Dominant inhibitory Ras mutants selectively inhibit the activity of either cellular or oncogenic Ras.

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Mol Cell Biol. 1991 August; 11(8): 4053-4064

Dominant inhibitory Ras mutants selectively inhibit the activity of either cellular or oncogenic Ras.

D W Stacey, L A Feig and J B Gibbs

Department of Molecular Biology, Cleveland Clinic Foundation, Ohio 44106.

ABSTRACT

Two dominant inhibitory Ras mutant proteins were analyzed bymicroinjection. One, [Asn-17]Ras, had a substitution in theputative Mg(2+)-binding site of Ha-Ras. The other, RAST, hada mutation in a yeast RAS protein that impaired its GTPase activityand increased its affinity for GAP. RAST also had a mutationthat blocked its localization to the plasma membrane. In NIH3T3 cells [Asn-17]Ras inhibited the function of normal Ras muchmore efficiently than that of oncogenic Ras. In contrast, RASTinterfered with the transforming activity of oncogenic Ras moreefficiently than that of normal Ras. These conclusions werebased on two separate types of analysis. The inhibitory Rasmutant proteins were first microinjected into cells stably transformedeither by oncogenic Ras or by high levels of expression of cellularRas. Results obtained in stably transformed cells were thenverified by coinjection of the inhibitory Ras mutant proteinstogether with transforming concentrations of either oncogenicor normal Ras protein. Whereas RAST was active in soluble form.[Asn-17]Ras required membrane localization for activity. Furthermore,mutations in the GAP/effector-binding domain reduced or eliminatedthe inhibitory activity of RAST but had no detectable effecton [Asn-17]Ras. These results are consistent with the possibilitythat [Asn-17]Ras functions by blocking the activation of endogenousRas proteins, while RAST functions by blocking the ability ofactivated Ras to stimulate a downstream target within the cells.The properties of RAST suggest that interference with the GAP/effector-bindingfunction of RAS represents a strategy for the preferential inactivationof oncogenic Ras in cells.

Mol Cell Biol. 1991 August; 11(8): 4053-4064

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