Induction of cell-mediated immunity to chemically modified antigens in guinea pigs. I. Characterization of the immune response to lipid-conjugated protein antigens.

Bovine serum albumin (BSA) conjugated with a lipid, dodecanoic acid, is capable of inducing strong delayed-type hypersensitivity (DTH) in guinea pigs. This paper reports experiments on the nature and specificity of this hypersensitivity. The response to lipid-conjugated BSA (L-BSA) was found to be classical DTH, as evidenced by its ability to be transferred passively by immune cells, but not by serum. In addition, special histologic examination of skin test sites demonstrated the characteristics of DTH rather than cutaneous basophil hypersensitivity. Similar results were obtained when lipid-conjugated purified protein derivative of tubercle bacilli (L-PPD) was used. The increased immunogenicity of L-BSA was not caused by the presence of protein aggregates, but seemed to be related to the hydrophobic nature of the conjugated side chains. A series of cross-reacting serum albumins was used for a study of the specificity of the antibody and DTH responses to BSA. It was found that the degree of enhancement of immunogenicity for DTH caused by lipid conjugation varied for different antigenic determinants on BSA.     

Precise localization of antigens on follicular dendritic cells

Summary Horse-spleen ferritin or bovine serum albumin conjugated to colloidal gold (BSA-gold) were injected subcutaneously in preimmunized mice. In draining lymph nodes both antigens were located in macrophages or between the cytoplasmic processes of follicular dendritic cells (FDC). Some of the antigens remained trapped on FDC until day 31 after injection. Simultaneous injection of both antigens showed that they were located between the infoldings of the same FDC. These cells are thus able to retain at least two different antigens on their surface. The peculiar arrangement of ferritin between the cytoplasmic infoldings suggests that this antigen is fixed on both cell membranes by specific antibodies. The trapped immune complexes could thus stabilize the FDC membrane system.The antigen retention requires the presence of specific antibodies since BSA-gold or ferritin injected without preimmunization were not found between FDC processes. Nonantigenic materials, such as colloidal gold or carbon particles, are not trapped by FDC, except when injected in large amounts.The antigens were trapped on the surface of FDC, however unfrequently in close contact with lymphocytes. FDC might protect lymphocytes against an excess of immune complexes and act as regulators of contacts between lymphocytes and immune complexes.Abbreviations BSA bovine serum albumin - BSA-gold BSA conjugated to colloidal gold particles - FDC follicular dendritic cells     

Dendritic cells take up and present antigens from viable and apoptotic polymorphonuclear leukocytes

Dendritic cells (DC) are endowed with the ability to cross-present antigens from other cell types to cognate T cells. DC are poised to meet polymorphonuclear leukocytes (PMNs) as a result of being co-attracted by interleukin-8 (IL-8), for instance as produced by tumor cells or infected tissue. Human monocyte-derived and mouse bone marrow-derived DC can readily internalize viable or UV-irradiated PMNs. Such internalization was abrogated at 4°C and partly inhibited by anti-CD18 mAb. In mice, DC which had internalized PMNs containing electroporated ovalbumin (OVA) protein, were able to cross-present the antigen to CD8 (OT-1) and CD4 (OT-2) TCR-transgenic T cells. Moreover, in humans, tumor cell debris is internalized by PMNs and the tumor-cell material can be subsequently taken up from the immunomagnetically re-isolated PMNs by DC. Importantly, if human neutrophils had endocytosed bacteria, they were able to trigger the maturation program of the DC. Moreover, when mouse PMNs with E. coli in their interior are co-injected in the foot pad with DC, many DC loaded with fluorescent material from the PMNs reach draining lymph nodes. Using CT26 (H-2(d)) mouse tumor cells, it was observed that if tumor cells are intracellularly loaded with OVA protein and UV-irradiated, they become phagocytic prey of H-2(d) PMNs. If such PMNs, that cannot present antigens to OT-1 T cells, are immunomagnetically re-isolated and phagocytosed by H-2(b) DC, such DC productively cross-present OVA antigen determinants to OT-1 T cells. Cross-presentation to adoptively transferred OT-1 lymphocytes at draining lymph nodes also take place when OVA-loaded PMNs (H-2(d)) are coinjected in the footpad of mice with autologous DC (H-2(b)). In summary, our results indicate that antigens phagocytosed by short-lived PMNs can be in turn internalized and productively cross-presented by DC.     

Decreased capacity of recombinant 45/47-kDa molecules (Apa) of Mycobacterium tuberculosis to stimulate T lymphocyte responses related to changes in their mannosylation pattern.

The Apa molecules secreted by Mycobacterium tuberculosis, Mycobacterium bovis, or BCG have been identified as major immunodominant antigens. Mass spectrometry analysis indicated similar mannosylation, a complete pattern from 1 up to 9 hexose residues/mole of protein, of the native species from the 3 reference strains. The recombinant antigen expressed in M. smegmatis revealed a different mannosylation pattern: species containing 7 to 9 sugar residues/mole of protein were in the highest proportion, whereas species bearing a low number of sugar residues were almost absent. The 45/47-kDa recombinant antigen expressed in E. coli was devoid of sugar residues. The proteins purified from M. tuberculosis, M. bovis, or BCG have a high capacity to elicit in vivo potent delayed-type hypersensitivity (DTH) reactions and to stimulate in vitro sensitized T lymphocytes of guinea pigs immunized with living BCG. The recombinant Apa expressed in Mycobacterium smegmatis was 4-fold less potent in vivo in the DTH assay and 10-fold less active in vitro to stimulate sensitized T lymphocytes than the native proteins. The recombinant protein expressed in Escherichia coli was nearly unable to elicit DTH reactions in vivo or to stimulate T lymphocytes in vitro. Thus the observed biological effects were related to the extent of glycosylation of the antigen.     

Recruitment of effector lymphocytes by initiator lymphocytes. Recruited lymphocytes are immunospecific and include graft-versus-host-reactive lymphocytes.

We have shown previously that initiator T lymphocytes (ITL), sensitized in vitro against fibroblast antigens, recruit effector T cells in vivo. After injection into hind footpads of syngeneic recipients, sensitized ITL migrated to the draining popliteal lymph nodes (PLN) and activated a trapping mechanism by which circulating lymphocytes were recruited in the PLN. This paper reports experiments designed to test the immunospecificity of these recruited T lymphocytes (RTL). We found that immunospecific RTL were depleted from other lymphoid organs during recruitment in the PLN. However, immunospecific ITL were not depleted from spleens during PLN recruitment. Thus ITL and RTL are functionally distinguishable. We show that specific GVH reactive lymphocytes were also lost from spleens and distal lymph nodes during trapping of RTL in the PLN. Thus, the trapping phase of the recruitment response is immunospecific, as are the sensitization and effector phases. The trapped RTL are antigen-specific, and include the pool of GVH-reactive-lymphocytes committed to the same alloantigen. Thus, it appears that GVH-reactive cells respond to syngeneic ITL sensitized against allogeneic fibroblasts.     

Lymphocyte traffic through lymph nodes and Peyer's patches of the rat: B- and T-cell-specific migration patterns within the tissue,and their dependence on splenic tissue

The migration routes of lymphocyte subsets through organ compartments are of importance when trying to understand the local events taking place during immune responses. We have therefore studied the traffic of B, T, CD4⁺, and CD8⁺ lymphocytes through lymph nodes and Peyer's patches. At various time points after injection into the rat, labeled lymphocytes were localized, and their phenotype characterized in cryostat sections using immunohistochemistry. Morphometry was also performed, and the recovery of ⁵¹Cr-labeled lymphocytes in these organs was determined. B and T lymphocytes entered the lymph nodes via the high endothelial venules in similar numbers. Most B lymphocytes migrated via the paracortex (T cell area) into the cortex (B cell area), and then back in substantial numbers into the paracortex. In contrast, T lymphocytes predominantly migrated into the paracortex and were rarely seen in the cortex. No obvious differences were seen between various lymph nodes and Peyer's patches and the routes of CD4⁺ and CD8⁺ lymphocytes. After injection of lymphocytes into animals with autotransplanted splenic tissue, the number of B lymphocytes that had migrated into the B cell area of lymph nodes and of Peyer's patches was significantly decreased, whereas CD4⁺ lymphocytes migrated in larger numbers into the T cell area of both organs.This study was supported by the Deutsche Forschungsgemein-schaft (SFB 244, A7).     

Tumor bearer T cells suppress BCG-potentiated antitumor responses. I. Requirements for their effect

Mice bearing established syngeneic tumors fail to reject them when immunized according to protocols based on optimal conditions for BCG potentiation of specific delayed-type hypersensitivity (DTH) and antitumor immunity. Serum factors from mice bearing either the poorly immunogenic mastocytoma, P815 (MA), or the more antigenic sarcoma, Meth A, have been shown to depress both DTH and antitumor immunity. This report demonstrates that lymphoid cells adoptively transferred from these tumor-bearing hosts also can suppress the efferent and afferent phases of DTH to tumor-specific antigens in both BCG-primed and unprimed syngeneic hosts. Suppressor cells (SC) were detected in spleen, thymus, and lymph nodes draining the tumor site, but not in distant superficial lymph nodes. Maximal suppressor activity apeared 6 days after tumor implantation and waned by 18 days. Suppression of the afferent phase of both the BCG-primed and unprimed responses was antigen specific; suppression of the efferent phase of the BCG-primed response was also specific but SC could partially suppress the unprimed responses to sheep red blood cells (SRBC). Amputation of 6-day-old tumors resulted in the disappearance of splenic SC within 2 days but did not affect SC in draining lymph nodes. SC suppressed DTH in a dose-dependent manner but even the highest doses tested did not totally eliminate the response. Depression of the peak DTH reaction was not accompanied by significant abrogation of antitumor activity. If, however, SC were transferred during the ongoing antitumor response, immunity was partially suppressed. Efferentphase SC were sensitive to treatment with anti-Thy 1 sera and complement but were unaffected by B-cell depletion.     

Nonspecific entry of thoracic duct immunoblasts into intradermal foci of antigens

Lymph borne immunoblasts were obtained by collecting thoracic duct lymph from inbred rats 3–5 days after either killed C. parvum, B. abortus or B.C.G. organisms had been injected subcutaneously into the hindquarter regions to stimulate the caudal lymph nodes. By incubating the lymph cells with a radioactive precursor of DNA, 5-iodo-2-deoxyuridine-¹²⁵I, the immunoblasts became labelled but the small lymphocytes did not. The labelled cells were washed and injected intravenously into syngeneic recipients which had had intradermal injections of various antigens at various previous times. The entry of labelled cells into these injection sites was monitored by counting the radioactivity that they contained up to 24 hr later.It was found that the accumulation of radioactivity in the skin lesions was maximal 12 hr after the donor cells had been injected, but the immunological specificity of the donor immunoblasts did not affect significantly the extent to which they entered lesions which contained the same or unrelated antigens. It was found also that the sites of intradermal injections of B.C.G. or C. parvum always attracted more immunoblasts than sites containing other antigens; this was a non-specific effect, thought to be related to the adjuvant properties of these organisms.     

Recruitment of effector lymphocytes by initiator lymphocytes. Circulating lymphocytes are trapped in the reacting lymph node.

In previous studies, we have shown that initiator T lymphocytes (ITL) sensitized in vitro recruit effector T lymphocytes in vivo. When ITL were sensitized against fibroblast antigens in vitro and injected into footpads of syngeneic recipients, they induced enlargement of the draining popliteal lymph node (PLN) and the development there of specific effector lymphocytes of recipient origin. To study the basis of this lymph node response in recruitment, we injected 51Cr-labeled spleen cells i.v. into recipients of sensitized ITL and found that the labeled circulating lymphocytes were trapped in the reacting PLN. The trapping depended on surface properties of the labeled circulating lymphocytes, as revealed by various enzymatic treatments. The trapping process was radiosensitive, both on the part of the trapped lymphocytes and the lymph node-trapping mechanism. Thus, sensitized ITL injected into the hind footpads migrate to the PLN and induce the trapping of circulating recruitable lymphocytes, which either differentiate into or regulate the differentiation of effector T lymphocytes.     

Mitogens and T-independent antigens stimulate T lymphocytes to secrete La antigens.

Previous reports from this laboratory suggest that certain I region-associated (Ia) antigens can be detected in normal mouse serum. It was found that, when mitogens are injected into mice, they produce substantial increases (up to 125-fold) in the levels of these Ia antigens in mouse serum. Similar increases were obtained when either T- or B-cell mitogens were injected. Furthermore, in vitro and in vivo studies demonstrated that the mitogens stimulated T cells to secrete Ia antigens. It appears likely, however, that the Ia antigens detected in these studies may differ from the conventional Ia glycoproteins found on the surface of B lymphocytes.All T-independent antigens tested also augmented the concentrations of Ia antigen in serum, the increases depending on the T-independent antigen injected and ranging from 3- to 125-fold. In contrast, T-dependent antigens, unless injected in large amounts, were unable to produce detectable changes in the serum levels of Ia antigen. These data indicate that an inverse relationship exists between the T dependence of an antigen and its ability to stimulate T cells to secrete Ia antigens. On the basis of this conclusion it is proposed that all antigens are T dependent and merely vary in the efficiency with which they activate T cells to release helper factors.     

Herpes simplex virus antigens directly activate NK cells via TLR2, thus facilitating their presentation to CD4 T lymphocytes

NK cells infiltrate human herpetic lesions, but their role has been underexplored. HSV can stimulate innate immune responses via surface TLR2, which is expressed on monocyte-derived dendritic cells (DCs) and NK cells. In this study, UV-inactivated HSV1/2 and immunodominant HSV2 glycoprotein D peptides conjugated to the TLR2 agonist dipalmitoyl-S-glyceryl cysteine stimulated CD4 T lymphocyte IFN-γ responses within PBMCs or in coculture with monocyte-derived DCs. NK cells contributed markedly to the PBMC responses. Furthermore, NK cells alone were activated directly by both Ags, also upregulating HLA-DR and HLA-DQ and then they activated autologous CD4 T lymphocytes. Using Transwells, Ag-stimulated NK cells and CD4 T lymphocytes were shown to interact through both cell-to-cell contact and cytokines, differing in relative importance in different donors. A distinct immunological synapse between Ag-stimulated NK cells and CD4 T lymphocytes was observed, indicating the significance of their cell-to-cell contact. A large proportion (57%) of NK cells was also in contact with CD4 T lymphocytes in the dermal infiltrate of human recurrent herpetic lesions. Thus, NK cells stimulated by TLR2-activating HSV Ags can present Ag alone or augment the role of DCs in vitro and perhaps in herpetic lesions or draining lymph nodes. In addition to DCs, NK cells should be considered as targets for adjuvants during HSV vaccine development.     

Characterization of lymphocyte responsiveness in early experimental syphilis. I. In vitro response to mitogens and Treponema pallidum antigens

Lymphoid cells from spleens and lymph nodes of rabbits infected with T. pallidum respond by proliferation to concanavalin A (Con A) and T. pallidum antigens. Spleen cell responsiveness to treponemal antigens appears 6 days after infection, is 100 to 600 fold higher than the response of uninfected control rabbits, and is maintained throughout the 31-day observation period. Specifically responding cells in the inguinal and popliteal lymph nodes of infected animals are demonstrable on day 10, and the magnitude of the response increases throughout the observation period. Specific responsiveness to T. pallidum antigens in vitro is enhanced in purified T cell populations and is abolished by treatment with goat anti-rabbit thymocyte serum and complement. The response of spleen and lymph node cells to Con A is unaffected during syphilitic infection. These results are consistent with a role for T cell-mediated specific immunity to treponemal antigens early after infection and do not support a hypothesis of depressed cellular immunity during syphilitic infection.     

Rat T lymphocyte-specific antigens and their cross-reactivity with mouse T cells.

Anti-rat T lymphocyte serum (ATLS)2 was prepared by immunizing rabbits with purified T cells from rat mesenteric nodes and absorbed with rat red cells and syngeneic sarcoma cells. The specificity of ATLS for rat T cells was confirmed by the following reasons: a) ATLS was not toxic for bone marrow cells but lysed most of the thymocytes and a number of spleen and lymph node cells, which were inversely correlated to the percentage of cells with B cell characteristics in respective organs; b) anatomical localization of ATLS-reactive cells in lymphoid organs coincided to the thymus-dependent areas, i.e. the paracortex of lymph node and the periarteriolar region of spleen; c) spleen cells treated with ATLS and complement failed to respond to phytohemagglutinin but normally responded to bacterial lipopolysaccharide; d) those cells treated with ATLS and complement could not induce a graft-vs-host reaction in F1 hosts, whereas the same treatment did not affect direct plaque-forming cells. All of these data confirm the specificity of ATLS and indicate that ATLS recognizes rat T lymphocyte-specific antigens (RTLA). Absorption studies showed that RTLA were present in higher concentration on medullary thymocytes and peripheral T cells than on cortical thymocytes, but absent from bone marrow, liver, and brain tissues. When the cross-reactivity of RTLA with mouse T cells was studied by C-dependent cytotoxicity and immunofluorescence, it was found that mouse T cells shared at least one determinant of RTLA with rat T cells, and that distribution pattern of the cross-reacting antigens in mouse lymphoid tissues was essentially the same as that of RTLA in rat lymphoid organs.     

Suppression of simian immunodeficiency virus replication in vitro by CD8+ lymphocytes

The AIDS-like disease in rhesus monkeys induced by the simian immunodeficiency virus (SIV) has been used as a model to explore the nature of the T lymphocyte response after infection with viruses of the human immunodeficiency virus family. Activated CD8+ lymphocytes are present in increased numbers in the paracortex of lymph nodes of SIV-infected rhesus monkeys with a lymphadenopathy syndrome. We demonstrate that SIV is more readily isolated from CD8+ lymphocyte-depleted PBL of SIV-infected animals than from their unfractionated PBL. Rather than reflecting the fact that the CD8+ lymphocyte-depleted cell populations are simply enriched for CD4+ lymphocytes, this indicates that CD8+ cells themselves are critical in this regulatory interaction. In fact, CD8+ lymphocytes from SIV-infected but not uninfected rhesus monkeys can block SIV replication in vitro in PBL populations. A T lymphocyte population that blocks replication of viruses of the HIV family may contribute to containing the progression of AIDS.     

Unusual distribution of Ia-like antigens on canine lymphocytes

The murine monoclonal antibody 7.2, specific for a framework determinant of human Ia antigens, cross-reacts with canine cell membranes recognizing a bimolecular complex (29 000 and 34 000 daltons) similar to that described in man. We investigated the distribution of these Ia-like antigens on mononuclear cells in peripheral blood, thoracic-duct lymph, marrow, alveolar lavage fluids, lymph nodes, and thymuses from normal dogs. By complement-mediated cytotoxicity and indirect immunofluorescence, virtually all lymphocytes expressing surface immunoglobulin (B lymphocytes), monocytes/macrophages, dendritic cells, and many thymus-epithelial cells were la-positive. Furthermore, most non-B-lymphocytes in peripheral blood, thoracic-duct lymph, and lymph nodes expressed Ia antigens. Alveolar (T) lymphocytes and most thymocytes were la-negative. Generally, fluorescence intensity was higher on monocytes/macrophages and B lymphocytes than on non-B-lymphocytes. In mixed leukocyte cultures and concanavalin A-induced blastogenesis assays, treatment of responder cells with antibody 7.2 and complement abolished proliferation. Proliferative responses could not be restored by adding untreated accessory cells, indicating that cytolytic treatment had eliminated responder T-lymphocytes. However, addition of antibody alone to cultures had no significant effect. These studies indicate that most mature canine T-lymphocytes express la-like antigens. Whether this is an intrinsic property of canine cells or possibly related to continuous in vivo stimulation remains to be determined.     

Responses of the thymus and the paracortex of draining lymph nodes to repeated applications of oxazolone to mouse skin.

The oxazolone-induced response in the paracortex of draining lymph nodes is characterized by an early increase in the proliferative activity that decreases to control levels when stimulation is continued. The possibility that this may be a toxic side effect of the concentrated oxazolone solution used was investigated by simultaneous registration of the changes taking place in the thymus. These were found to be different from toxin-induced changes and compatible with cell loss due to massive emigration of cells. Repopulation of the thymus took place over the last 1 1/2 week of stimulation. It was concluded that the changes in the thymus as well as the decline of the proliferative activity in the paracortex, are most likely physiological responses. The most important factor in maintaining a high production of paracortical lymphocytes under chronic stimulation is the increase in the lymphocyte mass in the paracortex.     

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.     

The influence of strong transplantation antigens (Ag-B) on lymphocyte migration in vivo.

The tissue localization of syngeneic thoracic duct lymphocytes was compared to that of allogeneic cells in four rat strain combinations differing at the Ag-B locus (HO → DA, DA → HO, AO → HO, HO → AO). Dual isotope labeling with [³H]uridine and [¹⁴C]uridine was applied in order so that the distribution of allogeneic and syngeneic cells could be followed in one recipient. During the first couple of hours after iv injection, allogeneic lymphocytes usually migrated as easily into the various tissues as did syngeneic cells. However, after 24 and 48 hr, a reduced amount of label associated with allogeneic cells was often measured in the tissues. This reduction differed in magnitude in the different strain combinations and was most pronounced in the lymph nodes. A reduced number of allogeneic cells also appeared in the thoracic duct. By contrast, no reduced localization of allogeneic lymphocytes was measured in the draining popliteal lymph nodes late after sc injection. In preimmunized animals allogeneic cells were rapidly removed from the blood and therefore failed to localize in the lymphoid tissues. Furthermore, the lymph node localization of allogeneic cells was more like that of syngeneic cells in splenectomized rats, as well as in irradiated recipients (when the irradiation was given shortly before cell transfer). It is concluded that transplantation antigens play no essential role in the interaction between recirculating lymphocytes and the venous endothelium at the sites where the large-scale physiological emigration of the cells takes place (the HEVS of the lymph nodes and the marginal zone vessels of the spleen). The elimination of allogeneic cells is found later; it probably takes place in the lymph nodes and spleen. Possible mechanisms responsible for this rapid removal of allogeneic lymphocytes in nonimmunized recipients are discussed.     

Interaction of vasoactive intestinal peptide with mouse lymphocytes: specific binding and the modulation of mitogen responses

Binding of radioiodinated vasoactive intestinal peptide (VIP) to mouse lymphocytes has been investigated. Specific cell binding of 125I-VIP was demonstrated with lymphocytes from mesenteric lymph nodes, subcutaneous lymph nodes, spleen, and Peyer's patches. The binding of VIP by these cells was accounted for by VIP binding sites upon T cells rather than non-T cells. In the presence of VIP, the in vitro response of lymphocytes to the T cell mitogens concanavalin A (Con A) and phytohemagglutinin (PHA) was inhibited in a dose-dependent fashion, whereas that to the B cell mitogen lipopolysaccharide (LPS) was not. There was a close correlation between the potency of VIP and some structurally related peptides for inhibition of 125I-VIP binding and the effect of those peptides on T cell mitogen responses. These observations demonstrate that mouse T lymphocytes have specific VIP receptors and that VIP can modulate the response of T cells to mitogenic stimulation. VIP may be an important immunoregulatory molecule, and may be implicated in the regulation of T cell function in mucosal tissues innervated by VIP-containing neurons.     

Nonrandom migration of CD4+, CD8+, and gamma delta+T19+ lymphocyte subsets following in vivo stimulation with antigen

We report here the results of experiments in which the migration of three T cell subsets (CD4+, CD8+, and gamma delta+T19+ cells) through antigen-stimulated lymph nodes and subcutaneous granulomas has been compared with that through normal skin and resting lymph nodes. The percentage of gamma delta+T19+ lymphocytes was halved and the percentage of CD8+ lymphocytes was doubled in lymph draining stimulated compared with control tissues, and all lymphocyte subsets except gamma delta+T19+ lymphocytes had higher hourly outputs in lymph draining antigen-stimulated compared with control tissues. Antigen also resulted in a higher percentage of CD8+ lymphoblasts and a lower percentage of gamma delta+T19+ lymphoblasts in efferent lymph draining antigen-stimulated lymph nodes. The data indicate that lymphocyte subsets leave the blood with differing efficiencies in different vascular beds and raise the possibility that antigen can influence the rate at which tissues extract individual T cell subsets from the blood.