Misa Hirose

PI3Kβ Plays a Critical Role in Neutrophil Activation by Immune Complexes

The β isoform of phosphoinositide 3-kinase may be an effective therapeutic target in inflammatory diseases. The Integrating Isoform The class I phosphoinositide 3-kinases (PI3Ks) are implicated in processes such as growth factor signaling and inflammation. PI3Kγ is activated by G protein–coupled receptors (GPCRs), whereas PI3Kα and PI3Kδ are activated by protein tyrosine kinase–coupled receptors. PI3Kβ is unusual in that it appears to respond to signals from both types of receptors, depending on the cellular context. Kulkarni et al. investigated the responses of mouse neutrophils to immune complexes of antibody and antigen, which trigger chronic inflammation in conditions such as autoimmune arthritis. Genetic and pharmacological evidence suggested that immune complexes stimulated PI3Kβ in a process involving activation of FcγR, a tyrosine kinase–coupled low-affinity antibody receptor, and autocrine signaling by a proinflammatory lipid (LTB4) through its GPCR. Mice deficient in PI3Kβ fared better than did controls in models of arthritis and inflammatory skin disease. These data implicate PI3Kβ in the integration of signals from tyrosine kinase–coupled receptors and GPCRs—and suggest that this isoform may be an effective therapeutic target in inflammatory diseases. Neutrophils are activated by immunoglobulin G (IgG)–containing immune complexes through receptors that recognize the Fc portion of IgG (FcγRs). Here, we used genetic and pharmacological approaches to define a selective role for the β isoform of phosphoinositide 3-kinase (PI3Kβ) in FcγR-dependent activation of mouse neutrophils by immune complexes of IgG and antigen immobilized on a plate surface. At low concentrations of immune complexes, loss of PI3Kβ alone substantially inhibited the production of reactive oxygen species (ROS) by neutrophils, whereas at higher doses, similar suppression of ROS production was achieved only by targeting both PI3Kβ and PI3Kδ, suggesting that this pathway displays stimulus strength–dependent redundancy. Activation of PI3Kβ by immune complexes involved cooperation between FcγRs and BLT1, the receptor for the endogenous proinflammatory lipid leukotriene B4. Coincident activation by a tyrosine kinase–coupled receptor (FcγR) and a heterotrimeric guanine nucleotide–binding protein (G protein)–coupled receptor (BLT1) may provide a rationale for the preferential activation of the β isoform of PI3K. PI3Kβ-deficient mice were highly protected in an FcγR-dependent model of autoantibody-induced skin blistering and were partially protected in an FcγR-dependent model of inflammatory arthritis, whereas combined deficiency of PI3Kβ and PI3Kδ resulted in near-complete protection in the latter case. These results define PI3Kβ as a potential therapeutic target in inflammatory disease.

Genetic identification and functional validation of FcγRIV as key molecule in autoantibody-induced tissue injury†

Autoantibody‐mediated diseases are clinically heterogeneous and often fail conventional therapeutic strategies. Gene expression profiling has helped to identify new molecular pathways in these diseases, although their potential as treatment targets largely remains to be functionally validated. Based on weighted gene co‐expression network analysis, we determined the transcriptional network in experimental epidermolysis bullosa acquisita (EBA), a paradigm of an antibody‐mediated organ‐specific autoimmune disease characterized by autoantibodies directed against type VII collagen. We identified 33 distinct and differentially expressed modules, including Fcγ receptor (FcγR) IV and components of the neutrophil‐associated enzyme system in autoantibody transfer‐induced EBA. Validation experiments, including functional analysis, demonstrated that FcγRIV expression on neutrophils crucially contributes to autoantibody‐induced tissue injury in the transfer model of EBA. Mice lacking the common γ‐chain of activating FcγRs, deficient in FcγRIV or treated with FcγRIV function blocking antibody, but not mice deficient in FcγRI, FcγRIIB, FcγRIII or both FcγRI and FcγRIII, were effectively protected from EBA. Skin disease was restored in γ‐chain‐deficient mice locally reconstituted with neutrophils from wild‐type, but not from γ‐chain‐deficient, mice. Our findings both genetically and functionally identify a novel disease‐related molecule, FcγRIV, in an autoantibody‐mediated disorder, which may be of importance for the development of novel targeted therapies. Copyright

Generation of antibodies of distinct subclasses and specificity is linked to H2s in an active mouse model of epidermolysis bullosa acquisita.

Epidermolysis bullosa acquisita (EBA) is an autoimmune blistering disease, characterized by antibodies to type VII collagen (COL7). EBA can be induced in mice by immunization with a fragment of the non-collagenous 1 domain of murine COL7. Contrary to other autoimmune diseases, e.g., rheumatoid arthritis, little is known about the genetic susceptibility for EBA. We therefore used the EBA mouse model to address the hypothesis that disease induction depends on the major histocompatibility complex (MHC) haplotype. Mice from different inbred strains were immunized with recombinant murine COL7. Five distinct responses were observed: induction of (i) severe disease in SJL/J (H2s) and female MRL/MpJ (H2k), (ii) mild and transient disease in C57Bl/10.s (H2s), (iii) microscopic blistering in DBA/1J (H2q), (iv) only presence of non-pathogenic autoantibodies in C57Bl/6J (H2b), NZM2410/J (H2z), BXD2 (H2b), and male MRL/MpJ, and (v) complete resistance to EBA in NOD/ShiLtJ (H2g7) and C57Bl/10.q (H2q) mice. Overall, susceptibility to EBA was strongly associated with H2s. In addition, the diseased phenotype was associated with autoantibodies to specific regions of COL7. Our findings show that induction of antibodies with a distinct specificity is linked to the MHC haplotype in experimental EBA. Furthermore, our data are the basis for future studies with the goal of identifying non-MHC EBA susceptibility genes.

Repetitive Immunization Breaks Tolerance to Type XVII Collagen and Leads to Bullous Pemphigoid in Mice

Bullous pemphigoid (BP) is a subepidermal autoimmune blistering disease of the elderly associated with considerable morbidity and mortality. As unspecific immunosuppressants are still the mainstay of BP therapy, several animal models, based on the passive transfer of autoantibodies or immune cells, have been developed to obtain a better understanding of the pathogenesis of BP and evaluate novel therapeutic interventions. We describe in this study an experimental model inducing BP by immunization of immunocompetent mice with a recombinant form of the immunodominant 15th noncollagenous domain of murine BP180 (type XVII collagen). The homologous noncollagenous 16A domain of human BP180 has previously been identified as an immunodominant region in human BP. Immunization of female SJL/J mice with the murine peptide led to clinical disease within 14 wk in 56% of mice. In contrast, none of the other strains developed blisters despite the presence of autoantibodies. The clinical disease manifested for at least 8 wk without further manipulation. This novel immunization-induced model reflects key immunopathological characteristics of human BP, including binding of complement-fixing autoantibodies along the dermal–epidermal junction, elevated total IgE serum levels, and infiltration of skin lesions with eosinophilic granulocytes. The use of immunocompetent mice and the induction of sustained clinical disease not requiring additional interventions make this immunization-induced mouse model most suitable to further explore the pathogenesis of BP and novel therapeutic interventions for this and other autoantibody-mediated diseases.

Enzymatic autoantibody glycan hydrolysis alleviates autoimmunity against type VII collagen

Autoantibody-mediated diseases comprise a heterogeneous group of disorders in which the pathogenic potential of autoantibodies has been clearly demonstrated. In general, their treatment relies on the long-term use of systemic corticosteroids and other immunosuppressants that are associated with considerable adverse reactions. EndoS, an endoglycosidase derived from Streptococcus pyogenes, specifically hydrolyzes the N-linked glycan of native IgG and has previously been shown to modulate the interaction between the Fc portion of autoantibody and Fcγ receptors on leukocytes. Here, different models of autoimmunity to type VII collagen, a structural protein of the dermal-epidermal junction (DEJ), were employed to explore the therapeutic potential of EndoS. First, pretreatment of otherwise pathogenic anti-murine type VII collagen (mCOL7) IgG with EndoS significantly reduced split formation at the DEJ in cryosections of murine skin and abrogated clinical disease in mice. Next, the effect of EndoS was also seen when the enzyme was injected into mice after pathogenic anti-mCOL7 IgG had been administered. Finally, to mimic the patient situation even closer, EndoS was applied in mice that had already developed clinical disease after immunization with mCOL7. In all EndoS-treated mice, disease progression was stopped, and in the majority of mice, clinical disease even regressed. Of note, EndoS was shown to hydrolyze already in vivo-bound pathogenic autoantibodies. In addition, EndoS treatment decreased lesional expression of activating FcγRs while increasing FcγRIIB expression.

Autoantibody-induced intestinal inflammation and weight loss in experimental epidermolysis bullosa acquisita.

Type VII collagen (COL7) is a major constituent of the cutaneous basement membrane. Loss of tolerance to COL7 leads to the blistering skin disease epidermolysis bullosa acquisita (EBA). Antibodies to COL7 have also been detected in patients with inflammatory bowel disease (IBD), yet reports on the expression of COL7 in the gut are controversial and a pathogenic relevance of anti‐COL7 autoantibodies in IBD has not been demonstrated. We therefore characterized the expression patterns of COL7 in murine gastrointestinal organs and investigated if anti‐COL7 antibodies induce an inflammatory response in the gut. COL7 expression was analysed on the mRNA and protein levels. Mice were injected with rabbit anti‐murine COL7 IgG (passive EBA) or immunized with a fragment of murine COL7 (active EBA). COL7 was found to be expressed in buccal mucosa, oesophagus, stomach, small intestine, and colon. In addition to skin blistering, in both passive and active EBA, autoantibodies bound to the gastrointestinal basement membrane, fixed complement, and led to recruitment of leukocytes. Furthermore, blister formation was observed in the oesophagus (40%/38% of mice in passive/active model), stomach (40%/63%), small intestine (20%/13%), and colon (20%/13%). Compared to control animals, we found a significantly reduced body weight in diseased mice, suggesting that autoantibody‐induced gastrointestinal inflammation is clinically relevant. Those observations may help us to understand the co‐incidence of IBD with EBA, and vice versa: The inflammatory response in IBD might expose novel antigens (COL7), which leads to the formation of anti‐COL7 antibodies. On the contrary, anti‐COL7 antibody‐induced gastrointestinal inflammation might pave the way for IBD pathogenesis. In summary, our results provide strong evidence that COL7 is expressed in different portions of the gut and that anti‐COL7 antibodies induce distinct gastrointestinal tissue damage. Copyright

Overexpression of the Flii gene increases dermal-epidermal blistering in an autoimmune ColVII mouse model of epidermolysis bullosa acquisita.

Epidermolysis bullosa (EB) is a severe genetic skin fragility syndrome characterized by blister formation. The molecular basis of EB is still largely unknown and wound healing in patients suffering from EB remains a major challenge to their survival. Our previous studies have identified the actin remodelling protein Flightless I (Flii) as an important mediator of wound repair. Here we identify Flii as a novel target involved in skin blistering. Flii expression was significantly elevated in 30 patients with EB, most prominently in patients with recessive dystrophic EB (RDEB) who have defects in production of type VII collagen (ColVII). Using an autoimmune ColVII murine model of EB acquisita (EBA) and an immunocompetent‐ColVII‐hypomorphic genetic mouse model of RDEB together with murine Flii alleles, we investigated the contribution of Flii to EB. Overexpression of Flii produced severe blistering post‐induction of EBA, while decreased Flii reduced blister severity, elevated integrin expression, and improved ColVII production. Flii+/− blistered skin showed reduced α‐SMA, TGF‐β1, and Smad 2/3 expression, suggesting that decreasing Flii may affect fibrosis. In support of this, Flii‐deficient fibroblasts from EBA mice were less able to contract collagen gels in vitro; however, addition of TGF‐β1 restored collagen contraction, suggesting an interplay between Flii and TGF‐β1. Elevated Flii gene and protein expression was further observed in the blisters of ColVII hypomorphic mice, a murine model of RDEB, suggesting that reducing Flii in blistered skin could be a potential new approach for treating patients with EB. Copyright

Animal models for autoimmune bullous dermatoses

Abstract:  Autoimmune bullous dermatoses are a group of severe diseases, which are clinically characterized by blisters and erosions of skin and/or mucous membranes. In order to investigate the pathogenesis of these potentially life‐threatening diseases and to develop more specific therapeutic approaches, animal models have been developed that aim to reproduce the clinical, histological and immunopathological findings. We here review established and novel animal models of autoimmune skin blistering diseases and discuss their applications and limitations.

Pathogenicity of Autoantibodies in Anti-p200 Pemphigoid

Recently, the C-terminus of laminin γ1 has been identified as target antigen in anti-p200 pemphigoid and the disease was renamed as anti-laminin γ1 pemphigoid. However, the pathogenic relevance of these autoantibodies has not yet been demonstrated. Therefore, we employed an ex vivo model of autoantibody-mediated leukocyte-dependent neutrophil activation and dermal-epidermal separation (DES) using cryosections of human skin. We showed that anti-p200 pemphigoid sera (n = 7) induced DES in a time-dependent manner, in contrast to sera from healthy controls. Furthermore, laminin γ1-specific IgG and serum depleted from anti-laminin γ1 reactivity were generated using the recombinant C-terminus of laminin γ1 (LAMC1-term; amino acids 1364 to 1609). Interestingly, both fractions labeled the dermal-epidermal-junction (DEJ) by indirect immunofluorescence microscopy on human foreskin and recognized a 200 kDa protein by immunoblotting with dermal extract. Human and rabbit IgG against LAMC1-cterm failed to attract neutrophils at the DEJ and to induce DES. In contrast, patient serum depleted from LAMC1-cterm reactivity led to the same extent of DES as non-depleted IgG. Repeated injection of rabbit anti-murine LAMC1-cterm IgG into both neonatal and adult C57BL/6mice as well as repetitive immunization of various mouse strains with murine LAMC1-cterm failed to induce macro- and microscopic lesions. In all mice, circulating anti-LAMC1-cterm antibodies were present, but only in some mice, IgG deposits were seen at the DEJ. We conclude that autoantibodies in anti-p200 pemphigoid sera are pathogenic while pathogenicity is not mediated by autoantibodies against laminin γ1. Further studies are needed to identify the pathogenically relevant autoantigen in anti-p200 pemphigoid.

Clearance rates of circulating and tissue‐bound autoantibodies to type VII collagen in experimental epidermolysis bullosa acquisita

Background  Epidermolysis bullosa acquisita (EBA) is a severe autoimmune skin disease characterized by autoantibodies to type VII collagen, the major component of anchoring fibrils. In this and other autoimmune bullous dermatoses, specific autoantibody detection systems are not only of diagnostic use but also allow monitoring of circulating and skin‐bound autoantibodies during the course of the disease. However, little is known about their natural clearance rates in these different compartments.