Identification of human peripheral T cell antigens.

A new type of differentiation antigens on human T cells was demonstrated by using a heterologous anti-human T cell serum (ATS). This type of antigen, referred to as human peripheral T cell antigen (HPTA), was found on peripheral T cells and medullary thymocytes, but not on cortical thymocytes and B cells. The percentage of ATS-reactive lymphocytes in human peripheral lymphoid organs was correlated with that of cells rosetting with sheep erythrocytes, but contrasted with the number of B cells defined by the presence of a complement (C) receptor or by rabbit anti-human B cell serum (ABS). ATS also reacted with T cells purified by nylon fiber column filtration but ABS did not. Chronic lymphocytic leukemia cells rosetted with either sheep erythrocytes or erythrocyte-antibody-complement complexes were lysed by ATS and ABS, respectively. Mitogenic responses of blood lymphocytes to phytohemagglutinin (PHA) and concanavalin-A (Con A) were abrogated by treating them with ATS and C, whereas ABS suppressed only their response to Con A. Although numerous thymus cells rosetted with SRBC, only 14% were reactive with ATS. Quantitative absorption studies demonstrated that HPTA content of the thymus cells was much lower than that of lymph node cells. Anatomical localization of ATS-reactive lymphocytes in human lymphoid organs studied by immunofluorescence indicated that they were present in the thymus-dependent paracortical areas of lymph node and in the medullary region of thymus. ABS, on the other hand, did not stain thymocytes but reacted selectively with the cells located in the lymphoid follicles of lymph node. These data, together with that from cell suspension studies, confirmed that HPTA were shared between medullary thymocytes and peripheral T cells.     

Immunohistochemical characterization of nurse cells in normal human thymus.

Lymphoepithelial complexes known as thymic "nurse" cells (TNC) have been isolated and described in the thymus of several animal species including man. Most of the investigations on TNC have been carried out in enzymatically digested thymuses in which TNC were isolated by differential sedimentation. In the present study we demonstrate TNC in immunohistochemically stained sections of human thymus as ring-shaped cells completely enclosing thymocytes and localized not only in the cortex, but also at the corticomedullary junction where they have not been previously described. TNC expressed epithelial markers [low and high molecular weight keratins identified by 35 beta H11 and 34 beta E12 monoclonal antibodies, a cortical antigen shared with neuroectodermal neoplasms recognized by the GE2 monoclonal antibody, and tissue polypeptide antigen (TPA:B1)], class II histocompatibility antigens (HLA-DR), and thymosin alpha 1. Double staining experiments with the nuclear proliferation-associated antigen Ki-67 and the cortical epithelium marker GE2 showed that most thymocytes enclosed in these cortical TNC were not proliferating. The antigens expressed by TNC indicate that not only cortical, but also medullary epithelial cells are part of the TNC system. The possible role of TNC in the education and maturation of thymocytes is discussed.     

Immunohistology of lymphoid and non-lymphoid cells in the thymus in relation to T lymphocyte differentiation

The present paper reports the distribution of lymphoid and non-lymphoid cell types in the thymus of mice. To this purpose, we employed scanning electron microscopy and immunohistology. For immunohistology we used the immunoperoxidase method and incubated frozen sections of the thymus with 1) monoclonal antibodies detecting cell-surface-differentiation antigens on lymphoid cells, such as Thy-1, T-200, Lyt-1, Lyt-2, and MEL-14; 2) monoclonal antibodies detecting the major histocompatibility (MHC) antigens, H-2K, I-A, I-E, and H-2D; and 3) monoclonal antibodies directed against cell-surface antigens associated with cells of the mononuclear phagocyte system, such as Mac-1, Mac-2, and Mac-3. The results of this study indicate that subsets of T lymphocytes are not randomly distributed throughout the thymic parenchyma; rather they are localized in discrete domains. Two major and four minor subpopulations of thymocytes can be detected in frozen sections of the thymus: 1) the majority of cortical thymocytes are strongly Thy-1+ (positive), strongly T-200+, variable in Lyt-1 expression, and strongly Lyt-2+; 2) the majority of medullary thymocytes are weakly Thy-1+, strongly T-200+, strongly Lyt-1+, and Lyt-2- (negative); 3) a minority of medullary cells are weakly Thy-1+, T-200+, strongly Lyt-1+, and strongly Lyt-2+; 4) a small subpopulation of subcapsular lymphoblasts is Thy-1+, T-200+, and negative for the expression of Lyt-1 and Lyt-2 antigens; 5) a small subpopulation of subcapsular lymphoblasts is only Thy-1+ but T-200- and Lyt-; and 6) a small subpopulation of subcapsular lymphoblasts is negative for all antisera tested. Surprisingly, a few individual cells in the thymic cortex, but not in the medulla, react with antibodies directed to MEL-14, a receptor involved in the homing of lymphocytes in peripheral lymphoid organs. MHC antigens (I-A, I-E, H-2K) are mainly expressed on stromal cells in the thymus, as well as on medullary thymocytes. H-2D is also expressed at a low density on cortical thymocytes. In general, anti-MHC antibodies reveal epithelial-reticular cells in the thymic cortex, in a fine dendritic staining pattern. In the medulla, the labeling pattern is more confluent and most probably associated with bone-marrow-derived interdigitating reticular cells and medullary thymocytes. We discuss the distribution of the various lymphoid and non-lymphoid subpopulations within the thymic parenchyma in relation to recently published data on the differentiation of T lymphocytes.     

Structure, biosynthesis, and polymorphism of chicken MHC class II (B-L) antigens and associated molecules

Chicken MHC class II (B-L) antigens were immunoprecipitated by the monoclonal antibody TaP1 from inbred chicken splenic leukocytes and a lymphoblastoid B cell line (RP9), and were studied by two dimensional gel electrophoresis. B-L antigens are composed of one alpha and one beta chain that are noncovalently bound at the cell surface. In all haplotypes studied, a single acidic 34,000 dalton non-polymorphic chain was observed, whereas two polymorphic chains could be distinguished, differing in both pH and m.w. The alpha-beta heterodimer is associated during its maturation in the cytoplasm with several basic invariant molecules with m.w. ranging from 30,000 to 42,000 daltons. Treatment of cells with tunicamycin and treatment of immunoprecipitated molecules with several glycosidases revealed a complex process of maturation for all of these molecules. The alpha and beta chains undergo a N-glycosylation of complex type, whereas the invariant molecules bear N-linked high mannose glycans, and perhaps also O-linked glycans in the RP9 lymphoblastoid line. Overall, the B-L antigens appear very similar to the HLA-DR and I-E antigens.     

Human T cell antigen expression during the early stages of fetal thymic maturation

Human thymus tissue was examined from 7 wk of gestation through birth for the expression of antigens reacting with a panel of anti-T cell monoclonal antibodies. Additionally, the reactivities of reagents against the transferrin receptor, against leukocytes, against low m. w. keratins, and against major histocompatibility complex antigens were studied on human fetal thymic tissue. Frozen tissue sections were evaluated by using indirect immunofluorescence assays. At 7 wk of gestation, no lymphoid cells were identified within the epithelial thymic rudiment; however, lymphoid cells reacting with both antibody 3A1, a pan T cell marker, and antibody T200, a pan leukocyte reagent, were identified in perithymic mesenchyme. After lymphoid colonization of the thymic rudiment at 10 wk of fetal gestation, fetal thymic tissue reacted with antibodies T1, T4, and T8. At 12 wk of gestation, antibodies T3, T6, A1G3 (anti-p80, a marker of mature thymocytes), and 35.1 (anti-E rosette receptor) all reacted with thymic tissue. Our findings indicate that T cell antigens were acquired sequentially on thymocytes at discrete stages during the first trimester of human fetal development. The 3A1 antigen was present on fetal lymphocytes before lymphoid cell colonization of thymic epithelium, suggesting that passage through the thymus was not required for the expression of the 3A1 antigen by T cell precursors. The appearance of mature T cell antigens, T3 and p80, on thymocytes by 12 wk of gestation implies that the T cell antigen repertoire may be established in the thymus during the first trimester. Thus, a critical period of T cell maturation appears to occur between 7 and 12 wk of human fetal gestation.     

Detection of thymic surface antigens and radioactive labeling of mouse lymphoid cells.

A method for the permanent and simultaneous detection of tissue-specific surface antigens and internal radioactive labeling of mouse lymphoid cells is described. Target cells were first reacted with a mouse-derived "antithymocyte serum", incubated with peroxidase-conjugated rabbit serum against mouse immunoglobulins and placed in a substrate solution that leads to staining of the antigen-positive cells. Radioactive labeling was demonstrated by autoradiography performed after the antigen assay. More than 90% of antigen-positive thymocytes could be specifically stained in the assay without staining of similarly treated antigen-negative cells. Autoradiographic grains could be detected over both antigen-positive and antigen-negative cells.     

Cell lineage segregation during bursa of Fabricius ontogeny

The population dynamics of myeloid and lymphoid lineages during bursa of Fabricius ontogeny were analyzed by immunofluorescence by using two monoclonal antibodies (mAb). CL-1 mAb reacts with all chicken hemopoietic cells, except mature erythrocytes. L22 mAb reacts with bursa and bursa-derived lymphocytes, with a minor subset of macrophages and with some cells of the thymic medulla. The staining of embryonic bursas by these antibodies helps to distinguish between two different lineages of hemopoietic cells: CL-1+/L22+ cells represent B lymphocytes and a minor subset of macrophages, while CL-1+/L22- cells correspond to most of the macrophages and to the granulocytes, which disappear at the end of the embryonic life. CL-1+/L22- as well as CL-1+/L22+ cells were first observed outside the bursal rudiment. This indicates that there is a pre-bursal segregation between these two hemopoietic lineages and that two different kinds of precursors colonize the bursal rudiment at about the same time (day 9 for CL-1+/L22- cells and days 9 or 10 for CL-1+/L22+ cells). Moreover our data show that the colonization of the bursal epithelium by hemopoietic precursors is a two-step phenomenon. The first cells which enter belong to the CL-1+/L22- lineage, express Ia-like antigens at a high level, are dendritic in morphology, and represent cells of the macrophage/dendritic cell lineage. They are responsible for the formation of the epithelial bud which are then colonized by a small number of lymphoid precursors which belong to the CL-1+/L22+ lineage. Quail-chick bursa grafting experiments were also performed and the grafts were examined for CL-1 (restricted to chicken hemopoietic cells) and L22 reactivity. These observations confirmed our previous findings about the kinetics of the colonization of bursal rudiment by hemopoietic precursors and give support for a pre-bursal segregation between two hemopoietic pathways.     

Immune complexes of E. coli antigens and maternal IgG in the bursa of Fabricius

The bursa of Fabricius of the chicken is known to be both a primary lymphoid organ and a secondary lymphoid tissue. Bursal follicles are equipped with antigen-trapping follicle-associated epithelium. However, bioactive antigens such as protein and bacteria have not been detected in the bursal parenchyma. By immunoperoxidase staining with a polyspecific antibody (Ab) against Escherichia coli, we detected aggregated E. coli antigens in the medulla of bursal follicles after hatching. The distribution of aggregated E. coli antigens is restricted to the medulla of bursal follicles. The antigens are not found in the spleen or the parenchyma of the caecal tonsil. The bursa is thus a trapping site for E. coli antigens from the external environment. Furthermore, two-color immunostaining clarified that these antigens form immune complexes with maternal IgG (MIgG) and are retained by reticular cells. Additionally, immune complexes in the bursa were shown to induce the rapid development of serum IgM Ab for indigenous E. coli. Our results suggest that immune complexes of MIgG and environmental antigens in the medulla of bursal follicles exert positive effects on B-cell differentiation in the bursa in situ.     

Human thymomas: evidence of immunohistologically defined normal and abnormal microenvironmental differentiation

Fifteen human thymomas were analyzed by immunoperoxidase studies on frozen and paraffin-embedded tissue sections in an attempt to identify the existence of immunologically defined microenvironments. All nine lymphocyte predominant thymomas contained a predominance of lymphocytes bearing the phenotype of cortical thymocytes and dendritic Class II major histocompatibility complex antigen-positive epithelial cells, thus defining cortical-like microenvironments. Medullary-like foci were also seen in all of these cases. Minor phenotypic abnormalities in Leu-2 and -3 antigen expression were seen in three cases. In contrast, the two epithelial predominant thymomas and four mixed thymomas all exhibited features of aberrant microenvironmental differentiation, with only two cases showing demarcation into cortical and medullary foci. A lack of Class II major histocompatibility complex antigens was associated with a decrease in the lymphoid populations and an increase in Leu-1 antigen expression by T cells of otherwise normal cortical phenotype when lymphocytes were present. In contrast, lack of Class I antigen on epithelial cells was not associated with any abnormality in lymphocyte phenotype or microenvironmental organization. We document for the first time abnormal microenvironments in thymomas that may offer insights into understanding normal thymic differentiation.     

Reactivity of monoclonal islet cell antibodies on normal hyperplastic and neoplastic thyroid C-cells

Summary Thyroid C-cell reactivity to 15 monoclonal antibodies raised against a series of pancreatic islet cells (H[human]ISL, B[bovine]ISL and R[rat]ISL) was evaluated using an indirect immunoperoxidase technique on frozen thyroid sections. Of the monoclonal anti-islet cell antibodies, five reacted specifically with bovine C-cells or human hyperplastic and neoplastic C-cells but not with follicular cells. Two monoclonal antibodies of the bovine series showed strong immunoreactivity with C-cells and only a weakly positive immunostaining of follicular cells. Five monoclonal antibodies reacted with both thyroid C-cells and follicular cells, whereas 3 monoclonal anti-islet cell antibodies did not stain any cell type of the thyroid. In human medullary carcinomas, calcitonin- and somatostatin-producing neoplastic cells were immunoreactive with the same monoclonal antibodies as were normal human C-cells. The protein bands identified by the monoclonal antibodies in human medullary carcinomas had the same molecular weight as those from pancreatic islet extracts. Our study demonstrates the presence of similar differentiation antigens on thyroid C-cells and pancreatic islet cells; this further illustrates common modes of differentiation and specialisation of these embryologically different members of the dispersed neuroendocrine system. The crossreactivity of seven of the monoclonal antibodies investigated with follicular epithelium of the thyroid suggests the existence of common antigenic determinants in different endocrine organs and may partly explain the multiple organ autoimmune response found in patients with polyendocrine diseases.     

Evidence for two populations of B-L (Ia-Like) molecules encoded by the chicken MHC

Two specific alloantisera detecting B-L (Ia-like) antigens on chicken lymphocytes of the B ⁶ and B ¹⁵ haplotypes were found to cross-react strongly. Anti-B-L6 and anti-B-L15 alloantisera both reacted with B-L molecules on B6 and B15 lymphocytes as demonstrated by immunofluorescence and SDS-PAGE analysis of ¹²⁵I-labeled B-L antigens isolated by incubation with anti-B-L alloantisera. Absorption studies showed that the anti-B-L alloantisera reacted with at least two kinds of antigenic determinant, one set shared by B-L6 and B-L15 molecules and another set specific for each haplotype. In spite of the absence of genetic evidence for more than one B-L locus in the chicken B complex, it was shown by sequential antibody incubations that these two different B-L antigenic determinants are associated with at least two separate species of B-L molecules, indicating the presence of at least two B-L loci within the MHC of the chicken.     

Immunohistology of thymic nurse cells

The demonstration of thymic nurse cells (TNC), complexes between stromal cells and thymocytes, in cell suspensions of murine thymuses, prompted us to investigate (1) the relationship of TNC to other thymic stromal cell types defined in situ, and (2) the maturation stage of the enclosed thymocytes. To this purpose we incubated frozen sections of TNC suspensions with various monoclonal antisera directed to T cells and stromal cell types, using immunohistology. This approach enabled us to study antigen expression on the "nursing" cell itself and to analyze the phenotype of the enclosed lymphocytes in cross sections of TNC. The results show that lymphocytes enveloped by TNC express high levels of Thy-1, moderate levels of T200, and variable amounts of Lyt-1. Due to enzymatic degradation Lyt-2 expression could not be studied. The enveloped cells also bear PNA receptors, but no detectable I-A/E antigens. Expression of H-2K antigens on enclosed thymocytes varied from weak to absent. The "nursing" cells react with ER-TR4, a monoclonal antibody which detects cortical epithelial-reticular cells. In addition TNC express I-A/E and H-2K antigens. In contrast, TNC do not react with ER-TR 5 and 7, monoclonal antibodies, which detect medullary epithelial cells and reticular fibroblasts, respectively. TNC do not express the macrophage antigens Mac-1 and Mac-2. We conclude that TNC in vitro represent the in vivo association of epithelial-reticular cells with cortical thymocytes. However, the enclosed thymocytes do not constitute a phenotypically distinct subset of subcapsular or outer cortical cells.     

Intracellular antigenic changes associated with meiosis in the orthopteran Stauroderus scalaris.

Monoclonal antibodies have been prepared against purified pachytene cells from grasshopper testes. Immunoblotting and immunofluorescence analyses identified those monoclonal antibodies which showed specificity for antigens in pachytene cells. Several antigenic changes were found to be associated with meiotic cells. Five monoclonal antibodies detected antigens which were located in the cytoplasm of premeiotic cells but were nuclear during meiosis. One monoclonal antibody showed a discrete cytoplasmic fluorescent pattern in meiotic, but not in premeiotic, cells. Another bound specifically to the nuclei of some epithelial cells at the base of follicles in mature testes.     

Mouse monoclonal antibodies to chicken VH idiotypic determinants reactivity with B and T cells

We have prepared mouse monoclonal antibodies against idiotypic (Id) determinants on chicken antibodies to N-acetylglucosamine (NAGA) and p-aminobenzoic acid (PABA) made by inbred line EL 6(3) birds. The monoclonal anti-NAGA Id antibody, termed CId-1, reacted with affinity purified antibodies to NAGA, but not with antibodies specific for PABA, arsanilic acid (Ars), phosphorylcholine (PC), or with normal chicken IgG and IgM. The monoclonal anti-PABA ID antibody, termed CId-2, reacted with anti-PABA antibodies and to a lesser extent with anti-Ars antibodies, but not with anti-NAGA, anti-PC, and normal IgG and IgM. The Id determinants were found among antibodies to NAGA and PABA made by outbred and inbred lines of White Leghorn chickens. The binding of the CId-1 and CId-2 antibodies to intact homologous anti-NAGA and anti-PABA antibodies, respectively, was not hapten-inhibitable in either case. Both anti-Id antibodies reacted specifically with isolated homologous heavy chains, suggesting VH Id specificities. The monoclonal CId-1 and CId-2 antibodies were reactive by immunofluorescence with approximately 0.9 and 0.2%, respectively, of the circulating lymphocytes and with approximately 0.4 and 0.15 of plasma cells. CId-1+ and CId-2+ bursal cells were first detected on the 16th and 14th days of incubation, respectively; both reached maximal frequencies by the 17th day of incubation. The CId-2 antibody reacted exclusively with immunoglobulin-positive cells. The CId-1 antibody also reacted with a subpopulation (0.4%) of immunoglobulin-negative lymphocytes from normal and agammaglobulinemic chickens, and thus would appear to recognize an idiotypic determinant expressed by certain clones of B and T cells.     

The influence of dexamethasone treatment on the lymphoid and stromal composition of the mouse thymus: a flowcytometric and immunohistological analysis

The effect of injection of a range of doses of dexamethasone on the distribution of T-cell subpopulations and stromal cells in the thymus of BALB/c mice was investigated with flowcytometry and immunohistology. To this purpose we used monoclonal antibodies directed to the T-cell differentiation antigens Thy-1, T200, Lyt-1, Lyt-2, T4, MEL-14, and monoclonal antibodies directed to various classes of stromal cells. Injection of dexamethasone in increasing doses of 5-130 mg/kg body weight gradually leads to a depletion of the cortical thymocyte population, i.e., bright Thy-1 + ve, dull T-200 + ve, bright Lyt-2 + ve, and bright T4 + ve cells. These cortical cells are very dull MEL-14 + and express variable numbers of Lyt-1 molecules. Also the medulla is affected by dexamethasone although to a lesser extent. Dexamethasone injection at 130 mg/kg selects for a dull Thy-1 + ve, bright T-200 + ve, and bright Lyt-1 + ve medullary population. These cells are either T4 + ve Lyt-2-ve or T4-ve Lyt-2 + ve. Under these conditions, MEL-14 + ve cells were no longer present in the cortex but accumulated in medullary perivascular spaces. Staining of sequential sections showed that this particular subpopulation has a typical "helper" phenotype. This observation provides strong evidence that perivascular compartments are an exit pathway for emigrating T cells. The medullary population contains a phenotypically distinct, dexamethasone-sensitive subpopulation. This conclusion is based on two findings: 130 mg/kg dexamethasone depletes the thymus of all but 4% of the thymocytes, which form a much smaller subpopulation than the population of dull Thy-1 + ve cells (amounting to 15% of the total thymocytes). The medulla contains a subpopulation of dull Lyt-2 + ve cells, which are resistant to 20 mg/kg dexamethasone, but depleted by 130 mg/kg. Dexamethasone also has a severe effect on thymic nonlymphoid cells. Even at low doses, dexamethasone induces TR4 + ve cortical epithelial-reticular cells to become spherical ("nurse cell-like") structures, depleted of lymphoid cells. These stromal cells no longer express MHC antigens in a membrane-bound fashion. In contrast, the medullary epithelial cells appear morphologically unaffected even at a dexamethasone dose of 130 mg/kg.     

Immunocytochemical detection of dendritic cell by S-100 protein in the chicken.

Positivity for S-100 protein in paraffin embedded chicken lymphoid tissue was found by using a polyclonal antibody against whole bovine S-100 protein. The S-100 protein-containing cells were observed in the locations which have been reported to contain avian dendritic cells such as the medulla of the bursal follicles, and the germinal centers and T-dependent areas in the spleen, Peyer's patches, caecal tonsil and Harderian gland. Positive cells were also found in the location where ellipsoid associated cell have been described, and between epithelial cells covering the Peyer's patches and the caecal tonsil, as well as between the cells lining the ducts within the Harderian gland. Macrophages were devoid of immunostaining. Our results confirm the location described elsewhere for chicken dendritic cells and indicate that S-100 protein can be considered as a cell marker for the identification of the chicken dendritic cell. Intraepithelial positive cells may be interdigitating dendritic cells in an unusual location (their function being the transport of the antigen from the epithelium to the diffuse lymphoid tissue), or cytotoxic T-lymphocytes which, in mammals, are immunoreactive for S-100 protein.     

人体胸腺和周围淋巴器官内T细胞亚群和NK细胞分布的研究

本文用多种Ｔ细胞和ＮＫ细胞单抗和免疫组织化学的ＡＢＣ技术,在冰冻切片上对人扁桃体、淋巴结、牌和胸腺内Ｔ细胞亚群和ＮＫ细胞的分布进行了检测。结果显示,ＣＤ５、ＣＤ８、ＣＤ４、ＣＤ３和ＡＩＧ３阳性细胞主要分布在扁桃体,淋巴结的副皮质区、脾的动脉周围淋巴鞘和胸腺,但各种抗体的反应强度不同。从各种Ｔ细胞工群的染色强度和形状看,胸腺髓质部的胸腺细胞相当于周围淋巴器官内的胸腺依赖区。胸腺内Ｔ细胞在分化过程中,质膜上的抗原也有相应变化。ＮＫ细胞主要分布在淋巴小结的生发中心,淋巴结和扁桃体的副皮质区,脾的红髓以及胸腺的筋质部。这些不同的分布,说明ＮＫ细胞不仅与淋巴小结的活动有关,可能还参与机体的免疫调节功能。     

Two new monoclonal antibodies (LN-1, LN-2) reactive in B5 formalin-fixed, paraffin-embedded tissues with follicular center and mantle zone human B lymphocytes and derived tumors

Two monoclonal antibodies (LN-1, LN-2) reactive with B lymphocytes in B5 formalin-fixed, paraffin-embedded tissue sections have been produced by utilizing cell extracts from pokeweed mitogen-stimulated peripheral blood lymphocytes and diffuse histiocytic lymphoma SU-DHL-4 cells, respectively. Both monoclonal antibodies were initially identified by indirect immunofluorescence screening techniques on paraformaldehyde-acetone-fixed cell preparations. Specificity screens with 36 well-characterized human lymphoma and leukemia cell lines showed that both LN-1 and LN-2 stained cell lines of B cell lineage but were unreactive with those of T cell or, with one exception, myeloid derivation. Null cell acute lymphoblastic leukemia cell lines were found to be LN-2+ but LN-1-. The B cell specificity of these reagents was confirmed on 15 lymphoma and 17 leukemia biopsy specimens by using indirect immunofluorescence techniques. Immunoperoxidase staining of sections from B5-fixed, paraffin-embedded human lymphoid tissues showed that LN-1 bound to the cell membrane and cytoplasm of germinal center cells whereas LN-2 stained the nuclear membrane and cytoplasm of germinal center and mantle zone B lymphocytes as well as interfollicular histiocytes and thymic medullary dendritic cells. Both monoclonal antibodies failed to stain cortical thymocytes, lymph node T cells, and peripheral blood T and myeloid cells. Immunoperoxidase staining of 20 nonlymphoid human organs and tissues revealed that LN-1 reacted positively with red blood cell precursors of the bone marrow, ciliated epithelial cells of the bronchus, distal tubular cells of the kidney, and ductal cells from several organs including the breast and prostate. In contrast, LN-2 was unreactive with all human nonlymphoid organs and tissues including the bone marrow. Indirect immunofluorescence staining of a panel of 26 solid tumor cells lines showed that LN-1 was reactive with the majority of epithelium-derived cell lines, glioblastomas, and astrocytomas but was unreactive with neuroblastomas, small cell carcinoma of the lung, and sarcomas. LN-2 was unreactive with 25 of 26 of the solid tumor cell lines by these techniques. Immunobiochemical studies have shown that LN-1 recognizes a cell surface sialoantigen whereas LN-2 is directed against a 35,000 dalton nuclear membrane protein. Because of their high specificity for B cell tumors and their ability to stain B5-fixed, paraffin-embedded tissues, LN-1 and LN-2 are useful reagents for the diagnosis and classification of the human lymphomas and leukemias.     

Detection of avian hematopoietic cell surface antigens with monoclonal antibodies to myeloid cells : Their distribution on normal and leukemic cells of various lineages

The isolation and characterization of monoclonal antibodies reacting with cell surface antigenic determinants of normal and leukemic avian hematopoietic cells is described. The antibodies were produced by immunizing mice with normal macrophages, as well as with myeloid cells transformed with the avian acute leukemia viruses MC29, AMV and E26. Eleven antibodies were characterized for their reactivity with a variety of normal and leukemic cells of the myeloid, B- and T-lymphoid and of the erythroid cell lineage. Using several methods, they could be subdivided into five distinct types: I. Four antibodies were specific for the myeloid lineage, predominantly reacting with immature myeloid cells. II. One antibody reacted with mature and immature myeloid cells as well as with T-lymphoid cells. III. Four antibodies reacted with myeloid, erythroid and T-lymphoid cells. IV. One antibody reacted with myeloid as well as with T- and B-lymphoid cells. V. One antibody reacted with all kinds of chicken hematopoietic cells except erythrocytes. The first type of antibodies detected glycoproteins with MWs of 170 and 130 kD. The pattern of antigens precipitated varied with the different monoclonal antibodies of this group. The antibody of the fourth type precipitated a 30 kD polypeptide from extracts of myeloid and lymphoid cells. None of the other antibodies precipitated any detectable proteins.     

Macrophage-derived chemokine and EBI1-ligand chemokine attract human thymocytes in different stage of development and are produced by distinct subsets of medullary epithelial cells: possible implications for negative selection

The chemoattractant activity of macrophage-derived chemokine (MDC), EBI1-ligand chemokine (ELC), and secondary lymphoid tissue chemokine (SLC) on human thymocytes was analyzed. Both ELC and SLC caused the accumulation of CD4+CD8- or CD4-CD8+ CD45RA+ thymocytes showing high CD3 expression. By contrast, a remarkable proportion of MDC-responsive thymocytes were CD4+CD8+ cells exhibiting reduced levels of CD8 or CD4+CD8- cells showing CD3 and CD45R0, but not CD45RA. MDC-responsive thymocyte suspensions were enriched in cells expressing the MDC receptor, CCR4, selectively localized to the medulla, and in CD30+ cells, whereas ELC-responsive thymocytes never expressed CD30. Reactivity to both MDC and ELC was localized to cells of the medullary areas, but never in the cortex. Double immunostaining showed no reactivity for either MDC or ELC by T cells, macrophages, or mature dendritic cells, whereas many medullary epithelial cells were reactive to MDC or ELC. However, MDC reactivity was consistently localized to the outer wall of Hassal's corpuscles, whereas ELC reactivity was often found in cells surrounding medullary vessels, but not in Hassal's corpuscles. Moreover, while most MDC-producing cells also stained positive for CD30L, this molecule was never found on ELC-producing cells. We suggest therefore that CD30L-expressing MDC-producing medullary epithelial cells attract CCR4-expressing thymocytes, thus favoring the CD30/CD30L interaction, and therefore the apoptosis, of cells that are induced to express CD30 by autoantigen activation. By contrast, ELC production by CD30L-lacking medullary epithelial cells may induce the migration into periphery of mature thymocytes that have survived the process of negative selection.