Circulating T and B lymphocytes of the mouse. I. Migratory properties

Studies on the identity of thoracic duct lymphocytes (TDL⁴) from normal and T cell-depleted mice indicated that as many circulating B lymphocytes were produced by healthy T cell-depleted mice as normal mice. Proportions of T and B cells from the thoracic duct of CBA mice changed markedly during the first 4 days of drainage from 82% T cells and 16% B cells at 12 hr to approximately equal proportions of both classes after 3 days. In absolute terms, T cells were mobilized rapidly by thoracic duct drainage and B cells very slowly. Histologically, this was reflected in a rapid depletion of the T cell-dependent areas of the lymphoid organs. The B cell-dependent areas, in contrast, became depleted of lymphocytes only after drainage for a week or more.The homing properties of circulating lymphocytes were investigated using TDL from normal and T cell-depleted mice as relatively pure sources of T and B cells, respectively. Four hours after injection of ⁵¹Cr-labeled T and B cells, a large proportion of both cell classes were found in the spleen. By 24 hr, many T cells had left the spleen and appeared in the lymph nodes. Such redistribution by B cells, however, was minimal.Intravenously injected T and B cells, labeled with tritiated uridine (³HU), localized specifically in the T and B cell-dependent areas, respectively, of the lymphoid tissues.³HU-labeled T cells were found to recirculate rapidly from blood to lymph. Labeled B cells, in contrast, recirculated only very slowly.     

Rapid anti-helminthic response of B lymphocytes in the intestinal mucosal tissues of rats

B cell response to Trichinella spiralis (Ts) adult antigen (Ag) was studied in rats 1-20 days postinfection. B cell recoveries from the mesenteric lymph node (MLN), Peyer's patches (PP), thoracic duct lymph (TDL), and the spleen were determined by FACS analysis and Ag-specific antibody-producing cells (Ab-pc) in these tissues were enumerated using the immunoplaque assay. Total B cell numbers increased 2-70 times from day 3 postinfection in the MLN and TDL obtained from MLN-resected rats (MX) and such proliferation was not found in the PP or the spleen. Ab-pc of all isotypes increased from day 3 in the MLN and from day 2 in the MX-TDL. Among all isotypes, IgE- and IgG1-pc showed the strongest response. Immunofluorescence study revealed that these B cells were activated in the non-PP region of the small intestine. These results indicate an early isotype switch to IgG1 and IgE production in Ts-infected small intestine.     

The generation of large pyroninophilic cells in the lymphoid tissues of rats infused with cell-free lymph.

The thoracic duct of Wistar strain rats was cannulated during 5 days for studying the effect of selective lymphocyte depletion on the lymphoid tissue. A technique for the continuous infusion of cell-free lymph, whole lymph of Eagle's medium to the rat with the thoracic duct fistula is described in detail. The prolonged drainage of lymph from rats was followed by lymphopenia, sever atrophy of lymphoid tissues and the depletion of small lymphocytes in the thymus-dependent areas of spleen and lymph nodes. The infusion of cell-free lymph into the drained rat resulted in the recovery of the weight of lymphoid tissues and in the massive proliferation and accumulation of large cells with prominent nucleoli and intensely pyroninophilic cytoplasm in the lymphocyte depleted areas of the peripheral lymphoid tissues and thymic cortex. There was histological evidence that the large pyroninophilic cells developed well in the spleen and tended to localize preferentially around the periarteriolar region through the marginal zone bridging channels to the red pulp. The infusion of Eagle's medium was found ineffective in restoring the weight of the lymphoid tissues and in bringing about the proliferation of lymphoid cells. The rats infused with whole lymph showed almost similar findings biologically and histologically to those of sham-operated rats.     

STUDIES ON LYMPHOCYTES

Continuous extracorporeal irradiation of the circulating blood (ECIB) of from 3 to 501/2 hr duration was used to study in the calf the differential depletion of lymphocytes from spleen, lymph nodes and thymus as compared to blood and thoracic duct lymph. The cell content of tissues was measured by planimetry and/or test point analysis. Lymphocyte depletion by ECIB from various lymphoreticular organs, and from different areas within a given organ, was less than in the circulating blood or the thoracic duct lymph and varied from one site of a lymphoreticular organ to another. The degree of depletion with time followed an exponential function with at least two components. The first component corresponded to a relatively rapid fall and the second to a very slow reduction in lymphocyte content. The former is related to the elimination of an easily mobilizable pool of lymphocytes while the latter corresponds to a more sessile mass of lymphocytes which exchange with blood lymphocytes very slowly. Elimination of the easily mobilizable pool of lymphocytes by ECIB from all tissues studied was observed within 10–15 hr, indicating that the rate of exchange with blood is similar for this group of cells in various lymphoreticular tissues. The size, however, of the easily mobilizable vs the more sessile pools of lymphocytes may vary considerably, the best estimates for the former being as follows (in per cent of total lymphocyte mass): lymph node medulla, less than 10%; lymph node cortex plus paracortical zone, 18% (depletion mainly paracortical); red pulp of the spleen, 37%; densely populated white pulp of the spleen, 55%; and loosely populated white pulp of the spleen, 60%. In comparison, the approximate fractions of lymphocytes originating fromthe easily mobilizable pools in various lymphoreticular tissues plus the cells already circulating a t the onset of EClB correspond to 64% for the thoracic duct lymph and 78% for the circulating blood respectively. These findings are discussed in relation to production, recirculation and life span of lymphocytes, and immune reactions.     

Antigenic relationship between medullary thymocytes and a subpopulation of peripheral T cells in the rat: description of a masked antigen.

Using differentially absorbed rabbit antisera to rat thoracic duct cells, an antigen is described which normally is expressed on the surface of T cells in thoracic duct lymph and lymph node, but which exists in a masked form on medullary thymocytes and apparently not at all on cortical thymocytes. This antigen is termed the rat masked thymocyte antigen (RMTA). RMTA on medullary thymocytes can be unmasked mechanically by sectioning in a cryostat or enzymatically by treating with neuraminidase. Trypsin destroys or removes RMTA. Nearly all the T cells in thoracic duct lymph and lymph node are RMTA⁺, whereas only 58–66% of T cells in spleen are RMTA⁺. RMTA⁺ T cells, which are cortisone resistant, reside in the paracortex and periarteriolar sheath regions of lymph node and spleen. RMTA^? T cells, which are cortisone sensitive, appear to reside in the red pulp of spleen. The results suggest that (i) two antigenically distinct populations of T cells exist in the rat, RMTA⁺ and RMTA^? T cells, (ii) medullary thymocytes are the immediate precursors of RMTA⁺ T cells, and (iii) cortical thymocytes may be the immediate precursors of RMTA^? cells.     

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.     

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.     

Dual fluorochrome analysis of human B lymphocytes: phenotypic examination of resting, anti-immunoglobulin stimulated, and in vivo activated B cells

B cell-enriched preparations were prepared from human peripheral blood and lymphoid tissues by the depletion of T cells and monocytes. Only B cells by virtue of their staining with anti-B1 conjugated to fluorescein were additionally examined. Dual fluorescence staining and flow cytometric analysis demonstrated that the majority of "resting" human peripheral blood and splenic B cells co-express the B cell-restricted B1 and B2 antigens and lack B5, a B cell-restricted activation antigen, and interleukin 2 receptor (IL 2R). In contrast, nearly 2/3 and 1/3 of B1+ cells isolated from lymph node expressed IL 2R and B5 antigens, respectively. When B1+ B cells from peripheral blood and spleen were "activated" by anti-Ig, they lost the B2 antigen and acquired the B5 and/or IL 2R antigens. 2/3 of B1+ cells strongly expressed IL 2R, and up to 1/2 of B1+ cells co-expressed B5. Delineation of increased numbers of B1+ cells that co-express B5 and/or IL 2R within lymphoid tissues obtained from patients with diseases characterized by "activated" B cells provides in vivo confirmation that these phenotypic changes correlate with B cell activation. We believe that the identification and isolation of these and similar subsets of cells defined by differing cell surface phenotypes should further our understanding both of normal B cell activation and the pathophysiology of B cell disease states.     

Physiology of B cells in mice with X-linked immunodeficiency. I. Size, migratory properties, and turnover of the B cell pool

In terms of certain immune functions and density of surface IgM, B cells from xid mice are often viewed as the equivalent of the immature (Lyb-5-) B cell subset of normal adult mice. In this paper we examine xid B cells with regard to certain physiologic functions, including homing to the lymphoid tissues, recirculation, and turnover. Xid mice were found to possess about one-third of the total number of B cells found in normal mice. This applied irrespective of whether one examined the spleen, lymph nodes, or outputs of B cells in thoracic duct lymph. In terms of migration to spleen, lymph nodes, and Peyer's patches, capacity to recirculate from blood to thoracic duct lymph, and turnover, xid B cells proved to be indistinguishable from normal spleen or thoracic duct B cells. Within these parameters, most xid B cells closely resemble the normal mature long-lived population of B cells residing in the recirculating pool of normal mice. Because xid B cells are functionally quite different from normal mature B cells, it seems reasonable to view xid B cells as an abnormal population not represented in normal mice.     

Interaction of the lymph node and splenic lymphocytes of mice in inactivation of allogeneic hematopoietic stem cells

A study was made of interaction of mouse spleen and lymph node lymphocytes in inactivation of allogeneic stem cells. It was established that T lymphocytes of the lymph nodes and spleen lymphocytes do not interact on combined administration; their action is of additive nature. B lymphocytes of the lymph nodes have a regulating activity both in respect to T lymphocytes of the lymph nodes and lymphocytes of the spleen. The stem cells serve as target. Depending on the stem cells/B lymphocytes ratio B lymphocytes are capable of exerting either helper or suppressor action.     

Freezing of rat lymphocytes. 2. Distribution and circulation of frozen-thawed 51Cr-labelled cells

Radioactive labelled synegenic fresh and frozen-thawed rat lymphoid cells were injected into groups of animals and their distribution in liver, spleen, lung, lymph nodes, and thoracic duct recorded. Principally the same pattern of distribution was demonstrated after injection of both fresh and frozen-thawed cells. However, more radioactivity was recovered from the liver and less from lymph nodes and thoracic ducts in recipients of frozen-thawed than of fresh cell preparations. This is caused by some damage to the cells in the freeze-thaw process.     

The entry of T and B lymphocytes into rat popliteal lymph nodes undergoing a graft-versus-host reaction

The entry of radiolabeled blood-borne T and B lymphocytes into resting popliteal lymph nodes and popliteal lymph nodes stimulated with semiallogeneic lymphocytes was investigated in rats. Thoracic duct lymphocytes separated into T- and B-lymphocyte populations on nylon-wool columns were radiolabeled with 51chromium and equal numbers of T or B lymphocytes were injected intravenously. While the ratio of T and B lymphocytes in the blood is approximately 3:1 it was found that the ratio of T to B lymphocytes migrating into lymph nodes was approximately 9 T to 1 B lymphocyte in both resting and antigenically stimulated lymph nodes. Since the ratio of T to B lymphocytes in thoracic duct lymph is similar to that of blood, there is a disparity between the number of T cells entering and leaving lymph nodes. These results suggest that some T lymphocytes may return to the blood directly and/or there is increased T lymphocyte death in lymph nodes.     

Circulating T and B lymphocytes of the mouse. II. Lifespan

The average lifespan of circulating lymphocytes was investigated by determining the percentage of labeling of thoracic duct lymphocytes (TDL⁵) from mice injected with tritiated thymidine (³HT) for various periods. Percentage of labeling of TDL from normal CBA mice, which consist of approximately 85% T cells and 15% B cells, was found to be directly proportional to the time of ³HT administration. This technique thus failed to demonstrate the presence of more than one population of lymphocytes. Less than 50% of TDL were labeled after ³HT injection for 8 weeks.Percentage of labeling of TDL from nude mice (which consist solely of B cells) was likewise found to be directly proportional to the duration of ³HT injection but occurred at a rate three to four times faster than in non-T cell-depleted CBA mice. Further experiments, in which a marker for B cells was used, allowed the rate of ³HT labeling of B cells to be studied in normal CBA mice. These data corroborated the findings in nude mice and indicated that, with regard to lifespan, thoracic duct B cells consisted of a single population with an average lifespan of 5–7 weeks. Similarly it was calculated that the average lifespan of thoracic duct T cells was in the order of 4–6 months.Studies on the rate of formation of TDL during prolonged thoracic duct drainage of normal CBA mice indicated that the percentage of newly formed cells increased rapidly after 24-hr drainage. The total numbers of newly formed cells, however, were found to remain relatively constant throughout the period of drainage investigated (up to 9 days) except for a transient increase during the second and third day. Newly formed small lymphocytes were found to consist of approximately equal proportions of T cells, B cells, and other “mononuclear” cells which lacked surface markers for either T or B cells. The great majority of large lymphocytes, in contrast, were found to be neither T cells nor B cells and probably belonged to the plasma cell line. In nude mice, production of newly formed lymphocytes during prolonged thoracic duct drainage was found to be very low in comparison with normal CBA mice.     

Further evidence for the existence of B-lymphocyte subpopulations.

We have studied the homing properties of B lymphocytes by using ⁵¹Cr-labeled lymphoid cells obtained from athymic, nu/nu mice, and animals made T-lymphocyte deficient by thymectomy and lethal irradiation followed by reconstitution with syngeneic bone marrow. Comparison was made to the patterns of distribution observed when cell preparations containing normal numbers of T and B lymphocytes were migrated. A small but significant percentage of labeled lymphocytes from lymph nodes, spleen, Peyer's Patches, and bone marrow of T-cell-deficient animals was shown to be lymph node seeking. Secondary transfers of lymph node cells from primary recipients caused enrichment of this lymph node-seeking population. Treatment of T-lymphocyte-deficient lymphoid cell preparations with neuraminidase reduced the percentages of cells homing to the lymph nodes. The data showed that B lymphocytes exhibit unique homing properties when injected into normal recipients. In addition, direct comparison of the homing patterns of B lymphocytes prepared from spleen and lymph nodes of athymic mice revealed differences suggesting that these lymphoid organs contained unique mixtures of at least two different kinds of B cell. The evidence supports the notion that the B-lymphocyte populations contain at least two subpopulations, one of which possesses the ability to home to lymph nodes.     

Effects of isolated tumor lymphocytes alone and with adherent cells

Summary The effect on the growth of gradient-isolated mouse mammary tumor cells of different populations of lymphoid cells were evaluated in micrototoxicity assays. Variable effects were obtained with tumor-bearer lymph node and spleen cells: in some experiments growth stimulation occurred, whereas in others inhibition was observed. Mixed effector populations gave more regular results: adherent spleen cells added to lymph node or spleen lymphocytes inhibited tumor cell growth in six of nine experiments; inhibition occurred when either of the effector populations in the mixture was derived from the tumor-bearing mouse. Tumor-associated lymphoid cells (TAL) stimulated growth of the tumor cells in five of seven experiments. However, TAL inhibited tumor growth when combined with adherent spleen cells from tumor-bearing animals. In contrast with the peripheral lymphoid cells, admixture of control adherent cells from normal animals with TAL did not inhibit growth. No natural killer effect was seen in these growth inhibition assays. These data indicate that lymphoid populations capable of inhibiting tumor cell growth can be found in tumor-bearing animals, but such combination of active cells are not present at the tumor site.     

The separation of different cell classes from lymphoid organs. X. Preparative electrophoretic separation of lymphocyte sub-populations from mouse spleen and thoracic duct lymph

Conditions have been established for the separation of viable mouse lymphoid cells by continuous free-buffer film preparative electrophoresis. The detailed electrophoretic distribution profiles of T and B lymphocytes from mouse spleen and thoracic duct have been determined. Cell surface θ-antigen was used as a marker for T cells, and high surface-density of immunoglobulin as a marker for B cells. Spleen cells from athymic “nude” mice were also studied. In the unselected normal spleen cell populations B lymphocytes are heterogeneous, about 60% being of low mobility with the remainder distributing broadly, and extending into the highest mobility fractions. T lymphocytes are predominantly of high mobility. Lymphoid cells lacking markers of either the B or T lineage are of intermediate mobility. There is only partial separation of T and B cells because of the extensive overlap between the populations. The high mobility B cells, which separate along with T cells, include a substantial proportion of large cells, and include cells with high surface density of immunoglobulin. The majority of these large B cells can be selectively eliminated by their adherence on passage through a glass-bead column. By pre-selecting the 50% non-adherent lymphocytes from spleen as the starting material, a very sharp and more extensive separation of B and T cells can be achieved, with 100% pure B cells and 90% pure T cells in many fractions. However these samples are not representative of the total T and B cell populations of spleen. In thoracic duct lymph high mobility B-cells are absent, there is little overlap between T and B cell mobility. 100% pure T and B cells can be isolated.     

Cellular responses of cats with primary toxoplasmosis.

The cellular responses of 8 kittens (4 inoculated orally with mouse brains containing Toxoplasma gondii cysts and 4 uninfected controls) were studied. Oocyst numbers, body weight, and rectal temperature were monitored daily. Blood was collected weekly for serology and mononuclear cell purification. At necropsy, peritoneal and alveolar macrophages, spleen, and lymph node cells were harvested. Infected cats shed oocysts 4-15 days postinfection, maintained normal body weight and rectal temperature, and developed anti-T. gondii immunoglobulin M and G. Infected cats had normal surface immunoglobulin-positive cell populations and peripheral blood lymphocyte functions. The infected cats differed in their responses from control cats in that they developed circulating T. gondii antigen-specific lymphocytes, had increased interleukin 1 secretion by monocytes, had spleen and lymph node cells with depressed mitogenic responses and interleukin 2 production, and had macrophages with enhanced abilities in preventing the intracellular proliferation of T. gondii. Overall, the primary response of the cat to an infection with T. gondii appeared similar to that of other hosts.     

The B cell is the initiating antigen-presenting cell in peripheral lymph nodes

We have examined the role of B cells in antigen presentation in lymph nodes in several ways. We found that mice depleted of B lymphocytes via chronic injection of anti-mu-chain antibody do not mount peripheral lymph node T cell proliferative responses to normally immunogenic doses of antigen. Depletion of B cells by passage of immune lymph node cells over anti-immunoglobulin columns early after immunization depletes antigen-presenting function from draining lymph nodes, and this function can be restored by using B cells or splenic adherent cells to allow the remaining T cells to proliferate. Lymph node B cells present antigen very effectively to lines of antigen-specific T cells. However, unfractionated lymph node cells from anti-mu-treated mice present very poorly, if at all, whereas unfractionated spleen cells from the same mice do present antigen. This is in keeping with our previous finding that helper T cell function in the spleen is normal in B cell-deprived mice. Finally, when mice homozygous for the lymphoproliferative gene lpr are treated chronically with anti-mu-chain antibody, lymphadenopathy is greatly retarded, suggesting a role for B cells in the massive proliferation of T cells in this syndrome. From this analysis, it would appear that the initiating antigen-presenting cell in the lymph node is a B lymphocyte, and that B lymphocytes in lymph nodes may be distinct from those in the spleen. It is of interest that these results also suggest that the lymph node lacks an antigen-presenting cell that is found in the spleen, perhaps the dendritic cell.