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IgA nephropathy (IgAN) is the most prevalent cause of primary glomerular disease worldwide, and the cytokine A PRoliferation‐Inducing Ligand (APRIL) is emerging as a key player in IgAN pathogenesis and disease progression. For a panel of anti‐huma...
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RISS 인기검색어
Structural prediction of antibody‐APRIL complexes by computational docking constrained by antigen saturation mutagenesis library data
한글로보기https://www.riss.kr/link?id=O119686357
- 저자
- 발행기관
- 학술지명
- 권호사항
-
발행연도
2019년
-
작성언어
-
-
Print ISSN
0952-3499
-
Online ISSN
1099-1352
-
등재정보
SCI;SCIE;SCOPUS
-
자료형태
학술저널
-
수록면
n/a-n/a [※수록면이 p5 이하이면, Review, Columns, Editor's Note, Abstract 등일 경우가 있습니다.]
- 소장기관
-
구독기관
- 전북대학교 중앙도서관
- 성균관대학교 중앙학술정보관
- 부산대학교 중앙도서관
- 전남대학교 중앙도서관
- 제주대학교 중앙도서관
- 중앙대학교 서울캠퍼스 중앙도서관
- 인천대학교 학산도서관
- 숙명여자대학교 중앙도서관
- 서강대학교 로욜라중앙도서관
- 계명대학교 동산도서관
- 충남대학교 중앙도서관
- 한양대학교 백남학술정보관
- 이화여자대학교 중앙도서관
- 고려대학교 도서관
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
IgA nephropathy (IgAN) is the most prevalent cause of primary glomerular disease worldwide, and the cytokine A PRoliferation‐Inducing Ligand (APRIL) is emerging as a key player in IgAN pathogenesis and disease progression. For a panel of anti‐human APRIL antibodies with known antagonistic activity, we sought to define their structural mode of engagement to understand molecular mechanisms of action and aid rational antibody engineering. Reliable computational prediction of antibody‐antigen complexes remains challenging, and experimental methods such as X‐ray co‐crystallography and cryoEM have considerable technical, resource, and throughput barriers. To overcome these limitations, we implemented an integrated and accessible experimental‐computational workflow to more accurately predict structures of antibody‐APRIL complexes. Specifically, a yeast surface display library encoding site‐saturation mutagenized surface positions of APRIL was screened against a panel of anti‐APRIL antibodies to rapidly obtain a comprehensive biochemical profile of mutational impact on binding for each antibody. The experimentally derived mutational profile data were used as quantitative constraints in a computational docking workflow optimized for antibodies, resulting in robust structural models of antibody‐antigen complexes. The model results were confirmed by solving the cocrystal structure of one antibody‐APRIL complex, which revealed strong agreement with our model. The models were used to rationally select and engineer one antibody for cross‐species APRIL binding, which quite often aids further testing in relevant animal models. Collectively, we demonstrate a rapid, integrated computational‐experimental approach to robustly predict antibody‐antigen structures information, which can aid rational antibody engineering and provide insights into molecular mechanisms of action.
Accurate computational prediction of the structure of antibody‐antigen complexes remains challenging due, in part, to the difficulty in identifying near‐native models from incorrect poses. A workflow was developed that integrates experimental deep mutational scanning data with antibody‐antigen docking for generation of high‐quality models (confirmed by X‐ray crystallography). This workflow was applied for a panel of antibodies against the antigen APRIL that enabled rational selection and engineering of one antibody for cross‐species antigen binding.
Accurate computational prediction of the structure of antibody‐antigen complexes remains challenging due, in part, to the difficulty in identifying near‐native models from incorrect poses. A workflow was developed that integrates experimental deep mutational scanning data with antibody‐antigen docking for generation of high‐quality models (confirmed by X‐ray crystallography). This workflow was applied for a panel of antibodies against the antigen APRIL that enabled rational selection and engineering of one antibody for cross‐species antigen binding.
IgA nephropathy (IgAN) is the most prevalent cause of primary glomerular disease worldwide, and the cytokine A PRoliferation‐Inducing Ligand (APRIL) is emerging as a key player in IgAN pathogenesis and disease progression. For a panel of anti‐human APRIL antibodies with known antagonistic activity, we sought to define their structural mode of engagement to understand molecular mechanisms of action and aid rational antibody engineering. Reliable computational prediction of antibody‐antigen complexes remains challenging, and experimental methods such as X‐ray co‐crystallography and cryoEM have considerable technical, resource, and throughput barriers. To overcome these limitations, we implemented an integrated and accessible experimental‐computational workflow to more accurately predict structures of antibody‐APRIL complexes. Specifically, a yeast surface display library encoding site‐saturation mutagenized surface positions of APRIL was screened against a panel of anti‐APRIL antibodies to rapidly obtain a comprehensive biochemical profile of mutational impact on binding for each antibody. The experimentally derived mutational profile data were used as quantitative constraints in a computational docking workflow optimized for antibodies, resulting in robust structural models of antibody‐antigen complexes. The model results were confirmed by solving the cocrystal structure of one antibody‐APRIL complex, which revealed strong agreement with our model. The models were used to rationally select and engineer one antibody for cross‐species APRIL binding, which quite often aids further testing in relevant animal models. Collectively, we demonstrate a rapid, integrated computational‐experimental approach to robustly predict antibody‐antigen structures information, which can aid rational antibody engineering and provide insights into molecular mechanisms of action.
Accurate computational prediction of the structure of antibody‐antigen complexes remains challenging due, in part, to the difficulty in identifying near‐native models from incorrect poses. A workflow was developed that integrates experimental deep mutational scanning data with antibody‐antigen docking for generation of high‐quality models (confirmed by X‐ray crystallography). This workflow was applied for a panel of antibodies against the antigen APRIL that enabled rational selection and engineering of one antibody for cross‐species antigen binding.
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