Mitogenic factor from inbred guinea pigs. II. Properties of the factor

Thymectomized adult rats which have been heavily irradiated and reconstituted with syngeneic bone marrow cells rapidly regain the ability to defend themselves against a primary infection with the intracellular bacterial parasite, Listeria monocytogenes. They do so by a cell-mediated immunological mechanism as evidenced by the protective immunity transferred adoptively by thoracic duct lymphocytes or peritoneal exudate cells from donors infected with this organism. But peritoneal exudate cells from thymus-derived donors convey only a fraction of the immunity transmitted by exudate cells from similarly infected intact rats. Since thymectomized irradiated animals can mobilize their cellular defenses more effectively when they are injected with a modest number of thoracic duct lymphocytes, an effect that cannot be duplicated with a massive infusion of bone marrow, it is argued that thymusdependent lymphocytes or T cells have an influential role in the development of cellular resistance to infection.     

3H-uridine incorporation as a T lymphocyte indicator in the rat

Although about 70% of rat thoracic duct small lymphocytes labeled readily in vitro with ³H-uridine, only 3–38% of peritoneal exudate lymphocytes labeled. Since exudate cells are mostly B lymphocytes, ³H-uridine in concentrations used were presumed to label the T lymphocyte. Percentages of small lymphocytes that labeled in cell suspensions from various tissues were consistent with other estimates of T cells in those sources: 74.7% in thoracic duct, 70.2% in blood and 65.6% in spleen. When lymphopenia was induced by polyethylene ³²P strips applied to the spleen, a procedure that depletes mostly small recirculating lymphocytes, both labeled (T) and nonlabeled (B) cells were depleted in similar time sequence. Both cell types recovered at a similar rate after the spleen strips were removed. Induction of peritoneal inflammation by PPD in tubercle-bacilli immune rats caused an enhanced lymphocytic exudation but no increase in percentage of labeled (T) lymphocytes.The defect in ³H-uridine incorporation that characterizes the rat B lymphocyte seemed to be relatively specific for that RNA precurser; ³H-cytidine labeled the majority of lymphocytes in peritoneal exudate.     

The mediator of cellular immunity: XI. Origin and development of MIF producing lymphocytes

Thoracic duct lymphocytes obtained from rats infected with Listeria monocytogenes were characterized with respect to size, turnover and their capacity to release macrophage migration inhibitory factor (MIF). Cells responsive to Listerial antigens (LMA) in the MIF assay were identified in lymph during the first week of an immunizing infection. These were immunoblasts or large lymphocytes, as evidenced by their sedimentation with S phase lymphocytes at unit gravity. When labeled cells from the lymph of Listeria-infected donors were infused into similarly infected recipients, donor S phase lymphocytes localized rapidly, and in substantial numbers, in peritoneal exudates induced by the unrelated organism, F. tularensis. Within this immigrant population were cells which conferred immunity against L. monocytogenes and released MIF in cultures containing LMA. Exudates harvested 36 hr or 61 hr after stimulation contained labeled lymphocytes that were smaller than the S phase cells recovered during the early post-induction period. The observed shift of radioactivity from large to smaller lymphocytes was parallelled by a shift MIF production to exudate fractions containing smaller cells. The MIF producing cells in exudates of advancing age also exhibited increasing resistance to inhibition by vinblastine. These findings suggest that MIF is released by a family of lymphocytes—large, medium and small. LMA-responsive lymphocytes are delivered to the thoracic duct soon after their formation, at a stage in development when they can be stimulated to release only low levels of MIF. These mediator producing cells circulate briefly in the blood and differentiate fully only after they extravasate into inflammatory foci.     

The mediator of cellular immunity. VIII. Effect of mitomycin C on specifically sensitized lymphocytes.

The antimitotic agent, mitomycin C, was used to probe cellular events underlying the expression of acquired resistance to L. monocytogenes in the rat. It was found that thoracic duct lymphocytes from donors primarily immunized with this organism can protect normal recipients against a Listeria challenge and that their ability to do so is inhibited by treatment of the lymphocytes with mitomycin C. Concentrations of the drug which are effective in this regard also inhibit lymphocyte proliferation, but have little if any effect upon RNA or protein synthesis in cells tested at the time of transfer. Yet mitomycin C probably has irreversible effects on lymphocytes in addition to its capacity to block cell replication, for inhibitor-treated immunoblasts fail to localize in peritoneal exudates induced in recipient rats. The inability of mitomycin-treated immunoblasts to extravasate in inflammatory foci is associated with a diminished capacity of specificially sensitized lymphocytes to promote cell division in peritoneal exudates induced by L. monocytogenes. The results illustrate the importance of lymphocyte-macrophage interactions in cellular resistance to infection and give credence to the view that these interactions occur locally at sites of microbial invasion.     

Generation of macrophage chemotactic activity in situ in Listeria-immune rats.

Macrophage chemotactic activity (MCA) is generated in situ in peritoneal inflammatory exudates induced by antigens of the intracellular parasite, Listeria monocytogenes. Chemotactic and chemokinetic activity is formed locally in response to an immunologically specific signal. In rats that have been immunized adoptively with thoracic duct lymphocytes (TDL) from specifically immunized donors, the production of MCA depends upon stimulation by LMA of exudate-seeking S-phase lymphocytes of their progeny. The sequential appearance, increase, and subsequent decline of MCA in the peritoneal cavity parallels the influx of lymphocytes and precedes maximal recruitment of labeled monocytes from the blood. The MCA response in peritoneal exudates induced in adoptively immunized rats correlates with the level of macrophage accumulation in the peritoneal cavity and at sites of LMA injection in the pinna of the ear. The results suggest that MCA is released locally by antigen-activated lymphocytes and imply that the factor(s) concerned has a purposeful role in the host's defense by promoting the rapid deployment and/or retention of monocyte-derived macrophages in centers of infection.     

The mediator of cellular immunity. X. Interaction of macrophages and specifically sensitized lymphocytes.

Specifically sensitized lymphocytes have a focusing influence on mononuclear phagocytes that is expressed in the local accumulation and division of macrophages in bacteria-induced exudates. This was demonstrated by injecting Listeria monocytogenes into the peritoneal cavity of normal rats immediately before the animals were transfused with thoracic duct lymphocytes from either Listeria-immune donors or donors that had been infected with the unrelated parasite, Francisella tularensis. Sensitized lymphocytes originally present in the intravenous inocula were found later in the exudates. The arrival in the inflamed peritoneal cavity of specifically sensitized lymphocytes was associated with an exuberant influx of newly formed host cells and a local proliferative response that involved both immunoblasts and macrophages. These cytokinetic observations provide a plausible explanation of the delayed inflammatory response induced by the parasite, and imply that sensitized lymphocytes contribute to the host's defence by encouraging the prompt and purposeful deployment of monocyte-derived macrophages in centers of infection. In addition to their focusing influence on mononuclear phagocytes, specifically sensitized lymphocytes or their products can enhance the metabolic and microbicidal activity of macrophages. This activation process was revealed in the ability of rats infected with L. monocytogenes or BCG to control the growth of F. tularensis at a challenge site in the testis. But resistance was expressed only when the challenge organisms were injected with killed bacteria against which the recipients had been specifically immunized. The results accord with the view that macrophages are functionally activated by an immunological mechanism, and imply that the process is triggered locally by sensitized lymphocytes which are recruited from the blood.     

Allogeneic restriction of the delayed inflammatory reaction in the rat.

Delayed-type hypersensitivity (DTH) to Listeria monocytogenes was measured in rats that were recipients of syngeneic, semisyngeneic, and allogeneic immune thoracic duct lymphocytes (TDL). DTH could be transferred only to recipients that shared at least one haplotype with the TDL donors. The restriction was expressed in an inability of sensitized lymphoblasts to localize efficiently at antigen injection sites in the pinna of the ear and peritoneal cavity. Failure of allogeneic lymphoblasts to extravasate in more than trace numbers into Listeria-antigen-induced exudates was reflected in an absence of other lymphocyte-mediated expressions of DTH. Thus, lymphocyte-dependent MCA was not detected in Listeria-antigen-induced peritoneal exudates borne by recipients of allogeneic immune TDL and blood monocytes were not recruited in increased numbers into such exudates as they were in exudates borne by syngeneic rats. But allogeneic restriction of the delayed inflammatory response to Listeria antigen was overcome, at least in part, when antigen-presenting macrophages of the same MHC type as the immune TDL donors were implanted in the peritoneal cavity. The results encourage the belief that the observed failure of immune TDL to transfer DTH to allogeneic recipients is related to the inability of sensitized donor T cells to recognize antigen displayed by allogeneic macrophages.     

Random recirculation of small T lymphocytes from thoracic duct lymph in the mouse

The migration of ⁵¹Cr-labeled nylon-wool separated mouse thoracic duct T cells has been followed in order to determine whether there is a circulation of small (nondividing) T cells through the small intestine. Approximately 6% of the injected dose of T-TDL localized in the small intestine (minus Peyer's patches). Experiments revealed that this gut-localizing cell population consisted almost entirely, if not exclusively, of lymphoblasts present in mouse T-TDL. When lymphoblasts and small lymphocytes from mouse T-TDL were separated by velocity sedimentation, and the migration of separated fractions was studied, we found large cells (66% blasts) migrated well to the gut but poorly to the lymph nodes, whereas small cells (2% blasts) showed minimal migration to the gut but localized randomly in lymph nodes and spleen. The in vivo distribution of small cells from T-TDL was similar to that of T-PLN. Furthermore, the recirculatory patterns of both ⁵¹Cr-labeled T-TDL and T-PLN were found to be identical as accessed by their rate of recovery in the thoracic duct lymph of recipient mice. These results support the notion that the vast majority of T-TDL and T-PLN are part of a common pool of recirculating T cells which recirculate randomly through lymph nodes and spleen and not the small intestine.     

Migration of recently divided B and T lymphocytes to peritoneum and lung

It is recognized that a population of newly divided (or young) cells migrate preferentially to inflamed foci. It has been shown that a large proportion of lymphocytes residing in the bronchoalveolar airspaces of rat are recently divided cells and that blood may be an important source of these cells. To further delineate how blood may contribute to lymphocyte subpopulations in inflamed peritoneum and lung, a comparison of the capacity of recently divided T and B cells to migrate from blood to inflamed peritoneum and lung was made. To label young lymphocytes, DA strain donor rats were given Initiated thymidine by vein in vivo for 7 days. After thoracic duct drainage, the following labeled cell populations were adoptively transferred by vein into syngeneic recipients: (i) unseparated thoracic duct lymphocytes (TDL), (ii) enriched T cells (>90%) or B cells (>80%) recovered after passage of TDL through nylon columns, and (iii) thoracic duct lymphocytes (> 99% B cells) obtained from “B rats” that were prepared by X irradiation, thymectomy, and bone marrow reconstitution. T and B cells were identified by specific heterologous antisera. The percentage recovery of labeled lymphocytes in the recipients with inflamed peritoneum or lung aspirates was determined from cell counts and autoradiographs. The studies indicated that (a) both labeled T and B cells migrated to inflamed peritoneum and lung; (b) labeled B cells migrated to peritoneum and lung better than did labeled TDL or T cells; and (c) labeled lymphocytes did not migrate to unstimulated peritoneum. The enhanced migration of newly divided B lymphocytes to inflamed peritoneum and normal lung (a site that is likely under chronic antigenic stimulation) was unexpected, but may provide additional information on the relative contribution of these subpopulations in the immune inflammatory response.     

Macrophages as effector cells of protective immunity in murine schistosomiasis

Mice infected with Schistosoma mansoni develop a dramatic (five- to eightfold) increase in numbers of peritoneal leukocytes, and approximately 65% of these cells are macrophages. By several biochemical and cytochemical criteria, these cells were comparable to resident peritoneal macrophages of normal mice. However, macrophages from schistosome-infected mice exhibited significant nonspecific tumoricidal activity in vitro, a function associated with immunologically activated cells. The time course for development of activated macrophages in the peritoneal cavity was dependent upon the route of infection. Cytotoxic cells were present in the peritoneal cavity by 3 weeks after intraperitoneal infection, but were not evident until several weeks later in animals infected percutaneously, subcutaneously, or intravenously. However, by 3 weeks after subcutaneous infection, tumoricidal macrophages appeared in the peritoneal cavity after intraperitoneal challenge with soluble schistosome antigens. Macrophage activation was independent of the development of egg granulomas, since tumoricidal cells could be found prior to the onset of egg production and were also present in mice infected with only male worms. Development of activated macrophages in these instances is thus consistent with previous observations on induction of T lymphocyte reactivity toward schistosomula. Since other manipulations known to activate macrophages have been shown to induce partial resistance to schistosome infection, the finding that macrophage activation results from primary S. mansoni infection itself suggests that these cells may play a major role in acquired immunity to this parasite.     

The bronchoalveolar lymphocyte: Studies on the life history and lymphocyte traffic from blood to the lung

Although recent work has shed some light on the identity and function of lymphocytes that reside in the bronchoalveolar air space (lung lymphocytes), little is known about the origin and life history of these cells. To determine the proportion of recently divided lung lymphocytes, DA-strain rats were labeled in vivo for 3 days with tritiated thymidine ([³H]dTR). Autoradiographs of lavaged lung and peritoneal cells indicated that a large fraction (44–77%) of lung lymphocytes was labeled and that these values were comparable to the proportion of labeled lymphocytes in peritoneal exudates (61–74%). To determine if some newly divided lung lymphocytes might come via the blood, additional experiments were performed in which rats were labeled ([³H]dTR) in vivo for 7 days. Lymphocytes were then obtained in labeled rats by thoracic duct drainage and were adoptively transferred (by vein) into syngeneic recipients. The percentage recovery of labeled lymphocytes in lung aspirates of recipient rats was determined from cell counts and autoradiographs. These results demonstrate that blood may be a source of recently divided lymphocytes but they do not indicate the relative contribution blood makes toward these cells in the lung.     

The mediator of cellular immunity. IV. Cooperation between lymphocytes and mononuclear phagocytes

Acquired resistance to an intravenous infection with Listeria monocytogenes involves the interaction of two cell types: specifically committed lymphocytes and monocyte-derived macrophages. This interaction was revealed in experiments using the polyfunctional alkylating agent, cyclophosphamide. Cyclophosphamide is toxic for both lymphocytes and blood monocyte antecedents. Rats treated with cyclophosphamide were immunized adoptively with cells obtained from the thoracic duct lymph of Listeria-immune donors. But such animals benefited from a lymphocyte injection only while they could assemble monocyte-derived macrophages in an inflammatory exudate. The results imply that blood monocytes provide an essential element to the host's defense mechanism against intracellular bacterial parasites, and that monocyte-derived macrophages are the instruments through which cellular resistance to infection is expressed.     

Characterization of cellular and molecular immune effectors against Trichinella spiralis newborn larvae in vivo.

The cellular and molecular immune effectors that participated in host immunity against Trichinella spiralis newborn larvae were characterized in vivo using AO rats. Donor rats were immunized with 2,000 muscle larvae orally or 11,400 newborn larvae i.v. Immune serum and cells from spleen, peripheral lymph nodes, mesenteric lymph node, thoracic duct lymph and the peritoneal cavity were obtained from donor rats 10-21 days after infection and transferred into normal recipient rats. The control recipients received either no cells and serum or normal cells and normal serum obtained from normal donors. Newborn larvae (20,000-50,000) were injected either i.v. or ip into these recipients and immunity against newborn larvae was measured either by muscle larvae burden of the recipients three weeks later or by direct recovery of newborn larvae from the peritoneal cavity of the recipients. The experiments demonstrated that immune lymphocytes conferred no protection in the recipients but that immune serum and immune peritoneal cells were protective and these effects were synergistic. Cell adherence to the cuticle and killing of newborn larvae were observed in the peritoneal cavity of immune rats. Positive fluorescence was observed on newborn larvae incubated with fractionated IgM and IgG(E) antibody isotypes. Massive deposition of antibody molecules on newborn larvae was demonstrated by scanning electron microscopy. Studies using transmission electron microscopy revealed that the larval adherent cells were stimulated macrophages, neutrophils and eosinophils.     

Immunoglobulin on activated T cells detected by indirect immunofluorescence

A high proportion of H2 antigen-activated thymus-derived thoracic duct lymphocytes stained positively with rabbit anti-mouse immunoglobulin reagents as detected by indirect immunofluorescence. In view of the specificity of the reagents used and the fact that T cells from other sources e.g., thymus, were not stained by this technique, it was concluded that the material detected on H-2 antigen-activated thymus-derived thoracic duct lymphocytes was indeed immunoglobulin. When H-2 antigen-activated thymus-derived thoracic duct lymphocytes were cultured in vitro at 37 °C for 18 hr, with or without prior treatment with chymotrypsin, surface immunoglobulin could no longer be detected on the cells. This suggested that immunoglobulin had not been synthesized by the cells but absorbed from elsewhere.     

The nature of the thymus dependency of mucosal mast cells. II. The effect of thymectomy and of depleting recirculating lymphocytes on the response to Nippostrongylus brasilliensis.

The effect of adult thymectomy and of lymphocyte depletion by thoracic duct drainage on the jejeunal mucosal mast cell (MMC) response to infestation with Nippostrongylus brasiliensis has been studied in rats. Adult thymectomy 2 to 4 weeks before infestation with the parasite had no effect on the production of MMC hyperplasia. However, long-term thymectomy (12–39 weeks) produced a progressive decline in the MMC response to infestation. When adult-thymectomized rats were depleted of recirculating lymphocytes by thoracic duct drainage, infestation either 2 weeks or 12 weeks after completion of drainage significantly reduced the MMC response. The MMC response was restored to normal when the animal's washed thoracic duct lymphocytes were returned to it, and could be regenerated over the course of 12 weeks in the presence of thymus tissue. It is concluded that the thymus influences MMC indirectly, through the production of peripheral T lymphocytes, and that the T-lymphocyte subset involved belongs to the long-lived recirculating pool.     

Antigenic relationship between bone marrow lymphocytes cortical thymocytes and a subpopulation of peripheral T cells in the rat: description of a bone marrow lymphocyte antigen.

Populations of rat bone marrow lymphocytes (BML) consisting of approximately 90 percent, “tnull” cells were prepared by density gradient centrifugation, passage through a column of fine glass beads, and treatment with anti-T cell and anti-B cell serum plus complement. Antisera to these bone marrow lymphocytes were raised in rabbits. After absorption with RBC and peritoneal exudate cells, the anti-BML sera were found by immunofluorescence to react selectively with “null” cells in bone marrow, with cortical thymocytes, and with a cortisone-sensitive subset of T cells in blood and in spleen, possibly in red pulp. The antigen that is common to these cell types is designated the rat bone marrow lymphocyte antigen (RBMLA). Lymphocytes that are positive fur KBMLA are negative for another lymphocyte-specific heteroantigen, rat musked thymocyte antigen (RMTA). As shown previously, RMTA is present on medullary thymocytes and ou cortisone-resistant T cells in white pulp of spleen, paracortex of lymph node and thoracic duct lymph. It is postulated that two developmentally and functionally distinct lines of T cells exist in peripheral lymphoid tissues of the rat, one derived from cortical thymocytes and one derived from medullary thymocytes. It is further postulated that the “null” population of bone marrow lymphocytes contains the lymphopoietic stem cells from which these two lines of T cells originate.     

Loss of natural resistance to schistosome in T cell deficient rat

Schistosomiasis is among the major neglected tropical diseases and effective prevention by boosting the immune system is still not available. T cells are key cellular components governing adaptive immune response to various infections. While common laboratory mice, such as C57BL/6, are highly susceptible to schistosomiasis, the SD rats are extremely resistant. However, whether adaptive immunity is necessary for such natural resistance to schistosomiasis in rats remains to be determined. Therefore, it is necessary to establish genetic model deficient in T cells and adaptive immunity on the resistant SD background, and to characterize liver pathology during schistosomiasis. In this study we compared experimental schistosomiasis in highly susceptible C57BL/6 (B6) mice and in resistant SD rats, using cercariae of Schistosoma japonicum. We observed a marked T cell expansion in the spleen of infected B6 mice, but not resistant SD rats. Interestingly, CD3e^−/− B6 mice in which T cells are completely absent, the infectious burden of adult worms was significantly higher than that in WT mice, suggesting an anti-parasitic role for T cells in B6 mice during schistosome infection. In further experiments, we established Lck deficient SD rats by using CRISPR/Cas9 in which T cell development was completely abolished. Strikingly, we found that such Lck deficiency in SD rats severely impaired their natural resistance to schistosome infection, and fostered parasite growth. Together with an additional genetic model deficient in T cells, the CD3e^−/− SD rats, we confirmed the absence of T cell resulted in loss of natural resistance to schistosome infection, but also mitigated liver immunopathology. Our further experiments showed that regulatory T cell differentiation in infected SD rats was significantly decreased during schistosomiasis, in contrast to significant increase of regulatory T cells in infected B6 mice. These data suggest that T cell mediated immune tolerance facilitates persistent infection in mice but not in SD rats. The demonstration of an important role for T cells in natural resistance of SD rats to schistosomiasis provides experimental evidences supporting the rationale to boost T cell responses in humans to prevent and treat schistosomiasis.     

In vivo and in vitro effects of monoclonal antibody to Ly antigens on immunity to infection

Injection of CBA mice with Brucella abortus strain 19 leads to chronic infection during which both cell-mediated immunity (delayed hypersensitivity and macrophage activation) and antibody production occur. Protection was efficiently transferred to naive mice using spleen cells from mice infected 5 or 12 weeks earlier. Selective lysis in vitro of these cells by antibody to cell surface antigens showed that Thy-1⁺ Ly-1⁺2⁺ T lymphocytes were required for transfer. Treatment with anti-Ia serum neither suppressed nor enhanced adoptive transfer. Thus Ia⁺ B lymphocytes were not required, and Ia⁺ suppressor T cells were not active in the response. Three injections per week of anti-Ly-1 monoclonal antibody beginning 5 days before infection led to a 10-fold increase in bacterial numbers 25 days after infection when acquired immunity was well established in untreated mice. The delayed hypersensitivity response was unaffected. In addition cells from these in vivo treated mice were unable to transfer resistance. Beginning the treatment on the day of infection abolished the IgG antibody response without affecting bacterial numbers. The studies emphasize the unique role of Ly-1⁺2⁺ T cells in immunity to Brucella and indicate the usefulness of these techniques in dissecting out those components of the immune response which contribute to recovery from infection.     

Vitamin B6 deficiency and the lymphoid system: I. Effects on cellular immunity and in vitro incorporation of 3H-uridine by small lymphocytes

Thoracic duct lymphocytes from vitamin B₆-deficient rats were found to have a reduced capacity to respond to foreign lymphoid cells in the mixed lymphocyte reaction (MLR), to produce normal lymphocyte transfer reactions, and to incorporate ³H-uridine in vitro. These findings indicate that specific nutritional deficiencies may impair cellular immunity and that this impairment can be monitored by the MLR. It is suggested that the reduction in MLR activity and in ³H-uridine uptake by TDL cells reflected either a shift in the proportions of T and B cells in the TDL and/or an impairment in the capacity of such cells to function in the MLR and in the in vitro test for ³H-uridine incorporation.     

Immunity to the protozoan parasite Eimeria nieschulzi in inbred CD-F rats

Immunity to the coccidial parasite, Eimeria nieschulzi, in CD-F rats was assessed by the numbers of oocysts shed in relation to the time after inoculation. Intravenous injections of syngeneic thoracic duct lymphocytes (TDL) from immunized rats elicited various degrees of adoptive immunity against primary infections of E. nieschulzi. Of the 16 rats injected with 10⁹ sensitized TDL, 7 were totally immune to a subsequent challenge by the parasite. This number of injected TDL also raised the serum antibody level to that of immune rats. Contact with immune TDL was deleterious to sporozoites of E. nieschulzi in vitro and produced immunocytoadherence of parasite to cell.