The cutting edge: membrane-anchored serine protease activities in the pericellular microenvironment.

The serine proteases of the trypsin-like (S1) family play critical roles in many key biological processes including digestion, blood coagulation, and immunity. Members of this family contain N- or C-terminal domains that serve to tether the serine protease catalytic domain directly to the plasma membrane. These membrane-anchored serine proteases are proving to be key components of the cell machinery for activation of precursor molecules in the pericellular microenvironment, playing vital functions in the maintenance of homoeostasis. Substrates activated by membrane-anchored serine proteases include peptide hormones, growth and differentiation factors, receptors, enzymes, adhesion molecules and viral coat proteins. In addition, new insights into our understanding of the physiological functions of these proteases and their involvement in human pathology have come from animal models and patient studies. The present review discusses emerging evidence for the diversity of this fascinating group of membrane serine proteases as potent modifiers of the pericellular microenvironment through proteolytic processing of diverse substrates. We also discuss the functional consequences of the activities of these proteases on mammalian physiology and disease.

Effective treatment of established human breast tumor xenografts in immunodeficient mice with a single dose of the alpha-emitting radioisotope astatine-211 conjugated to anti-HER2/neu diabodies.

PURPOSE: Successful radioimmunotherapy strategies depend on selecting radioisotopes with physical properties complementary to the biological properties of the targeting vehicle. Small, engineered antitumor antibody fragments are capable of rapid, highly specific tumor targeting in immunodeficient mouse models. We hypothesized that the C6.5 diabody, a noncovalent anti-HER2 single-chain Fv dimer, would be an ideal radioisotope carrier for the radioimmunotherapy of established tumors using the short-lived alpha-emitting radioisotope (211)At. EXPERIMENTAL DESIGN: Immunodeficient nude mice bearing established HER2/neu-positive MDA-MB-361/DYT2 tumors treated with N-succinimidyl N-(4-[(211)At]astatophenethyl)succinamate ((211)At-SAPS)-C6.5 diabody. Additional cohorts of mice were treated with (211)At-SAPS T84.66 diabody targeting the carcinoembryonic antigen or (211)At-SAPS on a diabody specific for the Müllerian inhibiting substance type II receptor, which is minimally expressed on this tumor cell line. RESULTS: A single i.v. injection of (211)At-SAPS C6.5 diabody led to a 30-day delay in tumor growth when a 20 muCi dose was administered and a 57-day delay in tumor growth (60% tumor-free after 1 year) when a 45 muCi dose was used. Treatment of mice bearing the same tumors with (211)At-SAPS T84.66 diabody at the same doses led to a delay in tumor growth, but no complete responses, likely due to substantially lower expression of this antigen on the MDA-MB-361/DYT2 tumors. In contrast, a dose of 20 muCi of (211)At-SAPS on the anti-Müllerian-inhibiting substance type II receptor diabody did not affect tumor growth rate, demonstrating specificity of the therapeutic effect. CONCLUSIONS: These findings indicate that diabody molecules can be effective agents for targeted radioimmunotherapy of solid tumors using powerful, short-lived alpha-emitting radioisotopes.