The role of multicellular aggregation in the survival of ErbB2-positive breast cancer cells during extracellular matrix detachment.

The metastasis of cancer cells from the site of the primary tumor to distant sites in the body represents the most deadly manifestation of cancer. In order for metastasis to occur, cancer cells need to evade anoikis, which is defined as apoptosis caused by loss of attachment to extracellular matrix (ECM). Signaling from ErbB2 has previously been linked to the evasion of anoikis in breast cancer cells but the precise molecular mechanisms by which ErbB2 blocks anoikis have yet to be unveiled. In this study, we have identified a novel mechanism by which anoikis is inhibited in ErbB2-expressing cells: multicellular aggregation during ECM-detachment. Our data demonstrate that disruption of aggregation in ErbB2-positive cells is sufficient to induce anoikis and that this anoikis inhibition is a result of aggregation-induced stabilization of EGFR and consequent ERK/MAPK survival signaling. Furthermore, these data suggest that ECM-detached ErbB2-expressing cells may be uniquely susceptible to targeted therapy against EGFR and that this sensitivity could be exploited for specific elimination of ECM-detached cancer cells.

The regulation of cancer cell death and metabolism by extracellular matrix attachment.

The metastasis of cancer cells to distant sites is responsible for the vast majority of cancer mortalities yet the molecular mechanisms underlying this extraordinarily complicated process have yet to be sufficiently elucidated. Recently, it has become clear that cancer cells need to inhibit anoikis, a cell death program induced by loss of attachment to the extracellular matrix (ECM), in order to successfully metastasize. These studies have motivated additional research into the relationship between ECM-detachment and cell viability, much of which reveals integral connections between ECM-detachment and cell metabolism. This review serves to thoroughly discuss the signaling pathways and metabolic changes that are induced by ECM-detachment. In addition, the molecular mechanisms by which cancer cells can alter signaling and metabolism to survive in the absence of ECM-attachment will be highlighted. Furthermore, cell death mechanisms that have been observed or implicated in cells detached from the ECM will also be examined. In aggregate, the studies discussed in this review reveal that ECM-detachment can regulate cancer cell metabolism in a variety of distinct cell types and suggest that interfering with metabolism in ECM-detached cells may be a novel and effective chemotherapeutic approach to selectively inhibit tumor progression.

MEKK3-MEK5-ERK5 signaling promotes mitochondrial degradation.

Mitochondria are vital organelles that coordinate cellular energy homeostasis and have important roles in cell death. Therefore, the removal of damaged or excessive mitochondria is critical for maintaining proper cellular function. The PINK1-Parkin pathway removes acutely damaged mitochondria through a well-characterized mitophagy pathway, but basal mitochondrial turnover occurs via distinct and less well-understood mechanisms. Here we report that the MEKK3-MEK5-ERK5 kinase cascade is required for mitochondrial degradation in the absence of exogenous damage. We demonstrate that genetic or pharmacological inhibition of the MEKK3-MEK5-ERK5 pathway increases mitochondrial content by reducing lysosome-mediated degradation of mitochondria under basal conditions. We show that the MEKK3-MEK5-ERK5 pathway plays a selective role in basal mitochondrial degradation but is not required for non-selective bulk autophagy, damage-induced mitophagy, or restraint of mitochondrial biogenesis. This illuminates the MEKK3-MEK5-ERK5 pathway as a positive regulator of mitochondrial degradation that acts independently of exogenous mitochondrial stressors.