Initiating the Classical Pathway: IgG recruitment, Hexamerization, and C1q binding in Real-Time

Jürgen Strasser; Frank J. Beurskens; Rob N. de Jong; Janine Schuurman; Paul W. H. I. Parren; Peter Hinterdorfer; Johannes Preiner

Initiating the Classical Pathway: IgG recruitment, Hexamerization, and C1q binding in Real-Time

Jürgen Strasser, Frank J. Beurskens, Rob N. de Jong, Janine Schuurman, Paul W. H. I. Parren, Peter Hinterdorfer, Johannes Preiner

Research output: Chapter in Book/Report/Conference proceedings › Conference contribution

Abstract

Complement activation is triggered by the formation of Immunoglobulin (IgG) hexamers on the surface of pathogens, tumors, or autoantigenic cells. The molecular pathway of how IgG binding to surface antigens initiates and facilitates hexamerization remains poorly understood. Here, we employed high-speed atomic force microscopy to directly visualize dynamic IgG binding and hexamer formation on antigenic lipid bilayer membranes and subsequent binding of C1q– the first component of complement- in real-time and under physiological conditions. With single-molecule force spectroscopy and quartz crystal microbalance we further characterized the molecular interactions by determining chemical rate constants and energies. Our data outline a process in which antigen recognition by IgGs nucleates subsequent oligomerization through IgG recruitment from solution or via lateral collisions. This finally leads to stable IgG hexamers competent of tightly binding C1q and thus initiates the classical complement pathway.

Original language	English
Title of host publication	Gordon Research Conference on Antibody Biology and Engineering
Publication status	Published - 2018
Event	Gordon Research Conference on Antibody Biology and Engineering 2018 - Lucca, Italy Duration: 25 Mar 2018 → 30 Mar 2018

Conference

Conference	Gordon Research Conference on Antibody Biology and Engineering 2018
Country/Territory	Italy
City	Lucca
Period	25.03.2018 → 30.03.2018

Cite this

@inproceedings{16726eaaec2141adb5c6d4f67180a4c3,

title = "Initiating the Classical Pathway: IgG recruitment, Hexamerization, and C1q binding in Real-Time",

abstract = "Complement activation is triggered by the formation of Immunoglobulin (IgG) hexamers on the surface of pathogens, tumors, or autoantigenic cells. The molecular pathway of how IgG binding to surface antigens initiates and facilitates hexamerization remains poorly understood. Here, we employed high-speed atomic force microscopy to directly visualize dynamic IgG binding and hexamer formation on antigenic lipid bilayer membranes and subsequent binding of C1q– the first component of complement- in real-time and under physiological conditions. With single-molecule force spectroscopy and quartz crystal microbalance we further characterized the molecular interactions by determining chemical rate constants and energies. Our data outline a process in which antigen recognition by IgGs nucleates subsequent oligomerization through IgG recruitment from solution or via lateral collisions. This finally leads to stable IgG hexamers competent of tightly binding C1q and thus initiates the classical complement pathway.",

author = "J{\"u}rgen Strasser and Beurskens, {Frank J.} and {de Jong}, {Rob N.} and Janine Schuurman and Parren, {Paul W. H. I.} and Peter Hinterdorfer and Johannes Preiner",

year = "2018",

language = "English",

booktitle = "Gordon Research Conference on Antibody Biology and Engineering",

note = "Gordon Research Conference on Antibody Biology and Engineering 2018 ; Conference date: 25-03-2018 Through 30-03-2018",

}

TY - GEN

T1 - Initiating the Classical Pathway: IgG recruitment, Hexamerization, and C1q binding in Real-Time

AU - Strasser, Jürgen

AU - Beurskens, Frank J.

AU - de Jong, Rob N.

AU - Schuurman, Janine

AU - Parren, Paul W. H. I.

AU - Hinterdorfer, Peter

AU - Preiner, Johannes

PY - 2018

Y1 - 2018

N2 - Complement activation is triggered by the formation of Immunoglobulin (IgG) hexamers on the surface of pathogens, tumors, or autoantigenic cells. The molecular pathway of how IgG binding to surface antigens initiates and facilitates hexamerization remains poorly understood. Here, we employed high-speed atomic force microscopy to directly visualize dynamic IgG binding and hexamer formation on antigenic lipid bilayer membranes and subsequent binding of C1q– the first component of complement- in real-time and under physiological conditions. With single-molecule force spectroscopy and quartz crystal microbalance we further characterized the molecular interactions by determining chemical rate constants and energies. Our data outline a process in which antigen recognition by IgGs nucleates subsequent oligomerization through IgG recruitment from solution or via lateral collisions. This finally leads to stable IgG hexamers competent of tightly binding C1q and thus initiates the classical complement pathway.

AB - Complement activation is triggered by the formation of Immunoglobulin (IgG) hexamers on the surface of pathogens, tumors, or autoantigenic cells. The molecular pathway of how IgG binding to surface antigens initiates and facilitates hexamerization remains poorly understood. Here, we employed high-speed atomic force microscopy to directly visualize dynamic IgG binding and hexamer formation on antigenic lipid bilayer membranes and subsequent binding of C1q– the first component of complement- in real-time and under physiological conditions. With single-molecule force spectroscopy and quartz crystal microbalance we further characterized the molecular interactions by determining chemical rate constants and energies. Our data outline a process in which antigen recognition by IgGs nucleates subsequent oligomerization through IgG recruitment from solution or via lateral collisions. This finally leads to stable IgG hexamers competent of tightly binding C1q and thus initiates the classical complement pathway.

M3 - Conference contribution

BT - Gordon Research Conference on Antibody Biology and Engineering

T2 - Gordon Research Conference on Antibody Biology and Engineering 2018

Y2 - 25 March 2018 through 30 March 2018

ER -

Initiating the Classical Pathway: IgG recruitment, Hexamerization, and C1q binding in Real-Time

Abstract

Conference

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