E-cadherin accumulation within the lymphovascular embolus of inflammatory breast cancer is due to altered trafficking.

E-Cadherin functions as a tumor suppressor in some invasive breast carcinomas and metastasis is promoted when its expression is lost. It has been observed, however, that in one of the most aggressive human breast cancers, inflammatory breast cancer (IBC), E-cadherin is overexpressed and this accounts for the formation of the lymphovascular embolus, a structure efficient at metastasis and resistant to chemotherapy through unknown cytoprotective mechanisms. Studies using a human xenograft model of IBC, MARY-X, indicate that the mechanism of E-cadherin overexpression is not transcriptional but related to altered protein trafficking. By real-time RT-PCR, E-cadherin transcript levels in MARY-X were 3- to 11-fold less than in other E-cadherin positive human breast carcinoma lines but the protein levels were 5- to 10-fold greater. In addition, several smaller E-cadherin protein fragments, e.g. 95 kDa, were present. To explain these observations, it was hypothesized that there may be altered protein trafficking. A real-time RT-PCR screen of candidate molecules generally known to regulate protein trafficking was conducted. The screen revealed 3.5- to 7-fold increased ExoC5 level and 10 to 20 fold decreased HRS and RAB7 levels, which was confirmed in human microdissected lymphovascular emboli. Since these alterations may only be correlative with E-cadherin overexpression, one of the molecules, Rab7, was selectively knocked down in MCF-7 cells. An increase in the full length 120 kDa E-cadherin and the de novo appearance of the 95 KD band were observed. These findings suggest that it is the altered E-cadherin trafficking that contributes to its oncogenic rather than suppressive role in IBC.