N-glycosylation and disulfide bond formation are two essential steps in protein folding that occur in the endo-plasmic reticulum (ER) and reciprocally influence each other. Here, to analyze crosstalk between N-glycosylation and oxidation, we investigated how the protein disulfide oxidase ERO1-alpha affects glycosylation of the angiogenic VEGF121, a key regulator of vascular homeostasis. ERO1 deficiency, while retarding disulfide bond formation in VEGF121, increased utilization of its single N-glycosylation sequon, which lies close to an intra-polypeptide disulfide bridge, and concomitantly slowed its secretion. Unbiased mass-spectrometric analysis revealed interactions between VEGF121 and N-glycosylation pathway proteins in ERO1-knockout (KO), but not wild-type cells. Notably, MAGT1, a thioredoxin-containing component of the post-translational oligosaccharyl-transferase complex, was a major hit exclusive to ERO1-deficient cells. Thus, both a reduced rate of formation of disulfide bridges, and the increased trapping potential of MAGT1 may increase N-glycosylation of VEGF121. Extending our investigation to tissues, we observed altered lectin staining of ERO1 KO breast tumor xenografts, implicating ERO1 as a physiologic regulator of protein N-glycosylation. Our study, highlighting the effect of ERO1 loss on N-glycosylation of proteins, is particularly relevant not only to angiogenesis but also to other cancer patho-mechanisms in light of recent findings suggesting a close causal link between alterations in protein glycosylation and cancer development.

Varone, E., Chernorudskiy, A., Cherubini, A., Cattaneo, A., Bachi, A., Fumagalli, S., et al. (2022). ERO1 alpha deficiency impairs angiogenesis by increasing N-glycosylation of a proangiogenic VEGFA. REDOX BIOLOGY, 56(October 2022) [10.1016/j.redox.2022.102455].

ERO1 alpha deficiency impairs angiogenesis by increasing N-glycosylation of a proangiogenic VEGFA

Erol G.;
2022

Abstract

N-glycosylation and disulfide bond formation are two essential steps in protein folding that occur in the endo-plasmic reticulum (ER) and reciprocally influence each other. Here, to analyze crosstalk between N-glycosylation and oxidation, we investigated how the protein disulfide oxidase ERO1-alpha affects glycosylation of the angiogenic VEGF121, a key regulator of vascular homeostasis. ERO1 deficiency, while retarding disulfide bond formation in VEGF121, increased utilization of its single N-glycosylation sequon, which lies close to an intra-polypeptide disulfide bridge, and concomitantly slowed its secretion. Unbiased mass-spectrometric analysis revealed interactions between VEGF121 and N-glycosylation pathway proteins in ERO1-knockout (KO), but not wild-type cells. Notably, MAGT1, a thioredoxin-containing component of the post-translational oligosaccharyl-transferase complex, was a major hit exclusive to ERO1-deficient cells. Thus, both a reduced rate of formation of disulfide bridges, and the increased trapping potential of MAGT1 may increase N-glycosylation of VEGF121. Extending our investigation to tissues, we observed altered lectin staining of ERO1 KO breast tumor xenografts, implicating ERO1 as a physiologic regulator of protein N-glycosylation. Our study, highlighting the effect of ERO1 loss on N-glycosylation of proteins, is particularly relevant not only to angiogenesis but also to other cancer patho-mechanisms in light of recent findings suggesting a close causal link between alterations in protein glycosylation and cancer development.
Articolo in rivista - Articolo scientifico
Angiogenesis; ERO1 alpha; N-glycosylation; Oxidative folding; VEGFA;
English
27-ago-2022
2022
56
October 2022
102455
open
Varone, E., Chernorudskiy, A., Cherubini, A., Cattaneo, A., Bachi, A., Fumagalli, S., et al. (2022). ERO1 alpha deficiency impairs angiogenesis by increasing N-glycosylation of a proangiogenic VEGFA. REDOX BIOLOGY, 56(October 2022) [10.1016/j.redox.2022.102455].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/511019
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