Differential expression of heparan sulfate domains in rat spleen.

The microarchitecture of the spleen is composed of a meshwork of reticulum cells and their matrix. Heparan sulfates (HS) are important components of this meshwork and are involved in processes such as cell adhesion, cell migration, and cytokine/growth factor binding. The expression of HS epitopes was analyzed using anti-HS antibodies. Four different staining patterns were observed, as exemplified by antibodies RB4EA12, HS4E4, AO4B08, and HS4C3. These antibodies recognize different chemical modifications in HS. In adult spleen, RB4EA12 stained only the reticular meshwork and blood vessels in the red pulp and marginal zone. HS4E4 stained blood vessel-associated basal lamina. AO4B08 and HS4C3 stained the reticular meshwork and blood vessels throughout the spleen, but only AO4B08 strongly stained smooth muscle cells and ring fibers. Interleukin-2 localized in the red pulp and marginal zone and was bound to HS. AO4B08, HS4C3, and RB4EA12 but not HS4E4 co-localized with interleukin-2. In 10-day-old spleen, HS4E4 recognized reticular fibers, which were not stained in the adult stage. Immunoelectron microscopy revealed that HS was restricted to basal laminae and reticular fibers. Taken together, data show that HS epitopes are differentially expressed in the spleen and that this may create specific extracellular environments for immunological processes.     

Immunohistochemical characteristics of chicken spleen ellipsoids using newly established monoclonal antibodies

Ellipsoids, the extra-vasculature sites surrounding penicilliary capillaries of the chicken spleen, play critical roles in the immune response and also in the clearance of pathogens or other particles. The meshwork of ellipsoids is formed by fibroblastic reticular cells. To characterize ellipsoidal reticular cells, a series of monoclonal antibodies against the chicken spleen have been developed. Of these antibodies, CSA-1 antibody reacts with fibroblastic reticular cells in ellipsoids and with endothelial cells. The reticular nature of positive cells in ellipsoids is indicated by immuno-electron microscopy, and by double-staining with anti-heat-shock protein 47 kDa (hsp47) antibody. The reaction of CSA-1 with reticular cells is limited in ellipsoids; CSA-1 does not react with reticular cells in other lymphoid organs. These findings indicate that ellipsoidal reticular cells share the antigen with endothelial cells. Ontogenic studies reveal that, on embryonic day 18, the development of ellipsoids is completed, penicilliary capillaries become fenestrated, and CSA-1 expression in ellipsoids begins. These findings suggest that CSA-1 is expressed on the cell surface of ellipsoidal reticular cells once they are exposed to blood flow.     

Correlative immuno-electron-microscopic and immunofluorescent localization of actin in sensory and supporting cells of the inner ear by use of a low-temperature embedding resin

Summary The cochleas from chinchilla inner ears were processed in the cold through Lowicryl K4M, and cured by UV light. Thick (2 m) sections were reacted with primary antibodies raised against actin, and anti-actin antibodies localized by FITC epifluorescence. On thin sections from the same blocks anti-actin antibodies were localized ultrastructurally with secondary antibodies coupled to colloidal gold.In the hair cells, actin was present in the stereocilia and cuticular plate, regions where thin filaments were observed by electron microscopy. Colloidal gold was uniformly distributed over these regions and over the stereocilia rootlets demonstrating that actin was present in this region although previously in permeabilized cells, the rootlet was not decorated with myosin subfragment S-1. Actin was present in the pillar and Deiters supporting cells at the reticular lamina and at the basilar membrane, where a meshwork of thin filaments was seen by electron microscopy. Colloidal gold particles were also localized over the thin processes of the pillar and Deiters cells, and over the region of the Deiters cell which envelops the base of the outer hair cell. In these regions actin co-localized with microtubules along the entire length of the supporting cells.     

Cytoskeletal components of lymphoid organs

Using light and electron microscopic immunolocalization with antibodies to cytoskeletal proteins, we have characterized the nonlymphoid cells of various human lymphoid organs (lymph nodes, tonsils, spleen). In all these tissues, the lymphoid follicles contain a three-dimensional meshwork of "dendritic reticulum cells" which are characterized by the presence of desmosomal junctions, as demonstrated by positive punctate staining with antibodies to the desmosome-specific proteins desmoplakin I and desmoglein, and by intermediate-sized filaments (IFs) of the vimentin type only. In contrast, the extrafollicular regions are characterized by an extended meshwork of other types of reticulum cells, which also contain vimentin IFs but lack desmosomal proteins. In addition, a considerable, although variable proportion of these extrafollicular reticulum cells forms IFs containing cytokeratins 8 and 18 and/or desmin-containing IFs. The occurrence of cytokeratins 8 and 18 in lymph nodes has also been shown by gel electrophoresis and immunoblotting. Results of double-label immunolocalization indicate that some of the extrafollicular reticulum cells coexpress all three kinds of IF protein. A large proportion of these cells also synthesizes another marker of myogenic differentiation, i.e., the isoform of alpha-actin specific for smooth muscle. This proportion includes some cells that are negative for desmin. Comparison of the distribution of cells expressing cytokeratins and/or desmin with that of reticulum cells showing strong alkaline phosphatase activity (as a marker for the so-called "fiber-associated (fibroblastic) reticulum cells") suggests that the former represent a subset of the latter. The biological meaning of these different patterns of expression in reticulum cells and of the resulting cell-type heterogeneity as well as possible implications of these observations for tumor diagnosis, notably of lymph-node metastases and lymphomas, are discussed.     

Analysis of lymphoid and dendritic cells in human lymph node, tonsil and spleen. A study using monoclonal and heterologous antibodies

The distribution of lymphoid and dendritic cells in human reactive lymph nodes, tonsils and spleens was examined by means of an indirect immunoperoxidase technique, using a panel of monoclonal and heterologous antibodies. The antibodies used were directed against antigens present on T cell subsets (Leu1, leu2a, Leu3a, TA1, OKT6), various types of B cells (BA1, BA2, HLA-DR, CR1) and cells of the mononuclear phagocyte system (alpha HM1, TA1, CR1, OKM1, NA 1/34). In the lymph node and tonsil Leu3a-positive cells (T-helper/inducer phenotype) and Leu2a-positive cells (T-suppressor/cytotoxic phenotype) are found in the thymus-dependent or T-cell area; in the spleen Leu3a-positive cells are found mostly in the periarteriolar lymphocyte sheath (PALS), while Leu2a-positive T-suppressor/cytotoxic cells are almost completely restricted to the cords of Billroth in the red pulp. The cells in the mantle zone of germinal centres and in the primary follicles in lymph nodes, tonsils and spleens have B-cell properties (BA1-, HLA-DR-, and CR1-positive). The cells in the germinal centres show a similar staining pattern (HLA-DR-, and partly CR1-positive). Follicles and T-cell-dependent areas have specific dendritic cells, each with a specific staining pattern: the dendritic reticulum cell (DRC) of the follicle stain with CR1, HLA-DR, BA2 and alpha HM1; the interdigitating cell of the T-cell areas in the lymph node, tonsil and spleen stain with HLA-DR and BA1. Moreover, large dendritic OKT6-positive cells are found in the T-cell areas of some of the peripheral lymph nodes, and are probably Langerhans cells. It is concluded that human lymph nodes and tonsils have an identical compartimentalisation, clearly differing from the spleen in cellular organization.     

Applicability of imprints to immuno-ultrastructural studies of lymphoid tissues

In order to evaluate the applicability of imprints to immuno-ultrastructural studies of lymphoid tissues, we compared distribution pattern and morphology of B cells, T cells, T-cell subsets, and follicular dendritic reticulum cells (DRC) at the light and ultrastructural level in imprints and sections of tonsils and lymph nodes. The surface antigenic profile of lymphoid cells was revealed with monoclonal antibodies in an avidin-biotin-peroxidase complex (ABC) method. Distribution of lymphoid cells in coherent areas of imprints recapitulated their disposition in sections of respective lymphoid tissues. Preservation of microanatomical relationships and ultrastructure of lymphoid cells in imprints allowed evaluation of associations and fine structural detail of lymphoid cells. Morphologic configurations of B cells in imprints, confined to round aggregates, were similar to fine structural morphology of B cells in mantle zones (MZ) and germinal centers (GC). Processes of DRCs in imprints formed conformations resembling their meshwork within follicles and mantled lymphoid cells. In imprints and sections, lymphocytes of cytotoxic/suppressor phenotype had a large amount of cytoplasm with many organelles. In contrast, cells of helper/inducer phenotype displayed a high nucleocytoplasmic (N/C) ratio and small numbers of organelles. Thus, imprints represent an easy, fast, and reliable method that lends itself to immunoultrastructural studies of lymphoid tissues.     

Binding of human lymphocyte-specific monoclonal antibodies to common marmoset lymphoid cells

Commercially available monoclonal antibodies which bind to human lymphocyte subsets were screened for their ability to bind to lymphoid cells from the common marmoset Callithrix jacchus. Anti-Leu-5 and T11 were the only pan T-cell antibodies which reacted strongly. None of the antibodies which bind human lymphocytes of the helper/inducer subpopulation reacted with C. jacchus cells and only one antibody, T8, specific for the cytotoxic/suppressor subset, bound to the marmoset cells. The two antibodies tested which bind human B cells, B1 and anti-HLA-DR, were also reactive with marmoset cells. The cellular specificity of the T11, T8, and B1 antibodies was determined by dual binding studies on the fluorescence-activated cell sorter. The B1 antibody bound only Ig+ cells and all Ig+ cells were B1+. The T11 and T8 antibodies bound only to Ig- marmoset lymphoid cells and, as in the human, all T8+ marmoset cells were also T11+. Thus, using these monoclonal antibodies in the common marmoset one can identify three populations of lymphoid cells: (1) T11+, T8+ cells; (2) T11+, T8- cells; (3) B1+ cells.     

Modulation of chronic lymphocytic leukemia (CLL) lymphocyte phenotypes by in vitro incubation with alpha 1 thymosin

In this study an attempt was made to elucidate (1) the level(s) of differentiation arrest of B cells, and (2) whether T-cell functional defects in CLL patients are related to their defective maturation. In addition, an attempt was also made to induce and/or correct maturation of T cells in CLL patients by in vitro incubation with alpha 1 thymosin. In CLL patients and controls, we determined the percentage of T and B cells with T11, T8, T4, C3, and mouse erythrocyte (ME) receptors, along with T-cell functional reactivity (measured by local xenogeneic graft vs host reaction), before and after incubation with alpha 1 thymosin. In about 60% of stable CLL patients, and in 80% of those in the progressive phase of disease, T cells possess receptors for ME and/or C3. After incubation with alpha 1 thymosin, separate analysis of surface markers on T and B cells revealed (along with the induction of T11 receptors on T-cell surface) induction of ME receptors on T and B cells in stable phase and selective loss of ME receptors on B cells in the progressive phase of CLL. After incubation of normal lymphocytes with alpha 1 thymosin, we observed an increase of T8 receptors, no change in expression of T11, and a decrease of T4 receptors along with the increase of the intensity of T-cell functional reactivity. In contrast, in CLL patients following incubation with alpha 1 thymosin, the induction of T8 receptors was less prominent in the progressive than in the stable phase of disease. Furthermore, induction of T8 receptors in CLL patients in the stable phase was accompanied by recovery of impaired or increase of preserved functional T-cell reactivity. In the progressive phase, however, T-cell functional areactivity remained unchanged. The findings suggest that different levels of B-cell-differentiation arrest along with defective maturation of T cells might be responsible for the spectrum of disease evolution in CLL.     

Class-specific regulation of anti-DNA antibody synthesis and the age-associated changes in (NZB x NZW)F1 hybrid mice

Investigations of regulatory helper and suppressor T cells in the in vitro anti-DNA antibody synthesis in NZB x NZW (B/W) F1 hybrid mice were initiated by the development of an in vitro system in which G10-passed B cells from B/W F1 mice were cocultured with mitomycin C-treated T cells in the presence of Con A and either in the presence or in the absence of LPS. It was revealed that each IgG and IgM anti-DNA antibody synthesis was under the regulation of separate L3T4+ helper and Ly-2+ suppressor T cells. The function of these class-specific regulatory T cells was age-dependent. Although the helper effect of L3T4+ T cells on IgG antibody synthesis increased, the effect of L3T4+ T cells on IgM antibody production decreased in B/W F1 mice with aging. The IgG anti-DNA antibody production in the cocultures of L3T4+ T cells and B cells was suppressed by addition of Ly-2+ T cells from young but not aged B/W F1 mice, whereas the production of IgM anti-DNA antibodies was suppressed by Ly-2+ T cells from aged but not young B/W F1 mice. We also found that although IgM anti-DNA antibody-producing B cells were already present in 2-mo-old mice, B cells producing IgG antibodies under the influence of L3T4+ T cells appeared in mice at 7 mo of age. These data clearly indicate that separate class-specific regulatory T cells are involved in the production of IgM and IgG anti-DNA antibodies and that the total serum level of the antibodies is reflected by both their age-associated changes and the generation of antibody-forming B cells in B/W F1 mice.     

The thymus microenvironment in regulating thymocyte differentiation

The thymus plays a crucial role in the development of T lymphocytes by providing an inductive microenvironment in which committed progenitors undergo proliferation, T-cell receptor gene rearrangements and thymocyte differentiate into mature T cells. The thymus microenvironment forms a complex network of interaction that comprises non lymphoid cells (e.g., thymic epithelial cells, TEC), cytokines, chemokines, extracellular matrix elements (ECM), matrix metalloproteinases and other soluble proteins. The thymic epithelial meshwork is the major component of the thymic microenvironment, both morphologically and phenotypically limiting heterogeneous regions in thymic lobules and fulfilling an important role during specific stages of T-cell maturation. The process starts when bone marrow-derived lymphocyte precursors arrive at the outer cortical region of the thymic gland and begin to mature into functional T lymphocytes that will finally exit the thymus and populate the peripheral lymphoid organs. During their journey inside the thymus, thymocytes must interact with stromal cells (and their soluble products) and extracellular matrix proteins to receive appropriate signals for survival, proliferation and differentiation. The crucial components of the thymus microenvironment, and their complex interactions during the T-cell maturation process are summarized here with the objective of contributing to a better understanding of the function of the thymus, as well as assisting in the search for new therapeutic approaches to improve the immune response in various pathological conditions.Key words: thymus, T-cell maturation, thymic microenvironment, thymocyte differantiation, chemokines, extracellular matrix, thymic nurse cells, metalloproteinases     

Regional Ultrastructural Differences in Basal Laminae Isolated from the Starfish Pisaster ochraceus

The ultrastructure of different regions of the basal laminae isolated from 5-1/2-6 day-old embryos of the starfish, Pisaster ochraceus , has been described after fixation in the presence of anionic dyes. Isolated basal laminae from all regions of the embryo exhibit a lamina lucida and lamina densa. No lamina fibroreticularis is present. Instead, a coarse meshwork of thick densely stained and thinner intermediately stained fibers is embedded in the lamina densa and extends into the blastocoel forming the extracellular matrix. The coarse meshwork associated with the ectodermal basal lamina consists primarily of thick densely stained fibers with a small number of intermediate ones while that associated with the endodermal one contains much less densely stained material. These structures were morphologically identical to those found in control embryos. Examination of different regions of the endodermal basal lamina shows that the amount of dense material varies from region to region. These differences in dense material may reflect biochemical differences, particularly of proteoglycans, which could provide positional information to migrating mesenchyme cells.     

Characterization of a T-cell clone recognizing idiotypes as tumor-associated antigens

Although heterogeneous T cells recognizing idiotypic determinants have been demonstrated to occur spontaneously in vitro or to be expanded by immunization with antigen or idiotype, their in vitro propagation and cloning was not successful. These previous studies have relied extensively on soluble immunoglobulin to induce proliferation of idiotype-specific T cells. This report describes a unique approach to obtain a stable T-cell clone specific for a monoclonal beta 2-6 fructosan binding myeloma ABPC48 (BALB/c origin), bearing well-defined A48 regulatory idiotopes. Following repeated immunizations with ABPC48 myeloma protein of C.B/R3 mice (H-2d, VHb, CHa), which differ only in the VH locus from BALB/c mice (H-2d, VHa CHa), several stable T-cell clones were obtained after stimulation in vitro with ABPC48 myeloma cells. The proliferation of a T-cell clone A48.B2 was observed with irradiated myeloma cells or hybridomas producing antibodies bearing A48 idiotype encoded by genes deriving from the VH 441-4 family. Proliferation of the clone did not occur with soluble ABPC48 myeloma protein or with Sepharose 4B-bound ABPC48 myeloma protein. Both anti-A48Id and anti-Iad monoclonal antibodies can specifically inhibit the proliferation of this clone when stimulated with ABPC48 myeloma cells. These results demonstrate recognition of idiotypes on B-cell tumours by T cells and implicate the role of class II major histocompatibility complex determinants in this cellular interaction.     

Secretions of anti-myelin-associated glycoprotein antibodies by B cells from patients with neuropathy and nonmalignant monoclonal gammopathy

Four patients with peripheral neuropathy and nonmalignant monoclonal gammopathy with anti-myelin-associated glycoprotein (MAG) antibodies were studied to determine whether secretion of anti-MAG IgM antibodies by B cells was autonomous, or whether the monoclonal B cells were responsive to T cells. Secretion of anti-MAG IgM by isolated B cells was stimulated by the addition of increasing numbers of pokeweed mitogen (PWM)-activated autologous OKT4+ helper T cells in all four patients. Secretion of anti-MAG IgM by peripheral blood lymphocytes was dependent on the ratio of OKT4+ T helper cells to OKT8+ T suppressor/cytotoxic cells. In three patients with an OKT4+ to OKT8+ T-cell ratio of 2:1, PWM activation stimulated secretion of anti-MAG IgM; in one patient with an OKT4+ to OKT8+ ratio of 1:2, activation by PWM suppressed anti-MAG IgM secretion. These studies suggest that the monoclonal B cells that secrete anti-MAG IgM are responsive to regulatory T cells.     

Characterizing T cell movement within lymph nodes in the absence of antigen

The recent application of two-photon microscopy to the visualization of T cell movement has presented trajectories of individual T cells within lymphoid organs both in the presence and in the absence of Ag-loaded dendritic cells. Remarkably, even though T cells largely move along conduits of the fibroblastic reticular cell network, they appear to execute random walks in lymphoid organs rather than chemotaxis. In this study, we analyze experimental trajectories of T cells using computer simulations of idealized random walks. Comparisons of simulations with experimental data provide estimates of key parameters that characterize T cell motion in vivo. For example, we find that the distance moved before turning is about twice the distance between intersections in the fibroblastic reticular cell network, suggesting that at an intersection a T cell will turn onto a new fiber approximately 50% of the time. Although the calibrated model appears to offer an accurate representation of T cell movement, it has also uncovered inconsistencies across different experimental data sets.     

Paradoxical inhibition of T-cell function in response to CTLA-4 blockade; heterogeneity within the human T-cell population

T-cell co-stimulation delivered by the molecules B7-1 or B7-2 through CD28 has a positive effect on T-cell activation, whereas engagement of cytotoxic T-lymphocyte antigen 4 (CTLA-4) by these molecules inhibits activation. In vivo administration to mice of blocking monoclonal antibodies or Fab fragments against CTLA-4 can augment antigen-specific T-cell responses and, thus, therapy with monoclonal antibody against CTLA-4 has potential applications for tumor therapy and enhancement of vaccine immunization. The effects of B7-1 and B7-2 co-stimulation through CD28 depend on the strength of the signal delivered through the T-cell receptor (TCR) and the activation state of T cells during activation. Thus, we sought to determine whether these factors similarly influence the effect of B7-mediated signals delivered through CTLA-4 during T-cell activation. Using freshly isolated human T cells and Fab fragments of a monoclonal antibody against CTLA-4, we demonstrate here that CTLA-4 blockade can enhance or inhibit the clonal expansion of different T cells that respond to the same antigen, depending on both the T-cell activation state and the strength of the T-cell receptor signal delivered during T-cell stimulation. Thus, for whole T-cell populations, blocking a negative signal may paradoxically inhibit immune responses. These results provide a theoretical framework for clinical trials in which co-stimulatory signals are manipulated in an attempt to modulate the immune response in human disease.     

The thymus microenvironment in regulating thymocyte differentiation

The thymus plays a crucial role in the development of T lymphocytes providing an inductive microenvironment in which committed progenitors undergo proliferation, T-cell receptor gene rearrangements and thymocyte differentiation into mature T-cells. The thymus microenvironment forms a complex network of interaction that comprises non lymphoid cells (e.g., thymic epithelial cells, TEC), cytokines, chemokines, extracellular matrix elements (ECM), matrix metalloproteinases and other soluble proteins. The thymic epithelial meshwork is the major component of thymic microenvironment, both morphologically and phenotypically limiting heterogeneous regions in thymic lobules and fulfilling an important role during specific stages of T-cell maturation. The process starts when bone marrow–derived lymphocyte precursors arrive at the outer cortical region of the thymic gland and begin to mature into functional T lymphocytes that will finally exit the thymus and populate the peripheral lymphoid organs. During their journey inside the thymus, thymocytes must interact with stromal cells (and their soluble products) and extracellular matrix proteins to receive appropriate signals for survival, proliferation and differentiation. The crucial components of the thymus microenvironment and their complex interactions during the T-cell maturation process with the objective of contributing to a better understanding of the function of the thymus as well as assist in the search for new therapeutic approaches to improve the immune response in various pathological conditions are summarized here.     

Human immunodeficiency virus type 1 assembly, budding, and cell-cell spread in T cells take place in tetraspanin-enriched plasma membrane domains

Human immunodeficiency virus type-1 (HIV-1) egress from infected CD4+ T cells is thought to be via assembly and budding at the plasma membrane and may involve components of the T-cell secretory apparatus, including tetraspanins. However, many studies on HIV-1 assembly have examined the trafficking of viral proteins in isolation, and most have used immortalized epithelial, fibroblastic, or hematopoietic cell lines that may not necessarily reflect natural infection of susceptible T cells. Here we have used immunofluorescence and cryoimmunoelectron microscopy (CEM) to examine protein transport during HIV-1 assembly in productively infected Jurkat CD4+ T cells and primary CD4+ T cells. The HIV-1 envelope glycoprotein (Env) and the core protein (Gag) colocalize strongly with CD63 and CD81 and less strongly with CD9, whereas no colocalization was seen between Env or Gag and the late endosome/lysosomal marker Lamp2. CEM revealed incorporation of CD63 and CD81 but not Lamp2 into virions budding at the plasma membrane, and this was supported by immunoprecipitation studies, confirming that HIV-1 egress in T cells is trafficked via tetraspanin-enriched membrane domains (TEMs) that are distinct from lysosomal compartments. CD63, CD81, and, to a lesser extent, CD9 were recruited to the virological synapse (VS), and antibodies against these tetraspanins reduced VS formation. We propose that HIV-1 promotes virus assembly and cell-cell transfer in T cells by targeting plasma membrane TEMs.     

Ultrastructural localization of concanavalin A receptors in the plasma membrane: association with underlying actin filaments

Whole-mount cell preparations of cultured rat 3Y1 cells were examined by stereo electron microscopy to identify the ultrastructural localization of concanavalin A (Con A) receptors in the plasma membrane, and to clarify the relationship between Con A receptors and cytoskeletal components. Well spread monolayer cells were extracted with saponin, briefly fixed, and then partially broken open with shearing force to facilitate the introduction of antibodies for identification of actin filaments. Stereo electron microscopy of such treated cells revealed a 3-dimensional image of filamentous structures such as fine filaments, microtubules (MT) and endoplasmic reticulum (ER) in the flattened areas of each cell. Just beneath the plasma membrane were meshworks of actin-containing fine filaments, as identified by an immunogold staining method. Microtubules and ER were observed to be either directly or indirectly associated with this meshwork. The broken open part of each cell exhibited a meshwork of filaments which were associated with the cytoplasmic surface of the plasma membrane. Some of the filaments were connected to the plasma membrane either by their ends or by their lateral surfaces. The localization of Con A receptors was examined by binding colloidal gold-labelled Con A to the surface of fixed, saponin-extracted cells. Virtually all gold particles bound externally at the same membrane sites where intracellular actin filaments attached internally. The observations strongly suggest that the distribution of Con A receptors was regulated by the underlying meshwork of actin filaments.     

Assessing the replicative history of human T cells

Upon encountering antigen, T cells clonally expand and differentiate into effector cells that directly or indirectly eliminate antigen-bearing pathogens. When renewed contact with the same pathogen occurs the immune response is mounted in a faster and more accurate way, a process that is referred to as immunological memory. The basis for T-cell memory is at least partially provided by an enhanced precursor frequency of antigen-specific T cells, and an increased responsiveness of primed T cells to activation signals. In contrast to B cells, which acquire mutations in the immunoglobulin genes after antigenic challenge, somatic markers are lacking that distinguish unprimed (or naive) from primed (encompassing memory and effector) T cells. Instead, differential expression of cell surface molecules on subsets of T cells and measures for replicative history can be used to obtain insight into the antigen-driven development of the T-cell compartment. Apart from fundamental issues addressing lineage relationships between naive, memory and effector T cells and the cellular basis for long-term T-cell memory, these types of studies have proved to be valuable in understanding T-cell reconstitution in situations of severe T-cell depletion, i.e., after chemotherapy, treatment with depleting CD4 monoclonal antibodies or during HIV infection.