Transfer of immunity to Babesia microti of human origin using T lymphocytes in mice

Lymph node and spleen cells from mice infected with Babesia microti of human origin developed the ability to transfer adoptive immunity to naive mice within 25 days after infection. This protective activity was greater in cells obtained at 32 days than in cells obtained at 25 days postinfection and remained stable up to 52 days postinfection. Recipients of lymph node cells and spleen cells displayed similar peak parasitemias although 2 days after peak parasitemia, immune spleen cell recipients had significantly lower parasitemias than immune lymph node cell recipients. Strong protective activity was demonstrated when cells were transferred 1 day postinfection, while equal numbers of cells, transferred 3 days postinfection did not confer significant protection over nonimmune cells. There was also a suggestion that the number of immune spleen cells necessary for significant protection was directly related to the number of parasites inoculated. The subpopulation of lymphocytes responsible for the transfer of adoptive immunity to B. microti of human origin was then studied in BALB/c mice depleted of T lymphocytes by thymectomy and lethal irradiation. One day after infection with B. microti, T-cell-depleted mice were given complement-treated immune spleen cells, anti-θ serum-treated immune spleen cells, nonimmune spleen cells, or no cells. Similar experiments were performed comparing the effects of anti-immunoglobulin serum-treated and unfractionated immune spleen cells on B. microti parasitemia. Treatment with anti-θ serum abrogated the protective activity of immune spleen cells while anti-immunoglobulin serum treatment had no effect. These results suggest that immunologic memory of B. microti in BALB/c mice is modulated by T rather than B lymphocytes.     

Biological characterization of T and B lymphocytes separated from normal mouse spleen by a physical adherence column method

The capacity of spleen cell populations enriched for T and B lymphocytes by a physical adherence column method to respond in vitro to phytomitogens and allogeneic lymphocytes was determined. Column filtrate cells (T lymphocytes) responded well to phytohaemagglutinin- and mitomycin-C-treated allogeneic spleen cells, but poorly to pokeweed mitogen. Adherent cell populations from the column (B and some T lymphocytes) responded well to pokeweed mitogen, but poorly to phytohaemagglutinin- and mitomycin-C-treated allogeneic cells.Purified peripheral T lymphocytes prepared from normal mouse spleen by the column method reconstituted the depleted in vitro antibody response to the thymic-dependent SRBC antigen of all B lymphocyte sources tested, namely, spleen cells from congenitally athymic mice, neonatally thymectomized mice, and adult thymectomized mice which had been reconstituted with bone marrow, and a lymphocyte population prepared by incubating spleen cells with anti-θ serum and complement. When transferred with sheep erythrocytes to congenitally athymic mice, purified peripheral T cells restored the in vivo IgM and IgG responses of these animals. These results confirm that the column filtrate is a thymus derived subpopulation of cells capable of cell-mediated immunity and cooperation with B lymphocytes in humoral immunity both in vitro and in vivo.     

Unique homing properties of nonadherent peritoneal cells

The nonadherent lymphocytic cells from the peritoneum after ⁵¹Cr labeling and intravenous injection into normal syngeneic recipient mice were observed to distribute in a different manner from spleen and lymph node lymphocytes. These differences in dynamic behavior occurred despite the morphologic similarities of the cells. Such patterns of distribution were directly related to cell viability since heat-killed cells migrate in a distinctly different manner. Treatment of lymph node, spleen, and non-adherent peritoneal cells with anti-θ serum to eliminate T cells modified the dynamic behavior of all the cell populations somewhat, but did not eliminate major differences in the distribution patterns of nonadherent peritoneal “lymphocytes” compared to lymph node and splenic lymphocytes. The suggestion is made that the peritoneal lymphocyte differs from other lymphocytes.     

Further studies on Th-B, a cell surface antigenic determinant present on mouse B cells, plasma cells and immature thymocytes.

A goat antiserum (Goat anti-M104E) has been produced which contains antibodies selectively cytotoxic for mouse B cells and a subpopulation of thymus cells. It reacts with the Th-B antigenic determinant which has been shown by us (1–3) to be present on B cells and on plasma cells and on some cells in the thymus. It also is very cytotoxic for mouse B cells while a previously developed rabbit antiserum was not. The antiserum was obtained by immunization with cells of the BALB/c mouse myeloma MOPC-104E. When the antiserum was purified by in vivo absorption in mice, antibodies remained which were cytotoxic for cells of all of several myelomas at a titer between 1:128 and 1:1024 as determined by an in vitro complement dependent cytotoxicity test. The in vivo purified antibodies were also cytotoxic for about 70% of thymus cells, for about 70% of spleen cells, for about 50% of lymph node cells and for about 20% of bone marrow cells. They were very cytotoxic for splenic or lymph node B cells separated from T cells by a nylon wool column and only slightly cytotoxic for splenic or lymph node T cells. The antibodies were only weakly cytotoxic for one out of five T cell tumors tested and not cytotoxic for the remaining four. Irrespective of target cells used, the cytotoxicity of purified Goat anti-M104E was easily removed by absorption with cell suspensions from tissues which contain B cells, plasma cells or thymus cells. In order to confirm that the same anti-Th-B antibodies recognize the determinant present on spleen cells and on some thymocytes, the purified Goat anti-M104E serum was absorbed with either spleen cells or thymus cells. The absorbed sera were tested for ability to label thymocytes or spleen cells using the fluorescence activated cell sorter (FACS). Either absorption removed essentially all the antibody capable of binding to either cell population. In addition it was shown, using the FACS, that only B cells and not T cells of the spleen contain the Th-B determinant. The anti-Th-B antibodies have now been used for the rapid elimination of B cells from a mixed population of lymphocytes without affecting the function of mature T cells. Thus in vitro treatment of spleen cells from SRBC-immunized donors with purified Goat anti-M104E plus complement results in the killing of a high proportion of the B memory cells as shown by the reduction of PFC produced when the treated cells are transferred to irradiated recipients. The T cell helper function of the transferred cells is not affected by Goat anti-M104E treatment as shown by appropriate cell transfer experiments in which effective B cells are provided by an AKR anti-Thy-1.2-treated spleen cell population and effective T cells are provided by the Goat anti-M104E-treated spleen cell population. Antibodies detecting Th-B may serve as an approach to understanding the ontogeny of lymphocytes. Our results suggest that Th-B is a cell surface marker appearing early in the development of lymphoid cells, on the common precursor of B and T cells and that it is lost from T cells as they mature in the thymus.     

Effect of various thymic and nonthymic factors on in vitro antibody formation by spleen cells from nude mice

Thymosin and thymic humoral factor (THF), both prepared from whole thymus tissue, increased the in vitro anti-SRBC response of spleen cells from nu/nu mice. Lymphoid and nonlymphoid control preparations did not influence the response. Standard isolation procedures for thymosin and THF were employed to prepare factors from thymus lymphocytes (TL) separated from calf thymus and from thymus tissue enriched in thymus epithelium (TE) by preirradiation of the calves. The activity of the TE preparations was greater than that of the total thymus (TT) preparations. The TL preparations were marginally effective. However, the activity of the TE preparations could not be attributed exclusively to epithelium-derived factors, since spleen and lymph node extracts from the irradiated calves contained stimulatory material of an unknown origin which may also be present in the TE preparations.     

Radiation-induced alterations in murine lymphocyte homing patterns: I. Radiolabeling studies

In vitro X-irradiation of ⁵¹Cr-labeled spleen, lymph node, bone marrow, or thymus cells was found to alter their subsequent in vivo distribution significantly in syngeneic BDF₁ mice. Irradiated cells demonstrated an increased distribution to the liver and a significantly lower retention in the lungs. Cells going to the lymph nodes or Peyer's patches showed a significant exposure-dependent decrease in homing following irradiation. Irradiated lymph node cells homed in greater numbers to the spleen and bone marrow, while irradiated cells from other sources showed no preferential distribution to the same tissues. Sampling host tissues at various times after irradiation and injection did not demonstrate any return to normal patterns of distribution. The alterations in lymphocyte homing observed after in vitro irradiation appear to be due to the elimination of a selective population of lymphocytes or membrane alterations of viable cells, and the detection of these homing changes is in turn dependent upon the relative numbers of various lymphoid subpopulations which are obtained from different cell sources. Radiation-induced alterations in the normal homing patterns of lymphoid cells may thus be of considerable importance in the evaluation of subsequent functional assays in recipient animals.     

In vitro immune blastogenesis during contact sensitivity in tumor-bearing mice: I. Description of progressive impairment and demonstration of splenic suppressor cells

T-cell responsiveness was measured by the DNA response of disassociated spleen and lymph node cells when exposed to antigen in vitro. Sensitized splenic lymphocytes from fibrosarcoma-bearing mice immunized with 2,4-dinitro-1,5-difluorobenzene (DN2FB) demonstrated a progressive decrease in T-cell responsiveness to the haptenprotein conjugate DNP-BSA. Hyporesponsiveness to the dinitrophenylated-protein conjugate appeared in the spleens but not lymph nodes of tumorous animals. Normal host lymph node cells (LNC) responded strongly 24 to 48 h after sensitization and subsequently declined with a corresponding increase in responsiveness in the spleen. Tumor-bearing hosts (TBH) had similar LNC kinetics during immunization, however, spleen cells were significantly suppressed when compared to normal BALB/c mice sensitization kinetics. Spleen cells from TBH were also capable of suppressing the in vitro response of normal primed lymphocytes to DNP-BSA when admixed. Results from these experiments suggest that in vitro measurement of contact sensitivity was affected by suppressor cells/products existing in the spleens but not lymph nodes of fibrosarcoma-bearing mice.     

Reutilization by maternal and embryonal cells of nuclear materials from H3-thymidine labeled lymphocytes introduced into the lumen of intestine of rats

Summary H³-thymidine labeled lymphocytes from thymus and lymph nodes of donor rats were washed and injected in to the intestine of recipient rats on the 11th and 19th day of gestation; subsequent labeling of maternal and embryonal cells was studied autoradiographically 24 hours after injection. In 12-day embryos, numerous stem cells or hemocytoblasts were labeled frequently intensely. In 20-day embryos, stem cells or hemocytoblasts scattered throughout the liver were often labeled. In other fetal tissues at this stage, cells in thymus, spleen, mesenteric lymph node and intestine were labeled but scarcely and weakly. In mothers, labeling in lymphoid tissues was scarce but definite, in thymus, mesenteric lymph node and spleen. These results suggest that nuclear materials from lymphocytes emigrated into the intestinal canal of the mother could be reutilized by maternal and embryonal cells.     

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.     

Thymus dependency of cells involved in transfer of delayed hypersensitivity to listeria monocytogenes in mice

Delayed-type hypersensitivity (DH) to Listeria antigens was induced in inbred C3Hf/Umc mice by intravenous injection of a sublethal dose of viable Listeria monocytogenes. Bone marrow, spleen, and lymph node cells from the immune mice were capable of passive transfer of DH to syngeneic neonatally thymectomized or lethally (900 R) irradiated recipients. Immune thymus cells as well as immune serum were ineffective in transferring DH to irradiated animals. In vitro treatment with antitheta isoantibody (anti-θ) and complement abolished the capacity of spleen and bone marrow cells from immune donors to transfer DH to irradiated hosts, indicating the thymus dependency of this cell population. The results with bone marrow indicate the existence of a small, but biologically significant, thymus-dependent population in this tissue.     

Prevention of macrophage tumoricidal activity by agents known to increase cellular cyclic AMP.

The concept of T-T cell interaction which was first suggested during cell-mediated immune response to alloantigens was evaluated in a syngeneic tumor system. The combination of lymph node and thymus cells from BALB/c mice immune against syngeneic tumor cells, mKSA, was shown to exhibit collaboration with respect to in vitro generation of effector cells capable of preventing growth of corresponding tumor cells in the tumor cell neutralization assay. While each cell population of either anatomical site did not prevent tumor growth when tested alone, combinations of both did. The antigen specificity of effector cells generated by synergizing cultures was similar to that of effectors derived from cultures containing optimal numbers of responding lymph node cells. The lymph node and thymus cell populations participating in synergy were found to be thymus dependent. These results suggest that we may be dealing with the same or similar T₁- and T₂-cell populations described before as displaying synergy in response to alloantigens in the graft versus host, mixed lymphocyte, and cell-mediated cytotoxicity reactions.     

Synergy among rat T cells in the proliferative response to alloantigen.

A synergistic interaction in the proliferative response to alloantigen is described for mixtures of rat thymus and lymph node cells. The optimal conditions for synergy are quantitatively defined. Regression analysis of the slope of the dose-response curve has been utilized to estimate the degree of interaction in thymus-lymph node cell mixtures. The slope of the response of cell mixtures was noted to be significantly greater than the slope for the response of lymph node cells alone. Irradiation was shown to have a differential effect on the response of thymus and lymph node cells in mixtures. Irradiated thymus cells retained the capacity for synergy in mixtures, whereas irradiated lymph node cells did not. Additional studies have demonstrated that both de novo protein synthesis and specific antigen recognition by both responding cell populations in mixtures was required for maximal synergy. These studies demonstrate that synergy cannot be explained as an artifact of altered cell density in vitro. They establish that thymus cells and lymph node cells represent distinct subsets which manifest qualitatively different functions in the proliferative response to alloantigen. Thymus cells can respond directly to alloantigen by proliferation but also have the capacity to amplify the proliferative response of lymph node cells—a capacity which is resistant to X irradiation but requires recognition of alloantigen and de novo protein synthesis. Lymph node cells may similarly respond by proliferation to alloantigen but lack the amplifier activity of thymus cells. Synergy for rat lymphoid cells, like mouse lymphoid cells, has been shown to involve an interaction of thymus-derived lymphocytes.     

Plaque-forming cells fater in vitro stimulation with theta-AKR antigen

Spleen cells of inbred mice strains carrying θ-C3H allele have been cultured in the presence of AKR thymus cells and their in vitro primary PFC response against thymic alloantigen θ-AKR was studied.The responses of a magnitude which was comparable with that obtained in previous in vivo experiments were obtained 4 days after stimulation. The strain-dependent variability of the magitude of anti-θ-AKR responses was observed in vitro. RR and C58/J spleen cells produced much more PFC than C57BL/6J and DBA/2J spleen cells. This was in agreement with previous in vivo studies on the genetic control of the anti-θ AKR responses.In the absence of AKR thymus cells, spleen cells of high responders, RR, developed in vitro PFC which released antibodies lytic to AKR thymus cells. Their number was ten-times lower than in stimulated cultures. Spleen cells of all strains tested produced also small numbers of PFC secreting antibodies against θ-identical allogenic thymus cells and even to syngenic thymus cells.     

Anti-theta Antisera may Contain Anti-allotype Contamination

THETA (θ) is a tissue-specific mouse allo-antigen present in the highest concentrations in thymus and brain^1–3. Anti-θ allo-antisera are produced after multiple injections of thymus cell suspensions into hosts differing at the θ locus, but not at the principal histocompatibility locus (H-2). Anti-θ antisera have been used by many investigators^3–9 to differentiate thymus derived lymphocytes from non-thymus derived lymphocytes and to describe the relative role of each class of cells in various immunological functions. Because it is possible that some thymocytes bear immunoglobulins bound to the cell surface, we tested the hypothesis that anti-θ allo-antisera contain antibodies directed against immunoglobulin allotype specificities of the donor, as well as antibodies to the donor θ allo-antigens.     

Cellular immune response to viral infection: in vitro studies of lymphocytes from mice infected with Sindbis virus

The development and evanescence of cell-mediated immunity to Sindbis virus infection in the mouse was studied using in vitro lymphocyte transformation. Adult mice were inoculated subcutaneously with Sindbis virus, a group A arbovirus, and cells from the draining lymph nodes and spleen were examined temporally for their ability to incorporate ³H-Tdr in the presence of Sindbis virus antigen in vitro. Lymphocyte transformation was shown to be specific and dose-related. Better stimulation was obtained with live virus antigen than with inactivated virus antigen. Specific ³H-Tdr incorporation was markedly reduced when lymph node cells were pretreated with anti-θ and complement, but anti-mouse immunoglobulin also reduced the response. Specifically sensitized cells were present in the draining lymph nodes 3–4 days after primary Sindbis virus infection, peaked at 6 days, and returned to control levels by 16 days. The response in the spleen appeared later and disappeared later. Neutralizing antibody appeared by Day 4, rose rapidly, and plateaued at a high level. The secondary cellular response differed from the primary response by being somewhat earlier and being elicitable with an amount of inactivated virus antigen which was insufficient to produce a primary response.     

Carbonic anhydrase activity in peripheral T-lymphocytes and appearance of the activity during their maturation in the thymus. A histochemical demonstration

Carbonic anhydrase (CA) activity is demonstrated in lymphoid tissue for the first time using the histochemical (Hansson's) method. A CA-positive reaction was seen in lymphocytes present in T-lymphocyte areas in both the lymph node and the spleen. The most intense staining was seen in the small T-lymphocytes, whereas the medium-sized T-lymphocytes were less markedly stained. The cortical lymphocytes in the thymus were completely devoid of staining, but the small medullary T-lymphocytes stained intensely. The results suggest that peripheral and thymic medullary T-lymphocytes contain CA activity, which appears in these cells during their maturation in the thymus.     

Induction of an antibody response in vitro against synthetic antigens in guinea pigs. I. Culture and assay conditions

Guinea pig spleen and lymph node cells were found to produce anti-2,4-dinitrophenyl (Dnp) oligolysine PFC in vivo against 2,4-dinitrophenyl-β-alanyl glycyl glycyl (Dagg-SRBC) but not against trinitrophenyl-SRBC target indicator cells. Furthermore, when sensitized spleen cells or their purified B-cell fractions were cocultured with primed peritoneal exudate lymphocytes (PEL) but not splenic T cells they were able to generate a secondary PFC response in vitro to the synthetic antigens, Dnp oligolysines. PFC were not induced in vitro if these same cultures were pulsed with short-chain peptides (five lysines) or the complex antigen, dinitrophenyl-bovine γ-globulin (DnpBGG). Con A was able to substitute for PEL in triggering spleen cells to mount a secondary in vitro PFC response to homologous Dnp oligolysines. More importantly, the Con A-aided spleen cell cultures were not induced above background values when challenged in vitro with heterologous Dnp oligolysines. This study suggests that spleen cells may lack a nonspecific signal for the development of a secondary in vitro PFC response.     

Carbonic anhydrase activity in peripheral T-lymphocytes and appearance of the activity during their maturation in the thymus

Summary Carbonic anhydrase (CA) activity is demonstrated in lymphoid tissue for the first time using the histochemical (Hansson's) method. A CA-positive reaction was seen in lymphocytes present in T-lymphocyte areas in both the lymph node and the spleen. The most intense staining was seen in the small T-lymphocytes, whereas the mediumsized T-lymphocytes were less markedly stained. The cortical lymphocytes in the thymus were completely devoid of staining, but the small medullary T-lymphocytes stained intensely. The results suggest that peripheral and thymic medullary T-lymphocytes contain CA activity, which appears in these cells during their maturation in the thymus.     

Suppressor activity in the spleen of neonatal mice.

Helper cells of T-cell origin are required for the in vitro proliferation of low numbers of adult mouse thymus cells in response to allogeneic spleen cells. These helper cells are present in the adult mouse spleen. We have demonstrated that neonatal mouse spleen cells lack the helper activity present in adult spleen cells. We have also shown that this lack of helper activity is the result of active suppression. The suppression is due to a suppressor cell which is present in high quantities in the neonatal spleen and can be eliminated by treatment with anti-θ serum and complement.