Lung-restricted inhibition of Janus kinase 1 is effective in rodent models of asthma.

Preclinical and clinical evidence indicates that a subset of asthma is driven by type 2 cytokines such as interleukin-4 (IL-4), IL-5, IL-9, and IL-13. Additional evidence predicts pathogenic roles for IL-6 and type I and type II interferons. Because each of these cytokines depends on Janus kinase 1 (JAK1) for signal transduction, and because many of the asthma-related effects of these cytokines manifest in the lung, we hypothesized that lung-restricted JAK1 inhibition may confer therapeutic benefit. To test this idea, we synthesized iJak-381, an inhalable small molecule specifically designed for local JAK1 inhibition in the lung. In pharmacodynamic models, iJak-381 suppressed signal transducer and activator of transcription 6 activation by IL-13. Furthermore, iJak-381 suppressed ovalbumin-induced lung inflammation in both murine and guinea pig asthma models and improved allergen-induced airway hyperresponsiveness in mice. In a model driven by human allergens, iJak-381 had a more potent suppressive effect on neutrophil-driven inflammation compared to systemic corticosteroid administration. The inhibitor iJak-381 reduced lung pathology, without affecting systemic Jak1 activity in rodents. Our data show that local inhibition of Jak1 in the lung can suppress lung inflammation without systemic Jak inhibition in rodents, suggesting that this strategy might be effective for treating asthma.

Adiponectin represses gluconeogenesis independent of insulin in hepatocytes.

Adiponectin plays important roles in regulating insulin sensitivity and atherogenesis. Adiponectin has been shown to suppress hepatic glucose production in rodents. It has not been reported whether ectopically expressed adiponectin could regulate glucose metabolism in cultured hepatocyte-like cells. In the current study, the effect of adiponectin on glucose production was analyzed by ectopically expressing the protein in hepatoma H4IIE cells using an adenovirus delivery system to generate both human full-length and the globular domain of the protein. Expression of adiponectin in hepatoma H4IIE cells, in the absence of insulin, suppressed expression of the genes encoding glucose-6-phosphatase and phosphoenolpyruvate carboxykinase, rate-limiting enzymes in the gluconeogenic pathway. Furthermore, expression of adiponectin in H4IIE cells suppressed glucose production from lactate and pyruvate. Purified recombinant human adiponectin also reduced glucose production in H4IIE cells and in rat primary hepatocytes in the absence of insulin. These data suggest that adiponectin protein could exert its function independent of the presence of insulin in these culture systems.