Endogenous relaxin regulates collagen deposition in an animal model of allergic airway disease.

We examined the relationship among relaxin (a peptide hormone that stimulates collagen degradation), airway fibrosis, other changes of airway remodeling, and airway hyperresponsiveness (AHR) in an animal model of allergic airway disease. Eight- to 10-wk-old relaxin gene-knockout (RLX(-/-)) and wild-type (RLX(+/+)) mice were sensitized with ovalbumin (OVA) or saline ip at d 0 and 14 and challenged three times per week for 6 wk with nebulized 2.5% OVA or saline. Saline-treated control RLX(+/+) and RLX(-/-) mice had equivalent collagen expression and baseline airway responses. OVA-treated RLX(-/-) mice developed airway inflammation equivalent to that in OVA-treated RLX(+/+) mice. However, OVA-treated RLX(-/-) mice had markedly increased lung collagen deposition as compared with OVA-treated RLX(+/+) and saline-treated mice (all P < 0.05). Collagen was predominantly deposited in the subepithelial basement membrane region and submucosal regions in both OVA-treated RLX(+/+) and RLX(-/-) mice. The increased collagen measured in OVA-treated RLX(-/-) mice was associated with reduced matrix metalloproteinase (MMP)-9 (P < 0.02) expression and failure to up-regulate matrix metalloproteinase-2 expression, compared with levels in OVA-treated RLX(+/+) mice. Goblet cell numbers were equivalent in OVA-treated RLX(-/-) and RLX(+/+) mice and increased, compared with saline-treated animals. Both OVA-treated RLX(+/+) and RLX(-/-) mice developed similar degrees of AHR after OVA treatment. These findings demonstrate a critical role for relaxin in the inhibition of lung collagen deposition during an allergic inflammatory response. Increased deposition of collagen per se did not influence airway epithelial structure or AHR.

Investigating the role of relaxin in the regulation of airway fibrosis in animal models of acute and chronic allergic airway disease.

Airway remodeling is a characteristic feature of asthma that leads to chronic irreversible airway obstruction. Fibrosis in the basement membrane region is a hallmark of remodeling in asthma that is not found in other diseases. In the outlined studies, we investigated the relationship between relaxin and airway fibrosis in asthma using acute and chronic models of allergic airway disease. These studies confirm a critical role for relaxin, in the regulation of collagen deposition in the airway/lung in animal models of allergic airway disease.

(Pro)insulin-specific regulatory T cells.

Regulatory anti-diabetogenic T cells (T(reg)) can be induced by the mucosal administration of insulin or proinsulin peptides, in the non-obese diabetic (NOD) mouse model of autoimmune type 1 diabetes. Naso-respirtory insulin (which avoids insulin degradation) induces CD8+ alpha(alpha) TCR gamma(delta) T(reg) whereas peptides that bind to the NOD MHC class II molecule, I-Ag7, insulin B9-23 and proinsulin B24-C36, induce CD4+ T(regs) Following naso-respiratory delivery of insulin to NOD mice increased numbers of CD8+ gamma(delta) T cells expressing interleukin (IL)10 are detected in the pancreatic lymph nodes. Neonatal (3 day) thymectomy (NTX) dramatically accelerates diabetes development in NOD mice, associated with lymphopaenia and a block in the maturation of mucosal intrepithelial lymphocytes (IEL), especially extrathymic-derived CD8+ alpha(alpha) TCR gamma(delta) IEL. Regulatory anti-diabetogenic T cells cannot be elicited by naso-respiratory insulin in NTX-NOD mice. Reconstitution of NTX-NOD mice with CD8+ alpha(alpha) TCR gamma(delta) T cells prevents diabetes. CD8+ gamma(delta) T(reg) are conceivably physiological and insulin-specific, induced by exposure to insulin in maternal milk. These findings infer an immunoregulatory role for extrathymic-derived IEL, developing under the influence of the thymus and conditioned by early exposure to the exogenous environment.