Transcriptional regulation of mast cell and basophil lineage commitment

Basophils and mast cells have long been known to play critical roles in allergic disease and in immunity against parasitic infection. Accumulated evidence also supports that basophils and mast cells have important roles in immune regulations, host defense against bacteria and viruses, and autoimmune diseases. However, origin and molecular regulation of basophil and mast cell differentiation remain incompletely understood. In this review, we focus on recent advances in the understanding of origin and molecular regulation of mouse and human basophil and mast cell development. A more complete understanding of how basophils and mast cells develop at the molecular level will lead to development of interventions that are more effective in achieving long-term success.     

Newly appreciated roles for basophils in allergy and protective immunity

Basophils are evolutionarily conserved in many animal species, in spite of the fact that they account for <1% of peripheral blood leukocyte. This suggests that basophils have an indispensable and nonredundant role in vivo, even though they show some phenotypic similarity with tissue-resident mast cells. However, their functional significance remained uncertain long after Paul Ehrlich discovered them as blood-circulating cells with basophilic granules more than 130 years ago. The study of basophils has been far behind that of mast cells, owing to the rarity of basophils and the paucity of tools for their detection and functional analysis. Recent development of novel analytical tools, including basophil-depleting antibodies and genetically engineered mice deficient only in basophils, has greatly advanced basophil research and illuminated previously unrecognized roles of basophils. We now appreciate that basophils and mast cells play distinct roles in immune responses. Basophils have crucial roles in the development of acute and chronic allergic responses, the protective immunity against ecto- and endoparasites, and the regulation of acquired immunity, including the augmentation of humoral memory responses and the initiation of Th2 responses. Thus, basophils are no longer the neglected minority and are key players in the immune system.     

Basophils in skin inflammation

Basophils represent less than 1% of peripheral blood leukocytes. Under physiological conditions, basophils principally circulate in peripheral blood, while mast cells reside in peripheral tissues. Like mast cells, they express the high-affinity IgE receptor on their cell surface and release chemical mediators. Because of morphological and functional similarities, basophils have long been considered to be redundant "circulating mast cells" and minor (probably negligible) players in inflammation. Mouse and human basophils cannot be stained in routinely processed histological specimens, and thus, our understanding of tissue basophils in allergic inflammation had been limited. However, recent studies in mice have revealed that basopihls play non-redundant roles from mast cells. Basophils function as a source of IL-4, IL-13, and CCL22, thereby contributing Th2 immunity. They are also capable of presenting antigens. Basophils are essential for the development of IgE-mediated chronic allergic skin inflammation in mice. Recent immunohistochemical studies with an basophil-specific antibody revealed that, in humans, varying numbers of basophils infiltrate skin lesions of inflammatory diseases, such as atopic dermatitis, urticaria, prurigo, and eosinophilic pustular folliculitis. Basophils may play important roles in a variety of inflammatory skin diseases than previously thought.     

Basophil modulation by cytokine instruction

Basophils have recently been recognized as critical effector cells in allergic reactions and protective immunity against helminths. Precise characterization of basophil biology could help to develop specific therapies that interfere with differentiation, tissue recruitment, or induction of effector functions and thereby ameliorate allergic disorders. The development, homeostasis, and effector functions of basophils are tightly regulated by extrinsic signals and in particular by cytokines. IL‐3, GM‐CSF, and thymic stromal lymphopoietin activate the STAT5 pathway that promotes proliferation, activation, and cytokine secretion but also induces a negative feedback loop via Pim‐1 and SOCS proteins. Basophils further express receptors for IL‐18 and IL‐33, which are associated with the signaling adaptor MyD88 and activate the NF‐κB and MAP kinase pathways. This review focuses on positive and negative regulation of basophils by these cytokines.     

Basophils as critical orchestrators of Th2-type immune responses

Basophils are relatively rare leukocytes that potentially play a role in both systemic anaphylaxis and, owing to their ability to migrate from the blood into various other tissues, in more localized aspects of allergic inflammation. Given their greater sensitivities to allergen provocation compared with their tissue-fixed mast cell counterparts, and by virtue of their capacity to more readily generate Th2-type cytokines, basophils have been considered to play more than a bystander role in initiating and maintaining allergic disorders. However, only very recently has clearer evidence shed light on the abilities of this cell type to orchestrate chronic allergic inflammation and promote Th2 immunity in the early induction stages of allergy. This review summarizes these recent advances in understanding the role of basophils in orchestrating and maintaining allergic responses.     

Important and specific role for basophils in acute allergic reactions

IgE‐mediated allergic reactions involve the activation of effector cells, predominantly through the high‐affinity IgE receptor (FcεRI) on mast cells and basophils. Although the mast cell is considered the major effector cell during acute allergic reactions, more recent studies indicate a potentially important and specific role for basophils and their migration which occurs rapidly upon allergen challenge in humans undergoing anaphylaxis. We review the evidence for a role of basophils in contributing to clinical symptoms of anaphylaxis and discuss the possibility that basophil trafficking during anaphylaxis might be a pathogenic (to target organs) or protective (preventing degranulation in circulation) response. Finally, we examine the potential role of basophils in asthma exacerbations. Understanding the factors that regulate basophil trafficking and activation might lead to new diagnostic and therapeutic strategies in anaphylaxis and asthma.     

Interleukin-3, but not granulocyte-macrophage colony-stimulating factor and interleukin-5, inhibits apoptosis of human basophils through phosphatidylinositol 3-kinase: requirement of NF-kappaB-dependent and -independent pathways

Basophils are key effector cells of allergic reactions. Although proinflammatory cytokines, such as interleukin (IL)-3, granulocyte-macrophage colony-stimulating factor (GM-CSF) and IL-5, inhibit eosinophil apoptosis in vitro, little is known about basophil apoptosis, and the signalling mechanisms required for basophil survival remain undefined. To address this issue, we used a novel negative-selection system to isolate human basophils to a purity of > 95%, and evaluated apoptosis by morphology using light and transmission electron microscopy, and by annexin-V binding and propidium iodide incorporation using flow cytometry. In this study, we demonstrated that the spontaneous rate of apoptotic basophils was higher than that of eosinophils as, at 24 hr, 57.6 +/- 4.7% of basophils underwent apoptosis compared with 39.5 +/- 3.8% of eosinophils. In addition, basophil cell death was significantly inhibited when cultured with IL-3 for 48 hr (84.6 +/- 4.9% vehicle-treated cells versus 40.9 +/- 3.9% IL-3-treated cells). IL-3 also up-regulated basophil CD69 surface expression. The effects of IL-3 on apoptosis and CD69 surface expression of human basophils were completely blocked by LY294002 (LY), a potent inhibitor of phosphatidylinositol 3-kinase (PI3-K), but only partially inhibited by lactacystin, a proteasome inhibitor that prevents degradation of IkappaB and NF-kappaB translocation. These observations reveal the novel finding that IL-3 prevents basophil apoptosis through the activation of PI3-K, which is only partially NF-kappaB dependent. As basophils are active participants in allergic reactions and IL-3 is one of the abundant proinflammatory cytokines in secretions from allergic tissue, we suggest that IL-3-mediated inhibition of basophil apoptosis may exacerbate the inflammation associated with allergic disorders.     

Biomarkers for evaluation of mast cell and basophil activation

Mast cells and basophils play a pathogenetic role in allergic, inflammatory, and autoimmune disorders. These cells have different development, anatomical location and life span but share many similarities in mechanisms of activation and type of mediators. Mediators secreted by mast cells and basophils correlate with clinical severity in asthma, chronic urticaria, anaphylaxis, and other diseases. Therefore, effective biomarkers to measure mast cell and basophil activation in vivo could potentially have high diagnostic and prognostic values. An ideal biomarker should be specific for mast cells or basophils, easily and reproducibly detectable in blood or biological fluids and should be metabolically stable. Markers of mast cell and basophil include molecules secreted by stimulated cells and surface molecules expressed upon activation. Some markers, such as histamine and lipid mediators are common to mast cells and basophils whereas others, such as tryptase and other proteases, are relatively specific for mast cells. The best surface markers of activation expressed on mast cells and basophils are CD63 and CD203. While these mediators and surface molecules have been associated to a variety of diseases, none of them fulfills requirements for an optimal biomarker and search for better indicators of mast cell/basophil activation in vivo is ongoing.     

Human basophils as effectors and immunomodulators of allergic inflammation and innate immunity

Abstract Basophils have often stood in the shadow of their tissue–fixed mast cell counterparts which share some, common features, such as high–affinity IgE receptor expression and the ability to release histamine. That rodent mast cells produce a variety of pro–allergic and inflammatory cytokines has further added to the deception that basophils only play a minor role in allergic inflammation. Surprisingly, in humans, basophils, but not mast cells, appear to be the prime early producers of the Th2–type cytokines IL–4 and IL–13, which perform several crucial functions in initiating and maintaining allergic responses. This putative immunomodulatory role of basophils is supported further by their ability to express CD40 ligand, which, together with IL–4 and IL–13, serve as inductors of B–cell proliferation and class switching to IgE and IgG4. Moreover, human basophils are the main cellular source for rapid IL–4 generation, a mandatory requirement for the development of Th2 responses. Recent specific staining techniques have localised basophils in various tissues affected by allergic diseases and it appears likely, but remains to be proven, that the interaction of basophils, T cells and B cells at these sites propagate pro–allergic immune responses. Additionally, basophil activation is not restricted to antigen–specific IgE crosslinking but can be caused in non–sensitised individuals by parasitic antigens, plant lectins and viral superantigens binding to non–specific IgEs. Finally, the presence of novel IgE–independent receptor targets that cause trafficking and Th2 cytokine release from basophils further underlines their potential role in innate as well as adaptive immunity.     

Antibody-mediated regulation of basophils: emerging views and clinical implications

An increasing number of human diseases, including allergies, infections, inflammation, and cancer, involve roles for basophils. Traditionally viewed as the rarest leukocytes that are present only in the circulation, basophils have recently emerged as important players in systemic as well as tissue-specific immune responses. Their functions are regulated by immunoglobulins (Igs), and this enables basophils to integrate diverse adaptive and innate immunity signals. IgE is well known to regulate basophil responses in the context of type 2 immunity and allergic inflammation; however, growing evidence shows that IgG, IgA, and IgD also shape specific aspects of basophil functions relevant to many human diseases. We discuss recent mechanistic advances underpinning antibody-mediated basophil responses and propose strategies for the treatment of basophil-associated disorders.     

Emerging functions of basophils in protective and allergic immune responses

Basophils that were long thought to have a redundant role in mast cells in the effector response to allergens and parasites are now being recognized to have important roles in the regulation of adaptive immune responses. Recent data have revealed their role in the initiation of the T helper cell 2 (Th2)-mediated immune response. Not only do basophils guide the Th1–Th2 balance by providing an early source of crucial Th2-skewing cytokines, interleukin (IL)-4 and thymic stromal lymphopoietin, but recent findings have also illustrated their capacity to function as antigen-presenting cells. Thus, basophils activate and instruct naive CD4 T cells, and guide their development into Th2 cells. Not only do basophils directly interact with T cells, but new insights have illustrated that they may also directly guide antibody responses in both the primary and memory responses. These and other studies have illustrated the emerging role of basophils in the regulation of type 2 immunity.     

Basophils are potent antigen‐presenting cells that selectively induce Th2 cells

Basophils and mast cells are important effector cells in helminth‐infected host and IgE‐mediated allergic inflammation. Although they have the same progenitors, basophils and mast cells complete their terminal differentiation in the bone marrow and peripheral tissues, respectively, and only basophils circulate in the blood. Although it is recognized that basophils are important for Th2 responses, and it is also well established that IL‐4 is required for Th2 differentiation from naïve CD4⁺ T cells, the nature of the cells that produce “early” IL‐4, remained elusive until recently. Three groups independently demonstrated that basophils are the predominant APC in inducing Th2 response against helminth parasites and allergens. Basophils express MHC class II and CD80/86, have the potential to take‐up and process protein Ag (particularly Ag–IgE complex) and to present peptide in the context of MHC class II, and to produce IL‐4. These Ag‐pulsed basophils induce the development of Th2 cells both in vitro and in vivo. Thus, basophils contribute to Th2/IgE response by the production of IL‐4 and presentation of MHC class II/peptide complex to naïve CD4⁺ T cells, in contrast to the Th1‐inducing action of DC. In this review, we summarize what is known regarding basophil function in allergy and parasite infection, examine the novel Ag‐presenting function of basophils and discuss potential clinical implications of this finding.     

Mast cells: not only in allergy

The past decade has confronted us with a striking abundance of novel findings regarding the roles of mast cells in immune responses in health and disease. Newly developed models and techniques have enabled clear-cut dissection of the mast cell contribution in these settings. We now understand that mast cells possess critical effector functions not only within the traditional context of allergic reactions. It is likely that mast cells played pivotal roles in primitive immune systems, yet these functions have been masked in the recent eras by newer immune functions, such as adaptive immunity. Conceivably, mast cells should be refocused on so as to obtain new insights about diverse pathologic conditions, ultimately leading to novel therapeutic approaches targeting these fascinating cells.     

Emerging roles of basophils in protective immunity against parasites

Basophils, the least common type of granulocyte, have long been considered as minor effector cells in allergic responses because of their ability to release allergy-inducing chemical mediators such as histamine and leukotriene C4. However, it is unlikely that many animal species evolutionarily conserve basophils to only elicit allergic responses without any host-beneficial function. The study of basophils has been hampered by their rarity and difficult identification, as well as the lack of suitable animal models. Recent studies using novel analytical tools, including basophil-depleting antibodies and genetically engineered mice deficient only in basophils, have illuminated the crucial and nonredundant roles for basophils in protective immunity against both ecto- and endoparasites.     

Immunoregulatory roles of eosinophils: a new look at a familiar cell

Eosinophils are usually considered as end-stage degranulating effector cells of innate immunity. However, accumulating evidence has revealed additional roles for eosinophils that are immunoregulatory in nature in both the adaptive and innate arms of immunity. Specifically, eosinophils have key immunoregulatory roles as professional antigen-presenting cells and as modulators of CD4⁺ T cell, dendritic cell, B cell, mast cell, neutrophil, and basophil functions. This review addresses the emerging immunoregulatory roles of eosinophils with a focus on recent data that support this new paradigm. Recognizing both the effector and immunoregulatory functions of eosinophils will enable a fuller understanding of the roles of eosinophils in allergic airways inflammation and may be pertinent to therapies that target eosinophils both for their acute and ongoing immunomodulatory functions.     

Regulation of allergic inflammation by the ectoenzyme E-NPP3 (CD203c) on basophils and mast cells

Adenosine 5′-triphosphate (ATP) is released from dying or damaged cells, as well as from activated cells. Once secreted, extracellular ATP induces several immune responses via P2X and P2Y receptors. Basophils and mast cells release ATP upon FcεRI-crosslinking, and ATP activates basophils and mast cells in an autocrine manner. Nucleotide-converting ectoenzymes, such as E-NTPD1, E-NTPD7, and E-NPP3, inhibit ATP-dependent immune responses by hydrolyzing ATP, thereby contributing to immune response regulation. E-NPP3 is a well-known activation marker for human basophils. E-NPP3’s physiologic function has recently been disclosed in mice. E-NPP3 is rapidly induced on basophils and mast cells after FcεRI-crosslinking and hydrolyzes extracellular ATP on cell surfaces to prevent ATP-dependent excess activation of basophils and mast cells. In the absence of E-NPP3, basophils and mast cells are overactivated and mice suffer from severe chronic allergic inflammation. Thus, the ATP-hydrolyzing ectoenzymes E-NPP3 has a nonnegligible role in the regulation of basophil- and mast cell-mediated allergic responses.     

Mast cells and basophils: friends as well as foes in bronchial asthma?

Human mast cells and basophils are conventionally considered primary effector cells of bronchial asthma. There is now compelling evidence that these cells differ immunologically, biochemically and pharmacologically, which suggests that they might have distinct roles in the appearance and fluctuation of the asthma phenotype. Recent data reveal the complexity of the roles of human mast cells and basophils in asthma and have shed light on the control of recruitment and activation of these cells in different lung compartments. Preliminary evidence suggests that these cells might not always be detrimental in asthma but, under some circumstances, have a protective role in modulating certain aspects of innate and acquired immunity and allergic inflammation.     

The role of basophils in the pathogenesis of allergic disease

There has been much controversy surrounding the importance of basophils in allergy. These cells are, after all, comparatively rare and yet they display remarkable potential to contribute to the symptoms of allergic inflammation. Furthermore, by virtue of their ability to rapidly elaborate T helper type 2 (Th2)‐type cytokines, they are well endowed to support ongoing allergic immunity. Despite this, basophils have often been regarded as redundant in this function as in murine models of allergy, their more numerous tissue‐fixed mast cell counterparts also display Th2‐type cytokine‐releasing potential, which is rather different in most human mast cells. Surprisingly, it is from murine models that the basophil has re‐surfaced as a key orchestrator of Th2‐type immunity and chronic allergic inflammation, a property that has long been hypothesized by researchers into human basophil function but never demonstrated. Moreover, murine experimental models also highlighted the ability of basophils to take up and present antigens in an MHC‐dependent manner. Controversy regarding basophils, however, has remained as recent methods for depleting these cells in murine models of allergy and parasitic infection have yielded conflicting results, where the role for this cell oscillates from essential antigen‐presenting cells to mere supporting functions in controlling Th2 responses. This review highlights the recent advances in understanding the role of this rather enigmatic cell in allergy. Cite this as: F. H. Falcone, E. F. Knol and B. F. Gibbs, Clinical & Experimental Allergy, 2011 (41) 939–947.     

Roles of basophils and mast cells in cutaneous inflammation

Mast cells and basophils are associated with T helper 2 (Th2) immune responses. Newly developed mast cell-deficient mice have provided evidence that mast cells initiate contact hypersensitivity via activating dendritic cells. Studies using basophil-deficient mice have also revealed that basophils are responsible for cutaneous Th2 skewing to haptens and peptide antigens but not to protein antigens. Recently, several studies reported the existence of innate lymphoid cells (ILCs), which differ from classic T cells in that they lack the T cell receptor. Mast cells and basophils can interact with ILCs and play some roles in the pathogenesis of Th2 responses. Basophil-derived interleukin (IL)-4 enhances the expression of the chemokine CCL11, as well as IL-5, IL-9, and IL-13 in ILC2s, leading to the accumulation of eosinophils in allergic reactions. IL-33-stimulated mast cells can play a regulatory role in the development of ILC2-mediated non-antigen-specific protease-induced acute inflammation. In this review, we discuss the recent advances in our understanding of mast cells and basophils in immunity and inflammation.     

The basophil-specific ectoenzyme E-NPP3 (CD203c) as a marker for cell activation and allergy diagnosis

Basophils are effector cells of allergic reactions. These cells produce and store a number of vasoactive and immunomodulatory mediators. During an allergic reaction, basophils can release their mediator substances into the extracellular space and thus contribute to the clinical picture and symptoms in allergy. The phenotypic hallmark of basophils is expression of high-affinity IgE receptors (Fc epsilon RI) on their cell surface together with expression of the activation-linked molecule CD203c. This ectoenzyme is located both on the plasma membrane and in the cytoplasmic compartment of basophils. Cross-linking of the Fc epsilon RI by an allergen or anti-IgE antibody results in a rapid upregulation of intracellular CD203c molecules to the cell surface and is accompanied by mediator release. CD203c is therefore a promising target molecule for a flow cytometry-based test to analyze sensitized individuals and patients with type I allergy. In the present article, we review the current knowledge of CD203c with special regard to its tissue distribution and regulation in basophil activation. In addition, we discuss the application of CD203c in allergy diagnosis.