Mutational activation of c-raf-1 and definition of the minimal transforming sequence.

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Mol Cell Biol. 1990 June; 10(6): 2503-2512

Mutational activation of c-raf-1 and definition of the minimal transforming sequence.

G Heidecker, M Huleihel, J L Cleveland, W Kolch, T W Beck, P Lloyd, T Pawson and U R Rapp

Section of Viral Pathology, National Cancer Institute-Frederick Cancer Research Facility, Maryland 21701.

ABSTRACT

A series of wild-type and mutant raf genes was transfected intoNIH 3T3 cells and analyzed for transforming activity. Full-lengthwild-type c-raf did not show transforming activity. Two typesof mutations resulted in oncogenic activity similar to thatof v-raf: truncation of the amino-terminal half of the proteinand fusion of the full-length molecule to gag sequences. A lowerlevel of activation was observed for a mutant with a tetrapeptideinsertion mapping to conserved region 2 (CR2), a serine- andthreonine-rich domain located 100 residues amino-terminal ofthe kinase domain. To determine essential structural featuresof the transforming region of raf, we analyzed point and deletionmutants of v-raf. Substitutions of Lys-56 modulated the transformingactivity, whereas mutation of Lys-53, a putative ATP bindingresidue, abolished it. Deletion analysis established that theminimal transforming sequence coincided precisely with CR3,the conserved Raf kinase domain. Thus, oncogenic activationof the Raf kinase can be achieved by removal of CR1 and CR2or by steric distortion and requires retention of an activekinase domain. These findings are consistent with a proteinstructure model for the nonstimulated enzyme in which the activesite is buried within the protein.

Mol Cell Biol. 1990 June; 10(6): 2503-2512

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