Abstract 3162: Differential mechanisms utilized by pancreatic tumor cells and associated fibroblasts to remodel stroma during metastatic invasion

Abstract

Abstract Metastatic invasion of tumors into peripheral tissues is known to rely upon protease-mediated degradation of the surrounding stroma. This remodeling process is dependent upon complex, actin-based specializations of the plasma membrane termed “invadopodia” that act to both sequester and release matrix metalloproteases. Here we report that cells of mesenchymal origin, including fibroblasts, pancreatic stellate cells, and tumor-associated fibroblasts, degrade substantial amounts of surrounding matrix by a mechanism independent of conventional invadopodia. First, as tumor cell-derived invadopodia are dependent upon the action of the GTPase Dyn2, loss of Dyn2 function inhibits invadopodia-based matrix degradation by pancreatic tumor cells. In surprising contrast, we have found that loss of Dyn2 function in mesenchymal cells does not inhibit degradation, but actually leads to a marked increase. Second, these degradative sites lack the punctate shape of conventional invadopodia but are instead spread along the cell base and are reticular and/or fibrous in character. Third, inhibition of either Src or Cdc42 function, known to drive invadopodia formation, had no effect on the mesenchymal matrix degradation induced by loss of Dyn2. Taken together, these data indicate that this mechanism of degradation is independent of classical invadopodial degradation. To define the mechanistic processes that differ between tumor and stromal cell types, we screened for matrix metalloprotease activity using zymography. An unexpected and significant upregulation of MMP2 activity in mesenchymal-derived cells upon loss of Dyn2 was observed, whereas MMP2 was nearly completely absent in the tumor cells. Further, loss of Dyn2 resulted in an upregulation of surface-bound MT1-MMP, known to activate MMP2. In contrast, loss of Dyn2 in the pancreatic tumor cells reduced surface levels of MT1-MMP. Thus, in mesenchymal cells, loss of Dyn2 induces retention of MT1-MMP at the surface, leading to large scale matrix degradation through an MT1-MMP/MMP2-dependent mechanism. Excitingly, co-culture invasion experiments demonstrate that the matrix degradation induced in these stromal fibroblasts is sufficient to promote invasion by pancreatic tumor cells. These findings provide evidence for a novel matrix remodeling process conducted by mesenchymal cells that is substantially more effective than conventional invadopodia, distinct in structural organization, independent of the classical invadopodial machinery, and capable of promoting invasion by pancreatic tumor cells. Supported by NCI RO1 CA104125 to MAM. Citation Format: Hong Cao, Robbin Eppinga, Eugene Krueger, Jing Chen, Gina Razidlo, Mark A. McNiven. Differential mechanisms utilized by pancreatic tumor cells and associated fibroblasts to remodel stroma during metastatic invasion. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 3162. doi:10.1158/1538-7445.AM2014-3162