Ras GTPase

(Redirected from Ras gene)

Ras, from "Rat sarcoma virus", is a family of related proteins that are expressed in all animal cell lineages and organs. All Ras protein family members belong to a class of protein called small GTPase, and are involved in transmitting signals within cells (cellular signal transduction). Ras is the prototypical member of the Ras superfamily of proteins, which are all related in three-dimensional structure and regulate diverse cell behaviours.

HRas structure PDB 121p, surface colored by conservation in Pfam seed alignment: gold, most conserved; dark cyan, least conserved.
Identifiers
SymbolRas
PfamPF00071
InterProIPR020849
PROSITEPDOC00017
SCOP25p21 / SCOPe / SUPFAM
CDDcd04138
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary

When Ras is 'switched on' by incoming signals, it subsequently switches on other proteins, which ultimately turn on genes involved in cell growth, differentiation, and survival. Mutations in Ras genes can lead to the production of permanently activated Ras proteins, which can cause unintended and overactive signaling inside the cell, even in the absence of incoming signals.

Because these signals result in cell growth and division, overactive Ras signaling can ultimately lead to cancer.[1] The three Ras genes in humans (HRAS, KRAS, and NRAS) are the most common oncogenes in human cancer; mutations that permanently activate Ras are found in 20 to 25% of all human tumors and up to 90% in certain types of cancer (e.g., pancreatic cancer).[2] For this reason, Ras inhibitors are being studied as a treatment for cancer and other diseases with Ras overexpression.

History

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The first two Ras genes, HRAS and KRAS, were identified[3] from studies of two cancer-causing viruses, the Harvey sarcoma virus and Kirsten sarcoma virus, by Edward M. Scolnick and colleagues at the National Institutes of Health (NIH).[4] These viruses were discovered originally in rats during the 1960s by Jennifer Harvey[5] and Werner H. Kirsten,[6] respectively, hence the name Rat sarcoma.[3] In 1982, activated and transforming human ras genes were discovered in human cancer cells by Geoffrey M. Cooper at Harvard,[7] Mariano Barbacid and Stuart A. Aaronson at the NIH,[8] Robert Weinberg at MIT,[9] and Michael Wigler at Cold Spring Harbor Laboratory.[10] A third ras gene was subsequently discovered by researchers in the group of Robin Weiss at the Institute of Cancer Research,[11][12] and Michael Wigler at Cold Spring Harbor Laboratory,[13] named NRAS, for its initial identification in human neuroblastoma cells.

The three human ras genes encode extremely similar proteins made up of chains of 188 to 189 amino acids. Their gene symbols are HRAS, NRAS and KRAS, the latter of which produces the K-Ras4A and K-Ras4B isoforms from alternative splicing.[citation needed]

Structure

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HRas structure PDB 121p, ribbon showing strands in purple, helices in aqua, loops in gray. Also shown are the bound GTP analog and magnesium ion.

Ras contains six beta strands and five alpha helices.[14] It consists of two domains: a G domain of 166 amino acids (about 20 kDa) that binds guanosine nucleotides, and a C-terminal membrane targeting region (CAAX-COOH, also known as CAAX box), which is lipid-modified by farnesyl transferase, RCE1, and ICMT.[citation needed]

The G domain contains five G motifs that bind GDP/GTP directly. The G1 motif, or the P-loop, binds the beta phosphate of GDP and GTP. The G2 motif, also called Switch I or SW1, contains threonine35, which binds the terminal phosphate (γ-phosphate) of GTP and the divalent magnesium ion bound in the active site. The G3 motif, also called Switch II or SW2, has a DXXGQ motif. The D is aspartate57, which is specific for guanine versus adenine binding, and Q is glutamine61, the crucial residue that activates a catalytic water molecule for hydrolysis of GTP to GDP. The G4 motif contains a LVGNKxDL motif, and provides specific interaction to guanine. The G5 motif contains a SAK consensus sequence. The A is alanine146, which provides specificity for guanine rather than adenine.

The two switch motifs, G2 (SW1) and G3 (SW2), are the main parts of the protein that move when GTP is hydrolyzed into GDP. This conformational change by the two switch motifs is what mediates the basic functionality as a molecular switch protein. This GTP-bound state of Ras is the "on" state, and the GDP-bound state is the "off" state. The two switch motifs have a number of conformations when binding GTP or GDP or no nucleotide (when bound to SOS1, which releases the nucleotide).[15]

Ras also binds a magnesium ion which helps to coordinate nucleotide binding.

Function

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Overview of signal transduction pathways involved in apoptosis

Ras proteins function as binary molecular switches that control intracellular signaling networks. Ras-regulated signal pathways control such processes as actin cytoskeletal integrity, cell proliferation, cell differentiation, cell adhesion, apoptosis, and cell migration. Ras and Ras-related proteins are often deregulated in cancers, leading to increased invasion and metastasis, and decreased apoptosis.

Ras activates several pathways, of which the mitogen-activated protein (MAP) kinase cascade has been well-studied. This cascade transmits signals downstream and results in the transcription of genes involved in cell growth and division.[16] Another Ras-activated signaling pathway is the PI3K/AKT/mTOR pathway, which stimulates protein synthesis, cellular migration and growth, and inhibits apoptosis.[17][18]

Activation and deactivation

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Ras is a guanosine-nucleotide-binding protein. Specifically, it is a single-subunit small GTPase, which is related in structure to the Gα subunit of heterotrimeric G proteins (large GTPases). G proteins function as binary signaling switches with "on" and "off" states. In the "off" state it is bound to the nucleotide guanosine diphosphate (GDP), while in the "on" state, Ras is bound to guanosine triphosphate (GTP), which has an extra phosphate group as compared to GDP. This extra phosphate holds the two switch regions in a "loaded-spring" configuration (specifically the Thr-35 and Gly-60). When released, the switch regions relax which causes a conformational change into the inactive state. Hence, activation and deactivation of Ras and other small G proteins are controlled by cycling between the active GTP-bound and inactive GDP-bound forms.

The process of exchanging the bound nucleotide is facilitated by guanine nucleotide exchange factors (GEFs) and GTPase activating proteins (GAPs). As per its classification, Ras has an intrinsic GTPase activity, which means that the protein on its own will hydrolyze a bound GTP molecule into GDP. However this process is too slow for efficient function, and hence the GAP for Ras, RasGAP, may bind to and stabilize the catalytic machinery of Ras, supplying additional catalytic residues ("arginine finger") such that a water molecule is optimally positioned for nucleophilic attack on the gamma-phosphate of GTP. An inorganic phosphate is released and the Ras molecule is now bound to a GDP. Since the GDP-bound form is "off" or "inactive" for signaling, GTPase Activating Protein inactivates Ras by activating its GTPase activity. Thus, GAPs accelerate Ras inactivation.

GEFs catalyze a "push and pull" reaction which releases GDP from Ras. They insert close to the P-loop and magnesium cation binding site and inhibit the interaction of these with the gamma phosphate anion. Acidic (negative) residues in switch II "pull" a lysine in the P-loop away from the GDP which "pushes" switch I away from the guanine. The contacts holding GDP in place are broken and it is released into the cytoplasm. Because intracellular GTP is abundant relative to GDP (approximately 10 fold more)[16] GTP predominantly re-enters the nucleotide binding pocket of Ras and reloads the spring. Thus GEFs facilitate Ras activation.[14] Well known GEFs include Son of Sevenless (Sos) and cdc25 which include the RasGEF domain.

The balance between GEF and GAP activity determines the guanine nucleotide status of Ras, thereby regulating Ras activity.

In the GTP-bound conformation, Ras has a high affinity for numerous effectors which allow it to carry out its functions. These include PI3K. Other small GTPases may bind adaptors such as arfaptin or second messenger systems such as adenylyl cyclase. The Ras binding domain is found in many effectors and invariably binds to one of the switch regions, because these change conformation between the active and inactive forms. However, they may also bind to the rest of the protein surface.

Other proteins exist that may change the activity of Ras family proteins. One example is GDI (GDP Disassociation Inhibitor). These function by slowing the exchange of GDP for GTP, thus prolonging the inactive state of Ras family members. Other proteins that augment this cycle may exist.

Membrane attachment

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Ras is attached to the cell membrane owing to its prenylation and palmitoylation (HRAS and NRAS) or the combination of prenylation and a polybasic sequence adjacent to the prenylation site (KRAS). The C-terminal CaaX box of Ras first gets farnesylated at its Cys residue in the cytosol, allowing Ras to loosely insert into the membrane of the endoplasmatic reticulum and other cellular membranes. The Tripeptide (aaX) is then cleaved from the C-terminus by a specific prenyl-protein specific endoprotease and the new C-terminus is methylated by a methyltransferase. KRas processing is completed at this stage. Dynamic electrostatic interactions between its positively charged basic sequence with negative charges at the inner leaflet of the plasma membrane account for its predominant localization at the cell surface at steady-state. NRAS and HRAS are further processed on the surface of the Golgi apparatus by palmitoylation of one or two Cys residues, respectively, adjacent to the CaaX box. The proteins thereby become stably membrane anchored (lipid-rafts) and are transported to the plasma membrane on vesicles of the secretory pathway. Depalmitoylation by acyl-protein thioesterases eventually releases the proteins from the membrane, allowing them to enter another cycle of palmitoylation and depalmitoylation.[19] This cycle is believed to prevent the leakage of NRAS and HRAS to other membranes over time and to maintain their steady-state localization along the Golgi apparatus, secretory pathway, plasma membrane and inter-linked endocytosis pathway.

Members

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The clinically most notable members of the Ras subfamily are HRAS, KRAS and NRAS, mainly for being implicated in many types of cancer.[20]

However, there are many other members of this subfamily as well:[21] DIRAS1; DIRAS2; DIRAS3; ERAS; GEM; MRAS; NKIRAS1; NKIRAS2; RALA; RALB; RAP1A; RAP1B; RAP2A; RAP2B; RAP2C; RASD1; RASD2; RASL10A; RASL10B; RASL11A; RASL11B; RASL12; REM1; REM2; RERG; RERGL; RRAD; RRAS; RRAS2

Ras in cancer

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Mutations in the Ras family of proto-oncogenes (comprising H-Ras, N-Ras and K-Ras) are very common, being found in 20% to 30% of all human tumors.[20] It is reasonable to speculate that a pharmacological approach that curtails Ras activity may represent a possible method to inhibit certain cancer types. Ras point mutations are the single most common abnormality of human proto-oncogenes.[22] Ras inhibitor trans-farnesylthiosalicylic acid (FTS, Salirasib) exhibits profound anti-oncogenic effects in many cancer cell lines.[23][24]

Inappropriate activation

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Inappropriate activation of the gene has been shown to play a key role in improper signal transduction, proliferation and malignant transformation.[16]

Mutations in a number of different genes as well as RAS itself can have this effect. Oncogenes such as p210BCR-ABL or the growth receptor erbB are upstream of Ras, so if they are constitutively activated their signals will transduce through Ras.[citation needed]

The tumour suppressor gene NF1 encodes a Ras-GAP – its mutation in neurofibromatosis will mean that Ras is less likely to be inactivated. Ras can also be amplified, although this only occurs occasionally in tumours.

Finally, Ras oncogenes can be activated by point mutations so that the GTPase reaction can no longer be stimulated by GAP – this increases the half life of active Ras-GTP mutants.[25]

Constitutively active Ras

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Constitutively active Ras (RasD) is one which contains mutations that prevent GTP hydrolysis, thus locking Ras in a permanently 'On' state.

The most common mutations are found at residue G12 in the P-loop and the catalytic residue Q61.

  • The glycine to valine mutation at residue 12 renders the GTPase domain of Ras insensitive to inactivation by GAP and thus stuck in the "on state". Ras requires a GAP for inactivation as it is a relatively poor catalyst on its own, as opposed to other G-domain-containing proteins such as the alpha subunit of heterotrimeric G proteins.
  • Residue 61[26] is responsible for stabilizing the transition state for GTP hydrolysis. Because enzyme catalysis in general is achieved by lowering the energy barrier between substrate and product, mutation of Q61 to K (Glutamine to Lysine) necessarily reduces the rate of intrinsic Ras GTP hydrolysis to physiologically meaningless levels.

See also "dominant negative" mutants such as S17N and D119N.

Ras-targeted cancer treatments

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Reovirus was noted to be a potential cancer therapeutic when studies suggested it reproduces well in certain cancer cell lines. It replicates specifically in cells that have an activated Ras pathway (a cellular signaling pathway that is involved in cell growth and differentiation).[27] Reovirus replicates in and eventually kills Ras-activated tumour cells and as cell death occurs, progeny virus particles are free to infect surrounding cancer cells. This cycle of infection, replication and cell death is believed to be repeated until all tumour cells carrying an activated Ras pathway are destroyed.[citation needed]

Another tumor-lysing virus that specifically targets tumor cells with an activated Ras pathway is a type II herpes simplex virus (HSV-2) based agent, designated FusOn-H2.[28] Activating mutations of the Ras protein and upstream elements of the Ras protein may play a role in more than two-thirds of all human cancers, including most metastatic disease. Reolysin, a formulation of reovirus, and FusOn-H2 are currently in clinical trials or under development for the treatment of various cancers.[29] In addition, a treatment based on siRNA anti-mutated K-RAS (G12D) called siG12D LODER is currently in clinical trials for the treatment of locally advanced pancreatic cancer (NCT01188785, NCT01676259).[30]

In glioblastoma mouse models SHP2 levels were heightened in cancerous brain cells. Inhibiting SHP2 in turn inhibited Ras dephosphorylation. This reduced tumor sizes and accompanying rise in survival rates.[31][32]

Other strategies have attempted to manipulate the regulation of the above-mentioned localization of Ras. Farnesyltransferase inhibitors have been developed to stop the farnesylation of Ras and therefore weaken its affinity to membranes.[2] Other inhibitors are targeting the palmitoylation cycle of Ras through inhibiting depalmitoylation by acyl-protein thioesterases, potentially leading to a destabilization of the Ras cycle.[33]

A novel inhibitor finding strategy for mutated Ras molecules was described in.[34] The Ras mutations in the 12th residue position inhibit the bound of the regulatory GAP molecule to the mutated Ras, causing uncontrolled cell growth. The novel strategy proposes finding small glue molecules, which attach the mutated Ras to the GAP, prohibiting uncontrolled cell growth and restoring the normal function. For this goal a theoretical Ras-GAP conformation was designed with a several Å gap between the molecules, and a high-throughput in silico docking was performed for finding gluing agents. As a proof of concept, two novel molecules were described with satisfying biological activity.

In other species

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In most of the cell types of most species, most Ras is the GDP type. This is true for Xenopus oocytes and mouse fibroblasts.[35]

Xenopus laevis

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As mentioned above most X. oocyte Ras is the GDP conjugate. Mammal Ras induces meiosis in X. laevis oocytes almost certainly by potentiating insulin-induced meiosis, but not progesterone-induced. Protein synthesis does not seem to be a part of this step. Injection increases synthesis of diacylglycerol from phosphatidylcholine. Some meiosis effects are antagonized by rap1 (and by a Ras modified to dock incorrectly). Both rap1 and the modified Ras are co-antagonists with p120Ras GAP in this pathway.[35]

Drosophila melanogaster

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Expressed in all tissues of Drosophila melanogaster but mostly in neural cells. Overexpression is somewhat lethal and, during development, produces eye and wing abnormalities. (This parallels - and may be the reason for - similar abnormalities due to mutated receptor tyrosine kinases.) The D. genes for rases in mammals produce abnormalities.[35]

Aplysia

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Most expression in Aplysia spp. is in neural cells.[35]

Caenorhabditis elegans

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The gene in C. elegans is let 60. Also appears to play a role in receptor tyrosine kinase formation in this model. Overexpression yields a multivulval development due to its involvement in that region's normal development; overexpression in effector sites in lethal.[35]

Dictyostelium discoideum

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Essential in Dictyostelium discoideum. This is evidenced by severe developmental failure in deficient ras expression and by significant impairment of various life activities when artificially expressed, such as: increased concentration of inositol phosphates; likely reduction of cAMP binding to chemotaxis receptors; and that is likely the reason cGMP synthesis is impaired. Adenylate cyclase activity is unaffected by ras.[35]

References

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  1. ^ Goodsell DS (1999). "The molecular perspective: the ras oncogene". The Oncologist. 4 (3): 263–4. doi:10.1634/theoncologist.4-3-263. PMID 10394594.
  2. ^ a b Downward J (January 2003). "Targeting RAS signalling pathways in cancer therapy". Nature Reviews. Cancer. 3 (1): 11–22. doi:10.1038/nrc969. PMID 12509763. S2CID 43074411.
  3. ^ a b Malumbres M, Barbacid M (June 2003). "RAS oncogenes: the first 30 years". Nature Reviews. Cancer. 3 (6): 459–65. doi:10.1038/nrc1097. PMID 12778136. S2CID 27928171.
  4. ^ Chang EH, Gonda MA, Ellis RW, Scolnick EM, Lowy DR (August 1982). "Human genome contains four genes homologous to transforming genes of Harvey and Kirsten murine sarcoma viruses". Proceedings of the National Academy of Sciences of the United States of America. 79 (16): 4848–52. Bibcode:1982PNAS...79.4848C. doi:10.1073/pnas.79.16.4848. PMC 346782. PMID 6289320.
  5. ^ Harvey JJ (December 1964). "An unidentified virus which causes the rapid production of tumours in mice". Nature. 204 (4963): 1104–5. Bibcode:1964Natur.204.1104H. doi:10.1038/2041104b0. PMID 14243400. S2CID 4144311.
  6. ^ Kirsten WH, Schauf V, McCoy J (1970). "Properties of a murine sarcoma virus". Bibliotheca Haematologica. International Symposium on Comparative Leukemia Research. 36 (36): 246–9. doi:10.1159/000391714. ISBN 978-3-8055-1160-5. PMID 5538357.
  7. ^ Cooper GM (August 1982). "Cellular transforming genes". Science. 217 (4562): 801–6. Bibcode:1982Sci...217..801C. doi:10.1126/science.6285471. PMID 6285471. S2CID 5807661.
  8. ^ Santos E, Tronick SR, Aaronson SA, Pulciani S, Barbacid M (July 1982). "T24 human bladder carcinoma oncogene is an activated form of the normal human homologue of BALB- and Harvey-MSV transforming genes". Nature. 298 (5872): 343–7. Bibcode:1982Natur.298..343S. doi:10.1038/298343a0. PMID 6283384. S2CID 37033023.
  9. ^ Parada LF, Tabin CJ, Shih C, Weinberg RA (June 1982). "Human EJ bladder carcinoma oncogene is homologue of Harvey sarcoma virus ras gene". Nature. 297 (5866): 474–8. Bibcode:1982Natur.297..474P. doi:10.1038/297474a0. PMID 6283357. S2CID 4338225.
  10. ^ Taparowsky E, Suard Y, Fasano O, Shimizu K, Goldfarb M, Wigler M (December 1982). "Activation of the T24 bladder carcinoma transforming gene is linked to a single amino acid change". Nature. 300 (5894): 762–5. Bibcode:1982Natur.300..762T. doi:10.1038/300762a0. PMID 7177195. S2CID 34179063.
  11. ^ Marshall CJ, Hall A, Weiss RA (September 1982). "A transforming gene present in human sarcoma cell lines". Nature. 299 (5879): 171–3. Bibcode:1982Natur.299..171M. doi:10.1038/299171a0. PMID 6287287. S2CID 4342747.
  12. ^ Hall A, Marshall CJ, Spurr NK, Weiss RA (1983). "Identification of transforming gene in two human sarcoma cell lines as a new member of the ras gene family located on chromosome 1". Nature. 303 (5916): 396–400. Bibcode:1983Natur.303..396H. doi:10.1038/303396a0. PMID 6304521. S2CID 4372475.
  13. ^ Shimizu K, Goldfarb M, Perucho M, Wigler M (January 1983). "Isolation and preliminary characterization of the transforming gene of a human neuroblastoma cell line". Proceedings of the National Academy of Sciences of the United States of America. 80 (2): 383–7. Bibcode:1983PNAS...80..383S. doi:10.1073/pnas.80.2.383. PMC 393381. PMID 6300838.
  14. ^ a b Vetter IR, Wittinghofer A (November 2001). "The guanine nucleotide-binding switch in three dimensions". Science. 294 (5545): 1299–304. Bibcode:2001Sci...294.1299V. doi:10.1126/science.1062023. PMID 11701921. S2CID 6636339.
  15. ^ Parker MI, Meyer JE, Golemis EA, Dunbrack RL (5 July 2022). "Delineating the RAS Conformational Landscape". Cancer Research. 82 (13): 2485–2498. doi:10.1158/0008-5472.CAN-22-0804. PMC 9256797. PMID 35536216. Retrieved 11 October 2022.
  16. ^ a b c Lodish H, Berk A, Zipursky SL, Matsudaira P, Baltimore D, Darnell J (2000). "Chapter 25, Cancer". Molecular cell biology (4th ed.). San Francisco: W.H. Freeman. ISBN 0-7167-3706-X.
  17. ^ Pal DS, Banerjee T, Lin Y, de Trogoff F, Borleis J, Iglesias PA, Devreotes PN (July 2023). "Actuation of single downstream nodes in growth factor network steers immune cell migration". Developmental Cell. 58 (13): 1170–1188.e7. doi:10.1016/j.devcel.2023.04.019. ISSN 1534-5807. PMC 10524337. PMID 37220748.
  18. ^ Lin Y, Pal DS, Banerjee P, Banerjee T, Qin G, Deng Y, Borleis J, Iglesias PA, Devreotes PN (2024-07-01). "Ras suppression potentiates rear actomyosin contractility-driven cell polarization and migration". Nature Cell Biology: 1–15. doi:10.1038/s41556-024-01453-4. ISSN 1476-4679.
  19. ^ Rocks O, Peyker A, Bastiaens PI (August 2006). "Spatio-temporal segregation of Ras signals: one ship, three anchors, many harbors". Current Opinion in Cell Biology. 18 (4): 351–7. doi:10.1016/j.ceb.2006.06.007. PMID 16781855.
  20. ^ a b Bos JL (September 1989). "ras oncogenes in human cancer: a review". Cancer Research. 49 (17): 4682–9. PMID 2547513.
  21. ^ Wennerberg K, Rossman KL, Der CJ (March 2005). "The Ras superfamily at a glance". Journal of Cell Science. 118 (Pt 5): 843–6. doi:10.1242/jcs.01660. PMID 15731001. S2CID 40171018.
  22. ^ Robbins and Cotran (2010). Pathologic Basis of Disease 8th ed. p. 282.
  23. ^ Rotblat B, Ehrlich M, Haklai R, Kloog Y (2008). "The Ras inhibitor farnesylthiosalicylic acid (Salirasib) disrupts the spatiotemporal localization of active Ras: a potential treatment for cancer". Small GTPases in Disease, Part B. Methods in Enzymology. Vol. 439. pp. 467–89. doi:10.1016/S0076-6879(07)00432-6. ISBN 978-0-12-374311-4. PMID 18374183.
  24. ^ Blum R, Jacob-Hirsch J, Amariglio N, Rechavi G, Kloog Y (February 2005). "Ras inhibition in glioblastoma down-regulates hypoxia-inducible factor-1alpha, causing glycolysis shutdown and cell death". Cancer Research. 65 (3): 999–1006. doi:10.1158/0008-5472.999.65.3. PMID 15705901. S2CID 21694752.
  25. ^ Reuter CW, Morgan MA, Bergmann L (September 2000). "Targeting the Ras signaling pathway: a rational, mechanism-based treatment for hematologic malignancies?". Blood. 96 (5): 1655–69. doi:10.1182/blood.V96.5.1655. PMID 10961860.
  26. ^ "Omim - Neuroblastoma Ras Viral Oncogene Homolog; Nras". Archived from the original on 2019-03-06. Retrieved 2017-09-10.
  27. ^ Lal R, Harris D, Postel-Vinay S, de Bono J (October 2009). "Reovirus: Rationale and clinical trial update". Current Opinion in Molecular Therapeutics. 11 (5): 532–9. PMID 19806501.
  28. ^ Fu X, Tao L, Cai R, Prigge J, Zhang X (May 2006). "A mutant type 2 herpes simplex virus deleted for the protein kinase domain of the ICP10 gene is a potent oncolytic virus". Molecular Therapy. 13 (5): 882–90. doi:10.1016/j.ymthe.2006.02.007. PMID 16569513.
  29. ^ Thirukkumaran C, Morris DG (2009). "Oncolytic viral therapy using reovirus". Gene Therapy of Cancer. Methods in Molecular Biology. Vol. 542. pp. 607–34. doi:10.1007/978-1-59745-561-9_31. ISBN 978-1-934115-85-5. PMID 19565924.
  30. ^ "ClinicalTrials.gov".
  31. ^ Bunda S, Burrell K, Heir P, Zeng L, Alamsahebpour A, Kano Y, Raught B, Zhang ZY, Zadeh G, Ohh M (November 2015). "Inhibition of SHP2-mediated dephosphorylation of Ras suppresses oncogenesis". Nature Communications. 6: 8859. Bibcode:2015NatCo...6.8859B. doi:10.1038/ncomms9859. PMC 4674766. PMID 26617336.
  32. ^ Taub B (2015-12-03). "Scientists Find Way To Deactivate Most Common Cancer-Causing Protein". IFLScience. Retrieved 2016-02-20.
  33. ^ Chavda B, Arnott JA, Planey SL (September 2014). "Targeting protein palmitoylation: selective inhibitors and implications in disease". Expert Opinion on Drug Discovery. 9 (9): 1005–19. doi:10.1517/17460441.2014.933802. PMID 24967607. S2CID 207494086.
  34. ^ Ranđelović I, Nyíri K, Koppány G, Baranyi M, Tóvári J, Kigyós A, Tímár J, Vértessy BG, Grolmusz V (February 2024). "Gluing GAP to RAS Mutants: A New Approach to an Old Problem in Cancer Drug Development". International Journal of Molecular Sciences. 25 (5): 2572. arXiv:2312.05791. doi:10.3390/ijms25052572. PMC 10932042. PMID 38473821.
  35. ^ a b c d e f Bollag G, McCormick F (1991). "Regulators and effectors of ras proteins". Annual Review of Cell Biology. 7 (1). Annual Reviews: 601–32. doi:10.1146/annurev.cb.07.110191.003125. PMID 1667084.

Further reading

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