N-glycosylation in the SERPIN domain of the C1-esterase inhibitor in hereditary angioedema
Zhen Ren, John Bao, Shuangxia Zhao, Nicola Pozzi, H. James Wedner, John P. Atkinson
Zhen Ren, John Bao, Shuangxia Zhao, Nicola Pozzi, H. James Wedner, John P. Atkinson
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Research Article Immunology

N-glycosylation in the SERPIN domain of the C1-esterase inhibitor in hereditary angioedema

Abstract

Hereditary angioedema is an autosomal dominant disorder caused by defects in C1-esterase inhibitor (C1-INH), resulting in poorly controlled activation of the kallikrein-kinin system and bradykinin overproduction. C1-INH is a heavily glycosylated protein in the serine protease inhibitor (SERPIN) family, yet the role of these glycosylation sites remains unclear. To elucidate the functional impact of N-glycosylation in the SERPIN domain of C1-INH, we engineered 4 sets consisting of 26 variants at or near the N-linked sequon (NXS/T). Among these, 6 are reported in patients with hereditary angioedema and 5 are known C1-INH variants without accessible clinical histories. We systematically evaluated their expression, structure, and functional activity with C1s̄, FXIIa, and kallikrein. Our findings showed that of the 11 reported variants, 7 were deleterious. Deleting N at the 3 naturally occurring N-linked sequons (N238, N253, and N352) resulted in pathologic consequences. Altering these sites by substituting N with A disrupted N-linked sugar attachment, but preserved protein expression and function. Furthermore, an additional N-linked sugar generated at N272 impaired C1-INH function. These findings highlight the importance of N-linked sequons in modulating the expression and function of C1-INH. Insights gained from identifying the pathological consequences of N-glycan variants should assist in defining more tailored therapy.

Authors

Zhen Ren, John Bao, Shuangxia Zhao, Nicola Pozzi, H. James Wedner, John P. Atkinson

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Figure 5

N352 glycosylation site variants.

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N352 glycosylation site variants. (A) WB analysis of supernatants from t...
(A) WB analysis of supernatants from transfected WT C1-INH and variant constructs of N352 under reducing conditions. One representative experiment of 3 is shown. Recombinant expression of N352A, N352S, and S354G was comparable to WT, whereas N352del, L353P, and S354del were barely secreted. The secretion of N352I was decreased (see Table 1). The consensus sequence of N352 glycosylation (NXS/T) is highlighted in blue, orange, and red. (BE) Binding analysis of N352 glycosylation site variants. (B and D) Representation of PKa and FXIIa binding of N352A, N352S, N352I, and S354G compared with WT. (C and E) N352I and S354G demonstrated impaired binding to both PKa and FXIIa. N352S showed decreased binding to PKa, but not to FXIIa. Data represent mean ± SEM of 3 independent experiments. **P < 0.01, ***P < 0.001, ****P < 0.0001 by 1-way ANOVA with Dunnett’s multiple-comparison test. (F) Structural analysis of N352. N352 is located in the loop connecting strands 2 and 3 in β-sheet B (S2B and S3B), which is the hydrophobic core of C1-INH. N352del disrupts the packing of the hydrophobic core and leads to protein misfolding. The substitution with L353P can cause structural disturbances by disrupting hydrogen bridges and affecting the packing of the loop between S2A and S3A, thus leading to protein misfolding. Yellow dashed line, hydrogen bond.