Lymphomas arise from clonal proliferation of lymphocytes at various stages of differentiation from precursor T and B cells to mature T cells and plasma cells: B cells arise from the bone marrow and produce immunoglobulins in a humoral response, whereas T cells are thymus-derived and respond in a cell-mediated reaction via cells that are antigenically marked or that produce lymphokines. Lymphocytes in circulating blood and lymph nodes normally have a ratio of about two thirds T cells to one third B cells, natural killer (NK) cells, and null cells. The normal lymph node comprises follicles, each organized into germinal centers, mantle zones, and the surrounding cortex (Fig. 6). The germinal center is composed of a framework of dendritic histiocytes, follicular dendritic cells, centroblasts, centrocytes, immunoblasts, small lymphocytes, and tingible body macrophages, whereas the surrounding cortex and paracortex contain mainly B and T cells, respectively.

As lymphomas arise from monoclonal proliferations, histological demonstration of a single-cell type aids diagnosis and classification and, hence, the planning of treatment and determination of prognosis. Histological identification of lymphomatous B cells was originally achieved with heterosera against immunoglobulins, these sera being counterstained with immunoperoxidase stain or labelled with immunofluorescent markers.¹⁹ Plasma cells could be similarly identified by their cytoplasmic immunoglobulins. T cells were first identified cytologically by rosette formation when combined with sheep erythrocytes but, in addition, have been noted to uniquely contain cytoplasmic α-naphthyl esterase, for which the cells can be stained.^20,21 More specific and sensitive immunohistochemical and cytogenetic techniques are now available, allowing further immunophenotyping of the cellular populations within the tumor biopsy.¹⁸

B-cell clonality can be indicated by quantitative histochemical staining for the kappa and lambda immunoglobulin light chains: the kappa–lambda ratio in benign lesions is 2:1, whereas the ratio is typically 10:1 or greater in malignant lesions.²¹ Orbital lymphomas are almost exclusively B-cell proliferations and contain a low proportion (10% to 20%) of T cells, whereas over a half of all lymphocytes within benign or atypical reactive lesions are T cells; in contrast, T-cell lymphomas contain around 90% T cells.²¹ The normal T-cell “helper:suppressor” ratio is 2:1, and this is maintained in malignant B-cell lymphomas, but typically increases to 5:1 in reactive lymphoid lesions.²¹ Reactive processes involve polyclonal or oligoclonal populations, in which each of the many clonal populations expresses a distinct gene rearrangement, whereas a malignant lymphoma arises from a monoclonal clone population—thereby expressing only a single immunoglobulin genomic rearrangement—these gene rearrangements being characterized by polymerase chain reaction (PCR) methods.

Cell surface markers have been identified for various cell types—initially the immunoglobulins and interleukins and, later, the cell surface antigen receptors—these being termed clusters of differentiation (CD); the CD markers are used to characterize the degree of cellular differentiation.^22,23 There are currently well over a hundred characterized cell surface markers, providing valuable help in the characterization of Hodgkin’s lymphoma and the subsets of non-Hodgkin’s B- and T-cell lymphomas (Table 4).²⁴ Some CD markers are typical of B cells, such as CD10, CD19, CD20, and CD22, whereas others (such as CD2, CD4, CD7, and CD8) are expressed by T cells.

Cytogenetic analysis now plays a significant role in the diagnosis of some lymphomas, as many such tumors may result from a failure of the regulation of somatic mutations either as a loss of suppressor gene activity or as an upregulation of a proto-oncogene that promotes mitosis with a differentiation of naive lymphocytes to memory cells and plasma cells. Changes in genetic control probably also explain the increased risk of developing non-Hodgkin’s lymphoma in immunocompromised patients with congenital immunodeficiencies, autoimmune diseases, on cytotoxic agents, or with acquired immunodeficiency syndrome (AIDS). Lymphomas in AIDS patients tend to be clinically aggressive—with involvement of bone marrow, bowel, and the central nervous system—and are associated with a poor prognosis.^{16,25,26,27,28,29}

Immunoglobulin gene expression has been studied in lymphoma, and conventional cytogenetic analysis provides information about chromosomal rearrangements within tumor cells. Gene rearrangements can be detected with restriction endonuclease cleavage and Southern blot techniques,^{30,31,32,33,34,35,36,37} the rearrangement appearing as a distinct and unique band with monoclonal lesions, whereas a polyclonal lesion, having immunoglobulins from many different lymphocyte populations, demonstrates only the control band.^{30,31,32,33,36,37} The technical difficulties with conventional techniques have, however, led to increased use of PCR or fluorescence in-situ hybridization (FISH) analysis to identify specific genetic abnormalities; multicolor interphase FISH assays allow detection of several diagnostic changes in a single cell, and simultaneous fluorescence immunophenotyping (FICTION technique) facilitates a correlation of cellular phenotype and genotype.¹⁸

Many cytogenetic abnormalities, mostly chromosomal translocations, have been shown to be characteristic for particular lymphomas, and these are particularly associated with upregulation of proto-oncogenes and transcription factors or with downregulation of apoptosis. Multiple chromosomal translocations are an integral part of normal B-cell differentiation, and this is thought to explain the high frequency of such genetic abnormalities within malignant lymphomas (Table 5). Examples of such mutations include that of the c-myc oncogene (8q24) in Burkitt’s lymphoma, the bcl-1 gene (11q13) in mantle cell lymphoma, the bcl-2 translocation (14;18)(q32;q21) in 70% to 90% follicular lymphomas and 10% to 35% of nodal large-cell lymphomas, and the bcl-6 gene (3q27) in diffuse large B-cell lymphoma.^{37,38,39,40,41,42,43,44}

The specific genes overexpressed or underexpressed as a result of some mutations or translocations have begun to be elucidated: Half of lymphoplasmacytic lymphomas, often with macroglobulinemia, are associated with a (9;14)(p13;q32) translocation, this translocation juxtaposing the immunoglobulin heavy chain (IgH) gene (on chromosome 14q32) and the PAX-5 gene (9p13). PAX-5 encodes the cell cycle regulation protein B-cell specific activation protein (BSAP)—a control protein involved throughout B-cell proliferation and differentiation with the exception of plasma cells (Table 4).⁴³ The PAX-5 gene belongs to a group of PAX genes, which have been identified as regulators of cell cycle and differentiation,^43,45 and BSAP factor may enhance B-cell lymphopoiesis by an unknown mechanism. The protein product of the bcl-2 gene reduces cellular apoptosis, and a (14:18)(q32;q21) translocation with increased bcl-2 protein production confers a survival advantage to the centrocytes in follicular lymphoma.⁴⁶ The c-myc gene is known to code for a proto-oncogene which, when upregulated, allows for unmitigated cell division.^7,47 The bcl-1 gene mutation allows upregulation of the PRAD-1 gene that encodes a cell cycle regulator, cyclin D1.⁴⁷ Anaplastic large cell lymphoma (ALCL) is typically associated with the t(2,5)(p23;q35) translocation, which includes fusion of the NPM (nucleophosmin) gene on 5q35 to a novel anaplastic lymphoma kinase (ALK) gene on 2p23, which results in phosphorylation of intracellular targets and triggers malignant transformation.⁴⁸ The ALK gene is not expressed on normal T cells and has both diagnostic and prognostic importance.