The proteoglycan (heparan sulfate proteoglycan) binding domain of APRIL serves as a platform for ligand multimerization and cross-linking.

A proliferation-inducing ligand (APRIL) (also known as TALL-2 and TRDL-1) is a member of the tumor necrosis factor (TNF) superfamily that has tumorigenic properties but is also important for the induction of humoral immune responses. APRIL binds two TNF receptors: transmembrane activator and calcium modulator and cyclophilin ligand interactor (TACI) and B-cell maturation antigen (BCMA) as well as heparan sulfate proteoglycans (HSPGs). The aim of this study was to clarify the role of the HSPG interaction in canonical APRIL signaling, because it has been proposed to act as a docking site and also to play a role in direct signaling. In this study, we generated point mutants of soluble APRIL that lack either the capacity to bind HSPGs or TACI and BCMA and then tested the function of these mutants in mouse B-cell assays. In contrast to previous reports, we found that APRIL alone is sufficient to costimulate B-cell proliferation and drive IgA production and does not require artificial antibody cross-linking. We found no evidence that APRIL requires signaling through HSPGs but, notably, were able to show that binding of APRIL to HSPGs is crucial for mediating natural APRIL cross-linking to allow for optimal activation of murine B cells.

Thymus-independent class switch recombination is affected by APRIL.

The tumour necrosis factor (TNF) family member a proliferation-inducing ligand (APRIL) is implicated in various B-cell processes, such as class switch recombination, plasma cell differentiation and plasma cell survival. This was suggested from initial studies analysing B-cell responses in APRIL-deficient and transgenic mice, and mice deficient for the TNF receptors of APRIL, transmembrane activator and CAML interactor (TACI) and B-cell maturation antigen. Here, we present additional evidence for the importance of APRIL in thymus-independent (TI) B-cell responses, using APRIL-deficient and transgenic mice. APRIL-deficient mice show an impaired immunoglobulin A (IgA) response towards TI B-cell antigens, whereas APRIL transgenic mice show exaggerated TI B-cell responses. Moreover, antibody titres to TI antigens were sustained in APRIL transgenic mice for a long time and even increased up to 75 days in the case of IgA against 4-hydroxy-nitrophenacetyl-lipopolysaccharide.

Specific TLR ligands regulate APRIL secretion by dendritic cells in a PKR-dependent manner.

A proliferation inducing ligand (APRIL) and B cell activating factor belonging to the TNF family (BAFF/BLyS) have been implicated in IgA class switch recombination in thymus-independent (TI) B cell responses. Dendritic cells (DC) are thought to regulate Ig class switching in TI B cell responses by providing B cells with cytokines, including APRIL and BAFF. We therefore set out to analyze the regulation of APRIL and BAFF expression by human monocyte-derived DC (moDC). We observed that moDC produce and secrete APRIL, but could not detect expression of BAFF. Importantly, stimulation with the Toll-like receptor ligands CpG and poly I:C specifically induced APRIL production, while other Toll-like receptor ligands were ineffective. The increase in APRIL was dependent on translation, but surprisingly not transcription. Instead, enhanced APRIL production and secretion resulted from activation of protein kinase receptor (PKR), as it was completely inhibited by the specific inhibitor of PKR, 2-aminopurine. This suggests that the specific induction of APRIL by CpG and poly I:C, and the signal integration by PKR, are regulated by translational modification and hint at a role for APRIL in the TI B cell response to viral infections.

Serpins prevent granzyme-induced death in a species-specific manner.

Expression of serine protease inhibitors (serpins) is one of the mechanisms used by tumour cells to escape immune surveillance. Previously, we have shown that expression of serpins SPI-6 and SPI-CI, respectively, renders tumour cells resistant to granzyme B (GrB)-mediated death and granzyme M (GrM)-mediated death. To obtain better insight into the interaction between serpins and their target proteases, we investigated the roles of protease inhibitor (PI)-9 and SPI-6 in the resistance to GrB-mediated and CD95-mediated death in further detail. Neither human PI-9 nor its murine orthologue SPI-6 was capable of preventing CD95-induced apoptosis in murine or human cells, indicating that these serpins do not inhibit the activation of apical caspases in this pathway. High expression of PI-9 or SPI-6 did prevent apoptosis induced by human GrB. Strikingly, only SPI-6, and not PI-9, was capable of inhibiting murine GrB, suggesting that a difference in enzymatic specificity exists between the mouse and the human granzymes. In agreement with this suggestion, murine GrB was clearly less effective in inducing apoptosis in human cells. Similar species specificity was also observed for SPI-CI and GrM when either their capacity to associate or the effectiveness of GrM-induced cytotoxicity was analysed. Our findings therefore indicate a species diversity that has a clear effect on mixed in vitro effector target settings.

In vivo triggering through 4-1BB enables Th-independent priming of CTL in the presence of an intact CD28 costimulatory pathway.

Triggering of 4-1BB, a member of the TNFR family, through in vivo administration of agonistic anti-4-1BB Ab delivers a powerful costimulatory signal to CTL. We found this signal to effectively replace the need for CD4(+) T cell help in the cross-priming of tumor-specific CTL immunity. Furthermore, 4-1BB Ab can convert an otherwise tolerogenic peptide vaccine into a formulation capable of efficient CTL priming. Initial activation of naive CTL can occur in the absence of 4-1BB costimulation, but this signal permits increased survival of Ag-stimulated CTL. Because naive CTL do not express 4-1BB at their surface, susceptibility to 4-1BB triggering depends on prior up-regulation of this receptor. We show that this requires both stimulation of the TCR and CD28-dependent costimulation. Accordingly, blockade of the CD28-costimulatory pathway abrogates the capacity of agonistic anti-4-1BB Ab to trigger Th-independent CTL immunity. In conclusion, our data reveal that the 4-1BB-mediated survival signal is positioned downstream of Ag-specific TCR triggering and CD28-dependent costimulation of naive CTL. The powerful effects of 4-1BB triggering on the induction, amplification, and persistence of CTL responses provide a novel strategy for increasing the potency of vaccines against cancers.