ANCA-associated vasculitis is linked to carriage of the Z allele of α1 antitrypsin and its polymers.

BACKGROUND: Small studies have linked α1 antitrypsin (α1AT) deficiency to patients with antineutrophil cytoplasmic antibodies (ANCA)-associated vasculitis (AAV). OBJECTIVE: To test the validity and the mechanism of this association between α1AT and AAV. METHODS: The distribution of α1AT deficiency alleles Z and S was compared between 856 White Europeans with AAV and 1505 geographic and ethnically matched healthy controls. Genotyping was performed by allelic discrimination assay. RESULTS: were compared between cases and controls using χ(2) tests. The serum and renal biopsies for α1AT polymers were compared using the polymer-specific 2C1 antibody. The role of α1AT polymers in promoting inflammation was investigated by examining their ability to prime neutrophils for ANCA activation as assessed by CD62L shedding, superoxide production and myeloperoxidase degranulation. Results The Z but not the S allele was over-represented in the patients compared with controls (HR=2.25, 95% CI 1.60 to 3.19). Higher concentrations of polymers of α1AT were detected in serum from patients carrying the Z allele than in those not carrying the Z allele (median (IQR) 1.40 (0.91-3.32) mg/dl vs 0.17 (0.06-0.28) mg/dl, p<0.001); polymers of α1AT were also seen in the renal biopsy of a patient with vasculitic glomerulonephritis. Polymers of α1AT primed neutrophils with CD62L shedding and increased superoxide production following ANCA activation. Carriage of the Z allele was not associated with disease severity, survival or relapse. CONCLUSIONS: The Z but not the S deficiency allele is associated with AAV. Polymers of α1AT are present in the serum and glomeruli of at least some patients with the Z allele, which may promote inflammation through priming of neutrophils.

Mechanisms of emphysema in alpha1-antitrypsin deficiency: molecular and cellular insights.

The severe, early onset emphysema that occurs in patients with circulating deficiency of alpha(1)-antitrypsin (alpha(1)-AT) attests to the importance of this protease inhibitor in maintaining lung parenchymal integrity. It has led to the powerful concept of protease:antiprotease balance being crucial to alveolar homeostasis. Pathogenic mutations cause alpha(1)-AT to self-associate into polymer chains that accumulate intracellularly rather than proceeding along the secretory pathway. Polymerisation of alpha(1)-AT abolishes antiprotease activity and confers toxic gain-of-function effects. Since alpha(1)-AT is predominantly synthesised in the liver, where it does not play a major homeostatic role, the directly toxic effects of polymerisation are clearest here. However, data from molecular, cellular, animal and ex vivo studies indicate that intrapulmonary polymerisation of alpha(1)-AT and inflammatory positive feedback loops may augment the destructive effects of decreased antiprotease levels in the lung. This review integrates the findings from these different approaches and highlights how multiple pathways may converge to give the severe, panacinar emphysema phenotype seen in alpha(1)-AT deficiency.