From Rhesus macaque to human: structural evolutionary pathways for immunoglobulin G subclasses

From Rhesus macaque to human: structural evolutionary pathways for immunoglobulin G subclasses

The Old World monkey, Rhesus macaque (Macaca mulatta, Mm), is frequently used as a primate model organism in the study of human disease and to test new vaccines/antibody treatments despite diverging before chimpanzees and orangutans. Mm and humans share 93% genome identity with substantial differenc...

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Veröffentlicht in:mAbs 2019-05, Vol.11 (4), p.709-724
Hauptverfasser: Tolbert, William David, Subedi, Ganesh Prasad, Gohain, Neelakshi, Lewis, George Kenneth, Patel, Kashyap Rajesh, Barb, Adam Wesley, Pazgier, Marzena
Format: Artikel
Sprache:eng
Schlagworte:
Animals
Biological Evolution
Crystallization
Crystallography, X-Ray
Humans
Immunoglobulin Fc Fragments - chemistry
Immunoglobulin Fc Fragments - metabolism
Immunoglobulin Isotypes - chemistry
Immunoglobulin Isotypes - metabolism
Macaca fascicularis
Macaca mulatta
Protein Binding
Protein Conformation
Receptors, IgG - metabolism
Structure-Activity Relationship
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container_end_page 724
container_issue 4
container_start_page 709
container_title mAbs
container_volume 11
creator Tolbert, William David
Subedi, Ganesh Prasad
Gohain, Neelakshi
Lewis, George Kenneth
Patel, Kashyap Rajesh
Barb, Adam Wesley
Pazgier, Marzena
description The Old World monkey, Rhesus macaque (Macaca mulatta, Mm), is frequently used as a primate model organism in the study of human disease and to test new vaccines/antibody treatments despite diverging before chimpanzees and orangutans. Mm and humans share 93% genome identity with substantial differences in the genes of the adaptive immune system that lead to different functional IgG subclass characteristics, Fcγ receptors expressed on innate immune cells, and biological interactions. These differences put limitations on Mm use as a primary animal model in the study of human disease and to test new vaccines/antibody treatments. Here, we comprehensively analyzed molecular properties of the Fc domain of the four IgG subclasses of Rhesus macaque to describe potential mechanisms for their interactions with effector cell Fc receptors. Our studies revealed less diversity in the overall structure among the Mm IgG Fc, with MmIgG1 Fc being the most structurally like human IgG3, although its C 2 loops and N glycan mobility are comparable to human IgG1. Furthermore, the Fcs of Mm IgG3 and 4 lack the structural properties typical for their human orthologues that determine IgG3's reduced interaction with the neonatal receptor and IgG4's ability for Fab-arm exchange and its weaker Fcγ receptor interactions. Taken together, our data indicate that MmIgG1-4 are less structurally divergent than the human IgGs, with only MmIgG1 matching the molecular properties of human IgG1 and 3, the most active IgGs in terms of Fcγ receptor binding and Fc-mediated functions. PDB accession numbers for deposited structures are 6D4E, 6D4I, 6D4M, and 6D4N for MmIgG1 Fc, MmIgG2 Fc, MmIgG3 Fc, and MmIgG4 Fc, respectively.
doi_str_mv 10.1080/19420862.2019.1589852
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Mm and humans share 93% genome identity with substantial differences in the genes of the adaptive immune system that lead to different functional IgG subclass characteristics, Fcγ receptors expressed on innate immune cells, and biological interactions. These differences put limitations on Mm use as a primary animal model in the study of human disease and to test new vaccines/antibody treatments. Here, we comprehensively analyzed molecular properties of the Fc domain of the four IgG subclasses of Rhesus macaque to describe potential mechanisms for their interactions with effector cell Fc receptors. Our studies revealed less diversity in the overall structure among the Mm IgG Fc, with MmIgG1 Fc being the most structurally like human IgG3, although its C 2 loops and N glycan mobility are comparable to human IgG1. Furthermore, the Fcs of Mm IgG3 and 4 lack the structural properties typical for their human orthologues that determine IgG3's reduced interaction with the neonatal receptor and IgG4's ability for Fab-arm exchange and its weaker Fcγ receptor interactions. Taken together, our data indicate that MmIgG1-4 are less structurally divergent than the human IgGs, with only MmIgG1 matching the molecular properties of human IgG1 and 3, the most active IgGs in terms of Fcγ receptor binding and Fc-mediated functions. 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Furthermore, the Fcs of Mm IgG3 and 4 lack the structural properties typical for their human orthologues that determine IgG3's reduced interaction with the neonatal receptor and IgG4's ability for Fab-arm exchange and its weaker Fcγ receptor interactions. Taken together, our data indicate that MmIgG1-4 are less structurally divergent than the human IgGs, with only MmIgG1 matching the molecular properties of human IgG1 and 3, the most active IgGs in terms of Fcγ receptor binding and Fc-mediated functions. 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source MEDLINE; DOAJ Directory of Open Access Journals; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; PubMed Central
subjects Animals
Biological Evolution
Crystallization
Crystallography, X-Ray
Humans
Immunoglobulin Fc Fragments - chemistry
Immunoglobulin Fc Fragments - metabolism
Immunoglobulin Isotypes - chemistry
Immunoglobulin Isotypes - metabolism
Macaca fascicularis
Macaca mulatta
Protein Binding
Protein Conformation
Receptors, IgG - metabolism
Structure-Activity Relationship
title From Rhesus macaque to human: structural evolutionary pathways for immunoglobulin G subclasses
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