Inflammation early in life can prime the local immune milieu of peripheral tissues, which can cause lasting changes in immunological tone that confer disease protection or susceptibility1. The cellular and molecular mechanisms that prompt changes in immune tone in many nonlymphoid tissues remain largely unknown. Here we find that time-limited neonatal inflammation induced by a transient reduction in neonatal regulatory T cells causes a dysregulation of subcutaneous tissue in mouse skin. This is accompanied by the selective accumulation of type 2 helper T (TH2) cells within a distinct microanatomical niche. TH2 cells are maintained into adulthood through interactions with a fibroblast population in skin fascia that we refer to as TH2-interacting fascial fibroblasts (TIFFs), which expand in response to TH2 cytokines to form subcutaneous fibrous bands. Activation of the TH2-TIFF niche due to neonatal inflammation primes the skin for altered reparative responses to wounding. Furthermore, we identify fibroblasts in healthy human skin that express the TIFF transcriptional signature and detect these cells at high levels in eosinophilic fasciitis, an orphan disease characterized by inflammation and fibrosis of the skin fascia. Taken together, these data define a previously unidentified TH2 cell niche in skin and functionally characterize a disease-associated fibroblast population. The results also suggest a mechanism of immunological priming whereby inflammation early in life creates networks between adaptive immune cells and stromal cells to establish an immunological set-point in tissues that is maintained throughout life.
© 2021. The Author(s), under exclusive licence to Springer Nature Limited.

The selection of affinity-matured Ab-producing B cells is supported by interactions with T follicular helper (Tfh) cells. In addition to cell surface-expressed molecules, cytokines produced by Tfh cells, such as IL-21 and IL-4, provide B cell helper signals. In this study, we analyze how the fitness of Th cells can influence Ab responses. To do this, we used a model in which IL-21R-sufficient (wild-type [WT]) and -deficient (Il21r(-/-)) Ag-specific Tfh cells were used to help immunodeficient Il21r(-/-) B cells following T-dependent immunization. Il21r(-/-) B cells that had received help from WT Tfh cells, but not from Il21r(-/-) Tfh cells, generated affinity-matured Ab upon recall immunization. This effect was dependent on IL-4 produced in the primary response and associated with an increased fraction of memory B cells. Il21r(-/-) Tfh cells were distinguished from WT Tfh cells by a decreased frequency, reduced conjugate formation with B cells, increased expression of programmed cell death 1, and reduced production of IL-4. IL-21 also influenced responsiveness to IL-4 because expression of both membrane IL-4R and the IL-4-neutralizing soluble (s)IL-4R were reduced in Il21r(-/-) mice. Furthermore, the concentration of sIL-4R was found to correlate inversely with the amount of IgE in sera, such that the highest IgE levels were observed in Il21r(-/-) mice with the least sIL-4R. Taken together, these findings underscore the important collaboration between IL-4 and IL-21 in shaping T-dependent Ab responses.Copyright © 2015 by The American Association of Immunologists, Inc.

The study of murine memory B cells has been limited by small cell numbers and the lack of a definitive marker. We have addressed some of these difficulties with hapten-specific transgenic (Tg) mouse models that yield relatively large numbers of antigen-specific memory B cells upon immunization. Using these models, along with a 5-bromo-2'-deoxyuridine (BrdU) pulse-label strategy, we compared memory cells to their naive precursors in a comprehensive flow cytometric survey, thus revealing several new murine memory B cell markers. Most interestingly, memory cells were phenotypically heterogeneous. Particularly surprising was the finding of an unmutated memory B cell subset identified by the expression of CD80 and CD35. We confirmed these findings in an analogous V region knock-in mouse and/or in non-Tg mice. There also was anatomic heterogeneity, with BrdU(+) memory cells residing not just in the marginal zone, as had been thought, but also in splenic follicles. These studies impact the current understanding of murine memory B cells by identifying new phenotypes and by challenging assumptions about the location and V region mutation status of memory cells. The apparent heterogeneity in the memory compartment implies either different origins and/or different functions, which we discuss.

Murine neonatal immunity is typically Th2 biased. This is characterized by high-level IL-4 production at all phases of the immune response and poor IFN-gamma memory responses. The differential expression of Th1/Th2 cytokines by neonates and adults could arise if the critical regulators of Th differentiation and function, STAT6 and T-bet, operate differently during the neonatal period. To test this idea, the Th cell responses of wild-type, T-bet-deficient, or STAT6-deficient mice were compared in vitro and in vivo. The absence of these factors had similar qualitative effects on the development of effector function in neonates and adults, i.e., if a Th lineage was inhibited or enhanced in adult animals, a similar phenomenon was observed in neonates. However, there was a striking difference observed in the in vivo Th1 memory responses of STAT6-deficient mice initially immunized as neonates. Antigen-specific IFN-gamma production was increased 50-100-fold in STAT6-deficient neonates, achieving levels similar to those of STAT6-deficient adults. These findings demonstrate that STAT6 and T-bet signals are central in shaping Th responses in wild-type neonates, as in adult mice, and that the master regulators of Th cell development and function are already firmly established in early life.