Imaging regulatory T cell dynamics and CTLA4-mediated suppression of T cell priming

Foxp3(+) regulatory T cells (Tregs) maintain immune homoeostasis through mechanisms that remain incompletely defined. Here by two-photon (2P) imaging, we examine the cellular dynamics of endogenous Tregs. Tregs are identified as two non-overlapping populations in the T-zone and follicular regions of the lymph node (LN). In the T-zone, Tregs migrate more rapidly than conventional T cells (Tconv), extend longer processes and interact with resident dendritic cells (DC) and Tconv. Tregs intercept immigrant DCs and interact with antigen-induced DC: Tconv clusters, while continuing to form contacts with activated Tconv. During antigen-specific responses, blocking CTLA4-B7 interactions reduces Treg-Tconv interaction times, increases the volume of DC: Tconv clusters and enhances subsequent Tconv proliferation in vivo. Our results demonstrate a role for altered cellular choreography of Tregs through CTLA4-based interactions to limit T-cell priming

Polymodal K+ channel modulation contributes to dual analgesic and anti-inflammatory actions of traditional botanical medicines.

Pain and inflammation contribute immeasurably to reduced quality of life, yet modern analgesic and anti-inflammatory therapeutics can cause dependence and side effects. Here, we screened 1444 plant extracts, prepared primarily from native species in California and the United States Virgin Islands, against two voltage-gated K+ channels - T-cell expressed Kv1.3 and nociceptive-neuron expressed Kv7.2/7.3. A subset of extracts both inhibits Kv1.3 and activates Kv7.2/7.3 at hyperpolarized potentials, effects predicted to be anti-inflammatory and analgesic, respectively. Among the top dual hits are witch hazel and fireweed; polymodal modulation of multiple K+ channel types by hydrolysable tannins contributes to their dual anti-inflammatory, analgesic actions. In silico docking and mutagenesis data suggest pore-proximal extracellular linker sequence divergence underlies opposite effects of hydrolysable tannins on different Kv1 isoforms. The findings provide molecular insights into the enduring, widespread medicinal use of witch hazel and fireweed and demonstrate a screening strategy for discovering dual anti-inflammatory, analgesic small molecules

Modulation de la réponse immunitaire par les immunoglobulines intraveineuses : effets sur la polarisation, la pathogénicité et le trafic des lymphocytes T

Dysregulated activation of T cells leads to pathogenic immune response to self-antigens. Despite an increasing use of high dose therapy of intravenous gammaglobulin (IVIg) in the treatment of T-cell and autoantibody-mediated inflammatory and autoimmune diseases, comprehension of the mechanisms underlying its therapeutic benefit has remained a major challenge. Particularly, the effect of IVIg in T cell mediated autoimmune conditions remains unexplored. I have investigated the effect of high dose IVIg on T cell polarization using actively induced experimental autoimmune encephalomyelitis (EAE), a T cell-mediated autoimmune condition. IVIg inhibits the differentiation of naïve CD4 T cells into effector subsets (Th1 and Th17 cells) and concomitantly induces an expansion of Foxp3+ regulatory cells. IVIg decreases the tissue damaging potential of pathogenic T cells by down regulating GM-CSF and podoplanin. Additionally, IVIg circumvents the neuronal damage by inhibiting the infiltration of CD4 T lymphocytes to the central nervous system by restraining their egress from the DLN through S1P-S1P1-mTOR pathway. Intriguingly and contrary to the current arguments, the inhibitory FcγRIIB and sialylation of IgG are dispensable for IVIg-mediated reciprocal modulation of effector and regulatory CD4 subsets. Altogether, therapeutic benefit of IVIg in EAE involves shifting the balance from Th17/Th1 towards Treg, down-regulating encephalitogenic mediators and inhibition of T cell trafficking to the target organ.L'activation dérégulée de lymphocytes T conduit à une réponse immune délétère envers les antigènes du soi. Malgré une utilisation croissante de doses élevées d'IVIg pour traiter les maladies auto-immunes, la compréhension des mécanismes sous-jacents aux bénéfices thérapeutiques demeure un enjeu majeur. En effet, les effets des IVIg restent inexplorés dans le cadre des maladies auto-immunes associées aux lymphocytes T. J'ai recherché les effets de doses élevées d'IVIg dans la polarisation des lymphocytes T en utilisant le modèle de l'encéphalomyélite auto-immune expérimentale (EAE), une maladie auto-immune associée aux lymphocytes T. Les IVIg inhibent la différenciation des lymphocytes T CD4+ naïfs en sous-populations effectrices (lymphocytes Th1 et Th17) et induisent, de manière concomitante, une prolifération des lymphocytes T Foxp3+. Les IVIg diminuent les effets délétères des lymphocytes T sur les tissus en diminuant l'expression du GM-CSF et de la podoplanine. En outre, les IVIg empêchent la dégénérescence neuronale en inhibant l'infiltrat en lymphocytes T CD4+ dans le système nerveux central (SNC). Ce mécanisme passe par une séquestration de ces lymphocytes dans les ganglions lymphatiques drainants à travers la voie de signalisation S1P-S1P1-mTor. De manière intéressante, et contrairement aux données actuelles, le récepteur inhibiteur FcγRIIB et la sialylation des IVIg ne sont pas indispensables pour la modulation des sous-populations de lymphocytes T CD4+ effecteurs et régulateurs induite par les IVIg. Ainsi, le bénéfice thérapeutique des IVIg dans le modèle de l'EAE implique un déséquilibre de la balance entre les lymphocytes Th17/Th1 et les lymphocytes Trég, au profit des lymphocytes Trég. Ces cellules diminuent l'expression de médiateurs favorisant l'apparition de l'encéphalomyélite et inhibent la migration des lymphocytes T vers l'organe cible

Intervenous immunoglobulins as modulators of immune response (effect on T cell polarisation, pathogenicity and trafficking)

L activation dérégulée de lymphocytes T conduit à une réponse immune délétère envers les antigènes du soi. Malgré une utilisation croissante de doses élevées d IVIg pour traiter les maladies auto-immunes, la compréhension des mécanismes sous-jacents aux bénéfices thérapeutiques demeure un enjeu majeur. En effet, les effets des IVIg restent inexplorés dans le cadre des maladies auto-immunes associées aux lymphocytes T. J ai recherché les effets de doses élevées d IVIg dans la polarisation des lymphocytes T en utilisant le modèle de l encéphalomyélite auto-immune expérimentale (EAE), une maladie auto-immune associée aux lymphocytes T. Les IVIg inhibent la différenciation des lymphocytes T CD4+ naïfs en sous-populations effectrices (lymphocytes Th1 et Th17) et induisent, de manière concomitante, une prolifération des lymphocytes T Foxp3+. Les IVIg diminuent les effets délétères des lymphocytes T sur les tissus en diminuant l expression du GM-CSF et de la podoplanine. En outre, les IVIg empêchent la dégénérescence neuronale en inhibant l infiltrat en lymphocytes T CD4+ dans le système nerveux central (SNC). Ce mécanisme passe par une séquestration de ces lymphocytes dans les ganglions lymphatiques drainants à travers la voie de signalisation S1P-S1P1-mTor. De manière intéressante, et contrairement aux données actuelles, le récepteur inhibiteur FcgRIIB et la sialylation des IVIg ne sont pas indispensables pour la modulation des sous-populations de lymphocytes T CD4+ effecteurs et régulateurs induite par les IVIg. Ainsi, le bénéfice thérapeutique des IVIg dans le modèle de l EAE implique un déséquilibre de la balance entre les lymphocytes Th17/Th1 et les lymphocytes Trég, au profit des lymphocytes Trég. Ces cellules diminuent l expression de médiateurs favorisant l apparition de l encéphalomyélite et inhibent la migration des lymphocytes T vers l organe cibleDysregulated activation of T cells leads to pathogenic immune response to self-antigens. Despite an increasing use of high dose therapy of intravenous gammaglobulin (IVIg) in the treatment of T-cell and autoantibody-mediated inflammatory and autoimmune diseases, comprehension of the mechanisms underlying its therapeutic benefit has remained a major challenge. Particularly, the effect of IVIg in T cell mediated autoimmune conditions remains unexplored. I have investigated the effect of high dose IVIg on T cell polarization using actively induced experimental autoimmune encephalomyelitis (EAE), a T cell-mediated autoimmune condition. IVIg inhibits the differentiation of naïve CD4 T cells into effector subsets (Th1 and Th17 cells) and concomitantly induces an expansion of Foxp3+ regulatory cells. IVIg decreases the tissue damaging potential of pathogenic T cells by down regulating GM-CSF and podoplanin. Additionally, IVIg circumvents the neuronal damage by inhibiting the infiltration of CD4 T lymphocytes to the central nervous system by restraining their egress from the DLN through S1P-S1P1-mTOR pathway. Intriguingly and contrary to the current arguments, the inhibitory FcgRIIB and sialylation of IgG are dispensable for IVIg-mediated reciprocal modulation of effector and regulatory CD4 subsets. Altogether, therapeutic benefit of IVIg in EAE involves shifting the balance from Th17/Th1 towards Treg, down-regulating encephalitogenic mediators and inhibition of T cell trafficking to the target organPARIS-BIUSJ-Biologie recherche (751052107) / SudocSudocFranceF

Immunomodulation by Intravenous Immunoglobulin: Role of Regulatory T Cells

International audienc

Intravenous Gammaglobulin Inhibits Encephalitogenic Potential of Pathogenic T Cells and Interferes with their Trafficking to the Central Nervous System, Implicating Sphingosine-1 Phosphate Receptor 1–Mammalian Target of Rapamycin Axis

International audienc

Effect of IVIg on human dendritic cell-mediated antigen uptake and presentation: Role of lipid accumulation

International audienc

T-cell calcium dynamics visualized in a ratiometric tdTomato-GCaMP6f transgenic reporter mouse.

Calcium is an essential cellular messenger that regulates numerous functions in living organisms. Here, we describe development and characterization of 'Salsa6f', a fusion of GCaMP6f and tdTomato optimized for cell tracking while monitoring cytosolic Ca2+, and a transgenic Ca2+ reporter mouse with Salsa6f targeted to the Rosa26 locus for Cre-dependent expression in specific cell types. The development and function of T cells was unaffected in Cd4-Salsa6f mice. We describe Ca2+ signals reported by Salsa6f during T cell receptor activation in naive T cells, helper Th17 T cells and regulatory T cells, and Ca2+ signals mediated in T cells by an activator of mechanosensitive Piezo1 channels. Transgenic expression of Salsa6f enables ratiometric imaging of Ca2+ signals in complex tissue environments found in vivo. Two-photon imaging of migrating T cells in the steady-state lymph node revealed both cell-wide and localized sub-cellular Ca2+ transients ('sparkles') as cells migrate

T-cell calcium dynamics visualized in a ratiometric tdTomato-GCaMP6f transgenic reporter mouse.

Calcium is an essential cellular messenger that regulates numerous functions in living organisms. Here, we describe development and characterization of 'Salsa6f', a fusion of GCaMP6f and tdTomato optimized for cell tracking while monitoring cytosolic Ca2+, and a transgenic Ca2+ reporter mouse with Salsa6f targeted to the Rosa26 locus for Cre-dependent expression in specific cell types. The development and function of T cells was unaffected in Cd4-Salsa6f mice. We describe Ca2+ signals reported by Salsa6f during T cell receptor activation in naive T cells, helper Th17 T cells and regulatory T cells, and Ca2+ signals mediated in T cells by an activator of mechanosensitive Piezo1 channels. Transgenic expression of Salsa6f enables ratiometric imaging of Ca2+ signals in complex tissue environments found in vivo. Two-photon imaging of migrating T cells in the steady-state lymph node revealed both cell-wide and localized sub-cellular Ca2+ transients ('sparkles') as cells migrate