TLR9 ligand induces the generation of CD20+ plasmablasts and plasma cells from CD27+ memory B-cells.

Plasma cells (PCs) have a heterogeneous phenotype in humans. While bone marrow PCs are CD20-CD138+, tonsil PCs are CD20+CD138+/- and peripheral plasmablasts (PBs) are CD20-CD138-. In vitro, PCs are mainly generated by the activation of CD27+ memory B-cells through transient stimulation of CD40, and their phenotype appears similar to that of bone marrow PCs. While CD20 expression is lost at the plasmablastic stage, CD138 expression appears only at the PC stage. Thus, the CD20+CD138± phenotype of tonsil PCs does not represent an intermediate stage in the differentiation of memory B-cells into PCs. Because it has been previously shown that TLR9 activation was more able than CD40 stimulation to induce the differentiation of IgM+ CD27+ B-cells, we wondered whether TLR9 or CD40 stimulation would induce the same phenotype of PCs. Thus, we compared the differentiation of CD27+ B-cells isolated from either the tonsils or peripheral blood and stimulated with either CD40L-expressing fibroblasts or a TLR9 ligand, CpG oligodeoxynucleotide (CpG ODN). We observed that CpG ODN mainly induced CD27+ B-cell differentiation into CD20+CD38+CD138- PBs and CD20+CD38+CD138± PCs, which appear similar to tonsil PCs. Removal of CpG ODN during differentiation induced a decrease in the CD20+ plasmablastic population, and, conversely, stimulation of CD40L-induced pre-plasmablasts with CpG ODN increased the population of CD20+CD38+ PBs. Analysis of Ig secretion showed that CpG ODN induced increased IgM secretion compared to CD40L. PCs from patients with multiple myeloma, the malignant counterpart of bone marrow PCs, rarely express CD20. We show that CpG ODN did not induce or increase CD20 in nine IgG or IgA myeloma cell lines. These data strongly suggest that CpG ODN mainly targets CD27+ IgM+ B-cells.

Osteoclasts support the survival of human plasma cells in vitro.

The aim of this in vitro study was to evaluate if osteoclasts (OCs) and dendritic cells (DCs), both of monocyte origin, can support the survival of normal human plasma cells (PCs). PCs differentiate from plasmablasts (PBs) arising from activated B cells, essentially memory B cells. To study the survival of both PBs (CD20(low)CD38(high)CD138(neg)) and PCs (CD20(neg)CD38(bright)CD138(bright)), we generated pre-PBs (CD20(low)CD38(pos)CD138(neg)) from CD40-activated B cells (CD20(high)CD38(neg)CD138(neg)) and cultured them on DCs or OCs in the presence of added IL-6. By quantitative and qualitative study, we showed that DCs support the survival of PBs and early PCs, but not that of PCs. In contrast, OCs support the survival of PBs, early PCs and PCs. PCs surviving on OCs 12 days after pre-PB input display phenotypic features of bone marrow PCs, CD138(bright)CD38(bright)HLA-DR(low)CD45(dim). The ability for OCs to support the survival of PCs was fully dependent on cell-cell contact and not inhibited by BCMA-Fc suggesting that secreted BAFF and APRIL were not involved.

Mcl-1L cleavage is involved in TRAIL-R1- and TRAIL-R2-mediated apoptosis induced by HGS-ETR1 and HGS-ETR2 human mAbs in myeloma cells.

We evaluated the ability of 2 human mAbs directed against TRAILR1 (HGS-ETR1) and TRAILR2 (HGS-ETR2) to kill human myeloma cells. HGS-ETR1 and HGS-ETR2 mAbs killed 15 and 9 human myeloma cell lines (HMCLs; n = 22), respectively. IL-6, the major survival and growth factor for these HMCLs, did not prevent their killing. Killing induced by either HGS-ETR1 or HGS-ETR2 was correlated with the cleavage of Mcl-1L, a major molecule for myeloma survival. Mcl-1L cleavage and anti-TRAILR HMCL killing were dependent on caspase activation. Kinetic studies showed that Mcl-1L cleavage occurred very early (less than 1 hour) and became drastic once caspase 3 was activated. Our data showed that both the extrinsic (caspase 8, Bid) and the intrinsic (caspase 9) pathways are activated by anti-TRAIL mAb. Finally, we showed that the HGS-ETR1 and, to a lesser extent, the HGS-ETR2 mAbs were able to induce the killing of primary myeloma cells. Of note, HGS-ETR1 mAb was able to induce the death of medullary and extramedullary myeloma cells collected from patients at relapse. Taken together, our data clearly encourage clinical trials of anti-TRAILR1 mAb in multiple myeloma, especially for patients whose disease is in relapse, at the time of drug resistance.

Allogeneic T lymphocytes as a source of peptide-dependent T cells specific for myeloma cells.

We investigated the generation of myeloma-specific CTLs from normal donors HLA mismatched with the myeloma cell line SBN. The T-cell line obtained was cloned and each CTL was assessed against SBN and SBN-EBV (a B-EBV cell line obtained by EBV infection of B cells from SBN patient) simultaneously. Among >270 clones evaluated, 2 CTLs (Vbeta13.1 and Vbeta17) killed SBN but spared SBN-EBV cells. Antibodies against HLA-I, but not HLA-A2, molecules abrogated their recognition of SBN. Moreover, SBN recognition was abrogated by anti-HLA-Cw6 antiserum. Both clones recognized two other HLA-Cw*0602 myeloma cell lines. Neither of them recognized HLA-Cw*0602 B-EBV cell lines, the PBMCs of HLA-Cw*0602-unrelated donors or HLA-Cw*0602 melanoma cell lines. We showed that HLA-Cw6 molecules were more expressed at the cell surface of B-EBV cells as compared with myeloma cells, suggesting that the lack of reactivity against B-EBV cells was not related to a low level of HLA expression. Since CTL clones did not express any KIR or NKG2D, we excluded the fact that NK cell receptors could be involved in myeloma-specific recognition through KIR-HLA-I or NKG2D-MICA,B interactions. Cold target competition and acid elution experiments confirmed that myeloma cell recognition was peptide dependent.