Lymphoid and non-lymphoid cells in nasal-associated lymphoid tissue (NALT) in the rat

Summary Lymphocyte and macrophage subpopulations and the stroma of mucosa-associated lymphoid tissue in the nasal cavity of the rat were examined by application of immunohistochemical and enzyme histochemical methods to cryostat sections. Nasal-associated lymphoid tissue was composed of a loose reticular network with lymphocytes and macrophages, covered by epithelium. The epithelium was infiltrated with B cells, T helper (W3/13-positive) and T suppressor/cytotoxic or large granular cells (OX8-positive), ED1-positive macrophages and Ia-positive cells. The B cell areas were populated by B cells, immunopositive for surface IgM or IgG. B cells with surface IgA or IgE were rare. Germinal centres were found infrequently. T helper cells were scattered throughout the B cell area. A few ED1-positive macrophages and ED5-positive follicular dendritic cells were observed. Strong Ia staining (mostly of B cells) was found in this area. The T cell areas contained T helper and T suppressor/cytotoxic cells in about equal amounts, and numerous ED1-positive macrophages. ED1 staining was also found in the subepithelial area. Numerous ED1-, ED2- and ED3-positive macrophages were found in the border between the lymphoid mass and the surrounding connective tissue. A few non-lymphoid cells showed weak acid phosphatase or non-specific esterase activity. The morphological observations suggest that nasal-associated lymphoid tissue plays an important role in the first contact with inhaled antigens.     

Regeneration of splenic tissue after autologous subcutaneous implantation: Development of non-lymphoid cells in the white pulp of the rat spleen

Summary Regeneration of splenic tissue after autologous subcutaneous implantation provides a useful model for studying the development of splenic tissue. The development of the various non-lymphoid cells of the white pulp in the rat is described. It appears that regeneration of the implants is initiated by ingrowing vessels and a newly formed reticulum, which forms the microenvironment for the homing lymphocytes. Marginal metallophils are found at their characteristic location at the inner border of the marginal sinus five weeks after implantation. Trapping of antigen-antibody complexes reappears when the first primary follicles can be recognized.     

Enhancement of antigen-presenting function of dendritic cells with culture supernatants of mouse peritoneal macrophages stimulated with certain particulate substances

The production from murine resident peritoneal macrophages (M phi) of a soluble factor, which was capable of enhancing the antigen-presenting (AP) function of dendritic cells (DC), was examined. The supernatants of peritoneal M phi (M phi sup) were prepared by culturing peritoneal M phi with particles, i.e., zymosan A, latex, and sheep red blood cells (SRBC), or antigen-antibody (Ag-Ab) complexes such as keyhole limpet hemocyanin (KLH)-anti-KLH, ovalbumin (OVA)-anti-OVA, and SRBC-anti-SRBC complexes. When exposed to M phi sup during antigen pulsing DC induced a marked antigen-specific T cell proliferation, relative to DC treated with the supernatants from M phi cultured without stimuli (control sup). On the other hand, M phi sup-treated splenic M phi stimulated antigen-specific T cell activation to almost the same extent as did splenic M phi treated with control sup. These results indicated that peritoneal M phi elaborated a soluble factor which preferentially enhanced the AP capacity of DC when stimulated with particles or Ag-Ab complexes. Analytical gel filtration of M phi sup revealed that the factor had an apparent molecular weight of 27,000 daltons which was distinct from interleukin 1.     

Characterization of non-lymphoid cells in the white pulp of the mouse spleen: An in vivo and in vitro study

Summary Non-lymphoid cells (marginal metallophils, follicular immunecomplex-retaining cells, interdigitating cells), which are present in certain areas of the white pulp in the mouse spleen were characterized by means of (immuno)enzyme histochemical techniques, carbon uptake and experiments with lethal X-irradiation. Marginal metallophils are clearly present at the inner border of the marginal zone and show a very strong, E-600 sensitive, non-specific esterase (NSE) activity. Follicular immune-complex-retaining cells show a weak and diffuse NSE activity and no carbon uptake as shown by the combined application of an immunohistoperoxidase technique (for the demonstration of immune complexes), enzyme histochemistry (for NSE activity) and carbon uptake (for phagocytosis). Interdigitating cells show a distinct focus of NSE activity in the cytoplasm, weak carbon uptake and high radiation sensitivity. Demonstration of NSE activity is useful for the identification of the different non-lymphoid cells in the white pulp of the mouse spleen. It is suggested that the in vitro observed dendritic cells of Steinman and Cohn (1973) belong to the mononuclear phagocyte system, as transitional cells are encountered with cytological features of both dendritic cells and macrophages. These in vitro dendritic cells (or a portion of them) are probably similar to the interdigitating cells.Abbreviations HRP horseradish peroxidase - IDC interdigitating cells - PALS periarteriolar lymphocytic sheath - NSE non-specific esterase     

An immunohistochemical study on the postnatal development of rat nasal-associated lymphoid tissue (NALT)

Summary This study concerns the development of nasal-associated lymphoid tissue in the rat, using immuno- and enzyme-histochemical staining techniques on cryostat sections. Nasal-associated lymphoid tissue is present at birth as a small accumulation of mainly T lymphocytes and non-lymphoid cells; B cells are rare. Distinct areas of T and B cells appear at 10 days after birth; by that time high endothelial venules are also observed. Intra-epithelial lymphocytes are present, most of them being T-helper cells. ED1+ macrophages are seen throughout the tissue. The proportion of ED1+cells does not change during ontogeny. ED2+cells (tissue macrophages) are present predominantly at the border between the lymphoid tissue and the surrounding connective tissue, in all age-groups. ED3+mononuclear cells are scattered throughout the nasal-associated lymphoid tissue of young animals. Later on, the ED3+ cells migrate into the border-area between lymphoid and connective tissue. Ia+ non-lymphoid cells in the nasal lymphoid tissue increase in number during ontogeny. Only a few of them show acid phosphatase activity, indicating that the proportion of classical scavenger macrophages is low. Some of them may be antigen presenting (dendritic) cells. Ia+ dendritic cells also occur between the epithelial cells. Moreover, some epithelial cells express the Ia marker.     

Characterization of nonspecific esterase activity in macrophages and intestinal epithelium of the rat.

We determined the histochemical characteristics of nonspecific esterase in different populations of rat macrophages. The cells included alveolar and peritoneal macrophages recovered by lavage and a mixed cell population obtained by collagenase digestion of the small intestine. The histochemically localized enzyme activity of alveolar and peritoneal macrophages was cytoplasmic, diffuse, and inhibited by sodium fluoride. Both populations were effectively stained using alpha-naphthyl acetate and alpha-naphthyl butyrate as the esterase substrate. When the intestinal cells were examined for activity, a greater percentage of cells showed positive nonspecific esterase than would be predicted by differential counts for macrophages on the basis of morphological criteria. We confirmed, using cell smears and tissue sections, that rat intestinal epithelial cells, a prominent component of the isolated cell population, possessed esterases that react similarly to macrophage esterases with histochemical procedures.     

Macrophage requirements of CR- and CR+ B lymphocytes for antibody production in vitro.

A Sephadex G-10 column coated with antigen-antibody complexes and complement retains complement receptor-bearing (CR+) mouse spleen cells. The effluent is rich in thymus-derived cells (T cells), and contains bone marrow-derived cells (B cells) which carry surface immunoglobulin (Ig), Ir-associated antigen (Ia), and Fc receptors, but no complement receptors (CR-). Although both unfractionated and CR- B cell populations are capable of producing antibody to red cell antigens, they differ in their requirements for the initiation of the response. Unfractionated B cells cooperate with primed as well as unprimed helper T cells; macrophages are required for this cooperation but can be replaced by 2-mercaptoethanol. CR- B cells cooperate with primed but not with unprimed T cells provided macrophages are added to cultures. After addition of culture supernatant from BCG-activated macrophages CR- B cells cooperate with both unprimed and primed T helper cells.     

Feedback regulation of immune responses by immune complexes; possible involvement of a suppressive lymphokine by FcR gamma-bearing B cell

Inoculations of antigen-antibody complexes (immune complexes) with the intact Fc portion generates suppressor cells in vivo by binding to FcR gamma on B cells via Fc portions. The cell type responsible for the suppression appears to be B cells bearing FcR gamma. Neither T cells nor macrophages participate in both the inductive and effective phases of this type of regulation. The suppression caused by splenic B cells, previously stimulated with immune complexes in vivo, is mediated by humoral factor(s) released from them. The suppressive factor(s) have H-2 gene product(s) coded by the right-hand side of the H-2 gene complex, but not for FcR gamma themselves or immunoglobulins. It has shared component(s) with suppressive B cell factor (SBF) released from FcR gamma + B cells stimulated with immune complexes in vitro, and it resembles SBF in its mode of action. These findings indicate that immune complexes, the final products of antibody responses, control the immune responses by stimulating surface FcR gamma on B cells. It is of interest that this type of regulation functions in vivo.     

Immunological properties of Fc receptor on lymphocytes. 5. Suppressive regulation of humoral immune response by Fc receptor bearing B lymphocytes.

High anti-DNP PFC responses to DNP-DE or DNP-KLH were obtained by transferring normal or primed FcR^? B cell fractions into irradiated syngeneic recipients. On the other hand, the FcR⁺ B cell fraction showed a low precursor activity. Trypsinization of the FcR⁺ B cells, to eliminate remaining antigen-antibody complexes on the surface, failed to augment the response in comparison with that of trypsin-untreated FcR⁺ B cells. Therefore, the weak precursor activity of FcR⁺ B cells seemed to be inherent. No synergistic interaction between the FcR⁺ B and precursor FcR^? B cells, to give rise to the maximum PFC response, was observed. On the contrary, the FcR⁺ B cells significantly suppressed the PFC responses of FcR^? B cells. This kind of suppression could be mediated by a factor released from the FcR⁺ B cell, but not from the FcR^? B or original-unrosetted spleen cell fraction. The factor was not attributable to macrophages, because the FcR⁺ B cells isolated from normal spleen cells, of which macrophages were depleted by Sephadex G-10 columns, could produce the factor with the same activity. Stimulation by specific antigen is not necessary for the induction of the factor(s) as well as of the suppressing FcR⁺ B cells. It seems to be necessary to stimulate FcR by antigen-antibody complexes to produce or release this factor.     

实验性大鼠肝癌组织中NOS之分布及意义

以酶组织化学方法对实验性大鼠肝癌组织中一氧化氮合酶（ＮＯＳ）的分布进行定位研究。结果显示：原发及转移的肝癌组织癌细胞中ＮＯＳ呈阴性反应,不同类型肝癌组织内未见明显差异,表明ＮＯＳ活性的降低与细胞的恶变相关。提示可作为临床肝癌诊断的一个指标。癌旁肝细胞、Ｋｕｐｆｅｒ细胞及癌组织中的巨噬细胞胞浆呈ＮＯＳ阳性,此处ＮＯ是否属于一种参与活化巨噬细胞杀伤肿瘤细胞的效应分子有待探讨。     

Trapping antigen-antibody complexes within the human placenta

The study was designed to evaluate possible mechanisms for the specific depletion of antifetal antibodies within the human placenta. The principal observations were that endogenous IgG is bound to the same cells to which exogenous antigen antibody complexes attach, i.e., placental macrophages. Moreover, the IgG was demonstrated to be attached to Fcγ receptors on the placental macrophages. Endogenous IgG was completely and specifically displaced by high concentrations of heterologous nonimmune IgG. That the IgG was present as antigen-antibody complexes was evidenced by macrophage receptor affinity, IgG size profile, and C1q binding. The results strongly support the theory that antifetal antibodies are removed by macrophages in the placenta as antigen-antibody complexes in much the same manner as macrophages filter immune complexes from the blood in the liver and spleen.     

The role of Ia antigens and Fc receptor-bearing T-cells in the inhibition of macrophage receptors for cytophilic antibody induced by soluble immune complexes

Soluble antigen-antibody complexes composed of 3 M KCl-extracted L1210 antigens and alloantibody to L1210 given to C3H mice caused immunosuppression in the mice. This was reflected in part by the inhibition of cytophilic antibody receptors on macrophages which could be used as a measure of the suppression. Thymocytes or splenic T cells from mice treated with immune complexes could adoptively transfer the suppression to normal syngeneic mice. These cells, which we have termed suppressor inducers, were found to be Ia positive: specifically, I-A⁺, I-J^?. Thus, treatment of the inducers with anti-la or anti-I-A antibodies and complement in vitro abrogated their ability to transfer the suppression to normal mice. In contrast treatment with anti-I-J serum and complement had no effect. Through a similar approach, the cooperating (acceptor) T cells were found to be I-A⁺, I-J^?. Pretreatment of mice with anti-Ia or anti-I-A serum before the administration of antigen-antibody complexes prevented the inhibition of macrophages. This was due at least in part to steric hindrance of adjacent Fc receptors on the FcR⁺ T cells with which the complexes interacted. Early interaction of immune complexes with FcR⁺ T cells was in fact demonstrated directly by the inability of the complexes to induce suppression when FcR⁺ T cells were depleted. The thymocytes or splenic T cells from anti-Ia-pretreated mice failed to transfer the suppression to recipient mice. In contrast, treatment with either anti-Ia or anti-I-A after the immune complexes did not abrogate the generation of suppressor inducers. Treatment of normal recipient mice with anti-Ia serum in vivo before they received the suppressor inducer cells did not prevent cooperation between the two types of cells. By the same token, blocking of Ia antigens of the inducers in vitro with anti-Ia serum (without complement) also did not impair the cooperative interaction. These results indicate that antigen-antibody complexes generate I-A-positive, I-J-negative T-suppressor inducer cells from FcR⁺ naive T cells. These in turn interact with Ia-positive (I-A⁺ and I-J^?) normal thymocytes or spleen T cells. This interaction most likely generates the ultimate suppressor T cells that suppress cytophilic antibody receptors on macrophages in vivo. However, the I-region determined antigens did not appear to be directly involved in the T-T interaction of suppressor inducer and acceptor cells.     

Non-lymphoid cells of bronchus-associated lymphoid tissue of the rat in situ and in suspension

Immunohistochemical, enzyme-histochemical and electron-microscopical methods were used to study non-lymphoid cells of control and stimulated rat bronchus associated lymphoid tissue (BALT) in situ and in suspensions. Particular attention was paid to the so-called antigen-handling cells, i.e., the interdigitating cells (IDC), which are situated in the T-cell areas, the follicular dendritic cells (FDC), which appear to be restricted to germinal centers, and macrophages, present both in T-cell and B-cell areas. The interdigitating cells were distinguished by being Ia-positive and by the presence of acid phosphatase and non-specific esterase activity in an area near the nucleus. Follicular dendritic cells could be observed in situ by using a monoclonal antibody and by the in vitro trapping of HRP-anti-HRP complexes. Several types of macrophages were found. At the electron-microscopical level no well-developed IDC and FDC could be detected in control BALT. However, in BALT of lipopolysaccharide-stimulated and mycoplasma-infected rats, well-developed IDC and FDC were found. It can be concluded that IDC's and FDC's can be found in BALT.     

The function and origin of follicular dendritic cells

Follicular dendritic cells (dendritic reticular cells) in germinal centres bind antigen-antibody complexes via C3 receptors and retain the complexes at their surface for long periods of time. The follicular dendritic cells (FDC) are distinct from macrophages and from dendritic cells found in T-dependent areas, and are not derived from bone marrow stem cells. On histological evidence it has been proposed that they are derived from reticulum cells. Complexes are probably transported to FDC by a subpopulation of B cells in the marginal zone. Binding of complexes to FDC causes germinal centre enlargement and is a very efficient, and possibly essential stimulus to the generation of B memory cells which recognize epitopes on antigen or antibody in the complexes. An hypothesis is discussed which draws together these observations and suggests that antigen on FDC plays a central role in control of humoral immunity.     

Visualization of antigen on nitrocellulose membrane by the oxidative coupling reaction of N,N'-dimethyl-p-phenylenediamine and 4-chloro-1-naphthol

A method which allows the highly sensitive and simple immunodetection of antigen-antibody complexes on nitrocellulose papers has been developed. The method is a modification of the procedure known as the "Nadi reaction" (oxidative coupling of 1-naphthol and N,N'-dimethyl-p-phenylendiamine) for histochemical purposes. Proteins were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and electrophoretically transferred to nitrocellulose membranes. Bound proteins were first reacted with a primary antibody and then with a horseradish peroxidase-labeled second antibody. The antigen-antibody complexes on the membranes were visualized with the oxidative coupling solution containing N,N'-dimethyl-p-phenylendiamine and 4-chloro-1-naphthol. Sensitivity was enhanced 4 to 16 times by the new method relative to that of the 4-chloro-1-naphthol method or the 3,3'-diaminobenzidine method.     

Spontaneous regression of Friend virus-induced erythroleukemia. III. The role of macrophages in regression.

The spontaneous regression of erythroleukemia induced by the RFV strain of Friend virus is a macrophage-dependent process. Functional suppression or elimination of the macrophage population in leukemic mice with silica, carrageenan, anti-macrophage serum, or trypan blue inhibited regression. Prior protection of the macrophages with PVNO allowed regression in silica or carrageenan-treated mice. Macrophage phagocytic activity was inhibited in about half the RFV-induced leukemic mice at 25 to 30 days post virus inoculation. Those animals with normal macrophages regressed, whereas whereas those with inhibited macrophages did not. Progressor mice could be induced to regress by inoculation with normal syngeneic macrophages; other cell types were ineffective. The inhibition of macrophage function in leukemic mice was the result of infection of the macrophages by virus. Removal of the infected cells by cytolysis with anti-virus antiserum and C restored the phagocytic activity of the population. Inhibited macrophages were less capable of responding to immobilized antigen-antibody complexes than normal macrophages, suggesting that the loss of function was due to a change in their Fc receptor.     

A Protocol for the Comprehensive Flow Cytometric Analysis of Immune Cells in Normal and Inflamed Murine Non-Lymphoid Tissues

Flow cytometry is used extensively to examine immune cells in non-lymphoid tissues. However, a method of flow cytometric analysis that is both comprehensive and widely applicable has not been described. We developed a protocol for the flow cytometric analysis of non-lymphoid tissues, including methods of tissue preparation, a 10-fluorochrome panel for cell staining, and a standardized gating strategy, that allows the simultaneous identification and quantification of all major immune cell types in a variety of normal and inflamed non-lymphoid tissues. We demonstrate that our basic protocol minimizes cell loss, reliably distinguishes macrophages from dendritic cells (DC), and identifies all major granulocytic and mononuclear phagocytic cell types. This protocol is able to accurately quantify 11 distinct immune cell types, including T cells, B cells, NK cells, neutrophils, eosinophils, inflammatory monocytes, resident monocytes, alveolar macrophages, resident/interstitial macrophages, CD11b^- DC, and CD11b⁺ DC, in normal lung, heart, liver, kidney, intestine, skin, eyes, and mammary gland. We also characterized the expression patterns of several commonly used myeloid and macrophage markers. This basic protocol can be expanded to identify additional cell types such as mast cells, basophils, and plasmacytoid DC, or perform detailed phenotyping of specific cell types. In examining models of primary and metastatic mammary tumors, this protocol allowed the identification of several distinct tumor associated macrophage phenotypes, the appearance of which was highly specific to individual tumor cell lines. This protocol provides a valuable tool to examine immune cell repertoires and follow immune responses in a wide variety of tissues and experimental conditions.     

Characterization of the population of phagocytic cells in thymic cell suspensions

Rat thymic phagocytic cells were characterized in vitro using various light- and electron-microscopical techniques. Thymic cell suspensions were mechanically prepared and enriched for non-lymphoid cells, which were predominantly phagocytic and of three types. Type I showed acid phosphatase (APh) activity in small granules dispersed throughout the cytoplasm and were mostly Ia antigen-positive, although the Ia membrane label varied in intensity and distribution among individual cells. Only a few cells had endogenous peroxidase activity. The type-I cells could not be clearly distinguished morphologically from type-II or -III cells, and most likely comprise precursors of both these cell types. Type-II were large pale cells with many slender cell processes. These cells had APh activity centrally positioned, were strongly positive for Ia on the cell membrane and were negative for endogenous peroxidase. The cytoplasm frequently contained Birbeck granules, which unequivocally classifies these cells as the in vitro equivalent of the interdigitating cells present in the medullary area of the thymus in situ. Type-III cells were rounded with a smooth or ruffled cell membrane and contained vacuoles and many phagolysosomes. They were strongly positive for APh which was present throughout the cytoplasm. About 50% of these cells were positive for endogenous peroxidase in a pattern resembling resident macrophages. The cells were negative for Ia antigens. Type-III cells mostly likely represent the macrophages found in the cortical area of the thymus.     

Immunocytochemical demonstration of the binding and internalization of growth hormone in GERL of Chang hepatoma cells

Summary The binding and internalization of endogenous growth hormone in Chang hepatoma cells were localized on the cell surface and in the Golgi-endoplasmic reticulum-lysosome (GERL) area by various indirect immunocytochemical labeling techniques, namely, peroxidase or colloidal gold conjugated to secondary antibody, and avidin-biotin complex methods. Rabbit antiserum and monoclonal antibodies raised against HPLC-purified porcine growth hormone were used in this study. In fixed material, antigen-antibody complexes were found to be homogeneously distributed along the cell membrane. Control groups showed negative binding on the cell surface. Trypsin treatment before immunolabeling removed antibody binding completely, but hyaluronidase was ineffective. Pretreatment of lectins did not block the recognition of primary antibody to antigen molecules on cell surface. Internalization of the antigen-antibody peroxidase or gold complexes was demonstrated in the cells, which were immunolabeled at 4°C, and then reincubated for 0–30 min at 37°C before fixation. After reincubation, the internalized ligand complexes were found in vesicles near the cell surface or in the GERL area near the Golgi apparatus which, however, did not label for peroxidase. These findings suggest that the trypsin-sensitive growth hormone, specifically bound and internalized into Chang hepatoma cells, is localized in the GERL instead of the Golgi apparatus and might be involved in the mechanism of tumor cell growth.     

Leukocytes as immunosensors: An immunoassay without labelled reagents

A novel quantitative nonlabel immunoassay is described. It is based on the recognition of antigen-antibody complexes by the Fc-receptors of phagocytic leukocytes and the subsequent activation of these cells. Activation which is proportional to the amount of immune complexes present can be detected by measuring the intensity of chemiluminescence emitted by the activated cells. In addition to determinations of an antigen and an antibody, the binding capacity of complement to antigen-antibody complexes can be estimated.