Regulation of haemopoietic stem-cell proliferation in mice carrying the Slj allele

We investigated a haemopoietic stromal defect, in mice heterozygous for the Slj allele, during haemopoietic stress induced by treatment with bacterial lipopolysaccharides (LPS) or lethal total body irradiation (TBI) and bone-marrow cell (BMC) reconstitution. Both treatments resulted in a comparable haemopoietic stem cell (CFU-s) proliferation in Slj/+ and +/+ haemopoietic organs. There was no difference in committed haemopoietic progenitor cell (BFU-e and CFU-G/M) kinetics after TBI and +/+ bone-marrow transplantation in Slj/+ and +/+ mice. The Slj/+ mice were deficient in their ability to support macroscopic spleen colony formation (65% of +/+ controls) as measured at 7 and 10 days after BMC transplantation. However, the Slj/+ spleen colonies contained the same number of BFU-E and CFU-G/M as colonies from +/+ spleens, while their CFU-s content was increased. On day 10 post-transplantation, the macroscopic 'missing' colonies could be detected at the microscopic level. These small colonies contained far fewer CFU-s than the macroscopic detectable colonies. Analysis of CFU-s proliferation-inducing activities in control and post-LPS sera revealed that Slj/+ mice are normal in their ability to produce and to respond to humoral stem-cell regulators. We postulate that Slj/+ mice have a normal number of splenic stromal 'niches' for colony formation. However, 35% of these niches is defective in its proliferative support.     

Regulation of haemopoietic stem-cell proliferation in mice carrying the Slj allele

We investigated a haemopoietic stromal defect, in mice heterozygous for the Sl^j allele, during haemopoietic stress induced by treatment with bacterial lipopolysaccharides (LPS) or lethal total body irradiation (TBI) and bone-marrow cell (BMC) reconstitution. Both treatments resulted in a comparable haemopoietic stem cell (CFU-s) proliferation in Sl^j/+ and +/+ haemopoietic organs. There was no difference in committed haemopoietic progenitor cell (BFU-e and CFU-G/M) kinetics after TBI and +/+ bone-marrow transplantation in Sl^j/+ and +/+ mice. the Sl^j/+ mice were deficient in their ability to support macroscopic spleen colony formation (65% of +/+ controls) as measured at 7 and 10 days after BMC transplantation. However, the Sl^j/+ spleen colonies contained the same number of BFU-E and CFU-G/M as colonies from +/+ spleens, while their CFU-s content was increased. On day 10 post-transplantation, the macroscopic ‘missing’ colonies could be detected at the microscopic level. These small colonies contained far fewer CFU-s than the macroscopic detectable colonies. Analysis of CFU-s proliferation-inducing activities in control and post-LPS sera revealed that Sl^j/+ mice are normal in their ability to produce and to respond to humoral stem-cell regulators. We postulate that Sl^j/+ mice have a normal number of splenic stromal ‘niches’ for colony formation. However, 35% of these niches is defective in its proliferative support.     

Stem cell (CFU-s) proliferation in sublethally irradiated mice

Abstract. The proliferation rate of haemopoietic stem cells (CFU-s) was followed after sublethal total body irradiation with 1.5 Gy. The [³H]-thymidine suicide technique was used to measure the CFU-s proliferation rate. The measurements extended from 10 min after irradiation up to 21 days. The CFU-s did not enter the DNA synthesis period (S-phase) shortly after irradiation, as had been previously suggested, but did so only with a delay of 14–16 hr. A large scatter of results was explained by an oscillatory pattern in CFU-s proliferation. The CFU-s prepared for cell division in synchronized waves, with a period of 20–22 hr.     

Effect of haemopoietic stem-cell proliferation regulators on early and late spleen colony-forming cells

An inhibitor and stimulator of CFU-s proliferation can be obtained from haemopoietic tissue containing, respectively, relatively quiescent CFU-s (e.g. normal bone marrow) and proliferating CFU-s (e.g. regenerating bone marrow). Their effects on the proliferative behaviour of steady-state and regenerating marrow CFU-s, which produce colonies 7, 10 and 12 days post-transplantation have been investigated. The results demonstrate changing sensitivities of CFU-s to inhibitor and stimulator as they progress through a developmental age structure, 'Older' CFU-s (producing early spleen colonies) are more sensitive to stimulator, 'Younger' CFU-s (producing late spleen colonies) are more sensitive to inhibitor.     

Effect of Haemopoietic Stem-Cell Proliferation Regulators On Early and Late Spleen Colony-Forming Cells

An inhibitor and stimulator of CFU-s proliferation can be obtained from haemopoietic tissue containing, respectively, relatively quiescent CFU-s (e.g. normal bone marrow) and proliferating CFU-s (e.g. regenerating bone marrow). Their effects on the proliferative behaviour of steady-state and regenerating marrow CFU-s, which produce colonies 7, 10 and 12 days post-transplantation have been investigated. The results demonstrate changing sensitivities of CFU-s to inhibitor and stimulator as they progress through a developmental age structure. ‘Older’ CFU-s (producing early spleen colonies) are more sensitive to stimulator, ‘Younger’ CFU-s (producing late spleen colonies) are more sensitive to inhibitor.     

The Sensitivity of G0-State Haemopoietic Spleen Colony-Forming Cells to A Stimulus For Proliferation

Haemopoietic spleen colony-forming units (CFU-s) close to the axis (axial CFU-s) of the long bones have a high probability of self-renewal. They are pluripotent cells and are largely in a G_o-State. By contrast, CFU-s close to the bone surface (marginal CFU-s) have a lower probability of self-renewal and are probably more mature, though still pluripotent. Most CFU-s proliferation arises in this zone. As a consequence, marginal CFU-s tend to have shorter G_o histories than do axial CFU-s. Femoral marrow was, therefore, divided into axial and marginal populations and the sensitivity of the CFU-s to an endogenous CFU-s-specific proliferation-stimulating factor was assessed and compared by the tritiated thymidine suicide technique. It was found that axial CFU-s are considerably more resistant to stimulation than are marginal CFU-s in that larger doses for longer periods of exposure are required to increase the proliferative activity of the cells. This behaviour is consistent with the suggestion that cells with a low division probability exist in deeper levels of the quiescent G_o-state. Although this hypothesis was developed from the behaviour of cells maintained in culture under sub-optimal physiological conditions, this phenomenon appears, in vivo, to be a characteristic of the stem cell population of haemopoietic tissue; their high resistance to stimulation maintaining the axial CFU-s in a quiescent state.     

In vivo studies on the regeneration kinetics of enriched populations of haemopoietic spleen colony-forming cells from normal bone marrow

Functional properties of mouse haemopoietic spleen colony-forming cells, enriched 40- to 80-fold, from normal bone marrow were studied. It was found that: (1) the number of partially purified CFU-s (colony forming unit-spleen) required to rescue lethally irradiated mice was similar to the number of normal unfractionated bone marrow CFU-s giving the same level of protection; (2) the homing of partially purified CFU-s was similar to that of CFU-s from unfractionated bone marrow; (3) the regeneration of CFU-s in spleen was similar for enriched and unfractionated cell populations between 4 and 11 days after transplantation. In contrast, the rate of regeneration of CFU-s in femur was slower with enriched progenitor cells than with unfractionated bone marrow. The growth rate in femur, however, could be restored to normal by injecting freshly isolated syngeneic thymocytes with the enriched CFU-s population. The results indicate that the partially purified CFU-s are by themselves functionally normal and show that the rate of CFU-s repopulation in bone marrow can be affected by cell types other than spleen colony-forming cells.     

The sensitivity of G0-state haemopoietic spleen colony-forming cells to a stimulus for proliferation

Haemopoietic spleen colony-forming units (CFU-s) close to the axis (axial CFU-s) of the long bones have a high probability of self-renewal. They are pluripotent cells and are largely in a G0-State. By contrast, CFU-s close to the bone surface (marginal CFU-s) have a lower probability of self-renewal and are probably more mature, though still pluripotent. Most CFU-s proliferation arises in this zone. As a consequence, marginal CFU-s tend to have shorter G0 histories than do axial CFU-s. Femoral marrow was, therefore, divided into axial and marginal populations and the sensitivity of the CFU-s to an endogenous CFU-s-specific proliferation-stimulating factor was assessed and compared by the tritiated thymidine suicide technique. It was found that axial CFU-s are considerably more resistant to stimulation than are marginal CFU-s in that larger doses for longer periods of exposure are required to increase the proliferative activity of the cells. This behaviour is consistent with the suggestion that cells with a low division probability exist in deeper levels of the quiescent G0-state. Although this hypothesis was developed from the behaviour of cells maintained in culture under sub-optimal physiological conditions, this phenomenon appears, in vivo, to be a characteristic of the stem cell population of haemopoietic tissue; their high resistance to stimulation maintaining the axial CFU-s in a quiescent state.     

Possibility of an artefact in determining hematopoietic stem cell proliferation by CFUs suicide methods

Spleen colonies in the irradiated mice are produced by both stem cells and by their more differentiated progeny. In the latter case the colonies are transitory, ceasing 10-11 days after cell injection. The transitory colonies may be the cause of systematic artifact during the determination of stem cell proliferation. It was shown in particular that the proliferation of stem cells after sublethal irradiation remains the same, while higher rates of suicide are determined by the death of the precursors of the transitory colonies. At the same time higher proliferation of stem cells is not artifact in lethally irradiated animals and is also detectable after exclusion of the effects of the precursors of the transient colonies.     

Non-circadian rhythm in proliferation of haematopoietic stem cells

The proportion of haematopoietic stem cells (CFU-s) engaged in DNA synthesis was determined by means of the [3H]-thymidine [( 3H]TdR) suicide technique during recovery of bone marrow from the damage caused by a sublethal total body irradiation. In contrast with previous reports the [3H]TdR suicide rate was not permanently increased. It was observed that CFU-s passed through S phase in synchronous waves, following a dose of irradiation of 1.5 Gy. After a dose of 2.6 Gy, there was only one initial wave of increased CFU-s sensitivity to the action of [3H]TdR. Following the depression occurring 26 hr after the irradiation with 2.6 Gy, the proportion of CFU-s killed by the [3H]TdR was permanently increased until 5-6 days after irradiation. Thereafter large differences in the [3H]TdR suicide data were observed among individual mice. Evidence was obtained that individual mice, which had been irradiated by a dose of 2.6 Gy 8-9 days before, had identical values of the CFU-s [3H]TdR suicide rate in the bone marrow from different bones of the lower extremities. The recurrence of the synchronous waves in CFU-s passage through the cell cycle was recorded when the CFU-s population regenerated to only about 10% of its normal value. These waves were obviously not related to a particular time of the day and, consequently, they did not represent the circadian rhythm. It is concluded that the synchronous waves in which CFU-s proliferation occurred reflected the action of the control mechanism on CFU-s proliferation. This mechanism should be endowed with an important systemic component besides locally operating factors.     

Non-Circadian Rhythm In Proliferation of Haematopoietic Stem Cells

Abstract. The proportion of haematopoietic stem cells (CFU-s) engaged in DNA synthesis was determined by means of the [³H]-thymidine ([³H]TdR) suicide technique during recovery of bone marrow from the damage caused by a sublethal total body irradiation. In contrast with previous reports the [³H]TdR suicide rate was not permanently increased. It was observed that CFU-s passed through S phase in synchronous waves, following a dose of irradiation of 1.5 Gy. After a dose of 2.6 Gy, there was only one initial wave of increased CFU-s sensitivity to the action of [³H]TdR. Following the depression occurring 26 hr after the irradiation with 2.6 Gy, the proportion of CFU-s killed by the [³H]TdR was permanently increased until 5-6 days after irradiation. Thereafter large differences in the [³H]TdR suicide data were observed among individual mice. Evidence was obtained that individual mice, which had been irradiated by a dose of 2.6 Gy 8-9 days before, had identical values of the CFU-s [³H]TdR suicide rate in the bone marrow from different bones of the lower extremities. the recurrence of the synchronous waves in CFU-s passage through the cell cycle was recorded when the CFU-s population regenerated to only about 10% of its normal value. These waves were obviously not related to a particular time of the day and, consequently, they did not represent the circadian rhythm. It is concluded that the synchronous waves in which CFU-s proliferation occurred reflected the action of the control mechanism on CFU-s proliferation. This mechanism should be endowed with an important systemic component besides locally operating factors.     

EFFECTS OF HUMAN LEUKOCYTE CONDITIONED MEDIUM ON MOUSE HAEMOPOIETIC PROGENITOR CELLS

Medium conditioned by human peripheral blood leukocytes (HLCM) was studied for its in vitro effects on haemopoietic progenitor cells (CFU-s and CFU-c) present in mouse bone marrow. HLCM has poor colony stimulating activity in semi-solid cultures of mouse bone marrow cells. but invariably increases the number of colonies obtained in the presence of plateau levels of semi-purified colony stimulating factor (CSF). In liquid cultures, HLCM appears to contain a potent initiator of DNA synthesis in CFU-s. an activity which coincides with an increased CFU-s maintenance and causes a three- to four-fold increase in CFU-c number. It is apparent from this study that HLCM, in addition to stimulating colony formation in cultures of human bone marrow cells, has a profound in vitro effect on primitive haemopoietic progenitor cells of the mouse, which cannot be attributed to CSF.     

Existence of pre-CFU-S in the liver of mouse embryos

Two types of CFU-s different in the size of their colonies have been found in the liver of 14 day old mice embryo. Statistic processing of the data allowed to prove that large spleen colonies are formed directly by CFU-s, whereas small colonies are formed by pre-CFU-s which undergo preliminary proliferation and only the stochastically differentiate into CFU-s. Approximate concentration of pre-CFU-s constitutes 2.67 per 10(5) embryo liver cells.     

THYMIDINE SUICIDE IN VIVO AND IN VITRO OF SPLEEN COLONY FORMING AND AGAR COLONY FORMING CELLS OF MOUSE BONE MARROW

The ‘thymidine suicide’technique for indicating differences in the proliferation rate of early haemopoietic progenitor cells (spleen colony forming and agar colony forming cells) in C57BL mice has been evaluated. Special care was taken to use the same bone marrow cell suspension for the two progenitor cell assays. Both the in vivo and the in vitro techniques were employed. Following ³H-TdR in vivo, about 20% of both types of progenitor cell are killed in normal mice; however, after incubation in vitro with ³H-TdR, 35% of agar colony forming cells but only 4% of spleen colony forming cells are killed. Reasons for the difference between the in vivo and the in vitro results are discussed. With bone marrow from continuously irradiated animals, the thymidine suicide for both agar colony forming and spleen colony forming cells is in the range 42–50%, and there is no difference between in vivo and in vitro suicide. The in vivo results support the conclusion, based on the effect of proliferation dependent cytotoxic agents, that in C57BL mice agar colony forming and spleen colony forming cells are proliferating at the same rate in normal animals, and are speeded up to the same extent by continuous γ-irradiation. It is considered that in normal C57BL mice the in vitro method does not give a correct estimate of the proliferation rate of these progenitor cells. It would seem that the similarity in the proliferation rate of agar colony forming and spleen colony forming cells in C57BL mice is not true for other strains of mice: indeed using normal CBA and in vivo suicide, we have shown a significantly greater thymidine suicide for agar colony forming cells compared to spleen colony forming cells.     

Comparative studies on the characteristics of proliferation and differentiation of spleen colony-forming cells

Using a single spleen colony transplantation technique and sex chromosome typing as a natural cytogenetic marker, most spleen colony-forming cells (CFC) in adult bone marrow or fetal livers of inbred LACA or C57 mice re-established hemopoiesis in lethally irradiated mice when the spleen colonies were sampled at 13 days after transplantation. However, most of the spleen colony-forming cells in the peripheral blood of normal mice possess little potential for proliferation and are less efficient in the re-establishment of hemopoiesis in lethally irradiated mice. The CFC population is heterogeneous in the mice. From the subsequent retransplantation of colonies from colony-forming cells in the peripheral blood, the simple assessment of spleen colony-forming units (CFU-s) content, based on the number of splenic colonies, does not reliably represent the content of hemopoietic stem cells.     

The effect of carbamylcholine on CFU-s differentiation

The proportion of spleen colony-forming units (CFU-s) killed by hydroxyurea was greatly increased after bone marrow cells (BMCs) from LACA mice were exposed to carbamylcholine (Cach; 1 X 10(-13) to 1 X 10(-9) in vitro and there was a marked change in the proportion of spleen colony types. Following treatment with Cach, granulocytic and mixed erythroid-type colonies increased from 20 to 26.3% and 16.1 to 29.6% in 9-day colonies and from 8.3 to 28.2% and 21.7 to 39.4% in 13-day colonies, respectively. Single cell suspensions of spleen colonies were made for granulocyte-macrophage progenitor (CFU-gm) and late erythroid progenitor (CFU-e) assays. The number of CFU-gm from Cach-treated BMC was about twice that from control BMC for both day 9 and day 13 groups; the number of CFU-e decreased relatively. The results suggest that cholinergic receptors on CFU-s may increase the tendency to differentiate into the granulocytic/monocytic line.     

Decrease in the ability of CFU-s in shielded marrow to be recruited into cell cycle after multiple irradiations: experimental results and computer simulations

Nine doses of 1.5 Gy given to mice with one shielded leg result in very similar perturbations in shielded marrow (CFU-s kinetics whatever the source of radiation (X or γ rays). At the time of the ninth irradiation, the size of the shielded CFU-s compartment is reduced to 75% of control level. After 15 min it decreases to 47% and, 1 day later, remains below the pre-ninth irradiation level (62% of control level) in spite of two significant peaks of CFU-s in DNA synthesis, at 1 and 8 hr after the ninth irradiation. For acceptable fitting to experimental data, computer simulations make it necessary to assume that a fraction of shielded marrow CFU-s is not capable of entering the cell cycle after the treatment. This is not explainable by defects in the stimulators of CFU-s proliferation secreted by shielded haemopoietic tissue because their production and their efficacy are demonstrated to be normal after the nine exposures. the incomplete recovery of the shielded CFU-s pool from porliferating CFU-s can be attributed to a loss in CFU-s by differentiation at birth.     

Bone Marrow Response to Damage Induced By Hydroxyurea Or Colchicine

The extent of bone marrow damage caused by the administration of single or repeated doses of either hydroxyurea (1000 mg/kg b.w.) or colchicine (1 mg/kg b.w.) are comparable. This conclusion is based on serial studies of bone marrow cellularity and of the CFUc numbers in the bone marrow. the proliferation response of the pluripotential haemopoietic stem cells, determined by the cells forming colonies in the spleen of lethally irradiated mice (CFUs) markedly differs if the bone marrow damage is caused by hydroxyurea or colchicine. While hydroxyurea administration stimulates a large proportion of the resting G₀ cells into the cell cycle, the damage induced by colchicine is followed by only a mild increase in the CFUs proliferation rate. The seeding efficiency of the spleen colony technique has been determined after both hydroxyurea and colchicine administration. This parameter, important for the estimation of the number of the pluripotential haemopoietic stem cells in blood forming organs, is significantly affected by hydroxyurea administration, but also by repeated injections of colchicine. Following a single dose of hydroxyurea, the time-course of the CFUs numbers, which were corrected for the change in the seeding efficiency, shows an overshoot occurring after 18–20 hr. At the other time periods, the number of pluripotential haemopoietic stem cells is little affected by a single hydroxyurea injection. This poses a question about the nature of the stimulus, which after hydroxyurea administration triggers the CFUs from the resting G₀ state into the cell cycle. There is evidence that this stimulus is probably not represented by the damage caused to the various intensively proliferating cell populations of the bone marrow. This evidence is based on experiments which show that colchicine induced damage, of a degree similar to that after hydroxyurea, does not stimulate the CFUs proliferation rate to an extent comparable to hydroxyurea. The possibility that colchicine could block CFUs in the G₀ state or that it could interfere with the progress of CFUs through the G₁ and S phases of the cell cycle have been ruled out by experiments which demonstrated that colchicine (1 mg/kg b.w.), administered 10 min before hydroxyurea, does not reduce the number of CFUs triggered into the cell cycle as the consequence of hydroxyurea administration.     

Decrease in the ability of CFU-s in shielded marrow to be recruited into cell cycle after multiple irradiations: experimental results and computer simulations

Nine doses of 1.5 Gy given to mice with one shielded leg result in very similar perturbations in shielded marrow (CFU-s kinetics whatever the source of radiation (X or gamma rays). At the time of the ninth irradiation, the size of the shielded CFU-s compartment is reduced to 75% of control level. After 15 min it decreases to 47% and, 1 day later, remains below the pre-ninth irradiation level (62% of control level) in spite of two significant peaks of CFU-s in DNA synthesis, at 1 and 8 hr after the ninth irradiation. For acceptable fitting to experimental data, computer simulations make it necessary to assume that a fraction of shielded marrow CFU-s is not capable of entering the cell cycle after the treatment. This is not explainable by defects in the stimulators of CFU-s proliferation secreted by shielded haemopoietic tissue because their production and their efficacy are demonstrated to be normal after the nine exposures. The incomplete recovery of the shielded CFU-s pool from proliferating CFU-s can be attributed to a loss in CFU-s by differentiation at birth.     

Characteristics of the Cfu-S Population In Mice Carrying the SlJ Allele

Abstract Abstract. A tentative characterization of haemopoietic stem cells with respect to their organ distribution, seeding fraction and colony formation in the spleen, radiosen-sitivity and humoral regulation was attempted in mice heterozygous for the mutant allele Sl^J and in their normal littermates. Sl^J/+ mice were characterized by a deficient CFU-s content of the blood and spleen and had slightly lower femoral CFU-s numbers. This CFU-s distribution could not be explained by differences in seeding efficiency ‘f’ between CFU-s of Sl^J/+ and +/+ origin in lethally irradiated recipients used in the CFU-s assay. the seeding fraction of CFU-s of +/+ origin did not differ in +/+ and Sl^J/+ recipients. However, in irradiated SI^J/+ recipient mice a 30% decrease was observed in the number of the colonies derived from splenic and femoral CFU-s of both +/+ and Sl^J/+ origin. the serum level of SHSF (splenic haemopoiesis stimulating factor) was decreased in Sl^J/+ mice, but significantly increased in Sl/Sl^d mice, as compared to their respective normal +/+ littermates. Endogenous colony formation in Sl^J/+ spleens was deficient in comparison to that observed in +/+ spleens, and distinct sex differences were observed. However, mutant and normal CFU-s from spleen and bone marrow had a similar survival following in-vitro y irradiation. Femurs and spleens of both Sl^J/+ and +/+ origin were implanted into both Sl^J/+ and +/+ hosts. Six weeks later the Sl^J/+ grafts contained less CFU-s than the +/+ grafts. These data show that the splenic stroma of Sl^J/+ mice is not defective in its capacity to lodge injected CFU-s but is deficient in its ability to maintain CFU-s under ‘steady-state’ conditions and stimulate their colony formation in a ‘perturbed state’. Some of the characteristics of Sl^J/+ mice segregate them from Sl/Sl^d mice, i.e. a deficient splenic CFU-s content, normal seeding fractions ‘f’ of CFU-s from spleen and bone marrow in the presence of an almost compensated anemia, and decreased serum levels of SHSF. the study of the Sl^J trait may be a useful extension of the current Sl/Sl^d model for exploration of hereditary defects in haematopoietic stroma.