Optimized conditions for GTP loading of Ras

Ras and the small GTPase group are essential for myriad cellular processes and cycle between GDP- and GTP-loaded states to allow stringent control of downstream signaling pathways. Biochemical studies of small GTPases can therefore require a specific nucleotide-bound state. Small GTPases possess basal intrinsic activity to process GTP into GDP plus inorganic phosphate, therefore in vitro exchange of GDP for GTP is necessary for assays on GTP-loaded states. Here, we assess the methodology of in vitro nucleotide exchange for soluble H-Ras. We begin by describing a protocol to quantify the nucleotide bound content of H-Ras using anion exchange chromatography and use this protocol to investigate optimal strategies for loading Ras with GTP by assessing the effects of time, temperature, H-Ras concentration, magnesium, excess nucleotide, and isoform identity. We continue by considering storage of GTP-loaded H-Ras and present optimal conditions to minimize intrinsic GTP hydrolysis. Finally, we conclude by investigating the nucleotide composition of recombinantly expressed H-Ras encompassing cancer mutations at residues Gly12, Gly13, and Gln61. We therefore describe methodology to quantitatively analyze the nucleotide content of small GTPases and their mutants, and demonstrate conditions to achieve efficient GTP loading of Ras.