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Nasal T-cell lymphoma
Annals of Oncology 5 (Suppl. 1): S39-S42, 1994. © 1994 Kluwer Academic Publishers. Printed in the Netherlands.
Original article Nasal T-cell lymphoma L. M. Weiss,1 D. A. Arber 1 & J. G. Strickler2 1 Division of Pathology, City of Hope National Medical Center, Duarte, California; 2 Department of Pathology, Mayo Clinic, Rochester, Minnesota, USA
Summary
Nasal T-cell lymphomas represent a controversial subset of malignant lymphomas and include lesions previously termed midline malignant reticulosis, lymphomatoid granulomatosis, and polymorphic reticulosis. Nasal T-cell lymphomas are rare in Western populations and much more prevalent in Asian countries. Clinically, adult males are most often affected. Histologically, an angiocentric infiltrate composed of a spectrum of atypical cells is usually present. Phenotypically, the neoplastic cells lack expression of B-lineage markers, and usually express the T-lineage-associated markers CD2, CD45RO, and CD43; however, they often lack other pan-T-
Key words: Epstein-Barr virus, lymphomatoid granulomatosis, malignant lymphoma, nasal lymphoma, natural killer cells, polymorphic reticulosis, T-cell lymphoma
Nasal lymphomas represent a controversial subset of malignant lymphomas, owing in part to the difficulty of recognizing them, both clinically and pathologically. Clinically, nasal lymphomas are part of the clinical spectrum of lethal midline granuloma or midfacial necrotizing lesions caused by various pathologic processes which also include Wegener's granulomatosis, infections, sarcoidosis, and idiopathic midline destructive disease. Pathologically, a mixed infiltrate is often found, difficult to distinguish from reactive processes. This has led to the use of an array of confusing pathologic terms, such as malignant granuloma, midline malignant reticulosis, lymphomatoid granulomatosis, and polymorphic reticulosis. The incidence of nasal lymphomas is difficult to assess, given the difficulty of recognition, the tendency in the literature to group these uncommon lymphomas with lymphomas arising in adjacent structures such as the sinuses and nasopharynx (which may or may not be similar to nasal lymphomas), and the differences among different populations studied. In 'Western' populations, nasal lymphomas are rare. In a series from the University of Virginia, 1.5% of all non-Hodgkin's lymphomas occurred in the nasal cavity and paranasal sinuses, although cases of 'midline malignant reticulosis' were excluded from the analysis [1]. Of 33 402 cases of malignant lymphomas registered in the Kiel Lymph Node Registry from 1972 to 1987, the incidence of malignant lymphomas in the nasal cavity and paranasal sinuses was found to be 0.17% of all malignant lymphomas and 0.44% of all extranodal malignant
lymphomas [2]. Eighty-five percent of these cases were considered to be primary in the nose, while only 15% were primary in the sinuses. In this latter study, cases with extranasal or extrasinusal tumor at the time of biopsy were excluded. Among Western populations, the incidence of a B-cell vs. T-cell phenotype varies widely among different series. In a combined series from the University of Virginia and the University of Minnesota, 85% of cases of nasal lymphoma were of B-cell phenotype, although the series may have been skewed by inclusion of cases from the nasal sinuses and exclusion of cases of 'midline malignant reticulosis' [3]. However, in the Kiel series B-cell lymphomas also predominated, accounting for 74% of cases of primary lymphomas of the nose [2]. Other, although smaller series, have shown a preponderance of cases of T-cell phenotype [4-8], particularly when selected for clinical features of lethal midline granuloma [4] or for histologic features of 'polymorphic reticulosis' [8]. Nasal lymphomas are much more prevalent in Asian countries and represent the second most frequent group of extranodal lymphomas after gastrointestinal tract lymphomas [9, 10]. In a series of 294 cases of malignant lymphoma occurring in Hong Kong Chinese patients, nasal lymphomas represented 2.6% of all nonHodgkin's lymphomas [9], while in a second series of 75 cases, nasal lymphomas represented 6.7% of nonHodgkin's lymphomas [10]. The overwhelming majority, perhaps representing greater than 90% of these Asian cases, possess at least some T-lineage markers
Downloaded from http://annonc.oxfordjournals.org/ at University of Birmingham on June 9, 2015
lineage markers. They often express the natural killer marker CD56, but usually lack the natural killer markers CD16 and CD57. Gene rearrangement studies have shown a germline configuration for the antigen receptor genes in the majority of cases. To date, evidence of Epstein-Barr virus has been consistently demonstrated, regardless of the geographic region studied. In situ hybridization studies have localized the Epstein-Barr virus to the atypical cells.
40
lesion (AIL) to describe these lymphomas [18]; most of the lesions occurring in the nose have had features of AIL grade 2 (polymorphous lymphoid infiltrate with atypia in the small lymphoid cells) or grade 3 (monomorphous population of large atypical lymphoid cells, associated with prominent necrosis) [8]. In contrast, nasal lymphomas of B-cell phenotype generally show a monomorphous population of large atypical lymphoid cells, without a prominent admixture of reactive cells. In addition, nasal B-cell lymphomas usually do not demonstrate angiocentricity or angioinvasion. Nasal T-cell lymphomas characteristically demonstrate a highly unusual phenotype. By definition, they lack expression of reliable B-lineage markers, such as CD20, CD19, or immunoglobulin expression. They usually express CD2, CD45RO, and CD43, consistent with a T-lineage neoplasm [4, 6-8, 13, 15, 17, 19]. However, they often completely lack other pan-, or subset-T-lineage markers such as CD3, CD5, alpha/ beta protein, gamma/delta protein, CD4, and CD8 [7, 13, 15, 19], although some studies have found the majority of the cases to be positive for CD3 [6, 8, 13]. The expression of the majority T-cell marker CD7 is also controversial, and has been reported to be usually positive [4, 7] and usually negative [15]. Analysis of recurrences has sometimes demonstrated a progressive loss of antigens, including CD3 [13]. Interestingly, these cases usually show expression of the natural killer marker CD56, although expression of other markers of natural killer cells, such as CD16 and CD57, is not generally found [7, 15, 19, 20]. In addition, a proportion of the tumor cells usually also express the activation markers CD25, CD30, and HLA-DR [4, 7, 12]. A variable rate of positivity has been found using the proliferation marker Ki-67; high proliferation rates are generally found in cases with a high component of large cells [4]. Antigen receptor gene rearrangement studies have yielded surprising results in these lymphomas. Although large numbers of these cases have not been studied, the majority have shown a germline configuration for the beta, gamma, and delta T-cell receptor genes [6, 15, 19, 21, 22], even when the monoclonality of the tumor cells can be demonstrated by other studies [22]. Occasional cases have been found to possess isolated beta, gamma, or delta T-cell receptor gene rearrangements [7,19,21,22]. To date, evidence of Epstein-Barr virus (EBV) has been consistently demonstrated in virtually all nasal T-cell lymphomas, including those from Asia, Peru, and Western populations, using polymerase chain reaction, Southern blot, in situ hybridization, and immunohistochemical studies [8, 14, 17, 21-24]. Southern blot studies employing a probe that hybridizes to a region adjacent to the terminal repeat region have demonstrated that EBV genomes are present in a monoclonal population of cells [21, 22]. In situ hybridization studies have localized EBV DNA (internal repeat region) [7, 14, 23] and RNA (EBER) to the atypical lymphoid
Downloaded from http://annonc.oxfordjournals.org/ at University of Birmingham on June 9, 2015
and lack B-lineage markers [10-15]. A high incidence of nasal lymphoma is also found in Peru, where nasal lymphoma represents approximately 8% of all hematolymphoid neoplasms [16]. Similar to the Asian cases, a high incidence of a T-cell phenotype is seen [17]. Clinically, series of patients with nasal T-cell lymphoma generally show a male predominance [8, 17], particularly in Asian populations [12, 13]. The median age affected is about fifty years. Nasal obstruction, with or without a discharge, is the presenting symptom in the majority of patients [12,17]. In one series, recurrent maxillary sinusitis was the presenting symptom in the majority of cases [7], and epistaxis and swelling of the face also occur in some patients. The lymphomas may involve the right or left nasal cavity (or both) or the septum. Grossly, they appear as a destructive mass, with frequent ulceration. The lymphomas are usually localized to the nose or show invasion of adjacent structures such as the nasopharynx, the paranasal sinuses, or the oropharynx, including the palate. Dissemination at the time of presentation occurs in a minority of patients and usually involves extranodal sites such as skin and lung, rather than lymph nodes [4, V]. Treatment has been inconsistent in the literature, with some groups using localized radiotherapy alone (for 'polymorphic reticulosis') [6, 8, 13], while other groups prefer multiagent chemotherapy with or without additional radiation therapy [7]. Use of chemotherapy alone has often not been sufficient to completely eradicate local disease [7]. Although some groups report a long median survival, death from disease occurs in approximately 50% of patients [8]. Relapse may occur either locally or may be systemic, often involving extranodal sites such as skin and lung. Histologically, a mixed infiltrate is characteristically present, including lymphoid cells, plasma cells, eosinophils, and histiocytes. The infiltrate often is angiocentric or frankly angioinvasive, and may also show invasion of cartilage or bone. Necrosis may be focal or widespread, and is often due to vascular compromise. The lesions vary from cases in which a mixed infiltrate of small atypical and large cells is found to cases in which atypical large cells predominate. Biopsies of recurrences may show a greater proportion of large cells than the initial biopsy [4]. Giemsa-stained touch preparations of the lesions may reveal azurophilic granules in the atypical cells [15]. The surface epithelium usually is ulcerated or undergoes squamous metaplasia, but occasionally may show pseudoepitheliomatous hyperplasia [6]. Nonulcerated epithelium may often contain small infiltrates of epitheliotropic atypical lymphocytes [12]. In the Working Formulation, most of the cases would fit into the categories of intermediate-grade lymphoma, diffuse mixed small- and large-cell and diffuse large-cell lymphoma, and high-grade lymphoma, largecell immunoblastic [6, 8, 12, 17]. Some investigators have used the term angiocentric immunoproliferative
41
References 1. Frierson HF, Mills SE, Innes DJ. Non-Hodgkin's lymphomas of the sinonasal region: Histologic subtypes and their clinicopathologic features. Am J Clin Pathol 1984; 81: 721-7.
Oncol 1990; 8: 271-81. 22. Medeiros LJ, Peiper SC, Elwood L et al. Angiocentric immunoproliferative lesions: A molecular analysis of eight cases. Hum Pathol 1991; 22:1150-7. 23. Weiss LM, Gaffey MJ, Chen Y-Y et al. Frequency of EpsteinBarr viral DNA in 'Western' sinonasal and Waldeyer's ring non-Hodgkin's lymphomas. Am J Surg Pathol 1992; 16: 15662.
Downloaded from http://annonc.oxfordjournals.org/ at University of Birmingham on June 9, 2015
cells [7, 8, 17, 24]. Immunohistochemical studies per- 2. Fellbaum C, Hansmann M-L, Lennert K. Malignant lymphomas of the nasal cavity and paranasal sinuses. Virchows Archiv formed mainly in frozen sections have consistently A Pathol Anat 1989; 414: 399-405. identified the EBV latent membrane protein [7, 14]. 3. Frierson HF, Innes DJ, Mills SE et al. Immunophenotypic anaSince latent membrane protein has transforming activilysis of sinonasal non-Hodgkin's lymphomas. Hum Pathol ty, it is possible that EBV is an important element in the 1989; 20: 636-42. pathogenesis of these lymphoma. Immunohistochemi4. Chott A, Rappersberger K, Schlossarek W et al. Peripheral T-cell lymphoma presenting as lethal midline granuloma. Hum cal studies for latent membrane protein that have been Pathol 1988; 19:1093-1101. performed on paraffin sections of these lymphomas 5. Ratech H, Burke JS, Blayney DW et al. A clinicopathologic have yielded inconsistent results [7, 8, 17], suggesting study of malignant lymphomas of the nose, paranasal sinuses, that the amount of latent membrane protein present and hard palate, including cases of lethal midline granuloma. Cancer 1989; 64: 2525-31. may not be as great as in Hodgkin's disease, where 6. Ferry JA, Sklar J, Zukerberg LR et al. Nasal lymphoma: A latent membrane protein is generally consistently clinicopathologic study with immunophenotypic and genotypic detectable even in paraffin sections. In addition, analysis. Am J Surg Pathol 1991; 15: 268-79. EBNA-2 has been identified in the neoplastic cells by 7. Kanavaros P, Lescs M-C, Briere J et al. Nasal T-cell lymphoma: two-color immunofluorescence [14]. A clinicopathologic entity associated with peculiar phenotype The above data suggest a unique type of malignant and with Epstein-Barr virus. Blood 1993; 81: 2688-95. 8. Strickler RG, Meneses MF, Habermann TM et al. 'Polylymphoma. The restricted pattern of pan-T antigens, morphic reticulosis': A reappraisal. Hum Pathol 1994 (in the absence of T-cell receptor antigen gene rearrangepress). ments in the majority of cases, the expression of the 9. Ho FCS, Todd D, Loke SL et al. Clinico-pathological features natural killer cell antigen CD56 in the majority of of malignant lymphomas in 294 Hong Kong Chinese patients: cases, and the presence of azurophilic granules in the Retrospective study covering an eight-year period. Int J Cancer 1984; 34:143-8. cytoplasm of cells as seen in Giemsa-stained touch preparations all suggest a natural killer cell derivation for 10. Ng CS, Chan JKC, Lo STH et al. Immunophenotypic analysis of non-Hodgkin's lymphomas in Chinese: A study of 75 cases this neoplasm. Natural killer cells are relatively infrein Hong Kong. Pathology 1986; 18:419-25. quent cells in the normal nasal mucosa, representing 11. Yamanaka N, Harabuchi Y, Sambe S et al. Non-Hodgkin's lymless than 2% of the lymphocytes [25]. On the other phoma of Waldeyer's ring and nasal cavity, clinical and immunologic aspects. Cancer 1985; 56Z: 768-76. hand, these lymphomas lack expression of the natural killer cell antigens CD16 and CD56, and although 12. Chan JKC, Ng Cs, Lau WH et al. Most nasal/nasopharyngeal lymphomas are peripheral T-cell neoplasms. Am J Surg Pathol EBV has been identified in non-neoplastic and neo1987; 11:418-29. plastic T cells, it has not yet been identified in natural 13. Ho FCS, Choy D, Loke S et al. Polymorphic reticulosis and killer cells in non-neoplastic lymphoid tissue [26]. conventional lymphomas of the nose and upper aerodigestive tract: A clinicopathologic study of 70 cases, and immunoKawa-Ha and colleagues have reported the presence of phenotypic studies of 16 cases. Hum Pathol 1990; 21: 1041EBV in CD3-negative lymphoproliferative disease of 50. large granular lymphocytes occurring in Asia [27], al- 14. Harabuchi Y, Yamanaka N, Kataura A et al. Epstein-Barr virus though another group did not detect EBV in similar in nasal T-cell lymphomas in patients with lethal midline granucases occurring in the United States and Europe [28]. loma. Lancet 1990; 335: 128-30. The expression of CD57 is not limited to natural killer 15. Chan JKC, Ng CS, Tsang WYW. Nasal/nasopharyngeal lymphomas: An immunohistochemical analysis of 57 cases on cells, but may also be found in T lymphocytes which frozen tissues. Mod Pathol 1993; 6:87A (abstract). have natural killer activity [19]. The expression of CD3, 16. Misad O, Solidoro A, Quiroz L et al. An overview of lymphoat least in some series of nasal T-cell lymphoma, with reticular malignancies in Peru. Prog Cancer Res Ther 1984; 27: transition in serial biopsies from CD3 + to CD3" in iso85-97. lated cases, might suggest the latter possibility. In sum- 17. Arber DA, Weiss LM, Albujar PF et al. Nasal lymphomas in Peru: High incidence of T-cell immunophenotype and Epsteinmary, the available data are not sufficient to offer defiBarr virus infection. Am J Surg Pathol 1993; 17: 392-99. nitive conclusions about the true lineage of this neo- 18. Lipford EH, Margolick JB, Longo DL et al. Angiocentric implasm. munoproliferative lesions: A clinicopathologic spectrum of Although nasal T-cell lymphoma appears to be a dispost-thymic T-cell proliferations. Blood 1988; 72:1674-81. tinctive type of neoplasm, non-Hodgkin's lymphomas 19. Weiss LM, Picker LJ, Grogan TM et al. Absence of clonal beta and gamma T-cell receptor gene rearrangements in a subset of with similar characteristics have been identified at peripheral T-cell lymphomas. Am J Pathol 1988; 130: 436-42. other sites. Most commonly, these lymphomas have 20. Ng CS, Chan JKC, Lo STH. Expression of natural killer cell been described at other locations in the respiratory markers in non-Hodgkin's lymphomas. Hum Pathol 1987; 18: tract, including the nasopharynx, the nasal sinuses, the 1257-62. oropharynx, the larynx, and the lung [4, 5,8,12,13,15, 21. Ho FCS, Srivastava G, Loke SL et al. Presence of Epstein-Barr virus DNA in nasal lymphomas of B and ' T cell type. Hematol 19,22,30].
42 24. Medeiros LJ, Jaffe ES, Chen Y-Y et al. Localization of EpsteinBarr viral genomes in angiocentric immunoproliferative lesions. Am J Surg Pathol 1992; 16: 439-47. 25. Winther B, Innes DJ, Mills SE et al. Lymphocyte subsets in normal airway mucosa of the human nose. Arch Otolaryngol Head Neck Surg 1987; 113: 59-62. 26. Deamant FD, Albujar PF, Chen Y-Y et al. Epstein-Barr virus distribution in non-neoplastic lymph nodes. Mod Pathol 1993. In press. 27. Kawa-Ha K, Ishihara S, Ninomiya T et al. CD-3-negative lymphoproliferative disease of granular lymphocytes containing Epstein-Barr viral DNA. J Clin Invest 1989; 84: 51-5. 28. Loughran TP, Zambello R, Ashley R et al. Failure to detect Epstein-Barr virus DNA in peripheral blood mononuclear cells of most patients with large granular lymphocyte leukemia. Blood 1993; 81: 2723-7.
29. Ritz J, Schmidt RE, Michon J et al. Characterization of functional surface structures on human natural killer cells. Adv Immunol 1988; 42: 181-211. 30. Lippman SM, Grogan TM, Spier CM et al. Lethal midline granuloma with a novel T-cell phenotype as found in peripheral T-cell lymphoma. Cancer 1987; 59: 946-39.
Correspondence to: Lawrence M. Weiss, M.D. Division of Pathology City of Hope National Medical Center 1500 E. Duarte Road Duarte, California 91010 USA
Downloaded from http://annonc.oxfordjournals.org/ at University of Birmingham on June 9, 2015
Original article Nasal T-cell lymphoma L. M. Weiss,1 D. A. Arber 1 & J. G. Strickler2 1 Division of Pathology, City of Hope National Medical Center, Duarte, California; 2 Department of Pathology, Mayo Clinic, Rochester, Minnesota, USA
Summary
Nasal T-cell lymphomas represent a controversial subset of malignant lymphomas and include lesions previously termed midline malignant reticulosis, lymphomatoid granulomatosis, and polymorphic reticulosis. Nasal T-cell lymphomas are rare in Western populations and much more prevalent in Asian countries. Clinically, adult males are most often affected. Histologically, an angiocentric infiltrate composed of a spectrum of atypical cells is usually present. Phenotypically, the neoplastic cells lack expression of B-lineage markers, and usually express the T-lineage-associated markers CD2, CD45RO, and CD43; however, they often lack other pan-T-
Key words: Epstein-Barr virus, lymphomatoid granulomatosis, malignant lymphoma, nasal lymphoma, natural killer cells, polymorphic reticulosis, T-cell lymphoma
Nasal lymphomas represent a controversial subset of malignant lymphomas, owing in part to the difficulty of recognizing them, both clinically and pathologically. Clinically, nasal lymphomas are part of the clinical spectrum of lethal midline granuloma or midfacial necrotizing lesions caused by various pathologic processes which also include Wegener's granulomatosis, infections, sarcoidosis, and idiopathic midline destructive disease. Pathologically, a mixed infiltrate is often found, difficult to distinguish from reactive processes. This has led to the use of an array of confusing pathologic terms, such as malignant granuloma, midline malignant reticulosis, lymphomatoid granulomatosis, and polymorphic reticulosis. The incidence of nasal lymphomas is difficult to assess, given the difficulty of recognition, the tendency in the literature to group these uncommon lymphomas with lymphomas arising in adjacent structures such as the sinuses and nasopharynx (which may or may not be similar to nasal lymphomas), and the differences among different populations studied. In 'Western' populations, nasal lymphomas are rare. In a series from the University of Virginia, 1.5% of all non-Hodgkin's lymphomas occurred in the nasal cavity and paranasal sinuses, although cases of 'midline malignant reticulosis' were excluded from the analysis [1]. Of 33 402 cases of malignant lymphomas registered in the Kiel Lymph Node Registry from 1972 to 1987, the incidence of malignant lymphomas in the nasal cavity and paranasal sinuses was found to be 0.17% of all malignant lymphomas and 0.44% of all extranodal malignant
lymphomas [2]. Eighty-five percent of these cases were considered to be primary in the nose, while only 15% were primary in the sinuses. In this latter study, cases with extranasal or extrasinusal tumor at the time of biopsy were excluded. Among Western populations, the incidence of a B-cell vs. T-cell phenotype varies widely among different series. In a combined series from the University of Virginia and the University of Minnesota, 85% of cases of nasal lymphoma were of B-cell phenotype, although the series may have been skewed by inclusion of cases from the nasal sinuses and exclusion of cases of 'midline malignant reticulosis' [3]. However, in the Kiel series B-cell lymphomas also predominated, accounting for 74% of cases of primary lymphomas of the nose [2]. Other, although smaller series, have shown a preponderance of cases of T-cell phenotype [4-8], particularly when selected for clinical features of lethal midline granuloma [4] or for histologic features of 'polymorphic reticulosis' [8]. Nasal lymphomas are much more prevalent in Asian countries and represent the second most frequent group of extranodal lymphomas after gastrointestinal tract lymphomas [9, 10]. In a series of 294 cases of malignant lymphoma occurring in Hong Kong Chinese patients, nasal lymphomas represented 2.6% of all nonHodgkin's lymphomas [9], while in a second series of 75 cases, nasal lymphomas represented 6.7% of nonHodgkin's lymphomas [10]. The overwhelming majority, perhaps representing greater than 90% of these Asian cases, possess at least some T-lineage markers
Downloaded from http://annonc.oxfordjournals.org/ at University of Birmingham on June 9, 2015
lineage markers. They often express the natural killer marker CD56, but usually lack the natural killer markers CD16 and CD57. Gene rearrangement studies have shown a germline configuration for the antigen receptor genes in the majority of cases. To date, evidence of Epstein-Barr virus has been consistently demonstrated, regardless of the geographic region studied. In situ hybridization studies have localized the Epstein-Barr virus to the atypical cells.
40
lesion (AIL) to describe these lymphomas [18]; most of the lesions occurring in the nose have had features of AIL grade 2 (polymorphous lymphoid infiltrate with atypia in the small lymphoid cells) or grade 3 (monomorphous population of large atypical lymphoid cells, associated with prominent necrosis) [8]. In contrast, nasal lymphomas of B-cell phenotype generally show a monomorphous population of large atypical lymphoid cells, without a prominent admixture of reactive cells. In addition, nasal B-cell lymphomas usually do not demonstrate angiocentricity or angioinvasion. Nasal T-cell lymphomas characteristically demonstrate a highly unusual phenotype. By definition, they lack expression of reliable B-lineage markers, such as CD20, CD19, or immunoglobulin expression. They usually express CD2, CD45RO, and CD43, consistent with a T-lineage neoplasm [4, 6-8, 13, 15, 17, 19]. However, they often completely lack other pan-, or subset-T-lineage markers such as CD3, CD5, alpha/ beta protein, gamma/delta protein, CD4, and CD8 [7, 13, 15, 19], although some studies have found the majority of the cases to be positive for CD3 [6, 8, 13]. The expression of the majority T-cell marker CD7 is also controversial, and has been reported to be usually positive [4, 7] and usually negative [15]. Analysis of recurrences has sometimes demonstrated a progressive loss of antigens, including CD3 [13]. Interestingly, these cases usually show expression of the natural killer marker CD56, although expression of other markers of natural killer cells, such as CD16 and CD57, is not generally found [7, 15, 19, 20]. In addition, a proportion of the tumor cells usually also express the activation markers CD25, CD30, and HLA-DR [4, 7, 12]. A variable rate of positivity has been found using the proliferation marker Ki-67; high proliferation rates are generally found in cases with a high component of large cells [4]. Antigen receptor gene rearrangement studies have yielded surprising results in these lymphomas. Although large numbers of these cases have not been studied, the majority have shown a germline configuration for the beta, gamma, and delta T-cell receptor genes [6, 15, 19, 21, 22], even when the monoclonality of the tumor cells can be demonstrated by other studies [22]. Occasional cases have been found to possess isolated beta, gamma, or delta T-cell receptor gene rearrangements [7,19,21,22]. To date, evidence of Epstein-Barr virus (EBV) has been consistently demonstrated in virtually all nasal T-cell lymphomas, including those from Asia, Peru, and Western populations, using polymerase chain reaction, Southern blot, in situ hybridization, and immunohistochemical studies [8, 14, 17, 21-24]. Southern blot studies employing a probe that hybridizes to a region adjacent to the terminal repeat region have demonstrated that EBV genomes are present in a monoclonal population of cells [21, 22]. In situ hybridization studies have localized EBV DNA (internal repeat region) [7, 14, 23] and RNA (EBER) to the atypical lymphoid
Downloaded from http://annonc.oxfordjournals.org/ at University of Birmingham on June 9, 2015
and lack B-lineage markers [10-15]. A high incidence of nasal lymphoma is also found in Peru, where nasal lymphoma represents approximately 8% of all hematolymphoid neoplasms [16]. Similar to the Asian cases, a high incidence of a T-cell phenotype is seen [17]. Clinically, series of patients with nasal T-cell lymphoma generally show a male predominance [8, 17], particularly in Asian populations [12, 13]. The median age affected is about fifty years. Nasal obstruction, with or without a discharge, is the presenting symptom in the majority of patients [12,17]. In one series, recurrent maxillary sinusitis was the presenting symptom in the majority of cases [7], and epistaxis and swelling of the face also occur in some patients. The lymphomas may involve the right or left nasal cavity (or both) or the septum. Grossly, they appear as a destructive mass, with frequent ulceration. The lymphomas are usually localized to the nose or show invasion of adjacent structures such as the nasopharynx, the paranasal sinuses, or the oropharynx, including the palate. Dissemination at the time of presentation occurs in a minority of patients and usually involves extranodal sites such as skin and lung, rather than lymph nodes [4, V]. Treatment has been inconsistent in the literature, with some groups using localized radiotherapy alone (for 'polymorphic reticulosis') [6, 8, 13], while other groups prefer multiagent chemotherapy with or without additional radiation therapy [7]. Use of chemotherapy alone has often not been sufficient to completely eradicate local disease [7]. Although some groups report a long median survival, death from disease occurs in approximately 50% of patients [8]. Relapse may occur either locally or may be systemic, often involving extranodal sites such as skin and lung. Histologically, a mixed infiltrate is characteristically present, including lymphoid cells, plasma cells, eosinophils, and histiocytes. The infiltrate often is angiocentric or frankly angioinvasive, and may also show invasion of cartilage or bone. Necrosis may be focal or widespread, and is often due to vascular compromise. The lesions vary from cases in which a mixed infiltrate of small atypical and large cells is found to cases in which atypical large cells predominate. Biopsies of recurrences may show a greater proportion of large cells than the initial biopsy [4]. Giemsa-stained touch preparations of the lesions may reveal azurophilic granules in the atypical cells [15]. The surface epithelium usually is ulcerated or undergoes squamous metaplasia, but occasionally may show pseudoepitheliomatous hyperplasia [6]. Nonulcerated epithelium may often contain small infiltrates of epitheliotropic atypical lymphocytes [12]. In the Working Formulation, most of the cases would fit into the categories of intermediate-grade lymphoma, diffuse mixed small- and large-cell and diffuse large-cell lymphoma, and high-grade lymphoma, largecell immunoblastic [6, 8, 12, 17]. Some investigators have used the term angiocentric immunoproliferative
41
References 1. Frierson HF, Mills SE, Innes DJ. Non-Hodgkin's lymphomas of the sinonasal region: Histologic subtypes and their clinicopathologic features. Am J Clin Pathol 1984; 81: 721-7.
Oncol 1990; 8: 271-81. 22. Medeiros LJ, Peiper SC, Elwood L et al. Angiocentric immunoproliferative lesions: A molecular analysis of eight cases. Hum Pathol 1991; 22:1150-7. 23. Weiss LM, Gaffey MJ, Chen Y-Y et al. Frequency of EpsteinBarr viral DNA in 'Western' sinonasal and Waldeyer's ring non-Hodgkin's lymphomas. Am J Surg Pathol 1992; 16: 15662.
Downloaded from http://annonc.oxfordjournals.org/ at University of Birmingham on June 9, 2015
cells [7, 8, 17, 24]. Immunohistochemical studies per- 2. Fellbaum C, Hansmann M-L, Lennert K. Malignant lymphomas of the nasal cavity and paranasal sinuses. Virchows Archiv formed mainly in frozen sections have consistently A Pathol Anat 1989; 414: 399-405. identified the EBV latent membrane protein [7, 14]. 3. Frierson HF, Innes DJ, Mills SE et al. Immunophenotypic anaSince latent membrane protein has transforming activilysis of sinonasal non-Hodgkin's lymphomas. Hum Pathol ty, it is possible that EBV is an important element in the 1989; 20: 636-42. pathogenesis of these lymphoma. Immunohistochemi4. Chott A, Rappersberger K, Schlossarek W et al. Peripheral T-cell lymphoma presenting as lethal midline granuloma. Hum cal studies for latent membrane protein that have been Pathol 1988; 19:1093-1101. performed on paraffin sections of these lymphomas 5. Ratech H, Burke JS, Blayney DW et al. A clinicopathologic have yielded inconsistent results [7, 8, 17], suggesting study of malignant lymphomas of the nose, paranasal sinuses, that the amount of latent membrane protein present and hard palate, including cases of lethal midline granuloma. Cancer 1989; 64: 2525-31. may not be as great as in Hodgkin's disease, where 6. Ferry JA, Sklar J, Zukerberg LR et al. Nasal lymphoma: A latent membrane protein is generally consistently clinicopathologic study with immunophenotypic and genotypic detectable even in paraffin sections. In addition, analysis. Am J Surg Pathol 1991; 15: 268-79. EBNA-2 has been identified in the neoplastic cells by 7. Kanavaros P, Lescs M-C, Briere J et al. Nasal T-cell lymphoma: two-color immunofluorescence [14]. A clinicopathologic entity associated with peculiar phenotype The above data suggest a unique type of malignant and with Epstein-Barr virus. Blood 1993; 81: 2688-95. 8. Strickler RG, Meneses MF, Habermann TM et al. 'Polylymphoma. The restricted pattern of pan-T antigens, morphic reticulosis': A reappraisal. Hum Pathol 1994 (in the absence of T-cell receptor antigen gene rearrangepress). ments in the majority of cases, the expression of the 9. Ho FCS, Todd D, Loke SL et al. Clinico-pathological features natural killer cell antigen CD56 in the majority of of malignant lymphomas in 294 Hong Kong Chinese patients: cases, and the presence of azurophilic granules in the Retrospective study covering an eight-year period. Int J Cancer 1984; 34:143-8. cytoplasm of cells as seen in Giemsa-stained touch preparations all suggest a natural killer cell derivation for 10. Ng CS, Chan JKC, Lo STH et al. Immunophenotypic analysis of non-Hodgkin's lymphomas in Chinese: A study of 75 cases this neoplasm. Natural killer cells are relatively infrein Hong Kong. Pathology 1986; 18:419-25. quent cells in the normal nasal mucosa, representing 11. Yamanaka N, Harabuchi Y, Sambe S et al. 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Correspondence to: Lawrence M. Weiss, M.D. Division of Pathology City of Hope National Medical Center 1500 E. Duarte Road Duarte, California 91010 USA
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