The role of the podoplanin-CLEC-2 pathway in stromal cell regulation of dendritic cell motility and lymph node architecture

Abstract

In addition to leukocytes, secondary lymphoid organs are populated by non-hematopoietic stromal cells. This diverse group of cells supports lymphocyte migration and homing, facilitates antigen delivery, and promotes T cell survival. However, there is relatively little known about the specific molecules governing the roles that these cells play in regulating dendritic cell (DC) motility and lymph node architecture. Here, we examine the interaction between two molecules, CLEC-2 and podoplanin (PDPN), that are critical for DC migration and maintaining structural integrity of lymph nodes. Together, these studies identify novel functions of lymph node stromal cells and a unique function for PDPN in the immune system. In response detecting an potentially harmful antigen, DCs in peripheral tissues mature and travel to downstream lymph nodes by following chemokine gradients secreted by lymphatic endothelial cells (LECs) and fibroblastic reticular cells (FRCs) present in the lymph node paracortex. We discovered that, in addition to chemokines, DC migration requires CLEC-2 on DCs, as engagement of CLEC-2 with PDPN, which is expressed by LECs and FRCs, incites DC motility and is required for DC entry into the lymphatics, efficient arrival in the lymph node, and migration along the FRC network within the lymph node. Next, we examined the effect of this interaction with respect to the stromal cell. Through a combination approaches, we discovered that PDPN is a master regulator of contractility in FRCs. The fact that FRCs are contractile cells was previously reported, but our study is the first to identify a function for this contractility: upon blockade of PDPN-mediated contractility, lymph nodes became enlarged, the FRC network became more sparse, and there were increased numbers of lymphocytes in the lymph node. Importantly, during an immune response, these changes resulted in more proliferation of antigen-specific T cells and impaired contraction of the lymph node upon resolution of inflammation. Finally, we found that CLEC-2 binding PDPN recapitulated the effect of PDPN deletion. Thus, during an immune response, CLEC-2+ DCs would use PDPN to efficiently migrate to the lymph node and simultaneously cause FRCs to relax and prepare the lymph node for expansion.