GTPase HRas: Difference between revisions
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== Function == | == Function == | ||
The ''RAS'' gene family was discovered due to the presence of two closely related retroviral cancer genes (oncogenes) within the Harvey and Kirsten '''RA'''t '''S'''arcoma viruses. These retroviral oncogenes arose via capture of two normal cellular genes, ''H-RAS'' and ''K-RAS''. A [[DNA]] transfection assay for [[Oncogenes|oncogenes]] in human bladder cancer later identified the same ''H-RAS'' gene. Remarkably, the mutated oncogenic form of ''H-RAS'' differed from its normal counterpart by a single nucleotide change that caused a single amino acid substitution. Biochemical studies of purified RAS proteins revealed that they were capable of binding nucleotides, with a particularly high affinity for GTP. Extensive genetic, biochemical, and structural studies have established a model in which the RAS proteins function as molecular switches, as do related GTP-binding proteins. The RAS switch is "ON" when it binds <scene name='User:Joseph_Lipsick/RAS/Ras-gtp_switches/5'>GTP</scene>, and is "OFF" when it binds <scene name='User:Joseph_Lipsick/RAS/Ras-gdp_switches/11'>GDP</scene>. The changes in protein conformation between the <scene name='User:Joseph_Lipsick/RAS/Ras-gtp_switch_i_ii_spacefill/2'>"ON"</scene> and <scene name='User:Joseph_Lipsick/RAS/Ras-gdp_switch_i_ii_spacefill/3'>"OFF"</scene> states are not very large. These changes primarily occur in two regions known as SWITCH I (yellow) and SWITCH II (magenta), and can be visualized by toggling the spin off and on in these partial space-filling models. The RAS protein itself has an intrinsic GTPase activity, thereby limiting the duration of time spent in the "ON" configuration. The binding sites of the nucleotide and the magnesium ion are revealed in high detail and consists of a characteristic <scene name='5p21/Ligand_binding_site/1'>Walker motif</scene> (GXXXXGK[T/S]). For additional details see<br /> | The ''RAS'' gene family was discovered due to the presence of two closely related retroviral cancer genes (oncogenes) within the Harvey and Kirsten '''RA'''t '''S'''arcoma viruses. These retroviral oncogenes arose via capture of two normal cellular genes, ''H-RAS'' and ''K-RAS''. A [[DNA]] transfection assay for [[Oncogenes|oncogenes]] in human bladder cancer later identified the same ''H-RAS'' gene. Remarkably, the mutated oncogenic form of ''H-RAS'' differed from its normal counterpart by a single nucleotide change that caused a single amino acid substitution. Biochemical studies of purified RAS proteins revealed that they were capable of binding nucleotides, with a particularly high affinity for GTP. Extensive genetic, biochemical, and structural studies have established a model in which the RAS proteins function as molecular switches, as do related GTP-binding proteins. The RAS switch is "ON" when it binds <scene name='User:Joseph_Lipsick/RAS/Ras-gtp_switches/5'>GTP</scene>, and is "OFF" when it binds <scene name='User:Joseph_Lipsick/RAS/Ras-gdp_switches/11'>GDP</scene>. The changes in protein conformation between the <scene name='User:Joseph_Lipsick/RAS/Ras-gtp_switch_i_ii_spacefill/2'>"ON"</scene> and <scene name='User:Joseph_Lipsick/RAS/Ras-gdp_switch_i_ii_spacefill/3'>"OFF"</scene> states are not very large. These changes primarily occur in two regions known as SWITCH I (yellow) and SWITCH II (magenta), and can be visualized by toggling the spin off and on in these partial space-filling models. The RAS protein itself has an intrinsic GTPase activity, thereby limiting the duration of time spent in the "ON" configuration. The binding sites of the nucleotide and the magnesium ion are revealed in high detail and consists of a characteristic <scene name='5p21/Ligand_binding_site/1'>Walker motif</scene> (GXXXXGK[T/S]).<br /> For additional details on RAS see<br /> | ||
[[H-RasK117R mutant]]<br /> | [[H-RasK117R mutant]]<br /> | ||
[[Ras Protein and Pancreas Cancer]]<br /> | |||
[[User:Joseph Lipsick/RAS]]<br /> | [[User:Joseph Lipsick/RAS]]<br /> | ||
[[H RAS protein (hebrew)]]<br /> | |||
[[Chani elisha]]. | [[Chani elisha]]. | ||
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== Structural highlights == | == Structural highlights == | ||
Interactions with the <scene name='37/379455/Cv/6'>nucleotide phosphate moiety in the active site</scene> of GTPase Hras determine its active conformation<ref>PMID:242356730</ref>. Water molecules shown as red spheres. | Interactions with the <scene name='37/379455/Cv/6'>nucleotide phosphate moiety in the active site</scene> of GTPase Hras determine its active conformation<ref>PMID:242356730</ref>. Water molecules shown as red spheres. <scene name='37/379455/Cv/7'>Mg coordination site</scene>. | ||
==3D structures of GTPase Hras== | |||
[[GTPase Hras 3D structures]] | |||
</StructureSection> | </StructureSection> | ||
==References== | ==References== | ||
Latest revision as of 16:13, 10 February 2021
FunctionThe RAS gene family was discovered due to the presence of two closely related retroviral cancer genes (oncogenes) within the Harvey and Kirsten RAt Sarcoma viruses. These retroviral oncogenes arose via capture of two normal cellular genes, H-RAS and K-RAS. A DNA transfection assay for oncogenes in human bladder cancer later identified the same H-RAS gene. Remarkably, the mutated oncogenic form of H-RAS differed from its normal counterpart by a single nucleotide change that caused a single amino acid substitution. Biochemical studies of purified RAS proteins revealed that they were capable of binding nucleotides, with a particularly high affinity for GTP. Extensive genetic, biochemical, and structural studies have established a model in which the RAS proteins function as molecular switches, as do related GTP-binding proteins. The RAS switch is "ON" when it binds , and is "OFF" when it binds . The changes in protein conformation between the and states are not very large. These changes primarily occur in two regions known as SWITCH I (yellow) and SWITCH II (magenta), and can be visualized by toggling the spin off and on in these partial space-filling models. The RAS protein itself has an intrinsic GTPase activity, thereby limiting the duration of time spent in the "ON" configuration. The binding sites of the nucleotide and the magnesium ion are revealed in high detail and consists of a characteristic (GXXXXGK[T/S]). H-RasK117R mutant Disease The two most common oncogenic mutations in H-RAS affect residues and , both of which are adjacent to the bound GTP molecule. These oncogenic mutations greatly inhibit the intrinsic GTPase activity, thereby causing the RAS switch to spend more time in the "ON" position. The RAS proteins are present at the plasma membrane and transmit signals from transmembrance receptor tyrosine kinases (e.g. EGF and PDGF receptors) to downstream intracellular effectors that include the MAPK protein kinase cascade and the PI3K lipid kinase. Binding of EGF or PDGF to their receptors causes a relocalization of a Guanine Nucleotide Exchange Factor (GEF) protein to the plasma membrane. The structure of , a prototypic GEF, together with RAS implies that the GEF prys open the nucleotide binding site with a loss of bound GDP. The ten-fold higher ratio of GTP to GDP within the cell results in the replacement of RAS-GDP ("OFF" state) with RAS-GTP ("ON" state). Consistent with this model, gain-of-function mutations of GEF genes can be oncogenic (e.g. VAV oncogene) even in the absence of mutations of RAS. Conversely, a GTPase Activating Protein () can bind to RAS-GTP and increase the rate of the intrinsic RAS GTPase. Consistent with this model, loss-of-function mutations of GAP genes (e.g. NF1 tumor suppressor) can be oncogenic even in the absence of mutations of RAS itself. More details in Allosteric modulation of H-Ras GTPase Structural highlightsInteractions with the of GTPase Hras determine its active conformation[1]. Water molecules shown as red spheres. . 3D structures of GTPase Hras |
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ReferencesReferences
- Milburn, et al. Science. 1990. 247: 939-45.
- Wittinghofer and Pai. Trends Biochem Sci. 1991. 16: 382-7.
- Malumbres and Barbacid. Nature Rev Cancer. 2003. 3: 459-65.
- Bos, Rehmann, and Wittinghofer. Cell. 2007. 129: 865-77.
- Karnoub and Weinberg. Nature Rev Mol Cell Biol. 2008. 9: 517-531.