Eric G. Pamer

Coordinate Regulation of Complex T Cell Populations Responding to Bacterial Infection

Bacterial infections activate complex T cell populations that differ in size and antigen specificity. We used tetramerized MHC class I molecules complexed with Listeria monocytogenes-derived epitopes to characterize four distinct CD8+ T lymphocyte populations during bacterial infection. Surprisingly, T cell populations differing in antigen specificity expand, contract, and enter the T cell memory compartment synchronously. Because the four L. monocytogenes epitopes are presented with different efficiencies and have distinct stabilities in infected cells, our findings suggest that these factors do not determine in vivo T cell dynamics. While T cell activation requires antigen presentation, the timing and extent of T cell expansion appear to be regulated in a coordinated fashion independent of antigen quantity and stability.

Early Programming of T Cell Populations Responding to Bacterial Infection

The duration of infection and the quantity of Ag presented in vivo are commonly assumed to influence, if not determine, the magnitude of T cell responses. Although the cessation of in vivo T cell expansion coincides with bacterial clearance in mice infected with Listeria monocytogenes, closer analysis suggests that control of T cell expansion and contraction is more complex. In this report, we show that the magnitude and kinetics of Ag-specific T cell responses are determined during the first day of bacterial infection. Expansion of Ag-specific T lymphocyte populations and generation of T cell memory are independent of the duration and severity of in vivo bacterial infection. Our studies indicate that the Ag-specific T cell response to L. monocytogenes is programmed before the peak of the innate inflammatory response and in vivo bacterial replication.

Direct Assessment of MHC Class I Binding by Seven Ly49 Inhibitory NK Cell Receptors

Mouse NK cells express at least seven inhibitory Ly49 receptors. Here we employ a semiquantitative cell-cell adhesion assay as well as class I/peptide tetramers to provide a comprehensive analysis of specificities of Ly49 receptors for class I MHC molecules in eight MHC haplotypes. Different Ly49 receptors exhibited diverse binding properties. The degree of class I binding was related to the extent of functional inhibition. The tetramer studies demonstrated that neither glycosylation nor coreceptors were necessary for class I binding to Ly49 receptors and uncovered peptide-specific recognition by a Ly49 receptor. The results provide a foundation for interpreting and integrating many existing functional studies as well as for designing tests of NK cell development and self-tolerance.

H-2M3 presents a listeria monocytogenes peptide to cytotoxic T lymphocytes

We report evidence that a major histocompatibility complex-encoded nonclassic class I molecule presents a foreign peptide to cytotoxic T lymphocytes (CTL) during an infection. Mice immunized with virulent Listeria monocytogenes generate CD8+ CTL with alpha beta receptors specific for a bacterial peptide presented by a conserved class I molecule encoded in the M region of the major histocompatibility complex. The Listeria peptide is digested by carboxypeptidase Y but resists aminopeptidase M, and only peptides with N-formyl methionine competitively block its presentation to CTL. Transfection with the H-2M3d gene enables a negative (H-2w17) cell line to present the bacterial peptide. One function, therefore, of H-2M3 is to present bacterial peptides to CTL during infection.

Efficiency of MHC class I antigen processing: A quantitative analysis

Listeria monocytogenes is an intracellular pathogen that secretes proteins into host cell cytosol. One such protein, the murein hydrolase p60, is processed by the host cell into the nonamer peptide p60 217-225 and presented to cytotoxic T lymphocytes by the H-2Kd MHC class I molecule. Using strains of L. monocytogenes that secrete different amounts of p60, we show that the rate of p60 217-225 production is proportional to the quantity of intracellular antigen. The appearance of p60 217-225 is coupled to the degradation of newly synthesized p60. By accounting for the rate of intracellular antigen secretion and degradation, we estimate that approximately 35 p60 molecules are degraded to produce one p60 217-225 epitope. These findings provide an estimate of the efficiency of antigen processing and shed light on the capacity of the MHC class I antigen processing pathway to accommodate foreign antigens.

A Listeria monocytogenes Pentapeptide Is Presented to Cytolytic T Lymphocytes by the H2-M3 MHC Class Ib Molecule

Polymorphism of MHC class Ia molecules severely constrains vaccine development against intracellular pathogens. Antigen presentation by MHC class Ib molecules, which are generally conserved between different individuals, may circumvent this obstacle. Herein, we use tandem mass spectrometry to identify a Listeria monocytogenes pentapeptide antigen that is presented to T lymphocytes by the H2-M3 MHC class Ib molecule. The peptide contains N-formyl methionine at the N terminus and exclusively hydrophobic amino acids. Mice of the H-2 d, H-2 b,and H-2 k haplotypes respond to this peptide upon infection with Listeria monocytogenes. Identification of antigens presented by MHC class Ib molecules is feasible and may provide opportunities for relatively unrestricted vaccine development.

MHC class I antigen processing of Listeria monocytogenes proteins: implications for dominant and subdominant CTL responses.

Summary: Listeria monocytogenes (L. monocytogenes) secretes proteins associated with its virulence into the cytosol of infected cells. These secreted proteins are degraded by host cell proteasomes and processed into peptides that are bound by MHC class I molecules in the endoplasmic reticulum. We have found that the MHC class I antigen‐processing pathway is very efficient at generating the epitopes that are presented to cytolytic T lymphocytes (CTL). Depending on which antigen is investigated, from 3 to 30 % of degraded antigens are processed into nonamer peptides that are bound by MHC class I molecules. Surprisingly, neither the efficiency of epitope generation nor the absolute number of epitopes per infected cell determines the magnitude of the in vivo CTL response. One of the least prevalent epitopes, derived from an antigen that is virtually undetectable in infected cells, primes the immunodominant CTL response in L. monocytogenes‐infected mice. Our studies suggest that immunodominant and subdominant T‐cell responses cannot be predicted by the prevalence of antigens or epitopes alone, and that additional factors, yet to be determined, are involved.

T CELL RESPONSES TO BACTERIAL INFECTION

Many exciting advances in our understanding of T cell mediated immunity to bacterial infection have occurred in the past several years. T cell responses have been more fully characterized, due in part to the development of MHC class I tetramers. The importance of cytokines and various effector molecules in defense against infection has come to light. Finally, intracellular bacteria are being exploited to deliver antigens and DNA in an effort to induce immunity to pathogens.

The CD40–CD154 system in anti-infective host defense

Research in the past few years has documented significant advances in our understanding of the CD40-CD40 ligand (CD154) system in diverse immune functions. This system influences many T cell mediated inflammatory immune responses and effector functions, unmasking a previously unexpected role for CD40-CD154 in cell mediated immunity. Manipulation of CD154 in animal models of infection by the use of CD154-deficient mice or anti-CD154 antibodies has shown the importance of this system in the initiation of the inflammatory response, in the activation of antigen-presenting cells and in resistance to infections.

Differing Roles of Inflammation and Antigen in T Cell Proliferation and Memory Generation

Recent studies have demonstrated that viral and bacterial infections can induce dramatic in vivo expansion of Ag-specific T lymphocytes. Although presentation of Ag is critical for activation of naive T cells, it is less clear how dependent subsequent in vivo T cell proliferation and memory generation are upon Ag. We investigated T cell expansion and memory generation in mice infected alternately with strains of Listeria monocytogenes that contained or lacked an immunodominant, MHC class I-restricted T cell epitope. We found substantial differences in the responses of effector and memory T cells to inflammatory stimuli. Although effector T cells undergo in vivo expansion in response to bacterial infection in the absence of Ag, memory T cells show no evidence for such bystander activation. However, Ag-independent expansion of effector T cells does not result in increased memory T cell frequencies, indicating that Ag presentation is critical for effective memory T cell generation. Early reinfection of mice with L. monocytogenes before the maximal primary T cell response induces typical memory expansion, suggesting that the capacity for a memory T cell response exists within the primary effector population. Our findings demonstrate that T cell effector proliferation and memory generation are temporally overlapping processes with differing requirements for Ag.