Your search keyword '"Kearney, Alice"' showing total 7 results

1. The contribution of conformational adjustments and long-range electrostatic forces to the CD2/CD58 interaction.

Author

Kearney A, Avramovic A, Castro MA, Carmo AM, Davis SJ, and van der Merwe PA

Subjects

Animals, Antigens, CD chemistry, Antigens, CD metabolism, CD2 Antigens metabolism, CD48 Antigen, CD58 Antigens metabolism, Humans, Killer Cells, Natural chemistry, Killer Cells, Natural metabolism, Osmolar Concentration, Protein Binding, Protein Structure, Quaternary, Rodentia, Static Electricity, T-Lymphocytes chemistry, T-Lymphocytes metabolism, CD2 Antigens chemistry, CD58 Antigens chemistry, Surface Plasmon Resonance

Abstract

CD2 is a T cell surface molecule that enhances T and natural killer cell function by binding its ligands CD58 (humans) and CD48 (rodents) on antigen-presenting or target cells. Here we show that the CD2/CD58 interaction is enthalpically driven and accompanied by unfavorable entropic changes. Taken together with structural studies, this indicates that binding is accompanied by energetically significant conformational adjustments. Despite having a highly charged binding interface, neither the affinity nor the rate constants of the CD2/CD58 interaction were affected by changes in ionic strength, indicating that long-range electrostatic forces make no net contribution to binding.

Published

2007

2. How much can a T-cell antigen receptor adapt to structurally distinct antigenic peptides?

Author

Mazza C, Auphan-Anezin N, Gregoire C, Guimezanes A, Kellenberger C, Roussel A, Kearney A, van der Merwe PA, Schmitt-Verhulst AM, and Malissen B

Subjects

Amino Acid Sequence, Animals, Complementarity Determining Regions chemistry, Crystallography, X-Ray, H-2 Antigens immunology, Ligands, Mice, Models, Molecular, Molecular Sequence Data, Mutant Proteins chemistry, Protein Structure, Secondary, Thermodynamics, Tyrosine, Antigens chemistry, Antigens immunology, Peptides chemistry, Receptors, Antigen, T-Cell immunology

Abstract

Binding degeneracy is thought to constitute a fundamental property of the T-cell antigen receptor (TCR), yet its structural basis is poorly understood. We determined the crystal structure of a complex involving the BM3.3 TCR and a peptide (pBM8) bound to the H-2K(bm8) major histocompatibility complex (MHC) molecule, and compared it with the structures of the BM3.3 TCR bound to H-2K(b) molecules loaded with two peptides that had a minimal level of primary sequence identity with pBM8. Our findings provide a refined structural view of the basis of BM3.3 TCR cross-reactivity and a structural explanation for the long-standing paradox that a TCR antigen-binding site can be both specific and degenerate. We also measured the thermodynamic features and biological penalties that incurred during cross-recognition. Our data illustrate the difficulty for a given TCR in adapting to distinct peptide-MHC surfaces while still maintaining affinities that result in functional in vivo responses. Therefore, when induction of protective effector T cells is used as the ultimate criteria for adaptive immunity, TCRs are probably much less degenerate than initially assumed.

Published

2007

3. Impact of salt bridges on the equilibrium binding and adhesion of human CD2 and CD58.

Author

Bayas MV, Kearney A, Avramovic A, van der Merwe PA, and Leckband DE

Subjects

Amino Acid Substitution, CD2 Antigens genetics, CD2 Antigens metabolism, CD58 Antigens genetics, CD58 Antigens metabolism, Cell Adhesion physiology, Humans, Protein Binding genetics, Protein Structure, Quaternary, Protein Structure, Tertiary, Salts chemistry, Salts metabolism, CD2 Antigens chemistry, CD58 Antigens chemistry, Models, Molecular

Abstract

This study describes quantitative investigations of the impact of single charge mutations on equilibrium binding, kinetics, and the adhesion strength of the CD2-CD58 interaction. Previously steered molecular dynamics simulations guided the selection of the charge mutants investigated, which include the CD2 mutants D31A, K41A, K51A, and K91A. This set includes mutations in which the previous cell aggregation and binding data either agreed or disagreed with the steered molecular dynamics predictions. Surface plasmon resonance measurements quantified the solution binding properties. Adhesion was quantified with the surface force apparatus, which was used previously to study the closely related CD2-CD48 interaction. The results reveal roles that these salt bridges play in equilibrium binding and adhesion. We discuss both the molecular basis of this behavior and its implications for cell adhesion.

Published

2007

4. Crystal structure and binding properties of the CD2 and CD244 (2B4)-binding protein, CD48.

Author

Evans EJ, Castro MA, O'Brien R, Kearney A, Walsh H, Sparks LM, Tucknott MG, Davies EA, Carmo AM, van der Merwe PA, Stuart DI, Jones EY, Ladbury JE, Ikemizu S, and Davis SJ

Subjects

Animals, Antigens, CD metabolism, CD2 Antigens metabolism, CD48 Antigen, CD58 Antigens chemistry, Evolution, Molecular, Humans, Ligands, Membrane Glycoproteins metabolism, Models, Molecular, Protein Binding, Protein Conformation, Protein Structure, Tertiary, Rats, Receptors, Immunologic metabolism, Signaling Lymphocytic Activation Molecule Family, Thermodynamics, Antigens, CD chemistry, CD2 Antigens chemistry, Membrane Glycoproteins chemistry, Receptors, Immunologic chemistry

Abstract

The structural analysis of surface proteins belonging to the CD2 subset of the immunoglobulin superfamily has yielded important insights into transient cellular interactions. In mice and rats, CD2 and CD244 (2B4), which are expressed predominantly on T cells and natural killer cells, respectively, bind the same, broadly expressed ligand, CD48. Structures of CD2 and CD244 have been solved previously, and we now present the structure of the receptor-binding domain of rat CD48. The receptor-binding surface of CD48 is unusually flat, as in the case of rat CD2, and shares a high degree of electrostatic complementarity with the equivalent surface of CD2. The relatively simple arrangement of charged residues and this flat topology explain why CD48 cross-reacts with CD2 and CD244 and, in rats, with the CD244-related protein, 2B4R. Comparisons of modeled complexes of CD2 and CD48 with the complex of human CD2 and CD58 are suggestive of there being substantial plasticity in the topology of ligand binding by CD2. Thermodynamic analysis of the native CD48-CD2 interaction indicates that binding is driven by equivalent, weak enthalpic and entropic effects, in contrast to the human CD2-CD58 interaction, for which there is a large entropic barrier. Overall, the structural and biophysical comparisons of the CD2 homologues suggest that the evolutionary diversification of interacting cell surface proteins is rapid and constrained only by the requirement that binding remains weak and specific.

Published

2006

5. Immunology: how do T cells recognize antigen?

Author

Choudhuri K, Kearney A, Bakker TR, and van der Merwe PA

Subjects

Antigens metabolism, Humans, Major Histocompatibility Complex immunology, Antigens immunology, Immunity, Cellular immunology, Models, Immunological, Receptors, Antigen, T-Cell metabolism, Signal Transduction immunology, T-Lymphocytes immunology

Abstract

T cells recognize small fragments of microorganisms (antigens) on the surface of other cells using T cell antigen receptors. The mechanism by which these receptors signal into T cells is controversial, but two recent studies provide important new clues.

Published

2005

6. Design of a calcium-binding protein with desired structure in a cell adhesion molecule.

Author

Yang W, Wilkins AL, Ye Y, Liu ZR, Li SY, Urbauer JL, Hellinga HW, Kearney A, van der Merwe PA, and Yang JJ

Subjects

Animals, Binding Sites, CD2 Antigens genetics, CD2 Antigens metabolism, Calcium chemistry, Calcium metabolism, Calcium-Binding Proteins genetics, Calcium-Binding Proteins metabolism, Cell Adhesion Molecules genetics, Cell Adhesion Molecules metabolism, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Protein Engineering, Protein Structure, Tertiary, Rats, Spectrometry, Fluorescence, Surface Plasmon Resonance, Terbium chemistry, Terbium metabolism, CD2 Antigens chemistry, Calcium-Binding Proteins chemistry, Cell Adhesion Molecules chemistry

Abstract

Ca2+, "a signal of life and death", controls numerous cellular processes through interactions with proteins. An effective approach to understanding the role of Ca2+ is the design of a Ca2+-binding protein with predicted structural and functional properties. To design de novo Ca2+-binding sites in proteins is challenging due to the high coordination numbers and the incorporation of charged ligand residues, in addition to Ca2+-induced conformational change. Here, we demonstrate the successful design of a Ca2+-binding site in the non-Ca2+-binding cell adhesion protein CD2. This designed protein, Ca.CD2, exhibits selectivity for Ca2+ versus other di- and monovalent cations. In addition, La3+ (Kd 5.0 microM) and Tb3+ (Kd 6.6 microM) bind to the designed protein somewhat more tightly than does Ca2+ (Kd 1.4 mM). More interestingly, Ca.CD2 retains the native ability to associate with the natural target molecule. The solution structure reveals that Ca.CD2 binds Ca2+ at the intended site with the designed arrangement, which validates our general strategy for designing de novo Ca2+-binding proteins. The structural information also provides a close view of structural determinants that are necessary for a functional protein to accommodate the metal-binding site. This first success in designing Ca2+-binding proteins with desired structural and functional properties opens a new avenue in unveiling key determinants to Ca2+ binding, the mechanism of Ca2+ signaling, and Ca2+-dependent cell adhesion, while avoiding the complexities of the global conformational changes and cooperativity in natural Ca2+-binding proteins. It also represents a major achievement toward designing functional proteins controlled by Ca2+ binding.

Published

2005

7. CDR3 loop flexibility contributes to the degeneracy of TCR recognition.

Author

Reiser JB, Darnault C, Grégoire C, Mosser T, Mazza G, Kearney A, van der Merwe PA, Fontecilla-Camps JC, Housset D, and Malissen B

Subjects

Complementarity Determining Regions immunology, Humans, Ligands, Protein Binding immunology, Protein Conformation, Protein Structure, Tertiary, Receptors, Antigen, T-Cell immunology, Structure-Activity Relationship, T-Lymphocytes chemistry, Complementarity Determining Regions chemistry, Receptors, Antigen, T-Cell chemistry, T-Lymphocytes immunology

Abstract

T cell receptor (TCR) binding degeneracy lies at the heart of several physiological and pathological phenomena, yet its structural basis is poorly understood. We determined the crystal structure of a complex involving the BM3.3 TCR and an octapeptide (VSV8) bound to the H-2K(b) major histocompatibility complex molecule at a 2.7 A resolution, and compared it with the BM3.3 TCR bound to the H-2K(b) molecule loaded with a peptide that has no primary sequence identity with VSV8. Comparison of these structures showed that the BM3.3 TCR complementarity-determining region (CDR) 3alpha could undergo rearrangements to adapt to structurally different peptide residues. Therefore, CDR3 loop flexibility helps explain TCR binding cross-reactivity.

Published

2003