Surface expression of precursor N-cadherin promotes tumor cell invasion.

The expression of N-cadherin (NCAD) has been shown to correlate with increased tumor cell motility and metastasis. However, NCAD-mediated adhesion is a robust phenomenon and therefore seems to be inconsistent with the "release" from intercellular adhesion required for invasion. We show that in the most invasive melanoma and brain tumor cells, altered posttranslational processing results in abundant nonadhesive precursor N-cadherin (proNCAD) at the cell surface, although total NCAD levels remain constant. We demonstrate that aberrantly processed proNCAD promotes cell migration and invasion in vitro. Furthermore, in human tumor specimens, we find high levels of proNCAD as well, supporting an overall conclusion that proNCAD and mature NCAD coexist on these tumor cell surfaces and that it is the ratio between these functionally antagonistic moieties that directly correlates with invasion potential. Our work provides insight into what may be a widespread mechanism for invasion and metastasis and challenges the current dogma of the functional roles played by classic cadherins in tumor progression.

Non-random subcellular distribution of variant EKLF in erythroid cells.

EKLF protein plays a prominent role during erythroid development as a nuclear transcription factor. Not surprisingly, exogenous EKLF quickly localizes to the nucleus. However, using two different assays we have unexpectedly found that a substantial proportion of endogenous EKLF resides in the cytoplasm at steady state in all erythroid cells examined. While EKLF localization does not appear to change during either erythroid development or terminal differentiation, we find that the protein displays subtle yet distinct biochemical and functional differences depending on which subcellular compartment it is isolated from, with PEST sequences possibly playing a role in these differences. Localization is unaffected by inhibition of CRM1 activity and the two populations are not differentiated by stability. Heterokaryon assays demonstrate that EKLF is able to shuttle out of the nucleus although its nuclear re-entry is rapid. These studies suggest there is an unexplored role for EKLF in the cytoplasm that is separate from its well-characterized nuclear function.

The minimal essential unit for cadherin-mediated intercellular adhesion comprises extracellular domains 1 and 2.

N-cadherin comprises five homologous extracellular domains, a transmembrane, and a cytoplasmic domain. The extracellular domains of N-cadherin play important roles in homophilic cell adhesion, but the contribution of each domain to this phenomenon has not been fully evaluated. In particular, the following questions remain unanswered: what is the minimal domain combination that can generate cell adhesion, how is domain organization related to adhesive strength, and does the cytoplasmic domain serve to facilitate extracellular domain interaction? To address these issues, we made serial constructs of the extracellular domains of N-cadherin and produced various cell lines to examine adhesion properties. We show that the first domain of N-cadherin alone on the cell surface fails to generate adhesive activity and that the first two domains of N-cadherin form the "minimal essential unit" to mediate cell adhesion. Cell lines expressing longer extracellular domains or N-cadherin wild type cells formed larger cellular aggregates than those expressing shorter aggregates. However, adhesion strength, as measured by a shearing test, did not reveal any differences among these aggregative cell lines, suggesting that the first two domains of N-cadherin cells generate the same strength of adhesive activity as longer extracellular domain cells. Furthermore, truncations of the first two domains of N-cadherin are also sufficient to form cisdimerization at an adhesive junction. Our findings suggest that the extracellular domains of N-cadherin have distinct roles in cell adhesion, i.e. the first two domains are responsible for homophilic adhesion activity, and the other domains promote adhesion efficiency most likely by positioning essential domains relatively far out from the cell surface.