David Coe

In Vitro Expansion Improves In Vivo Regulation by CD4+CD25+ Regulatory T Cells

CD4+CD25+ T regulatory cells (Tregs) can actively suppress immune responses and thus have substantial therapeutical potential. Clinical application is, however, frustrated by their scarcity, anergic status, and lack of defined specificity. We found that a single injection of a small number of expanded but not fresh HY-specific Tregs protected syngeneic male skin grafts from rejection by immune-competent recipients. The expanded Tregs were predominantly located in the grafts and graft-draining lymph nodes. In vitro expanded Tregs displayed a phenotype of CD25highCD4lowFoxp3+CTLA4+, and also up-regulated IL10 and TGFβ while down-regulating IFN-γ, GM-CSF, IL5, and TNF-α production. Furthermore, expanded Tregs appeared to express a reduced level of Foxp3, which could be prevented by adding TGFβ to the culture, and they also tended to lose Foxp3 following the repeated stimulation. Finally, a proportion of expanded HY-specific Tregs secreted IL2 in response to their cognate peptide, and this finding could be confirmed using Tregs from Foxp3GFP reporter mice. We not only demonstrated that expanded Tregs are superior to fresh Tregs in suppressing T cell responses against alloantigens, but also revealed some novel immunobiological properties of expended Tregs which are very instructive for modifying current Treg expansion procedures.

Ig gene-like molecule CD31 plays a nonredundant role in the regulation of T-cell immunity and tolerance

CD31 is an Ig-like molecule expressed by leukocytes and endothelial cells with an established role in the regulation of leukocyte trafficking. Despite genetic deletion of CD31 being associated with exacerbation of T cell-mediated autoimmunity, the contribution of this molecule to T-cell responses is largely unknown. Here we report that tumor and allograft rejection are significantly enhanced in CD31-deficient mice, which are also resistant to tolerance induction. We propose that these effects are dependent on an as yet unrecognized role for CD31-mediated homophilic interactions between T cells and antigen-presenting cells (APCs) during priming. We show that loss of CD31 interactions leads to enhanced primary clonal expansion, increased killing capacity, and diminished regulatory functions by T cells. Immunomodulation by CD31 signals correlates with a partial inhibition of proximal T-cell receptor (TCR) signaling, specifically Zap-70 phosphorylation. However, CD31-deficient mice do not develop autoimmunity due to increased T-cell death following activation, and we show that CD31 triggering induces Erk-mediated prosurvival activity in T cells either in conjunction with TCR signaling or autonomously. We conclude that CD31 functions as a nonredundant comodulator of T-cell responses, which specializes in sizing the ensuing immune response by setting the threshold for T-cell activation and tolerance, while preventing memory T-cell death.

Self-recognition of the endothelium enables regulatory T-cell trafficking and defines the kinetics of immune regulation

Localization of CD4+CD25+Foxp3+ regulatory T (Treg) cells to lymphoid and non-lymphoid tissue is instrumental for the effective control of immune responses. Compared with conventional T cells, Treg cells constitute a minute fraction of the T-cell repertoire. Despite this numeric disadvantage, Tregs efficiently migrate to sites of immune responses reaching an optimal number for the regulation of T effector (Teff) cells. The array and levels of adhesion and chemokine receptor expression by Tregs do not explain their powerful migratory capacity. Here we show that recognition of self-antigens expressed by endothelial cells in target tissue is instrumental for efficient Treg recruitment in vivo. This event relies upon IFN-γ-mediated induction of MHC-class-II molecule expression by the endothelium and requires optimal PI3K p110δ activation by the T-cell receptor. We also show that, once in the tissue, Tregs inhibit Teff recruitment, further enabling a Teff:Treg ratio optimal for regulation.

Enhanced activation of an amino-terminally truncated isoform of the voltage-gated proton channel HVCN1 enriched in malignant B cells.

Significance B lymphocytes are crucial cells in immune responses. Their activity is regulated by signaling pathways involving reactive oxygen species (ROS). Voltage-gated proton channels modulate B-cell responses by facilitating production of ROS. Here we compare the full-length proton channel HVCN1L with a shorter protein isoform, HVCN1S, which lacks the first 20 amino acids. Cells with HVCN1S display enhanced proton currents upon stimulation. In addition, HVCN1S is internalized to a lesser extent by interactions with the B-cell receptor, resulting in greater plasma membrane expression. Finally, HVCN1S expression results in greater proliferation and migration. Compared with normal B lymphocytes, HVCN1S expression is higher in B-cell lines and in B cells from patients with chronic lymphocytic leukemia, where it may contribute to disease pathogenesis. HVCN1 (Hydrogen voltage-gated channel 1) is the only mammalian voltage-gated proton channel. In human B lymphocytes, HVCN1 associates with the B-cell receptor (BCR) and is required for optimal BCR signaling and redox control. HVCN1 is expressed in malignant B cells that rely on BCR signaling, such as chronic lymphocytic leukemia (CLL) cells. However, little is known about its regulation in these cells. We found that HVCN1 was expressed in B cells as two protein isoforms. The shorter isoform (HVCN1S) was enriched in B cells from a cohort of 76 CLL patients. When overexpressed in a B-cell lymphoma line, HVCN1S responded more profoundly to protein kinase C-dependent phosphorylation. This more potent enhanced gating response was mediated by increased phosphorylation of the same residue responsible for enhanced gating in HVCN1L, Thr29. Furthermore, the association of HVCN1S with the BCR was weaker, which resulted in its diminished internalization upon BCR stimulation. Finally, HVCN1S conferred a proliferative and migratory advantage as well as enhanced BCR-dependent signaling. Overall, our data show for the first time, to our knowledge, the existence of a shorter isoform of HVCN1 with enhanced gating that is specifically enriched in malignant B cells. The properties of HVCN1S suggest that it may contribute to the pathogenesis of BCR-dependent B-cell malignancies.

Hepatocyte Growth Factor Receptor c-Met Instructs T Cell Cardiotropism and Promotes T Cell Migration to the Heart via Autocrine Chemokine Release.

Summary Effector-T-cell-mediated immunity depends on the efficient localization of antigen-primed lymphocytes to antigen-rich non-lymphoid tissue, which is facilitated by the expression of a unique set of “homing” receptors acquired by memory T cells. We report that engagement of the hepatocyte growth factor (HGF) receptor c-Met by heart-produced HGF during priming in the lymph nodes instructs T cell cardiotropism, which was associated with a specialized homing “signature” (c-Met+CCR4+CXCR3+). c-Met signals facilitated T cell recruitment to the heart via the chemokine receptor CCR5 by inducing autocrine CCR5 ligand release. c-Met triggering was sufficient to support cardiotropic T cell recirculation, while CCR4 and CXCR3 sustained recruitment during heart inflammation. Transient pharmacological blockade of c-Met during T cell priming led to enhanced survival of heart, but not skin, allografts associated with impaired localization of alloreactive T cells to heart grafts. These findings suggest c-Met as a target for development of organ-selective immunosuppressive therapies.

Metabolic Regulation of Regulatory T Cell Development and Function

It is now well established that the effector T cell (Teff) response is regulated by a series of metabolic switches. Quiescent T cells predominantly require adenosine triphosphate-generating processes, whereas proliferating Teff require high metabolic flux through growth-promoting pathways, such as glycolysis. Pathways that control metabolism and immune cell function are intimately linked, and changes in cell metabolism at both the cell and system levels have been shown to enhance or suppress specific T cell effector functions. Furthermore, functionally distinct T cell subsets require distinct energetic and biosynthetic pathways to support their specific functional needs. In particular, naturally occurring regulatory T cells (Treg) are characterized by a unique metabolic signature distinct to that of conventional Teff cells. We here briefly review the signaling pathways that control Treg metabolism and how this metabolic phenotype integrates their differentiation and function. Ultimately, these metabolic features may provide new opportunities for the therapeutic modulation of unwanted immune responses.

Obesity-induced metabolic stress leads to biased effector memory CD4+ T cell differentiation via PI3K p110δ/Akt-mediated signals

Summary Low-grade systemic inflammation associated to obesity leads to cardiovascular complications, caused partly by infiltration of adipose and vascular tissue by effector T cells. The signals leading to T cell differentiation and tissue infiltration during obesity are poorly understood. We tested whether saturated fatty acid-induced metabolic stress affects differentiation and trafficking patterns of CD4+ T cells. Memory CD4+ T cells primed in high-fat diet-fed donors preferentially migrated to non-lymphoid, inflammatory sites, independent of the metabolic status of the hosts. This was due to biased CD4+ T cell differentiation into CD44hi-CCR7lo-CD62Llo-CXCR3+-LFA1+ effector memory-like T cells upon priming in high-fat diet-fed animals. Similar phenotype was observed in obese subjects in a cohort of free-living people. This developmental bias was independent of any crosstalk between CD4+ T cells and dendritic cells and was mediated via direct exposure of CD4+ T cells to palmitate, leading to increased activation of a PI3K p110δ-Akt-dependent pathway upon priming.

Regulatory T Cell Migration Is Dependent on Glucokinase-Mediated Glycolysis

SUMMARY Migration of activated regulatory T (Treg) cells to inflamed tissue is crucial for their immune‐modulatory function. While metabolic reprogramming during Treg cell differentiation has been extensively studied, the bioenergetics of Treg cell trafficking remains undefined. We have investigated the metabolic demands of migrating Treg cells in vitro and in vivo. We show that glycolysis was instrumental for their migration and was initiated by pro‐migratory stimuli via a PI3K‐mTORC2‐mediated pathway culminating in induction of the enzyme glucokinase (GCK). Subsequently, GCK promoted cytoskeletal rearrangements by associating with actin. Treg cells lacking this pathway were functionally suppressive but failed to migrate to skin allografts and inhibit rejection. Similarly, human carriers of a loss‐of‐function GCK regulatory protein gene—leading to increased GCK activity—had reduced numbers of circulating Treg cells. These cells displayed enhanced migratory activity but similar suppressive function, while conventional T cells were unaffected. Thus, GCK‐dependent glycolysis regulates Treg cell migration. HIGHLIGHTSMigration of regulatory T (Treg) cells requires glycolysisThis is mediated by the enzyme glucokinase induced by a PI3K‐mTORC2 pathwayTreg cells lacking this pathway are unable to localize to inflammatory sitesA loss‐of‐function GCK regulator gene causes enhanced motility of human Treg cells Regulatory T cell localization to inflammatory sites is key to their homeostatic function. Kishore and colleagues demonstrate that Treg cell migration requires the activation of glycolysis by the enzyme glucokinase induced via a Treg cell‐selective PI3K‐mTORC2 pathway.

CD31 signals confer immune privilege to the vascular endothelium

Significance Maintenance of vascular integrity during effector immune responses occurring in tissues is a prerequisite of a healthy immune response. The mechanism whereby the vascular endothelium remains undamaged while interacting with effector immune cells migrating to the site of inflammation is largely unknown. This study shows that signals mediated by CD31, a trans-homophilic receptor expressed at high levels by the endothelium, are both necessary and sufficient to prevent inflammation-induced endothelial cell death and confer immune privilege to the vascular endothelium. We also provide proof of principle that this property can be harnessed therapeutically in pancreatic β-cell transplantation, whereby CD31 gene transfer alone endows allogeneic targets with indefinite resistance to immune attack in vivo. Constitutive resistance to cell death induced by inflammatory stimuli activating the extrinsic pathway of apoptosis is a key feature of vascular endothelial cells (ECs). Although this property is central to the maintenance of the endothelial barrier during inflammation, the molecular mechanisms of EC protection from cell-extrinsic, proapoptotic stimuli have not been investigated. We show that the Ig-family member CD31, which is expressed by endothelial but not epithelial cells, is necessary to prevent EC death induced by TNF-α and cytotoxic T lymphocytes in vitro. Combined quantitative RT-PCR array and biochemical analysis show that, upon the engagement of the TNF receptor with TNF-α on ECs, CD31 becomes activated and, in turn, counteracts the proapoptotic transcriptional program induced by TNF-α via activation of the Erk/Akt pathway. Specifically, Akt activation by CD31 signals prevents the localization of the forkhead transcription factor FoxO3 to the nucleus, thus inhibiting transcription of the proapoptotic genes CD95/Fas and caspase 7 and de-repressing the expression of the antiapoptotic gene cFlar. Both CD31 intracellular immunoreceptor tyrosine-based inhibition motifs are required for its prosurvival function. In vivo, CD31 gene transfer is sufficient to recapitulate the cytoprotective mechanisms in CD31− pancreatic β cells, which become resistant to immune-mediated rejection when grafted in fully allogeneic recipients.

Molecular Mechanisms of induction of antigen-specific allograft tolerance by intranasal peptide administration

We have previously shown that intranasal (i.n.) administration of a single MHC class II-restricted HY peptide to female mice induces tolerance to up to five additional epitopes expressed on test male grafts, a phenomenon known as linked suppression. In this study, we investigated the molecular mechanisms involved both in the induction phase following peptide administration and during linked suppression after grafting. We report that following initial i.n. administration, peptide is widely disseminated and is presented by functionally immature dendritic cells. These fail to cause optimal stimulation of the responding HY-specific CD4+ T cells that express genes characteristic of regulatory T cells. Following i.n. peptide plus LPS administration, causing immunization, HY-specific CD4+ T cells express genes characteristic of activated T cells. We further find that following male skin grafting, HY-specific CD8+ T cells from peptide-treated tolerant mice display both quantitative and qualitative differences compared with similar cells from untreated mice that reject their grafts. In tolerant mice there are fewer HY-specific CD8+ cells and they express several genes characteristic of exhausted T cells. Furthermore, associated with specific chemokine receptor and integrin expression, HY-specific CD8+ T cells show more limited migration from the graft draining lymph node into other tissues.