ROS1

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External IDsGeneCards: [1]
Orthologs
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Proto-oncogene tyrosine-protein kinase ROS is an enzyme that in humans is encoded by the ROS1 gene.[1][2]

Function

This proto-oncogene, highly expressed in a variety of tumor cell lines, belongs to the sevenless subfamily of tyrosine kinase insulin receptor genes. The protein encoded by this gene is a type I integral membrane protein with tyrosine kinase activity. The protein may function as a growth or differentiation factor receptor.[2]

Role in cancer

ROS1 is a receptor tyrosine kinase (encoded by the gene ROS1) with structural similarity to the anaplastic lymphoma kinase (ALK) protein; it is encoded by the c-ros oncogene and was first identified in 1986.[3][4][5][6] The exact role of the ROS1 protein in normal development, as well as its normal physiologic ligand, have not been defined.[4] Nonetheless, as gene rearrangement events involving ROS1 have been described in lung and other cancers, and since such tumors have been found to be remarkably responsive to small molecule tyrosine kinase inhibitors, interest in identifying ROS1 rearrangements as a therapeutic target in cancer has been increasing.[3][7] Recently, the small molecule tyrosine kinase inhibitor, crizotinib, was approved for the treatment of patients with metastatic NSCLC whose tumors are ROS1 -positive.[8]

Gene rearrangements involving the ROS1 gene were first detected in glioblastoma tumors and cell lines.[9][10] In 2007 a ROS1 rearrangement was identified in a cell line derived from a lung adenocarcinoma patient.[11] Since that discovery, multiple studies have demonstrated an incidence of approximately 1% in lung cancers, demonstrated oncogenicity, and showed that inhibition of tumor cells bearing ROS1 gene fusions by crizotinib or other ROS1 tyrosine kinase inhibitors was effective in vitro.[12][13][14] Clinical data supports the use of crizotinib in lung cancer patients with ROS1 gene fusions.[15][16] Preclinical and clinical work suggests multiple potential mechanisms of drug resistance in ROS1 + lung cancer, including kinase domain mutations in ROS1 and bypass signaling via RAS and EGFR.[17][18][19] Although the most preclinical and clinical studies of ROS1 gene fusions have been performed in lung cancer, ROS1 fusions have been detected in multiple other tumor histologies, including ovarian carcinoma, sarcoma, cholangiocarcinomas and others.[20] Crizotinib or other ROS1 inhibitors may be effective in other tumor histologies beyond lung cancer as demonstrated by a patient with an inflammatory myofibroblastic tumor harboring a ROS1 fusion with a dramatic response to crizotinib.[21]

Preclinical findings

From a large-scale survey of tyrosine kinase activity in non-small cell lung cancer (NSCLC), and identified more than 50 distinct tyrosine kinases and over 2500 downstream substrates, with the goal of identifying candidate oncogenes.[22] In a sampling of 96 tissue samples from NSCLC patients, approximately 30% displayed high levels of phosphotyrosine expression; further analysis was conducted to identify highly phosphorylated tyrosine kinases in NSCLC from a panel of 41 NSCLC cell lines, and 150 patient samples.[22] Among the top 20 receptor tyrosine kinases identified in this analysis, 15 were identified in both cell lines and tumors, and among these were both ALK and [22] These initial findings paved the way for more expansive analyses of ROS1 kinase fusions in NSCLC and other cancers.

Fusion prevalence

In patients with NSCLC, approximately 2% are positive for a ROS1 gene rearrangement, and these rearrangements are mutually exclusive of ALK rearrangement.[23][unreliable medical source] ROS1 fusion-positive patients tend to be younger, with a median age of 49.8 years, and never-smokers, with a diagnosis of adenocarcinoma. There is a higher representation of Asian ethnicity and patients with Stage IV disease.[23] ROS1 rearrangements are estimated to be roughly half as common as ALK-rearranged NSCLCs. Similar to ALK-rearranged, ROS1-rearranged NSCLC have younger age of onset and a non-smoking history.[23] A benefit of a small-molecule ALK, ROS1 , and cMET inhibitor, crizotinib, was also shown in this patient group.

ROS1 expression was found in approximately 2% of NSCLC patients, and its expression was limited to those patients with ROS1 gene fusions.[7][unreliable medical source] Similar findings were reported in a separate analysis of 447 NSCLC samples, of which 1.2% were found to be positive for ROS1 rearrangement; this study also confirmed the activity of the ALK/ROS1 /cMET inhibitor crizotinib in ROS1 -positive tumors.[4] ROS1 fusions were also identified in approximately 2% of adenocarcinomas and 1% of glioblastoma samples in an assessment of kinase fusions across different cancers.[24][unreliable medical source]

Table 1: Sampling of ROS1 Rearrangements Observed in NSCLC and Other Cancers. All of the kinase fusions retain the tyrosine kinase domain of ROS1 . List is not exhaustive. (Adapted from Stumpfova 2012).

Cancer Type ROS1 Fusion Gene
NSCLC FIG - ROS1*; SLC34A2 - ROS1*; CD74 - ROS1*; SDC - ROS1*; EZR - ROS1; LRIG3 - ROS1; TPM3 - ROS1
Gastric SLC34A2 - ROS1*
Colorectal SLC34A2 - ROS1*
Spitzoid melanoma TPM3 - ROS1
Cholangiosarcoma FIG - ROS1*
Glioblastoma FIG - ROS1*
Ovarian FIG - ROS1*
Angiosarcoma CEP85L-ROS1

* Multiple variant isoforms observed

CD74; cluster of differentiation 74, long/short isoforms; EZR; ezrin; FIG; fused in glioblastoma; SDC4; LRIG3; leucine-rich repeats and immunoglobulin-like domains 3; SDC; syndecan 4; SLC34A2; solute carrier family 34 (sodium phosphate), member 2; TPM3; tropomyosin 3

As a drug target

Several drugs target ROS1 fusions in cancer, with varying levels of success; most of the drugs to date have been tested only for ROS1-positive non-small cell lung carcinoma (NSCLC).[25] However, some clinical trials (like those for entrectinib, DS-6051b, and TPX-0005) accept patients with ROS1 cancer in any type of solid tumor.

  • Crizotinib is approved for treating metastatic ROS1-positive NSCLC in many countries. In clinical trials, crizotinib was shown to be effective for 70-80% of ROS1+ NSCLC patients, but it does not effectively treat the brain. Some patients have a response that lasts for years.[26] Crizotinib is available to patients with solid tumors other than NSCLC through clinical trials.[27][28]
  • Entrectinib (RXDX-101) is a selective tyrosine kinase inhibitor developed by Ignyta, Inc., with specificity, at low nanomolar concentrations, for all of three Trk proteins (encoded by the three NTRK genes, respectively) as well as the ROS1, and ALK receptor tyrosine kinases. An open label, multicenter, global phase 2 clinical trial called STARTRK-2 started in 2015 to test the drug in patients with ROS1/NTRK/ALK gene rearrangements.[29]
  • Lorlatinib (also known as PF-06463922) was shown in an ongoing Phase 2 clinical trial to be effective in some ROS1+ NSCLC patients, and treats the cancer in the brain as well as the body. Lorlatinib has the potential to overcome certain resistance mutations that develop during treatment with crizotinib.[30]
  • Ceritinib demonstrates clinical activity (including treating the brain) in ROS1+ NSCLC patients who had previously received platinum-based chemotherapy. In preclinical studies, ceritinib is unable to overcome most ROS1 resistance mutations, including ROS1 G2032R. It has more severe side effects than crizotinib for some patients. Ceritinib is US FDA approved for first line treatment of ALK+ metastatic non-small cell lung cancer.[31][32]
  • TPX-0005 preclinical data suggests it is a potent inhibitor of ROS1+ cancer.[33] A Phase I clinical trial opened in March 2017 for patients with advanced solid tumors harboring ALK, ROS1, or NTRK1-3 rearrangements.[34]
  • DS-6051b preclinical data show it is active against ROS1-positive cancers.[30] It is an ongoing clinical trial.[35]
  • Cabozantinib preclinical data has shown the drug might overcome crizotinib resistance in ROS1+ cancer in early studies.[36] However, the required dosage makes the drug difficult to tolerate for many patients. Cabozantinib is US FDA approved for metastatic medullary thyroid cancer (as Cometriq) and renal cell carcinoma (as Cabometyx).

Global ROS1 Initiative

The Global ROS1 Initiative is a worldwide, multi-stakeholder collaboration with a goal of improving patient outcomes and accelerating research for any type of ROS1+ cancer[37]. It is the first such collaboration focused on cancers driven by a single oncogene and was initiated by ROS1+ cancer patients and carers who call themselves "The ROS1ders.";[38] their website tracks targeted therapies, clinical trials, world experts and new developments for ROS1+ cancers[39]. Partners in the Initiative include patient-focused nonprofits Bonnie J. Addario Lung Cancer Foundation and Addario Lung Cancer Medical Institute, clinicians who treat ROS1+ patients, ROS1 researchers, pharmaceutical firms and biotech companies.

References

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  27. Clinical trial number NCT02465060 for "NCI-MATCH: Targeted Therapy Directed by Genetic Testing in Treating Patients With Advanced Refractory Solid Tumors, Lymphomas, or Multiple Myeloma" at ClinicalTrials.gov
  28. Clinical trial number NCT02693535 for "TAPUR: Testing the Use of Food and Drug Administration (FDA) Approved Drugs That Target a Specific Abnormality in a Tumor Gene in People With Advanced Stage Cancer (TAPUR)" at ClinicalTrials.gov
  29. Clinical trial number NCT02568267 for "Basket Study of Entrectinib (RXDX-101) for the Treatment of Patients With Solid Tumors Harboring NTRK 1/2/3 (Trk A/B/C), ROS1, or ALK Gene Rearrangements (Fusions) (STARTRK-2)" at ClinicalTrials.gov
  30. 30.0 30.1 Khotskaya YB, Holla VR, Farago AF, Mills Shaw KR, Meric-Bernstam F, Hong DS (2017). "Targeting TRK family proteins in cancer". Pharmacology & Therapeutics. 173: 58–66. doi:10.1016/j.pharmthera.2017.02.006. PMID 28174090.
  31. Santarpia M, Daffinà MG, D'Aveni A, Marabello G, Liguori A, Giovannetti E, Karachaliou N, Gonzalez Cao M, Rosell R, Altavilla G (2017). "Spotlight on ceritinib in the treatment of ALK+ NSCLC: design, development and place in therapy". Drug Design, Development and Therapy. 11: 2047–2063. doi:10.2147/DDDT.S113500. PMC 5503498. PMID 28740365.
  32. Califano R, Greystoke A, Lal R, Thompson J, Popat S (2017). "Management of ceritinib therapy and adverse events in patients with ALK-rearranged non-small cell lung cancer". Lung Cancer (Amsterdam, Netherlands). 111: 51–58. doi:10.1016/j.lungcan.2017.06.004. PMID 28838397.
  33. "TPX-0005: A Multi-Faceted Approach to Overcoming Clinical Resistances from Current ALK or ROS1 Inhibitor Treatment in Lung Cancer". meeting abstract in Journal of Thoracic Oncology. Retrieved 12 Oct 2017.
  34. Clinical trial number NCT03093116 at ClinicalTrials.gov
  35. Clinical trial number NCT02279433 for "A First-in-human Study to Evaluate the Safety, Tolerability and Pharmacokinetics of DS-6051b" at ClinicalTrials.gov
  36. Katayama R, Kobayashi Y, Friboulet L, Lockerman EL, Koike S, Shaw AT, Engelman JA, Fujita N (2015). "Cabozantinib overcomes crizotinib resistance in ROS1 fusion-positive cancer". Clinical Cancer Research. 21 (1): 166–74. doi:10.1158/1078-0432.CCR-14-1385. PMC 4286456. PMID 25351743.
  37. https://www.lungcancerfoundation.org/patients/ros1
  38. "ROS1+ Cancer Patients Partner to Increase Research". National Cancer Institute. Retrieved 12 Oct 2017.
  39. https://ros1cancer.com/

Further reading

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