Antigen-presenting B cells: efficient uptake and presentation by activated B cells for induction of cytotoxic T lymphocytes against vesicular stomatitis virus

Salmonella modulates B cell biology to evade CD8(+) T cell-mediated immune responses

Although B cells and antibodies are the central effectors of humoral immunity, B cells can also produce and secrete cytokines and present antigen to helper T cells. The uptake of antigen is mainly mediated by endocytosis; thus, antigens are often presented by MHC-II molecules. However, it is unclear if B cells can present these same antigens via MHC-I molecules. Recently, Salmonella bacteria were found to infect B cells, allowing possible antigen cross-processing that could generate bacterial peptides for antigen presentation via MHC-I molecules. Here, we will discuss available knowledge regarding Salmonella antigen presentation by infected B cell MHC-I molecules and subsequent inhibitory effects on CD8(+) T cells for bacterial evasion of cell-mediated immunity.

CD8 T cell priming by B lymphocytes is CD4 help dependent

While it is generally accepted that B lymphocytes can present antigen and activate CD4 T cells, priming of CD8 T cells by B lymphocytes remains controversial. Recently, we showed that mice injected with genetically programmed B lymphocytes generate antigen specific CD4 and CD8 T cell responses in vivo that could also be induced in mice lacking functional dendritic cells. To gain further insights into the requirements for T cell priming by antigen-presenting B lymphocytes, in vitro experiments were performed using ovalbumin (OVA) and OVA-specific TCR-transgenic CD4 and CD8 T cells. We found that while B lymphocytes can directly prime CD4 T cells, the activation of CD8 T cells requires T cell help. Transfer experiments show that help can either be contact dependent or be mediated by soluble factors in the supernatants of activated OVA-specific CD4 T cells. Furthermore, the effect of activated CD4 T cells can be replaced by soluble recombinant IL-4. Collectively, the data show the existence of different requirements for priming of CD4 and CD8 T cells and point to the previously unappreciated fact that the induction of CD8 T cell responses by B lymphocytes requires T cell help.

Antigen processing of vesicular stomatitis virus in situ. Interdigitating dendritic cells present viral antigens independent of marginal dendritic cells but fail to prime CD4(+) and CD8(+) T cells

Acute macrophage (M phi) depletion, using a liposome-mediated 'suicide technique', markedly suppressed priming of splenic CD4(+) and CD8(+) T-cell responses to vesicular stomatitis virus (VSV). However, phagocytic marginal dendritic cells (MDC), but not interdigitating dendritic cells (IDC), are now known to be also depleted by this technique. To clarify the role splenic dendritic cell (DC) subsets and M phi play in priming for a virus-specific T-cell-mediated immune response, DC and M phi were purified from VSV-infected mice and assayed for the presence of epitopes recognized by VSV helper T (Th) cells and cytotoxic T lymphocytes (CTL). Antigen pulse experiments performed in situ demonstrated that VSV Th cell and CTL epitopes became transiently associated only with DC, but not M phi or B cells, indicating that DC represent the critical antigen-presenting cell (APC) population in vivo for this virus. The failure of MDC/M phi-deficient mice to become primed was not due to the complete elimination of antigen-presenting DC because VSV peptide/class I and II complexes were detected on IDC following lipsome-mediated elimination of phagocytic cells. However, the VSV-induced chemokine response was dramatically suppressed in these mice. Thus, despite the expression of VSV peptide/class I and II complexes, IDC are not sufficient to prime VSV Th cells in the absence of MDC and/or splenic M phi.

T and B cell tolerance and responses to viral antigens in transgenic mice: implications for the pathogenesis of autoimmune versus immunopathological disease

Experiments with transgenic mice illustrate clonal elimination of T cells specific for antigens expressed appropriately in the thymus, but presence of inducible T cells when the antigen presented on class I MHC antigens is expressed exclusively on non-lymphohemopoietic cells in the periphery (pancreatic beta islet cells). TCR-transgenic LCMV-carrier mice expressing LCMV in the thymus exhibit clonal elimination at the early CD4+8+ thymocyte stage, causing CTL unresponsiveness in these mice. In contrast, studies with RIP LCMV-GP-transgenic mice (expressing GP in pancreatic beta cells) and with TCR-RIP LCMV-GP double-transgenic mice show that CTL reactivity is normal. These experiments argue against so-called peripheral anergy of class I MHC antigen-restricted cytotoxic T cells as a general mechanism of peripheral immunological tolerance to self. They reveal that self epitopes that are genetically self and presented by class I antigens may not be considered immunologically self if expressed solely extrathymically, despite the fact that they are antigenic and can be recognized by induced effector T cells. Genetic self that is presented on cells which can induce neither tolerance nor an immune response is immunologically dealt with as foreign and therefore may be called nonimmunological self. Appropriate presentation of the same epitope on antigen-presenting cells promptly induces effector T cells and causes disease; such disease should not be called autoimmune because it is an immunopathological T-cell mediated disease, comparable to an unfavorably balanced immunopathological T-cell response to a virus. Mechanisms that control autoantibody responses were studied in mice expressing a viral transgene. Such mice generate neutralizing antiviral autoantibody responses only when the transgenic viral antigen is linked to a foreign T-helper determinant. These findings, therefore, document differences in levels of T- vs B-cell tolerance (so-called split tolerance) under a given expression level of a "self" antigen. They illustrate how unresponsiveness of B cells to produce T-independent IgM is dose-dependent and that IgG autoantibodies are triggered by introducing foreign T-helper determinants that can be recognised in a linked fashion. This model suggests that, while T-cell tolerance to tolerogenic self in the thymus is solid, B-cell tolerance in general is not. From the point of view of autoantibody responses these T-helper cells may also be called immunopathological; i.e., these T-helper cells are specific for foreign epitopes that, via linked recognition, trigger truly autoimmune B cells.(ABSTRACT TRUNCATED AT 400 WORDS)

T helper cells in cytotoxic T lymphocyte development: analysis of the cellular basis for deficient T helper cell function in the L3T4-independent T helper cell pathway

In this present study, lymphokine (IL-2/IL-4) production in VSV-induced Th cell (L3T4+Lyt-2- VSV-immune T cells) and memory CTL populations (L3T4-Lyt-2+ VSV-immune T cells) has been assessed in order to gain some understanding as to why the Lyt-2+ subset (L3T4-independent Th cell pathway) fails to provide Th cell function for anti-VSV CTL responses. Our studies demonstrated that following specific antigen (VSV, H-2 antigen) or mitogen stimulation, lymphokine activity was detected in the supernatants obtained from VSV-induced Th but not VSV memory CTL populations. The presence of blocking concentrations of PC61, a monoclonal antibody (mAb) to the IL-2 receptor (IL-2R), revealed augmented lymphokine activity only in the VSV-induced Th cell supernatant. VSV-induced Th cells secreted both IL-2 and IL-4 following stimulation with VSV. Two lines of evidence supported the view that both these lymphokines were important for an anti-VSV CTL response: (1) mAb to either IL-2 or IL-4 inhibited CTL maturation and (2) the combination of exogenous IL-2 and IL-4 reconstituted a class I-restricted. VSV-specific CTL response in Th cell-depleted T cell cultures. The failure to detect lymphokine production in bulk cultures of the VSV memory CTL population was consistent with limiting dilution (LD) analysis of lymphokine-producing cells in the spleen of VSV-immune mice. Thus, approximately 1/15,000 Lyt-2-depleted, VSV-immune T cells were positive for lymphokine production following VSV stimulation, whereas less than 1/1,000,000 L3T4-depleted, VSV-immune T cells were scored as lymphokine-secreting cells following stimulation with this same virus. Similarly, precursor estimates for lymphokine-producing cells against allogeneic class I antigens demonstrated that the majority of lymphokine-producing cells also resided in the L3T4+ subset. Lymphokine-secreting Lyt-2+ cells were detected at low but not high cell densities suggesting that Lyt-2+ cells may secrete another lymphokine(s) that inhibits IL-2/IL-4 production. Thus, these studies demonstrate an obligatory requirement for the L3T4-dependent Th cell pathway for optimal CTL responses derived from either CTLp or memory CTLs.

T lymphocyte stress response. I. Induction of heat shock protein synthesis at febrile temperatures is correlated with enhanced resistance to hyperthermic stress but not to heavy metal toxicity or dexamethasone-induced immunosuppression

We have investigated the effect of febrile temperatures (less than or equal to 41 degrees C) on T cell heat shock protein (hsp) synthesis and the acquisition of stress tolerance. Enhanced synthesis of hsps was detected in highly purified T cells and two cloned T cell lines representing helper T (D10) and cytotoxic T cell (Qa-2 128.38) subsets at temperatures as low as 39 degrees C with a maximal response at 41 degrees C. Three major hsps with approximate molecular weights of 110, 90, and 75 were detected in these T cell populations. Western blot analysis using a monoclonal antibody specific for hsp70 indicated that the 75-kDa protein represented hscp70, the cognate or constitutively produced member of the hsp70 family. Although the strongly heat-inducible hsp70 could not be detected in T cells incubated at 41 degrees C by immunoblot analysis, two-dimensional SDS-PAGE analysis did detect a modest induction of hsp70. Thus, hscp70 and not hsp70 was the major intracellular hsp70 member in T cells incubated at febrile temperatures. Enhanced hsp synthesis reflected augmented transcription of hsp genes which was contingent on the continued presence of hyperthermic stress. In order to determine whether induction of hsp synthesis conferred a state of increased resistance to thermal stress, splenic T cells were incubated at either 37 degrees or 41 degrees C (induction temperatures) and then subjected to a heat-shock challenge temperature. These studies revealed that following heat-shock challenge, mitogen-stimulated T cells preincubated at 41 degrees C synthesized DNA at an enhanced rate relative to controls (induction temperature, 37 degrees C). Thus, febrile temperatures were capable of inducing a state of acquired thermotolerance in T cells. However, the thermotolerant state did not protect T cell proliferation against other unrelated stressors such as cadmium and dexamethasone. Reconstitution experiments with accessory cells and interleukin-2-containing supernatants failed to reveal enhanced resistance in thermotolerant T cells to cadmium toxicity or the immunosuppressive activities of dexamethasone. The possibility that higher intracellular concentrations of hsps are required to demonstrate protection against these stressors was tested by the concurrent exposure of T cells to a febrile temperature (41 degrees C) and ethanol. This resulted in a synergistic increase in hsp90 and hsp70 synthesis; however, there was no evidence of enhanced resistance to cadmium- or dexamethasone-induced stress in T cells given this induction protocol. Similarly, alloreactive cytotoxic T lymphocyte responses were inhibited to the same extent in both control and thermotolerant T cells.(ABSTRACT TRUNCATED AT 400 WORDS)

T helper cells in cytotoxic T lymphocyte development: role of L3T4(+)-dependent and -independent T helper cell pathways in virus-specific and alloreactive cytotoxic T lymphocyte responses

I have compared the requirements for T helper (Th) cell function during the generation of virus-specific and alloreactive cytotoxic thymus (T)-derived lymphocyte (CTL) responses. Restimulation of vesicular stomatitis virus (VSV)-immune T cells (VSV memory CTLs) with VSV-infected stimulators resulted in the generation of class I-restricted, VSV-specific CTLs. Progression of VSV memory CTLs (Lyt-1-2+) into VSV-specific CTLs required inductive signals derived from VSV-induced, Lyt-1+2- Th cells because: (i) cultures depleted by negative selection of Lyt-1+ T cells failed to generate CTLs; (ii) titration of VSV memory CTLs into a limiting dilution (LD) microculture system depleted of Th cells generated curves which were not consistent with a single limiting cell type; (iii) LD analysis of VSV memory CTLs did produce single-hit curves in the presence of Lyt-1+2- T cells sensitized against VSV; and (iv) monoclonal anti-L3T4 antibody completely abrogated CTL generation against VSV. Similar results were also obtained with Sendai virus (SV), a member of the paramyxovirus family. The notion that a class II-restricted, L3T4+ Th cell plays an obligatory role in the generation of CTLs against these viruses is also supported by the observation that purified T cell lymphoblasts (class II antigen negative) failed to function as antigen-presenting cells for CTL responses against VSV and SV. T cell lymphoblasts were efficiently lysed by class I-restricted, anti-VSV and -SV CTLs, indicating that activated T cells expressed the appropriate viral peptides for CTL recognition. Furthermore, heterogeneity in the VSV-induced Th cell population was detected by LD analysis, suggesting that at least two types of Th cells were required for the generation of an anti-VSV CTL response. VSV-induced Th cell function could not simply be replaced by exogenous IL-2 because this lymphokine induced cytotoxic cells that had the characteristics of lymphokine-activated killer (LAK) cells and not anti-viral CTLs. In contrast, CTL responses against allogeneic determinants could not be completely blocked with antibodies against L3T4 and depletion of L3T4+ cells did not prevent the generation of alloreactive CTLs in cultures stimulated with allogeneic spleen cells or activated T cell lymphoblasts. Thus, these studies demonstrate an obligatory requirement for an L3T4-dependent Th cell pathway for CTL responses against viruses such as VSV and SV; whereas, CTL responses against allogeneic determinants can utilize an L3T4-independent pathway.

Activated B cells can deliver help for the in vitro generation of antiviral cytotoxic T cells

The experiments described in this paper show that activated B cells can deliver help for antiviral cytotoxic T (Tc) cell responses in vitro. This conclusion is based on four observations. (i) Influenza viruses induced secondary Tc cell responses in vitro in the absence of CD4+ T cells. This capacity correlated with the B-cell mitogenicity of these viruses. (ii) Depletion of both CD4+ T cells and B cells prevented the generation of anti-influenza Tc cell responses, whereas depletion of either CD4+ T cells or B cells alone failed to do so. In addition, supplementation of unprimed B cells restored the Tc cell responsiveness of primed splenocytes that had been depleted of both CD4+ T cells and B cells. (iii) Contact between T and B cells was not obligatory for the delivery of B-cell helper signal, and hence help was mediated by a soluble factor(s). (iv) Lipopolysaccharide-activated B cells could replace the CD4+ T-cell requirement in the induction of Tc cell responses to nonmitogenic influenza virus in vitro.