CD26/dipeptidyl peptidase IV expression in human lymphomas is restricted to CD30-positive anaplastic large cell and a subset of T-cell non-Hodgkin's lymphomas

CD26 is identical to the cell surface ectoenzyme dipeptidyl peptidase IV (DPPIV). is associated with T-cell activation and proliferation and also may function as an auxiliary adhesion factor. Although has been previously studied on lymphoid populations and on leukemias/lymphomas of B- and T-cell phenotype, little is known about its expression and functional role in some specific types of lymphomas, such as CD30-positive anaplastic large cell (ALC) lymphomas and Hodgkin's disease (HD). A series of 81 lymphoma samples, including 23 cases of HD, 17 cases of CD30-positive ALC lymphomas, 41 cases of other non-Hodgkin's lymphomas (NHL), and a panel of HD- or ALC lymphoma-derived human cell lines were evaluated for expression by enzyme histochemistry and immunohistochemistry on frozen sections and cell smears. protein was expressed on neoplastic cells in 12 of 17 (71%) ALC lymphomas irrespective of their antigenic phenotype and in seven of 15 (47%) T-cell NHLs. In contrast, we did not detect expression in tumor cells from 26 cases of B-cell NHL other than ALC lymphomas or in Reed Sternberg (RS) cells and variants of 21 of 23 HD cases. Accordingly, expression was maintained on the CD30-positive ALC lymphoma cell line Karpas 299, but the molecule was not detected on HD-derived cell lines of B, T, or non-B non-T phenotype. These results may support a new potential tool for the phenotypic separation of ALC lymphomas from HD based on the differential expression of the molecule. Moreover, given the demonstration that is identical to the human adenosine deaminase (ADA) binding protein, it could be speculated that also may function by interacting with ADA to regulate the growth of expressing neoplastic cells in ALC lymphomas.     

TIA-1 expression in lymphoid neoplasms. Identification of subsets with cytotoxic T lymphocyte or natural killer cell differentiation.

TIA-I is a 15-kd cytotoxic granule-associated protein expressed in natural killer (NK) cells and cytotoxic T lymphocytes. TIA-1 expression was evaluated by paraffin immunohistochemistry in 115 T- or NK-cell neoplasms, 45 B-cell neoplasms, and 45 Hodgkin''s lymphomas. TIA-1-positive granules were identified within the cytoplasm of neoplastic cells in 6/6 large granular lymphocytic leukemias, 11/11 hepatosplenic T-cell lymphomas, 15/15 intestinal T-cell lymphomas, 6/6 NK-like T-cell lymphomas of no special type, 2/2 NK-cell lymphomas, 8/9 nasal T/NK-cell lymphomas, 7/8 subcutaneous T-cell lymphomas, 4/5 pulmonary T- or NK-cell angiocentric lymphomas (lymphomatoid granulomatosis), 12/19 T-cell anaplastic large-cell lymphomas, 2/12 nodal peripheral T-cell lymphomas, 1/3 CD8+ cutaneous T-cell lymphomas, and 5/38 classical Hodgkin''s disease. All B-cell neoplasms, nodular lymphocyte-predominant Hodgkin''s disease (7 cases), CD4+ cutaneous T-cell lymphomas (6 cases), adult T-cell leukemia/lymphomas (3 cases), T-cell chronic or prolymphocytic leukemias (3 cases), and T-cell lymphoblastic leukemia/lymphomas (7-cases) were TIA-1 negative. These findings indicate that most large granular lymphocytic leukemias, hepatosplenic T-cell lymphomas, intestinal T-cell lymphomas, NK-like T-cell lymphomas, NK-cell lymphomas, nasal T/NK-cell lymphomas, subcutaneous T-cell lymphomas, pulmonary angiocentric lymphomas of T or NK phenotype, and anaplastic large-cell lymphomas are cytotoxic T-or NK-cell neoplasms.     

In vivo expression of the CTLA4 inhibitory receptor in malignant and reactive cells from Human lymphomas

The CTLA4 receptor is a CD28 homologue which induces inhibitory effect on activated T-cells. Peripheral T-cells proliferate spontaneously in CTLA4-deficient mice. These results led to an analysis of CTLA4 expression in human lymphomas (n=82) including Hodgkin's disease (HD) and non-Hodgkin's lymphomas (NHLs), using immunohistochemistry. CTLA4 was present in neoplastic cells from most (10/11) T-cell malignancies, except for anaplastic and lymphoblastic subtypes (0/4). Malignant B-cells from rare (3/55) B-NHLs (all of follicular subtype) were also CTLA4-positive. Other B-NHLs (52/55) were negative in malignant B-cells and occasionally positive in T-cells. Reactive small lymphocytes, but not Reed–Sternberg cells, from all (12/12) HD cases were strongly CTLA4-positive. The CTLA4 ligands CD80 and CD86 were simultaneously expressed in most CTLA4-negative lymphoma cases. CTLA4 is thus expressed either in the reactive or in the malignant cell populations, depending on the lymphoma subtype. These results provide new insights leading towards therapeutic strategies based either on enhancement of anti-tumour immunity by CTLA4 blockade in reactive lymphocytes or on triggering of a CTLA4-mediated inhibitory pathway in lymphoma cells. © 1997 John Wiley & Sons, Ltd.     

Characterization of tumor-infiltrating T lymphocytes in B-cell lymphomas of mucosa-associated lymphoid tissue.

B-cell lymphomas of mucosa-associated lymphoid tissue invariably contain large numbers of reactive tumor-infiltrating T cells. In the stomach, these lymphomas develop secondary to Helicobacter pylori infection, and clinical and in vitro studies have shown that their growth depends on help provided by H. pylori-specific T cells. In this study we characterized tumor-infiltrating T cells in low- and high-grade B-cell lymphomas of mucosa-associated lymphoid tissue using immunohistochemistry. In most cases, CD4+ T cells dominated and almost all T cells were CD45RO+ memory cells. In 11 of 13 cases studied, the proliferating T cells were CD4+ and no proliferation was observed in the CD8+ subset. In low-grade lymphomas, between 7 and 24% of T cells expressed CD40L whereas no CD40L expression was observed in the majority of high-grade tumors. Examination of homing receptor profile showed that both alpha 4 beta 7 integrin+ and L-selectin+ T cells were present. Examination of T cell diversity by a panel of antibodies against different T-cell receptor V beta regions and by analysis of T-cell receptor genes using polymerase chain reaction suggested that the T cells in these tumors were polyclonal. These results show that low-grade B-cell lymphomas of mucosa-associated lymphoid tissue contain a significant population of activated helper T cells that may be important in supporting tumor growth.     

CD56+/CD4+ lymphomas and leukemias are morphologically, immunophenotypically, cytogenetically, and clinically diverse

CD56, a neural adhesion molecule, is a marker of natural killer (NK) lymphocytes as well as a subgroup of CD8+ T cells. Normal lymphocytes with a CD56/CD4 phenotype are scarce. Physiologic increases may occur in patients with immunosuppression, chronic inflammation, and autoimmune disorders. We report 4 cases of lymphomas/leukemias with the unusual CD56/CD4 phenotype. Two were of T-cell and 2 of true NK-cell origin. The T-cell lymphomas had large granular lymphocyte morphologic features and splenomegaly. One patients had a benign course; the other died within months of the leukemia diagnosis. The 2 NK cell lymphomas had blastic morphologic features, initially involved skin, and had a very aggressive clinical course; 1 patient died of acute leukemia, and 1 had recurrence after bone marrow transplantation. Cytogenetic analyses did not show a consistent pattern of abnormalities. The NK lymphoma with acute leukemia had a t(2;5) but was CD30- and anaplastic lymphoma kinase negative. Although CD56+/CD4+ lymphomas/leukemias are a heterogeneous group, there may be a distinct subgroup of NK lymphoblastoid lymphomas of the skin, judging from our cases, as well as those previously reported.     

CD5+ T-cell/histiocyte-rich large B-cell lymphoma.

CD5 expression in neoplastic large B-cells in T-cell/histiocyte-rich large B-cell lymphoma has not been reported, to the best of our knowledge. Here we describe the first case of CD5+ T-cell/histiocyte-rich large B-cell lymphoma that is well documented by histomorphology, immunohistochemistry, flow cytometry immunophenotyping and sorting, and immunoglobulin heavy-chain gene rearrangement study by polymerase chain reaction. The expression of CD5 in large neoplastic B-cells was demonstrated by immunohistochemistry and multicolor flow cytometry. The clonal nature of the CD5+ neoplastic B-cells was confirmed by rearranged immunoglobulin heavy (IgH) chain with polymerase chain reaction (PCR) of flow cytometry-sorted CD5+/CD19+/kappa+ cells. The CD5+ neoplastic large B-cells expressed bcl-6 and MUM1/IRF4 but not CD138 by immunohistochemistry. This suggests that the neoplastic cells may be of late germinal-center B-cell/ early post-germinal center B-cell origin. The patient responded to chemotherapy, CHOP (Cytoxan, doxorubicin, vincristine, and prednisone), and Rituxan very well and is currently in complete remission clinically. We propose that the current case, CD5+ T-cell/histiocyte-rich large B-cell lymphoma, represents a variant of recently reported de novo CD5+ diffuse large B-cell lymphomas. Our patient has had an excellent response to treatment; however, the clinical and biologic significance of CD5 expression in T-cell/histiocyte-rich large B-cell lymphoma requires further studies. Awareness of the CD5+ T-cell/histiocyte-rich large B-cell lymphoma variant will prompt pathologists to perform CD5 immunohistochemical stain in cases of T-cell/histiocyte-rich large B-cell lymphoma. This will lead to identifying more cases to understand the clinical and biologic characteristics of this variant.     

Expression of enolases in T cell tumors and Hodgkin's disease

Frozen biopsy specimens taken from 30 cases with T cell tumors (8 with T cell acute lymphoblastic leukemia, 8 with T cell lymphoblastic lymphoma, and 14 with peripheral T cell lymphomas), and from 12 with Hodgkin's disease, were investigated using a direct immunohistochemical method to detect alpha-, beta- and gamma-enolases. Normal thymus and lymph node specimens with reactive lymphadenitis were also investigated. Subcortical thymocytes and the majority of deep cortical thymocytes showed reactivity of alpha-/beta-/gamma- approximately +/- -enolases, and medullary thymocytes and small lymphocytes in T zone areas of lymph node showed reactivity of alpha-/beta+/gamma- approximately +/- -enolases. Seven of the 8 cases with T cell acute lymphoblastic leukemia showed reactivity of alpha-/beta-/gamma(-)-enolases or alpha+/beta-/gamma(-)-enolases in leukemic lymphocytes, 7 of the 8 cases with T cell lymphoblastic lymphoma showed reactivity of beta(+)-enolase, and all 14 cases with peripheral T-cell lymphomas showed reactivity of alpha-/beta- approximately +/gamma(+)-enolases in lymphoma cells. All the 12 cases with Hodgkin's disease showed reactivity of alpha-/beta+/gamma(+)-enolases in Reed-Sternberg and Hodgkin's cells. These results indicate the following: (a) The neoplastic cells of T cell acute lymphoblastic leukemia, T cell lymphoblastic lymphoma and peripheral T cell lymphomas present different expressions in each of these three categories. This may imply a difference of maturation and differentiation or activation among neoplastic T lymphocytes. (b) T lymphocytes may switch from alpha- to beta-enolase and from alpha- to gamma-enolase in the course of differentiation and activation. (c) It is worth noting that the Reed-Sternberg and Hodgkin's cells of Hodgkin's disease present an identical expression of enolases.     

Increased number of Epstein-Barr virus latently infected B-cells in T-cell non-Hodgkin's lymphoma tissues

Summary Epstein-Barr virus (EBV) is a causative agent of malignant lymphomas occurring in immunocompromised hosts. Similar lymphoid tumors can be induced in mice with severe combined immunodeficiency (SCID mice) by transplanting human B-cells with latently infected EBV. We have previously observed that when apparently EBV-negative lymphomas were engrafted into SCID mice, 11 of 18 T-cell non-Hodgkin's lymphomas (NHLs) produced EBV associated lymphomas, but only 2 of 30 engrafted with B-NHLs. Previous studies suggested that EBV-infected cell inducing lymphomas in SCID mice may preferentially exist in T-cell NHL tissues. To prove this assumption, in situ hybridization (ISH) using oligonucleotide probes for EBV-encoded small RNAs 1 (EBER1) was used in this study to demonstrate EBV-bearing lymphocytes in NHL tissues. It was found that EBV-bearing cells existe in 9 of the 10 T-cell NHL surgical specimens. By contrast, in B cell NHLs, only 2 of 10 carried EBV-bearing cells. Further semi-quantitative analysis demonstrated that apparently significantly more EBV-bearing cells were present in T-cell NHL tissues than in B-cell NHLs. Moreover, these EBV-bearing cells in lymphoma tissues were shown to be of B-cell lineage, by the combinated analysis of immunostaining with CD20 and ISH with EBER1. These results indicated the increase of EBV-bearing B-cells in T-cell NHL tissues, suggesting the activation of B-cells with latently infected EBV by neoplastic T-cells.     

Distribution of T-cell subsets in follicular and diffuse lymphomas of B-cell type.

The authors examined the number and distribution of cells reacting with monoclonal antibodies to T-cell subsets in frozen tissue sections of B-cell lymphomas (30 follicular and 17 diffuse lymphomas). In five diffuse lymphomas (two lymphocytic, three small cleaved cell) the neoplastic B-lymphocytes reacted with the monoclonal antibody anti-T1. In all other cases, the monoclonal antibodies to T-cell subsets reacted only with small lymphocytes concentrated between the follicles of follicular lymphomas and distributed randomly in diffuse lymphomas. The distribution of T cells and the T4+/T8+ ratio in follicular small cleaved and mixed lymphomas was similar, although not identical, to that seen in hyperplastic lymphoid follicles. Fewer T cells and a decrease in the T4+/T8+ ratio were seen in follicular large cell lymphoma and in diffuse large cell lymphomas. The number and distribution of T cells in follicular lymphomas is consistent with the hypothesis that there is a functional interaction between neoplastic B cells and benign T cells. No tumors were found in which the neoplastic B cells reacted with anti-T3, anti-T4, or anti-T8.     

Leu-22 (L60). A more sensitive marker than UCHL1 for peripheral T-cell lymphomas, particularly large-cell types

Paraffin-embedded sections of 77 peripheral T-cell lymphomas (PTCLs) were stained with several monoclonal antibodies, including the preferential T-cell markers Leu-22 (L60[CD43]) and UCHL1 (CD45RO). The staining characteristics of L60 and UCHL1 were compared to determine the value of each in the immunophenotypic analysis of PTCLs. Lineage specificity was evaluated among 39 B-cell lymphomas and 33 cases of Hodgkin's disease (HD). L60 and/or UCHL1 stained 95% of PTCLs, whereas L60 and UCHL1 alone stained 90% and 69% of cases, respectively. L60 demonstrated significantly greater numbers of immunopositive tumor cells than UCHL1 in 37% of the PTCL cases, principally because of enhanced marking of large, neoplastic cells. UCHL1 was a better marker in only 10% of the PTCL cases. L60 stained 33% of B-cell lymphomas, usually small lymphocytic or lymphoplasmacytic types. UCHL1 stained only 8% of B-cell lymphomas, all large-cell types. L60 and UCHL1 stained Reed-Sternberg cells and variants in three cases of nodular sclerosing HD. These results suggest that both L60 and UCHL1 are useful markers of PTCLs in routinely processed tissue. L60 is a more sensitive marker of large neoplastic T-cells than UCHL1 but is less lineage-specific. These antibodies are most effective when used as part of a panel of monoclonal antibodies.     

Differential expression of thymus and activation regulated chemokine and its receptor CCR4 in nodal and cutaneous anaplastic large-cell lymphomas and Hodgkin's disease.

Recent studies demonstrated that Hodgkin/Reed-Sternberg (H/RS) cells in Hodgkin's disease (HD) express thymus and activation-regulated chemokine (TARC), whereas reactive lymphocytes surrounding H/RS cells express its ligand, CC-chemokine receptor 4 (CCR4). Because in vitro studies showed that CCR4 expression is a marker for lymphocytes bearing a T-helper 2 (Th2) phenotype, it was suggested that expression of TARC is a new immune escape mechanism in HD. To find out whether this mechanism might also be operative in CD30+ malignant lymphomas other than HD, TARC and CCR4 expression was investigated by immunohistochemistry on paraffin and frozen-tissue sections of 39 nodal CD30+ anaplastic large cell lymphomas (ALCL), including 27 ALK-negative and 12 ALK-positive ALCL, 25 primary cutaneous CD30+ ALCL, including 11 patients with lymphomatoid papulosis, and 31 cases of HD. TARC was expressed by the neoplastic cells in 12/27 (44%) nodal ALK-negative ALCL and all cases of classic HD, but not in nodal ALK-positive ALCL (0/12) and only rarely in primary cutaneous CD30+ ALCL (3/25). In contrast, CCR4 was expressed by the neoplastic cells in 9/9 cutaneous CD30+ ALCL, and in 9/15 (60%) nodal ALK-negative ALCL, but only in 1/4 (25%) nodal ALK-positive ALCL and not by the H/RS cells in HD (0/8). Apart from three cases of HD showing 10 to 15% CCR4-positive lymphocytes surrounding TARC-positive H/RS cells, CCR4-positive reactive T cells were few (<5%) in all other cases studied. Our results demonstrate a differential expression of TARC and CCR4 in different types of CD30+ malignant lymphomas. The small number of CCR4-positive reactive T cells in most cases studied argues against an important role of TARC expression in the evasion of antitumor responses.     

Aberrant expression of T-cell-associated antigens on B-cell non-Hodgkin lymphomas

We describe 9 well-characterized cases of B-cell non-Hodgkin lymphoma (NHL) that showed aberrant expression of T-cell-associated antigens by 2-color flow cytometry. Cases were as follows: chronic lymphocytic leukemia/small lymphocytic lymphoma, 4; follicle center cell lymphoma, 2; mantle cell lymphoma, 1; and diffuse large B-cell lymphoma, 2. CD2 was the most commonly expressed antigen (5 cases). CD8 and CD7 were identified in 2 cases each, including 1 case that expressed both CD7 and CD4. The disease course and response to treatment were compatible with the type and stage of lymphoma. No unusually aggressive behavior was noted in any case. A control group of 59 cases of benign lymph nodes analyzed during the same period showed no aberrant expression of T-cell-associated antigens; thus, such expression is not a feature of benign lymphoid proliferations. Study of these B-cell lymphomas may prove invaluable to study aberrant activation of silent or repressed T-cell differentiation genes. CD2-expressing B-cell NHLs may represent clonal expansion of CD2+ B lymphocytes that normally constitute a small fraction of peripheral B lymphocytes and should not be confused with composite B- and T-cell lymphomas. Unless aggressive behavior is noted consistently, no aggressive treatment is justified.     

Use of monoclonal antibodies for the typing of malignant lymphomas in routinely processed biopsy samples

Eight antibodies (UCHL1 (CD45RO), MT1 (CD43), MT2 (CD45R), 4KB5 (CD45R), MB1 (CD45R), MB2, L26 (CD20) and LN1 (CDw75)) have been examined for reactivity with routine specimens of normal and hyperplastic lymphoid organs (n = 6), non-Hodgkin's lymphomas (n = 62), Hodgkin's disease (n = 27) and non-lymphoid malignancies (n = 9). In normal and hyperplastic lymphoid organs, UCHL1 and MT1 stained predominantly T cells; 4KB5, MB1, MB2, L26 and LN1 stained predominantly B cells; and MT2 reacted with a subset of B and T cells. The lineage of the neoplastic cells was correctly identified in 24 of 28 (86%) peripheral T-cell lymphomas; and in 31 of 35 (88%) B-cell malignancies. In two cases of lymphocyte-predominant Hodgkin's disease, the Hodgkin's and Reed-Sternberg (H&RS) cells were 4KB5+, L26+ and/or LN1+. The H&Rs cells in nodular sclerosis and mixed cellularity Hodgkin's disease were positive with 4KB5 in 17 of 25 cases. Antibodies UCHL1, MT1, MB1, MB2, L26 and LN1 also labelled some H&RS cells, but in a much smaller proportion of the cases. In three of nine non-lymphoid neoplasms, UCHL1 and MB2 showed a staining of the neoplastic cells, but the staining was cytoplasmic rather than membrane-associated. The remaining antibodies were unreactive with the non-lymphoid malignancies. It is concluded that many non-Hodgkin's lymphomas can be typed in routine specimens, and that antibodies UCHL1, MT1, L26 and LN1 are especially useful in this respect. The antibodies do not provide a means of distinguishing between non-Hodgkin's lymphomas and Hodgkin's disease.     

Detection of B- and T-cells in paraffin-embedded tissue sections. Diagnostic utility of commercially obtained 4KB5 and UCHL-1

Although many recent studies have begun exploring the diagnostic utility of anti-B- and anti-T-cell antibodies that work on paraffin-embedded tissue sections, the most optimal panel to use remains uncertain. In addition, many of the published reports have used antibodies obtained before their commercial formulation and distribution. For these reasons, B5-fixed paraffin-embedded tissue samples from 174 reactive or neoplastic lymphoid and hematopoietic proliferations were immunostained with the commercially obtained antibodies 4KB5, UCHL-1, and, in selected cases, L26. In reactive nodes, 4KB5 stained B-cell areas and UCHL-1 T-cell areas. Seventy-nine percent of the B-cell neoplasms were 4KB5 positive, and only 2% were UCHL-1 positive. Two cases of myeloma were 4KB5 and UCHL-1 negative. The 4KB5-negative B-cell lymphomas (ML-B) were all L-26 positive. UCHL-1 stained 78% of the T-cell lymphomas (ML-T), and 4KB5 stained 14%. In the five 4KB5-positive putative T-cell lymphomas, immunoglobulin and T-cell receptor gene rearrangement studies were performed. In Hodgkin's disease (HD), Reed-Sternberg (RS) cells were UCHL-1 negative in 75% of cases and occasionally positive in 25%. Definite 4KB5 positivity of RS cells was identified in both cases of lymphocyte predominant HD and in one case of nodular sclerosing HD with monomorphic large cell areas. With the exception of 1 of 15 acute nonlymphocytic leukemias that was UCHL-1 positive, all acute leukemias were 4KB5 and UCHL-1 negative. In summary, commercially obtained 4KB5 and UCHL-1 form a useful but not absolutely specific or sensitive paraffin section immunoperoxidase panel for the categorization of B- and T-cell lymphoid neoplasms. Addition of L26 appears to add to the sensitivity and specificity of the panel. Definite immunophenotypic distinction of HD from non-Hodgkin's lymphomas, particularly of T-cell type, often was not possible.     

Methods in pathology. Identification of T-cell lymphomas in paraffin-embedded tissues using polyclonal anti-CD3 antibody: comparison with frozen section immunophenotyping and genotypic analysis.

While L26 (CD20) is now well established as a B-cell marker of high specificity for use in paraffin-embedded tissues, paraffin-reactive T-cell antibodies (UCHL1, MT1, Leu-22, DF-T1, and MT2) have not shown comparable lineage specificity. A new commercially available polyclonal antibody directed against a synthetic peptide sequence of the CD3 (T-cell) antigen has recently become available for use on paraffin sections. In order to evaluate the utility of this antibody, we studied CD3 expression in conjunction with L26 and leukocyte common antigen (LCA) in 15 T-cell and 20 B-cell non-Hodgkin's lymphomas (NHL), all genotypically confirmed by DNA hybridization and immunophenotyped by immunoperoxidase studies in frozen tissue. Ten of 15 T-cell NHLs (67%) showed unequivocal immunolabeling of neoplastic cells with anti-CD3 in paraffin-embedded tissue. Of the five negative cases, three were lymphoblastic lymphomas, and two were peripheral (postthymic) lymphomas (one anaplastic large cell, Ki-1 positive and one large cell, immunoblastic). CD3 expression was identical in paraffin and cryostat sections (100% concordance). Twenty of 20 B-cell NHLs were positive with L26 and LCA but were negative with anti-CD3. Other neoplasms examined, including three granulocytic sarcomas and 45 nonhematopoietic tumors, were similarly negative with anti-CD3. We conclude that polyclonal anti-CD3 is a sensitive and highly specific T-cell marker in paraffin-embedded tissue and, when used in conjunction with LCA and L26, that it can determine cell lineage in the majority of non-Hodgkin's lymphomas.     

Immunophenotyping of non-Hodgkin's lymphomas in paraffin-embedded tissue sections. A comparison with genotypic analysis.

Several monoclonal antibodies (MoAbs) are now available for immunophenotyping non-Hodgkin's lymphomas (NHLs) in paraffin-embedded tissue sections. To determine the reliability of these reagents in predicting the genotype, 44 cases of NHL were studied with the alkaline phosphatase-anti-alkaline phosphatase technique with the use of the following MoAbs: leukocyte common antigen (CD45), Mac 387, L26, 4KB5, MB1, MB2, LN2, UCHL1, MT1, and MT2. The lineage of the neoplastic cells was determined in all cases by gene rearrangement studies for immunoglobulin heavy chain and for the T-cell receptor beta-chain. Genotypic results showed B-cell lineage in 33 cases (75%), T-cell lineage in 6 cases (14%), and mixed or undetermined lineage in 5 cases (11%). A concordance of lineage assignment by paraffin section immunophenotyping with gene rearrangement studies was observed in 37 of 39 (95%) lymphomas with an unequivocally defined genotype. MoAb L26 was the most sensitive in detecting B-cell genotype; MoAbs MT1 and UCHL1 were the most sensitive and specific, respectively, in detecting T-cell genotype. The authors conclude that lineage assignment of NHLs in paraffin sections is reflective of the corresponding genotype when an appropriate panel of MoAbs is used.     

Alkaline phosphatase-positive malignant lymphoma. A subtype of B-cell lymphomas.

Alkaline phosphatase (ALP) activity was evaluated histochemically and cytochemically in concert with immunologic technics in 60 cases of non-Hodgkin's lymphomas and lymphocytic leukemias. Surface membranes of neoplastic cells were positive for ALP only in certain B-cell malignancies: 3 of 6 lymphocytic lymphomas of intermediate differentiation, 4 of 13 nodular lymphomas, and 1 of 7 Burkett's lymphomas. All other B-cell tumors, including chronic lymphocytic leukemia, well-differentiated lymphocytic lymphoma, and diffuse "histiocytic" lymphoma, were ALP-negative. The neoplastic cells of Sezary syndrome and lymphoblastic lymphoma were also consistently negative for ALP. In control lymph nodes ALP-positive lymphocytes were present only in primary follicles and in mantle zones of secondary follicles. ALP-positive lymphomas appear to be neoplastic counterparts of these normal lymphocytes, not only cytochemically, but also with respect to their morphologic and immunologic characteristics. Furthermore, histochemical inhibition tests suggested that the ALP activity demonstrated may reflect a newly recognized, unique isoenzyme.     

alpha-Naphthyl acetate esterase activity--a cytochemical marker for T lymphocytees. Correlation with immunologic studies of normal tissues, lymphocytic leukemias, non-Hodgkin''s lymphomas, Hodgkin''s disease, and other lymphoproliferative disorders.

Cytochemical identification of T lymphocytes on the basis of alpha-naphthyl acetate esterase (NAE) activity was compared with immunologic markers for cell suspensions and/or cryostat sections of 113 specimens. Nonneoplastic tissues (peripheral blood, lymph nodes, spleens, tonsils, thymus, and pleural fluid) and specimens from various lymphoproliferative disorders, including acute and chronic lymphocytic leukemia, lymphosarcoma cell leukemia, hairy cell leukemia, non-Hodgkin's lymphomas of B-and T-cell types, and Hodgkin's disease, were evaluated. T (E-rosetting) cells demonstrated several patterns of NAE reactivity: 1) a strong globular reaction product, the most specific pattern for T-cell identification, 2) granular cytoplasmic staining, or 3) no reactivity. B lymphocytes revealed a granular pattern of NAE staining, were devoid of enzyme, or, in rare instances, exhibited strong NAE activity. Percentages of lymphoid cells with strong (globular) NAE activity closely paralleled T-cell (E-rosette) values in the majority of cases, with the best correlations observed for peripheral blood studies. However, discordant results were noted for some neoplastic and nonneoplastic tissues, including cases of T-cell lymphoma or leukemia. Markedly discrepant results were noted for thymic lymphocytes, most of which revealed E-rosette formation and weak or absent NAE activity. Lymph nodes involved by Hodgkin's disease demonstrated a heterogeneous pattern of staining in E-rosetting cells and in Reed-Sternberg variants. Cryostat section studies of reactive lymph nodes and nodular lymphomas demonstrated strong NAE staining in lymphoid cells of T-cell (interfollicular, internodular) areas, with little or no positivity in follicles or nodules (B-cell areas). NAE staining patterns further suggested that T cells comprise part of the follicular cuff and possibly represent a minor population of some neoplastic nodules. Although NAE determinations do not represent a consistently reliable alternative to immunologic methods for T-cell identification, this easily applicable cytochemical marker is complementary to other techniques in assessing neoplastic or nonneoplastic tissues, particularly cryostat sections. (Am J Pathol 97:17--42, 1979).     

Genotypic and immunophenotypic characterization of two human light chain-only B-cell non-Hodgkin's lymphomas

Two atypical human non-Hodgkin's lymphomas (NHLs) that exhibited unusual genotypic and in situ immunophenotypic abnormalities are described. Immunophenotypically, both NHLs lacked surface Ig heavy chains. With the exception of the MB2 B-cell-associated antigen, no B- and T-cell differentiation antigen was detected in case 1. NHL 2 failed to show evidence of clonality by immunohistochemical analysis but revealed the presence of many B-lymphocytes with an abnormal phenotypic profile: CD19+, CD20+, CD22+, kappa-, lambda-, CD9-, CD10-, CD21-, and CD24-. Genotypic analysis indicated that both lymphomas derived from anomalously matured pre-B-cells that had rearranged the lambda or kappa light chain genes but not the Ig heavy chain gene. The neoplastic cells of the two NHLs resemble the light chain-only B-cells recently discovered, following Epstein-Barr virus immortalization, in the human bone marrow. The authors' data confirm, therefore, the existence of the light chain-only B-cells in the human hematopoietic compartment. Moreover, their results emphasize the conclusive role of the immunogenotypic analysis in defining clonality, lineage, and maturation abnormalities of such atypical NHLs.