The relative importance of the bone marrow and spleen in the production and dissemination of B lymphocytes.

The relative importance of the bone marrow and spleen in the production of B lymphocytes was investigated in guinea pigs by the combined use of [³H]TdR radio-autography and fluorescent microscopy after the staining of B cells by FITC-F(ab′)₂-goat-anti-guinea pig Ig. Large and small lymphoid cells possess sIg in the marrow and spleen but B cell turnover in the marrow exceeds that in the spleen. That newly generated bone marrow B cells are not derived from an extramyeloid bursa equivalent was demonstrated by the absence of [³H]TdR labeled B cells in tibial marrow 72 hr after [³H]TdR was administered systemically, while the circulation to the hind limbs was occluded. Pulse and chase studies with [³H]TdR showed that large marrow B cells are derived from sIg-negative, proliferating precursors resident in the bone marrow and not from the enlargement of activated small B lymphocytes. The acquisition of [³H]TdR by splenic B cells lagged behind that observed in the marrow. Three days after topical labeling of tibial and femoral bone marrow with [³H]TdR, a substantial proportion of splenic B cells were replaced by cells that had seeded there from the labeled marrow. The studies unequivocally identify the bone marrow as the organ of primary importance in B cell generation and indicate that in the guinea pig rapidly renewed B lymphocytes of the spleen are replaced by lymphocytes recently generated in bone marrow. The rate of replacement of B lymphocytes in the lymph node by cells newly generated in the bone marrow takes place at a slower tempo than in the spleen.     

Peyer's patches export lymphocytes throughout the lymphoid system in sheep

The lymphocyte output from small intestine containing either the long continuous ileal Peyer's patch (PP) or several smaller jejunal PP was examined in young lambs. Most studies were done in 2-mo-old lambs, 1 mo after removal of mesenteric lymph nodes (MLN). Extracorporeal perfusion of part of the intestine and addition of fluorescein isothiocyanate to the perfusate led to the labeling, in their normal microenvironment, of a regionally defined population of cells. One day later considerable numbers of emigrant lymphocytes were identified by fluorescence microscopy in the spleen, MLN and peripheral lymph nodes, jejunal PP, and bone marrow. In nonperfused ileal PP and thymus the labeling indexes were low. The highest labeling index was in the blood where 3.7% of the lymphocytes were labeled. A similar organ distribution of emigrant cells was found on day 3. When MLN were included in the perfused region more emigrants were identified. In some animals the intestinal lymphatic draining the perfused ileum was cannulated. Continual lymph drainage caused a dramatic decrease in the labeling indexes in other lymphoid organs. A substantial number of lymphocytes leave both ileal PP and jejunal PP via lymphatics and travel to all other lymphoid organs. However, the number of emigrant lymphocytes compared with the total number of labeled lymphocytes in the perfused tissue was about 10 times greater after perfusing gut with the jejunal PP than after ileal PP perfusion. We conclude that relatively more lymphocytes emigrate from the jejunal PP than from the ileal PP.     

Differentiation of lymphocytes in mouse bone marrow. I. Quantitative radioautographic studies of antiglobulin binding by lymphocytes in bone marrow and lymphoid tissues

The density of surface immunoglobulin on small lymphocytes in the bone marrow and other lymphoid tissues has been compared by radioautographic measurements of antiglobulin binding.Cell suspensions from CBA mice were exposed to ¹²⁵I-labeled rabbit anti-mouse globulin in a wide range of concentrations for 30 min at 0 °C. With increasing concentration of antiglobulin-¹²⁵I the percentage of labeled antiglobulin-binding small lymphocytes in spleen and lymph node suspensions reached well-defined plateau levels. Very few normal or cortisone-resistant thymus cells were labeled under identical conditions. Bone marrow small lymphocytes showed a linear increment in labeled cells throughout the antiglobulin-¹²⁵I dose range, their labeling intensity varied widely, and approximately one half remained unlabeled at high antiglobulin-¹²⁵I concentrations. In 6 wk-old congenitally athymic mice the bone marrow small lymphocyte labeling pattern resembled that in CBA mice, while nearly all (91–97%) small lymphocytes in lymph nodes, thoracic duct lymph and blood, and 75% of those in the spleen, became labeled under plateau conditions. Treatment of cells from 10 wk-old CBA mice with AKR anti-θ C3H serum and complement resulted in almost complete (93%) antiglobulin-labeling of residual small lymphocytes from the spleen but had little effect on bone marrow lymphocyte labeling. Under germfree conditions the proportion of antiglobulin-binding small lymphocytes was slightly elevated in all lymphoid tissues of CBA mice.The results demonstrate that many of the small lymphocytes in mouse bone marrow have readily detectable surface immunoglobulin molecules which vary considerably in density from cell to cell, while others neither have detectable surface immunoglobulin, nor are they θ-bearing, thymus-dependent or recirculating cells. The concept of bone marrow small lymphocytes as a maturing cell population is discussed.     

Evidence of extensive lymphocyte death in sheep Peyer's patches. II. The number and fate of newly-formed lymphocytes that emigrate from Peyer's patches

The emigration of newly produced lymphocytes from Peyer's patches (PP) of lambs was studied. Mesenteric lymph nodes (MLN) were excised from most animals a few weeks after birth, and then at 8 to 10 wk of age, the dividing cells in 3 to 4 m of the small intestine were labeled in situ with [3H]thymidine. An extracorporeal perfusion system was used to restrict the 15-min period of labeling to the perfused lengths of intestine, which included either the large continuous ileal PP or a number of smaller jejunal PP. One or 3 days later, the number of labeled cells in the perfused tissue and in other lymphoid organs was studied by autoradiography. In the perfused tissues, labeled lymphocytes accounted for 63.7% of ileal PP cells by 1 day and for 86.7% by 3 days compared with only 9.6% of lymphocytes in the perfused MLN. Labeled lymphoid cells in the perfused PP were nearly all in the follicles. Labeled lymphocytes that must have been produced in the segments of ileum or jejunum at the time of the perfusion, subsequently emigrated via the lymphatics, and were identified in the spleen, MLN, other lymph nodes, blood, jejunal PP, and at a lower frequency in the thymus, nonperfused ileal PP, and bone marrow. In lymph nodes, spleen, and nonperfused PP, more than 80% of the immigrant newly formed PP-derived cells were small- and medium-sized lymphocytes, and about 15% were large lymphocytes. The nature of the labeled cells in the lamina propria of the nonperfused small intestine was quite different in that approximately 50% were plasma cells as early as 24 hr after the cells were born in the perfused gut. It is proposed that terminal B cell differentiation was most likely initiated within the PP in response to the entry of antigen. It was estimated that at both 1 and 3 days after perfusion there were about 100 times more labeled cells in the perfused ileal PP than could be accounted for by emigration to other organs. It was concluded that these results provide additional support for the view that PP in lambs produce a tremendous number of lymphocytes, but relatively few leave their site of production; most apparently die in situ.     

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.     

Migratory patterns of B lymphocytes. IV. Effect of anti-Ig on follicular localization of radioactively labeled murine spleen and bone marrow cells.

A study was made of the localization of nylon-wool-adherent (AD) and nonadherent (NA) murine spleen cells in lymphoid tissue of irradiated syngeneic recipients. Cells were labeled in vitro with [³H]uridine or ⁵¹Cr and injected intravenously. Localization in recipient tissues was expressed as percent of injected radioactivity. NA and AD [³H]uridine labeled cells gave spleen to lymph node (S:LN) ratios of 1.0 and 2.7, respectively. After treatment of AD cells with rabbit anti-mouse Fab + C at 37 °C, localization in S decreased markedly.NA cells primarily localized in LN paracortex and splenic periarteriolar sheaths. Untreated and NRS-treated AD cells localized in lymphoid follicles, whereas anti-Fab-treated AD cells did not. When ⁵¹Cr-labeled AD cells were treated with anti-Fab at 4 °C without C, there was a transient decrease in splenic localization at 24 hr followed by a recovery to the normal pattern at 48 hr after transfer. [³H]uridine-labeled bone marrow (BM) cells showed less localization in lymphoid tissue than did S cells. Some BM cells were seen in LN follicles, particularly at 48 hr after transfer, but this localization was not affected by prior treatment with anti-Fab + C. The possible role of surface Ig in the determination of follicular localization of B lymphocytes is discussed.     

Lymphoid cell kinetics in guinea pigs infected with Trichostrongylus colubriformis: tritiated thymidine uptake in gut and allied lymphoid tissue, humoral IgE and hemagglutinating antibody responses, delayed hypersensitivity reactions, and in vitro lymphocyte transformations during primary infections

The kinetics of the lymphocyte responses of Trichostrongylus colubriformis-infected and normal guinea pigs were measured by the in vivo uptake of tritiated thymidine either as dpm ³H/mg tissue or as the percentage change in [³H] -labeled lymphoblasts in autoradiographs of tissue impression smears and sections. The lymphoid response was predominantly a local one centering on the infected area of the small intestine. The greatest lymphocyte reactions as assessed by counts of labeled lymphoblasts occurred in the Peyer's patches and mesenteric lymph nodes where the peak responses took place 11 and 6 days after infection, respectively. The local nature of the responses was exemplified by the fact that the mesenteric lymph nodes of the anterior small intestine showed a peak response on the sixth day but the response from the posterior small intestine peaked 7 days later. A similar but less dramatic relationship existed among the Peyer's patches. In addition no labeled lymphoblast response was elicited in the inguinal lymph nodes or cecal lymphoid patches throughout the infection and the first increased responsiveness of the spleen did not take place until after Day 13, by which time the lymphoid proliferations associated with the infected intestine had subsided. Initially, the spleen showed a marked depletion of labeled blast cells during the first 7 days of the infection. This was taken as indicating at the time the infection was being established the export of cells capable of transformation in response to parasite antigen. This was supported by the observation that large numbers of phytohemagglutinin responsive lymphocytes were found in the peripheral circulation at this time. The in vitro responsiveness of peripheral lymphocytes to T. colubriformis antigen was also studied. Positive lymphocyte transformations first occurred 6 days after infection but thereafter declined to the normal level by Day 13; the peak transformation ratio was found 25 days after infection but by Day 38 it had declined to a low but persistently positive level. There was a correlation between the circulation of specifically sensitized cells, probably of thymic origin, IgE antibody titers, and the development of positive dermal delayed hypersensitivity reactions in infected guinea pigs, suggesting a close relationship among these three immunological phenomena.All lymphoblast responses in Peyer's patches, mesenteric lymph nodes, and lamina propria of the intestine were completed before the immune elimination of the parasite commenced 10 days after infection. During the first 10 days of infection specifically sensitized lymphocytes appeared and disappeared from the circulation. The loss of circulating sensitized lymphocytes at the time immune elimination of the parasite was taking place in the gut suggested that the sensitized cells were “homing-in” on the local area of infection. After the immune elimination of the parasite had commenced, the level of sensitized lymphocytes and IgE antibodies then increased rapidly in the blood. Evidence from the kinetics of the hemagglutinating antibodies indicated that stage specific antigens occur in T. colubriformis.     

Ontogeny of lymphatic structures in the pig omentum

Summary The development of lymphoid populations in the omentum majus during the prenatal and postnatal life of the pig was studied. T lymphocytes, monocytes and mast cells were first found on the 40th day of gestation. B lymphocytes appeared on the 72nd day of gestation when the first macrophage aggregates were formed. Macrophages appeared to be the prerequisite for the formation of dense lymphatic areas (DLA's). At later stages T cells were observed only in the omentum of germfree pigs. DLA's of conventional pig omentum are filled exclusively with B cells.     

REUTILIZATION OF LYMPHOCYTE DNA BY CELLS OF INTESTINAL CRYPTS AND REGENERATING LIVER

Lymphoid cells from mice injected 54 hours and 30 hours earlier with ³H-thymidine were washed and transfused into isogenic recipients at 29 to 30 hours after partial hepatectomy. The recipients were killed 28 to 30 hours later, and liver, intestine, Peyer''s patch, spleen, and the transfused cells were examined in autoradiographs exposed 6 months. Approximately 80 per cent of the labeled transfused cells were classed as lymphocytes. The labeled DNA contained in the transfused cells was partitioned to about 14 times as many recipient liver and intestinal cells, appearing in 72 to 78 per cent of hepatocyte nuclei, in 30 to 35 per cent of liver reticuloendothelial nuclei, and in 90 to 95 per cent of intestinal crypt nuclei. The label was not comparably widespread in the lymphoid organs, but was limited to a few intensely labeled lymphocytes and a somewhat larger number of very weakly labeled cells. When heat-killed cells rather than living cells were transfused, intensely labeled lymphocytes were absent from the lymphoid organs, but the labeling of cells in the recipients was otherwise identical. The results suggest that (a) reutilized DNA is derived from dead cells, (b) reutilized DNA is mainly degraded to nucleosides and nucleotides, the usual immediate de novo DNA precursors, before reincorporation into DNA, and (c) DNA reutilization may occur in the lymphoid organs, but on a less active scale than in intestine or regenerating liver.     

Germinal centers and the B-cell system

Summary The migration pattern of germinal center cells of the rabbit appendix was studied and compared with that of appendix dome cells, spleen cells, thymus cells and thoracic duct lymphocytes. To discriminate T-and B-cell migration pathways, normal or T-cell-depleted rabbits were used as donors. Cell suspensions were labeled in vitro with ³H-leucine followed by intravenous transfer. The migration of labeled cells in lymphoid organs was studied using autoradiography, particular attention being paid to the spleen of the recipient. B-cells from the appendix dome, spleen and thoracic-duct lymph migrate to primary follicles or the corona of secondary follicles via thymus-dependent areas of peripheral lymphoid organs. In contrast, a B-cell subpopulation from the germinal centers of the appendix migrates to the center of splenic primary follicles and into germinal centers. The migration of germinal center cells to splenic follicle centers is not enhanced by specific antigens. The migration properties of B-cells, possibly changing during differentiation, may be instrumental in the two types of immune reactions, i.e., plasma-cell reaction and germinal-center reaction.     

THE PREDOMINANT ROLE OF THE SPLEEN IN LYMPHOCYTE RECIRCULATION

Lymphocyte recirculation through the isolated pig spleen was studied by means of a perfusion system which kept the organ alive for a prolonged period of time. By changing the perfusate to a leucocyte-enriched or cell-free perfusate and taking serial arterial and venous samples, the numbers of lymphocytes which homed to or were released from the spleen were measured. In all experiments more lymphocytes homed than were released per minute. There was no apparent difference when autologous or allogeneic cells were used. The number of lymphocytes released depended on the number of lymphocytes homed previously. During the phase of constant release up to 3-3 × 10⁶ lymphocytes were released per gram spleen per minute. From these values it can be extrapolated that up to 270 × 10⁹ lymphocytes recirculate through the isolated pig spleen per day. Based on kinetic data from other species it is estimated that in the entire pig a total number of 300–400 × 10⁹ lymphocytes recirculate per day. Thus, it can be concluded that the spleen is the most important organ for lymphocyte recirculation in the pig.     

Comparison of in vitro and in vivo cell cycle parameters of lymphoid cells in Pig spleens

Summary Parameters of the cell cycle of lymphoid cells were estimated by analyzing percent labeled mitoses curves after a ³H-thymidine flash. Either anaesthetized pigs were labeled and multiple biopsies taken from the spleen in vivo or isolated perfused pig spleens were labeled in vitro. The data from in vivo and in vitro experiments were very similar.The mean values for cell cycle parameters were: 20.2 to 20.5 hours for the generation time, about 0.5 to 1 hour for G₂, about 1.2 to 1.3 hours for M; about 17 to 16.5 hours for S and about 1.5 to 1.7 hours for G₁. The mean grain count halving time of labeled mitoses was in accordance with the measured generation time. The isolated perfused spleen seems to give results equal to in vivo data and could, therefore, be employed as a model for studying cell cycle parameters not only in animal but also in human lymphoid tissue.The expert technical assistance of Mrs. A. Fischer is gratefully acknowledged. This study was supported by the Deutsche Forschungsgemeinschaft, SFB 112.     

急性巨细胞病毒感染导致新生豚鼠脾细胞亚群的定量改变

新生豚鼠皮下接种豚鼠巨细胞病毒(GPCMV)后,导致脾脏GPCMV急性感染,脾脏肿大,脾细胞增生,计算表明,脾T淋巴细胞,B淋巴细胞、吞噬细胞数显著高于正常动物,接种病毒后第5天即可在脾细胞检出高滴度感染性病毒(达2.5 log10 TCID50/10~7细胞),其中,主要是脾B淋巴细胞、T淋巴细胞和巨噬细胞携带病毒。     

Variation in the homing properties of 51Cr-labeled thy antigen-positive lymphoma

The homing properties of five thy antigen-positive murine lymphoma cell lines in normal syngeneic mice were compared to those of thymus, lymph node, bone marrow, and spleen cells. YAC lymphoma cells migrated in significant numbers to the spleen but in somewhat smaller percentages than normal lymphoid cells. An immunoselected subline of YAC was recovered from recipient spleens in about double the amounts observed with the parental lymphoma line. The migration patterns produced by lymphoma YC8, AKR, and LSTRA more closely resemble those of the selected subline of YAC. None of the lymphoma used in this study homed to recipient lymph nodes. That the selective distribution of labeled lymphoma cells was a function of cell viability was demonstrated by the fact that heat-killed lymphoma cells were recovered almost exclusively from the liver. Neuraminidase treatment, prior to ⁵¹Cr labeling, changed the migration in vivo of all the lymphoma studied except YAC. In contrast, trypsinization of the lymphoma did not influence their distribution in vivo. Binding of concanavalin A (Con A) to the cell membrane modified the homing of normal lymph node cells but did not change the migration of lymphoma cells. The conclusion was drawn that many receptors normally present on T lymphocytes are missing or modified after transformation and that the lymphoma in question more closely resembles the sessile splenic T1 lymphocyte.     

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.     

Pathways of lymphocyte migration within the periarterial lymphoid sheath of rat spleen

Summary Male Wistar rats were injected intravenously with 5-(³H)uridine-labeled lymphocytes isolated from lymph nodes of syngeneic donors and enriched in T cells. After short periods of time (3 to 120 min after injection), labeled lymphocytes were localized in spleen compartments using autoradiography to identify routes of lymphocyte movement from blood into splenic parenchyma and to follow migration pathways of recirculating lymphocytes within the periarterial lymphoid sheath (PALS). Topographical analysis of labeled lymphocytes was performed in specific planes of PALS characterized by the diameter of the arterial vessel and termed PALS large, PALS medium, and PALS small (PALS L, PALS M, PALS S, respectively). Attention was also paid to accumulations of labeled lymphocytes close to the arterial vessel wall. Initially, labeled lymphocytes were localized in PALS S and PALS M near the terminal branching of arterial vessels and in the marginal zone (MZ). We conclude that lymphocytes emigrate from blood into splenic parenchyma within two white pulp compartments: in MZ, and directly within PALS through the wall of capillary vessels. The sequential accumulation of labeled cells near arterial vessels of increasing diameter suggests that the recirculating pool of lymphocytes migrates into the central part of PALS L by two routes: from MZ, and along arterial vessels from PALS S and PALS M.R.B. was a fellow of the Alexander von Humboldt-Stiftung, on leave from the Department of Histology and Embryology, Institut of Biostructure, Academy of Medicine, ul. Swiecickiego 6, PL-60-781 Pozna, Poland.     

POST-MITOTIC AGE OF MONONUCLEAR CELLS MIGRATING INTO TA-3(St) SOLID TUMORS

Subcutaneous transplantation of 5 × 10⁶ TA-3(St) mammary carcinoma cells into A/J mice produced rapidly growing tumors that showed a substantial accumulation of lymphocytes, monocytes and macrophages. This must have resulted primarily from an influx of circulating cells, since none of the cell types exhibited any significant local proliferation as indicated by 1 hr ³H-TdR uptake. The post mitotic age of the various leukocyte types in circulation of normal and tumor bearing animals, and those appearing within the tumors, was evaluated by a repeated ³H-TdR labeling protocol designed to label newly formed leukocytes. Tumor transplantation (or injection of an equivalent volume of saline in control animals) was preceded by thirteen ³H-TdR injections (12.5 μCi every 8 hr) and followed by eight more injections at equivalent intervals. Animals were serially sacrificed at 5-14 days after tumor transplantation or saline injection. Total lymphocyte labeling in the blood during these intervals was higher in tumor bearing mice (approximately 25% between 5 and 12 days) than in the saline injected controls (approximately 20%), indicating that tumor transplantation resulted in an increase in the proportion of young lymphocytes in circulation. More significantly, a much higher labeling (57-60% at 5-12 days) was exhibited by lymphocytes isolated from the tumors, indicating selective migration (and/or retention) of newly formed lymphocytes within the tumor. This finding applied to lymphocytes in all size categories. Although blood monocyte labeling in the control and experimental animals was similar (e.g. 83% at day 5 and 52% at day 14), significantly higher labeling (e.g. 93% and 70% at the respective intervals) was exhibited by monocytes isolated from tumors. This suggested a preferential accumulation of young monocytes at the tumor site. An identical macrophage labeling pattern compared to that shown by monocytes within the tumor indicated a rapid monocyte-macrophage transition. Since these findings in the present strain-specific solid tumor are similar to those previously obtained in this laboratory in the strain-nonspecific Ehrlich ascites tumor, the phenomenon of selective localization of newly formed mono-nuclear leukocytes appears to be a general occurrence in transplanted murine tumors.     

Differentiation of lymphocytes in mouse bone marrow. II. Kinetics of maturation and renewal of antiglobulin-binding cells studied by double labeling

DNA labeling by ³H-thymidine in vitro and antiglobulin-¹³¹I binding in vitro were used to determine the development and turnover of immunoglobulin-bearing lymphocytes in mouse bone marrow.Bone marrow cells from CBA mice previously injected repeatedly with ³H-thymidine for 1–84 hr were exposed to ¹³¹I-labeled rabbit-antimouse globulin for 30 min at 0 °C, and examined radioautographically. The antiglobulin-binding cells in bone marrow were predominantly (97–98%) nondividing small lymphocytes. Some plasmacytoid and monocytoid cells, but not the proliferating large lymphoid cells, also bound antiglobulin. The ³H-thymidine labeling index of the small lymphocyte population showed a rapid exponential increase (50% in 32 hr). The first small lymphocytes to show ³H-thymidine labeling were those lacking antiglobulin-binding capacity, reaching approximately 90% ³H-thymidine labeling after 2 days. Small lymphocytes which bound antiglobulin-¹³¹I at a concentration of 1.0 μg/ml became labeled with ³H-thymidine only after a lag of approximately 1.5 days. More avid antiglobulinbinding cells were delayed a further 12 hr in ³H-thymidine labeling. During in vitro culture the proportion of antiglobulin-binding small lymphocytes increased progressively in bone marrow but decreased in spleen cell suspensions.The results demonstrate a continuous, rapid renewal of immunoglobulin-bearing small lymphocytes in adult mouse bone marrow. Surface immunoglobulin molecules are not detectable when marrow small lymphocytes are first formed, but they appear and increase progressively in density as the cells mature.     

Regulation of bone marrow lymphocyte production: III. Increased production of B and non-B lymphocytes after administering systemic antigens

To examine the influence of exogenous stimuli on the genesis of lymphocytes in mouse bone marrow, the production rate and subsets of marrow lymphocytes were examined after a systemic injection of sheep red blood cells (SRBC). Radioautographic analysis after either pulse labeling or infusion of [³H]thymidine revealed a pronounced increase in the number of newly formed small lymphocytes appearing in the marrow, maximal 4–5 days after SRBC injection and dose related. The resulting expansion of the marrow lymphocyte population included both immature B cells and null cells, as shown by cell surface and cytoplasmic markers. Similar stimulation of marrow lymphocyte production followed an injection of either bovine serum albumin or mineral oil. No comparable stimulation occurred in either the thymus or the spleen. The results demonstrate that antigens and nonspecific irritants can exert a central effect in the bone marrow, producing a surge in the production of both primary B and non-B lymphocytes. The possible role of external stimulants in determining the normal rate of bone marrow lymphocyte production is discussed.     

FATE OF THYMOCYTES: STUDIES WITH 125I-IODODEOXYURIDINE AND 3H-THYMIDINE IN MICE

Cortical thymocytes of young adult mice were labeled in situ with radioactive DNA precursors. As a result of cell emigration and cell death, total thymic radioactivity decreased within 8 days to 10% or less of that present on day 1. Accumulation of thymic migrants in peripheral lymphoid organs was estimated by computing the net thymus-derived radioactivity in these tissues. Thymic cell death was assessed by comparing values obtained with ¹²⁵I-UdR to those acquired with ³H-TdR. The results indicate that cortical thymocytes migrate to the spleen, mesenteric lymph node, femurs and intestine; nevertheless, only a small fraction of the activity originally present in the thymus was recovered in these organs; the vast majority of newly formed cortical thymocytes apparently die after a relatively short life span. Exclusive of the fraction which dies in situ, evidence for thymocyte death is seen in bone marrow; however, most migrants appear to terminate in the intestine.