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How T cells lose their touch.

T cells are among the most sensitive of cells, but in this issue of Immunity, Honda et al. (2014) demonstrate that effector T cells must lose their touch within hours to protect the host from immunopathology.

Immunology: Dendritic Cells Pull the T Cell's Strings.

Cells communicate by sensing diffusible or surface-associated chemical signals, with the surface-associated molecules also providing mechanical cues. New work now shows that both chemical and mechanical signals are critical for the communication between T cells and antigen-presenting dendritic cells in the initiation and maintenance of immune responses.

Pointing B cells in the right direction.

T cell receptors adapt by spacing out.

T cells have a light touch.

Bias in synapse stability leads to suppression of naive CD8 T cell activation by memory CD8 T cells during secondary responses

Dendritic cell-expressed common gamma-chain recruits IL-15 for trans-presentation at the murine immunological synapse.

Consortium biology in immunology: the perspective from the Immunological Genome Project.

Although the field has a long collaborative tradition, immunology has made less use than genetics of 'consortium biology', wherein groups of investigators together tackle large integrated questions or problems. However, immunology is naturally suited to large-scale integrative and systems-level approaches, owing to the multicellular and adaptive nature of the cells it encompasses. Here, we discuss the value and drawbacks of this organization of research, in the context of the long-running 'big science' debate, and consider the opportunities that may exist for the immunology community. We position this analysis in light of our own experience, both positive and negative, as participants of the Immunological Genome Project.

Erratum: Consortium biology in immunology: the perspective from the Immunological Genome Project

Tumor Necrosis Factor Receptor Superfamily in T Cell Priming and Effector Function.

The tumor necrosis factor receptor superfamily (TNFRSF) and their ligands mediate lymphoid tissue development and homeostasis in addition to key aspects of innate and adaptive immune responses. T cells of the adaptive immune system express a number of TNFRSF members that are used to receive signals at different instructive stages and produce several tumor necrosis factor superfamily (TNFSF) members as effector molecules. There is also one example of a TNFRSF member serving as a ligand for negative regulatory checkpoint receptors. In most cases, the ligands in afferent and efferent phases are membrane proteins and thus the interaction with TNFRSF members must take place in immunological synapses and other modes of cell-cell interaction. A particular feature of the TNFRSF-mediated signaling is the prominent use of linear ubiquitin chains as scaffolds for signaling complexes that activate nuclear factor κ-B and Fos/Jun transcriptional regulators. This review will focus on the signaling mechanisms triggered by TNFRSF members in their role as costimulators of early and late phases of T cell instruction and the delivery mechanism of TNFSF members through the immunological synapses of helper and cytotoxic effector cells.

Understanding the spatial and functional link between the IL-2R and TCR at the immunological synapse

Human CAR19 CD8+ iTreg exceed CAR19 CD8 CTLs both in suppressing GVHD lethality and eliminating CD19+ Nalm-6 lymphoma cells in vivo

Droplet-based synthetic cells provide fine-tuned biophysical cues for T cell expansion

Transcriptional programs define molecular characteristics of innate lymphoid cell classes and subsets.

The recognized diversity of innate lymphoid cells (ILCs) is rapidly expanding. Three ILC classes have emerged, ILC1, ILC2 and ILC3, with ILC1 and ILC3 including several subsets. The classification of some subsets is unclear, and it remains controversial whether natural killer (NK) cells and ILC1 cells are distinct cell types. To address these issues, we analyzed gene expression in ILCs and NK cells from mouse small intestine, spleen and liver, as part of the Immunological Genome Project. The results showed unique gene-expression patterns for some ILCs and overlapping patterns for ILC1 cells and NK cells, whereas other ILC subsets remained indistinguishable. We identified a transcriptional program shared by small intestine ILCs and a core ILC signature. We revealed and discuss transcripts that suggest previously unknown functions and developmental paths for ILCs.

Differential splicing across immune system lineages.

Alternative splicing (AS) allows increased diversity and orthogonal regulation of the transcriptional products of mammalian genomes. To assess the distribution and variation of alternative splicing across cell lineages of the immune system, we comprehensively analyzed RNA sequencing and microarray data generated by the Immunological Genome Project Consortium. AS is pervasive: 60% of genes showed frequent AS isoforms in T or B lymphocytes, with 7,599 previously unreported isoforms. Distinct cell specificity was observed, with differential exon skipping in 5% of genes otherwise coexpressed in both B and T cells. The distribution of isoforms was mostly all or none, suggesting on/off switching as a frequent mode of AS regulation in lymphocytes. From the identification of differential exon use in the microarray data, clustering of exon inclusion/exclusion patterns across all Immunological Genome Project cell types showed that ∼70% of AS exons are distributed along a common pattern linked to lineage differentiation and cell cycling. Other AS events distinguished myeloid from lymphoid cells or affected only a small set of exons without clear lineage specificity (e.g., Ptprc). Computational analysis predicted specific associations between AS exons and splicing regulators, which were verified by detection of the hnRPLL/Ptprc connection.

Magnesium for T cells: strong to the finish!

'Popeye, the Sailor' cartoons taught children that eating spinach boosts strength and helps defend against bullies. Lötscher and colleagues report that dietary deficiency of magnesium ions (Mg2+), against which eating spinach is an excellent antidote, impairs the activity of a key adhesion molecule, LFA-1, and hinders the ability of CD8+ T cells to grapple with assorted bullies, such as tumors and bacteria.

Recent advances in understanding TCR signaling: a synaptic perspective.

The T cell receptor is a multi-subunit complex that carries out a range of recognition tasks for multiple lymphocyte types and translates recognition into signals that regulate survival, growth, differentiation, and effector functions for innate and adaptive host defense. Recent advances include the cryo-electron microscopy-based structure of the extracellular and transmembrane components of the complex, new information about coupling to intracellular partners, lateral associations in the membrane that all add to our picture of the T cell signaling machinery, and how signal termination relates to effector function. This review endeavors to integrate structural and biochemical information through the lens of the immunological synapse- the critical interface with the antigen-presenting cell.

The CD58-CD2 axis in cancer immune evasion.

CD8 helps TCR catch slippery self pMHC.

Phagocytes Get Close to Their Enemies.

Phagocytosis is key for many organismal functions. In a recent issue of Cell, Freeman et al. (2016) demonstrate a feed-forward signaling mechanism wherein F-actin and integrin receptors drive contact formation between phagocytes and antibody-coated solid particles, signaling their engulfment. This mechanism translates nanoscale proximity effects into wider self-propagating signals.