Your search keyword '"Twist KA"' showing total 6 results

1. Structural and functional correlates of enhanced antiviral immunity generated by heteroclitic CD8 T cell epitopes.

Author

Trujillo JA, Gras S, Twist KA, Croft NP, Channappanavar R, Rossjohn J, Purcell AW, and Perlman S

Subjects

Amino Acid Substitution, Animals, Antigens, Viral genetics, CD8-Positive T-Lymphocytes pathology, Coronavirus genetics, Coronavirus Infections genetics, Epitopes, T-Lymphocyte genetics, HeLa Cells, Histocompatibility Antigens Class I genetics, Histocompatibility Antigens Class I immunology, Humans, Mice, Mutation, Missense, Peptides genetics, Viral Proteins genetics, Viral Proteins immunology, Antigens, Viral immunology, CD8-Positive T-Lymphocytes immunology, Coronavirus immunology, Coronavirus Infections immunology, Epitopes, T-Lymphocyte immunology, Peptides immunology

Abstract

Peptides that bind poorly to MHC class I molecules often elicit low-functional avidity T cell responses. Peptide modification by altering the anchor residue facilitates increased binding affinity and may elicit T cells with increased functional avidity toward the native epitope ("heteroclitic"). This augmented MHC binding is likely to increase the half-life and surface density of the heteroclitic complex, but precisely how this enhanced T cell response occurs in vivo is not known. Furthermore, the ideal heteroclitic epitope will elicit T cell responses that completely cross-react with the native epitope, maximizing protection and minimizing undesirable off-target effects. Such epitopes have been difficult to identify. In this study, using mice infected with a murine coronavirus that encodes epitopes that elicit high (S510, CSLWNGPHL)- and low (S598, RCQIFANI)-functional avidity responses, we show that increased expression of peptide S598 but not S510 generated T cells with enhanced functional avidity. Thus, immune responses can be augmented toward T cell epitopes with low functional avidity by increasing Ag density. We also identified a heteroclitic epitope (RCVIFANI) that elicited a T cell response with nearly complete cross-reactivity with native epitope and demonstrated increased MHC/peptide abundance compared with native S598. Structural and thermal melt analyses indicated that the Q600V substitution enhanced stability of the peptide/MHC complex without greatly altering the antigenic surface, resulting in highly cross-reactive T cell responses. Our data highlight that increased peptide/MHC complex display contributes to heteroclitic epitope efficacy and describe parameters for maximizing immune responses that cross-react with the native epitope., (Copyright © 2014 by The American Association of Immunologists, Inc.)

Published

2014

2. Molecular imprint of exposure to naturally occurring genetic variants of human cytomegalovirus on the T cell repertoire.

Author

Smith C, Gras S, Brennan RM, Bird NL, Valkenburg SA, Twist KA, Burrows JM, Miles JJ, Chambers D, Bell S, Campbell S, Kedzierska K, Burrows SR, Rossjohn J, and Khanna R

Subjects

Antigens, Viral immunology, Cross Reactions immunology, Epitopes, T-Lymphocyte genetics, Epitopes, T-Lymphocyte immunology, Genetic Variation immunology, HLA-B8 Antigen genetics, HLA-B8 Antigen immunology, Heart Transplantation, Humans, Immunologic Memory immunology, Kidney Transplantation, Lung Transplantation, Lymphocyte Activation immunology, Transplantation Immunology, CD8-Positive T-Lymphocytes immunology, Cytomegalovirus genetics, Cytomegalovirus immunology, Cytomegalovirus Infections immunology, T-Lymphocyte Subsets immunology

Abstract

Exposure to naturally occurring variants of herpesviruses in clinical settings can have a dramatic impact on anti-viral immunity. Here we have evaluated the molecular imprint of variant peptide-MHC complexes on the T-cell repertoire during human cytomegalovirus (CMV) infection and demonstrate that primary co-infection with genetic variants of CMV was coincident with development of strain-specific T-cell immunity followed by emergence of cross-reactive virus-specific T-cells. Cross-reactive CMV-specific T cells exhibited a highly conserved public T cell repertoire, while T cells directed towards specific genetic variants displayed oligoclonal repertoires, unique to each individual. T cell recognition foot-print and pMHC-I structural analyses revealed that the cross-reactive T cells accommodate alterations in the pMHC complex with a broader foot-print focussing on the core of the peptide epitope. These findings provide novel molecular insight into how infection with naturally occurring genetic variants of persistent human herpesviruses imprints on the evolution of the anti-viral T-cell repertoire.

Published

2014

3. Preemptive priming readily overcomes structure-based mechanisms of virus escape.

Author

Valkenburg SA, Gras S, Guillonneau C, Hatton LA, Bird NA, Twist KA, Halim H, Jackson DC, Purcell AW, Turner SJ, Doherty PC, Rossjohn J, and Kedzierska K

Subjects

Animals, Binding Sites genetics, CD8-Positive T-Lymphocytes virology, Crystallization, Epitopes, T-Lymphocyte genetics, Flow Cytometry, Genes, MHC Class I genetics, Mice, Mice, Inbred C57BL, Mutagenesis, Site-Directed, Reverse Transcriptase Polymerase Chain Reaction, Sequence Analysis, DNA, beta 2-Microglobulin immunology, CD8-Positive T-Lymphocytes immunology, Epitopes, T-Lymphocyte immunology, Immune Evasion genetics, Influenza A virus genetics, Influenza A virus immunology, Models, Molecular, beta 2-Microglobulin chemistry

Abstract

A reverse-genetics approach has been used to probe the mechanism underlying immune escape for influenza A virus-specific CD8(+) T cells responding to the immunodominant D(b)NP366 epitope. Engineered viruses with a substitution at a critical residue (position 6, P6M) all evaded recognition by WT D(b)NP366-specific CD8(+) T cells, but only the NPM6I and NPM6T mutants altered the topography of a key residue (His155) in the MHC class I binding site. Following infection with the engineered NPM6I and NPM6T influenza viruses, both mutations were associated with a substantial "hole" in the naïve T-cell receptor repertoire, characterized by very limited T-cell receptor diversity and minimal primary responses to the NPM6I and NPM6T epitopes. Surprisingly, following respiratory challenge with a serologically distinct influenza virus carrying the same mutation, preemptive immunization against these escape variants led to the generation of secondary CD8(+) T-cell responses that were comparable in magnitude to those found for the WT NP epitope. Consequently, it might be possible to generate broadly protective T-cell immunity against commonly occurring virus escape mutants. If this is generally true for RNA viruses (like HIV, hepatitis C virus, and influenza) that show high mutation rates, priming against predicted mutants before an initial encounter could function to prevent the emergence of escape variants in infected hosts. That process could be a step toward preserving immune control of particularly persistent RNA viruses and may be worth considering for future vaccine strategies.

Published

2013

4. Crystal structure of the bacteriophage T4 late-transcription coactivator gp33 with the β-subunit flap domain of Escherichia coli RNA polymerase.

Author

Twist KA, Campbell EA, Deighan P, Nechaev S, Jain V, Geiduschek EP, Hochschild A, and Darst SA

Subjects

Amino Acid Sequence, Conserved Sequence, Crystallography, X-Ray, DNA-Directed RNA Polymerases, Escherichia coli Proteins metabolism, Models, Molecular, Molecular Sequence Data, Promoter Regions, Genetic genetics, Protein Structure, Secondary, Protein Structure, Tertiary, Protein Subunits metabolism, Sequence Homology, Amino Acid, Sigma Factor chemistry, Trans-Activators metabolism, Transcription, Genetic, Viral Proteins metabolism, Bacteriophage T4 chemistry, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Protein Subunits chemistry, Trans-Activators chemistry, Viral Proteins chemistry

Abstract

Activated transcription of the bacteriophage T4 late genes, which is coupled to concurrent DNA replication, is accomplished by an initiation complex containing the host RNA polymerase associated with two phage-encoded proteins, gp55 (the basal promoter specificity factor) and gp33 (the coactivator), as well as the DNA-mounted sliding-clamp processivity factor of the phage T4 replisome (gp45, the activator). We have determined the 3.0 Å-resolution X-ray crystal structure of gp33 complexed with its RNA polymerase binding determinant, the β-flap domain. Like domain 4 of the promoter specificity σ factor (σ(4)), gp33 interacts with RNA polymerase primarily by clamping onto the helix at the tip of the β-flap domain. Nevertheless, gp33 and σ(4) are not structurally related. The gp33/β-flap structure, combined with biochemical, biophysical, and structural information, allows us to generate a structural model of the T4 late promoter initiation complex. The model predicts protein/protein interactions within the complex that explain the presence of conserved patches of surface-exposed residues on gp33, and provides a structural framework for interpreting and designing future experiments to functionally characterize the complex.

Published

2011

5. A novel method for the production of in vivo-assembled, recombinant Escherichia coli RNA polymerase lacking the α C-terminal domain.

Author

Twist KA, Husnain SI, Franke JD, Jain D, Campbell EA, Nickels BE, Thomas MS, Darst SA, and Westblade LF

Subjects

Amino Acid Sequence, Amino Acid Substitution, DNA-Directed RNA Polymerases isolation & purification, Escherichia coli genetics, Molecular Sequence Data, Protein Structure, Tertiary, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits isolation & purification, Recombinant Proteins isolation & purification, Sequence Deletion, Up-Regulation, DNA-Directed RNA Polymerases chemistry, DNA-Directed RNA Polymerases genetics, Escherichia coli enzymology, Protein Engineering methods, Recombinant Proteins chemistry, Recombinant Proteins genetics

Abstract

The biochemical characterization of the bacterial transcription cycle has been greatly facilitated by the production and characterization of targeted RNA polymerase (RNAP) mutants. Traditionally, RNAP preparations containing mutant subunits have been produced by reconstitution of denatured RNAP subunits, a process that is undesirable for biophysical and structural studies. Although schemes that afford the production of in vivo-assembled, recombinant RNAP containing amino acid substitutions, insertions, or deletions in either the monomeric β or β' subunits have been developed, there is no such system for the production of in vivo-assembled, recombinant RNAP with mutations in the homodimeric α-subunits. Here, we demonstrate a strategy to generate in vivo-assembled, recombinant RNAP preparations free of the α C-terminal domain. Furthermore, we describe a modification of this approach that would permit the purification of in vivo-assembled, recombinant RNAP containing any α-subunit variant, including those variants that are lethal. Finally, we propose that these related approaches can be extended to generate in vivo-assembled, recombinant variants of other protein complexes containing homomultimers for biochemical, biophysical, and structural analyses., (Copyright © 2011 The Protein Society.)

Published

2011

6. Complete structural model of Escherichia coli RNA polymerase from a hybrid approach.

Author

Opalka N, Brown J, Lane WJ, Twist KA, Landick R, Asturias FJ, and Darst SA

Subjects

Amino Acid Sequence, Cryoelectron Microscopy, Crystallography, X-Ray, Molecular Sequence Data, Protein Conformation, Sequence Homology, Amino Acid, DNA-Directed RNA Polymerases chemistry, Escherichia coli enzymology, Models, Molecular

Abstract

The Escherichia coli transcription system is the best characterized from a biochemical and genetic point of view and has served as a model system. Nevertheless, a molecular understanding of the details of E. coli transcription and its regulation, and therefore its full exploitation as a model system, has been hampered by the absence of high-resolution structural information on E. coli RNA polymerase (RNAP). We use a combination of approaches, including high-resolution X-ray crystallography, ab initio structural prediction, homology modeling, and single-particle cryo-electron microscopy, to generate complete atomic models of E. coli core RNAP and an E. coli RNAP ternary elongation complex. The detailed and comprehensive structural descriptions can be used to help interpret previous biochemical and genetic data in a new light and provide a structural framework for designing experiments to understand the function of the E. coli lineage-specific insertions and their role in the E. coli transcription program., Competing Interests: The authors have declared that no competing interests exist.

Published

2010