[Targeting--a new way to identify unknown tumor markers in blood vessels]. / Målsökning--nytt sätt att identifiera hittills okända tumörmarkörer i blodkärl.

The expression of specific molecules on the surface of vascular endothelial cells in tumours might be a key to anticancer therapy with angiostatic drugs. A new method to find these molecules on tumour vessels, targeting, is presented here. Some of these tumour-specific molecules have been identified by means of so called phage libraries. They are gene-manipulated phages, where the surface is decorated with randomly generated short peptides. After intravenous injection a few of the peptides, expressed on the surface of the phage, attach to complementary structures on the endothelial cell, as a ligand attaches to its receptor. Through biopsies and immunohistochemistry the phage can be isolated and identified. The part of the DNA of the phage that codes for the peptide-sequence of importance is sequenced. This seeking for such vessel-addresses can in the future be used for diagnostic purposes and also for local tumour-treatment. It is envisioned that cytotoxic drugs can be coupled to peptides on nanoparticles and act locally, in order to minimize toxic systemic side effects.

Angiostatic peptides use plasma fibronectin to home to angiogenic vasculature.

A group of angiogenesis inhibitors are derived from fragments of extracellular matrix or blood proteins. Endostatin, antithrombin, and anastellin are members of this group of substances. The plasma adhesion proteins fibronectin and vitronectin serve as cofactors for these three antiangiogenic proteins. Anginex is a synthetic 33-amino acid peptide that was originally modeled to reproduce the beta-sheet structure of antiangiogenic proteins. Here, we show that anginex initiates fibronectin polymerization and is inactive in mice that lack plasma fibronectin. Anginex shares these characteristics with anastellin. Fluorescein-labeled anginex and anastellin specifically localized in angiogenic vessels in vivo. This localization was dependent on plasma fibronectin and inhibited by an Arg-Gly-Asp peptide. Thus, anginex shares with several physiological angiogenesis inhibitors a dependence on plasma adhesion proteins. The role of the adhesion protein interaction apparently is to form integrin-binding complexes that deliver the antiangiogenic proteins to sites of angiogenesis. This functional convergence of several antiangiogenic factors has important implications for antiangiogenic therapies.

Antitumor activity of a homing peptide that targets tumor lymphatics and tumor cells.

LyP-1 is a peptide selected from a phage-displayed peptide library that specifically binds to tumor and endothelial cells of tumor lymphatics in certain tumors. Fluorescein-conjugated LyP-1 and a related peptide, LyP-1b, strongly accumulated in primary MDA-MB-435 breast cancer xenografts and their metastases from i.v. peptide injections, allowing visualization of orthotopic tumors in intact mice. The LyP peptide accumulation coincided with hypoxic areas in tumors. LyP-1 induced cell death in cultured human breast carcinoma cells that bind and internalize the peptide. Melanoma cells that do not bind LyP-1 were unaffected. Systemic LyP-1 peptide treatment of mice with xenografted tumors induced with the breast cancer cells inhibited tumor growth. The treated tumors contained foci of apoptotic cells and were essentially devoid of lymphatics. These results reveal an unexpected antitumor effect by the LyP-1 peptide that seems to be dependent on a proapoptotic/cytotoxic activity of the peptide. As LyP-1 affects the poorly vascularized tumor compartment, it may complement treatments directed at tumor blood vessels.

Nucleolin expressed at the cell surface is a marker of endothelial cells in angiogenic blood vessels.

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.

Anastellin, an FN3 fragment with fibronectin polymerization activity, resembles amyloid fibril precursors.

Anastellin is a carboxy-terminal fragment of the first FN3 domain from human fibronectin. It is capable of polymerizing fibronectin in vitro, and it displays anti-tumor, anti-metastatic and anti-angiogenic properties in vivo. We have determined the structure of anastellin using nuclear magnetic resonance spectroscopy and identified residues critical for its activity. Anastellin exhibits dynamic fluctuations and conformational exchange in solution. Its overall topology is very similar to the corresponding region of full-length FN3 domains. However, its hydrophobic core becomes solvent-accessible and some of its beta-strands lose their protection against hydrogen bonding to beta-strands from other molecules. These features seem to be relevant for the fibronectin polymerization activity of anastellin and resemble the characteristics of amyloid fibril precursors. We suggest that this analogy is not random and may reflect similarities between fibronectin and amyloid fibril formation.

Nanocrystal targeting in vivo.

Inorganic nanostructures that interface with biological systems have recently attracted widespread interest in biology and medicine. Nanoparticles are thought to have potential as novel intravascular probes for both diagnostic (e.g., imaging) and therapeutic purposes (e.g., drug delivery). Critical issues for successful nanoparticle delivery include the ability to target specific tissues and cell types and escape from the biological particulate filter known as the reticuloendothelial system. We set out to explore the feasibility of in vivo targeting by using semiconductor quantum dots (qdots). Qdots are small (<10 nm) inorganic nanocrystals that possess unique luminescent properties; their fluorescence emission is stable and tuned by varying the particle size or composition. We show that ZnS-capped CdSe qdots coated with a lung-targeting peptide accumulate in the lungs of mice after i.v. injection, whereas two other peptides specifically direct qdots to blood vessels or lymphatic vessels in tumors. We also show that adding polyethylene glycol to the qdot coating prevents nonselective accumulation of qdots in reticuloendothelial tissues. These results encourage the construction of more complex nanostructures with capabilities such as disease sensing and drug delivery.