Molecular studies in different types of melanoma tumors : correlations to clinical data
Author: Zebary, Abdlsattar
Date: 2013-12-03
Location: Öron-Näsa-Hals föreläsningssalen, Karolinska Universitetssjukhuset, Solna
Time: 13:00
Department: Inst för onkologi-patologi / Dept of Oncology-Pathology
Abstract
Approximately 90% of melanomas arise from skin sites (known as cutaneous malignant melanoma; CMM), whereas the non-cutaneous melanoma (mucosal and ocular melanomas) are rare, accounting for about 10%. Familial melanoma accounts for up to 10% of patients diagnosed with CMM. Both genetics (e.g. CDKN2A and CDK4 germline mutations, as well as polymorphisms in MC1R and other genes) and environmental factors (ultraviolet radiation) contribute to the induction of melanoma. The MAPK and the PI3K are the two most commonly activated signaling cascades in melanomas. Activation of these two pathways occurs frequently through alterations in BRAF, NRAS and KIT oncogenes. The involvement of these oncogenes in common CMM subtypes is well-studied. However, the frequency of mutations in BRAF, NRAS and KIT and also PTEN has not been well-characterized in the other rare melanoma subtypes, at least not in Caucasian populations. The overall aim of this thesis was to better define the molecular genetic alterations of BRAF, NRAS and KIT in different subtypes of melanomas and to correlate the mutation status with the histopathological features of the tumors and with the clinical parameters of the patients.
For the first project, Formalin-fixed paraffin embedded samples of primary familial and sporadic CMMs were collected from eight centers in Europe and Australia. The overall aim was to better define the frequencies of BRAF and NRAS mutations in familial melanoma with and without germline CDKN2A mutations. Overall, 89 tumors from patients with germline CDKN2A mutations, 46 from patients without germline CDKN2A mutations, and 50 sporadic melanomas were analyzed for BRAF exon 15 and NRAS (exon 2) mutations using direct DNA sequencing. The tumors were also evaluated for pERK and pAkt expression by immunohistochemistry. The BRAF and NRAS mutation frequencies detected in familial melanomas were 43% and 11%, respectively. These frequencies did not differ significantly between tumors from germline CDKN2A mutation carriers and non-carriers. The frequency of BRAF mutation (41%) and NRAS mutation (12%) in the sporadic melanomas did not differ significantly from that identified in the familial melanomas. Expression of pERK and pAkt was observed in 65% and 46% of the familial melanomas, respectively. Similar frequencies of pERK and pAkt expressions were observed in the sporadic melanomas.
In the second project, we analyzed a large number of a rare subtype of melanoma; sinonasal mucosal melanoma. In total, 56 primary tumors were screened for mutations in KIT (exons 11, 13 and 17), NRAS (exons 1 and 2) and BRAF exon 15 using direct sequencing. Twelve of the 56 (21%) tumors contained one mutation in these oncogenes; 2 tumors harbored KIT mutations, another 2 harbored BRAF mutations and 8 had NRAS mutations. The mutations were more frequently detected in tumors originated from the paranasal sinuses than from the nasal cavity (p=0.045). Patients with melanoma in the paranasal sinuses had a worse overall survival than patients with melanoma in the nasal cavity (p=0.027).
In the third project, primary and metastatic acral lentiginous melanomas were investigated for mutations in BRAF (exons 11 and 15), NRAS (exons 1 and 2), KIT (exons 9, 11, 13, 17 and 18) and PTEN (exons 1, 3-6 and 10-12) by direct sequencing. The data showed an identical mutation frequency of 15% (13 out of 88) of both KIT and NRAS, whereas BRAF mutations were found in 17% (15 out of 88) of the primary tumors. Of the 25 cases evaluated for PTEN mutations, only one tumor contained a mutation (4%). The BRAF, NRAS and KIT mutation status in 16 metastases was similar to that identified in the matched primaries. In comparison with BRAF wild-type tumors, BRAF mutated tumors were more commonly diagnosed in young individuals (p=0.028) and significantly associated with tumor location on the feet (p=0.039) and female gender (p=0.039). The anatomical site was an independent prognostic factor with better overall survival for patients with tumors on hand or subungual areas than those with tumors on the feet or under toenails (p=0.025).
In the fourth project, we evaluated 124 primary and 76 metastatic (73 were matched metastases) CMMs for BRAFV600E expression by immunohistochemistry using VE1 antibody. Overall, 55% (110 out of 200) tumors displayed a positive homogenous staining. There was a consistency in BRAFV600E staining between the matched primaries and metastatic CMMs. In 28 tumors a discrepancy was observed between the VE1 staining and the mutation analysis methods. Re-analysis of 25 tumors of the discrepant cases by pyrosequencing revealed a new BRAFV600E mutation in three cases, supporting the results seen with VE1 staining. In the remaining 22 tumors the results of the pyrosequencing and the initial mutation methods were similar. Overall sensitivity and specificity with VE1 antibody staining were 97% and 80%, respectively.
For the first project, Formalin-fixed paraffin embedded samples of primary familial and sporadic CMMs were collected from eight centers in Europe and Australia. The overall aim was to better define the frequencies of BRAF and NRAS mutations in familial melanoma with and without germline CDKN2A mutations. Overall, 89 tumors from patients with germline CDKN2A mutations, 46 from patients without germline CDKN2A mutations, and 50 sporadic melanomas were analyzed for BRAF exon 15 and NRAS (exon 2) mutations using direct DNA sequencing. The tumors were also evaluated for pERK and pAkt expression by immunohistochemistry. The BRAF and NRAS mutation frequencies detected in familial melanomas were 43% and 11%, respectively. These frequencies did not differ significantly between tumors from germline CDKN2A mutation carriers and non-carriers. The frequency of BRAF mutation (41%) and NRAS mutation (12%) in the sporadic melanomas did not differ significantly from that identified in the familial melanomas. Expression of pERK and pAkt was observed in 65% and 46% of the familial melanomas, respectively. Similar frequencies of pERK and pAkt expressions were observed in the sporadic melanomas.
In the second project, we analyzed a large number of a rare subtype of melanoma; sinonasal mucosal melanoma. In total, 56 primary tumors were screened for mutations in KIT (exons 11, 13 and 17), NRAS (exons 1 and 2) and BRAF exon 15 using direct sequencing. Twelve of the 56 (21%) tumors contained one mutation in these oncogenes; 2 tumors harbored KIT mutations, another 2 harbored BRAF mutations and 8 had NRAS mutations. The mutations were more frequently detected in tumors originated from the paranasal sinuses than from the nasal cavity (p=0.045). Patients with melanoma in the paranasal sinuses had a worse overall survival than patients with melanoma in the nasal cavity (p=0.027).
In the third project, primary and metastatic acral lentiginous melanomas were investigated for mutations in BRAF (exons 11 and 15), NRAS (exons 1 and 2), KIT (exons 9, 11, 13, 17 and 18) and PTEN (exons 1, 3-6 and 10-12) by direct sequencing. The data showed an identical mutation frequency of 15% (13 out of 88) of both KIT and NRAS, whereas BRAF mutations were found in 17% (15 out of 88) of the primary tumors. Of the 25 cases evaluated for PTEN mutations, only one tumor contained a mutation (4%). The BRAF, NRAS and KIT mutation status in 16 metastases was similar to that identified in the matched primaries. In comparison with BRAF wild-type tumors, BRAF mutated tumors were more commonly diagnosed in young individuals (p=0.028) and significantly associated with tumor location on the feet (p=0.039) and female gender (p=0.039). The anatomical site was an independent prognostic factor with better overall survival for patients with tumors on hand or subungual areas than those with tumors on the feet or under toenails (p=0.025).
In the fourth project, we evaluated 124 primary and 76 metastatic (73 were matched metastases) CMMs for BRAFV600E expression by immunohistochemistry using VE1 antibody. Overall, 55% (110 out of 200) tumors displayed a positive homogenous staining. There was a consistency in BRAFV600E staining between the matched primaries and metastatic CMMs. In 28 tumors a discrepancy was observed between the VE1 staining and the mutation analysis methods. Re-analysis of 25 tumors of the discrepant cases by pyrosequencing revealed a new BRAFV600E mutation in three cases, supporting the results seen with VE1 staining. In the remaining 22 tumors the results of the pyrosequencing and the initial mutation methods were similar. Overall sensitivity and specificity with VE1 antibody staining were 97% and 80%, respectively.
List of papers:
I. Zebary A, Omholt K, van Doorn R, Ghiorzo P, Harbst K, Hertzman Johansson C, Höiom V, Jonsson G, Pjanova D, Puig S, Scarra GB, Harland M, Olsson H, Egyhazi Brage S, Palmer J, Kanter-Lewensohn L, Vassilaki I, Hayward NK, Newton-Bishop J, Gruis NA, and Hansson J. Somatic BRAF and NRAS Mutations in Familial Melanomas with Known Germline CDKN2A Status: A GenoMEL Study. J Invest Dermatol. 2013 Jun 14.
Fulltext (DOI)
Pubmed
II. Zebary A*, Jangard M*, Omholt K, Ragnarsson-Olding B, and Hansson J. KIT, NRAS and BRAF mutations in sinonasal mucosal melanoma: a study of 56 cases. Br J Cancer. 2013 Aug 6; 109:559-64.
Fulltext (DOI)
Pubmed
View record in Web of Science®
III. Zebary A, Omholt K, Vassilaki I, Höiom V, Lindén D, Viberg L, Kanter-Lewensohn L, Hertzman Johansson C, and Hansson J. KIT, NRAS, BRAF and PTEN mutations in a sample of Swedish patients with acral lentiginous melanoma. J Dermatol Sci. 2013 Aug 8; 72:284–289.
Fulltext (DOI)
Pubmed
IV. Eriksson H*, Zebary A*, Vassilaki I, Omholt K, Ghaderi M, and Hansson J. BRAFV600E protein expression in primary cutaneous melanoma and paired metastases. [Submitted]
I. Zebary A, Omholt K, van Doorn R, Ghiorzo P, Harbst K, Hertzman Johansson C, Höiom V, Jonsson G, Pjanova D, Puig S, Scarra GB, Harland M, Olsson H, Egyhazi Brage S, Palmer J, Kanter-Lewensohn L, Vassilaki I, Hayward NK, Newton-Bishop J, Gruis NA, and Hansson J. Somatic BRAF and NRAS Mutations in Familial Melanomas with Known Germline CDKN2A Status: A GenoMEL Study. J Invest Dermatol. 2013 Jun 14.
Fulltext (DOI)
Pubmed
II. Zebary A*, Jangard M*, Omholt K, Ragnarsson-Olding B, and Hansson J. KIT, NRAS and BRAF mutations in sinonasal mucosal melanoma: a study of 56 cases. Br J Cancer. 2013 Aug 6; 109:559-64.
Fulltext (DOI)
Pubmed
View record in Web of Science®
III. Zebary A, Omholt K, Vassilaki I, Höiom V, Lindén D, Viberg L, Kanter-Lewensohn L, Hertzman Johansson C, and Hansson J. KIT, NRAS, BRAF and PTEN mutations in a sample of Swedish patients with acral lentiginous melanoma. J Dermatol Sci. 2013 Aug 8; 72:284–289.
Fulltext (DOI)
Pubmed
IV. Eriksson H*, Zebary A*, Vassilaki I, Omholt K, Ghaderi M, and Hansson J. BRAFV600E protein expression in primary cutaneous melanoma and paired metastases. [Submitted]
Institution: Karolinska Institutet
Supervisor: Hansson, Johan
Issue date: 2013-11-12
Rights:
Publication year: 2013
ISBN: 978-91-7549-371-8
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