Thrombospondin-derived peptide attenuates Sjögren's syndrome-associated ocular surface inflammation in mice.

Sjögren's syndrome is the second most common rheumatic disease in which autoimmune response targets exocrine glands (salivary and lacrimal glands) result in clinical symptoms of dry mouth and dry eye. Inflammation of the lacrimal gland induces tear abnormalities that contribute to the inflammation of the ocular surface, which includes ocular mucosa. Thrombospondin-1 (TSP-1) plays a critical regulatory role in the ocular mucosa and as such TSP-1-/- mice develop spontaneously chronic ocular surface inflammation associated with Sjögren's syndrome. The autoimmune pathology is also accompanied by a peripheral imbalance in regulatory (Treg ) and inflammatory Th17 effectors. In this study, we demonstrate an in-vitro effect of a CD47-binding TSP-derived peptide in the induction of transforming growth factor (TGF)-ß1-secreting forkhead box protein 2 (Foxp3+ ) Tregs from activated CD4+ CD25- T cells and the inhibition of pathogenic T helper type 17 (Th17)-promoting interleukin (IL)-23 derived from antigen-presenting cells. The in-vivo administration of this peptide promotes Foxp3+ Treg induction and inhibition of Th17 development. Consistent with these results, topical administration of CD47-binding TSP peptide, both before and after the onset of the disease, attenuates clinical symptoms of SS-associated dry eye in TSP-1-/- mice. Augmented expression of Foxp3 detected in the draining lymph nodes of TSP peptide -treated mice compared to those treated with control peptide suggests the ability of TSP peptide to restore peripheral immune imbalance. Thus, our results suggest that TSP-derived peptide attenuates Sjögren's syndrome-associated dry eye and autoimmune inflammation by preventing Th17 development while promoting the induction of Tregs . Collectively, our data identify TSP-derived peptide as a novel therapeutic option to treat autoimmune diseases.

A nanomedicine to treat ocular surface inflammation: performance on an experimental dry eye murine model.

MUC5AC is a glycoprotein with gel-forming properties, whose altered expression has been implicated in the pathogenesis of dry eye disease. The aim of our study was to achieve an efficient in vivo transfection of MUC5AC, restore its normal levels in an inflamed ocular surface and determine whether restored MUC5AC levels improve ocular surface inflammation. Cationized gelatin-based nanoparticles (NPs) loaded with a plasmid coding a modified MUC5AC protein (pMUC5AC) were instilled in healthy and experimental dry eye (EDE) mice. MUC5AC expression, clinical signs, corneal fluorescein staining and tear production were evaluated. Ocular specimens were processed for histopathologic evaluation, including goblet cell count and CD4 immunostaining. Neither ocular discomfort nor irritation was observed in vivo after NP treatment. Expression of modified MUC5AC was significantly higher in ocular surface tissue of pMUC5AC-NP-treated animals than that of controls. In healthy mice, pMUC5AC-NPs had no effect on fluorescein staining or tear production. In EDE mice, both parameters significantly improved after pMUC5AC-NP treatment. Anterior eye segment of treated mice showed normal architecture and morphology with lack of remarkable inflammatory changes, and a decrease in CD4+ T-cell infiltration. Thus, pMUC5AC-NPs were well tolerated and able to induce the expression of modified MUC5A in ocular surface tissue, leading to reduction of the inflammation and, consequently improving the associated clinical parameters, such as tear production and fluorescein staining. These results identify a potential application of pMUC5AC-NPs as a new therapeutic modality for the treatment of dry eye disease.

Modulation of conjunctival goblet cell function by inflammatory cytokines.

Ocular surface inflammation associated with Sjögren's syndrome is characterized by a loss of secretory function and alteration in numbers of mucin secreting goblet cells. Such changes are a prominent feature of ocular surface inflammatory diseases and are attributed to inflammation; however, the exact effect of the inflammatory cytokines on conjunctival goblet cell function remains largely unknown. In this study, we developed a primary culture of mouse goblet cells from conjunctival tissue and evaluated the effects on their function by inflammatory cytokines detected in the conjunctiva of mouse model of Sjögren's syndrome (Thrombospondin-1 deficient mice). We found that apoptosis of goblet cells was primarily induced by TNF-α and IFN-γ. These two cytokines also inhibited mucin secretion by goblet cells in response to cholinergic stimulation, whereas IL-6 enhanced such secretion. No changes in secretory response were detected in the presence of IL-13 or IL-17. Goblet cells proliferated to varying degrees in response to all the tested cytokines with the greatest response to IL-13 followed by IL-6. Our results therefore reveal that inflammatory cytokines expressed in the conjunctiva during an ocular surface disease directly disrupt conjunctival goblet cell functions, compromising the protective function of tears, thereby contributing to ocular surface damage.