Kathryn A. Pape

Visualization of peptide-specific T cell immunity and peripheral tolerance induction in vivo

An adoptive transfer system was used to monitor physically the behavior of a trace population of TCR transgenic T cells in vivo. After subcutaneous injection of antigen in adjuvant, the antigen-specific cells accumulated first in the paracortical region of the draining lymph nodes, proliferated there for several days, and then moved into lymph node follicles, where they accounted for most of the T cells. They then disappeared slowly from the draining nodes, and the remaining cells were hypersensitive to antigenic stimulation in vitro. In contrast, when the antigen was introduced into the blood, the antigen-specific cells rapidly accumulated in the paracortical regions of all lymph nodes, proliferated there for a short time, but never entered follicles. Most of the cells then rapidly disappeared, leaving behind a population that was hyporesponsive to antigenic stimulation. These results provide a physical basis for the classical finding that antigen-specific memory and tolerance can be influenced by the form of antigen administration.

Different B cell populations mediate early and late memory during an endogenous immune response.

A cell enrichment technique reveals the dynamics of the endogenous memory B cell response. Memory B cells formed in response to microbial antigens provide immunity to later infections; however, the inability to detect rare endogenous antigen-specific cells limits current understanding of this process. Using an antigen-based technique to enrich these cells, we found that immunization with a model protein generated B memory cells that expressed isotype-switched immunoglobulins (swIg) or retained IgM. The more numerous IgM+ cells were longer lived than the swIg+ cells. However, swIg+ memory cells dominated the secondary response because of the capacity to become activated in the presence of neutralizing serum immunoglobulin. Thus, we propose that memory relies on swIg+ cells until they disappear and serum immunoglobulin falls to a low level, in which case memory resides with durable IgM+ reserves.

Use of adoptive transfer of T-cell-antigen-receptor-transgenic T cells for the study of T-cell activation in vivo

Summary: Adoptive transfer of TCR‐transgenic T cells uniformly expressing an identifiable TCR of known peptide/MHC specificity can be used to monitor the in vivo behavior of antigen‐specific T cells. We have used this system to show that naive T cells are initially activated within the T‐cell zones of secondary lymphoid tissue to prohferate in a B7‐dependent manner. If adjuvants or inflammatory cytokines are present during this period, enhanced numbers of T cells accumulate, migrate into B‐cell‐rich follicles, and acquire the capacity to produce IFN‐7 and help B cells produce IgG2a. If inflammation is absent, most of the initially activated antigen‐specific T cells disappear without entering the follicles and the survivors are poor producers of IL‐2 and IFN‐γ Our results indicate that inflammatory mediators play a key role in regulating the anatomic location, clonal expansion, survival and lymphokine production potential of antigen‐stimulated T cells in vivo.

A germinal center–independent pathway generates unswitched memory B cells early in the primary response

Early IgM+ and switched Ig+ memory B cells develop from a germinal center (GC)–independent pathway, whereas late switched memory cells are GC dependent.

Visualization of the Genesis and Fate of Isotype-switched B Cells during a Primary Immune Response

The life history of isotype-switched B cells is unclear, in part, because of an inability to detect rare antigen-specific B cells at early times during the immune response. To address this issue, a small population of B cells carrying targeted antibody transgenes capable of class switching was monitored in immunized mice. After contacting helper T cells, the first switched B cells appeared in follicles rather than in the red pulp, as was expected. Later, some of the switched B cells transiently occupied the red pulp and marginal zone, whereas others persisted in germinal centers (GCs). Antigen-experienced IgM B cells were rarely found in GCs, indicating that these cells switched rapidly after entering GCs or did not persist in this environment.

In vivo assessment of the relative contributions of deletion, anergy, and editing to B cell self-tolerance.

In normal B cell development, a large percentage of newly formed cells bear receptors with high levels of self-reactivity that must be tolerized before entry into the mature B cell pool. We followed the fate of self-reactive B cells expressing high affinity anti-hen egg lysozyme (HEL) Ag receptors exposed in vivo to membrane HEL in a setting in which the anti-HEL L chain was “knocked-in” at the endogenous L chain locus. These mice demonstrated extensive and efficient L chain receptor editing responses and had B cell numbers comparable to those found in animals lacking membrane Ag. BrdU labeling indicated that the time required for editing in response to membrane HEL was ∼6 h. In mice transgenic for soluble HEL, anti-HEL B cells capable of editing showed evidence for both editing and anergy. These data identify receptor editing as a major physiologic mechanism by which highly self-reactive B cells are tolerized to membrane and soluble self-Ags.

Antigen-Experienced CD4 T Cells Display a Reduced Capacity for Clonal Expansion In Vivo That Is Imposed by Factors Present in the Immune Host

It is thought that protective immunity is mediated in part by Ag-experienced T cells that respond more quickly and vigorously than naive T cells. Using adoptive transfer of OVA-specific CD4 T cells from TCR transgenic mice as a model system, we show that Ag-experienced CD4 T cells accumulate in lymph nodes more rapidly than naive T cells after in vivo challenge with Ag. However, the magnitude of clonal expansion by Ag-experienced T cells was much less than that of naive T cells, particularly at early times after primary immunization. Ag-experienced CD4 T cells quickly reverted to the slower but more robust clonal expansion behavior of naive T cells after transfer into a naive environment. Conversely, the capacity for rapid clonal expansion was acquired by naive CD4 T cells after transfer into passively immunized recipients. These results indicate that rapid in vivo response by Ag-experienced T cells is facilitated by Ag-specific Abs, whereas the limited capacity for clonal expansion is imposed by some other factor in the immune environment, perhaps residual Ag.

Heterogeneity in the differentiation and function of memory B cells

Vaccines that induce neutralizing antibodies have led to the eradication of small pox and have severely reduced the prevalence of many other infections. However, even the most successful vaccines do not induce protective antibodies in all individuals, and can fail to induce lifelong immunity. A key to remedying these shortcomings may lie in a better understanding of long-lived memory B cells. Recent studies have revealed novel insights into the differentiation and function of these cells, and have shown that the memory B cell pool is much more heterogeneous than previously appreciated.

Apoptosis and antigen affinity limit effector cell differentiation of a single naïve B cell

For a single B cell, many roads to take To successfully fight a pathogen, immunological B cells must wage a multipronged attack: They can differentiate into antibody-secreting plasma cells or become T cell–helping germinal center cells, or even long-lived memory cells. But can a single B cell acquire all of these different fates? To find out, Taylor et al. tracked the responses of single B cells in mice. Although some B cells acquired only one fate, others differentiated into all three. The authors linked the ability of B cells to differentiate into multiple subsets to their ability to proliferate and resist cell death, and the affinity of their antigen receptor. Science, this issue p. 784 Antigen affinity and the ability to resist cell death determine the differentiation patterns of individual immunological B cells. When exposed to antigens, naïve B cells differentiate into different types of effector cells: antibody-producing plasma cells, germinal center cells, or memory cells. Whether an individual naïve B cell can produce all of these different cell fates remains unclear. Using a limiting dilution approach, we found that many individual naïve B cells produced only one type of effector cell subset, whereas others produced all subsets. The capacity to differentiate into multiple subsets was a characteristic of clonal populations that divided many times and resisted apoptosis, but was independent of isotype switching. Antigen receptor affinity also influenced effector cell differentiation. These findings suggest that diverse effector cell types arise in the primary immune response as a result of heterogeneity in responses by individual naïve B cells.

A Protease-Dependent Mechanism for Initiating T-Dependent B Cell Responses to Large Particulate Antigens

Ab production is critical for antimicrobial immunity, and the initial step in this process is the binding of Ag to the BCR. It has been shown that small soluble proteins can directly access the lymph node follicles to reach naive B cells, but virus particles must be translocated into follicles via subcapsular sinus macrophages. In this article, we explore how large particulate Ags generate humoral immune responses. Ag-specific follicular B cells rapidly acquired Ag, presented peptide:MHC class II ligands, and produced T-dependent Ab responses following s.c. injection of 1-μm, Ag-linked microspheres, despite the microspheres being confined to the subcapsular sinus. The mechanism of Ag acquisition did not require dendritic cells, subcapsular sinus macrophages, or B cell movement to the subcapsular sinus. Rather, B cell Ag acquisition was protease-dependent, suggesting that some protein Ags are cleaved from the surface of particles to directly initiate humoral immune responses.