Teresa Barlozzari scite author profile

A series of novel thienopyrimidine-based receptor tyrosine kinase inhibitors has been discovered. Investigation of structure-activity relationships at the 5- and 6-positions of the thienopyrimidine nucleus led to a series of N,N'-diaryl ureas that potently inhibit all of the vascular endothelial growth factor (VEGF) and platelet-derived growth factor (PDGF) receptor tyrosine kinases. A kinase insert domain-containing receptor (KDR) homology model suggests that these compounds bind to the "inactive conformation" of the enzyme with the urea portion extending into the back hydrophobic pocket adjacent to the adenosine 5'-triphosphate (ATP) binding site. A number of compounds have been identified as displaying excellent in vivo potency. In particular, compounds 28 and 76 possess favorable pharmacokinetic (PK) profiles and demonstrate potent antitumor efficacy against the HT1080 human fibrosarcoma xenograft tumor growth model (tumor growth inhibition (TGI) = 75% at 25 mg/kg.day, per os (po)).

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In vivo natural reactivity of mice against tumor cells

Riccardi

Santoni

Barlozzari

et al. 1980

Intl Journal of Cancer

157

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A rapid in vivo clearance of tumor cells was found in normal mice following intravenous inoculation of [125l]dUrd‐labelled YAC‐1 and RBL‐5 cultured cell lines derived from lymphomas. The ability of mice to eliminate tumor cells from spleen, liver and lungs during the first 4 h, as evaluated by the recovery of radioactivity in these organs, was found to correlate with the level of natural killer (NK) cell reactivity in their spleen and lungs, as measured simultaneously in vitro in a shortterm 51Cr release assay (CRA). Lower recovery of radioactivity was found in mouse strains with high spontaneous levels of NK activity. The degree of clearance was also found to be age‐dependent and older mice of several strains, whose NK activity had declined to low levels, were less effective in eliminating tumor cells. In vivo treatment with interferon and interferon inducers (poly I:C, pyran copolymer, Corynebacterium parvum, murine sarcoma virus) increased the levels of NK activity in the spleen and lungs and also augmented the in vivo clearance of tumor cells from the lungs and liver. Immunopharmacological treatments with antimacrophage agents (silica, iota‐carrageenan, Seakem‐carrageenan), antineoplastic drugs (dexamethasone, cyclophosphamide, 5‐(3,‐3′dimethyl‐I‐triazeno)‐imidazole‐4‐carboxamide, 4‐amino‐L‐D‐arabinofuranosyl‐2‐(IH)‐pyrimidone, adriamycin) or irradiation (850 R γ‐ray) had comparable effects on both in vitro cytolytic activity and in vivo clearance of tumor cells. When the susceptibility to in vitro and in vivocytotoxicity by several other tumors was examined, the lines with detectable sensitivity to lysis by NK cells were found to be cleared in vivo to a greater degree in a high NK strain (CBA) than in a low NK strain (SJL). In contrast, NK‐resistant lines were cleared at approximately the same rate in both strains. However, the actual levels of in vivo clearance and the degree of difference between the strains for the various NK‐sensitive lines did not correlate well with their relative sensitivities to lysis in vitro. In the various situations in which the in vivo recovery of a particular NK‐sensitive line was studied relative to the levels of NK reactivity in the recipients, the best correlations were seen with clearance from the lungs. In several instances, clearance from the spleen did not correlate well with splenic NK activity. These data indicate that rapid in vivo clearance of radiolabelled NK‐sensitive tumor cell lines is appreciably influenced by levels of NK reactivity, but that other factors are probably also involved.

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Suppression of Microtubule Dynamics by Binding of Cemadotin to Tubulin: Possible Mechanism for Its Antitumor Action

et al. 1998

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Cemadotin (LU103793) (NSC D-669356) is a water-soluble synthetic analogue of dolastatin 15 that inhibits cell proliferation in vitro and the growth of human tumor xenografts. Cemadotin is in phase II clinical trials as a promising cancer chemotherapeutic agent. The drug blocks cells at mitosis. Its primary mode of action has been unclear but is believed to involve an action on microtubules. We have found that cemadotin binds to tubulin and strongly suppresses microtubule dynamics. Scatchard analysis of cemadotin binding to tubulin indicated that there are two affinity classes of cemadotin-binding sites with Kd values of 19.4 microM and 136 microM. Cemadotin did not inhibit the binding of vinblastine to tubulin, and, conversely, vinblastine did not inhibit the binding of cemadotin to tubulin. By quantitative video microscopy of individual microtubules, we found that cemadotin strongly suppressed dynamic instability of microtubules assembled to steady state using bovine brain tubulin devoid of microtubule-associated proteins. It reduced the rate and extent of growing and shortening, increased the rescue frequency, and increased the percentage of time the microtubules spent in an attenuated or paused state, neither growing nor shortening detectably. At the lowest effective cemadotin concentrations, dynamics were suppressed in the absence of significant microtubule depolymerization. The results suggest that cemadotin exerts its antitumor activity by suppressing spindle microtubule dynamics through a distinct molecular mechanism by binding at a novel site in tubulin.

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Suppression of activity of mouse natural killer (NK) cells by activated macrophages from mice treated with pyran copolymer

Santoni

Riccardi

Barlozzari

et al. 1980

Intl Journal of Cancer

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Treatment of young mice with pyran copolymer caused a substantial decrease in natural killer (NK) cell activity at 7 days. The decrease in cytotoxicity was associated with the presence of splenic suppressor cells, capable of inhibiting in vitro the NK activity of spleen cells from normal mice. The suppressor cells appeared to be macrophages, being plastic-adherent, phagocytic and radioresistant, and lacking demonstrable Thy 1.2 antigen. Sonicates or culture supernatants of adherent spleen cells from pyran-treated mice were also able to inhibit NK activity, suggesting that suppressor cells act by release of soluble factors.

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Suppression of natural killer (NK) activity by splenic adherent cells of low NK‐reactive mice

Riccardi

Santoni

Barlozzari

et al. 1981

Intl Journal of Cancer

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Adherent cells with the ability to inhibit NK activity were found in the spleens of young 8-week-old SJL/J mice. Such suppressor cells were also found in the spleens of other low-NK-reactive strains, but not in the spleen of age-matched high-NK-reactive strains. These suppressor cells had the characteristics of macrophages, since they were plastic- and nylon-adherent, phagocytosed latex and iron particles, and were resistant to treatment with anti-Thy-1.2 serum plus complement. Their inhibitory activity appeared to be due to their production and/or release of soluble suppressive factor(s). Their suppressor activity was similar to that of pyran copolymer-activated macrophages, which were previously shown to be suppressive for cytotoxicity by NK cells. We suggest here that macrophages may be involved in the physiological regulation of NK activity and may contribute to the low NK activity in some strains of mice.

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