Diffuse Large B-Cell Lymphoma Remodels the Fibroblastic Reticular Network That Acquires Aberrant Immunosuppressive Capabilities; Implications for the Regulation of Anti-Tumor Immunity in the Immuno-Oncology Era

Immunotherapy has demonstrated potential to reactivate or transfer T cell immunity and regress tumors, offering hope to relapsed or refractory diffuse large B-cell lymphoma (DLBCL) patients. However, many DLBCL patients do not experience therapeutic benefit, likely owing to a lack of pre-existing anti-tumor immunity and/or poorly understood immunosuppressive mechanisms in the tumor microenvironment (TME). Understanding the different obstacles that cytotoxic T cells face in the DLBCL TME will help the development of novel therapeutic approaches to overcome them and optimize immunotherapy. Stroma-associated gene signatures reflecting fibroblast and immune cell activity as well as angiogenesis have been associated with outcome in DLBCL but the biology underlying these signatures has been understudied. Here we have examined beyond tumor 9effacement9 and hypothesized that, rather than being sparse bystanders, lymph node stromal cells may be important players in driving immune suppression in lymphoma. Multiplex immunofluorescence (IF) confocal microscopy analysis of the major stromal cell subsets revealed a marked expansion and remodeling of podoplanin, PDPN+ fibroblastic reticular cells (FRCs) in DLBCL lymph node tissue TME biopsies across GCB and ABC subtypes (n=40) compared to reactive control tissues (n=10). FRC myofibroblasts were similarly remodeled in tumors from the transgenic mouse model of DLBCL (Iμ-HABCL6, n=10) compared to wild type littermates (n=5). These altered PDPNhigh, αSMAhigh FRC networks were interspersed within effaced lymph node tissues in close proximity to DLBCL tumor cells. To model the interactions between tumor cells and FRCs, we established 2D and 3D co-culture platforms that combined DLBCL cells (or non-malignant control B-cells) and PDPN+ FRCs derived from human or murine lymph node tissues. These quantitative assays have shown that tumor cells activate FRCs promoting their proliferation, increased expression of PDPN, marked elongation/stretching and subsequent reduced ability to contract 3D collagen matrix (non-contractile) (P An important function of FRCs in regulating immunity is attracting and maintaining T cells by secreting chemokines and promoting their migration along the network. Functional assays revealed that T cells show significantly reduced chemotaxis as well motility (quantitative time-lapse movies) across 2D and 3D lymphoma FRC networks compared to control FRCs (P In conclusion our data indicate that DLBCL tumor cells convert FRCs into immunosuppressive CAFs, which exhibit altered immumomodulatory activities at different levels that we believe has important implications for the regulation of anti-tumor immunity as well as response to immunotherapy. Disclosures Vardi:Gilead: Research Funding; Janssen: Honoraria. Ramsay:Roche Glycart AG: Research Funding; MedImmune: Research Funding; Celgene Corporation: Research Funding.