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Clinical and molecular evidence for c-kit receptor as a therapeutic target in neuroblastic tumors

TitleClinical and molecular evidence for c-kit receptor as a therapeutic target in neuroblastic tumors
Publication TypeArticolo su Rivista peer-reviewed
Year of Publication2005
AuthorsUccini, S., Mannarino O., McDowell H.P., Pauser U., Vitali Roberta, Natali P.G., Altavista P., Andreano T., Coco S., Boldrini R., Bosco S., Clerico A., Cozzi D., Donfrancesco A., Inserra A., Kokai G., Losty P.D., Nicotra M.R., Raschellà G., Tonini G.P., and Dominici C.
JournalClinical Cancer Research
Volume11
Pagination380-389
ISSN10780432
Keywordsadolescent, Age Factors, allele, Alleles, article, Blotting, cancer survival, Child, controlled study, Correlation analysis, DNA Mutational Analysis, exon, Exons, Female, gene amplification, gene mutation, human, human tissue, Humans, immunohistochemistry, Infant, major clinical study, male, Messenger, messenger RNA, Multivariate analysis, mutation, Neuroblastoma, newborn, Northern, Northern blotting, Phosphorylation, Preschool, priority journal, Proportional Hazards Models, protein analysis, protein expression, protein phosphorylation, Proto-Oncogene Proteins c-kit, Regression analysis, Reverse Transcriptase Polymerase Chain Reaction, reverse transcription polymerase chain reaction, RNA, Southern, stem cell factor, stem cell factor receptor, survival rate, Time Factors, treatment outcome
Abstract

Purpose: Clinicobiological characteristics of neuroblastic tumor (NT) expressing c-kit tyrosine kinase receptor and/or its ligand, stem cell factor (SCF), are debated. This study aimed at investigating the clinicobiological features of primary NTs expressing c-kit and/or SCF in order to define the clinical relevance of selective therapeutic targeting. Experimental Design: c-Kit and SCF expression was studied in 168 NTs using immunohistochemistry and in 106 of 168 using Northern blot. Quantitative determination of c-kit expression in 54 additional NTs was also done using real-time reverse transcription-PCR. Correlations between c-kit and SCF expression and clinicobiological features were analyzed using χ 2 test, univariate, and multivariate regression analyses. Results: c-Kit protein was detected in 21 of 168 NTs (13%) and its mRNA in 23 of 106 NTs (22%). SCF protein was shown in 30 of 106 NTs (28%) and its mRNA in 33 of 106 NTs (31%). No mutations in exon 11 of c-kit gene were identified. By univariate analysis, c-kit and SCF expression correlated with advanced stage, MYCN amplification, and 1p36 allelic loss. Cox simple regression analysis showed that overall survival probability was 17% in the c-kit-positive subset versus 68% in the negative (P < 0.001), 43% in the SCF-positive subset versus 78% in the negative (P < 0.001). When using real-time reverse transcription-PCR, significant levels of c-kit mRNA were found in 35 of 54 NTs (65%), but the correlations with clinicobiological features were no longer documented. Conclusions: c-Kit expression can be detected in the majority of primary NTs. High levels of expression are preferentially found in tumors with unfavorable clinicobiological variables. c-Kit may represent a useful therapeutic target in a subset of otherwise untreatable NTs.

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URLhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-19944428974&partnerID=40&md5=e4af065c9e027fbed4f7b82f15805ffe
Citation KeyUccini2005380