Pharmacodynamic characterization of the efficacy signals due to selective BRAF inhibition with PLX4032 in malignant melanoma.

PURPOSE: About 65% to 70% of melanomas harbor a mutation in v-raf murine sarcoma viral oncogene homolog B1 (BRAF) that causes the steady-state activation of extracellular signal-regulated kinase (ERK). We sought to investigate the efficacy of PLX4032 (BRAF inhibitor) to identify patterns/predictors of response/resistance and to study the effects of BRAF in melanoma. EXPERIMENTAL DESIGN: Well-characterized melanoma cell lines, including several with acquired drug resistance, were exposed to PLX4032. Growth inhibition, phosphosignaling, cell cycle, apoptosis, and gene expression analyses were performed before and after exposure to drug. RESULTS: Using a growth-adjusted inhibitory concentration of 50% cutoff of 1 microM, 13 of 35 cell lines were sensitive to PLX4032, 16 resistant, and 6 intermediate (37%, 46%, and 17% respectively). PLX4032 caused growth inhibition, G(0)/G(1) arrest, and restored apoptosis in the sensitive cell lines. A BRAF mutation predicted for but did not guarantee a response, whereas a neuroblastoma RAS viral oncogene homolog mutation or wild-type BRAF conferred resistance. Cells with concurrent BRAF mutations and melanocortin 1 receptor germ line variants and/or a more differentiated melanocyte genotype had a preferential response. Acquired PLX4032 resistance reestablishes ERK signaling, promotes a nonmelanocytic genotype, and is associated with an increase in the gene expression of certain metallothioneins and mediators of angiogenesis. CONCLUSIONS: PLX4032 has robust activity in BRAF mutated melanoma. The preclinical use of this molecule identifies criteria for its proper clinical application, describes patterns of and reasons for response/resistance, and affords insight into the role of a BRAF mutation in melanoma.

A human ovarian carcinoma murine xenograft model useful for preclinical trials.

OBJECTIVE: To establish a murine xenograft model of human ovarian carcinoma. METHODS: A slurry of fresh human tumor from patients with intraperitoneal malignancies was heterotransplanted intraperitoneally into nude (nu/nu) and severely combined immunodeficient mice (CB-17, SCID). Xenograft growth was assessed by serial examination and necropsy. The xenografts were passaged to new animals when tumors were palpably greater than 1 cm(3). Histopathologic analysis of the xenografts was performed at each passage as well as immunohistochemical staining for p53 mutations. Persistent expression of human genes by the xenografts at higher passages was assessed by RT-PCR amplification of the human beta-globin gene. This xenograft model was used in the preclinical evaluation of an adenoviral vector containing a beta-galactosidase reporter gene and a wild-type p53 gene. RESULTS: Tumor growth was not established in any of the nude mice heterotransplanted with tissue from six different ovarian cancer patients. Eleven of 13 specimens established xenograft growth when injected in SCID mice. Nine xenografts have been subsequently passaged between 6 and 24 animal generations to date. All xenografts retained histopathologic similarities to their original human tumors and the p53 expression patterns remained stable through higher passages. Within 24 h after intraperitoneal administration of an adenoviral vector, transduction of the reporter gene was evident in the xenografts. In addition, administration of an adenoviral vector containing a wild-type p53 gene significantly decreased the tumor burden compared to controls (P < 0.04). CONCLUSIONS: This murine xenograft model of human ovarian carcinoma appears to be reliable and reproducible and has utility for the study of novel therapeutics.