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Abstract
Background
Duchenne muscular dystrophy (DMD) is a progressive muscle‐wasting disease caused by mutations in the dystrophin gene, which leads to structural instability of the dystrophin–glycoprotein‐complex with subsequent muscle degeneration. In addition, muscle inflammation has been implicated in disease progression and therapeutically addressed with glucocorticosteroids. These have numerous adverse effects. Treatment with human immunoglobulin G (IgG) improved clinical and para‐clinical parameters in the early disease phase in the well‐established mdx mouse model. The aim of the present study was to confirm the efficacy of IgG in a long‐term pre‐clinical study in mdx mice.
Methods
IgG (2 g/kg body weight) or NaCl solution as control was administered monthly over 18 months by intraperitoneal injection in mdx mice beginning at 3 weeks of age. Several clinical outcome measures including endurance, muscle strength, and echocardiography were assessed. After 18 months, the animals were sacrificed, blood was collected for analysis, and muscle samples were obtained for ex vivo muscle contraction tests, quantitative PCR, and histology.
Results
IgG significantly improved the daily voluntary running performance (1.9 m more total daily running distance, P < 0.0001) and slowed the decrease in grip strength by 0.1 mN, (P = 0.018). IgG reduced fatigability of the diaphragm (improved ratio to maximum force by 0.09 ± 0.04, P = 0.044), but specific tetanic force remained unchanged in the ex vivo muscle contraction test. Cardiac function was significantly better after IgG, especially fractional area shortening (P = 0.012). These results were accompanied by a reduction in cardiac fibrosis and the infiltration of T cells (P = 0.0002) and macrophages (P = 0.0027). In addition, treatment with IgG resulted in a significant reduction of the infiltration of T cells (P ≤ 0.036) in the diaphragm, gastrocnemius, quadriceps, and a similar trend in tibialis anterior and macrophages (P ≤ 0.045) in gastrocnemius, quadriceps, tibialis anterior, and a similar trend in the diaphragm, as well as a decrease in myopathic changes as reflected by a reduced central nuclear index in the diaphragm, tibialis anterior, and quadriceps (P ≤ 0.002 in all).
Conclusions
The present study underscores the importance of an inflammatory contribution to the disease progression of DMD. The data demonstrate the long‐term efficacy of IgG in the mdx mouse. IgG is well tolerated by humans and could preferentially complement gene therapy in DMD. The data call for a clinical trial with IgG in DMD.
Our modern understanding of the hygiene hypothesis is that bacteria are not only the cause of disease but also essential for a healthy immune response and regulation. Varied microbial exposure prenatally and in early childhood protects us from pathological immune reactions such as autoimmune diseases and allergies. Against this background, the hypothesis that bacteria can act as allergens appears paradoxical. Nevertheless, there is growing evidence that Staphylococcus aureus (S. aureus) is associated with allergic reactions and serine protease-like proteins (Spls) produced by S. aureus have been identified as pacemakers of allergic reactions. To open prospects for treatment or causal therapy in patients at risk, the underlying mechanism of allergy induction by Spls was studied, focusing on the IL-33 pathway in airway inflammation. In a murine asthma model C57BL/6 J wild-type mice were repeatedly exposed to SplD via intratracheal application. After two weeks a Th2-biased inflammatory response was observed in the airways: IL-33 and eotaxin production, eosinophilia, bronchial hyperreactivity, and goblet cell hyperplasia. Blocking IL-33 activity with its soluble receptor ST2 counteracted these effects: significantly decreased numbers of eosinophils, IL-13+ type 2 ILCs, IL-13+CD4+ T cells as well as reduced IL-5 and IL-13 production by lymph node cells were observed. This study indicates that SplD induces allergic airway inflammation via the IL-33/ST2 axis. IL-33 upregulation was not accompanied by cell death, which indicates that IL-33 may not be passively released by dying cells but actively secreted by the airway epithelium. Future identification of the physiological substrates of the Spls may help to shed light on the source of IL-33 in SplD-induced airway inflammation.
While the causes of allergy induction by S. aureus Spls were addressed by investigating the underlying mechanism, the consequences of this were also of interest: Does the pro-allergenic response to S. aureus affect patients exposed to S. aureus in their airways? Therefore, the humoral and cellular immune response against Spls was studied in cystic fibrosis (CF) patients who are more frequently colonized with S. aureus than the healthy population and suffer from frequent recurrent airway infections. In this patient cohort a Th2 shift of the Spl-specific immune response became evident, including high Spl-specific serum IgE levels, strong induction of Th2 cell differentiation and production of type 2 cytokines following ex vivo stimulation with recombinant Spls. The observed response seems to be specific for Spls rather than being a general feature of S. aureus proteases since other putative allergens of S. aureus (ScpA, SspB) did not show increased IgE binding in CF sera. The Th2-driven immune response might impede antibacterial clearance and worsen the clinical picture. Larger clinical studies are needed to validate this notion by correlating the anti-S. aureus immune response with clinical parameters and testing new therapy options.
These results and findings shed light on a novel, possibly underestimated facet of the immune response against S. aureus and give impetus for further research on bacterial allergens in general, reaching beyond the species S. aureus.