Mg(++)-induced endothelial cell migration: substratum selectivity and receptor-involvement.

The activation of endothelial cells during angiogenesis requires cell spreading and migration. These processes are influenced by extracellular signals such as chemoattractants from the local microenvironment. We have shown previously that transmembrane Ca++ influx is necessary for motility and cell spreading, thus we hypothesized that the extracellular divalent cations Mg++ and Ca++ may regulate human umbilical vein endothelial cell (HUVEC) spreading and act as chemoattractants. Studies demonstrated that extracellular Mg++ induced a statistically better spread phenotype when cells were plated on multiple extracellular matrix substrata; Ca++ promoted cell spreading only on vitronectin. Mg++ but not Ca++ acted as a potent chemoattractant when HUVEC migrated on gelatin- and type IV collagen- but not on vitronectin-coated filters. A checkerboard analysis of migration showed that Mg++ induces both chemokinetic and chemotactic migration peaking at 0.1 and 10 mM, respectively. An equivalent effect of oligomycin was seen on motility to Mg++ or to vascular endothelial growth factor (VEGF) in extracellular Mg(++)-free conditions, ruling out an exclusive role for Mg++ as a migration energy producer. The Mg(++)-stimulated chemotaxis was inhibited > 60% by pertussis toxin, d-erythrosphingosine, and tyrphostin B48, but unaffected by cholera toxin exposure. These data suggest that Mg(++)-induced chemotaxis may be promoted through a Gi protein-coupled receptor pathway with a requirement for protein kinase C activity and protein tyrosine phosphorylation. Thus, Mg++ may be a newly recognized receptor-mediated chemoattractant for endothelial cells.

Adenosine receptor mediates motility in human melanoma cells.

Cell motility is an essential component of tumor progression and metastasis. A number of factors, both autocrine and paracrine, have been found to influence cell motility. In the present study, adenosine and adenine nucleotides directly stimulated chemotaxis of A2058 melanoma cells in the absence of exogenous factors. Three adenosine receptor agonists stimulated motility in the melanoma cells and two adenosine receptor antagonists strongly inhibited the chemotactic response to both adenosine and AMP. The chemotactic stimulation by adenosine and AMP was pertussis toxin sensitive. Otherwise unresponsive Chinese hamster ovary cells which were transfected with the adenosine A1 receptor cDNA acquired the direct, pertussis toxin sensitive, chemotactic response to adenosine, and this response was inhibited by adenosine receptor antagonists. These findings demonstrate that adenosine and adenine nucleotides are capable of stimulating chemotaxis of tumor cells mediated through an adenosine receptor, probably of the A1 subtype. The possibility of antimetastatic therapies based on inhibition of adenosine receptor activity is raised.

General mechanisms of metastasis.

In the present article, the steps involved in the process of tumor metastasis are discussed. Several events are required for malignant cells to leave the primary tumor and proliferate at a distant site: vessel formation (angiogenesis), cell attachment, invasion (matrix degradation, cell motility), and cell proliferation. Molecular mechanisms underlying each of these steps are described. Based on blocking these processes, new anti-metastasis therapies are being developed.

Stimulation of tumor cell motility linked to phosphodiesterase catalytic site of autotaxin.

A family of extracellular type I phosphodiesterases has recently been isolated by cDNA cloning, but a physiological function linked to the phosphodiesterase active site has remained unknown. We now present evidence that the phosphodiesterase catalytic site, 201YMRPVYPTKTFPN213, is essential for the motility stimulating activity of autotaxin (ATX), one member of the exophosphodiesterase family. Native ATX possesses phosphodiesterase activity at neutral and alkaline pH, binds ATP noncovalently, and undergoes threonine phosphorylation. Homogeneously purified recombinant ATX, based on the teratocarcinoma sequence, retains these same activities. A single amino acid in the phosphodiesterase catalytic site, Thr210, is found to be necessary for motility stimulation, phosphodiesterase activity, and phosphorylation. Two mutant recombinant proteins, Ala210- and Asp210-ATX, lack motility stimulation and lack both enzymatic activities; Ser210-ATX possesses intermediate activities. Another mutation, with the adjacent lysine (Lys209) changed to Leu209-ATX, possesses normal motility stimulation with sustained phosphodiesterase activity but exhibits no detectable phosphorylation. This mutation eliminates the phosphorylation reaction and indicates that the dephosphorylated state is an active motility-stimulating form of the ATX molecule. By demonstrating that the phosphodiesterase enzymatic site is linked to motility stimulation, these data reveal a novel role for this family of exo/ecto-enzymes and open up the possibility of extracellular enzymatic cascades as a regulatory mechanism for cellular motility.