Conformational isomerism and the diversity of antibodies.

Foote, Jefferson; Milstein, C.

doi:10.1073/pnas.91.22.10370

Cited by 244 publications

(233 citation statements)

References 24 publications

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“…However, recent crystallographic and thermodynamic analyses of both germline and mature Ab-Ag complexes have suggested that the Ab repertoire can be further enhanced at the tertiary structural level (7,14,18,19,34,35). The present study provides an elegant correlation of CDR conformational versatility in a germline Ab with its multispecificity.…”

Section: Discussionmentioning

confidence: 70%

“…Our data illustrate the importance of paratope adaptability *Structural Biology Unit, National Institute of Immunology, New Delhi 110 067, India; and † Regional Centre for Biotechnology, Gurgaon 122 016, India for facilitating polyreactivity of germline mAb through systematically designed crystallographic experiments. The present analysis, in light of earlier studies (1,5,8,9,(14)(15)(16)(17)(18)(19), suggests the possibility that generation of diversity in the primary Ab repertoire may involve multiple mechanisms in a hierarchical order. The proposed model may account for enhanced diversity of primary immune receptors without increasing the size of the germline gene repertoire.…”

mentioning

confidence: 84%

“…Six structures of the germline mAb BBE6.12H3, in different chemical environments, quantitatively define the conformational repertoire of the CDRs, providing a rich data set for examining paratope topologies, although thermodynamic and computational studies have provided interesting clues regarding the generation of diversity in primary Ab response (5,19,33,34). Similarly, crystallographic and kinetic analyses of mature Abs SPE7 and NQ22/61.1, respectively, have also suggested conformational isomerism (7,19). Our data consisting of six BBE6.12H3 Fab structures-two Ag free and four Ag bound-provided a rich source of information reflecting correlation of paratope conformational flexibility and polyreactivity.…”

Section: Discussionmentioning

confidence: 99%

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Structural Elucidation of the Mechanistic Basis of Degeneracy in the Primary Humoral Response

Khan

Salunke

2012

The Journal of Immunology

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The mechanistic basis for efficient combating of the infinite range of foreign Ags by the limited repertoire of naive Abs expressed on primary B cell surfaces during their first encounter was addressed through elegantly designed crystallographic analyses. Resolution of the discrepancy arising from the limited number of possible germline Ab receptors on primary B cells for recognizing the unlimited pool of possible Ags has been attempted by invoking the degenerate recognition potential of the germline Abs. Structural analyses of germline mAb BBE6.12H3 in an Ag-free state, as well as bound to four different peptide Ags, established the correlation of its degenerate specificity with conformational versatility of the paratope. Six distinct paratope topologies observed for a single germline mAb provided a quantitative description of the primary Ag recognition repertoire at the tertiary structural level. Each of the four different peptide Ags was bound specifically to a distinct conformation of the paratope, which was also different from that of the Ag-free states of the same germline mAb. A minimal conserved motif in the pristine Ag-combining site essential for multispecificity and Ag binding-mediated change in the elbow angle of Fab was also discernible. It is proposed that the generation of a primary Ab repertoire involves large, yet finite, germline Ab clones, each capable of adopting discrete conformations, which in turn exhibit diverse binding modes.

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Section: Discussionmentioning

confidence: 70%

mentioning

confidence: 84%

Section: Discussionmentioning

confidence: 99%

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Structural Elucidation of the Mechanistic Basis of Degeneracy in the Primary Humoral Response

Khan

Salunke

2012

The Journal of Immunology

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“…Furthermore, these states/substates can interconvert, with the transition rate determining the probability distribution and population size of these states. Based on the thermodynamic and kinetic properties of proteins, a more "real" model, the conformational selection model [87][88][89] was proposed to explain the protein-ligand binding mechanism at the molecular population level.…”

Section: Conformational Selection Mechanism Of Protein-ligand Bindingmentioning

confidence: 99%

Physicochemical bases for protein folding, dynamics, and protein-ligand binding

Xie

Liu

et al. 2014

Sci. China Life Sci.

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Proteins are essential parts of living organisms and participate in virtually every process within cells. As the genomic sequences for increasing number of organisms are completed, research into how proteins can perform such a variety of functions has become much more intensive because the value of the genomic sequences relies on the accuracy of understanding the encoded gene products. Although the static three-dimensional structures of many proteins are known, the functions of proteins are ultimately governed by their dynamic characteristics, including the folding process, conformational fluctuations, molecular motions, and protein-ligand interactions. In this review, the physicochemical principles underlying these dynamic processes are discussed in depth based on the free energy landscape (FEL) theory. Questions of why and how proteins fold into their native conformational states, why proteins are inherently dynamic, and how their dynamic personalities govern protein functions are answered. This paper will contribute to the understanding of structure-function relationship of proteins in the post-genome era of life science research. free energy landscape, entropy-enthalpy non-complementarity, ruggedness, driving force, thermodynamics, kinetics Citation:Li HM, Xie YH, Liu CQ, Liu SQ. Physicochemical bases for protein folding, dynamics, and protein-ligand binding.

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“…This loss in flexibility is due to an increased effective correlation time (in this case, probable loss of flexibility of the binding site for hapten), leading to a larger negative NOE (that is, the cross-peaks are in the same phase as the diagonal peaks and have an increased intensity). Conformational mobility of the antibody combining site has been proposed as a possible mechanism for cross-reactivity and multiphasic binding kinetics (Foote & Milstein, 1994). Such a mechanism may be common.…”

Section: Discussionmentioning

confidence: 99%

Binding of Phenylphosphocholine−Carrier Conjugates to the Combining Site of Antibodies Maintains a Conformation of the Hapten

et al. 1996

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The structural basis of the binding of phenylphosphocholine haptens to antibodies was studied. This was done by preparing antibodies and testing binding to conjugates of phenylphosphocholine. The choice of haptens was made in order to evaluate the contribution of the carrier to binding, and its effect on hapten conformation in the active site. Thus, phosphocholine (PC) was diazophenyl-linked to tyrosine or histidine as single amino acid carriers and to tripeptides or octapeptides containing tyrosine or histidine as central amino acids to which PC was attached. Relative affinity was assessed by inhibition enzymelinked immunosorbent assay (ELISA) and binding constants were determined by fluorescence quenching. Fluorinated haptens were used to determine the kinetics of binding using 19 F nuclear magnetic resonance. The transferred nuclear Overhauser effect was used to characterize conformation of the bound hapten. We had previously shown that nitrophenylphosphocholine unlinked to carrier is bound in the active site as a bent structure [Bruderer, U., Peyton, D. H., Barbar, E., Fellman, J. H., & Rittenberg, M. B. (1992) Biochemistry 31, 584-589]. We show here that this same bent conformation is retained in the active site regardless of the neighboring carrier or the conformation of the hapten in the unbound conjugate. The presence of the carrier residues in the bound state does, however, influence affinity.In order to elicit a humoral immune response, most smallmolecule haptens must be coupled to protein carriers. It has been documented that protein carriers are internalized, processed to peptides, and presented on the surface of the B cell, where they induce T lymphocyte help to drive further the B cell response (Lanzavecchia, 1990). Internalization requires an initial interaction between the hapten-carrier conjugate and the membrane-bound antibody on the B cell surface. The contribution of the carrier to the initial interaction between ligand and B cell receptor remains unknown. Furthermore, procedures used to produce haptencarrier protein conjugates usually yield heterogeneous products, with multiple hapten units bound per carrier molecule. While this approach is advantageous for effective induction of antibody, it disallows determination of specific structural details of antigen-antibody interactions.Many structural studies of antigen-antibody interactions have focused on changes in the conformation of the hapten upon binding (Glaudemans et al., 1990;Anglister & Naider, 1991;Cheetham et al., 1991). Additional studies have emphasized structural dynamics of the antibody itself (Theriault et al., 1991; Constantine et al., 1993a,b). For example, the result of heavy (H-) chain CDR3-hapten interactions in an anti-dansyl antibody was found to include a decrease in H-chain CDR3 internal motion, and the formation of a hydrophobic core comprising two H-chain CDR3 tyrosines and the dansyl ring (Odaka et al., 1992;Takahashi et al., 1992). Another significant finding is that the antibody may, in some cases, exist as...

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Conformational isomerism and the diversity of antibodies.

Cited by 244 publications

References 24 publications

Structural Elucidation of the Mechanistic Basis of Degeneracy in the Primary Humoral Response

Structural Elucidation of the Mechanistic Basis of Degeneracy in the Primary Humoral Response

Physicochemical bases for protein folding, dynamics, and protein-ligand binding

Binding of Phenylphosphocholine−Carrier Conjugates to the Combining Site of Antibodies Maintains a Conformation of the Hapten

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