Abstract
The zebrafish is a powerful genetic model that has only recently been used to dissect developmental pathways involved in oncogenesis. We hypothesized that operative pathways during embryogenesis would also be used for oncogenesis. In an effort to define RAS target genes during embryogenesis, gene expression was evaluated in Tg(hsp70-HRAS(G12V)) zebrafish embryos subjected to heat shock. dusp6 was activated by RAS, and this was used as the basis for a chemical genetic screen to identify small molecules that interfere with RAS signaling during embryogenesis. A KRAS(G12D)-induced zebrafish embryonal rhabdomyosarcoma was then used to assess the therapeutic effects of the small molecules. Two of these inhibitors, PD98059 and TPCK, had anti-tumor activity as single agents in both zebrafish embryonal rhabdomyosarcoma and a human cell line of rhabdomyosarcoma that harbored activated mutations in NRAS. PD98059 inhibited MEK1 whereas TPCK suppressed S6K1 activity; however, the combined treatment completely suppressed eIF4B phosphorylation and decreased translation initiation. Our work demonstrates that the activated pathways in RAS induction during embryogenesis are also important in oncogenesis and that inhibition of these pathways suppresses tumor growth.
Highlights
The zebrafish was first established as a powerful vertebrate model organism for large-scale developmental genetic screens (Gaiano et al, 1996; Haffter et al, 1996)
Establishing a chemical screen platform using inducible RAS zebrafish embryos to dissect tumorigenesis pathways The activation of RAS during embryogenesis may recapitulate the activation of its pathways during tumorigenesis
A microarray analysis was performed by comparing the transcription profiles of Tg(hsp70-HRASG12V) and wild-type embryos subjected to heat shock
Summary
The zebrafish was first established as a powerful vertebrate model organism for large-scale developmental genetic screens (Gaiano et al, 1996; Haffter et al, 1996). A rag2-KRASG12D-induced embryonal rhabdomyosarcoma (ERMS) revealed that zebrafish and human ERMS share two conserved gene signatures, one of which is associated with tissue-restricted gene expression in rhabdomyosarcoma and a second that comprises a RAS-induced gene signature (Langenau et al, 2007). These zebrafish cancer models share similar histopathological features and molecular pathways to human disease, and respond to drugs in a similar manner as humans, and can be implemented in different steps of novel anti-cancer agent development
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