A tumor-homing peptide, F3, selectively binds to endothelial cells in tumor blood vessels and to tumor cells. Here, we show that the cell surface molecule recognized by F3 is nucleolin. Nucleolin specifically bound to an F3 peptide affinity matrix from extracts of cultured breast carcinoma cells. Antibodies and cell surface biotin labeling revealed nucleolin at the surface of actively growing cells, and these cells bound and internalized fluorescein-conjugated F3 peptide, transporting it into the nucleus. In contrast, nucleolin was exclusively nuclear in serum-starved cells, and F3 did not bind to these cells. The binding and subsequent internalization of F3 were blocked by an antinucleolin antibody. Like the F3 peptide, intravenously injected antinucleolin antibodies selectively accumulated in tumor vessels and in angiogenic vessels of implanted “matrigel” plugs. These results show that cell surface nucleolin is a specific marker of angiogenic endothelial cells within the vasculature. It may be a useful target molecule for diagnostic tests and drug delivery applications.
Nanoparticle-based diagnostics and therapeutics hold great promise because multiple functions can be built into the particles. One such function is an ability to home to specific sites in the body. We describe here biomimetic particles that not only home to tumors, but also amplify their own homing. The system is based on a peptide that recognizes clotted plasma proteins and selectively homes to tumors, where it binds to vessel walls and tumor stroma. Iron oxide nanoparticles and liposomes coated with this tumorhoming peptide accumulate in tumor vessels, where they induce additional local clotting, thereby producing new binding sites for more particles. The system mimics platelets, which also circulate freely but accumulate at a diseased site and amplify their own accumulation at that site. The self-amplifying homing is a novel function for nanoparticles. The clotting-based amplification greatly enhances tumor imaging, and the addition of a drug carrier function to the particles is envisioned.clotting ͉ liver ͉ peptide ͉ tumor targeting ͉ iron oxide
Expression of adhesion receptor integrin ␣v3 in an activated functional form strongly promotes metastasis in human breast cancer cells. Here, we report that ␣v3 cooperates with matrix metalloproteinase type 9 (MMP-9) in breast cancer cell migration. This cooperation is regulated by the activation state of the integrin. Expression of activated ␣v3 in metastatic variants of MDA-MB 435 human breast cancer cells and primary metastatic cells from breast cancer patients strongly enhanced migration toward vitronectin and fibrinogen. This enhancement was mediated by a soluble factor produced by breast cancer cells expressing activated ␣v3. When transferred, this factor also up-regulated ␣v3-dependent migration of breast cancer cells that express the nonactivated integrin. The factor was identified as metalloproteinase MMP-9. Whereas all tested breast cancer cell variants produced latent MMP-9, only those with activated ␣v3 produced the mature form of this metalloproteinase. Recombinant mature MMP-9, but not latent MMP-9 or either form of MMP-2, enhanced ␣v3-dependent breast cancer cell migration. The migratory response was inhibited by tissue inhibitors of metalloproteinase or when MMP-9 was depleted from the inducing supernatants. The results indicate a causal relationship between the expression of activated integrin ␣v3 and production of enzymatically active MMP-9 in metastatic breast cancer cells. These molecules cooperate to enhance breast cancer cell migration toward specific matrix proteins, and this may contribute to the strongly enhanced metastatic capacity of breast cancer cells that express activated ␣v3.M etastasis is the primary cause of death in breast cancer patients. Metastatic dissemination depends on tumor cell adhesion, migration, and invasion. These steps involve integrins, a family of transmembrane adhesion receptors, composed of noncovalently linked ␣ and  subunits (1). Integrins are known to exist in distinct states of activation, and these determine integrin functionality and affinity for ligands (2). For example, integrin activation controls which ligands are recognized, whether an integrin can support cell arrest under dynamic flow conditions or only stationary adhesion, and whether cells can migrate on or toward specific substrates (3). The importance of integrin activation has long been appreciated in leukocytes and platelets, where it controls inflammatory responses and thrombus formation (4, 5). Recent findings indicate that other cell types, such as endothelial cells and tumor cells, can also regulate their interaction with extracellular matrix proteins by integrin activation (6-9). This regulation may help to control angiogenesis and tumor metastasis.In breast and ovarian cancer, as well as in melanoma and glioma, malignant progression is associated with expression of tumor cell integrin ␣v3 (10-14). We recently found that ␣v3 can exist in human breast cancer cells in an activated or a nonactivated functional state. Only the activated state supports breast cancer cell arrest du...
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