KRAS

For other uses, see Kras.
KRAS
Available structures
PDBOrtholog search: PDBe RCSB
Identifiers
AliasesKRAS, C-K-RAS, CFC2, K-RAS2A, K-RAS2B, K-RAS4A, K-RAS4B, KI-RAS, KRAS1, KRAS2, NS, NS3, RALD, RASK2, K-ras, KRAS proto-oncogene, GTPase, c-Ki-ras2, OES, c-Ki-ras, K-Ras 2, 'C-K-RAS, K-Ras, Kirsten RAt Sarcoma virus, Kirsten Rat Sarcoma virus
External IDsOMIM: 190070; MGI: 96680; HomoloGene: 37990; GeneCards: KRAS; OMA:KRAS - orthologs
Orthologs
SpeciesHumanMouse
Entrez

3845

16653

Ensembl

ENSG00000133703

ENSMUSG00000030265

UniProt

P01116

P32883

RefSeq (mRNA)

NM_004985
NM_033360
NM_001369786
NM_001369787

NM_021284

RefSeq (protein)

NP_004976
NP_203524
NP_001356715
NP_001356716
NP_004976.2

Location (UCSC)Chr 12: 25.21 – 25.25 MbChr 6: 145.16 – 145.2 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

KRAS (Kirsten rat sarcoma virus) is a gene that provides instructions for making a protein called K-Ras, a part of the RAS/MAPK pathway. The protein relays signals from outside the cell to the cell's nucleus. These signals instruct the cell to grow and divide (proliferate) or to mature and take on specialized functions (differentiate). It is called KRAS because it was first identified as a viral oncogene in the Kirsten RAt Sarcoma virus.[5] The oncogene identified was derived from a cellular genome, so KRAS, when found in a cellular genome, is called a proto-oncogene.

The K-Ras protein is a GTPase, a class of enzymes which convert the nucleotide guanosine triphosphate (GTP) into guanosine diphosphate (GDP). In this way the K-Ras protein acts like a switch that is turned on and off by the GTP and GDP molecules. To transmit signals, it must be turned on by attaching (binding) to a molecule of GTP. The K-Ras protein is turned off (inactivated) when it converts the GTP to GDP. When the protein is bound to GDP, it does not relay signals to the nucleus.

The gene product of KRAS, the K-Ras protein, was first found as a p21 GTPase.[6][7] Like other members of the ras subfamily of GTPases, the K-Ras protein is an early player in many signal transduction pathways. K-Ras is usually tethered to cell membranes because of the presence of an isoprene group on its C-terminus. There are two protein products of the KRAS gene in mammalian cells that result from the use of alternative exon 4 (exon 4A and 4B respectively): K-Ras4A and K-Ras4B. These proteins have different structures in their C-terminal region and use different mechanisms to localize to cellular membranes, including the plasma membrane.[8]

Function

KRAS acts as a molecular on/off switch, using protein dynamics. Once it is allosterically activated, it recruits and activates proteins necessary for the propagation of growth factors, as well as other cell signaling receptors like c-Raf and PI 3-kinase. KRAS upregulates the GLUT1 glucose transporter, thereby contributing to the Warburg effect in cancer cells.[9] KRAS binds to GTP in its active state. It also possesses an intrinsic enzymatic activity which cleaves the terminal phosphate of the nucleotide, converting it to GDP. Upon conversion of GTP to GDP, KRAS is deactivated. The rate of conversion is usually slow, but can be increased dramatically by an accessory protein of the GTPase-activating protein (GAP) class, for example RasGAP.[citation needed] In turn, KRAS can bind to proteins of the Guanine Nucleotide Exchange Factor (GEF) class (such as SOS1), which forces the release of bound nucleotide (GDP). Subsequently, KRAS binds GTP present in the cytosol and the GEF is released from ras-GTP.

Other members of the Ras family include: HRAS and NRAS. These proteins all are regulated in the same manner and appear to differ in their sites of action within the cell.[citation needed]

Clinical significance when mutated

This proto-oncogene is a Kirsten ras oncogene homolog from the mammalian Ras gene family. A single amino acid substitution, and in particular a single nucleotide substitution, is responsible for an activating mutation. The transforming protein that results is implicated in various malignancies, including lung adenocarcinoma,[10] mucinous adenoma, ductal carcinoma of the pancreas and colorectal cancer.[11][12]

Several germline KRAS mutations have been found to be associated with Noonan syndrome[13] and cardio-facio-cutaneous syndrome.[14]

Somatic KRAS mutations are found at high rates in leukemias, colorectal cancer,[15] pancreatic cancer[16] and lung cancer.[17]

Colorectal cancer

The impact of KRAS mutations is heavily dependent on the order of mutations. Primary KRAS mutations generally lead to a self-limiting hyperplastic or borderline lesion, but if they occur after a previous APC mutation it often progresses to cancer.[18] KRAS mutations are more commonly observed in cecal cancers than colorectal cancers located in any other places from ascending colon to rectum.[19][20]

As of 2006, KRAS mutation was predictive of a very poor response to panitumumab (Vectibix) and cetuximab (Erbitux) therapy in colorectal cancer.[21]

As of 2008, the most reliable way to predict whether a colorectal cancer patient will respond to one of the EGFR-inhibiting drugs was to test for certain “activating” mutations in the gene that encodes KRAS, which occurs in 30%–50% of colorectal cancers. Studies show patients whose tumors express the mutated version of the KRAS gene will not respond to cetuximab or panitumumab.[22]

As of 2009, although presence of the wild-type (or normal) KRAS gene does not guarantee that these drugs will work, a number of large studies[23][24] had shown that cetuximab had efficacy in mCRC patients with KRAS wild-type tumors. In the Phase III CRYSTAL study, published in 2009, patients with the wild-type KRAS gene treated with Erbitux plus chemotherapy showed a response rate of up to 59% compared to those treated with chemotherapy alone. Patients with the KRAS wild-type gene also showed a 32% decreased risk of disease progression compared to patients receiving chemotherapy alone.[24]

As of 2012, it was known that emergence of KRAS mutations was a frequent driver of acquired resistance to cetuximab anti-EGFR therapy in colorectal cancers. The emergence of KRAS mutant clones can be detected non-invasively[how?] months before radiographic progression. It suggests to perform an early initiation of a MEK inhibitor as a rational strategy for delaying or reversing drug resistance.[25]

KRAS amplification

KRAS gene can also be amplified in colorectal cancer and tumors harboring this genetic lesion are not responsive to EGFR inhibitors. Although KRAS amplification is infrequent in colorectal cancer, as of 2013 it was hypothesized to be responsible for precluding response to anti-EGFR treatment in some patients.[26] As of 2015 amplification of wild-type Kras has also been observed in ovarian,[27] gastric, uterine, and lung cancers.[28]

Lung cancer

Whether a patient is positive or negative for a mutation in the epidermal growth factor receptor (EGFR) will predict how patients will respond to certain EGFR antagonists such as erlotinib (Tarceva) or gefitinib (Iressa). Patients who harbor an EGFR mutation have a 60% response rate to erlotinib. However, the mutation of KRAS and EGFR are generally mutually exclusive.[29][30][31] Lung cancer patients who are positive for KRAS mutation (and the EGFR status would be wild type) have a low response rate to erlotinib or gefitinib estimated at 5% or less.[29]

Different types of data including mutation status and gene expression did not have a significant prognostic power.[32] No correlation to survival was observed in 72% of all studies with KRAS sequencing performed in non-small cell lung cancer (NSCLC).[32] However, KRAS mutations can not only affect the gene itself and the expression of the corresponding protein, but can also influence the expression of other downstream genes involved in crucial pathways regulating cell growth, differentiation and apoptosis. The different expression of these genes in KRAS-mutant tumors might have a more prominent role in affecting patient's clinical outcomes.[32]

A 2008 paper published in Cancer Research concluded that the in vivo administration of the compound oncrasin-1 "suppressed the growth of K-ras mutant human lung tumor xenografts by >70% and prolonged the survival of nude mice bearing these tumors, without causing detectable toxicity", and that the "results indicate that oncrasin-1 or its active analogues could be a novel class of anticancer agents which effectively kill K-Ras mutant cancer cells."[33]

Pancreatic cancer

Over 90% of pancreatic ductal adenocarcinomas (PDACs) have a KRAS mutation.[34][35][36] There is one approved drug, sotorasib, that targets the KRAS G12C mutation, but only ~1% of PDACs have this mutation.[34] Another KRAS inhibitor, MRTX1133 targets G12D mutation which is present in over 40% of PDACs[37][38] is currently in clinical trials to treat solid tumors including pancreatic adenocarcinoma.[39]

KRAS testing

In July 2009, the US Food and Drug Administration (FDA) updated the labels of two anti-EGFR monoclonal antibody drugs indicated for treatment of metastatic colorectal cancer, panitumumab (Vectibix) and cetuximab (Erbitux), to include information about KRAS mutations.[40]

In 2012, the FDA cleared a genetic test by QIAGEN named therascreen KRAS test, designed to detect the presence of seven mutations in the KRAS gene in colorectal cancer cells. This test aids physicians in identifying patients with metastatic colorectal cancer for treatment with Erbitux. The presence of KRAS mutations in colorectal cancer tissue indicates that the patient may not benefit from treatment with Erbitux. If the test result indicates that the KRAS mutations are absent in the colorectal cancer cells, then the patient may be considered for treatment with Erbitux.[41]

As a therapeutic target

As of 2014, driver mutations in KRAS were known to underlie the pathogenesis of up to 20% of human cancers.[42] Hence KRAS is an attractive drug target, but as of 2018 lack of obvious binding sites had hindered pharmaceutical development.[43] One potential drug interaction site is where GTP/GDP binds, but due to the extraordinarily high affinity of GTP/GDP for this site, it appeared unlikely as of 2018 that drug-like small molecule inhibitors could compete with GTP/GDP binding. Other than where GTP/GDP binds, there are no obvious high affinity binding sites for small molecules.[44]

G12C mutation

Surface model of a KRASG12C protein, showing a GDP molecule (orange) in its high-affinity binding site and the covalent inhibitor sotorasib (aqua) occupying an adjacent "cryptic" binding pocket. Sotorasib forms an irreversible bond with a cysteine residue and disrupts function of the mutated protein. From PDB: 6OIM​.[45][46]

One fairly frequent driver mutation is KRASG12C which is adjacent a shallow binding site. As of 2019, this allowed the development of electrophilic KRAS inhibitors that can form irreversible covalent bonds with nucleophilic sulfur atom of Cys-12 and hence selectively target KRASG12C and leave wild-type KRAS untouched.[47]

In 2021, the U.S. FDA approved one KRASG12C mutant covalent inhibitor, sotorasib (AMG 510, Amgen) for the treatment of non-small cell lung cancer (NSCLC), the first KRAS inhibitor to reach the market and enter clinical use.[48][49]

A second is adagrasib (MRTX-849, Mirati Therapeutics)[50][51] while JNJ-74699157 (also known as ARS-3248, Wellspring Biosciences/Janssen) has received an investigational new drug (IND) approval to start clinical trials.[52] An antisense oligonucleotide (ASO) targeting KRAS, AZD4785 (AstraZeneca/Ionis Therapeutics), completed a phase I study[53] but in 2019 was discontinued from further development because of insufficient knockdown of the target.[54]

A phase Ia/Ib dose escalation trial of the oral selective KRAS G12C inhibitor divarasib was published in 2023, where the drug was tested in non-small cell lung cancer, colorectal cancer, and other solid tumors with KRAS G12C mutations.[55] It continues in phase I and II studies for several cancer types as of August 2023.[56][57][58][59]

G12D mutation

The most common KRAS mutation is G12D which is estimated to be present in up to 37% pancreatic cancers and over 12% of colorectal cancers. Normally amino acid position 12 of the KRAS protein is occupied by glycine but in G12D it is occupied by aspartic acid.[60]

As of 2023, there are no commercial drug candidates targeting the KRAS G12D mutation in the clinical phase of development.

A novel inhibitor finding strategy for mutated G12D KRAS molecules was described in.[61] The KRAS mutations in the 12th residue position inhibit the bound of the regulatory GAP molecule to the mutated KRAS, causing uncontrolled cell growth. The novel strategy proposes finding small glue molecules, which attach the mutated KRAS to the GAP, prohibiting uncontrolled cell growth and restoring the normal function. For this goal a theoretical KRAS-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.

As of 2021, there were a number of drug candidates in preclinical stages of development targeting the KRAS G12D mutation. Mirati therapeutics has stated it was seeking investigational new drug (IND) approval in H1:2021 to start clinical trials.[62] As of 2022 Revolution Medicines was exploring a small molecule therapy and reported anti-tumor activity in KRAS-G12D mutant tumor models.[63]

In 2021, the first clinical trial of a gene therapy targeting KRAS G12D was recruiting patients, sponsored by the National Cancer Institute.[64]

In June 2022, a case report was published about a 71-year-old woman with metastatic pancreatic cancer after extensive treatment (Whipple Surgery, radiation and multiple agent chemotherapy) who received a single infusion of her blood with engineered T cells with 2 genes encoding T cell receptors, directed to both the G12D mutation and an HLA allele (HLA-C*08:02). Her tumor regressed persistently. But another similarly treated patient died from the cancer.[65]

Interactions

KRAS has been shown to interact with:

References

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Further reading

  • Kahn S, Yamamoto F, Almoguera C, Winter E, Forrester K, Jordano J, et al. (1987). "The c-K-ras gene and human cancer (review)". Anticancer Research. 7 (4A): 639–652. PMID 3310850.
  • Yamamoto F, Nakano H, Neville C, Perucho M (1985). "Structure and mechanisms of activation of c-K-ras oncogenes in human lung cancer". Progress in Medical Virology. 32: 101–114. PMID 3895297.
  • Porta M, Ayude D, Alguacil J, Jariod M (February 2003). "Exploring environmental causes of altered ras effects: fragmentation plus integration?". Molecular Carcinogenesis. 36 (2): 45–52. doi:10.1002/mc.10093. PMID 12557259. S2CID 23937262.
  • Smakman N, Borel Rinkes IH, Voest EE, Kranenburg O (November 2005). "Control of colorectal metastasis formation by K-Ras". Biochimica et Biophysica Acta (BBA) - Reviews on Cancer. 1756 (2): 103–114. doi:10.1016/j.bbcan.2005.07.001. PMID 16098678.
  • Castagnola P, Giaretti W (November 2005). "Mutant KRAS, chromosomal instability and prognosis in colorectal cancer". Biochimica et Biophysica Acta (BBA) - Reviews on Cancer. 1756 (2): 115–125. doi:10.1016/j.bbcan.2005.06.003. PMID 16112461.
  • Deramaudt T, Rustgi AK (November 2005). "Mutant KRAS in the initiation of pancreatic cancer". Biochimica et Biophysica Acta (BBA) - Reviews on Cancer. 1756 (2): 97–101. doi:10.1016/j.bbcan.2005.08.003. PMID 16169155.
  • Pretlow TP, Pretlow TG (November 2005). "Mutant KRAS in aberrant crypt foci (ACF): initiation of colorectal cancer?". Biochimica et Biophysica Acta (BBA) - Reviews on Cancer. 1756 (2): 83–96. doi:10.1016/j.bbcan.2005.06.002. PMID 16219426.
  • Su YH, Wang M, Aiamkitsumrit B, Brenner DE, Block TM (2005). "Detection of a K-ras mutation in urine of patients with colorectal cancer". Cancer Biomarkers. 1 (2–3): 177–182. doi:10.3233/CBM-2005-12-305. PMID 17192038.
  • Domagała P, Hybiak J, Sulżyc-Bielicka V, Cybulski C, Ryś J, Domagała W (November 2012). "KRAS mutation testing in colorectal cancer as an example of the pathologist's role in personalized targeted therapy: a practical approach". Polish Journal of Pathology. 63 (3): 145–164. arXiv:1305.1286. doi:10.5114/PJP.2012.31499. PMID 23161231. S2CID 17666526.

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