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Type 2 cytokine responses promote parasitic immunity and initiate tissue repair; however, they can also result in immunopathologies when not properly restricted. Although basophilia is recognized as a common feature of type 2 inflammation, the roles basophils play in regulating these responses are unknown. Here, we demonstrate that helminth-induced group 2 innate lymphoid cell (ILC2) responses are exaggerated in the absence of basophils, resulting in increased inflammation and diminished lung function. Additionally, we show that ILC2s from basophil-depleted mice express reduced amounts of the receptor for the neuropeptide neuromedin B (NMB). Critically, NMB stimulation inhibited ILC2 responses from control but not basophil-depleted mice, and basophils were sufficient to directly enhance NMB receptor expression on ILC2s. These studies suggest that basophils prime ILC2s to respond to neuron-derived signals necessary to maintain tissue integrity. Further, these data provide mechanistic insight into the functions of basophils and identify NMB as a potent inhibitor of type 2 inflammation. Siracusa and colleagues reveal a regulatory role for basophils in the context of anti-helminth immunity and identify the neuropeptide neuromedin B as a potent inhibitor of type 2 inflammation.

Alterations in commensal bacteria are associated with an increased risk of allergic disease. David Artis and his colleagues now report that commensal-derived signals influence basophil development and T H 2 cytokine–dependent allergic airway inflammation by suppressing serum IgE levels. Individuals with hyper IgE syndrome also have elevated circulating basophil numbers, suggesting a mechanistic link between commensal bacteria, B cell–mediated production of IgE and basophil hematopoiesis. Commensal bacteria that colonize mammalian barrier surfaces are reported to influence T helper type 2 (T H 2) cytokine-dependent inflammation and susceptibility to allergic disease, although the mechanisms that underlie these observations are poorly understood. In this report, we find that deliberate alteration of commensal bacterial populations via oral antibiotic treatment resulted in elevated serum IgE concentrations, increased steady-state circulating basophil populations and exaggerated basophil-mediated T H 2 cell responses and allergic inflammation. Elevated serum IgE levels correlated with increased circulating basophil populations in mice and subjects with hyperimmunoglobulinemia E syndrome. Furthermore, B cell–intrinsic expression of myeloid differentiation factor 88 (MyD88) was required to limit serum IgE concentrations and circulating basophil populations in mice. Commensal-derived signals were found to influence basophil development by limiting proliferation of bone marrow–resident precursor populations. Collectively, these results identify a previously unrecognized pathway through which commensal-derived signals influence basophil hematopoiesis and susceptibility to T H 2 cytokine–dependent inflammation and allergic disease.

Parasitic helminth infections remain a significant global health issue and are responsible for devastating morbidity and economic hardships. During infection, helminths migrate through different host organs, which results in substantial tissue damage and the release of diverse effector molecules by both hematopoietic and non-hematopoietic cells. Thus, host protective responses to helminths must initiate mechanisms that help to promote worm clearance while simultaneously mitigating tissue injury. The specialized immunity that promotes these responses is termed type 2 inflammation and is initiated by the recruitment and activation of hematopoietic stem/progenitor cells, mast cells, basophils, eosinophils, dendritic cells, neutrophils, macrophages, myeloid-derived suppressor cells, and group 2 innate lymphoid cells. Recent work has also revealed the importance of neuron-derived signals in regulating type 2 inflammation and antihelminth immunity. These studies suggest that multiple body systems coordinate to promote optimal outcomes post-infection. In this review, we will describe the innate immune events that direct the scope and intensity of antihelminth immunity. Further, we will highlight the recent progress made in our understanding of the neuro-immune interactions that regulate these pathways and discuss the conceptual advances they promote.

TSLP's role in allergy The cytokine thymic stromal lymphopoietin (TSLP) has been described as the master switch of allergic inflammation. Here, TSLP is shown to induce the development of basophils from bone-marrow progenitors and to activate peripheral basophils in an interleukin-3 (IL-3)-independent manner. Basophils elicited by TSLP differ from those dependent on IL-3 both phenotypically and functionally, and may play an important part in allergic diseases associated with T-helper type 2 cells. CD4 + T-helper type 2 (T H 2) cells, characterized by their expression of interleukin (IL)-4, IL-5, IL-9 and IL-13, are required for immunity to helminth parasites 1 and promote the pathological inflammation associated with asthma and allergic diseases 2 . Polymorphisms in the gene encoding the cytokine thymic stromal lymphopoietin (TSLP) are associated with the development of multiple allergic disorders in humans, indicating that TSLP is a critical regulator of T H 2 cytokine-associated inflammatory diseases 3 , 4 , 5 , 6 . In support of genetic analyses, exaggerated TSLP production is associated with asthma, atopic dermatitis and food allergies in patients, and studies in murine systems demonstrated that TSLP promotes T H 2 cytokine-mediated immunity and inflammation 5 , 7 , 8 , 9 , 10 , 11 , 12 . However, the mechanisms through which TSLP induces T H 2 cytokine responses remain poorly defined. Here we demonstrate that TSLP promotes systemic basophilia, that disruption of TSLP–TSLPR interactions results in defective basophil responses, and that TSLPR-sufficient basophils can restore T H 2-cell-dependent immunity in vivo . TSLP acted directly on bone-marrow-resident progenitors to promote basophil responses selectively. Critically, TSLP could elicit basophil responses in both IL-3–IL-3R-sufficient and -deficient environments, and genome-wide transcriptional profiling and functional analyses identified heterogeneity between TSLP-elicited versus IL-3-elicited basophils. Furthermore, activated human basophils expressed TSLPR, and basophils isolated from eosinophilic oesophagitis patients were distinct from classical basophils. Collectively, these studies identify previously unrecognized heterogeneity within the basophil cell lineage and indicate that expression of TSLP may influence susceptibility to multiple allergic diseases by regulating basophil haematopoiesis and eliciting a population of functionally distinct basophils that promote T H 2 cytokine-mediated inflammation.

The mammalian intestine is colonized by beneficial commensal bacteria and is a site of infection by pathogens, including helminth parasites. Helminths induce potent immunomodulatory effects, but whether these effects are mediated by direct regulation of host immunity or indirectly through eliciting changes in the microbiota is unknown. We tested this in the context of virus-helminth coinfection. Helminth coinfection resulted in impaired antiviral immunity and was associated with changes in the microbiota and STAT6-dependent helminth-induced alternative activation of macrophages. Notably, helminth-induced impairment of antiviral immunity was evident in germ-free mice, but neutralization of Ym1, a chitinase-like molecule that is associated with alternatively activated macrophages, could partially restore antiviral immunity. These data indicate that helminth-induced immunomodulation occurs independently of changes in the microbiota but is dependent on Ym1.

Anti-helminth responses require robust type 2 cytokine production that simultaneously promotes worm expulsion and initiates the resolution of helminth-induced wounds and hemorrhaging. However, how infection-induced changes in hematopoiesis contribute to these seemingly distinct processes remains unknown. Recent studies have suggested the existence of a hematopoietic progenitor with dual mast cell-erythrocyte potential. Nonetheless, whether and how these progenitors contribute to host protection during an active infection remains to be defined. Here, we employed single cell RNA-sequencing and identified that the metabolic enzyme, carbonic anhydrase (Car) 1 marks a predefined bone marrow-resident hematopoietic progenitor cell (HPC) population. Next, we generated a Car1-reporter mouse model and found that Car1-GFP positive progenitors represent bipotent mast cell/erythrocyte precursors. Finally, we show that Car1-expressing HPCs simultaneously support mast cell and erythrocyte responses during Trichinella spiralis infection. Collectively, these data suggest that mast cell/erythrocyte precursors are mobilized to promote type 2 cytokine responses and alleviate helminth-induced blood loss, developmentally linking these processes. Collectively, these studies reveal unappreciated hematopoietic events initiated by the host to combat helminth parasites and provide insight into the evolutionary pressure that may have shaped the developmental relationship between mast cells and erythrocytes.

The role of p53 in tumor suppression has been extensively studied and well-established. However, the role of p53 in parasitic infections and the intestinal type 2 immunity is unclear. Here, we report that p53 is crucial for intestinal type 2 immunity in response to the infection of parasites, such as Tritrichomonas muris and Nippostrongylus brasiliensis . Mechanistically, p53 plays a critical role in the activation of the tuft cell-IL-25-type 2 innate lymphoid cell circuit, partly via transcriptional regulation of Lrmp in tuft cells. Lrmp modulates Ca 2+ influx and IL-25 release, which are critical triggers of type 2 innate lymphoid cell response. Our results thus reveal a previously unrecognized function of p53 in regulating intestinal type 2 immunity to protect against parasitic infections, highlighting the role of p53 as a guardian of immune integrity. P53 is a well-known tumour suppressor, however its role in intestinal type 2 immunity is currently unclear. Here authors report that during parasitic infections, p53 triggers tuft cell Ca 2+ influx and IL-25 release, and shows a regulatory role for p53 in intestinal type 2 immunity via transcriptional regulation of the Lrmp gene.

Carbonic anhydrase (Car) enzymes are a family of metalloenzymes that are traditionally known for their ability to regulate pH and CO 2 homeostasis. However, emerging studies now demonstrate that Car family members exhibit lineage-specific expression patterns within immune cells. Moreover, it has been shown that genetically and pharmacologically targeting specific Car family members is sufficient to regulate immune cell development and activation. This work has identified Car enzymes as viable therapeutic targets that can influence immunity and inflammation. Here we contribute to this growing body of literature and demonstrate that Car8 is highly expressed by basophils and basophil precursor cells compared to other Car family members. While deletion of Car8 had no effect on basophil development or recruitment, mice deficient in Car8 were protected from basophil- and interleukin (IL)-4-dependent atopic dermatitis-like inflammation. Consistent with these findings, Car8-deficient basophils exhibit defects in the cytokine-stimulated release of IL-4 that is associated with altered calcium signaling pathways. Collectively, these studies reveal the lineage-specific expression patterns of Car8 and its unappreciated function in regulating basophil activation.

Control of infection depends on the efficient coordination of responses by various cell populations of the immune system. Gause and colleagues review the interactions between cells of the innate immune system and stroma that enable effective responses to invading pathogens. Innate cells are responsible for the rapid recognition of infection and mediate essential mechanisms of pathogen elimination, and also facilitate adaptive immune responses. We review here the numerous intricate interactions among innate cells that initiate protective immunity. The efficient eradication of pathogens depends on the coordinated actions of multiple cells, including innate cells and epithelial cells. Rather than acting as isolated effector cells, innate cells are in constant communication with other responding cells of the immune system, locally and distally. These interactions are critically important for the efficient control of primary infections as well for the development of 'trained' innate cells that facilitate the rapid elimination of homologous or heterologous infections.