Primary Undifferentiated/Dedifferentiated Cutaneous Melanomas: History
Please note this is an old version of this entry, which may differ significantly from the current revision.
Contributor: , , , , , ,

Diagnosing cutaneous melanoma is usually straightforward based on these malignancies’ histopathological and immunohistochemical features. Nevertheless, melanomas can imitate various other neoplasms, sometimes lacking the expression of conventional melanocytic markers and expressing non-melanocytic ones. 

  • cutaneous melanoma
  • dedifferentiated melanoma
  • undifferentiated melanoma

1. Introduction

Cutaneous melanoma is an aggressive malignancy responsible for most deaths caused by skin cancers. However, melanoma is a heterogeneous disease with widely variable clinical, histopathological, immunohistochemical, and molecular features, all of which influence treatment and prognosis. [1]. Cutaneous melanomas can undergo divergent transformation, displaying immunohistochemical and ultrastructural features of other cell lineages such as epithelial cells, fibroblasts, nervous cells, osteocartilaginous cells, smooth muscle, or rhabdomyoblasts [2]. In this respect, Agaimy et al. define undifferentiated melanomas (UM) as melanomas lacking characteristic histopathological and immunohistochemical features (such as S100, MelanA, HMB45, SOX10, and MITF) and dedifferentiated/transdifferentiated melanomas (DM) as melanomas lacking these characteristics but displaying non-melanocytic ones [3]. These tumors are usually present as biphasic neoplasms with conventional melanoma components and heterologous components resembling other malignancies [2]. Divergent differentiation is a well-described phenomenon in metastatic settings [3][4][5][6][7][8][9]. Phenotype switching in metastatic melanomas is a form of cancer cell plasticity and is considered an adaptative mechanism for promoting invasion and resistance to therapy [10][11][12][13]. On the contrary, primary cutaneous melanomas displaying divergent differentiation are sporadic and poorly described in the scientific literature [3][14][15][16][17][18]. Consequently, diagnosing dedifferentiated primary cutaneous melanomas represents a serious challenge, requiring extensive histopathological and immunohistochemical analysis as these dedifferentiated tumors may also present small areas of conventional melanoma [15][17][18]. Furthermore, molecular analysis may help establish the diagnosis by revealing characteristic melanoma mutations [18].

2. General Characteristics of Undifferentiated/Dedifferentiated Melanomas

The terms “undifferentiated melanoma”, “dedifferentiated melanoma”, and “transdifferentiated melanoma” have been inconsistently used to describe melanomas that lack a melanocytic phenotype, at least partially, and may acquire differentiation towards other cell lineages. Undifferentiated melanomas are defined as completely lacking conventional histopathological and immunohistochemical melanocytic differentiation (negative for the five commonly used melanoma markers—MelanA, MiTF, HMB45, S100, and SOX10) and displaying a “vimentin-only” phenotype [19][20][21]. Dedifferentiated/transdifferentiated melanomas are biphasic tumors that show a transition between conventional melanoma components and undifferentiated areas with histopathological and immunohistochemical features of other cell lineages [19][20]. The dedifferentiated component most often resembles atypical fibroxanthoma/undifferentiated pleomorphic sarcoma. Still, it can also bear features of various other entities such as carcinomas, leiomyosarcoma, rhabdomyosarcoma, ganglioneuroblastic tumors, other sarcomas, and spindle cell neoplasms [19][20][22].
These tumors are most often encountered in metastatic lesions following systemic dissemination and divergent transformation of a conventional melanoma [21] and are exceptionally rare in primary settings, either mucosal or cutaneous [19]. Undifferentiated and dedifferentiated primary cutaneous melanomas show a preference for highly sun-damaged skin, such as the head and neck, in elderly individuals and often present as large, ulcerated nodules or plaques [19]. They also tend to have a slight predilection for male patients [19][21][23].
Undifferentiated/dedifferentiated melanomas are usually deeply invasive with a Breslow thickness over 4 mm and display a conventional area that can be either in situ or invasive of various subtypes (superficial spreading, nodular, lentigo maligna, acral lentiginous, or desmoplastic) as well as an undifferentiated/dedifferentiated component that usually represents over 50% of the tumor. The transition between the two components is typically abrupt [19]. Such cases represent important diagnostic challenges, particularly those lacking conventional components such as small biopsy specimens.
While the correct diagnosis of primary cutaneous undifferentiated/dedifferentiated melanoma is crucial to provide the best therapeutic options, the prognosis of these patients does not seem significantly different from a conventional melanoma when adjusted for tumor thickness [24]. Nevertheless, divergent differentiation is most often encountered in metastatic settings, and it seems to be associated with resistance to targeted and immune therapy [25].

3. Histological, Immunohistochemical, and Molecular Features of Primary Cutaneous Undifferentiated/Dedifferentiated Melanomas

Since primary cutaneous melanomas with divergent differentiation are rare, most articles discussing these lesions are case reports. However, in 2021, Ferreira et al. published a more extensive series of 11 cases [23]. They included tumors displaying a biphasic appearance with conventional melanoma areas and dedifferentiated areas lacking expression of S100, SOX10, MelanA, and HMB45. These patients were primarily elderly, with a mean age of 76, and had a slight but insignificant male predilection. The most affected sites were sun-exposed areas such as the head and neck, followed by the extremities. In most cases (7), the dedifferentiated component was represented by atypical fibroxanthoma, while two others displayed rhabdomyosarcomatous differentiation with positive expression of desmin, myogenin, and MyoD1, and the remaining two cases displayed epithelial differentiation with positive expression of AE1/AE3 and MNF116. The diagnosis of atypical fibroxanthoma is one of exclusion as no immunohistochemical marker is entirely specific for this neoplasm, and extensive tests should be performed to rule out other entities. DNA sequencing was performed on seven cases to further evaluate these neoplasms, all of which displayed genetic mutations frequently encountered in melanomas. NF1 mutations were noted in five cases, with four presenting this mutation in both the conventional and the dedifferentiated components. The fifth case displayed this mutation in the dedifferentiated component, while the conventional component was unavailable for analysis due to insufficient material. One case displayed an NRAS mutation in both components, and one showed a BRAF p.V600E mutation in the dedifferentiated area. Finally, non-p.V600E BRAF mutations were found in three of the cases, which also had NF1 mutations [23].
Even rarer than melanomas with atypical fibroxanthoma features are rhabdoid melanoma. Rhabdoid melanomas are often encountered in metastatic sites and are exceptionally rare as primary cutaneous melanomas [26]. Rhabdoid melanomas are defined as melanomas exhibiting large pleomorphic cells with abundant eosinophilic cytoplasm with hyaline inclusions and eccentric nuclei [27]. It must be noted that the term “rhabdoid” describes a morphological feature as these areas not only usually lack conventional melanocytic markers but most often also lack muscle-specific markers, thus failing to exhibit true rhabdomyosarcomatous differentiation [26][27][28]. Such cases may still be challenging to diagnose as they are usually amelanotic and clinically atypical for a melanocytic lesion. Therefore, a comprehensive histopathological examination is required to spot small areas resembling melanoma [27][29]. Cases displaying true rhabdomyosarcomatous differentiation express one or more markers such as desmin, actin, MyoD1, and myogenin while failing to express conventional melanocytic markers in the dedifferentiated area [26][29][30][31][32]
Primary cutaneous melanomas can rarely present osteoid and chondroid areas, sometimes expressing bone-specific markers such as SATB2. Nevertheless, this expression is usually weaker than in osteosarcomas [33]. These tumors tend to occur on acral skin, but various other locations, such as the sun-exposed skin of the face, have been reported [34][35][36]. Local traumatism may trigger these lesions, as various authors have reported a history of trauma at the site of osteo-chondroid melanomas [35]. In this respect, Ali et al. presented the case of a 26-year-old female with melanoma on her index finger with a biphasic neoplasm composed of conventional melanoma and areas of osseous differentiation positive for SATB2 [34]
Cutaneous melanomas can display angiomatoid features in even rarer instances than those discussed above. Fonda-Pascual et al. described such a case, whereby they reported a nodular melanoma arising on the scalp of a 63-year-old woman. The tumor showed an area of tubular structures filled with erythrocytes [37]. However, the immunohistochemical tests were negative for CD31 and D2-40 and positive for S100, SOX9, and HMB45. Further genetic tests revealed a BRAF V600E mutation. Ambrogio et al. also reported a case of an 87-year-old man with a cutaneous melanoma displaying pseudo-angiomatous features [38]. This tumor expressed S100, MelanA, and HMB45 in the differentiated component but not in the area with pseudo-vascular spaces. However, this area lacked expression of vascular markers, and SOX10 was positive in both components.
Apart from the aforementioned dedifferentiated melanomas, a few other rarer possibilities have been cited in the literature, including melanomas expressing macrophage and vascular markers and other markers such as keratins, FLI-1, CEA, calretinin, PAX8, and PAX2 [39]. Aberrant expression of these markers, sometimes associated with the loss of various melanocytic markers, may pose significant diagnostic challenges. Therefore, comprehensive immunohistochemical analysis and molecular studies may be required to establish a diagnosis.
Finally, desmoplastic melanomas represent particular entities as they may appear deceivingly bland and usually lack expression of melanocytic markers such as HMB45, MelanA, tyrosinase, and PRAME but generally express S100 and SOX10 [39][40]. Nevertheless, cases of desmoplastic melanomas lacking all conventional melanocytic markers, including S100 and SOX10, have been described [39][41].

4. Conclusions

Undifferentiated/dedifferentiated primary cutaneous melanomas are sporadic and may be difficult to diagnose due to their unusual histopathological and immuno-histochemical characteristics. Clinical presentations may be useful as this type of tumor most often affects elderly males and occurs on the sun-exposed skin of the head and neck followed by the extremities. However, extensive immunohistochemical analysis is mandatory in such cases as most of them fail to express HMB45 and MelanA but may have retained expression, at least focally, of S100, SOX10, and PRAME. Nevertheless, none of these markers are entirely specific for melanomas, and further molecular analysis may be required to detect mutations associated with melanomas. Additionally, detecting genetic mutations in dedifferentiated melanomas helps diagnose these lesions, evaluate the prognosis, and identify the best therapeutic approach.

This entry is adapted from the peer-reviewed paper 10.3390/ijms24129985


  1. Davis, L.E.; Shalin, S.C.; Tackett, A.J. Current state of melanoma diagnosis and treatment. Cancer Biol. Ther. 2019, 20, 1366–1379.
  2. Banerjee, S.S.; Eyden, B. Divergent differentiation in malignant melanomas: A review. Histopathology 2008, 52, 119–129.
  3. Agaimy, A.; Specht, K.; Stoehr, R.; Lorey, T.; Märkl, B.; Niedobitek, G.; Straub, M.; Hager, T.; Reis, A.C.; Schilling, B.; et al. Metastatic Malignant Melanoma with Complete Loss of Differentiation Markers (Undifferentiated/Dedifferentiated Melanoma): Analysis of 14 Patients Emphasizing Phenotypic Plasticity and the Value of Molecular Testing as Surrogate Diagnostic Marker. Am. J. Surg. Pathol. 2016, 40, 181–191.
  4. Dumitru, A.V.; Tampa, M.Ş.; Georgescu, S.R.; Păunică, S.; Matei, C.N.; Nica, A.E.; Costache, M.; Motofei, I.; Sajin, M.; Păunică, I.; et al. Immunohistochemical mismatch in a case of rhabdomyoblastic metastatic melanoma. Rom. J. Morphol. Embryol. 2018, 59, 339–344.
  5. Campbell, K.; Kumarapeli, A.R.; Gokden, N.; Cox, R.M.; Hutchins, L.; Gardner, J.M. Metastatic melanoma with dedifferentiation and extensive rhabdomyosarcomatous heterologous component. J. Cutan. Pathol. 2018, 45, 360–364.
  6. Kilsdonk, M.J.; Romeijn, T.R.; Kelder, W.; van Kempen, L.C.; Diercks, G.F. Angiosarcomatous transdifferentiation of metastatic melanoma. J. Cutan. Pathol. 2020, 47, 1211–1214.
  7. Berro, J.; Abdul Halim, N.; Khaled, C.; Assi, H.I. Malignant melanoma with metaplastic cartilaginous transdifferentiation: A case report. J. Cutan. Pathol. 2019, 46, 935–941.
  8. Yousef, S.; Joy, C.; Velaiutham, S.; Maclean, F.M.; Harraway, J.; Gill, A.J.; Vargas, A.C. Dedifferentiated melanoma with MDM2 gene amplification mimicking dedifferentiated liposarcoma. Pathology 2022, 54, 371–374.
  9. Alkhasawneh, A.; Nassri, A.; John, I. Dedifferentiated Melanoma with Expression of Cytokeratin and GATA3 in a Patient with History of Breast Carcinoma. Am. J. Dermatopathol. 2019, 41, 502–504.
  10. Huang, F.; Santinon, F.; Flores González, R.E.; Del Rincón, S.V. Melanoma Plasticity: Promoter of Metastasis and Resistance to Therapy. Front. Oncol. 2021, 11, 756001.
  11. Benboubker, V.; Boivin, F.; Dalle, S.; Caramel, J. Cancer Cell Phenotype Plasticity as a Driver of Immune Escape in Melanoma. Front. Immunol. 2022, 13, 873116.
  12. Arozarena, I.; Wellbrock, C. Phenotype plasticity as enabler of melanoma progression and therapy resistance. Nat. Rev. Cancer 2019, 19, 377–391.
  13. Diazzi, S.; Tartare-Deckert, S.; Deckert, M. The mechanical phenotypic plasticity of melanoma cell: An emerging driver of therapy cross-resistance. Oncogenesis 2023, 12, 7.
  14. Gharpuray-Pandit, D.; Coyne, J.; Eyden, B.; Banerjee, S.S. Rhabdomyoblastic differentiation in malignant melanoma in adults: Report of 2 cases. Int. J. Surg. Pathol. 2007, 15, 20–25.
  15. Shenjere, P.; Fisher, C.; Rajab, R.; Patnaik, L.; Hazell, S.; Thway, K. Melanoma with rhabdomyosarcomatous differentiation: Two further cases of a rare pathologic pitfall. Int. J. Surg. Pathol. 2014, 22, 512–519.
  16. Antonov, N.K.; Niedt, G.W. Malignant Melanoma with Rhabdomyosarcomatous Differentiation: A Case Report. Am. J. Dermatopathol. 2016, 38, 456–460.
  17. Erstine, E.M.; Tetzlaff, M.T.; Ko, J.S.; Prieto, V.G.; Cheah, A.L.; Billings, S.D. Living on the Edge: Diagnosing Sarcomatoid Melanoma Using Histopathologic Cues at the Edge of a Dedifferentiated Tumor: A Report of 2 Cases and Review of the Literature. Am. J. Dermatopathol. 2017, 39, 593–598.
  18. Kiuru, M.; McDermott, G.; Berger, M.; Halpern, A.C.; Busam, K.J. Desmoplastic melanoma with sarcomatoid dedifferentiation. Am. J. Surg. Pathol. 2014, 38, 864–870.
  19. Ferreira, I.; Arends, M.J.; van der Weyden, L.; Adams, D.J.; Brenn, T. Primary de-differentiated, trans-differentiated and undifferentiated melanomas: Overview of the clinicopathological, immunohistochemical and molecular spectrum. Histopathology 2022, 80, 135–149.
  20. Cota, C.; Saggini, A.; Lora, V.; Kutzner, H.; Rütten, A.; Sangüeza, O.; Requena, L.; Cerroni, L. Uncommon Histopathological Variants of Malignant Melanoma: Part 1. Am. J. Dermatopathol. 2019, 41, 243–263.
  21. Agaimy, A.; Stoehr, R.; Hornung, A.; Popp, J.; Erdmann, M.; Heinzerling, L.; Hartmann, A. Dedifferentiated and Undifferentiated Melanomas: Report of 35 New Cases with Literature Review and Proposal of Diagnostic Criteria. Am. J. Surg. Pathol. 2021, 45, 240–254.
  22. Saggini, A.; Cota, C.; Lora, V.; Kutzner, H.; Rütten, A.; Sangüeza, O.; Requena, L.; Cerroni, L. Uncommon Histopathological Variants of Malignant Melanoma. Part 2. Am. J. Dermatopathol. 2019, 41, 321–342.
  23. Ferreira, I.; Droop, A.; Edwards, O.; Wong, K.; Harle, V.; Habeeb, O.; Gharpuray-Pandit, D.; Houghton, J.; Wiedemeyer, K.; Mentzel, T.; et al. The clinicopathologic spectrum and genomic landscape of de-/trans-differentiated melanoma. Mod. Pathol. 2021, 34, 2009–2019.
  24. Wiedemeyer, K.; Brenn, T. Dedifferentiated and undifferentiated melanomas: A practical approach to a challenging diagnosis. Hum. Pathol. 2023, S0046-8177, 74–76.
  25. Massi, D.; Mihic-Probst, D.; Schadendorf, D.; Dummer, R.; Mandalà, M. Dedifferentiated melanomas: Morpho-phenotypic profile, genetic reprogramming and clinical implications. Cancer Treat. Rev. 2020, 88, 102060.
  26. Glutsch, V.; Wobser, M.; Schilling, B.; Gesierich, A.; Goebeler, M.; Kneitz, H. PRAME Expression as Helpful Immunohistochemical Marker in Rhabdoid Melanoma. Dermatopathology 2022, 9, 148–157.
  27. Murakami, T.; Ogata, D.; Arai, E.; Tsuchida, T. Case of primary hypomelanotic rhabdoid melanoma on the forehead. J. Dermatol. 2019, 46, e278–e279.
  28. Torresetti, M.; Brancorsini, D.; Morgese, F.; Cognigni, V.; Scalise, A.; Berardi, R.; Di Benedetto, G. A case report of metastatic giant sarcomatoid melanoma with BRAF V600E mutation: A complete response to targeted therapy. Oncotarget 2020, 11, 3256–3262.
  29. Yim, S.H.; Kim, D.; Hong, D.; Jung, K.E.; Lee, Y.; Seo, Y.J.; Park, S. Primary cutaneous malignant melanoma with rhabdomyosarcomatous differentiation originating from a melanocytic nevus in a patient with myelodysplastic syndrome. J. Cutan. Pathol. 2022, 49, 875–880.
  30. Kuwadekar, A.; Allard, J.; Dardik, M.; Smith, F. Melanoma with rhabdomyosarcomatous differentiation. BMJ Case Rep. 2018, 2018, bcr2018224263.
  31. Tran, T.A.N.; Linos, K.; de Abreu, F.B.; Carlson, J.A. Undifferentiated Sarcoma as Intermediate Step in the Progression of Malignant Melanoma to Rhabdomyosarcoma: Histologic, Immunohistochemical, and Molecular Studies of a New Case of Malignant Melanoma with Rhabdomyosarcomatous Differentiation. Am. J. Dermatopathol. 2019, 41, 221–229.
  32. Baltres, A.; Salhi, A.; Houlier, A.; Pissaloux, D.; Tirode, F.; Haddad, V.; Karanian, M.; Ysmail-Dahlouk, S.; Boukendakdji, F.; Dahlouk, D.; et al. Malignant melanoma with areas of rhabdomyosarcomatous differentiation arising in a giant congenital nevus with RAF1 gene fusion. Pigment. Cell Melanoma Res. 2019, 32, 708–713.
  33. Szczepanski, J.M.; Siddiqui, J.; Patel, R.M.; Harms, P.W.; Hrycaj, S.M.; Chan, M.P. Expression of SATB2 in primary cutaneous sarcomatoid neoplasms: A potential diagnostic pitfall. Pathology 2023, 55, 350–354.
  34. Ali, A.M.; Wang, W.L.; Lazar, A.J. Primary chondro-osseous melanoma (chondrosarcomatous and osteosarcomatous melanoma). J. Cutan. Pathol. 2018, 45, 146–150.
  35. Savant, D.; Kenan, S.; Kenan, S.; Kahn, L. Osteogenic melanoma: Report of a case mimicking osteosarcoma and review of the literature. Skeletal Radiol. 2018, 47, 711–716.
  36. Abbati, F.; Altimari, A.; Corti, B.; Dika, E.; Sperandi, F.; Melotti, B. BRAF-mutated malignant melanoma with chondrosarcomatous differentiation in inguinal nodal metastasis. Clin. Case Rep. 2021, 9, 2200–2204.
  37. Fonda-Pascual, P.; Moreno-Arrones, O.M.; Alegre-Sanchez, A.; Real, C.M.G.-D.; Miguel-Gomez, L.; Martin-Gonzalez, M. Primary cutaneous angiomatoid melanoma. JDDG J. Dtsch. Dermatol. Ges. 2018, 16, 345–347.
  38. Ambrogio, F.; Colagrande, A.; Cascardi, E.; Grandolfo, M.; Filotico, R.; Foti, C.; Lupo, C.; Casatta, N.; Ingravallo, G.; Cazzato, G. Partially Dedifferentiated Primitive Malignant Melanoma with Pseudo-Angiomatous Features: A Case Report with Review of the Literature. Diagnostics 2023, 13, 495.
  39. Saliba, E.; Bhawan, J. Aberrant Expression of Immunohistochemical Markers in Malignant Melanoma: A Review. Dermatopathology 2021, 8, 359–370.
  40. Cazzato, G.; Lospalluti, L.; Colagrande, A.; Cimmino, A.; Romita, P.; Foti, C.; Demarco, A.; Arezzo, F.; Loizzi, V.; Cormio, G.; et al. Dedifferentiated Melanoma: A Diagnostic Histological Pitfall-Review of the Literature with Case Presentation. Dermatopathology 2021, 15, 494–501.
  41. Kooper-Johnson, S.; Mahalingam, M.; Loo, D.S. SOX-10 and S100 Negative Desmoplastic Melanoma: Apropos a Diagnostically Challenging Case. Am. J. Dermatopathol. 2020, 42, 697–699.
This entry is offline, you can click here to edit this entry!