The oncofetal protein, 5T4, is a suitable target for antibody-guided anti-cancer chemotherapy with calicheamicin.

The oncofetal protein, 5T4, is a tumor-associated protein displayed on the cell membrane of various carcinomas. This molecule is a promising target for anti-tumor vaccine development and for targeted therapy with staphylococcus exotoxin. The potential use of 5T4 as a target for antibody-guided chemotherapy has not been demonstrated. We report oncolytic efficacy and selectivity in vitro and in vivo with immuno-conjugates of calicheamicin (CM) and the anti-5T4 antibody, H8. CM is a potent cytotoxic drug that causes double strand breaks in DNA. Conjugates of CM and H8 were constructed with acid-labile as well as acid-stabile linkers. In vitro, when applied to monolayers of 5T4(+) cells, CM-conjugates targeting 5T4 were consistently more toxic than either free drug or a non-binding control CM-conjugate. This difference was less pronounced on 5T4-deficient cells. In vivo, four 5T4-positive subcutaneous tumor models were treated with conjugates. Efficacy was demonstrated by reduction of tumor growth relative to controls treated with drug vehicle. To evidence selectivity, the efficacy of the anti-5T4 conjugates was compared to the efficacy of H8, a mixture of H8 and calicheamicin, calicheamicin alone or calicheamicin conjugated to the anti-CD33 antibody, hP67.6. In addition, the efficacy and selectivity of an acid-labile conjugate of H8 was evaluated in an orthotopic model for 5T4(+) lung cancer. Increased survival following treatment was used as a parameter of efficacy. Calicheamicin conjugates of H8 were effective and selective in all the examined tumor models. Differences in efficacy between the acid-labile and acid-stabile conjugates depended on the investigated tumor model.

Characterization of a soluble vascular endothelial growth factor receptor-immunoglobulin chimera.

To investigate the interaction between vascular endothelial growth factor (VEGF) and its receptor, we have constructed a chimeric protein consisting of the extracellular ligand-binding domain of the human VEGF receptor subtype KDR fused to a human IgG1 Fc domain (KDR-Fc). KDR-Fc was expressed in human 293 kidney epithelial cells as a 300-kDa secreted, dimeric glycoprotein that bound 125I-VEGF165 with high affinity (Kd = 150 pM). Unlike the full length cellular receptor, KDR-Fc did not require heparin for 125I-VEGF165 binding, although heparin did stimulate 125I-VEGF165 binding approximately 50 to 100%. Similar results were observed for KDR-Fc expressed in yeast cells. Since yeast do not synthesize heparan sulfate proteoglycans, we conclude that cellular heparan sulfates do not account for the lack of a heparin requirement for 125I-VEGF165 binding to KDR-Fc. The polycationic protein protamine, which inhibits (IC50 = 1 microgram/ml) 125I-VEGF165 binding to bovine aortic endothelial cells and other KDR-expressing cells by blocking heparin interactions, had no effect on the heparin independent component of 125I-VEGF165 binding to KDR-Fc. Protamine does inhibit (IC50 = 1 microgram/ml) the heparin dependent component of 125I-VEGF165 binding to KDR-Fc. KDR-Fc bound VEGF121 with the same affinity as VEGF165. Heparin had no effect on 125I-VEGF121 binding to KDR-Fc, indicating that heparin interaction with the 44 amino acids contained in VEGF165 but not VEGF121 allow for maximal VEGF165 binding. Deletion analysis of KDR-Fc demonstrated that the determinants required for high affinity VEGF binding are located in the three aminoterminal Ig-domains of the protein. Heparin had no effect on 125I-VEGF165 binding to the three Ig-domain receptor, suggesting that there are heparin binding determinants located in KDR Ig-domains 4 to 7.

Inhibition of human cytomegalovirus UL80 protease by specific intramolecular disulfide bond formation.

A symmetrically substituted disulfide compound, CL13933, was identified as a potent inhibitor of human cytomegalovirus UL80 protease. Two types of inhibited protease were observed, depending on inhibitor concentration. At high concentrations, CL13933 formed a covalent adduct with the protease on Cys residues. At lower concentrations, this compound induced specific intramolecular disulfide formation between Cys84 and Cys87, and between Cys138 and Cys161. In contrast, Cys202 did not form disulfide bonds. Inhibition was reversed upon reduction of the protease. Each of the five cysteines of the UL80 protease was individually mutated to Ala. Each of the mutant proteases retained enzymatic activity, but mutants C138A and C161A were resistant to inhibition by CL13933, suggesting that disulfide bond formation between Cys138 and Cys161 is responsible for inhibition. This disulfide is apparently not induced by air oxidation. Examination of the CL13933 loading patterns of wild type and the five mutant proteases by mass spectrometry revealed that residues Cys87, Cys138, and Cys161 react with CL13933, and that the disulfide pair partner of each (Cys84, Cys161, and Cys138, respectively) is able to displace the compound via thiol-disulfide exchange. The possible significance of these reactive thiols in the protease is discussed.

Flavins inhibit human cytomegalovirus UL80 protease via disulfide bond formation.

Among the most potent inhibitors of human cytomegalovirus protease identified by random screening of a chemical library was 1,4-dihydro-7,8-dimethyl 6H-pyrimido[1,2-b]-1,2,4,5-tetrazin-6-one (1) (PTH2). The oxidized form (2), PT, which is present in solutions of PTH2, was shown to be the actual inhibitory species which irreversibly inactivates the protease; recycling of PTH2 by dissolved oxygen results in complete inhibition of the protease at substoichiometric amounts of compound. No evidence for a covalent adduct between the protease and the inhibitor was obtained, and protease activity was restored by incubation of the inactivated enzyme with the reducing agent bismercaptoethyl sulfone, suggesting that disulfide bond formation was responsible for the observed inhibition. The five cysteines of the protease are normally in the reduced state; analysis of tryptic peptides from inhibited protease indicated that disulfide bonds Cys84-Cys87 and Cys138-Cys161 were formed. Using site-directed mutagenesis, the disulfide pair induced between Cys138 and Cys161 disulfide is dependent upon interaction of PT with the protease and does not form spontaneously, unlike that of the Cys84-Cys87 pair which can form in the absence of inhibitor. The inhibitor's redox chemistry is analogous to that of flavin, and, in fact, flavin inhibits the protease by the same mechanism, causing formation of a disulfide bond between Cys138 and Cys161. That the cysteines are dispensable, but can regulate protease activity by formation of a unique disulfide pair, suggests a plausible mechanism for control of proteolysis during the viral life cycle.