Microbiology & Immunology - Research Publications
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ItemNo Preview AvailableQ&A: What do we know about influenza and what can we do about it?(Springer Science and Business Media LLC, 2009)
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ItemNo Preview AvailableThe challenge of viral immunity(CELL PRESS, 2007-09)Bringing together discussion of innate immunity, B cell and T cell responses, vaccine design and efficacy, and the genetics of HIV and AIDS resistance allows us to access the extraordinary complexity of viral immunity and host responsiveness.
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ItemNo Preview AvailableThe virus-immunity ecosystem(SPRINGER WIEN, 2005)The ecology of pathogenic viruses can be considered both in the context of survival in the macro-environments of nature, the theme pursued generally by epidemiologists, and in the micro-environments of the infected host. The long-lived, complex, higher vertebrates have evolved specialized, adaptive immune systems designed to minimise the consequences of such parasitism. Through evolutionary time, the differential selective pressures exerted variously by the need for virus and host survival have shaped both the "one-host" viruses and vertebrate immunity. With the development of vaccines to protect us from many of our most familiar parasites, the most dangerous pathogens threatening us now tend to be those "emerging", or adventitious, infectious agents that sporadically enter human populations from avian or other wild-life reservoirs. Such incursions must, of course, have been happening through the millenia, and are likely to have led to the extraordinary diversity of recognition molecules, the breadth in effector functions, and the persistent memory that distinguishes the vertebrate, adaptive immune system from the innate response mechanisms that operate more widely through animal biology. Both are important to contemporary humans and, particularly in the period immediately following infection, we still rely heavily on an immediate response capacity, elements of which are shared with much simpler, and more primitive organisms. Perhaps we will now move forward to develop useful therapies that exploit, or mimic, such responses. At this stage, however, most of our hopes for minimizing the threat posed by viruses still focus on the manipulation of the more precisely targeted, adaptive immune system.
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ItemQ&A: What have we found out about the influenza A (H1N1) 2009 pandemic virus?(Springer Science and Business Media LLC, 2009)
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ItemDifferential antigen presentation regulates the changing patterns of CD8+ T cell immunodominance in primary and secondary influenza virus infections(ROCKEFELLER UNIV PRESS, 2003-08-04)The specificity of CD8+ T cell responses can vary dramatically between primary and secondary infections. For example, NP366-374/Db- and PA224-233/Db-specific CD8+ T cells respond in approximately equal numbers to a primary influenza virus infection in C57BL/6 mice, whereas NP366-374/Db-specific CD8+ T cells dominate the secondary response. To investigate the mechanisms underlying this changing pattern of immunodominance, we analyzed the role of antigen presentation in regulating the specificity of the T cell response. The data show that both dendritic and nondendritic cells are able to present the NP366-374/Db epitope, whereas only dendritic cells effectively present the PA224-233/Db epitope after influenza virus infection, both in vitro and in vivo. This difference in epitope expression favored the activation and expansion of NP366-374/Db-specific CD8+ memory T cells during secondary infection. The data also show that the immune response to influenza virus infection may involve T cells specific for epitopes, such as PA224-233/Db, that are poorly expressed at the site of infection. In this regard, vaccination with the PA224-233 peptide actually had a detrimental effect on the clearance of a subsequent influenza virus infection. Thus, differential antigen presentation impacts both the specificity of the T cell response and the efficacy of peptide-based vaccination strategies.
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ItemProtection and compensation in the influenza virus-specific CD8+ T cell response(NATL ACAD SCIENCES, 2003-06-10)Influenza virus-specific CD8+ T cells generally recognize peptides derived from conserved, internal proteins that are not subject to antibody-mediated selection pressure. Prior exposure to any one influenza A virus (H1N1) can prime for a secondary CD8+ T cell response to a serologically different influenza A virus (H3N2). The protection afforded by this recall of established CD8+ T cell memory, although limited, is not negligible. Key characteristics of primary and secondary influenza-specific host responses are probed here with recombinant viruses expressing modified nucleoprotein (NP) and acid polymerase (PA) genes. Point mutations were introduced into the epitopes derived from the NP and PA such that they no longer bound the presenting H2Db MHC class I glycoprotein, and reassortant H1N1 and H3N2 viruses were made by reverse genetics. Conventional (C57BL/6J, H2b, and Ig+/+) and Ig-/- (muMT) mice were more susceptible to challenge with the single NP [HKx31 influenza A virus (HK)-NP] and PA (HK-PA) mutants, but unlike the Ig-/- mice, Ig+/+ mice were surprisingly resistant to the HK-NP/-PA double mutant. This virus was found to promote an enhanced IgG response resulting, perhaps, from the delayed elimination of antigen-presenting cells. Antigen persistence also could explain the increase in size of the minor KbPB1703 CD8+ T cell population in mice infected with the mutant viruses. The extent of such compensation was always partial, giving the impression that any virus-specific CD8+ T cell response operates within constrained limits. It seems that the relationship between protective humoral and cellular immunity is neither simple nor readily predicted.
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ItemContribution of T cell receptor affinity to overall avidity for virus-specific CD8+ T cell responses(NATL ACAD SCIENCES, 2005-08-09)Prior analysis has characterized the clonal characteristics of effector CD8(+) T cells specific for the prominent influenza A virus nucleoprotein (NP) and acid polymerase (PA) peptides presented by H2D(b). Using a single-cell approach and determination of CDR3beta profiles, a limited, predominantly "public" repertoire was found for CD8(+)D(b)NP(366)(+)Vbeta8.3+ cells, whereas diverse and "private" T cell antigen receptor (TCR)beta clonotypes were typical of the CD8(+)D(b)PA(224)(+)Vbeta7+ response. This single-cell approach has now been used to relate the contributions of particular clonotypes (or affinities) to high-avidity TCRs, as defined by binding under conditions of limiting tetramer availability. At least by the measure of CDR3beta usage, no difference could be found between total and high-avidity populations in the spectrum of TCR-pMHC affinities throughout the limited, and relatively public, CD8(+)D(b)NP(366)(+)Vbeta8.3+ populations. Conversely, the more even (by clone size), diverse, and private CD8(+)D(b)PA(224)(+)Vbeta7+ response was characterized by the clear partitioning of the largest T cell clones in the high-avidity compartment. These results suggest that the relatively constrained CD8(+)D(b)NP(366)(+)Vbeta8.3+ set utilizes a relatively narrow range of affinities, whereas the broader CD8(+)D(b)PA(224)(+)Vbeta7+ response is induced at a range of TCR-pMHC affinities. Thus, whereas TCR sequence (or affinity) appears to contribute substantially to the avidity profile of diverse virus-specific CD8+ populations, other mechanisms may be prominent where the TCR spectrum is more limited.
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ItemConserved T cell receptor usage in primary and recall responses to an immunodominant influenza virus nucleoprotein epitope(NATL ACAD SCIENCES, 2004-04-06)The CD8+ T cell response to the immunodominant DbNP366 epitope has been analyzed sequentially to determine the prevalence and persistence of different T cell antigen receptor (TCR)Vbeta8.3 clonotypes after primary and secondary influenza virus challenge. Based on the length and amino acid sequences of the complementarity-determining region 3 of TCRbeta (CDR3beta) loop and associated Jbeta usage, the same dominant TCRbeta signatures were found in the blood, the spleen, and the site of virus-induced pathology in the infected respiratory tract. Longitudinal analysis demonstrated that TCRbeta prominent in the antigen-driven phase of response persisted into memory and were again expanded after secondary challenge. A proportion of these high-frequency TCRbeta expressed "public" CDR3beta sequences that were detected in every mouse sampled, whereas others were found more than once but were not invariably present. Analysis of N-region nucleotide diversity established that as many as 10 different nucleic acid sequences (maximum of four "nucleotypes" in any one mouse) could encode a single public TCRbeta amino acid sequence. Conversely, whereas some of the unique, "private" TCRbeta achieved a substantial clone size, they were always specified by a single nucleotype. Although there is a strong stochastic element in this response, the public TCRbeta seem to represent a "best fit" for this immunodominant epitope, are selected preferentially from the naive TCR repertoire, and assume even greater prominence after secondary challenge.
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ItemA virus-specific CD8+ T cell immunodominance hierarchy determined by antigen dose and precursor frequencies(NATL ACAD SCIENCES, 2006-01-24)Immunodominance hierarchies are a substantial, but poorly understood, characteristic of CD8(+) T cell-mediated immunity. Factors influencing the differential responses to the influenza A virus nucleoprotein (NP(366-374)) and acid polymerase (PA(224-233)) peptides presented by H2D(b) have been analyzed by disabling (N5--> Q substitution) these peptides in their native configuration, then expressing them in the viral neuraminidase protein. This strategy of shifting epitopes within the same viral context resulted in an apparent equalization of D(b)NP(366) [epitope consisting of viral nucleoprotein (NP) amino acid residues 366-374 complexed with the H2D(b) MHC class I glycoprotein] and D(b)PA(224) (H2D(b)+PA(224-233)) epitope abundance after direct infection in vitro and induced reproducible changes in the magnitude of the D(b)NP(366)- and D(b)PA(224)-specific T cell subsets generated after infection of mice. Comparison of D(b)NP(366)- and D(b) PA(224)-specific CD8(+) T cell responses induced from the native configuration and from the viral neuraminidase stalk demonstrated that the size of both primary and secondary responses is influenced by relative epitope levels and that, at least after secondary challenge, the magnitude of responses is also determined by CD8(+) T cell precursor frequency. Thus, this immunodominance hierarchy is a direct function of antigen dose and T cell numbers.