Catherine Haluszczak

The antigen-specific CD8+ T cell repertoire in unimmunized mice includes memory phenotype cells bearing markers of homeostatic expansion.

Memory T cells exhibit superior responses to pathogens and tumors compared with their naive counterparts. Memory is typically generated via an immune response to a foreign antigen, but functional memory T cells can also be produced from naive cells by homeostatic mechanisms. Using a recently developed method, we studied CD8 T cells, which are specific for model (ovalbumin) and viral (HSV, vaccinia) antigens, in unimmunized mice and found a subpopulation bearing markers of memory cells. Based on their phenotypic markers and by their presence in germ-free mice, these preexisting memory-like CD44hi CD8 T cells are likely to arise via physiological homeostatic proliferation rather than a response to environmental microbes. These antigen-inexperienced memory phenotype CD8 T cells display several functions that distinguish them from their CD44lo counterparts, including a rapid initiation of proliferation after T cell stimulation and rapid IFN-γ production after exposure to proinflammatory cytokines. Collectively, these data indicate that the unprimed antigen-specific CD8 T cell repertoire contains antigen-inexperienced cells that display phenotypic and functional traits of memory cells.

CD8α+ Dendritic Cell Trans Presentation of IL-15 to Naive CD8+ T Cells Produces Antigen-Inexperienced T Cells in the Periphery with Memory Phenotype and Function

Various populations of memory phenotype CD8+ T cells have been described over the last 15–20 y, all of which possess elevated effector functions relative to naive phenotype cells. Using a technique for isolating Ag-specific cells from unprimed hosts, we recently identified a new subset of cells, specific for nominal Ag, but phenotypically and functionally similar to memory cells arising as a result of homeostatic proliferation. We show in this study that these virtual memory (VM) cells are independent of previously identified innate memory cells, arising as a result of their response to IL-15 trans presentation by lymphoid tissue-resident CD8α+ dendritic cells in the periphery. The absence of IL-15, CD8+ T cell expression of either CD122 or eomesodermin or of CD8a+ dendritic cells all lead to the loss of VM cells in the host. Our results show that CD8+ T cell homeostatic expansion is an active process within the nonlymphopenic environment, is mediated by IL-15, and produces Ag-inexperienced memory cells that retain the capacity to respond to nominal Ag with memory-like function. Preferential engagement of these VM T cells into a vaccine response could dramatically enhance the rate by which immune protection develops.

Multiple Innate Signaling Pathways Cooperate with CD40 to Induce potent, CD70-dependent Cellular Immunity

We have previously shown that Toll-like receptor (TLR) agonists cooperate with CD40 to generate CD8 T cell responses exponentially larger than the responses generated with traditional vaccine formulations. We have also shown that combined TLR agonist/anti-CD40 immunization uniquely induces the upregulation of CD70 on antigen bearing dendritic cells (DCs). In contrast, immunization with either a TLR agonist or a CD40 stimulus alone does not significantly increase CD70 expression on DCs. Furthermore, the CD8(+) T cell response generated by combined TLR agonist/anti-CD40 immunization is dependent on the expression of CD70 by DCs, as CD70 blockade following immunization dramatically decreases the CD8 T cell response. Here we show that other innate pathways, independent of the TLRs, can also cooperate with CD40 to induce potent, CD70 dependent, CD8 T cell responses. These innate stimuli include Type I IFN (IFN) and alpha-galactosylceramide (alphaGalCer) or aC-GalCer, glycolipids that are presented by a nonclassical class I MHC molecule, CD1d, and are able to activate NKT cells. Furthermore, this combined IFN/anti-CD40 immunization generates protective memory against bacterial challenge with Listeria monocytogenes. Together these data indicate the importance of assessing CD70 expression on DCs as a marker for the capacity of a given vaccine formulation to potently activate cellular immunity. Our data indicate that optimal induction of CD70 expression requires a coordinated stimulation of both innate (TLR, IFN, alphaGalCer) and adaptive (CD40) signaling pathways.

Comparison of OX40 Ligand and CD70 in the Promotion of CD4+ T Cell Responses

The TNF superfamily members CD70 and OX40 ligand (OX40L) were reported to be important for CD4+ T cell expansion and differentiation. However, the relative contribution of these costimulatory signals in driving CD4+ T cell responses has not been addressed. In this study, we found that OX40L is a more important determinant than CD70 of the primary CD4+ T cell response to multiple immunization regimens. Despite the ability of a combined TLR and CD40 agonist (TLR/CD40) stimulus to provoke appreciable expression of CD70 and OX40L on CD8+ dendritic cells, resulting CD4+ T cell responses were substantially reduced by Ab blockade of OX40L and, to a lesser degree, CD70. In contrast, the CD8+ T cell responses to combined TLR/CD40 immunization were exclusively dependent on CD70. These requirements for CD4+ and CD8+ T cell activation were not limited to the use of combined TLR/CD40 immunization, because vaccinia virus challenge elicited primarily OX40L-dependent CD4 responses and exclusively CD70-dependent CD8+ T cell responses. Attenuation of CD4+ T cell priming induced by OX40L blockade was independent of signaling through the IL-12R, but it was reduced further by coblockade of CD70. Thus, costimulation by CD70 or OX40L seems to be necessary for primary CD4+ T cell responses to multiple forms of immunization, and each may make independent contributions to CD4+ T cell priming.

Type I IFN-Dependent T Cell Activation Is Mediated by IFN-Dependent Dendritic Cell OX40 Ligand Expression and Is Independent of T Cell IFNR Expression

Type I IFNs are important for direct control of viral infection and generation of adaptive immune responses. Recently, direct stimulation of CD4+ T cells via type I IFNR has been shown to be necessary for the formation of functional CD4+ T cell responses. In contrast, we find that CD4+ T cells do not require intrinsic type I IFN signals in response to combined TLR/anti-CD40 vaccination. Rather, the CD4 response is dependent on the expression of type I IFNR (IFNαR) on innate cells. Further, we find that dendritic cell (DC) expression of the TNF superfamily member OX40 ligand was dependent on type I IFN signaling in the DC, resulting in a reduced CD4+ T cell response that could be substantially rescued by an agonistic Ab to the receptor OX40. Taken together, we show that the IFNαR dependence of the CD4+ T cell response is accounted for exclusively by defects in DC activation.

Intrinsic B cell hypo‐responsiveness in mice prematurely expressing human CR2/CD21 during B cell development

We previously reported that human CR2 (hCR2) prematurely expressed under a murine Vλ2 promoter/Vλ2–4 enhancer minigene during the CD43+CD25– late pro‐B cell stage of development results in peripheral B cells with impaired responses to immunization with T‐dependent antigens. Herein, we show that hCR2 transgenic (Tg) mice also demonstrate a severe defect in T‐independent antigen responses and are substantially protected from clinical arthritis, synovitis and cartilage/bone destruction in a collagen‐induced arthritis model. This outcome is found despite the apparently normal development of autoreactive T cells with equivalent cytokine and proliferative responses to antigen when compared to non‐Tg control mice. These data suggest the presence of an intrinsic B cell defect in the hCR2 Tg mice. We also show that an hCR2‐dependent Ca2+ influx can be generated in both developing and mature Tg B cells, but with different rates of decay as compared to control wild‐type (WT) mice. In addition, although analysis of tyrosine‐phosphorylated proteins in WT and Tg B cells following B cell receptor (BCR)‐induced activation revealed the presence of distinctly different phosphorylation patterns, no differences were identified in several candidate protein targets. Overall, these data suggest that premature hCR2 expression and the consequences thereof during B cell development intrinsically alters the way mature B cells develop and subsequently respond to antigen through the BCR signaling complex.

Phenotype and function of protective, CD4-independent CD8 T cell memory

While the need for CD4 T cells in the generation of CD8 T cell memory has been well documented, the mechanism underlying their requirement remains unknown. Here, we detail an immunization method capable of generating CD8 memory T cells that are indifferent to CD4 T cell help. Using a subunit vaccination that combines polyIC and an agonistic CD40 antibody, we program protective CD4-independent CD8 T cell memory. When cells generated by combined polyIC/CD40 immunization are compared to cells produced following a CD4-dependent vaccination, Listeria monocytogenes, they display dramatic differences, both phenotypically and functionally. The memory cells generated in a CD4-deficient host by polyIC/CD40 immunization provide protection against secondary infectious challenge, whereas cells generated by LM immunization in the same environment do not. Interestingly, combined polyIC/CD40 immunization generates long-term memory cells with low Blimp-1 and elevated Eomes expression despite high expression of Blimp-1 during the primary response. The potency of combined polyIC/CD40 to elicit CD8+ T cell memory in the absence of CD4 T cells suggests that it could be considered as a vaccine adjuvant in clinical situations where CD4 responses/numbers are compromised.

Increased B cell deletion and significantly reduced auto-antibody titre due to premature expression of human complement receptor 2 (CR2, CD21)

The involvement of complement receptor 2 (CR2) in B cell tolerance and autoimmune disease has been revealed over the past decade or so. Our previous studies have established that mice prematurely expressing human CR2 under the control of a lambda light chain promoter (in particular the hCR2high line) have a marked deficit in their immune response to various antigens and fail to develop collagen-induced arthritis. This phenotype appears to be the result of irreversible changes in B cell signalling pathways and suggested that hCR2 expressing mice are protected from developing autoimmune disease. To test this hypothesis, we examined the ability of the hCR2 to block the development of spontaneous autoimmune disease on the C57BL/6j-Faslpr/Faslpr (B6lpr) background. We found that expression of hCR2 on the B6lpr background resulted in a significant reduction in levels of anti-nuclear antibodies (ANA) generated as mice aged but the levels of ANA were still higher than those found in age matched C57BL/6j (B6) mice. B cells from hCR2high mice were found to display a higher baseline level of apoptosis, whether analysed ex vivo or after in vitro culture, than their B6 counterparts and this was apparently linked to both surface IgM expression by the B cells and C3 levels in the mice. Our data also provides evidence that B cell survival in the presence of hCR2 is heavily modified by the background strain of the mouse. Overall, we have demonstrated that mice expressing hCR2 on their B cells during bone marrow development display a higher degree of apoptosis which may lead to a deletion of autoreactive B cells and be protective against the development of autoimmune disease.