Advancing multimer analysis of von Willebrand factor by single-molecule AFM imaging

Achim Löf; Gesa König; Sonja Schneppenheim; Reinhard Schneppenheim; Martin Benoit; Ulrich Budde; Jochen P Müller; Maria A Brehm

doi:10.1371/journal.pone.0210963

Advancing multimer analysis of von Willebrand factor by single-molecule AFM imaging

Standard

Advancing multimer analysis of von Willebrand factor by single-molecule AFM imaging. / Löf, Achim; König, Gesa; Schneppenheim, Sonja; Schneppenheim, Reinhard; Benoit, Martin; Budde, Ulrich; Müller, Jochen P; Brehm, Maria A.

in: PLOS ONE, Jahrgang 14, Nr. 1, 2019, S. e0210963.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Löf, A, König, G, Schneppenheim, S, Schneppenheim, R, Benoit, M, Budde, U, Müller, JP & Brehm, MA 2019, 'Advancing multimer analysis of von Willebrand factor by single-molecule AFM imaging', PLOS ONE, Jg. 14, Nr. 1, S. e0210963. https://doi.org/10.1371/journal.pone.0210963

APA

Löf, A., König, G., Schneppenheim, S., Schneppenheim, R., Benoit, M., Budde, U., Müller, J. P., & Brehm, M. A. (2019). Advancing multimer analysis of von Willebrand factor by single-molecule AFM imaging. PLOS ONE, 14(1), e0210963. https://doi.org/10.1371/journal.pone.0210963

Vancouver

Löf A, König G, Schneppenheim S, Schneppenheim R, Benoit M, Budde U et al. Advancing multimer analysis of von Willebrand factor by single-molecule AFM imaging. PLOS ONE. 2019;14(1):e0210963. https://doi.org/10.1371/journal.pone.0210963

Bibtex

@article{9a1f8c4c431e41939c86d3086c7f3bc7,

title = "Advancing multimer analysis of von Willebrand factor by single-molecule AFM imaging",

abstract = "The formation of hemostatic plugs at sites of vascular injury crucially involves the multimeric glycoprotein von Willebrand factor (VWF). VWF multimers are linear chains of N-terminally linked dimers. The latter are formed from monomers via formation of the C-terminal disulfide bonds Cys2771-Cys2773', Cys2773-Cys2771', and Cys2811-Cys2811'. Mutations in VWF that impair multimerization can lead to subtype 2A of the bleeding disorder von Willebrand Disease (VWD). Commonly, the multimer size distribution of VWF is assessed by electrophoretic multimer analysis. Here, we present atomic force microscopy (AFM) imaging as a method to determine the size distribution of VWF variants by direct visualization at the single-molecule level. We first validated our approach by investigating recombinant wildtype VWF and a previously studied mutant (p.Cys1099Tyr) that impairs N-terminal multimerization. We obtained excellent quantitative agreement with results from earlier studies and with electrophoretic multimer analysis. We then imaged specific mutants that are known to exhibit disturbed C-terminal dimerization. For the mutants p.Cys2771Arg and p.Cys2773Arg, we found the majority of monomers (87 ± 5% and 73 ± 4%, respectively) not to be C-terminally dimerized. While these results confirm that Cys2771 and Cys2773 are crucial for dimerization, they additionally provide quantitative information on the mutants' different abilities to form alternative C-terminal disulfides for residual dimerization. We further mutated Cys2811 to Ala and found that only 23 ± 3% of monomers are not C-terminally dimerized, indicating that Cys2811 is structurally less important for dimerization. Furthermore, for mutants p.Cys2771Arg, p.Cys2773Arg, and p.Cys2811Ala we found 'even-numbered' non-native multimers, i.e. multimers with monomers attached on both termini; a multimer species that cannot be distinguished from native multimers by conventional multimer analysis. Summarizing, we demonstrate that AFM imaging can provide unique insights into VWF processing defects at the single-molecule level that cannot be gained from established methods of multimer analysis.",

keywords = "Amino Acid Substitution, Cysteine/chemistry, Dimerization, HEK293 Cells, Humans, Microscopy, Atomic Force/methods, Models, Molecular, Mutant Proteins/chemistry, Mutation, Missense, Particle Size, Protein Multimerization/genetics, Recombinant Proteins/chemistry, Single Molecule Imaging/methods, von Willebrand Diseases/blood, von Willebrand Factor/chemistry",

author = "Achim L{\"o}f and Gesa K{\"o}nig and Sonja Schneppenheim and Reinhard Schneppenheim and Martin Benoit and Ulrich Budde and M{\"u}ller, {Jochen P} and Brehm, {Maria A}",

year = "2019",

doi = "10.1371/journal.pone.0210963",

language = "English",

volume = "14",

pages = "e0210963",

journal = "PLOS ONE",

issn = "1932-6203",

publisher = "Public Library of Science",

number = "1",

}

RIS

TY - JOUR

T1 - Advancing multimer analysis of von Willebrand factor by single-molecule AFM imaging

AU - Löf, Achim

AU - König, Gesa

AU - Schneppenheim, Sonja

AU - Schneppenheim, Reinhard

AU - Benoit, Martin

AU - Budde, Ulrich

AU - Müller, Jochen P

AU - Brehm, Maria A

PY - 2019

Y1 - 2019

N2 - The formation of hemostatic plugs at sites of vascular injury crucially involves the multimeric glycoprotein von Willebrand factor (VWF). VWF multimers are linear chains of N-terminally linked dimers. The latter are formed from monomers via formation of the C-terminal disulfide bonds Cys2771-Cys2773', Cys2773-Cys2771', and Cys2811-Cys2811'. Mutations in VWF that impair multimerization can lead to subtype 2A of the bleeding disorder von Willebrand Disease (VWD). Commonly, the multimer size distribution of VWF is assessed by electrophoretic multimer analysis. Here, we present atomic force microscopy (AFM) imaging as a method to determine the size distribution of VWF variants by direct visualization at the single-molecule level. We first validated our approach by investigating recombinant wildtype VWF and a previously studied mutant (p.Cys1099Tyr) that impairs N-terminal multimerization. We obtained excellent quantitative agreement with results from earlier studies and with electrophoretic multimer analysis. We then imaged specific mutants that are known to exhibit disturbed C-terminal dimerization. For the mutants p.Cys2771Arg and p.Cys2773Arg, we found the majority of monomers (87 ± 5% and 73 ± 4%, respectively) not to be C-terminally dimerized. While these results confirm that Cys2771 and Cys2773 are crucial for dimerization, they additionally provide quantitative information on the mutants' different abilities to form alternative C-terminal disulfides for residual dimerization. We further mutated Cys2811 to Ala and found that only 23 ± 3% of monomers are not C-terminally dimerized, indicating that Cys2811 is structurally less important for dimerization. Furthermore, for mutants p.Cys2771Arg, p.Cys2773Arg, and p.Cys2811Ala we found 'even-numbered' non-native multimers, i.e. multimers with monomers attached on both termini; a multimer species that cannot be distinguished from native multimers by conventional multimer analysis. Summarizing, we demonstrate that AFM imaging can provide unique insights into VWF processing defects at the single-molecule level that cannot be gained from established methods of multimer analysis.

AB - The formation of hemostatic plugs at sites of vascular injury crucially involves the multimeric glycoprotein von Willebrand factor (VWF). VWF multimers are linear chains of N-terminally linked dimers. The latter are formed from monomers via formation of the C-terminal disulfide bonds Cys2771-Cys2773', Cys2773-Cys2771', and Cys2811-Cys2811'. Mutations in VWF that impair multimerization can lead to subtype 2A of the bleeding disorder von Willebrand Disease (VWD). Commonly, the multimer size distribution of VWF is assessed by electrophoretic multimer analysis. Here, we present atomic force microscopy (AFM) imaging as a method to determine the size distribution of VWF variants by direct visualization at the single-molecule level. We first validated our approach by investigating recombinant wildtype VWF and a previously studied mutant (p.Cys1099Tyr) that impairs N-terminal multimerization. We obtained excellent quantitative agreement with results from earlier studies and with electrophoretic multimer analysis. We then imaged specific mutants that are known to exhibit disturbed C-terminal dimerization. For the mutants p.Cys2771Arg and p.Cys2773Arg, we found the majority of monomers (87 ± 5% and 73 ± 4%, respectively) not to be C-terminally dimerized. While these results confirm that Cys2771 and Cys2773 are crucial for dimerization, they additionally provide quantitative information on the mutants' different abilities to form alternative C-terminal disulfides for residual dimerization. We further mutated Cys2811 to Ala and found that only 23 ± 3% of monomers are not C-terminally dimerized, indicating that Cys2811 is structurally less important for dimerization. Furthermore, for mutants p.Cys2771Arg, p.Cys2773Arg, and p.Cys2811Ala we found 'even-numbered' non-native multimers, i.e. multimers with monomers attached on both termini; a multimer species that cannot be distinguished from native multimers by conventional multimer analysis. Summarizing, we demonstrate that AFM imaging can provide unique insights into VWF processing defects at the single-molecule level that cannot be gained from established methods of multimer analysis.

KW - Amino Acid Substitution

KW - Cysteine/chemistry

KW - Dimerization

KW - HEK293 Cells

KW - Humans

KW - Microscopy, Atomic Force/methods

KW - Models, Molecular

KW - Mutant Proteins/chemistry

KW - Mutation, Missense

KW - Particle Size

KW - Protein Multimerization/genetics

KW - Recombinant Proteins/chemistry

KW - Single Molecule Imaging/methods

KW - von Willebrand Diseases/blood

KW - von Willebrand Factor/chemistry

U2 - 10.1371/journal.pone.0210963

DO - 10.1371/journal.pone.0210963

M3 - SCORING: Journal article

C2 - 30645640

VL - 14

SP - e0210963

JO - PLOS ONE

JF - PLOS ONE

SN - 1932-6203

IS - 1

ER -