Project description:CD8 T cell memory is characterized by rapid recall of effector function, increased proliferation, and reduced activation requirements. Despite the extensive functional characterization, the molecular mechanisms that facilitate these enhanced properties are not well characterized. In this study, the assay for transposase-accessible chromatin sequencing was employed to map the cis-regulatory elements in CD8 T cells responding to acute and chronic lymphocytic choriomeningitis virus infections. Integration of chromatin accessibility profiles with gene expression data identified unique regulatory modules that were enriched for distinct combinations of transcription factor-binding motifs. Memory CD8 T cells displayed a chromatin accessibility structure that was absent from other acute and exhausted cells types and included key effector and proliferative genes. Stimulation of memory cells revealed enhanced transcription of "memory-primed" genes compared with naive cells. Thus, memory CD8 T cells display a preprogrammed chromatin accessibility profile and maintain a molecular history of cis-element usage, thereby reducing the steps necessary to revive effector functions.

Project description:The paucity of murine memory B cell markers has been a significant impediment to the study of memory. The most commonly used marker is IgG, which is neither sensitive nor specific, because activated nonmemory cells can be IgG(+), and memory cells can be IgM(+). In this article, we show that, together, PD-L2 (CD273), CD80, and CD73 define at least five phenotypic subsets of murine memory B cells. These subsets are generated from naive cells bearing a single BCR in response to a single T-dependent Ag. This diversity is independent of class switch, because IgG(1)- and IgM-bearing memory cells are found within each compartment. Memory subsets defined by PD-L2, CD80, and CD73 are biologically distinct from one another, because they differ in ontogeny and selection. Together, these distinctions suggest that there is a spectrum of memory B cells and progressive acquisition from more naive-like to more memory-like properties.

Project description:During reinfection, high-affinity IgG Abs form complexes with both soluble Ag and Ag displayed on the surface of infected cells. These interactions regulate cellular activation of both innate cells and B cells, which express specific combinations of activating Fc?Rs (Fc?RI, Fc?RIII, Fc?RIV) and/or the inhibitory Fc?R (Fc?RIIB). Direct proof for functional expression of Fc?R by Ag-specific CD8 T cells is lacking. In this article, we show that the majority of memory CD8 T cells generated by bacterial or viral infection express only Fc?RIIB, and that Fc?RIIB could be detected on previously activated human CD8 T cells. Of note, Fc?R stimulation during in vivo Ag challenge not only inhibited the cytotoxicity of memory CD8 T cells against peptide-loaded or virus-infected targets, but Fc?RIIB blockade during homologous virus challenge enhanced the secondary CD8 T cell response. Thus, memory CD8 T cells intrinsically express a functional Fc?RIIB, permitting Ag-Ab complexes to regulate secondary CD8 T cell responses.

Project description:NK cells respond rapidly during viral infection. The development, function, and survival of NK cells are thought to be dependent on IL-15. In mice lacking IL-15, NK cells are found in severely decreased numbers. Surprisingly, following infection of IL-15- and IL-15Ralpha-deficient mice with mouse CMV, we measured a robust proliferation of Ly49H-bearing NK cells in lymphoid and nonlymphoid organs capable of cytokine secretion and cytolytic function. Remarkably, even in Rag2(-/-) x Il2rg(-/-) mice, a widely used model of NK cell deficiency, we detected a significant number of NK cells 1 wk after mouse CMV infection. In these mice we measured a >300-fold expansion of NK cells, which was dependent on recognition of the m157 viral glycoprotein ligand and IL-12. Together, these findings demonstrate a previously unrecognized independence of NK cells on IL-15 or other common gamma signaling cytokines during their response against viral infection.

Project description:The molecular mechanisms that regulate mature T cell fate and enable cells to differentiate into memory T cells are largely unknown. Memory T cells share certain key features with stem cells: they both have the ability to self-renew and are long-lived. The Wnt-?-catenin signaling pathway is a key player in regulating stem cell self-renewal and differentiation. We generated a conditional knockout mouse that specifically lacks ?-catenin in mature T cells and report in this article that ?-catenin is not involved in regulating effector versus memory T cell differentiation. ?-catenin-deficient memory T cells were phenotypically and functionally indistinguishable from control cells and made normal recall responses. ?-catenin deficiency does not affect T cell migration, T cell function in a model of chronic infection, or lymphopenia-induced proliferation. Together, our data suggest that self-renewal and differentiation are regulated differently in memory T cells compared with epithelial and hematopoietic stem cells.

Project description:The youngest peripheral T cells (recent thymic emigrants [RTEs]) are functionally distinct from naive T cells that have completed postthymic maturation. We assessed the RTE memory response and found that RTEs produced less granzyme B than their mature counterparts during infection but proliferated more and, therefore, generated equivalent target killing in vivo. Postinfection, RTE numbers contracted less dramatically than those of mature T cells, but RTEs were delayed in their transition to central memory, displaying impaired expression of CD62L, IL-2, Eomesodermin, and CXCR4, which resulted in impaired bone marrow localization. RTE-derived and mature memory cells expanded equivalently during rechallenge, indicating that the robust proliferative capacity of RTEs was maintained independently of central memory phenotype. Thus, the diminished effector function and delayed central memory differentiation of RTE-derived memory cells are counterbalanced by their increased proliferative capacity, driving the efficacy of the RTE response to that of mature T cells.

Project description:Tissue-resident memory T (TRM) cells serve as vanguards of antimicrobial host defense in nonlymphoid tissues, particularly at barrier epithelia and in organs with nonrenewable cell types (e.g., brain). In this study, we asked whether an augmented ability to sense Ag complemented their role as early alarms of pathogen invasion. Using mouse polyomavirus, we show that brain-resident mouse polyomavirus-specific CD8 T cells, unlike memory cells in the spleen, progressively increase binding to MHC class I tetramers and CD8 coreceptor expression. Using the two-dimensional micropipette adhesion-frequency assay, we show that TRM cells in brain, as well as in kidney, express TCRs with up to 20-fold higher affinity than do splenic memory T cells, whereas effector cells express TCRs of similar high affinity in all organs. Together, these data demonstrate that TRM cells retain high TCR affinity, which endows them with the high Ag sensitivity needed for front-line defense against infectious agents.

Project description:Sensitized recipients with pretransplant donor-specific Abs are at higher risk for Ab-mediated rejection than nonsensitized recipients, yet little is known about the properties of memory B cells that are central to the recall alloantibody responses. Using cell enrichment and MHC class I tetramers, C57BL/6 mice sensitized with BALB/c splenocytes were shown to harbor H-2K(d)-specific IgG(+) memory B cells with a post-germinal center phenotype (CD73(+)CD273(+)CD38(hi)CD138(-)GL7(-)). These memory B cells adoptively transferred into naive mice without memory T cells recapitulated class-switched recall alloantibody responses. During recall, memory H-2K(d)-specific B cells preferentially differentiated into Ab-secreting cells, whereas in the primary response, H-2K(d)-specific B cells differentiated into germinal center cells. Finally, our studies revealed that, despite fundamental differences in alloreactive B cell fates in sensitized versus naive recipients, CTLA-4Ig was unexpectedly effective at constraining B cell responses and heart allograft rejection in sensitized recipients.

Project description:Because NK cells lack gene-recombination machinery and are thought to be relatively short-lived, it is unclear whether NK cells can mount long-term effective recall responses to reinfections by diverse pathogens. In this article, we report that FcR?-deficient NK cells, which we recently identified and termed g(-)NK cells, possess distinct memory features directed by FcR-mediated Ab-dependent target recognition. The presence of g(-)NK cells was associated with prior human CMV (HMCV) infection, yet g(-)NK cell responses were not restricted to HCMV-infected target cells. In the presence of virus-specific Abs, g(-)NK cells had greatly enhanced functional capabilities, superior to conventional NK cells, and were highly responsive to cells infected with either HCMV or HSV-1. Remarkably, the g(-)NK cell subset persisted long-term at nearly constant levels in healthy individuals. Therefore, FcR? deficiency distinguishes an Ab-dependent memory-like NK cell subset with enhanced potential for broad antiviral responses.

Project description:CD8(+) T cells responding to intracellular infection give rise to cellular progeny that become terminally differentiated effector cells and self-renewing memory cells. T-bet and eomesodermin (Eomes) are key transcription factors of cytotoxic lymphocyte lineages. We show in this study that CD8(+) T cells lacking Eomes compete poorly in contributing to the pool of Ag-specific central memory cells. Eomes-deficient CD8(+) T cells undergo primary clonal expansion but are defective in long-term survival, populating the bone marrow niche and re-expanding postrechallenge. The phenotype of Eomes-deficient CD8(+) T cells supports the hypothesis that T-bet and Eomes can act redundantly to induce effector functions, but can also act to reciprocally promote terminal differentiation versus self-renewal of Ag-specific memory cells.