Fiona M. McConnell

RANK signals from CD4+3− inducer cells regulate development of Aire-expressing epithelial cells in the thymic medulla

Aire-expressing medullary thymic epithelial cells (mTECs) play a key role in preventing autoimmunity by expressing tissue-restricted antigens to help purge the emerging T cell receptor repertoire of self-reactive specificities. Here we demonstrate a novel role for a CD4+3− inducer cell population, previously linked to development of organized secondary lymphoid structures and maintenance of T cell memory in the functional regulation of Aire-mediated promiscuous gene expression in the thymus. CD4+3− cells are closely associated with mTECs in adult thymus, and in fetal thymus their appearance is temporally linked with the appearance of Aire+ mTECs. We show that RANKL signals from this cell promote the maturation of RANK-expressing CD80−Aire− mTEC progenitors into CD80+Aire+ mTECs, and that transplantation of RANK-deficient thymic stroma into immunodeficient hosts induces autoimmunity. Collectively, our data reveal cellular and molecular mechanisms leading to the generation of Aire+ mTECs and highlight a previously unrecognized role for CD4+3−RANKL+ inducer cells in intrathymic self-tolerance.

CD4+CD3− Accessory Cells Costimulate Primed CD4 T Cells through OX40 and CD30 at Sites Where T Cells Collaborate with B Cells

In this report we identify an accessory cell that interacts with primed and memory T cells at sites where they collaborate with B cells. These cells are distinguished from conventional dendritic cells by their lack of response to Flt3 ligand and their inability to process antigen. Unlike dendritic cells, the CD4(+)CD3(-) cells have little CD80 or CD86 expression but do express high levels of the TNF ligands, OX40 ligand and CD30 ligand. We show that Th2-primed cells express the receptors for these TNF ligands and preferentially survive when cocultured with these cells. Furthermore, we show that the preferential survival of OX40(+) T cells and support of memory T cell help for B cells are linked to their association with CD4(+)CD3(-) cells in vivo.

Immune tolerance. Group 3 innate lymphoid cells mediate intestinal selection of commensal bacteria-specific CD4⁺ T cells.

Innate lymphoid cells keep gut T cells in check Trillions of bacteria inhabit our guts. So do many types of immune cells, including T cells, which might be expected to attack these bacteria. How, then, do our bodies manage to keep the peace? Working in mice, Hepworth et al. report one such mechanism. A population of immune cells, called innate lymphoid cells, directly killed CD4+ T cells that react to commensal gut microbes. Some of the specifics of this process parallel how the immune system keeps developing self-reactive T cells in check in the thymus. Furthermore, this peacekeeping process may be disrupted in children with inflammatory bowel disease. Science, this issue p. 1031 Innate lymphoid cells delete commensal bacteria–specific CD4+ T cells from the intestine in mice. Inflammatory CD4+ T cell responses to self or commensal bacteria underlie the pathogenesis of autoimmunity and inflammatory bowel disease (IBD), respectively. Although selection of self-specific T cells in the thymus limits responses to mammalian tissue antigens, the mechanisms that control selection of commensal bacteria–specific T cells remain poorly understood. Here, we demonstrate that group 3 innate lymphoid cell (ILC3)–intrinsic expression of major histocompatibility complex class II (MHCII) is regulated similarly to thymic epithelial cells and that MHCII+ ILC3s directly induce cell death of activated commensal bacteria–specific T cells. Further, MHCII on colonic ILC3s was reduced in pediatric IBD patients. Collectively, these results define a selection pathway for commensal bacteria–specific CD4+ T cells in the intestine and suggest that this process is dysregulated in human IBD.

Mice Deficient in OX40 and CD30 Signals Lack Memory Antibody Responses because of Deficient CD4 T Cell Memory

Recently, we reported that a CD4+CD3−CD11c− accessory cell provided OX40-dependent survival signals to follicular T cells. These accessory cells express both OX40 ligand and CD30 ligand, and the receptors, OX40 and CD30, are both expressed on Th2-primed CD4 T cells. OX40 and CD30 signals share common signaling pathways, suggesting that CD30 signals might substantially compensate in OX40-deficient mice. In this report we have dissected the signaling roles of CD30 alone and in combination with OX40. CD30-deficient mice showed an impaired capacity to sustain follicular germinal center responses, and recall memory Ab responses were substantially reduced. Deficiencies in OX40 and CD30 signals were additive; secondary Ab responses were ablated in double-deficient mice. Although the initial proliferation of OX40/CD30 double-knockout OTII transgenic T cells was comparable to that of their normal counterparts, they failed to survive in vivo, and this was associated with reduced T cell numbers associated with CD4+CD3− cells in B follicles. Finally, we show that OX40/CD30 double-knockout OTII transgenic T cells fail to survive compared with normal T cells when cocultured with CD4+CD3− cells in vitro.

Rank Signaling Links the Development of Invariant γδ T Cell Progenitors and Aire+ Medullary Epithelium

Summary The thymic medulla provides a specialized microenvironment for the negative selection of T cells, with the presence of autoimmune regulator (Aire)-expressing medullary thymic epithelial cells (mTECs) during the embryonic-neonatal period being both necessary and sufficient to establish long-lasting tolerance. Here we showed that emergence of the first cohorts of Aire+ mTECs at this key developmental stage, prior to αβ T cell repertoire selection, was jointly directed by Rankl+ lymphoid tissue inducer cells and invariant Vγ5+ dendritic epidermal T cell (DETC) progenitors that are the first thymocytes to express the products of gene rearrangement. In turn, generation of Aire+ mTECs then fostered Skint-1-dependent, but Aire-independent, DETC progenitor maturation and the emergence of an invariant DETC repertoire. Hence, our data attributed a functional importance to the temporal development of Vγ5+ γδ T cells during thymus medulla formation for αβ T cell tolerance induction and demonstrated a Rank-mediated reciprocal link between DETC and Aire+ mTEC maturation.

Neonatal and Adult CD4+CD3− Cells Share Similar Gene Expression Profile, and Neonatal Cells Up-Regulate OX40 Ligand in Response to TL1A (TNFSF15)

We report here the quantitative expression of a set of immunity-related genes, including TNF family members, chemokine receptors, and transcription factors, in a CD4+CD3− accessory cell. By correlating gene expression between cell-sorted populations of defined phenotype, we show that the genetic fingerprint of these CD4+CD3− cells is distinct from dendritic cells, plasmacytoid dendritic cells, T cells, B cells, and NK cells. In contrast, it is highly similar to CD4+CD3− cells isolated from embryonic and neonatal tissues, with the exception that only adult populations express OX40L and CD30L. We have previously reported that IL-7 signals regulate CD30L expression. In the present study, we show that both neonatal and adult CD4+CD3− cells express the TNF family member, death receptor 3 (TNFRSF25), and that addition of TL1A (TNFSF15), the ligand for death receptor 3, up-regulates OX40L on neonatal CD4+CD3− cells. Finally, we demonstrate that this differentiation occurs in vivo: neonatal CD4+CD3− cells up-regulate both CD30L and OX40L after adoptive transfer into an adult recipient.

Cutting Edge: Lymphoid Tissue Inducer Cells Maintain Memory CD4 T Cells within Secondary Lymphoid Tissue

Phylogeny shows that CD4 T cell memory and lymph nodes coevolved in placental mammals. In ontogeny, retinoic acid orphan receptor (ROR)γ-dependent lymphoid tissue inducer (LTi) cells program the development of mammalian lymph nodes. In this study, we show that although primary CD4 T cell expansion is normal in RORγ-deficient mice, the persistence of memory CD4 T cells is RORγ-dependent. Furthermore, using bone marrow chimeric mice we demonstrate that LTi cells are the key RORγ-expressing cell type sufficient for memory CD4 T cell survival in the absence of persistent Ag. This effect was specific for CD4 T cells, as memory CD8 T cells survived equally well in the presence or absence of LTi cells. These data demonstrate a novel role for LTi cells, archetypal members of the innate lymphoid cell family, in supporting memory CD4 T cell survival in vivo.

Heterogeneity of lymphoid tissue inducer cell populations present in embryonic and adult mouse lymphoid tissues

Lymphoid tissue inducer (LTi) cells have a well established role in secondary lymphoid tissue development. Here, we report on the heterogeneity of LTi cells based on their CD4 and chemokine receptor expression. The CD4− LTi‐cell population has a similar phenotype to the CD4+ population, with similar chemokine‐receptor‐expressing subsets. In both embryonic and adult spleen the CD4− LTi‐cell population is comparable as a proportion of total splenocytes to its CD4+ counterpart. In contrast, different proportions of CD4+ and CD4− LTi cells are found in different lymph nodes. Both CD4+ and CD4− LTi cells share the anatomical location and are associated with vascular cell adhesion molecule‐1‐positive stromal cells in spleen and lymph nodes. The numbers of both CD4+ and CD4− LTi cells in adult spleen are augmented in the presence of B cells. With the exception of CD4, there is a strong correlation coefficient (0·89) for gene expression between the two populations. Polymerase chain reaction analysis of individual CD4+ and CD4− LTi cells shows that a similar proportion in embryonic and adult spleen co‐expressed both CXCR5 and CCR7 or CXCR5 alone: 84·6% for adult CD4+ and 87·6% for adult CD4−; 95·3% for embryonic CD4+ and 91·5% for embryonic CD4−. Consistently fewer CCR7 single‐positive cells were found in the CD4+ and CD4− fractions in the embryo.

The role of lymphoid tissue inducer cells in splenic white pulp development

CD4+CD3– lymphoid tissue inducer (LTi) cells are crucial for the development and organisation of lymph nodes and gut associated lymphoid tissues. In this report, we characterise their appearance in the developing spleen and highlight their importance in relation to the development of splenic T cell zones. LTi cells were detected in embryonic spleen from embryonic day 13, although their progenitors were present at embryonic day 12. These cells clustered initially around splenic blood vessels in a lymphotoxin (LT)‐independent manner, but up‐regulation of VCAM‐1 expression on stromal cells associated with the blood vessels was LT dependent. After birth, T cell colonisation of these clusters to form nascent white pulp areas was also LT dependent. Transfer experiments reconstituting RAG–/– mice with either WT or LTα–/– splenocytes demonstrated that lymphocyte expression of LT was not essential for the organisation of a discrete CD3+ T cell zone with localised podoplanin and CCL21 expression. Our studies indicate that a combination of LT signals from LTi cells and LT‐independent signals from lymphocytes is sufficient for expression of podoplanin and CCL21 on splenic T cell zone stroma and subsequent T cell organisation.

Changes in the Levels of Inositol Lipids and Phosphates during the Differentiation of HL60 Promyelocytic Cells towards Neutrophils or Monocytes

HL60 cells were adapted to grow in a serum-free medium containing 1 mg l-1 inositol, in which they differentiated normally towards neutrophils (in 0.9% by volume dimethylsulphoxide) and towards monocytes (in 10 nM phorbol myristate acetate). Cells that had been equilibrium-labelled with [2-3H] myo-inositol contained a complex pattern of inositol metabolites, several of which were at relatively high concentrations. These included InsP5 and InsP6, which were present at concentrations of about 25 μM and 60 μM, respectively. Striking and different changes occurred in the levels of some of the inositol polyphosphates as the cells differentiated towards either neutrophils or monocytes. Most notable were a large but gradual accumulation of Ins(1, 3, 4, 5, 6)P5 as HL60 cells decreased in size and acquired neutrophil characteristics, and much more rapid and sequential declines in InsP4, InsP5 and InsP6 as the cells started to take on monocyte character. There was a marked accumulation of free inositol and of phosphatidylinositol in the cells during neutrophil differentiation, probably caused at least in part by an increased rate of inositol uptake providing an increased intracellular inositol supply. The same accumulation of Ins( 1, 3, 4, 5, 6)P5 occurred during neutrophil differentiation, whether it was induced by dimethylsulphoxide or by a combination of retinoic acid and a T-lymphocyte cell line-derived differentiation factor. Ins(1, 4, 5)P3, a physiological intracellular mediator of Ca2+ release from membrane stores, did not change in concentration during these differentiation processes. These observations suggest that some of the more abundant cellular inositol polyphosphates play some important, but not yet understood, role either in the processes of haemopoietic differentiation or in the expression of differentiated cell character in myeloid cells.