KINETIC PROPERTIES OF HAEMOPOIETIC STEM CELLS

A comparison of the exocolonizing and autorepopulating tests for haemopoietic stem-cell assay indicate that the ‘overshoot’in splenic colony formation, observed 12–14 days after 150 rad total-body radiation (TBR), only occurs with the auto-repopulation assay. The explanation is that the priming dose of 150 rad increases the absolute seeding rate of stem cells from the marrow. A seeding rate significantly greater than normal can ‘take’only if the spleen is available—it can expand and accommodate stem cells while the bone marrow cannot. If, however, the absolute number of colony-forming cells are decreased in the femur, a relative increase in seeding rate can take place even in the splenectomized animal. Evidence is presented concerning the different turnover states of exo- and autorepopulating stem cells (CFU) and those responsible for erythropoietic response (ERC), and the precursors of agar colony-formers.     

ADAPTATION OF HEMOPOIETIC TISSUE RESULTING FROM ESTRONE-INDUCED OSTEOSCLEROSIS IN MICE

The redistribution of hemopoietic tissue resulting from estrone-induced osteosclerosis in the mouse was studied. As the marrow was gradually replaced by bone, extramedullary hematopoiesis in the spleen increased at a rate sufficient to maintain hemopoietic homeostasis. The total numbers of colony forming units (CFU) in the tibia and spleen as well as the proportion of CFU in cycle was assessed. After five injections of estrone, tibial CFUs decreased to 2% of control values whereas splenic CFUs increased approximately nine-fold. The proliferative capacity of the splenic CFU was also increased in the estrone-treated animals. The increased numbers of splenic CFUs as well as the increased proliferative capacity of this compartment are probably related to the ability of extramedullary hematopoiesis in the spleen to compensate for a marrow that has been replaced by bone.     

THE INFLUENCE OF GENETIC RESISTANCE ON CFU GROWTH KINETICS IN SPLEEN AND FEMUR

An impaired colony formation of C57BL marrow cells transplanted into F_t (C57BL x CBA) mice was observed. In accordance with the literature this phenomenon has been designated as ‘genetic resistance’. Studies to elucidate the mechanism of the genetic resistance demonstrated that the multiplication phase of the CFU growth curve started in the semi-isogeneic combination about 48 hr later than in the isogeneic combination. In the spleen this resulted in a lower ‘dip’. For the spleen as well as for the femur similar CFU doubling times were found during the multiplication phase when both transplantation combinations were compared. Furthermore the percentage of CFU in S-phase (assessed with the ³H-TdR suicide technique) during the first days after transplantation were similar in both combinations. When the spleen was removed 5–6 months before irradiation and bone marrow transplantation was performed the growth curve of parental CFU in the femur was identical with the growth curve of isogeneic CFU (no delay was observed). These results are discussed and a few theories explaining the observations are proposed.     

Radiation sensitivity of hemopoietic stroma: long-term partial recovery of hemopoietic stromal damage in mice treated during growth

We studied the ability of the hemopoietic organ stroma to recover from damage inflicted by 5 or 7 Gy gamma radiation administered during a period of stromal growth in 4-week-old mice. Irradiation resulted in an immediate depletion of femoral colony-forming fibroblastic progenitors (CFU-F) down to 10-20% of age-matched control values. A full recovery to normal numbers occurred between 120 and 240 days after irradiation and was followed by a secondary decrease 1 year after irradiation. This secondary decrease was accompanied by a decrease in the femoral CFU-S and CFU-C content. Femoral CFU-F attained normal numbers and it was demonstrated to occur from surviving CFU-F and could not be enhanced or prolonged following infusion of unirradiated bone marrow cells after irradiation. During the transient CFU-F recovery the hemopoietic stroma remained severely damaged as judged by the regenerative capacity of spleen and femur stroma after subcutaneous implantation, and the ability of the spleen to accumulate CFU-S in response to lipopolysaccharide injection. We have reported earlier that in similarly irradiated adult mice, no restoration of femoral CFU-F was observed. This difference between 4-week-old and adult mice could not be explained by a difference in in vitro radiosensitivity of CFU-F or in their in vivo regeneration kinetics following irradiation and subsequent lipopolysaccharide injection. We conclude from these observations that the recovery kinetics of the CFU-F population is different in young and adult irradiated mice, infused CFU-F do not contribute to CFU-F regeneration in an irradiated femur, CFU-F are not the sole determinants of stromal regeneration in femur and spleen following irradiation.     

A COMPARATIVE STUDY OF THE REPOPULATING POTENTIAL OF GRAFTS FROM VARIOUS HAEMOPOIETIC SOURCES: CFU REPOPULATION

The growth rate of the CFU populations in spleens and femora has been studied in irradiated mice injected with cell suspensions, containing equivalent number of CFU, from various sources. The doubling times are shown to be dependent upon the source of the cells. Grafts of bone marrow, spleen and foetal liver cells produced doubling times in the spleen of approximately 25, 19 and 16 hr respectively. Grafts of marrow-derived and spleen-derived spleen colony cells both gave rise to CFU doubling times lower than those of the corresponding primary grafts (approx. 33 and 26 hr respectively in the spleen). In the case of both bone marrow and spleen grafts the CFU population growth was shown to be independent of the size of the graft. A hypothesis is advanced which invokes at least a dual population of CFU, having different doubling times, different seeding capacities in the haemopoietic tissues following i.v. injection and present in different proportions in the various haemopoietic tissues.     

Cloning stem cells in the bone marrow of irradiated mice]

Different amount of intact or irradiated bone marrow from syngenous donors was administered to mice irradiated with a lethal dose. There was revealed a linear dependence of the number of the 8-9-day colonies grown in the bone marrow of the femur on the amount of the administered cells, and an exponential dependence on the irradiation dose. Regularity of the stem cell cloning in the bone marrow was analogous to such in the spleen. Radiosensitivity of the colony-forming units (CFU) differed depending on the site (the spleen, the bone marrow) of their colony formation. The CFU settling in the marrow proved to be more radioresistant (D(0) equalled 160-200 P) in comparison with the CFU settling in the spleen (D(0) constituted 80-100 P). It is supposed that a different radiosensitivity of the CFU was caused by the presence of heterogenic population of the stem cells and also by specific peculiarities of the organ (the spleen, the bone marrow) in which the colonies formed.     

EFFECTS OF PRE-IRRADIATION ON ISOGENEIC AND SEMI-ISOGENEIC CFU GROWTH: A STUDY ON GENETIC RESISTANCE

The genetic resistance to a parental bone marrow transplant as demonstrated, when transplantation was performed early after irradiation, failed to occur if the interval between irradiation and transplantation was increased to 4 days. A similar radiation induced weakening of genetic resistance to a parental bone marrow graft in spleen and bone marrow could be demonstrated in mice, which had been irradiated with a sublethal dose at 7 days prior to the lethal irradiation and transplantation. The pre-irradiation of the recipient with a sublethal dose induced an enhancement of the growth in spleen and bone marrow of isogeneic transplanted CFU. The pre-irradiation of a single tibia also resulted in a significant weakening of the resistance in the spleen. The experiments with partial body pre-irradiation suggested a local effect of the pre-irradiation, but it could be shown that the enhanced CFU growth is not caused by an enhanced seeding of CFU in pre-irradiated bone marrow. The role of microenvironment in the phenomenon of genetic resistance is discussed.     

MULTIPLICATION OF HAEMOPOIETIC COLONY FORMING UNITS (CFU) IN MICE AFTER X-IRRADIATION AND BONE MARROW TRANSPLANTATION

Kinetics of the multiplication of haemopoietic CFUs was studied in lethally irradiated mice receiving various numbers of syngeneic bone marrow cells. After transplantation of a small number of bone marrow cells, the growth rate of CFU in femoral bone marrow appeared to decrease after about 10 days after transplantation, before the normal level of CFU in the femur was attained. In the spleen it was found that the overshoot which was observed about 10 days after transplantation of a large number of bone marrow cells is smaller or absent when a small number of cells is transplanted. Experiments dealing with transplantation of 50 x 10⁶ bone marrow cells 0, 4 or 10 days after a lethal irradiation indicated that the decline in growth rate of CFUs about 10 days after irradiation could not be attributed to environmental changes in the host.
The results are explained by the hypothesis that a previous excessive proliferation of CFUs diminishes the growth rate thereafter. This hypothesis is supported by experiments in which 50 x 10⁶ bone marrow cells derived from normal mice or from syngeneic chimaeras were transplanted. The slowest growth rate was observed when bone marrow that had been subjected to the most excessive proliferation in the weeks preceding the experiment was transplanted.     

THE RELATIONSHIP BETWEEN SPLEEN COLONY PRODUCTION AND SPLEEN CELLULARITY

The fraction, f, of injected spleen colony-forming cells which can be recovered from the spleen of a radiated mouse has been determined at various times up to 24 hr following the initial cell injection. the cellularity of the spleen at the time of assay was also measured and compared with the calculated f number. the linear relationship between these two parameters indicated that over the period of 2-24 hr the number of CFU/10⁶ spleen cells was constant, both falling in a parallel fashion. A further experiment using non-irradiated W/W^v mice in which the spleen size did not change showed the same f number at the end of this period as at 2 hr. It is concluded that CFU are expelled from the spleen during its post-irradiation contraction thus leading to the apparent fall in f number. It is also concluded that a more realistic f number is obtained by assaying the splenic CFU content 24 hr after the primary cell transfer rather than 2 hr.     

REGULATION OF HAEMOPOIETIC STEM CELL TURNOVER IN PARTIALLY IRRADIATED MICE

The existence of a possible local control of CFU turnover was studied in mice in which one tibia only was irradiated (LR mice) and in mice in which one tibia was shielded during whole-body irradiation ('TBR'mice). In both the LR and 'TBR'mice, the increased CFU turnover continued in the irradiated tibiae even after the time when in the unirradiated (shielded) tibiae it returned to normal levels. The early temporary decrease in the CFU numbers in the shielded tibiae of 'TBR'mice is attributed to a temporary demand for increased differentiation rather than to migration of CFU. The direct control of CFU turnover appears to be local in nature, in contrast to the stimulus for CFU differentiation.     

THE PROLIFERATIVE CAPACITY OF HAEMOPOIETIC COLONY FORMING UNITS IN THE RAT

After transplantation into rats lethally treated with cytotoxic chemicals both bone marrow and spleen CFU in the spleen and spleen derived CFU in the bone marrow expand with doubling times ( T _d) of approximately 18 hr. However, bone marrow derived CFU in the bone marrow have a T _d of 36 hr. Evidence obtained using tritiated thymidine in vitro and methotrexate in vivo show that the proliferation rate of bone marrow derived CFU is similar in both the bone marrow and spleen and calculations suggest that the different T _d between these two sites is due to the higher loss of CFU through differentiation in the bone marrow compared to the spleen. These findings further support the hypothesis of an environment in the spleen which favours CFU self-maintenance over differentiation with the opposite situation occurring in the bone marrow.     

Chemical radioprotection of hemopoietic colony-forming cells: comparative effect of AET, anoxia, and urethan

The bone marrow colony-forming unit (CFU) technique of Till and McCulloch was employed to test the radioprotective effect of AET, anoxia, urethan on marrow cells irradiated in vivo. For AET and anoxia, a dose-reduction factor of 1.9 to 2.1 was found. Since the marrow cells were assayed for CFU content immediately after irradiation of the donor, the observed effect can be interpreted as a "true" radiation dose reduction. By contrast, urethan injection did not increase the survival of marrow CFU assayed immediately after whole-body x-irradiation. However, both urethan and AET afforded radioprotection of endogenous CFU content of spleen and bone marrow, but not of endogenous spleen colony count. It is concluded that the mechanism of radioprotection by urethan is fundamentally different from that of AET or anoxia.     

THE f NUMBER OF PRIMARY TRANSPLANTED SPLENIC COLONY-FORMING CELLS

The proportion of murine haemopoietic stem cells that settled in the spleen, after transplanting spleen cells into lethally-irradiated recipient mice, was found by comparing the number of spleen colonies obtained by transplanting a whole spleen with an estimate of the total number of colony-forming units (CFU) present in the intact spleen. the latter number was estimated assuming that endogenous spleen colonies were produced from surviving spleen-derived CFU which exhibited the same survival parameters as transplanted CFU.
Account was taken of the post-irradiation loss of CFU from the spleen in the endogenous assay, which was found to be a reasonably constant factor for doses higher than about 100 rad X-rays.
The total measured number of CFU/spleen from transplantation was less than the number calculated in the intact spleen by a factor, the primary f number, of 0.03 ± 0.02.     

Green tea polyphenols mitigate bone loss of female rats in a chronic inflammation-induced bone loss model

The purpose of this study was to explore the bioavailability, efficacy and molecular mechanisms of green tea polyphenols (GTP) related to preventing bone loss in rats with chronic inflammation. A 2 [placebo vs. lipopolysaccharide (LPS)]×2 (no GTP vs. 0.5% GTP in drinking water) factorial design enabled the evaluation of effects of LPS administration, GTP levels, and LPS×GTP interaction. Urinary GTP components and 8-hydroxy-2′-deoxyguanosine (8-OHdG) levels were determined by high-pressure liquid chromatography for bioavailability and molecular mechanism, respectively. Efficacy was evaluated by examining changes in femoral mineral content (BMC) and density (BMD) using dual-energy X-ray absorptiometry, and bone turnover biomarkers [osteocalcin (OC) and tartrate-resistant acid phosphatase (TRAP)] using respective ELISA kits. The mRNA expression of tumor necrosis factor-α (TNF-α) and cyclooxygenase-2 (COX-2) in spleen was determined by real-time RT-PCR. Neither LPS administration nor GTP levels affected body weight and femoral bone area throughout the study period. Only GTP supplementation resulted in increased urinary epigallocatechin and epicatechin concentrations. LPS administration led to a decrease in femur BMC and BMD, and serum OC levels, but an increase in serum TRAP, urinary 8-OHdG and spleen mRNA expression of TNF-α and COX-2 levels. GTP supplementation resulted in higher values for femur BMC, BMD and serum OC, but lower values for serum TRAP, urinary 8-OHdG and spleen mRNA expression of TNF-α and COX-2 levels. We conclude that GTP mitigates bone loss in a chronic inflammation-induced bone loss model by reducing oxidative stress-induced damage and inflammation.     

Increased intracortical bone remodeling during lactation in beagle dogs

There are substantial changes in skeletal and mineral metabolism during pregnancy and lactation. The purpose of this study was to determine the changes in intracortical bone remodeling and turnover during lactation in beagle dogs. A femur and rib were obtained from dogs near the end of lactation or soon after weaning and compared with nonlactating controls. Rib cortical bone had much higher bone turnover rates than did femoral diaphyseal cortical bone. The number of single-labeled osteons and the number of resorption spaces were significantly greater during lactation in both the rib and the femur. Additionally, the mineral apposition rate, basic multicellular unit activation frequency, and bone turnover rates were greater in the femoral cortical bone from the lactating dogs than from the controls. These data demonstrate that during lactation, intracortical bone remodeling increases, and this may provide a mechanism for the skeleton to be responsive to the calcium requirements of the mother. In addition, these data may help explain the transient decreases in cortical bone mineral density that are reported to occur during human lactation.     

STUDY OF CELL DEATH IN FRIEND LEUKAEMIA

Cell death of splenic Friend leukaemic cells has been studied in vivo, using ¹²⁵I-UdR and ³H-TdR pulse labelling. The evolution of the splenic specific activity has been measured by autoradiography and external counting during 40 hr after injection of the labelled precursor. These two techniques show the existence of a large reutilization of ³H-TdR (50%), which is measurable as soon as 7 hr after the injection. The DNA turnover rate is rapid, 83-8 % of the splenic cellular DNA being renewed per day. These results confirm that most of the cells produced in the Friend leukaemic spleen are rapidly lost; they also demonstrate that this cell loss is mainly due to a massive death, which occurs in proerythroblastic and erythroblastic compartments after one or two cell divisions. Friend leukaemic cells, which are characterized by a limited capacity of proliferation and a short lifespan, do not appear to be malignant.     

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.     

THE ROLE OF THE SPLEEN IN THE REPOPULATION OF THE HAEMOPOIETIC SYSTEM OF HEAVILY-IRRADIATED MICE

The respective role of the spleen or of the bone marrow in the regeneration of the haemopoietic progenitor compartment of heavily-irradiated mice has been investigated. Splenectomy was used to this end in animals injected with exogenous isogenic cells or regenerating from endogenous spleen or marrow cells. Analysis of the data as a function of time shows that the presence of the spleen affects marrow CFU repopulation only at the early post-irradiation stages. The expansion of the marrow progenitor pool proceeds, however, rather independently of the spleen and marrow CFU remain eventually as the main source of haemopoietic cells in the surviving mice. Thus the reaction of the spleen may be envisaged as a fast, important but transient contribution to the overall haemopoietic function of heavily-irradiated animals.     

THE COMPARATIVE EFFECT OF BUSULPHAN ('MYLERAN') AND AMINOCHLORAMBUCIL ON HAEMOPOIETIC COLONY FORMING UNITS IN THE RAT

Using the spleen colony assay technique, it has been shown that busulphan (‘Myleran’) in a dose of 10^-2 g/kg (1/2 LD₅₀), causes a marked and prolonged depression (over 90%) in the number of colony forming units per femur (CFU/femur). This depression is apparent before there is any marked reduction of the total cell count per femur and is maximal 2–4 days after an intraperitoneal (i.p.) injection of the drug. It is then followed by a steady recovery, normal values being reached after about 20 days. In contrast, aminochlorambucil (2·5 x 10^-3) g/kg = 1/2 LD⁵⁰) although producing a rapid fall in the marrow cellularity has no discernable effect on the CFU/femur. If, however, a depression of CFUs is first induced by busulphan and, after allowing time for 50% recovery (13 days), aminochlorambucil is now given, a further severe depression of the CFUs/femur occurs resulting in a considerable prolongation of the neutropenia observed in the blood. The possible implications of this in the mode of action of these two drugs, and in the chemotherapy of leukaemia, are discussed.     

Further studies on the biological properties of Friend virus-induced leukemic cells differentiating along the erythrocytic pathway

When Friend virus-induced leukemic cell lines were injected into irradiated hosts after the second radiation dose, the colony-forming unit (CFU) in the recipient spleens per 10⁴ cells was found to be 7-fold higher than the CFU obtained when the second radiation dose had been given shortly after the inoculation of the cells. Serial passage of the cells from the spleen colonies to irradiated hosts resulted in a marked increase of the CFU value, indicating that this cell population was capable of both self-replication and erythroid differentiation. The “f” fraction, which indicates the percentage of the inoculated cells that reach the spleen in the irradiated recipients, was found to be approximately 15%. If the highest CFU value obtained from serial colony-to-colony passages is corrected by this factor, a final cloning efficiency of about 18% is demonstrated. Neither induced plethora nor the administration of erythropoietin (1 u/mouse/for 2 days) appeared to affect the spleen colony-forming ability of the leukemic cells. Erythroid differentiation is not detectable in the transplantable subcutaneous tumors which were used to initiate the tissue culture lines and which also are capable of inducing erythroid spleen clones in irradiated recipients. This lends support to the theory of the influence of “microenvironmental factors” on the fate of stem cells with potential for differentiation.