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.     

LYMPHOCYTE POPULATIONS IN MOUSE BONE MARROW: QUANTITATIVE KINETIC STUDIES IN YOUNG, PUBERTAL AND ADULT C3H MICE

Continuous ³H-thymidine infusion was used to characterize two kinetic subpopula-tions of small lymphocytes in mouse bone marrow during normal growth and development. Young (4 wk), pubertal (8 wk) and mature (16 wk) C3H mice were infused subcutaneously with ³H-thymidine for periods up to 10 days. Femoral marrow was then examined in radioautographic smears. During the first 3 days the proportion of marrow small lymphocytes labelled by ³H-thymidine showed a rapid exponential increase to 93%, 81% and 72% in 4 wk, 8 wk and 16 wk mice respectively. The rate of appearance of labelled small lymphocytes then declined markedly but remained higher in younger than in older animals. The labelling curves were found to represent the summation of two exponential curves from which the proportions and renewal rate of corresponding cell populations were calculated. Most marrow small lymphocytes comprised a rapidly renewing population but in mice of increasing age the relative incidence of these cells fell (93-3% at 4 wk; 88-0% at 8 wk; 78-5% at 16 wk) and their half-renewal time (T_½) lengthened (14 hr at 4 wk; 18 hr at 8 wk; 24 hr at 16 wk). The remaining small lymphocytes were slowly renewing with mean T_½ of 4, 7 and 14 days in 4, 8 and 16 wk mice, respectively. Some heavily labelled small lymphocytes persisted in the marrow up to 10 wk after fourteen daily ³H-thymidine injections in 10–12 wk mice. The numbers of rapidly renewing cells decreased from 604 times 10³ to 228 times 10³ per mm³ of marrow from 4 wk to 16 wk, respectively, while slowly renewing cells increased from 44 times 10³ to 61 times 10³ per mm³. The total number of nucleated marrow cells per femur increased from 4 wk to 16 wk but the rapidly renewing small lymphocytes per femur fell in numbers by 36% and in renewal rate by 63%. The results demonstrate a selective change in bone marrow small lymphocytes with age; rapidly renewing cells decline in number and renewal rate while the number of slowly renewing cells increases. The concept of bone marrow as a primary lymphoid organ is discussed.     

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.     

Properties of reticulum cell sarcomas in SJL/J mice: II. Fate of labeled tumor cells in normal and irradiated syngeneic mice

Transplantable reticulum cell sarcoma (RCS) cells were labeled with ³H-uridine or ³H-thymidine in vitro and injected intravenously into normal and irradiated syngeneic SJL/J mice. RCS cells exhibited typical B cell migration characteristics in peripheral lymphoid organs in both normal and irradiated recipients, localizing in follicles in a pattern resembling that of labeled normal bone marrow cells. However, over the first 72 hr after transfer, RCS cells diluted their label much less in irradiated than in normal recipients, reflecting their inability to proliferate in the irradiated hosts. The presence of unlabeled tumor cells did not significantly affect the distribution of labeled normal bone marrow or lymph node cells in the recipients. Thus, RCS fails to grow in irradiated recipients in spite of undisturbed homing characteristics and in the absence of any evidence of cytotoxic influences from the host.     

Population dynamics of "null" and Thy1lo lymphocytes in mouse bone marrow: genesis of cells with natural killer cell lineage characteristics.

The population dynamics of "null" small lymphocytes lacking B and T lineage markers in mouse bone marrow have been examined using a combination of immunolabeling and hydroxyurea (HU) deletion techniques. The binding of the B lineage-associated mAb, 14.8, and anti-Thy1.2 to bone marrow cells has been detected radioautographically. Null cells lacking 14.8 and Thy1.2 determinants (14.8- Thy1-) formed a substantial subset (12-14%) of bone marrow small lymphocytes, representing 0.5 x 10(6) cells per femur (2-3% of nucleated cells). HU treatment revealed an exceptionally rapid turnover of the null small lymphocyte population (T1/2, 7.5 hr) compared with 14.8+ cells (T1/2, 20.5 hr) and Thy1+ cells (T1/2, 53 hr). Small lymphocytes bearing low intensities of Thy1 (Thy1lo) were also rapidly renewed (T1/2, 28 hr) whereas those with high intensities of Thy1 (Thy1hi) were renewed only slowly (T1/2, 123 hr). During ontogeny, null small lymphocytes first appeared in the fetal liver by Day 11 and the fetal spleen by Day 16, but increased rapidly in the bone marrow in early postnatal life. Double immunolabeling techniques demonstrated that 10% of null small lymphocytes in the bone marrow expressed NK1.1 antigen, while larger proportions bound to tumor (YAC.1) cells in vitro and displayed Fc receptors. The NK1.1-bearing fraction of null small lymphocytes in bone marrow was depleted by HU treatment only after an initial delay. NK1.1 was also expressed on subsets of Thy1lo cells and Thy1hi cells. The results have revealed the continuous production in mouse bone marrow of null and Thy1lo small lymphocytes, totaling 1-3 x 10(7) cells/day and 1.2 x 10(6) cells/day, respectively. The findings suggest that the large-scale production of null lymphocytes in mouse bone marrow includes the genesis of NK lineage cells which express NK1.1 and Thy1lo during a period of terminal maturation.     

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.     

Maturation of bone marrow lymphocytes. III. Genesis of Fc receptor-bearing "null" cells and B lymphocytes subtypes defined by concomitant expression of surface IgM, Fc, and complement receptors.

Lymphocyte subtypes in mouse bone marrow have been analyzed according to the combination of three surface membrane markers, IgM molecules, Fc, and complement receptors (FcR, CR), expressed simultaneously on individual cells. Marrow cell suspensions were depleted of IgM-, FcR-, and CR-bearing cells, respectively, by differential centrifugation after rosetting with appropriately sensitized erythrocytes. After rerosetting, the FcR-depleted marrow fraction showed many IgM + ve but no CR + ve small lymphocytes, the CR-depleted fraction contained both IgM + ve and FcR + ve small lymphocytes, while the IgM-depleted fraction showed many FcR + ve but few CR + ve small lymphocytes. Radioautography after [³H]thymidine labeling for 1 and 4 days in vivo demonstrated an active turnover of the various lymphocyte subtypes, particularly rapid for (IgM ? ve, FcR + ve) cells. The results demonstrate the presence of three subtypes of marrow small lymphocytes which correspond with three proposed stages in the maturation of newly formed primary B lymphocytes; (a) null cells (IgM ? ve, FcR ? ve, CR ? ve), (b) IgM + ve, FcR ? ve, CR ? ve, and (c) IgM + ve, FcR + ve, CR + ve. In addition, the turnover of a sizeable population of null small lymphocytes which bear FcR, without IgM and CR, suggests the genesis of a distinct marrow lymphocyte lineage, not previously described.     

B lymphocyte differentiation in lethally irradiated and reconstituted mice. I. The effect of Strontium-89 induced bone marrow aplasia on the recovery of the B cell compartment in the spleen.

The influence of ⁸⁹Sr-treatment on the recovery of the B cell compartment in lethally irradiated, fetal liver reconstituted mice was studied by means of membrane fluorescence. ⁸⁹Sr is a bone-seeking radio-isotope which causes in a dose of 3 μCi ⁸⁹Sr/g body weight a depletion of all nucleated cells, including immunoglobulin-bearing (B) cells, of the bone marrow.Treatment of irradiated and fetal liver reconstituted mice with 3 μCi ⁸⁹Sr/g body weight immediately and at 17 days after irradiation and reconstitution prevented recovery of the nucleated cell population, including B cells, in the bone marrow. In the spleen of such mice both nucleated cells and B cells reappeared at day 7 and 14 respectively. The B cell population in the spleen did not recover up to normal values during the experimental period of 45 days. It is concluded that B cell differentiation in lethally irradiated, fetal liver reconstituted mice can take place outside the bone marrow. The efficiency of this extra-medullary differentiation is discussed. The conclusion was drawn that mice with a ⁸⁹Sr-induced bone marrow aplasia are able to generate B lymphocytes. Consequently the bone marrow microenvironment seems not to be obligate to the differentiation of B lymphocytes. The peripheral lymphoid organs of such mice were found to be unable to compensate completely for the absence of B lymphocyte production in the bone marrow.     

Regulation of lymphocyte production in the bone marrow. I. Turnover of small lymphocytes in mice depleted of B lymphocytes by treatment with anti-IgM antibodies

To examine the concept that the genesis of lymphocytes in the bone marrow may be regulated by homeostatic feedback signals from peripheral B lymphocytes or their products, lymphocyte production was measured in mice selectively depleted of B lymphocytes by repeated administration of anti-IgM antibodies from birth. The turnover of small lymphocytes was quantitated radioautographically after DNA labeling by continuous infusion of 3H-thymidine. In the femoral marrow of anti-IgM-treated mice, the number of small lymphocytes was reduced and their turnover time was shorter than in control mice, presumably reflecting the premature elimination from the marrow of maturing cells about to express surface IgM. The absolute number of small lymphocytes being produced per femur in unit time, however, was identical in anti-IgM-treated and control mice. Lymphocyte production in the thymus was also unaffected by anti-IgM suppression whereas in the spleen the turnover of small lymphocytes was reduced due to the lack of young immigrant B lymphocytes from the bone marrow. The results demonstrate that the normal large-scale production of lymphocytes in mouse bone marrow is independent of the magnitude of the peripheral pool of B lymphocytes or the level of circulating immunoglobulins, suggesting the process is not subject to feedback control. Some implications for the genesis and diversity of primary B lymphocytes are discussed.     

Regulation of bone marrow lymphocyte production: IV. Cells mediating the stimulation of marrow lymphocyte production by sheep red blood cells: Studies in anti-IgM-suppressed mice,athymic mice,and silica-treated mice

Some cellular requirements have been examined for the stimulation of lymphocyte production in mouse bone marrow by injected sheep red blood cells (SRBC). The increased genesis of marrow lymphocytes after a single dose of SRBC assayed radioautographically after [³H]thymidine labeling was unimpaired in the marrow of mice treated with anti-IgM antibodies from birth to eliminate B lymphocytes, and in congenitally athymic mice lacking T lymphocytes. However, pretreatment of mice with silica to depress macrophage function completely abolished the SRBC effect both on the total lymphocyte production and on the number of B and null small lymphocytes in the marrow. Comparative studies were performed on the thymus and spleen. The results demonstrate that the stimulation of marrow lymphocyte production by SRBC is mediated by a silica-sensitive mechanism, does not require B or T lymphocytes, and is independent of the humoral immune response. Thus, extrinsic agents may amplify the production of primary B cells and other lymphocytes in the bone marrow by an antigen-nonspecific mechanism, putatively mediated by macrophages.     

STEM CELL KINETICS IN THE L 5222 RAT LEUKAEMIA

The behaviour of normal haemopoietic stem cells of the bone marrow during the development of the acute transferable rat leukaemia, L 5222, has been investigated. The granulopoietic committed stem cells, measured by the in vitro colony technique, showed a marked decrease to less than half normal levels. Pluripotent stem cells included in the small lymphocytes of the bone marrow, and labelled with ³H-thymidine by the complete labelling method, showed only a modest decrease in number and an unchanged labelling intensity. The results suggest that in this leukaemia the pluripotent stem cells may be affected in such a way that they are unable to react by proliferation to the depletion of the succeeding cell compartments. This might be due to inhibition by leukaemic cells or to a disturbed feedback regulation between the committed and pluripotent stem cell compartments.     

Modulation of lymphocyte functions by group A streptococcal membrane

Protoplast membranes isolated from group A streptococci suppress functions of mouse B cells in vivo and in vitro. Intraperitoneal injection 24 or 72 hr (but not 12 hr) before collection of lymphoid cells results in a selective decrease in the mitogenic response of bone marrow cells to dextran sulfate (DS). The response of bone marrow cells to lipopolysaccharide (LPS), and spleen cells to both DS and LPS, is unaltered. In vitro exposure of lymphocytes to membranes concomitantly with mitogen reduces the response to both DS and LPS, however, the DS response is more susceptible to low doses of membrane. Suppression of the response to DS in vitro is not mediated by cells bearing Thy 1.2 antigen. Neither the phytohemagglutinin (PHA)-responsive cells nor the adherent cells participate in suppression of the LPS response in vitro. In contrast to the suppression of B-cell functions neither the PHA nor concanavalin A (Con A) response of mouse bone marrow, spleen, or thymus cells is altered by streptococcal protoplast membranes injected 24 hr before collection of cells. In vitro exposure of spleen cells to a limited range of concentrations of membrane results in an enhanced proliferative response of spleen cells stimulated by suboptimal doses of PHA. This synergism is not mediated by the adherent cells. Addition of membranes to spleen cell cultures in vitro has no effect upon the response of spleen cells to suboptimal doses of Con A or to optimal doses of either Con A or PHA. Higher concentrations of membranes reduce the proliferative response of both control and mitogen-stimulated cells. This nonselective suppression by high doses of membranes is not due to toxicity. Delayed hypersensitivity to sheep erythrocytes is potentiated by injection of membranes. These studies suggest that streptococcal membranes preferentially suppress the immature B cells and enhance certain T-cell functions.     

Stimulation of uptake of tritiated thymidine into mouse marrow cells in culture by a factor from L-cell conditioned medium

Uptake of ³H-thymidine into suspension cultures of mouse marrow cells was stimulated by the addition of serum-free conditioned medium harvested from cultures of mouse L-cells. Characterization of the “conditioning factor activity” (CFA) by gel filtration, ion exchange chromatography, velocity sedimentation, polyacrylamide gel electrophoresis and susceptibility to trypsin digestion indicated that the CFA detected by stimulation of ³H-thymidine uptake is the same as the CFA detected previously by its ability to stimulate colony formation by marrow cells in vitro. The ³H-thymidine uptake assay was used to investigate the kinetics of disappearance of CFA as a function of time in the presence of mouse marrow cells. The CFA recoverable from the cultures decreased rapidly during the first day, and approached background levels by the fifth day. There was no evidence of inhibitory substances in the depleted media. Even if the cultures continued to receive fresh conditioned medium at daily intervals, ³H-thymidine uptake decreased sharply after the fifth day, indicating that the marrow cells had lost their capacity to respond to CFA.     

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.     

DIURNAL VARIATION IN THE LABELING INDEX OF MOUSE EPIDERMIS: A DOUBLE ISOTOPE AUTORADIOGRAPHIC DEMONSTRATION OF CHANGING FLOW RATES

A diurnal rhythmicity in the labeling index was observed in the epidermis of hairless mice, injected with either ¹⁴C- or ³H-thymidine, at different times during a 24 hr period. A modified autoradiographic technique, using ¹⁴C- and ³H-thymidine and two overlying emulsion layers, makes it possible to clearly differentiate synthesizing cells which are singly labeled with either carbon-14 or tritium, and cells labeled with both isotopes. At various times during a 24 hr period, hairless mice were injected with thymidine-2-¹⁴C and colcemid, followed at 2 or 3 hr by a second injection of ³H-thymidine. The labeling indices were calculated for the ¹⁴C- and ³H-thymidine injection times. These labeling indices were consistent with the control, single isotope, labeling indices and exhibited the same diurnal rhythm. Cells singly labeled with ³H- or ¹⁴C-thymidine have either started or completed DNA synthesis during the interval between the two injections. Flow rates into and out of DNA synthesis, throughout the 24 hr period, can be calculated from these singly labeled cells. The flow rates varied rhythmically throughout the day and paralleled changes in the labeling indices. The influx and efflux flow rates, at all times measured, were not equal. The influx flow rate was reflected in the efflux rate at a time later equal to the duration of S. By means of these flow rates, the per cent of cells in DNA synthesis was calculated for each hour during a 24 hr period. The resulting labeling index curve matches the observed 24 hr diurnal rhythm in labeling indices. By extension of these flow rates through mitosis, the resulting mitotic index curve is comparable to the reported 24 hr diurnal rhythm in mitotic indices.     

MIGRATION OF SMALL LYMPHOCYTES IN ADULT MICE DEMONSTRATED BY PARABIOSIS

Parabiotic BALB/C mice were used to study the traffic of small lymphocytes in immunological mature but unchallenged mice. By giving ³H-thymidine (³H-TdR) injections to only one member (A) of a pair by preventing the escape of the radioactive isotope to the other member (B), the kinetics of newly-formed cells was followed. Less than 10% labelled small lymphocytes were found in the peripheral lymphoid tissues of both A and B members, while the thymusses and bone marrows of A members showed labelling percentages up to 70% in this period. Hardly any labelled cells gained entrance into the thymus while a detectable number was found in the bone marrows of B members. Results from pairs set up to follow migration of long-lived lymphocytes revealed that labelled cells detected 4–5 weeks after injections were equilibrated between the peripheral tissues and the bone marrows of the partners. Very few labelled cells were seen in the thymic medulla and none were observed in the thymic cortex, germinal centres or medullary cords of lymph nodes from any B member. It was concluded that short-lived small lymphocytes are formed primarily in the thymus and bone marrow and the migration of these cells is limited in adult animals. Furthermore, the vast majority of long-lived small lymphocytes are freely recirculating, and these cells gain entrance to and are normal residents in the bone marrow.     

Fv-2 locus controls the proportion of erythropoietic progenitor cells (BFU-E) synthesizing DNA in normal mice

We have found that Fv-2 on chromosome 9 of the mouse, the locus originally identified as a major determinant of host susceptibility (Fv-2^s) or resistance (Fv-2^r) to Friend leukemia virus in mice, also functions in uninfected animals, where it determines whether a high (Fv-2^s) or low (Fv-2^r) proportion of erythropoietic progenitor cells BFU-E are normally engaged in DNA synthesis. Adult mice belonging to five inbred strains of genotype Fv-2^rr, two inbred strains and three congenic strains of genotype Fv-2^ss, two kinds of F1 hybrid of genotype Fv-2^rs, and appropriate controls were given high specific activity ³H-thymidine intravenously for 1 hr and their bone marrow and spleen cells were assayed for surviving BFU-E at 7 days and CFU-E at 2 days in plasma culture. A high proportion of BFU-E in all Fv-2^ss and Fv-2^rs mice were killed, but all or nearly all of the BFU-E in Fv-2^rr mice survived exposure to ³H-thymidine. The allelic difference at Fv-2 had no significant effect on the proportion of other progenitor or stem cells (CFU-E, CFU-C or CFU-S) normally undergoing DNA synthesis in the hemopoietic tissues, or on the hemoglobin concentration, red blood cells, hematocrit, total or differential white blood cell counts in the peripheral blood of these animals. While a few or no BFU-E were killed by ³H-thymidine in adult B6 (Fv-2^rr) mice, a high proportion of BFU-E were killed by ³H-thymidine in these animals when they were less than 7 weeks old. Bleeding of adult B6 mice or lethal irradiation followed by repopulation by syngeneic bone marrow cells rendered a high proportion of their BFU-E vulnerable to ³H-thymidine. BFU-E of adult B6 mice which in vivo were unaffected by ³H-thymidine were rapidly killed when exposed to ³H-thymidine in vitro. Fv-2 thus seems to act at or near the G₁-S or G₀-S boundary to influence the rate or probability of transition between the nonDNA-synthesizing and the DNA-synthesizing states of BFUE. The gene that controls susceptibility or resistance to a murine erythroleukemia virus appears also to be a regulatory gene that controls the proliferative behaviour of normal cells at a specific stage of erythropoietic differentiation.     

Splenic lymphocytopoiesis and migration pattern of splenic lymphocytes

The spleens of young pigs were selectively labeled with tritiated thymidine ([³H]-TdR) and the relative and absolute numbers of labeled lymphocytes found 24 hr later in different lymphoid and nonlymphoid organs were determined autoradiographically. It was deduced that about 4.6 × 10⁹ lymphocytes (that is, about 15% of all splenic lymphocytes) are produced by the spleen per day and about 17% of the newly formed lymphocytes leave the spleen within the first day of labeling. Spleen-derived lymphocytes could be found in relatively high numbers in the lymph nodes, blood, gut-associated lymphoid tissues, and, surprisingly, in the bone marrow, whereas the concentration in the thymus was very low. In a second series, pigs were labeled with [³H]TdR and only the spleen was excluded from labeling. The labeling index of splenic small lymphocytes was about 10% 1 day later, indicating a high rate of influx of newly formed lymphocytes into the pig spleen. The spleen of the young pig is an important lymphocytopoietic organ and exports and imports newly formed lymphocytes at high rates.     

Megalodiscus temperatus: absorption and incorporation of tritiated tyrosine, thymidine, and adenosine

Autoradiographic and liquid scintillation counting studies indicate adults of Megalodiscus temperatus can absorb large amounts of thymidine and adenosine, but use little of the thymidine in in vitro exposures of up to 72 hr. Labeling of worms exposed to ³H-adenosine in periods as short as 3 hr was achieved especially over young eggs, testes, and the ovary. Large amounts of tyrosine are found in the free amino acid pool of this worm but little is incorporated into tissues for exposure periods of up to 24 hr. Ligation experiments and autoradiograms of frozen-dried worms show thymidine and adenosine can enter via the tegument. Adenosine added to the exposure medium did not inhibit absorption of tyrosine but did markedly reduce the uptake of ³H-thymidine in 8-hr in vitro exposures. Bacteria adhering to the glycocalyx of M. temperatus were identified as Escherichia coli, but their role in uptake phenomena is unknown. The association of thymidine with the lymph vessels indicates a circulatory or excretory role for this system in M. temperatus. Adenosine was considered the best compound of the three to use for labeling cells for studies on the reproductive system.     

Studies on follicular growth in the immature rat and hamster: Effect of a single injection of gonadotropin or estrogen on the rate of3H-thymidine incorporation into ovarian DNAin vitro

Initiation of follicular growth by specific hormonal stimuli in ovaries of immature rats and hamsters was studied by determining the rate of incorporation of³H-thymidine into ovarian DNAin vitro. Incorporation was considered as an index of DNA synthesis and cell multiplication. A single injection of pregnant mare serum gonadotropin could thus maximally stimulate by 18 hr³H-thymidine incorporation into DNA of the ovary of immature hamsters. Neutralization of pregnant mare serum gonadotropin by an antiserum to ovine follicle stimulating hormone only during the initial 8–10 hr and not later could inhibit the increase in³H-thymidine incorporationin vitro observed at 18 hr, suggesting that the continued presence of gonadotropin stimulus was not necessary for this response. The other indices of follicular growth monitored such as ovarian weight, serum estradiol and uterine weight showed discernible increase at periods only after the above initial event. A single injection of estrogen (diethyl stilbesterol or estradiol-l7β) could similarly cause 18 hr later, a stimulation in the rate of incorporation of³H-thymidine into DNAin vitro in ovaries of immature rats. The presence of endogenous gonadotropins, however, was obligatory for observing this response to estrogen. Evidence in support of the above was two-fold: (i) administration of antiserum to follicle stimulating hormone or luteinizing hormone along with estrogen completely inhibited the increase in³H-thymidine incorporation into ovarian DNAin vitro; (ii) a radioimmunological measurement revealed following estrogen treatment, the presence of a higher concentration of endogenous follicle stimulating hormone in the ovary. Finally, administration of varying doses of ovine follicle stimulating hormone along with a constant dose of estrogen to immature rats produced a dose-dependent increment in the incorporation of³H-thymidine into ovarian DNAin vitro. These observations suggested the potentiality of this system for developing a sensitive bioassay for follicle stimulating hormone.