IL-4-dependent effector phase in autoimmune exocrinopathy as defined by the NOD.IL-4-gene knockout mouse model of Sjögren's syndrome.

NOD mice manifest many features of autoimmune exocrinopathy (Sjögren's syndrome), a disease generally characterized by a chronic, progressive immunological attack against the exocrine tissues of the salivary and lacrimal glands. Previous studies using the NOD congenic partner strain, NOD.Igmu(null), defined an important role for B lymphocytes in the development of xerostomia, implicating autoantibodies reactive with the acetylcholine muscarinic receptor (M3R) as the possible effector mechanism. In the present study, we have examined the impact of the cytokine, interleukin (IL)-4, on autoimmune exocrinopathy by using the IL-4 gene knockout (KO) NOD mouse strain, NOD.IL-4-/-. Despite manifesting the physiological aberrations and marked leukocytic infiltration of the salivary glands characteristic of autoimmune xerostomia in NOD mice, the NOD.IL-4-/- mice do not develop xerostomia. However, NOD.IL-4-/- mice that received adoptively transferred T lymphocytes derived from NOD.Igmu-/- mice progress to xerostomia, thereby reversing the defect. While progression or lack of progression to xerostomia correlated with the ability of the NOD.IL-4-/- mice to express detectable anti-M3R autoantibodies, the precise mechanism of how IL-4 influences the development of autoimmune xerostomia remains speculative.

Basal keratinocytes from uninvolved psoriatic skin exhibit accelerated spreading and focal adhesion kinase responsiveness to fibronectin.

We previously proposed that the keratinocyte hyperproliferative state in psoriatic skin results from a combination of T cell cytokine interaction with basal keratinocytes that exist in a primed state. We now provide evidence that basal keratinocytes from psoriatic uninvolved skin are in a preactivated state with regard to their interaction with fibronectin. Freshly isolated basal keratinocytes (K(1)/K(10)(-)) from non-lesional psoriatic skin demonstrated a significantly higher percentage of spreading cells 1 h after plating on fibronectin-coated plates than keratinocytes isolated from normal skin (p =0.0002). No differences were observed on collagen-laminin-coated plates, however. The keratinocyte spreading on fibronectin-coated plates involved alpha 5 beta 1 and alpha V beta 1 integrins. To address the potential signaling cascades that may respond to integrin changes in psoriatic keratinocytes, focal adhesion kinase changes were assessed. The percentage of keratinocytes from psoriatic uninvolved skin that exhibit positive focal adhesion kinase staining was significantly greater than the percentage from healthy volunteers after 1 h incubation on fibronectin (p =0.006). Additionally, focal adhesion kinase isolated from uninvolved psoriatic keratinocytes had a greater degree of tyrosine phosphorylation. Thus, the proliferative effect of fibronectin in combination with T cell lymphokines on psoriatic uninvolved basal keratinocyte progenitors may be due to abnormal in vivo integrin-driven focal adhesion kinase activity and downstream signaling.

Evidence for antimuscarinic acetylcholine receptor antibody-mediated secretory dysfunction in nod mice.

OBJECTIVE: Antibodies directed against general and specific target-organ autoantigens are present in the sera of human patients and animal models with autoimmune disease. The relevance of these autoantibodies to the disease process remains ambiguous in most cases. In autoimmune exocrinopathy (Sjögren's syndrome), autoantibodies to the intracellular nuclear proteins SSA/Ro and SSB/La, as well as the cell surface muscarinic cholinergic receptor (M3) are observed. To evaluate the potential role of these factors in the loss of secretory function of exocrine tissues, a panel of monoclonal and polyclonal antibodies was developed for passive transfer into the NOD animal model. METHODS: Monoclonal antibodies to mouse SSB/La, rat M3 receptor, and a rabbit polyclonal antiparotid secretory protein antibody were obtained for this study. These antibody reagents were subsequently infused into NOD-scid mice. Saliva flow rates were subsequently monitored over a 72-hour period. Submandibular gland lysates were examined by Western blotting for alteration of the distribution of the water channel protein aquaporin (AQP). RESULTS: Evaluation of the secretory response indicated that only antibodies directed toward the extracellular domains of the M3 receptor were capable of mediating the exocrine dysfunction aspect of the clinical pathology of the autoimmune disease. In vitro stimulation with a muscarinic agonist of submandibular gland cells isolated from mice treated with anti-M3 antibody, but not saline or the isotype control, failed to translocate AQP to the plasma membrane. CONCLUSION: These findings define a clear role for the humoral immune response and the targeting of the cell surface M3 signal transduction receptor as primary events in the development of clinical symptoms of autoimmune exocrinopathy. Furthermore, the anti-M3 receptor activity may negatively affect the secretory response through perturbation of normal signal transduction events, leading to translocation of the epithelial cell water channel.