Somatic Mutations Lead to an Oncogenic Deletion of Met in Lung Cancer

Kong-Beltran, Monica; Seshagiri, Somasekar; Zha, Jiping; Zhu, Wenjing; Bhawe, Kaumudi; Mendoza, Nerissa; Holcomb, Thomas; Pujara, Kanan; Stinson, Jeremy; Fu, Ling; Severin, Christophe; Rangell, Linda; Schwall, Ralph; Amler, Lukas C.; Wickramasinghe, Dineli; Yauch, Robert L.

doi:10.1158/0008-5472.can-05-2749

Cited by 411 publications

(395 citation statements)

References 48 publications

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“…Accordingly, increased c-MET expression has been observed in metastatic melanoma (Natali et al 1993), and copy number gain of the c-MET locus at 7q33-qter seems to be a late event in melanoma progression (Wiltshire et al 1995;Bastian et al 1998). However, similar to EGFR above, neither focal MET amplifications nor activating MET point mutations have been detected in melanoma, although both have been observed in other human cancers Schmidt et al 1997;Kong-Beltran et al 2006;Smolen et al 2006). However, several lines of experimental and functional evidence support a causal role for MET signaling in human melanoma.…”

Section: Receptor Tyrosine Kinase (Rtks) Activationmentioning

confidence: 95%

Malignant melanoma: genetics and therapeutics in the genomic era

2006

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Cell for cell, probably no human cancer is as aggressive as melanoma. It is among a handful of cancers whose dimensions are reported in millimeters. Tumor thickness approaching 4 mm presents a high risk of metastasis, and a diagnosis of metastatic melanoma carries with it an abysmal median survival of 6-9 mo. What features of this malignancy account for such aggressive behavior? Is it the migratory history of its cell of origin or the programmed adaptation of its differentiated progeny to environmental stress, particularly ultraviolet radiation? While the answers to these questions are far from complete, major strides have been made in our understanding of the cellular, molecular, and genetic underpinnings of melanoma. More importantly, these discoveries carry profound implications for the development of therapies focused directly at the molecular engines driving melanoma, suggesting that we may have reached the brink of an unprecedented opportunity to translate basic science into clinical advances. In this review, we attempt to summarize our current understanding of the genetics and biology of this disease, drawing from expanding genomic information and lessons from development and genetically engineered mouse models. In addition, we look forward toward how these new insights will impact on therapeutic options for metastatic melanoma in the near future. The diseaseMelanomas most often arise within epidermal melanocytes of the skin, although they can also derive from noncutaneous melanocytes such as those lining the choroidal layer of the eye, GI and GU mucosal surfaces, or the meninges. Melanoma is also among the more common causes of "metastatic cancer of unknown primary," which may reflect either a propensity to arise in unexpected sites along the neural crest migratory route, or rapid growth of poorly differentiated lesions arising from indolent or unrecognized cutaneous primary lesions. Clinical staging for primary cutaneous melanoma employs measurements of thickness (in millimeters), presence of ulceration, penetration through cutaneous layers, mitotic rate, evidence of "in transit" metastasis, tumor spread to draining lymph nodes, and evidence of distant metastasis. Management issues in melanoma can be classified in terms of prevention, diagnosis, local disease management, and treatment of metastatic disease.In view of the epidemiological and emerging experimental evidence linking melanoma incidence to UV exposure and skin phototype, prevention and screening strategies represent key areas for reduction of disease incidence and severity. For most cutaneous melanomas in the so-called radial growth phase (e.g., thin melanomas), surgical removal affords curative treatment. In contrast, a significant fraction of patients diagnosed with intermediate-thickness (2-4 mm) cutaneous melanoma eventually succumb to recurrence at regional or distant sites.Critical biological questions facing the melanoma research community include: (1) What genetic and environmental factors contribute to and/or modulate risk of melanom...

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Section: Receptor Tyrosine Kinase (Rtks) Activationmentioning

confidence: 95%

Malignant melanoma: genetics and therapeutics in the genomic era

2006

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“…Moreover, it is notable that all three of these mechanisms of MET/MET dysregulation have been documented in non-small cell lung cancer (NSCLC; refs. [19][20][21][22]. Early studies established that MET can be overexpressed or activated [as measured by phosphorylation of the catalytic domain as well as juxtamembrane (JM) domain], or the gene mutated (in the semaphorin or JM domains) and/or amplified in lung cancer.…”

Section: Hfg/met In Lung Cancermentioning

confidence: 99%

“…Using NSCLC tissues and cell lines, we (37) and Kong-Beltran and colleagues (22) functionally characterized tumor-specific somatic intronic MET mutations, which immediately flank exon 14 (22). Exon 14 was found to encode the JM domain and Y1003 residue that serves as the binding site for casitas B-lineage lymphoma (CBL), the E3 ubiquitin ligase that controls MET turnover (22).…”

Section: Met Mutationsmentioning

confidence: 99%

“…Exon 14 was found to encode the JM domain and Y1003 residue that serves as the binding site for casitas B-lineage lymphoma (CBL), the E3 ubiquitin ligase that controls MET turnover (22). In each case of MET exon 14 skipping, confirmed by reverse transcriptase polymerase chain reaction, the result was a decrease in the ubiquitination of MET and consequent delayed receptor downregulation after stimulation with HGF.…”

Section: Met Mutationsmentioning

confidence: 99%

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MET in Lung Cancer: Biomarker Selection Based on Scientific Rationale

Salgia

2017

Molecular Cancer Therapeutics

124

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MET or hepatocyte growth factor (HGF) receptor pathway signaling mediates wound healing and hepatic regeneration, with pivotal roles in embryonic, neuronal, and muscle development. However, dysregulation of MET signaling mediates proliferation, apoptosis, and migration and is implicated in a number of malignancies. In non-small cell lung cancer (NSCLC), aberrant MET signaling can occur through a number of mechanisms that collectively represent a significant proportion of patients. These include MET or HGF protein overexpression, MET gene amplification, MET gene mutation or fusion/rearrangement, or aberrations in downstream signaling or regulatory components. Responses to MET tyrosine kinase inhibitors have been documented in clinical trials in patients with MET-amplified or METoverexpressing NSCLC, and case studies or case series have shown that MET mutation/deletion is a biomarker that is also predictive of response to these agents. However, other recent clinical data have highlighted an urgent need to elucidate optimal biomarkers based on genetic and/or protein diagnostics to correctly identify patients most likely to benefit in ongoing clinical trials of an array of MET-targeted therapies of differing class. The latest advances in the development of MET biomarkers in NSCLC have been reviewed, toward establishing appropriate MET biomarker selection based on a scientific rationale. Mol Cancer Ther; 16(4); 555-65.Ó2017 AACR.

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“…Naturally occurring somatic mutants of the Met receptor, which lead to loss of the Cbl TKB-binding site, have been identified in human lung cancers and, as a consequence, these receptors are poorly ubiquitinated and not targeted for degradation (Kong-Beltran et al, 2006) (Figure 3). In a similar manner, the loss of the direct Cbl TKB-binding site in the CSF-1R (Mancini et al, 2002), as well as the loss of Cbl recruitment to the Kit receptor (Herbst et al, 1995), results in enhanced transforming activity.…”

Section: Loss Of Cbl Ubiquitylation In Oncogenic Rtksmentioning

confidence: 99%

From Tpr-Met to Met, tumorigenesis and tubes

2007

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The receptor for hepatocyte growth factor (HGF)/scatter factor (SF), Met, controls a program of invasive epithelial growth through the coordination of cell proliferation and survival, cell migration and epithelial morphogenesis. This process is important during embryogenesis and for organ regeneration in the adult. However, when deregulated the HGF/SF-Met signaling axis contributes to tumorigenesis and metastasis. Studies on the oncogenic activation of the Met receptor have shed light on the molecular mechanisms underlying the oncogenic activation of receptor tyrosine kinase (RTKs). More than a decade ago, work on the Met related oncogene, Tpr-Met, revealed the mechanism for activation of RTK-derived oncogenes generated following chromosomal translocation. More recently, studies on the mechanisms of downregulation of the Met RTK highlight a role for loss of downregulation in RTK oncogenic activation.

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Somatic Mutations Lead to an Oncogenic Deletion of Met in Lung Cancer

Cited by 411 publications

References 48 publications

Malignant melanoma: genetics and therapeutics in the genomic era

Malignant melanoma: genetics and therapeutics in the genomic era

MET in Lung Cancer: Biomarker Selection Based on Scientific Rationale

From Tpr-Met to Met, tumorigenesis and tubes

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