Potentiating the activity of rituximab against mantle cell lymphoma in mice by targeting interleukin-2 to the neovasculature.

There is increasing interest in the site-directed pharmacodelivery of therapeutic payloads to the tumor site using antibodies as transport vehicles. Here, we investigated the efficacy of L19-IL2, an antibody-cytokine fusion protein that specifically delivers IL-2 to the tumor site by homing to the extra-domain B of fibronectin (EDB-Fn) expressed on tumor-associated blood vessels, against mantle cell lymphoma (MCL) in mice. L19-IL2 was shown to selectively localize at lymphoma lesions in vivo and to mediate significant lymphoma growth retardation, which was potentiated by co-administration of the anti-CD20 antibody rituximab. When co-injected with rituximab, L19-IL2 induced complete remissions of localized MCL xenografts in 6/8 mice (75%), whereas the combination of rituximab and equivalent doses of non-targeted IL-2 only slightly delayed tumor growth. In disseminated MCL, combination therapy with L19-IL2 and rituximab exhibited a significant survival benefit over treatment with IL-2 and rituximab and completely eradicated the disease in 2/7 cases (28.6%). Mechanistically, histological analyses of post-therapeutic lymphoma tissues revealed a strong intratumoral accumulation of macrophages and natural killer cells after a single dose of the immunocytokine, whereas L19-IL2 had no significant impact on microvessel density or on tissue penetration of co-injected rituximab. Collectively, these results provide the scientific rationale for the clinical evaluation of L19-IL2 in combination with anti-CD20 immunotherapy in patients with MCL.

Non-invasive monitoring of tumor-vessel infarction by retargeted truncated tissue factor tTF-NGR using multi-modal imaging.

The fusion protein tTF-NGR consists of the extracellular domain of the thrombogenic human tissue factor (truncated tissue factor, tTF) and the peptide GNGRAHA (NGR), a ligand of the surface protein CD13 (aminopeptidase N), upregulated on endothelial cells of tumor vessels. tTF-NGR preferentially activates blood coagulation within tumor vasculature, resulting in tumor vessel infarction and subsequent tumor growth retardation/regression. The anti-vascular mechanism of the tTF-NGR therapy approach was verified by quantifying the reduced tumor blood-perfusion with contrast-enhanced ultrasound, the reduced relative tumor blood volume by ultrasmall superparamagnetic iron oxide-enhanced magnetic resonance imaging, and by in vivo-evaluation of hemorrhagic bleeding with fluorescent biomarkers (AngioSense(680)) in fluorescence reflectance imaging. The accumulation of tTF-NGR within the tumor was proven by visualizing the distribution of the iodine-123-labelled protein by single-photon emission computed tomography. Use of these multi-modal vascular and molecular imaging tools helped to assess the therapeutic effect even at real time and to detect non-responding tumors directly after the first tTF-NGR treatment. This emphasizes the importance of imaging within clinical studies with tTF-NGR. The imaging techniques as used here have applicability within a wider scope of therapeutic regimes interfering with tumor vasculature. Some even are useful to obtain predictive biosignals in personalized cancer treatment.

Anticancer therapy by tumor vessel infarction with polyethylene glycol conjugated retargeted tissue factor.

tTF-NGR consists of the extracellular domain of tissue factor and the peptide GNGRAHA, a ligand of the surface protein aminopeptidase N and of integrin αvß3. Both surface proteins are upregulated on endothelial cells of tumor vessels. tTF-NGR shows antitumor activity in xenografts and inhibition of tumor blood flow in cancer patients. We performed random TMS(PEG)12 PEGylation of tTF-NGR to improve the antitumor profile of the molecule. PEGylation resulted in an approximately 2-log step decreased procoagulatory activity of the molecule. Pharmacokinetic studies in mice showed a more than 1-log step higher mean area under the curve. Comparison of the LD10 values for both compounds and their lowest effective antitumor dose against human tumor xenografts showed an improved therapeutic range (active/toxic dose in mg/kg body weight) of 1/5 mg/kg for tTF-NGR and 3/>160 mg/kg for TMS(PEG)12 tTF-NGR. Results demonstrate that PEGylation can significantly improve the therapeutic range of tTF-NGR.