Abstract
Rho GTPases regulate cellular morphology and dynamics, and some are key drivers of cancer progression. This superfamily offers attractive potential targets for therapeutic intervention, with RhoA, Rac1 and Cdc42 being prime examples. The challenges in developing agents that act on these signaling enzymes include the lack of obvious druggable pockets and their membrane-bound activities. However, progress in targeting the similar Ras protein is illuminating new strategies for specifically inhibiting oncogenic GTPases. The structures of multiple signaling and regulatory states of Rho proteins have been determined, and the post-translational modifications including acylation and phosphorylation points have been mapped and their functional effects examined. The development of inhibitors to probe the significance of overexpression and mutational hyperactivation of these GTPases underscores their importance in cancer progression. The ability to integrate in silico, in vitro, and in vivo investigations of drug-like molecules indicates the growing tractability of GTPase systems for lead optimization. Although no Rho-targeted drug molecules have yet been clinically approved, this family is clearly showing increasing promise for the development of precision medicine and combination cancer therapies.
Highlights
Comparison of the guanosine triphosphatase (GTPase) structures reveals a unique feature among the Rho family: A helical stretch of approximately 10–15 residues located between α4 and β5 [1,20]
In contrast to the Ras GTPase family members, which are mutated in 30% of human tumours [65], cancer-linked mutations are rarely found in Rho GTPase members
Inhibiting of certain Rho GTPases may reduce the ability of cancerous cells to invade new tissues, and prevent secondary tumor formation by inhibiting the mechanism which allow for tumor metastasis
Summary
The Ras superfamily consists of GTP (guanosine triphosphate)-binding proteins (G proteins) that range in size from 20 to 40 kDa. Most members have an intrinsic guanosine triphosphatase (GTPase) activity that allows them to hydrolyze GTP. The human genome encodes 22 Rho family members [3] with RhoA, Cdc, and. The structural mechanisms of RhoA, Rac and Cdc are well-defined, serum response factor (SRF) to activate transcription [11]. The structural mechanisms of RhoA, Rac as are their regulatory partners and post-translational modifications. Cdc are well-defined, as are their regulatory partners and post-translational cancer progressionInand increasing tractability of relatives including. Rho proteins of arenovel discussed here to showcase the for therapeutic intervention.
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