Structure and activation of C1, the complex initiating the classical pathway of the complement cascade

Mortensen, Simon A.; Sander, Bjoern; Jensen, Rasmus K.; Pedersen, Jan Skov; Golas, Monika M.; Jensenius, Jens C.; Hansen, Annette G.; Thiel, Steffen; Andersen, Gregers Rom

doi:10.1073/pnas.1616998114

Cited by 89 publications

(81 citation statements)

References 38 publications

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“…The observed arrangement of the C1r and C1s heterotetramer differs from predictions based on a tetrameric C1s arrangement (25,31). The CUB2 domains of C1r and C1s are rotated, and the C1r-C1s dimers are shifted along each other, shortening the contact sites of C1q-collagen helices 2 and 5 from 14 (31) to 11 nm in C1-IgG1 6 ( fig.…”

contrasting

confidence: 59%

“…The arrangement of the C1q arms, induced upon binding the Fc hexamer, is also indicative of a compaction. The gC1q domains in unbound C1 are spread apart up to 30 to 35 nm (31). Bending of the collagen-like helices of arms 3 and 6, which embrace C1r 2 s 2 in the longest dimension, and incomplete binding of the gC1q heads (on arms 5 and 6) to Fc platforms support the notion of a surface-induced conformational change.…”

mentioning

confidence: 69%

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Structures of C1-IgG1 provide insights into how danger pattern recognition activates complement

Ugurlar

Howes

Kreuk

et al. 2018

Science

148

193

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Danger patterns on microbes or damaged host cells bind and activate C1, inducing innate immune responses and clearance through the complement cascade. How these patterns trigger complement initiation remains elusive. Here, we present cryo-electron microscopy analyses of C1 bound to monoclonal antibodies in which we observed heterogeneous structures of single and clustered C1-immunoglobulin G1 (IgG1) hexamer complexes. Distinct C1q binding sites are observed on the two Fc-CH2 domains of each IgG molecule. These are consistent with known interactions and also reveal additional interactions, which are supported by functional IgG1-mutant analysis. Upon antibody binding, the C1q arms condense, inducing rearrangements of the C1rs proteases and tilting C1q's cone-shaped stalk. The data suggest that C1r may activate C1s within single, strained C1 complexes or between neighboring C1 complexes on surfaces.

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confidence: 59%

mentioning

confidence: 69%

Structures of C1-IgG1 provide insights into how danger pattern recognition activates complement

Ugurlar

Howes

Kreuk

et al. 2018

Science

148

193

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“…However, the micrographs presented in that study (10) and a related contemporary study (11) do not prove a central location of the C1r and C1s SP domains. Our SAXS rigid body modeling of the nonactivated C1 complex placed the C1r and C1s SP domains at the periphery independent of their initial position, and this location was supported by our ab initio SAXS modeling (2). Consistently, our ns EM class averages showed up to 10 protruding spherical domains in agreement with six C1q globular heads and four SP domains from C1r and C1s located in the periphery of C1.…”

supporting

confidence: 77%

“…1) fit the SAXS data better (χ 2 = 1.26 ± 0.07) than the models we described in ref. 2. The analysis that we presented in ref.…”

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confidence: 99%

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Reply to Arlaud et al.: Structure of the C1 complex and the unbound C1r ₂ s ₂ tetramer

Mortensen

Sander

Jensen

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Arlaud et al.(1) raised concerns regarding our smallangle X-ray scattering (SAXS) and EM models of the unbound C1r 2 s 2 tetramer (2). They reference studies supporting an interaction of two C1rs dimers via C1r CCP1-serine protease (SP) interactions. In response, we conducted refinements against our SAXS data by imposing distance restraints derived from C1r CCP1-CCP2-SP crystal structures (3,4). The resulting models with central C1r dimers (Fig. 1) fit the SAXS data better (χ 2 = 1.26 ± 0.07) than the models we described in ref.2. The analysis that we presented in ref.2 was therefore incomplete and should have considered C1r-mediated dimerization. We thank Arlaud et al.(1) for their remark. A representative output model is now deposited in the Small Angle Scattering Biological Data Bank, together with a model from our study (2).Negative stain (ns) images of free C1r 2 s 2 (2) are not instrumental in excluding either of the models because many computed projections obtained by rotation of the SAXS models resemble each other at ns resolution levels ( Fig. 2 B and D). Part of our ns images exhibit "split ends" (Fig. 2A), so this feature is not a result of averaging as proposed by Arlaud et al.(1). These images are not in agreement with the SAXS output model in Fig. 1. However, we also observed particles with simple ends, as in the study of Tschopp et al. (5) (compare Fig. 2C and averages 2 and 3 in figure 3 of ref. 2). Our SAXS models based on C1r CCP1-SP contacts are consistent with these images (Fig. 2 C-F), with best agreement observed for some nonrepresentative SAXS solutions with more extended C1s conformations (Fig. 2F). Further experiments are required to decide conclusively between the two possible structures of unbound C1r 2 s 2 .However, although our analysis of unbound C1r 2 s 2 in our study (2) is incomplete, this fact does not change our conclusions regarding the structure of nonactivated C1 and its consequential intermolecular activation mechanism. The CUB1-EGF tetramerization of the C1r 2 s 2 inside the C1 complex assumed by us (2) is consistent with models developed by Brier et al. (6) and Venkatraman Girija et al. (7) featuring the CUB1-EGF-CUB2 domains of C1r and C1s located in one central plane, consistent with the fact that both C1r CUB domains, but only the C1s CUB1 domain, contain a binding site for C1q collagen stems (8, 9). The CCP1-CCP2-SP domains were suggested to be tucked inside the C1q collagen stems in nonactivated C1, and Arlaud et al.(1) reference an EM study in favor of this model (10). However, the micrographs presented in that study (10) and a related contemporary study (11) do not prove a central location of the C1r and C1s SP domains. Our SAXS rigid body modeling of the nonactivated C1 complex placed the C1r and C1s SP domains at the periphery independent of their initial position, and this location was supported by our ab initio SAXS modeling (2). Consistently, our ns EM class averages showed up to 10 protruding spherical domains in agreement with six C1q globular heads and four...

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Antibody density on bacteria regulates C1q recruitment by monoclonal IgG but not IgM

Aymerich,

Schlotheuber,

Bucheli

et al. 2024

Eur J Immunol

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Antibodies that trigger the complement system play a pivotal role in the immune defense against pathogenic bacteria and offer potential therapeutic avenues for combating antibiotic‐resistant bacterial infections, a rising global concern. To gain a deeper understanding of the key parameters regulating complement activation by monoclonal antibodies, we developed a novel bioassay for quantifying classical complement activation at the monoclonal antibody level, and employed this assay to characterize rare complement‐activating antibacterial antibodies on the single‐antibody level in postimmunization murine antibody repertoires. We characterized monoclonal antibodies from various antibody isotypes against specific pathogenic bacteria (Bordetella pertussis and Neisseria meningitidis) to broaden the scope of our findings. We demonstrated activation of the classical pathway by individual IgM‐ and IgG‐secreting cells, that is, monoclonal IgM and IgG2a/2b/3 subclasses. Additionally, we could observe different epitope density requirements for efficient C1q binding depending on antibody isotype, which is in agreement with previously proposed molecular mechanisms. In short, we found that antibody density most crucially regulated C1q recruitment by monoclonal IgG isotypes, but not IgM isotypes. This study provides additional insights into important parameters for classical complement initiation by monoclonal antibodies, a knowledge that might inform antibody screening and vaccination efforts.

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Structure and activation of C1, the complex initiating the classical pathway of the complement cascade

Cited by 89 publications

References 38 publications

Structures of C1-IgG1 provide insights into how danger pattern recognition activates complement

Structures of C1-IgG1 provide insights into how danger pattern recognition activates complement

Reply to Arlaud et al.: Structure of the C1 complex and the unbound C1r ₂ s ₂ tetramer

Antibody density on bacteria regulates C1q recruitment by monoclonal IgG but not IgM

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Structure and activation of C1, the complex initiating the classical pathway of the complement cascade

Cited by 89 publications

References 38 publications

Structures of C1-IgG1 provide insights into how danger pattern recognition activates complement

Structures of C1-IgG1 provide insights into how danger pattern recognition activates complement

Reply to Arlaud et al.: Structure of the C1 complex and the unbound C1r 2 s 2 tetramer

Antibody density on bacteria regulates C1q recruitment by monoclonal IgG but not IgM

Contact Info

Product

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Reply to Arlaud et al.: Structure of the C1 complex and the unbound C1r ₂ s ₂ tetramer