Areas Of Secondary Lymphoid Organs Research Articles

Wiskott-Aldrich syndrome: current research concepts.

Wiskott-Aldrich syndrome: current research concepts.

Maturation of dendritic cells induced by cytokines and haptens.

Recently, elucidation has progressed on a crucial role played by dendritic cells (DCs) in the induction of primary antigen-specific immune reactions. Although mature DCs exhibit potent antigen presenting function, DCs are scattered in nonlymphoid organs throughout the body as immature cells that have only minimum antigen presenting function. When they are stimulated to maturate, they increase their expression of class II major histocompatibility (MHC) antigen and several co-stimulatory molecules, resulting in the augmentation of antigen presenting function. Furthermore, these maturated DCs move to the T-dependent areas of secondary lymphoid organs to sensitize naive T cells for these antigens. Therefore, it is important to understand the mechanism to induce the maturation of DCs. Recent progress in the study of DC biology depicts various factors, such as cytokines, bacterial products and haptens, which are responsible for DC maturation. In this paper, the mechanism of DC maturation induced by cytokines and chemicals is described.

Geographical considerations regarding donor leukocyte infusions for the treatment of relapsed hematological malignancies.

Infusion of donor leukocytes, to provoke graft-versus-host disease and a graft versus leukemia effect, is remarkably effective in the treatment of some forms of relapsed hematological malignancies after transplantation of allogeneic stem cells. In this commentary I argue that the variable susceptibility of tumor cells to donor leukocyte infusions can be predicted on the basis of their localization to the T cell areas of secondary lymphoid organs and the amount of donor chimerism in the patient. This conclusion leads to the hypothesis that it may be possible to modulate graft-versus-leukemia reactions in a controlled and predictable fashion.

A dendritic-cell-derived C-C chemokine that preferentially attracts naive T cells.

Dendritic cells form a system of highly efficient antigen-presenting cells. After capturing antigen in the periphery, they migrate to lymphoid organs where they present the antigen to T cells. Their seemingly unique ability to interact with and sensitize naive T cells gives dendritic cells a central role in the initiation of immune responses and allows them to be used in therapeutic strategies against cancer, viral infection and other diseases. How they interact preferentially with naive rather than activated T lymphocytes is still poorly understood. Chemokines direct the transport of white blood cells in immune surveillance. Here we report the identification and characterization of a C-C chemokine (DC-CK1) that is specifically expressed by human dendritic cells at high levels. Tissue distribution analysis demonstrates that dendritic cells present in germinal centres and T-cell areas of secondary lymphoid organs express this chemokine. We show that DC-CK1, in contrast to RANTES, MIP-1alpha and interleukin-8, preferentially attracts naive T cells (CD45RA+). The specific expression of DC-CK1 by dendritic cells at the site of initiation of an immune response, combined with its chemotactic activity for naive T cells, suggests that DC-CK1 has an important rule in the induction of immune responses.

Human dendritic cells skew isotype switching of CD40-activated naive B cells towards IgA1 and IgA2.

Within T cell-rich areas of secondary lymphoid organs, interdigitating dendritic cells recruit antigen-specific T cells that then induce B cells to secrete Igs. This study investigates the possible role(s) of dendritic cells in the regulation of human B cell responses. In the absence of exogenous cytokines, in vitro generated dendritic cells (referred to as Dendritic Langerhans cells, D-Lc) induced surface IgA expression on approximately 10% of CD40-activated naive sIgD+ B cells. In the presence of IL-10 and TGF-beta, a combination of cytokines previously identified for its capacity to induce IgA switch, D-Lc strongly potentiated the induction of sIgA on CD40-activated naive B cells from 5% to 40-50%. D-Lc alone did not induce the secretion of IgA by CD40-activated naive B cells, which required further addition of IL-10. Furthermore, D-Lc skewed towards the IgA isotype at the expense of IgG, the Ig production of CD40-activated naive B cells cultured in the presence of IL-10 and TGF-beta. Importantly, under these culture conditions, both IgA1 and IgA2 were detected. In the presence of IL-10, secretion of IgA2 by CD40-activated naive B cells could be detected only in response to D-Lc and was further enhanced by TGF-beta. Collectively, these results suggest that in addition to activating T cells in the extrafollicular areas of secondary lymphoid organs, human D-Lc also directly modulate T cell-dependent B cell growth and differentiation, by inducing the IgA isotype switch.

Functional CD40 antigen on B cells, dendritic cells and fibroblasts.

During antigen specific immune responses, antigen specific naive B cells undergo a cascade of events including activation, expansion, mutations, isotype switch, selections and differentiation into either antibody secreting plasma cells or memory B cells. These antigendependent events occur in different areas of secondary lymphoid organs, as well as other non-lymphoid organs. It requires the interaction of B cells with antigens and numerous cell types including T cells, dendritic cells (DC) and follicular dendritic cells (FDC). These cells interact with B cells through different cell surface molecules and through the release of polypeptidic mediators called cytokines.

Functional CD40 on B lymphocytes and dendritic cells

B lymphocytes, generated through a process called lymphopoiesis in foetal liver and bone marrow, migrate into peripheral lymphoid organs (lymph nodes, spleen, tonsils) as mature sIgD+ sIgM+ B cells which are also referred to as naive B cells. During antigen-specific immune responses, antigen-specific naive B cells undergo a cascade of events including activation, expansion, mutations, isotype switch, selections and differentiation into either antibodysecreting plasma cells or memory B cells. These antigen-dependent events occur in different areas of secondary lymphoid organs, as well as other nonlymphoid organs. This requires the interaction of B cells with antigens and numerous cell types including T cells, dendritic cells (DC) and follicular dendritic cells (FDC). These cells interact with B cells through different cell surface molecules and through the release of polypeptidic mediators called cytokines.

Molecular control of B lymphocyte growth and differentiation.

During antigen driven immune responses, antigen-specific naive B lymphocytes undergo a cascade of events including activation, expansion, mutations, isotype switch, selections and differentiation into either antibody secreting plasma cells or memory B cells. These antigen-dependent events, which we propose to call immunopoiesis, occur in different areas of secondary lymphoid organs, as well as other nonlymphoid organs. B cells interact with antigens and numerous cell types (T cells, dendritic cells, follicular dendritic cells and macrophages) through numerous cell surface molecules and cytokines. B cells costimulated through their antigen receptor and cytokines such as interleukin 2 (IL-2), IL-4 and IL-10 undergo limited proliferation and differentiation into immunoglobulin (Ig) secreting cells. In contrast, crosslinking of the B cell CD40 antigen, a member of the tumor necrosis factor (TNF) receptor family, results in major cellular activation further modulated by cytokines. In particular, IL-4 and IL-13 permit establishment of long-term factor-dependent B cell lines, as well as isotype switch towards the production of IgE and IgG4. Addition of IL-10 to CD40-activated B cells results in limited proliferation and remarkable differentiation into plasma cells. IL-10 also participates in isotype switch towards IgG1, IgG3 and IgA. The ligand for CD40, a member of the TNF family, is transiently expressed on activated T cells, and interrupted CD40/CD40-L interactions result in profoundly altered humoral immune responses.

Intrathyroidal dendritic cells.

The presence, marker pattern, and ultrastructure of antigen-presenting dendritic cells were studied in normal thyroid glands from 9 subjects (6 obtained at surgery; 3 at autopsy) and in the thyroid glands form 13 patients with Graves' hyperthyroidism, 10 patients with simple nontoxic goiter, and 1 patient with Hashimoto's disease (all obtained at surgery). The immunohistochemical characterization of the cells was carried out using the monoclonal antibodies OKIa (class II MHC determinants), RFD1 and L25. These latter monoclonal antibodies react strongly with active dendritic cells in T-cell areas of secondary lymphoid organs (the interdigitating cells in lymph nodes and spleen). Antigen-presenting dendritic cells were defined as cells with an eccentric reniform nucleus, long cytoplasmic protrusions, and strong membrane-bound class II MHC positivity combined with little or no cytoplasmic acid phosphatase activity. According to these criteria normal human thyroid tissue contained a few dendritic cells; they were localized outside the thyroid follicles. These dendritic cells in normal thyroid tissue lacked the marker molecules identified by the monoclonal antibodies RFD1 and L25. In fact, the majority of the dendritic cells were strongly positive for the C3bi receptor (identified by the monoclonal antibody FK 24), which indicates a more monocyte/macrophage character of the cell. In Hashimoto's goiter, Graves' disease, and sporadic nontoxic goiter (which we consider an autoimmune thyroid disease) the numbers of dendritic cells were higher compared to those in the normal gland, and these dendritic cells were clearly positive for RFD1 and L25. The cells were often seen in contact with a few intrathyroidal lymphocytes, forming small lymphoid cell clusters. They were also found in the T-cell zones of larger well organized intrathyroidal lymphoid structures (focal thyroiditis). On ultrastructural examination the dendritic cells in Graves' glands, Hashimoto's goiter, and sporadic nontoxic goiter were similar to the interdigitating cells present in secondary lymphoid organs. The data suggest active involvement of dendritic cells in the immune process in the thyroids of patients with autoimmune thyroid disease.

Antigen-driven selection of virgin and memory B cells.

This review has summarized the evidence indicating that far more B cells are produced in adult bone marrow than are required to maintain B cell numbers in the periphery. It is shown that most if not all these newly-formed B cells have the potential to become mature peripheral B cells. However, to do this they need to receive an appropriate signal in secondary lymphoid organs. Cells failing to receive such a signal die after a brief period. Two separate situations have been identified which result in recruitment of newly-formed virgin B cells into the peripheral B-cell pool: Following activation by antigen. When the peripheral B-cell pool has been depleted. It is proposed that the first of these signals requires T help and is initiated by antigen presented on interdigitating cells in extrafollicular areas of secondary lymphoid organs. This process seems to be confined to periods immediately following administration of antigen and does not continue in established immune responses to thymus-dependent antigens. It seems probable that continued B cell activation, occurring during long term antibody responses, takes place in the follicles of secondary lymphoid organs and is driven by antigen presented on follicular dendritic cells. Indirect evidence is cited which suggests that somatic mutation in rearranged immunoglobulin V-region genes occurs mainly following B-cell activation in follicles and not during primary B lymphopoiesis. It is suggested that this may involve a hypermutation process which is switched on in activated B cells in germinal centers. Evidence is presented suggesting that plasma cells generated from B cells activated early in immune responses have an average life-span of less than 3 d. However, plasma cells generated in established responses appear to have an average life-span in excess of 20 d. Later sections in the review consider how B-cell recruitment in thymus-independent antibody responses differs markedly from recruitment during thymus-dependent responses. The possible role of splenic marginal zone B cells in some thymus-independent antibody responses is discussed and the evidence indicating that SIgM + ve, IgD-ve marginal zone B cells develop as a distinct population from recirculating SIgM + ve, IgD + ve B cells is summarized.