoactivated localization microscopy, dual-color fluorescence cross-correlation spectroscopy and transmission electron microscopy. In quiescent T cells, both molecules existed in separate membrane domains (protein islands), and these domains concatenated after T cell activation. These concatemers were identical to signaling microclusters, a prominent hallmark of T cell activation. This separation versus physical juxtapositioning of receptor domains and domains containing downstream signaling molecules in quiescent versus activated T cells may be a general feature of plasma membrane–associated signal transduction.

T cells use two directionally distinct pathways for cytokine secretion

Activated T helper cells produce many cytokines, some of which are secreted through the immunological synapse toward the antigen-presenting cell. Here we have used immunocytochemistry, live-cell imaging and a surface-mediated secretion assay to show that there are two cytokine export pathways in T helper cells. Some cytokines, including interleukin 2 and interferon-γ, were secreted into the synapse, whereas others, including tumor necrosis factor and the chemokine CCL3 (MIP-1α), were released multidirectionally. Each secretion pathway was associated with different trafficking proteins, indicating that they are molecularly distinct processes. These data suggest that T helper cells release some cytokines into the immunological synapse to impart specific communication and others multidirectionally to promote inflammation and to establish chemokine gradients.

Plasma membrane-associated proteins are clustered into islands attached to the cytoskeleton

Although much evidence suggests that the plasma membrane of eukaryotic cells is not homogenous, the precise architecture of this important structure has not been clear. Here we use transmission electron microscopy of plasma membrane sheets and specific probes to show that most or all plasma membrane-associated proteins are clustered in cholesterol-enriched domains (“islands”) that are separated by “protein-free” and cholesterol-low membrane. These islands are further divided into subregions, as shown by the localization of “raft” and “non-raft” markers to specific areas. Abundant actin staining and inhibitor studies show that these structures are connected to the cytoskeleton and at least partially depend on it for their formation and/or maintenance.

TCR-peptide-MHC interactions in situ show accelerated kinetics and increased affinity.

The recognition of foreign antigens by T lymphocytes is essential to most adaptive immune responses. It is driven by specific T-cell antigen receptors (TCRs) binding to antigenic peptide–major histocompatibility complex (pMHC) molecules on other cells. If productive, these interactions promote the formation of an immunological synapse. Here we show that synaptic TCR–pMHC binding dynamics differ significantly from TCR–pMHC binding in solution. We used single-molecule microscopy and fluorescence resonance energy transfer (FRET) between fluorescently tagged TCRs and their cognate pMHC ligands to measure the kinetics of TCR–pMHC binding in situ. When compared with solution measurements, the dissociation of this complex was increased significantly (4–12-fold). Disruption of actin polymers reversed this effect, indicating that cytoskeletal dynamics destabilize this interaction directly or indirectly. Nevertheless, TCR affinity for pMHC was significantly elevated as the result of a large (about 100-fold) increase in the association rate, a likely consequence of complementary molecular orientation and clustering. In helper T cells, the CD4 molecule has been proposed to bind cooperatively with the TCR to the same pMHC complex. However, CD4 blockade had no effect on the synaptic TCR affinity, nor did it destabilize TCR–pMHC complexes, indicating that the TCR binds pMHC independently of CD4.

STAT1 from the cell membrane to the DNA

The binding of interferons (IFNs) to their receptors leads to the phosphorylation and activation of signal transducers and activators of transcription (STATs), and their translocation from the cytoplasm to the nucleus. The mechanisms by which the STATs move to the nuclear pore are not, however, known. Here it is shown that IFN‐α and ‐γ signalling and STAT1 translocation are independent of the actin cytoskeleton or microtubules. Using fluorescence loss in photobleaching (FLIP) and fluorescence recovery after photobleaching (FRAP) experiments, the mobility of a fusion protein of STAT1 with green fluorescent protein (STAT1–GFP) was compared with that of GFP and protein kinase C–GFP. In IFN‐γ‐treated and control cells, cytoplasmic STAT1–GFP shows high, energy‐independent, mobility comparable to that of freely diffusible GFP. A random walk model for movement of STAT1 from the plasma membrane to the nuclear pore is, therefore, indicated. Nuclear STAT1–GFP showed similar high mobility, with exclusion from nucleoli, consistent with high rates of association and dissociation of STAT1–DNA and/or STAT1–protein complexes in the nucleoplasm of the cell.

Of JAKs, STATs, blind watchmakers, jeeps and trains

Janus kinase/signal transducer and activator of transcription (JAK/STAT) signalling is essential but not sufficient for full responses to the interferons (IFNs), most cytokines and some growth factors. The IFN‐γ and interleukin‐6 (IL‐6) response pathways have been used as model systems to investigate both the signals involved and their organisation. Activated STAT1 diffuses freely in the cytoplasmic and nuclear compartments of the cell providing a ‘random walk’ element in the IFN‐γ response. Completely foreign chimeric receptors and, remarkably, in the absence of STAT3, the endogenous IL‐6 receptor can efficiently mediate an IFN‐γ‐like response. Accordingly all of the signals required for an IFN‐γ response can be generated through physiological levels of a foreign ligand. JAK/STAT signalling, therefore, appears ‘soft‐wired’, modular and highly flexible with substantial overlap between different response pathways. The data are consistent with a generic or ‘core’ set of signals from JAK/receptor complexes with ‘add‐on’ modulation through specific receptor motifs. The cellular background likely profoundly affects the nature of the response.

Evidence for a functional sidedness to the αβTCR

The T cell receptor (TCR) and associated CD3γε, δε, and ζζ signaling dimers allow T cells to discriminate between different antigens and respond accordingly, but our knowledge of how these parts fit and work together is incomplete. In this study, we provide additional evidence that the CD3 heterodimers congregate on one side of the TCR in both the αβ and γδTCR-CD3 complexes. We also report that the other side of the αβTCR mediates homotypic αβTCR interactions and signaling. Specifically, an erythropoietin receptor-based dimerization assay was used to show that, upon complex assembly, the CD3ε chains of two CD3 heterodimers are arranged side-by-side in both the αβ and γδTCR-CD3 complexes. This system was also used to show that αβTCRs can dimerize in the cell membrane and that mutating the unusual outer strands of the Cα domain impairs this dimerization. Finally, we present data showing that, for CD4 T cells, the mutations that impair αβTCR dimerization also alter ligand-induced calcium mobilization, TCR accumulation at the site of pMHC contact, and polarization toward the site of antigen contact. These data reveal a “functional-sidedness” to the αβTCR constant region, with dimerization occurring on the side of the TCR opposite from where the CD3 heterodimers are located.

A region encompassing the FERM domain of Jak1 is necessary for binding to the cytokine receptor gp130

The terminal portion of the Janus kinases (Jaks) contains a divergent FERM ( our‐point‐one, zrin, adixin, oesin) homology domain comprising 19 conserved hydrophobic regions. To determine the role of this domain in governing recruitment of Jak1, but not Jak3, to the gp130 subunit of the interleukin‐6 family of cytokine receptors, the interaction of three Jak1/Jak3 chimeras with gp130 was investigated. Chimeras 1, 2 and 3 (Jak1 FERM regions 1–19, 1–18 and 1–8/Jak3, respectively) were all enzymically active. Chimeras 1 and 2 interacted with the cytoplasmic domain of gp130, although less efficiently than Jak1. Only chimera 2, however, restored gp130 signalling in Jak1‐negative cells. The data are consistent with recruitment of Jak1 to gp130 through the Jak1 FERM domain, but also emphasise the likely requirement for precise Jak/receptor orientation to sustain function.

B cell antigen receptors of the IgM and IgD classes are clustered in different protein islands that are altered during B cell activation.

Antigen stimulates the dispersion and remodeling of preformed distinct clusters of B cell receptors on the cell surface. How BCRs mingle The B cell antigen receptor (BCR) consists of a plasma membrane–bound antibody [immunoglobulin (Ig)] that is associated with a pair of signaling proteins. Antigen binding to the BCR stimulates B cells to differentiate into antibody-secreting cells. Maity et al. used high-resolution microscopy, electron microscopy, and proximity ligation assays to visualize the organization of IgM-BCRs and IgD-BCRs on mature B cells. Under resting conditions, the different BCRs were separated in relatively large clusters called protein islands. Antigen triggered the protein islands to become smaller and more disperse, reducing the distance between the different BCRs. The B cell antigen receptors (BCRs) play an important role in the clonal selection of B cells and their differentiation into antibody-secreting plasma cells. Mature B cells have both immunoglobulin M (IgM) and IgD types of BCRs, which have identical antigen-binding sites and are both associated with the signaling subunits Igα and Igβ, but differ in their membrane-bound heavy chain isoforms. By two-color direct stochastic optical reconstruction microscopy (dSTORM), we showed that IgM-BCRs and IgD-BCRs reside in the plasma membrane in different protein islands with average sizes of 150 and 240 nm, respectively. Upon B cell activation, the BCR protein islands became smaller and more dispersed such that the IgM-BCRs and IgD-BCRs were found in close proximity to each other. Moreover, specific stimulation of one class of BCR had minimal effects on the organization of the other. These conclusions were supported by the findings from two-marker transmission electron microscopy and proximity ligation assays. Together, these data provide evidence for a preformed multimeric organization of BCRs on the plasma membrane that is remodeled after B cell activation.

Fluorescence correlation spectroscopy: linking molecular dynamics to biological function in vitro and in situ

Fluorescence correlation spectroscopy (FCS) is a minimally invasive real-time fluorescence technique capable of detecting single molecules in vitro and in situ. By recording and correlating the fluctuations in fluorescence intensity measurements, it is possible to obtain information on molecular mobility and diffusion, hydrodynamic radii, local concentrations and photochemical and photophysical properties. By using dual-color cross-correlation spectroscopy, it is possible to monitor highly specific molecular-level interactions such as binding processes and chemical reactions. Recent advances in alternative detection schemes have allowed the extension of these techniques to the monitoring of slower timescales (e.g. Raster Image Correlation Spectroscopy-RICS) or higher concentrations (e.g. Total Internal Reflection-TIR-FCS). Given the versatility of these techniques, they have become commonplace tools used to specifically unravel the spatio-temporal dynamics of macromolecular entities in living biological systems.