An engineered immunomodulatory IgG1 Fc suppresses autoimmune inflammation through pathways shared with i.v. immunoglobulin
Sunny L. Sneed, … , Pamela B. Conley, Robert M. Anthony
Sunny L. Sneed, … , Pamela B. Conley, Robert M. Anthony
Published February 15, 2024
Citation Information: J Clin Invest. 2024;134(4):e172980. https://doi.org/10.1172/JCI172980.
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Research Article Immunology

An engineered immunomodulatory IgG1 Fc suppresses autoimmune inflammation through pathways shared with i.v. immunoglobulin

Abstract

Immunoglobulin G (IgG) antibodies in the form of high-dose intravenous immunoglobulin (IVIG) exert immunomodulatory activity and are used in this capacity to treat inflammatory and autoimmune diseases. Reductionist approaches have revealed that terminal sialylation of the single asparagine-linked (N-linked) glycan at position 297 of the IgG1 Fc bestows antiinflammatory activity, which can be recapitulated by introduction of an F241A point mutation in the IgG1 Fc (FcF241A). Here, we examined the antiinflammatory activity of CHO-K1 cell–produced FcF241A in vivo in models of autoimmune inflammation and found it to be independent of sialylation. Intriguingly, sialylation markedly improved the half-life and bioavailability of FcF241A via impaired interaction with the asialoglycoprotein receptor ASGPR. Further, FcF241A suppressed inflammation through the same molecular pathways as IVIG and sialylated IgG1 Fc and required the C-type lectin SIGN-R1 in vivo. This contrasted with FcAbdeg (efgartigimod), an engineered IgG1 Fc with enhanced neonatal Fc receptor (FcRn) binding, which reduced total serum IgG concentrations, independent of SIGN-R1. When coadministered, FcF241A and FcAbdeg exhibited combinatorial antiinflammatory activity. Together, these results demonstrated that the antiinflammatory activity of FcF241A requires SIGN-R1, similarly to that of high-dose IVIG and sialylated IgG1, and can be used in combination with other antiinflammatory therapeutics that rely on divergent pathways, including FcAbdeg.

Authors

Sunny L. Sneed, Brian B. Reese, Ana F.S. Laureano, Sneha Ratnapriya, Isabella Fraschilla, Kate L. Jeffrey, Greg P. Coffey, Pamela B. Conley, Robert M. Anthony

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Figure 1

Manipulation of Fc glycosylation of CHO-K1–produced FcF241A.

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Manipulation of Fc glycosylation of CHO-K1–produced FcF241A. (A) Sequenc...
(A) Sequence alignment of WT human IgG1 Fc (FcWT) and FcF241A, with the gray box designating residue 241 and the black box designating N297 in both sequences. Graphic of human IgG Fc structure with positions of F241 (gray hexagon) and N297 (black hexagon) marked, showing their relative proximity and location within the interior of the Fc structure. (B) Schematic representing the different N-linked glycoforms that may be present on Fc N297 and their nomenclature. Blue squares, N-acetylglucosamine (GlcNAc); yellow circles, galactose; green circles, mannose; red triangles, fucose; purple diamonds, sialic acid. (C) CHO-K1 cells were transfected with plasmids for either FcWT or FcF241A, and then N297 glycoforms on the purified Fc products were analyzed via HPLC. (D) Percentages of N297 glycans from CHO-K1 cells expressing FcF241A (green), FcF241A transfected with ST6GAL1 (FcF241A/ST6, blue), FcF241A transfected with B4GALT1 and ST6GAL1 (FcF241A/B4ST6, purple), and FcF241A transfected with siRNA against SLC35A1 (FcF241A/siSLC, maroon). Fc glycoforms were analyzed via HPLC. Bar graphs are plotted as means with SDs in C and D.