Histology of the bone marrow antibody response

The histology of the specific and non-specific antibody response in mouse and rat bone marrow was studied after subcutaneous priming and intravenous boosting with horseradish peroxidase (HRP). Cells producing specific antibody against HRP were found only occasionally in the bone marrow after subcutaneous priming. After the intravenous boost injection their number gradually increased. These anti-HRP forming cells were found as single cells, randomly dispersed throughout the bone marrow. Such a random distribution was also found for cytoplasmic (non-specific) immunoglobulin containing cells. At no time point after immunization could lymphoid aggregates or trapping of immune complexes be observed in the bone marrow of either species. On the basis of these observations it is concluded that the bone marrow forms a suitable microenvironment for immigrating antibody-forming cells but does not contribute actively to the induction of the immune response.     

Changes occurring in the epithelium covering the bronchus-associated lymphoid tissue of rats after intratracheal challenge with horseradish peroxidase

Summary Changes occurring in the epithelium covering bronchus-associated lymphoid tissue (BALT) in the rat after several intratracheal administrations of horseradish peroxidase (HRP) were studied using morphological and ultrastructural methods. The epithelium is invaded by W3/ 25-positive (T-helper) lymphocytes, the BALT epithelial cells become Ia-positive and develop microvilli; there is an apparent loss of cilia. The number of non-ciliated cells in stimulated BALT increases. The non-ciliated cells can be subdivided into two cell types, one with electron-dense cytoplasm and cytoplasmic granules and the other without granules. The electron-density of the latter cell type is intermediate between that of the ciliated cells and that of the granulecontaining non-ciliated cells. The granule-containing cell types may be responsible for the uptake of antigens, while the other non-ciliated cell may be involved in the production of the secretory component and the passage of secretory IgA.Supported by a research grant from the Nederlands Astma Fonds     

Double immunocytochemical staining in the study of antibody-producing cells in vivo. Combined detection of antigen specificity (anti-TNP) and (sub)class of intracellular antibodies

Mice and rabbits were immunized with trinitrophenyl (TNP)-conjugated keyhole limpet hemocyanin (KLH). Cells producing specific antibodies against the hapten TNP were detected in vivo in spleen and lymph nodes using a TNP--alkaline phosphatase (AP) conjugate. Using horseradish peroxidase (HRP)-conjugated anti-mouse (sub)class (IgG2A, IgG2B, IgM) antibodies and anti-rabbit class (IgG, IgM) antibodies and a double immunocytochemical staining technique for simultaneous demonstration of the enzymes AP and HRP, we were able to determine both the antigen specificity (anti-TNP) and the (sub)class of intracellular antibodies produced by individual antibody-forming cells in vivo.     

IgE antibody-forming cells in rats infected with Nippostrongylus brasiliensis and immunized with antigens

The distribution of IgE antibody-forming cells was examined in rats infected with Nippostrongylus brasiliensis (Nb) or immunized with Nb antigen or with OA. The frequency of antigen-specific IgE antibody-forming cells was detected by a passive cutaneous anaphylactic (PCA) reaction using cell extract from lymphoid organs. In Nb-infected rats, anti-Nb and anti-4th stage larvae (L4) IgE-forming cells distributed mainly in the mesenteric and the bronchial lymph nodes (LN) near the parasite-harboring sites. After intraperitoneal (ip) immunization with Nb antigen mixed with Al(OH)3 and Bordetella pertussis (Bp) as adjuvants, anti-Nb IgE antibody-forming cells were detected in the mesenteric and the bronchial LN. Anti-Nb or OA IgE antibody-forming cells after subcutaneous (sc) immunization were found in the inguinal and the axillary LN. An effect of Bp on the distribution of IgE antibody-forming cells seems to be ruled out. The distribution of IgG2a antibody-forming cells was similar to that of IgE antibody-forming cells, indicating that the distribution of the IgE antibody-forming cells is not preferential. IgE antibody-forming cells were stimulated in the regional LN near the site of antigen administration. IgE antibody-forming cells induced by potentiated IgE antibody production were also examined. Rats were immunized ip or sc with OA and infected with Nb. Anti-OA IgE antibody-forming cells were found in all of the lymphoid organs and especially in the regional LN near the Nb parasite-harboring and antigen administration sites.     

Migration of specific antibody-forming cells during the secondary immune response against horseradish peroxidase

Mice were primed subcutaneously in the hind footpads with horseradish peroxidase (HRP) and boosted intravenously 10 weeks later. Removal of the popliteal lymph nodes (draining the site of primary immunization) before the booster injection markedly depressed the secondary immune response in the spleen and bone marrow. This was taken as evidence that the secondary humoral immune response against HRP in the spleen and bone marrow is largely dependent upon immigration of cells from the popliteal lymph nodes after the booster injection. In rats primed subcutaneously in the hind footpads with HRP, antibody-forming cells were demonstrated in the blood, but not in the thoracic duct lymph 3 days after an intravenous booster injection with HRP.     

Appearanc of cytotoxic cells within the bronchus after local infection with herpes simplex virus.

Cells from rabbit spleens, bronchial washings (BW) and bronchus-associated lymphoid tissues (BALT) were examined for their ability to lyse cells infected with herpes simplex virus (HSV). Specific lysis of HSV-infected cells was mediated by BW cells as early as 4 days after intratracheal infection of the rabbits with the virus whereas lysis by spleen cells and BALT cells was not detected until 7 or more days after infection. Lysis by spleen cells was initially detected 7 days after intraperitoneal injection of the virus but lysis by BW and BALT cells was not observed until 14 days after infection. Although spleen, BW, and BALT cells could lyse antibody-coated target cells, antibodies detectable by antibody-dependent cellular cytotoxicity could not be detected in bronchial washings until 7 or more days after infection. The data suggest that cells capable of direct cytotoxicity of virus-infected cells appear within the bronchus after local infection by the virus.     

In vitro development of a primary antibody response with lymph node cells.

Utilizing a variety of lymphoid tissues from three common laboratory species, comparative studies were performed to investigate the competence of the dissociated cells to respond to a heterologous erythrocyte with the development of specific plaque-forming cells. Dissociated spleen cells harvested from BDF1 mice consistently developed specific plaque-forming cells (PFC) to sheep red blood cells (SRBC), while hamster spleen cells inconsistently developed specific antibody-forming cells to SRBC. Under identical conditions, guinea pig spleen cells did not develop significant numbers of PFC to SRBC. However, lymph node cell cultures of all three species tested yielded specific PFC. In the mouse and hamster lymph node cell cultures, the yield of PFC per culture or per 10⁶ recovered viable cells was always greater than the yield from companion spleen cell cultures. Guinea pig mesenteric lymph node cell cultures developed the major PFC response to SRBC, while both mesenteric and peripheral lymph node cell cultures from hamsters were equivalent in their response to SRBC. The data demonstrate that it is possible to develop a primary antibody response to SRBC in vitro utilizing normal endogenous hamster or guinea pig lymphoid cells, if lymph nodes are the source of cells.     

What is the clinical relevance of different lung compartments?

The lung consists of at least seven compartments with relevance to immune reactions. Compartment 1 - the bronchoalveolar lavage (BAL), which represents the cells of the bronchoalveolar space: From a diagnostic point of view the bronchoalveolar space is the most important because it is easily accessible in laboratory animals, as well as in patients, using BAL. Although this technique has been used for several decades it is still unclear to what extent the BAL represents changes in other lung compartments. Compartment 2 - bronchus-associated lymphoid tissue (BALT): In the healthy, BALT can be found only in childhood. The role of BALT in the development of the mucosal immunity of the pulmonary surfaces has not yet been resolved. However, it might be an important tool for inhalative vaccination strategies. Compartment 3 - conducting airway mucosa: A third compartment is the bronchial epithelium and the submucosa, which both contain a distinct pool of leukocytes (e.g. intraepithelial lymphocytes, IEL). This again is also accessible via bronchoscopy. Compartment 4 - draining lymph nodes/Compartment 5 - lung parenchyma: Transbronchial biopsies are more difficult to perform but provide access to two additional compartments - lymph nodes with the draining lymphatics and lung parenchyma, which roughly means "interstitial" lung tissue. Compartment 6 - the intravascular leukocyte pool: The intravascular compartment lies between the systemic circulation and inflamed lung compartments. Compartment 7 - periarterial space: Finally, there is a unique, lung-specific space around the pulmonary arteries which contains blood and lymph capillaries. There are indications that this "periarterial space" may be involved in the pulmonary host defense. All these compartments are connected but the functional network is not yet fully understood. A better knowledge of the complex interactions could improve diagnosis and therapy, or enable preventive approaches of local immunization.     

Appendix and γM-antibody formation: VII. Rosette-forming cells in rabbits immunized with sheep erythrocytes

After intravenous immunization with sheep red blood cells the rabbit spleen shows a sharp rise in the number of plaque-forming cells but there is no detectable rise in PFC in the appendix or mesenteric lymph node of the same animals. Repeated immunization via an appendicostomy blind loop results in virtually no local PFC and only a small rise in splenic PFC.In lethally irradiated animals neither thymocytes nor appendix cells alone restore the splenic PFC response. Simultaneous injection of the two cell types restores both direct and indirect plaque formation. The injected cells were labeled with tritiated adenosine and a standard rosette assay for specific antigen-binding cells applied to recipients' spleen cells following immunization. Rosettes appeared by 3 days after immunization whether thymocytes or appendix cells were labeled. Labeled rosettes were observed only in animals receiving labeled appendix cells.This result demonstrates the presence of rosette forming cell precursors in rabbit appendix cell populations and suggests that the cells of gut-associated lymphoid tissues include antibody-forming cell precursors which are normally seeded to the spleen and draining lymph nodes.     

Induction of B cell priming by neonatal injection of mice with thymic-independent (type 2) antigens.

Mice injected at birth with the thymus-independent type 2 antigen TNP-AECM-Ficoll have augmented anti-TNP antibody responses when their spleen cells subsequently are challenged in vitro with TNP-coupled thymic independent or thymic dependent antigens. This neonatal priming effect was shown to occur in neonatal nu/nu mice and thus does not appear to require T lymphocytes. The primary explanation for the priming effect seems to be an increase of approximately 10-fold in the numbers of TNP-specific precursors of antibody-forming cells. The neonatal injection of TNP-AECM-Ficoll induces little or no antibody formation directly. It appears, therefore, that some thymic independent antigens can deliver a signal to immature B cells, which causes clonal expansion, but is unable to induce differentiation into antibody-forming cells.     

Relationship of germinal centers in lymphoid tissue to immunologic memory. VI. Transfer of B cell memory with lymph node cells fractionated according to their receptors for peanut agglutinin

We isolated germinal center B cells by exploiting their high affinity for peanut agglutinin (PNA). The PNA+ and PNA- B cells, fractionated by panning on PNA-coated petri dishes, were examined for their ability to transfer memory responses to irradiated recipients at various times after priming. With such fractionated B cells from lymph nodes taken at the peak of germinal center formation, the largest response was obtained in recipients of the PNA+ B cell population. At 4 to 5 wk after priming, and 10 days after challenge with an unrelated antigen, memory responses were approximately equal in recipients of PNA+ or PNA- B cells. At 14 wk after priming, memory responses were found only in recipients of the PNA- B cell population. Memory B cells from the spleen, taken from mice primed in the footpad 8 wk earlier, were also PNA-. Finally, we show that boosting with a TNP-conjugate in the footpad, 6 mo after priming in the same footpad, induced the reappearance of marked memory responsiveness in the PNA+ B cell fraction of the draining node.     

Multigene DNA priming-boosting vaccines protect macaques from acute CD4+-T-cell depletion after simian-human immunodeficiency virus SHIV89.6P mucosal challenge

We evaluated four priming-boosting vaccine regimens for the highly pathogenic simian human immunodeficiency virus SHIV89.6P in Macaca nemestrina. Each regimen included gene gun delivery of a DNA vaccine expressing all SHIV89.6 genes plus Env gp160 of SHIV89.6P. Additional components were two recombinant vaccinia viruses, expressing SHIV89.6 Gag-Pol or Env gp160, and inactivated SHIV89.6 virus. We compared (i) DNA priming/DNA boosting, (ii) DNA priming/inactivated virus boosting, (iii) DNA priming/vaccinia virus boosting, and (iv) vaccinia virus priming/DNA boosting versus sham vaccines in groups of 6 macaques. Prechallenge antibody responses to Env and Gag were strongest in the groups that received vaccinia virus priming or boosting. Cellular immunity to SHIV89.6 peptides was measured by enzyme-linked immunospot assay; strong responses to Gag and Env were found in 9 of 12 vaccinia virus vaccinees and 1 of 6 DNA-primed/inactivated-virus-boosted animals. Vaccinated macaques were challenged intrarectally with 50 50% animal infectious doses of SHIV89.6P 3 weeks after the last immunization. All animals became infected. Five of six DNA-vaccinated and 5 of 6 DNA-primed/particle-boosted animals, as well as all 6 controls, experienced severe CD4(+)-T-cell loss in the first 3 weeks after infection. In contrast, DNA priming/vaccinia virus boosting and vaccinia virus priming/DNA boosting vaccines both protected animals from disease: 11 of 12 macaques had no loss of CD4(+) T cells or moderate declines. Virus loads in plasma at the set point were significantly lower in vaccinia virus-primed/DNA-boosted animals versus controls (P = 0.03). We conclude that multigene vaccines delivered by a combination of vaccinia virus and gene gun-delivered DNA were effective against SHIV89.6P viral challenge in M. nemestrina.     

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 antigen-induced selective recruitment of specific T lymphocytes to the lung

The purpose of the present studies was to investigate the mechanisms by which specific T lymphocytes accumulate in the lung. After the intratracheal (IT) inoculation of influenza virus into guinea pigs, the detection of specific T lymphocytes in the lung coincided with the development of immunity in both hilar nodes and systemic lymphoid tissue. Animals immunized in the footpads with virus failed to develop immune responses in the lung unless rechallenged IT with immunogen. In adoptive transfer experiments, IT inoculation of influenza into nonimmune guinea pigs, followed immediately by the i.v. injection of a mixture of 3H-thymidine-labeled syngeneic T lymphocytes specific for influenza virus and 14C-thymidine-labeled syngeneic T lymphocytes specific for an irrelevant antigen resulted in the selective accumulation of the virus-specific T lymphocytes in the lung. Taken together, these studies indicate that the selective recruitment by antigen of circulating immune cells is one of the mechanisms by which specific T cells accumulate in the lung.     

Rapid development of T cell memory

Prime-boost immunization is a promising strategy for inducing and amplifying pathogen- or tumor-specific memory CD8 T cell responses. Although expansion of CD8 T cell populations following the second Ag dose is integral to the prime-boost strategy, it remains unclear when, after priming, memory T cells become competent to proliferate. In this study, we show that Ag-specific CD8 T cells with the capacity to undergo extensive expansion are already present at the peak of the primary immune response in mice. These early memory T cells represent a small fraction of the primary immune response and, at early time points, their potential to proliferate is obscured by large effector T cell populations that rapidly clear Ag upon reimmunization. With sufficient Ag boosting, however, secondary expansion of these memory cells can be induced as early as 5-7 days following primary immunization. Importantly, both early and delayed boosting result in similar levels of protective immunity to subsequent pathogen challenge. Early commitment and differentiation of memory T cells during primary immunization suggest that a short duration between priming and boosting is feasible, providing potential logistic advantages for large-scale prime-boost vaccination of human populations.     

Immunodominance in the T-Cell response to multiple non-H-2 histocompatibility antigens

Immunization of C57BL/6 mice with BALB.B spleen cells in vivo and subsequent boosting in mixed lymphocyte culture result in the generation of cytolytic T lymphocytes (CTLs) which are specific for a limited number of immunodominant antigens. Experiments are described which suggest the existence of a hierarchy of immunodominance in this donor: host combination. Two antigens, CTT-1.3 and CTT-2.3, are dominant in the C57BL/6 anti-BALB.B CTL response. The distribution of these antigens among CXB recombinant inbred (RI) strains suggests that they segregate as single gene traits. Elimination of the CTT-1.3 and CTT-2.3 antigens by complementation in the responder, or elimination from the priming and boosting stages by the selection.of CXB RI strain mice as responders or stimulators, reveals a second level of immunodominant antigens which include CTT-3.3 and CTT-4.3. CXB mice which express one of the CTT-1.3 or CTT-2.3 antigens will produce CTLs specific for the other antigen upon priming and boosting with BALB.B cells. Expression of both antigens in responders results in the generation of CTLs specific for the second level, dominant antigens. Immunodominance is not confined to the C57BL/6 anti-BALB.B system but can also be observed in the BALB.B anti-C57BL/6 and B10.D2 anti-DBA/2 systems. Finally, generation of CTLs following priming and boosting with dominant and dominated antigens presented on different cells confirmed that immunodominance can only be observed when the dominant and dominated antigens are presented on the same cells. These observations suggest that immunodominance is revealed at the level of antigen-presenting cells primarily involved in vivo priming.     

Cellular immune responses of mice to influenza virus infection

Mice infected with influenza virus develop cytotoxic T lymphocytes (CTL) specific for viral antigens prior to the appearance of virus-specific antibody-forming cells (AFCs). Effector T cells were detected at a time coincident with a precipitous decline in pulmonary virus titer. CTLs of draining lymph nodes and spleen were found to be cross-reactive among H-2 compatible cells infected with influenza type A virus subtypes. AFCs were observed to be primarily hemagglutinin specific. Virus-specific IgA-secreting AFCs were detected in mediastinal lymph nodes of infected mice.     

Double-enzyme conjugates, producing an intermediate color, for simultaneous and direct detection of three different intracellular immunoglobulin determinants with only two enzymes

A new double-enzyme conjugate was synthesized by coupling alkaline phosphatase (AP) to horseradish peroxidase (HRP). After AP (blue) and subsequent HRP (red) cytochemistry, this new conjugate produced a stable intermediate-colored (violet) product. By coupling this double-enzyme conjugate to an antigen (trinitrophenyl, TNP) or an antibody (anti-mouse immunoglobulin G2a), anti-TNP or -IgG2a-producing cells could be demonstrated as violet cells in spleen sections. This led to the development of a rapid one-step incubation--two-step cytochemical procedure for simultaneous detection of three different determinants in a single tissue section. To demonstrate this novel triple staining method, we coupled three different antigens to, respectively, AP, HRP, and AP-HRP. When spleen sections of immunized animals were incubated with a mixture of these three antigen-enzyme conjugates, we could distinguish antibody-forming cells against each of these three antigens simultaneously as red (HRP), blue (AP), and violet (AP-HRP) cells. The simultaneous detection of three different classes of intracellular antibodies in a single section also proved to be possible with this method. With this study we provide a new direct method for detection of three different intracellular immunoglobulins after a one-step incubation and a two-step standard cytochemical procedure.     

The kinetics of antigen-reactive cells during lymphocyte recruitment

Lymphocyte recruitment, the increased traffic of lymphocytes from blood to lymph which occurs within antigenically stimulated lymph nodes, was monitored in the efferent lymph of single lymph nodes in sheep after immunization with allogeneic lymphocytes or purified protein derivative. Specific antigen-reactive cells were assayed by their ability to proliferate in vitro in the presence of the priming antigen. During lymphocyte recruitment such cells were no longer detected in the efferent lymph draining either the immunized node or a nonstimulated node remote from the region of antigen administration. These results probably reflect the selective removal of specific lymphocytes from the recirculating pool. Alternatively, the findings could involve a state of specific unresponsiveness of the cells.     

Low incidence of bronchus-associated lymphoid tissue (BALT) in chronically inflamed human lungs.

The relevance of bronchus-associated lymphoid tissue (BALT) in man is still under discussion. Animal experiments indicate that the development of BALT is dependent on microbial stimulation. Therefore, the incidence of BALT was investigated retrospectively in specimens removed during surgical procedures on patients with chronic pulmonary inflammation. All these patients had severe chronic bronchitis and bronchiectasis, but BALT was found in only 8%. In patients with BALT and a malignant tumor, occlusion of a bronchus with poststenotic pneumonia was always present and BALT was observed exclusively in areas peripheral to the occlusion. In man other compartments of the lung must be responsible for the immune function of BALT found in animals.