Katrin Witzlau

Critical role for miR-181a/b-1 in agonist selection of invariant natural killer T cells

T-cell receptor (TCR) signal strength determines selection and lineage fate at the CD4+CD8+ double-positive stage of intrathymic T-cell development. Members of the miR-181 family constitute the most abundantly expressed microRNA at this stage of T-cell development. Here we show that deletion of miR-181a/b-1 reduced the responsiveness of double-positive thymocytes to TCR signals and virtually abrogated early invariant natural killer T (iNKT) cell development, resulting in a dramatic reduction in iNKT cell numbers in thymus as well as in the periphery. Increased concentrations of agonist ligand rescued iNKT cell development in miR-181a/b-1−/− mice. Our results define a critical role of miR-181a/b-1 in early iNKT cell development and show that miR-181a/b-1 sets a TCR signaling threshold for agonist selection.

Multiple extrathymic precursors contribute to T-cell development with different kinetics.

T-cell development in the thymus depends on continuous supply of T-cell progenitors from bone marrow (BM). Several extrathymic candidate progenitors have been described that range from multipotent cells to lymphoid cell committed progenitors and even largely T-lineage committed precursors. However, the nature of precursors seeding the thymus under physiologic conditions has remained largely elusive and it is not known whether there is only one physiologic T-cell precursor population or many. Here, we used a competitive in vivo assay based on depletion rather than enrichment of classes of BM-derived precursor populations, thereby only minimally altering physiologic precursor ratios to assess the contribution of various extrathymic precursors to T-lineage differentiation. We found that under these conditions multiple precursors, belonging to both multipotent progenitor (MPP) and common lymphoid progenitor (CLP) subsets have robust T-lineage potential. However, differentiation kinetics of different precursors varied considerably, which might ensure continuous thymic output despite gated importation of extrathymic precursors. In conclusion, our data suggest that the thymus functions to impose T-cell fate on any precursor capable of filling the limited number of progenitor niches.

Multicongenic fate mapping quantification of dynamics of thymus colonization

Ziętara et al demonstrate with multicongenic fate mapping that thymus seeding is directly restricted to the duration of niche occupancy rather than long-range effects.

Chemokine receptor CX3CR1 promotes dendritic cell development under steady-state conditions

Expression of CX3CR1 is an attribute of myeloid precursors committed to the monocyte/macrophage (Mφ)/DC lineages and is maintained during all stages of DC differentiation. Nevertheless, the exact role of this molecule during developmental progression of myeloid precursors towards the DC lineage remains elusive. To overcome potential compensatory mechanisms and issues of redundancy, we employed competitive adoptive transfer experiments to assess a possible function of CX3CR1 in DC and monocyte/Mφ differentiation in vivo. We show here that expression of CX3CR1 promotes the generation of DCs and monocytes/Mφ under steady‐state conditions and during compensatory expansion after selective depletion of DCs, but not under inflammatory conditions evoked by sub‐lethal irradiation. Direct administration of CX3CR1‐deficient and CX3CR1‐sufficient precursors into the spleen or the thymus resulted in a similar competitive advantage of WT over CX3CR1‐deficient precursors as i.v. transfer, suggesting that CX3CR1‐mediated survival rather than recruitment to lymphoid organs is critical for DC/Mφ differentiation. In conclusion, our data support the hypothesis that CX3CR1 promotes proper development of myeloid precursors into DCs and monocytes/Mφs under steady‐state conditions, possibly by providing survival signals or mediating accessibility to organ‐specific niches, rather than acting as a mediator of homing to the spleen or the thymus.

MicroRNA-181a/b-1 Is Not Required for Innate γδ NKT Effector Cell Development

Thymic development of αβ T lymphocytes into invariant natural killer (NK) T cells depends on their selection via agonistic lipid antigen presented by CD1d. If successful, newly selected NKT cells gain effector functions already in the thymus. Some γδ T cell subsets also acquire effector functions in the thymus. However, it is not clear whether agonistic TCR stimulation is involved in thymic γδ T cell selection and development. Here we combine two genetic models to address this question. MiR-181a/b-1–/–mice, which show impaired agonistic T cell selection of invariant αβ NKT cells, were crossed to Tcrd-H2BeGFP reporter mice to monitor selection, intra-thymic expansion and differentiation of γδ T cells. We found that miR-181a/b-1-deficiency had no effect on numbers of thymic γδ T cell or on their differentiation towards an IL-17- or IFN-γ-producing effector phenotype. Also, the composition of peripheral lymph node γδ T cells was not affected by miR-181a/b-1-deficiency. Dendritic epidermal γδ T cells were normally present in knock-out animals. However, we observed elevated frequencies and numbers of γδ NKT cells in the liver, possibly because γδ NKT cells can expand and replace missing αβ NKT cells in peripheral niches. In summary, we investigated the role of miR-181a/b-1 for selection, intrathymic development and homeostasis of γδ T cells. We conclude that miR-181a/b-1-dependent modulation of T cell selection is not critically required for innate development of γδ NKT cells or of any other γδ T cell subtypes.

Limited niche availability suppresses murine intrathymic dendritic-cell development from noncommitted progenitors

The origins of dendritic cells (DCs) and other myeloid cells in the thymus have remained controversial. In this study, we assessed developmental relationships between thymic dendritic cells and thymocytes, employing retrovirus-based cellular barcoding and reporter mice, as well as intrathymic transfers coupled with DC depletion. We demonstrated that a subset of early T-lineage progenitors expressed CX3CR1, a bona fide marker for DC progenitors. However, intrathymic transfers into nonmanipulated mice, as well as retroviral barcoding, indicated that thymic dendritic cells and thymocytes were largely of distinct developmental origin. In contrast, intrathymic transfers after in vivo depletion of DCs resulted in intrathymic development of non-T-lineage cells. In conclusion, our data support a model in which the adoption of T-lineage fate by noncommitted progenitors at steady state is enforced by signals from the thymic microenvironment unless niches promoting alternative lineage fates become available.

Responsiveness of Developing T Cells to IL-7 Signals Is Sustained by miR-17∼92

miRNAs regulate a large variety of developmental processes including development of the immune system. T cell development is tightly controlled through the interplay of transcriptional programs and cytokine-mediated signals. However, the role of individual miRNAs in this process remains largely elusive. In this study, we demonstrated that hematopoietic cell–specific loss of miR-17∼92, a cluster of six miRNAs implicated in B and T lineage leukemogenesis, resulted in profound defects in T cell development both at the level of prethymic T cell progenitors as well as intrathymically. We identified reduced surface expression of IL-7R and concomitant limited responsiveness to IL-7 signals as a common mechanism resulting in reduced cell survival of common lymphoid progenitors and thymocytes at the double-negative to double-positive transition. In conclusion, we identified miR-17∼92 as a critical modulator of multiple stages of T cell development.

Overexpression of Vα14Jα18 TCR promotes development of iNKT cells in the absence of miR-181a/b-1.

Expression of microRNA miR‐181a/b‐1 is critical for intrathymic development of invariant natural killer T (iNKT) cells. However, the underlying mechanism has remained a matter of debate. On the one hand, growing evidence suggested that miR‐181a/b‐1 is instrumental in setting T‐cell receptor (TCR) signaling threshold and thus permits agonist selection of iNKT cells through high‐affinity TCR ligands. On the other hand, alterations in metabolic fitness mediated by miR‐181a/b‐1‐dependent dysregulation of phosphatase and tensin homolog (Pten) have been proposed to cause the iNKT‐cell defect in miR‐181‐a/b‐1‐deficient mice. To re‐assess the hypothesis that modulation of TCR signal strength is the key mechanism by which miR‐181a/b‐1 controls the development of iNKT cells, we generated miR‐181a/b‐1‐deficient mice expressing elevated levels of a Vα14Jα18 TCRα chain. In these mice, development of iNKT cells was fully restored. Furthermore, both subset distribution of iNKT cells as well as TCR Vβ repertoire were independent of the presence of miR‐181a/b‐1 once a Vα14Jα18 TCRα chain was overexpressed. Finally, levels of Pten protein were similar in Vα14Jα18 transgenic mice irrespective of their miR‐181a/b‐1 status. Collectively, our data support a model in which miR‐181 promotes development of iNKT cells primarily by generating a permissive state for agonist selection with alterations in metabolic fitness possibly constituting a secondary effect.

Extra-Thymic Physiological T Lineage Progenitor Activity Is Exclusively Confined to Cells Expressing either CD127, CD90, or High Levels of CD117

T cell development depends on continuous recruitment of progenitors from bone marrow (BM) to the thymus via peripheral blood. However, both phenotype and functional characteristics of physiological T cell precursors remain ill-defined. Here, we characterized a putative CD135+CD27+ T cell progenitor population, which lacked expression of CD127, CD90, and high levels of CD117 and was therefore termed triple negative precursor (TNP). TNPs were present in both BM and blood and displayed robust T lineage potential, but virtually no myeloid or B lineage potential, in vitro. However, TNPs did not efficiently generate T lineage progeny after intravenous or intrathymic transfer, suggesting that a physiological thymic microenvironment does not optimally support T cell differentiation from TNPs. Thus, we propose that physiological T cell precursors are confined to populations expressing either CD127, CD90, or high levels of CD117 in addition to CD135 and CD27 and that TNPs may have other physiological functions.

Decreased production of class-switched antibodies in neonatal B cells is associated with increased expression of miR-181b

The increased susceptibility to infections of neonates is caused by an immaturity of the immune system as a result of both qualitative and quantitative differences between neonatal and adult immune cells. With respect to B cells, neonatal antibody responses are known to be decreased. Accountable for this is an altered composition of the neonatal B cell compartment towards more immature B cells. However, it remains unclear whether the functionality of individual neonatal B cell subsets is altered as well. In the current study we therefore compared phenotypical and functional characteristics of corresponding neonatal and adult B cell subpopulations. No phenotypic differences could be identified with the exception of higher IgM expression in neonatal B cells. Functional analysis revealed differences in proliferation, survival, and B cell receptor signaling. Most importantly, neonatal B cells showed severely impaired class-switch recombination (CSR) to IgG and IgA. This was associated with increased expression of miR-181b in neonatal B cells. Deficiency of miR-181b resulted in increased CSR. With this, our results highlight intrinsic differences that contribute to weaker B cell antibody responses in newborns.