Radiation dose-fractionation and dose-rate relationships for long-term repopulating hemopoietic stem cells in a murine bone marrow transplant model

Fractionated and low-dose-rate total-body irradiation (TBI) were compared with single-dose high-dose-rate TBI for induction of long-term hemopoietic chimerism in a murine syngeneic bone marrow transplantation model. At 5 months after TBI and bone marrow transplantation, the degree of stable blood chimerism was determined from the proportion of stem cell-derived donor (B6-Gpi-1a) and host (B6-Gpi-1b) blood erythrocytes. This end point was used to construct radiation dose-response curves for long-term donor marrow engraftment corresponding to ablation of primitive bone marrow stem cells of the host. Increasing dose fractionation and decreasing dose rate had the effect of restoring host hemopoiesis and required higher TBI doses for equal donor engraftment. Most of the dose recovery occurred within the first 6 h between fractions, consistent with the kinetics of sublethal damage repair. The late chimerism data were fitted to the linear-quadratic model using indirect and direct analysis for a fixed threshold response. Both analyses gave relatively low alpha/beta ratios (below 2 Gy), within the range normally seen in late-responding tissues. The dose-rate data gave a repair half-time of 2 h as estimated by the incomplete-repair model. These estimates contrast with the much higher alpha/beta values and lower repair half-times derived from acute hemopoietic failure as indicated by LD50/30, with the implication that separate target cell populations with differing radiosensitivities are involved in these two bone marrow end points.     

Loss of estrogen upregulates osteoblastogenesis in the murine bone marrow. Evidence for autonomy from factors released during bone resorption

Loss of sex steroids causes an increase in both the resorption and formation of bone, with the former exceeding the latter. Based on evidence that the increased bone resorption after estrogen loss is due to an increase in osteoclastogenesis, we hypothesized that estrogen loss also stimulates osteoblastogenesis. We report that the number of mesenchymal osteoblast progenitors in the murine bone marrow was increased two- to threefold between 2 and 8 wk after ovariectomy and returned to control levels by 16 wk. Circulating osteocalcin, as well as osteoclastogenesis and the rate of bone loss, followed a very similar temporal pattern. Inhibition of bone resorption by administration of the bisphosphonate alendronate led to a decrease of the absolute number of osteoblast progenitors; however, it did not influence the stimulating effect of ovariectomy on osteoblastogenesis or osteoclastogenesis. These observations indicate that the increased bone formation that follows loss of estrogen can be explained, at least in part, by an increase in osteoblastogenesis. Moreover, they strongly suggest that unlike normal bone remodeling, whereby osteoblast development is stimulated by factors released from the bone matrix during osteoclastic resorption, estrogen deficiency unleashes signals that can stimulate the differentiation of osteoblast progenitors in a fashion that is autonomous from the need created by bone resorption, and therefore, inappropriate.     

Changes in the functional capacity of marrow stromal cells after autologous bone marrow transplantation

Marrow stromal cells were evaluated several months after autologous BMT for their capacity to support both normal hemopoiesis and secrete the main growth factors involved in its control, G-CSF, GM-CSF, IL-3 and SCF. Stromal layers (SL) were obtained by long-term marrow cultures (LTMC) established from 15 patients (9 with hematologic malignancies and 6 with solid tumors) 3 months after autologous BMT and were compared to pre-graft patients. After irradiation, both post-graft and pre-graft SL were recharged with the same inoculum of normal marrow cells. As compared to pre-graft values, CFU-GM production on post-graft SL was significantly increased during the first 2 weeks of culture whereas it was decreased from week 3 to week 8. These findings were only observed in patients with hematologic malignancies and not in patients with solid tumors. Growth factor secretion was evaluated by ELISA in the supernatants of unstimulated and IL-1-stimulated SL from 10 post-graft patients, 13 pre-graft patients and 5 normal controls. In any group of patients, IL-3 was undetectable either spontaneously or after IL-1-stimulation. As compared to controls, secretion by IL-1-stimulated SL was not different for GM-CSF in pre- and post-graft patients but tended to be decreased for G-CSF in post-graft patients. SCF secretion, which was not induced by IL-1, appeared dramatically decreased in both pre- and post-graft patients. The capacity of post-graft SL to support CFU-GM growth in LTMC was correlated at week 1 with G-CSF secretion and from week 3 to week 8 with SCF secretion. These results suggest that microenvironment remains qualitatively damaged several months after BMT involving a decreased capacity both to support early hemopoiesis and to secrete SCF, particularly in patients grafted for hemopoietic malignancies.     

Changes in the number of stem cells during mouse bone marrow cultivation on a sublayer of fibroblast-like cells

A determination was made of the number of colonies in the spleen of irradiated mice after administration to them of a culture of mouse bone marrow cells. Colony-forming units proved to persist in the culture only for a short time. Use of preliminarily grown underlayer of fibroblasts of bone marrow origin had no effect on the perservation and dynamics of the changes in the number oc colony-forming units.     

Characterization of the response of human bone marrow endothelial cells to in vitro irradiation

Endothelial cell dysfunction is a classic consequence of radiation damage. Bone marrow endothelial cells (BMEC) are a critical component of the stroma in the regulation of haemopoiesis. In animal models, radiation-induced injury of BMEC has been described and a role for BMEC in haemopoietic regeneration after irradiation has been suggested. However, functions of BMEC involved in the haemopoietic regeneration have not been assessed. Therefore we studied the functional response of human BMEC to irradiation using the transformed human BMEC line (TrHBMEC) irradiated with 2. 5 or 10Gy. Our results showed a time- and a dose-dependent increase in damage to irradiated TrHBMEC measured by a decreased number of adherent cells which correlated with increased apoptosis and augmented release of soluble ICAM-1 and von Willebrand factor. 2 Gy irradiated TrHBMEC expressed more ICAM-1 on their surface than non-irradiated cells, whereas no change in VCAM-1, E-selectin and PECAM-1 expression was observed. An increased production of G-CSF, GM-CSF, IL-8, IL-6, IL-1alpha, IL-11, MIP-1alpha and SCF and no production of LIF, TNF-alpha, TPO and IL-3 by 2 Gy irradiated TrHBMEC was observed. The haemopoietic supportive function of TrHBMEC was not altered after a 2 Gy exposure. These results suggest that although radiation induces endothelial cell damage, irradiated cells still support the proliferation and the differentiation of CD34+ haemopoietic cells.     

Immune reconstitution after autologous progenitor hemopoietic cell transplantation. A study comparing autologous bone marrow and autologous peripheral blood transplantation

BACKGROUND: In order to find out the effect of peripheral blood (PB) hematopoietic progenitor cells on immune reconstitution the present study compares, through a randomized trial, some lymphoid subsets after peripheral blood (PBT) or bone marrow (BMT) autologous transplantation. MATERIAL AND METHODS: Twelve patients suffering from malignant hematological disorders were included (6 BMT and 6 PBT). From these patients 14 lymphoid and natural killer (NK) subsets were sequentially analyzed using appropriate dual staining. NK activity was analyzed by measuring Cr51 release from the K562 cell line. Studies were done in days and -6, +10, +17, +24, +31, +38, +52, +66, +90, +120, +180 and +360 after transplantation. RESULTS: The CD8+ cell regeneration was produced mainly by activated cells (CD38+), and no differences were observed between BMT and PBT, but CD8+ HLADR+ cells were higher in the PBT group. During the first year after transplantation CD4+ lymphoid cells were never within normal range, and its recovery was due to the memory subset (CD4+/CD45RO+). The CD19+ lymphocytes began their regeneration after the first month and it was produced mainly by by the CD19+/CD5+ subset. NK cells recovered faster in patients who underwent PBT, but NK activity was similar in both subgroups of patients and it was within normal range from day +17 until the end of the study. CONCLUSION: T, B and NK lymphoid reconstitution do not differ significantly between patients that receive BM or PB as hemathopoietic rescue, but PB seems influence a faster reconstitution of cytotoxic subsets (CD8+/HLADR+ and NK lymphoid cells).     

The effect of dietary protein on reproduction in the mare. V. Endocrine changes and conception during the early post partum period

Pregnant Anglo-Arab and Thoroughbred mares (n = 24) were divided randomly according to age and breed into 4 groups of 6 mares each from approximately 6 weeks before their expected foaling date. Diets received by the 4 groups varied in essential amino-acid and total protein contents. Serum progestagen, FSH and LH concentrations were determined from the day of parturition until foal heat and during the 1st oestrous cycle following foal heat. Serum progestagen, FSH and LH concentrations did not differ between the treatment groups. Progestagen concentrations were high (mean = 7.0: 5.2-16.4 ng/ml) at parturition but decreased rapidly within 48 h. As progestagen concentrations decreased LH concentrations increased from Days 3-6 post partum to reach maximum values at, or the day after ovulation. FSH concentrations declined 3-4 d after parturition and increased 2-3 d before ovulation at foal heat. The duration of elevated progestagen concentrations during the luteal phase of the subsequent oestrous cycle affected the interovulatory period. A 12-14 d FSH cyclical releasing pattern occurred. Season/photoperiod affected the resumption of normal oestrous cyclicity during the post partum period. The duration of the 1st oestrous cycle after foal heat in mares fed a low-quality protein diet showed a greater range (13-30 d) compared to mares fed a high-quality protein diet (18-26 d).     

Induction of Fas ligand in murine bone marrow NK cells by bacterial polysaccharides

Bacterial polysaccharides have a wide range of activities in mammals. We have studied the effect of LPS and poly-beta-(1-->4)-D-mannuronate (mannuronan, poly-M), an exopolysaccharide from Pseudomonas aeruginosa, on the cytotoxicity mediated by murine bone marrow cells (BMC). Addition of LPS or mannuronan to BMC induced a time- and dose-dependent cytotoxicity against Jurkat cells. The LPS- or mannuronan-induced cytotoxicity was due to increased Fas ligand (FasL) expression by BMC, since 1) Fas-transfected L1210-Fas target cells were more susceptible to lysis than the Fas(low)-expressing parent L1210 cells, 2) stimulated BMC from FasL-defective gld/gld mice were not cytolytic and, 3) the cytolytic activity of normal BMC was inhibited by a Fas-Fc fusion protein. Flow cytometry showed an increase in surface FasL in LPS-stimulated BMC. RT-PCR analysis of BMC revealed constitutive expression of FasL mRNA, which was increased after LPS stimulation. Immunomagnetic depletion of NK1.1-, CD2-, or CD32/16-expressing cells from BMC abrogated the LPS-induced BMC cytotoxicity against L1210-Fas cells, suggesting that NK cells were the cytotoxic effector cells. Depletion of CD45R/B220-, Gr-1-, or CD11b/Mac-1-expressing cells only partially decreased BMC-mediated cytotoxicity, and depletion of CD4- or CD8a-expressing cells had no effect. The results support the conclusion that LPS and mannuronan induce expression of cytotoxic FasL on bone marrow NK cells.     

The effect of superoxide dismutase on the recovery of human bone marrow hemopoietic stem cells stored at 4 degreesC

Epidemiological research during the past 40 years has demonstrated with increasing clarity that amphibole asbestos fibres--crocidolite, amosite and tremolite--are more carcinogenic than chrysotile. A smaller number of well-controlled studies using lung burden analyses, while adding to the specificity of this conclusion, have shown that amphibole fibres also differ from chrysotile in being far more durable and biopersistent in lung tissue. Analyses of mesothelioma and lung cancer in a large cohort of Canadian chrysotile miners and millers have recently shown that the low-level presence of fibrous tremolite in these mines, rather than the chrysotile, may well be responsible. The high risk of lung cancer, but not of mesothelioma, in the chrysotile textile industry remains anomalous and cannot be explained in this way. These various findings are directly relevant to the choice of the experimental methods which should be used for screening man-made fibres for industrial use. Although it is clear that biopersistence is a major determinant of cancer risk in animals, and perhaps also in man, other factors affecting the biological activity of mineral fibres may also be important.     

Intracardiac right-to-left shunting and the risk of stroke during bone marrow infusion

We describe a patient who developed a paradoxical embolus to the brain during infusion of bone marrow. She had a patent foramen ovale through which right-to-left shunting led to multiple cerebral emboli. This complication can be prevented by positioning the tip of the infusion catheter in the main pulmonary artery and reducing the volume of marrow product infused.     

Changes in bone mass and bone biomarkers of cynomolgus monkeys during pregnancy and lactation

A substantial amount of calcium is transferred from the mother to the fetus and infant during pregnancy and lactation. Involvement of the skeleton in meeting this demand should be reflected in changes in bone mass and turnover. The purpose of the study was to determine the effects of pregnancy, lactation, and recovery on the skeleton in 43 young (prepeak bone mass) female monkeys. Whole body (WBBMC) and lumbar vertebrae 2-4 bone mineral content were determined by dual x-ray absorptiometry at baseline and 1, 4, and 10 months postpartum. Alkaline phosphatase, bone Gla protein, and urinary crosslinks were measured at baseline, during the third trimester, and 1, 4, and 10 months postpartum. Compared to nonpregnant, nonlactating monkeys, pregnant monkeys had similar rates of bone mass gain (nonpregnant, nonlactating WBBMC, 25+/-9 mg/day; pregnant WBBMC, 20+/-14 mg/day). Compared to pregnant monkeys, lactating females had increased bone turnover, as indicated by elevated bone biomarker levels (lactating alkaline phosphatase, 259+/-20 IU/L) and decreased bone mass (lactating WBBMC, -99+/-21 mg/day). Densitometry showed that bone mass gain in the lactating monkeys did not compensate for lactational loss by 10 months postpartum (WBBMC, 6.95+/-9 mg/day). This lack of recovery may have been due to the fact that serum estrogen concentrations were just beginning to return to baseline at 10 months postpartum. In conclusion, the cynomolgus monkey skeleton responds similarly to that of women during pregnancy and lactation. Recovery from lactational bone loss is not complete by 10 months postpartum.     

Stromal factors support the expansion of the whole hemopoietic spectrum from bone marrow CD34+DR- cells and of some hemopoietic subsets from CD34+ and CD34+DR+ cells

Ex vivo expanded bone marrow CD34+DR- cells could offer a graft devoid of malignant cells able to promptly reconstitute hemopoiesis after transplant. We investigated the specific expansion requirements of this subpopulation compared to the more mature CD34+ and CD34+DR+ populations. The role of stromal factors was assessed by comparing the expansion obtained when the cells were cultured in (1) long-term bone marrow culture (LTBMC) medium conditioned by an irradiated human BM stroma (CM), (2) medium supplemented with 15% FBS (FBSM) and (3) non-conditioned LTBMC medium (LTM) for 21 days. The effect of the addition of G-CSF (G) and/or of MIP-1alpha (M) to a combination of IL-3, SCF, IL-6 and IL-11 (3, S, 6, 11) was analyzed. Compared to CD34+DR- cells, CD34+ and CD34+DR+ cells gave rise to a similar number of viable cells and to a lower progenitor expansion. The expansion potential of CD34+ and CD34+DR+ cells was equivalent in CM and in FBSM except for both the emergence of CD61 + megakaryocytic cells and LTC-IC maintenance which were improved by culture in CM. In contrast, expansion from CD34+DR- cells was enhanced by CM for all the parameters tested. Compared to FBSM, CM induced a higher level of CFU-GM and BFU-E expansion and allowed the emergence of CD61+ cells. HPP-CFC were maintained or expanded in CM but decreased in FBSM. Compared to input, the number of LTC-IC remaining after 21 days of CD34+DR- expansion culture was strongly decreased in FBSM and variably maintained or expanded in CM. Comparison with LTM indicated that stroma conditioning is responsible for this effect. G-CSF significantly improved CFU-GM and HPP-CFC expansion from CD34+DR- cells without being detrimental to the LTC-IC pool. The growth of CD61+ cells was significantly enhanced by G-CSF in CM. Addition of MIP-1alpha had no significant effect either on progenitor expansion or on LTC-IC, regardless of culture medium. We conclude that factors present in stroma- conditioned medium are necessary to support the expansion of the whole spectrum of hematopoietic cells from CD34+DR- cells and to support the expansion of cell subsets from CD34+ and CD34+DR+.     

Changes in the processes of bone marrow cell proliferation and differentiation in white mice under the influence of heparin

In experiments carried out on albino mice daily heparin injections (250 units/kg) for two weeks resulted in 30% increase of leukocyte count in the venous blood. The femur bone marrow kariocyte count remained unchanged, while the leukoerythroblastic ratio rose from 4.1 to 7.6. Autoradiography demonstrated that the duration of the mitotic cycle and its phases in myeloid cells underwent no change, constituting: T--13 hrs, ts--8 hrs, tG2--1 hour, t(G1+M)--4 hrs. In heparinized animals the curve of labeled mitoses was nearly ideal. It is suggested that there occurred a change in the stem cells differentiation towards the myeloid type in the bone marrow under the effect of heparin.     

In vivo analysis of murine serum sulfate metabolism and splenic glycosaminoglycan biosynthesis during acute inflammation and amyloidosis

OBJECTIVE: Highly sulfated glycosaminoglycans (GAG) have been demonstrated in every form of amyloid examined to date. Based on temporal studies in murine amyloidogenesis heparan sulfate is deposited coincidentally with the amyloid protein. Our purpose was to follow in vivo GAG synthesis by monitoring 35SO4 incorporation during amyloidogenesis. Several necessary previously unexamined nonamyloidogenic controls were also examined. METHODS: Murine splenic amyloid was induced with lipopolysaccharide (LPS) and amyloid enhancing factor (AEF). Splenic GAG synthesis was monitored by 35SO4 incorporation. Corrections were made for alterations in SO4 metabolism which occur during inflammation. RESULTS: All animals with an inflammatory reaction had a marked increase in GAG synthesis. Those animals receiving AEF, or AEF+LPS, had a significant increase in heparan sulfate synthesis. This was particularly profound in the group developing amyloid (i.e., AEF+LPS). CONCLUSION: Our results indicate that critical factors in amyloid deposition include quantitative as well as qualitative changes that take place in tissue GAG synthesis. A distinct metabolic effect of AEF is demonstrated for the first time.