Biology of marrow stromal cell lines derived from long-term bone marrow cultures of Trp53-deficient mice.

To investigate the effect of Trp53 (formerly known as p53) on stromal cells of the hematopoietic microenvironment, long-term bone marrow cultures were established from mice in which the Trp53 gene had been inactivated by homologous recombination (Trp53(-/-)) or their wild-type littermates (Trp53(+/+)). Long-term bone marrow cultures from Trp53(-/-) mice continued to produce nonadherent cells for 22 weeks, while Trp53(+/+) cultures ceased production after 15 weeks. There was a significant increase in the number of nonadherent cells produced in Trp53(-/-) long-term bone marrow cultures beginning at week 9 and continuing to week 22 (P < 0.02). The Trp53(-/-) cultures also showed significantly increased cobblestone island formation indicative of early hematopoietic stem cell-containing colonies beginning at week 10 (P < 0.01). Cobblestone islands persisted until weeks 15 and 22 in Trp53(+/+) and Trp53(-/-) cultures, respectively. Co-cultivation experiments in which Trp53(+/+) Sca1(+)lin- enriched hematopoietic stem cells were plated on Trp53(-/-) stromal cells showed increased cobblestone island formation compared to Trp53(-/-) Scal+lin- cells plated on Trp53(+/+) or Trp53(-/-) stromal cells. Radiation survival curves for clonal bone marrow stromal cells revealed a similar D0 for the Trp53(+/+) and Trp53(-/-) cell lines (1.62 +/- 0.16 and 1.49 +/- 0. 08 Gy, respectively; P = 0.408), and similar n (8.60 +/- 3.23 and 10.71 +/- 0.78, respectively) (P = 0.491). Cell cycle analysis demonstrated a G2/M-phase arrest that occurred 6 h after irradiation for both Trp53(+/+) and Trp53(-/-) stromal cell lines. After 10 Gy irradiation, there was no significant increase in the frequency of apoptosis detected in Trp53(+/+) compared to Trp53(-/-) marrow stromal cell lines. In the stromal cell lines, ICAM-1 was constitutively expressed on Trp53(+/+) but not Trp53(-/-) cells; however, a 24-h exposure to TNF-alpha induced detectable ICAM-1 on Trp53(-/-) cells and increased expression on Trp53(+/+) cells. To test the effect of Trp53 on the radiation biology of hematopoietic progenitor cells, the 32D cl 3 cell line was compared with a subclone in which expression of an E6 inserted transgene accelerates ubiquitin-dependent degradation of Trp53, thus preventing accumulation of Trp53 after genotoxic stress. The radiation survival curves were similar with no significant difference in the D0 or n, or in the percentage of cells undergoing apoptosis after 10 Gy irradiation between the two cell lines. Cells of the 32D-E6 cell line displayed a G2/M-phase arrest 6 h after 10 Gy, while cells of the parent line exhibited both a G2/M-phase arrest and a G1-phase arrest at 24 and 48 h. The results suggest a complex mechanism of action of Trp53 on the interactions between stromal and hematopoietic cells in long-term bone marrow cultures.     

Survival of erythroid burst-forming units and erythroid colony-forming units in canine bone marrow cells exposed in vitro to 1 MeV neutron radiation or X rays

Conditioned media (CM) from allogeneic stimulated cultures of light density cells (less than 1.08 g/cm3) from the peripheral blood of normal dogs were used to stimulate the growth of erythroid burst-forming units (BFU-E) in bone marrow from normal dogs. Maximum numbers of BFU-E were obtained when 5% (vol/vol) 3 X CM and 2 U/ml erythropoietin were added to plasma clot cultures of bone marrow cells. In addition, the radiation sensitivity (D0 value) was determined for CFU-E and for BFU-E in bone marrow cells exposed in vitro to 1 MeV fission neutron radiation or 250 kVp X rays. BFU-E were more sensitive than CFU-E to the lethal effects of both types of radiation. For bone marrow cells exposed to 1 MeV neutron radiation, the D0 for CFU-E was 0.27 +/- 0.01 Gy, and the D0 for BFU-E was 0.16 +/- 0.03 Gy. D0 values for CFU-E and BFU-E were, respectively, 0.61 +/- 0.05 Gy and 0.26 +/- 0.09 Gy for cells exposed to X rays. The neutron RBE values for the culture conditions described were 2.3 +/- 0.01 for CFU-E and 1.6 +/- 0.40 for BFU-E.     

Radiosensitivity of stromal precursors and mature hematopoietic stromal cells in a culture

Radiosensitivity of hemopoietic stroma precursors from a long-term culture of murine bone marrow, as measured by the adherent cell layer implantation techniques, was characterized by D0 = 3.02 +/- 0.7 Gy and n = 1.6. Mature cells of the hemopoietic microenvironment survived after doses of up to 100 Gy. Their irreversible damage was only observed after 150-200 Gy irradiation. The results obtained support the suggestion of different histogenetical origin of the hemopoietic and stromal precursors.     

Production and differentiation of NK lineage cells in long-term bone marrow cultures in the absence of exogenous growth factors.

Neither lytic NK cells nor IL-2-responsive NK precursors were produced in myeloid (Dexter) long-term bone marrow cultures (LTBMC). However, when myeloid LTBMC were switched to lymphoid (Whitlock-Witte) conditions and reseeded ("recharged") with fresh bone marrow cells (BMC), nonadherent cells with NK lytic activity and NK 1.1+ phenotype were produced within 1-2 weeks without the addition of exogenous IL-2 to the cultures. NK- and T cell-depleted BMC proliferated extensively in switched cultures and in 2 weeks generated cells that lysed the NK target YAC-1 but not the LAK target P815. The presence of NK precursors in the cultures was confirmed by reculturing nonadherent cells harvested from recharged LTBMC in fresh medium containing 50 U rIL-2/ml. High levels of NK lytic activity were generated. Sequential expression of NK 1.1 and IL-2 responsiveness followed by lytic activity was demonstrated by harvesting cells early after recharge, prior to the appearance of lytic cells. Elimination of NK 1.1+ cells depleted the ability to respond to IL-2 in secondary culture. Our studies demonstrate that myeloid-to-lymphoid switched LTBMC support the proliferation and differentiation of NK lineage cells from their NK 1.1-, nonlytic progenitors in the absence of an exogenous source of growth factors.     

Persistent production of colony-stimulating factor (CSF-1) by cloned bone marrow stromal cell line D2XRII after X-irradiation

The adherent stromal layer in long-term bone marrow cultures (LTBMC) provides the cellular environment necessary for the in vitro proliferation and differentiation of pluripotential hematopoietic stem cells. The role of humoral hematopoietic growth factors, colony-stimulating factors (CSF) in the regulation of hematopoietic cell production in this system is poorly understood. We have recently isolated and cloned an adherent cell line, D2XRII, derived from murine LTBMC. Plateau phase 25 cm2 cultures of 2 X 10(6) D2XRII cells in 8.0 ml produced CSF-1 (M-CSF) at around 100-150 units/0.1 ml medium. Following X-irradiation there was a dose-dependent decrease in the production of CSF-1 to a plateau of 50% of control levels at 10,000 rad. Higher doses did not produce a further decrease. The X-ray dose reducing CSF-1 production to 50% was 100-fold above the lethal dose as measured by clonagenic survival following trypsinization and replating. Trypsinized replated viable adherent but nondividing X-irradiated D2XRII cells were maintained for up to 8 weeks after irradiation and demonstrated continuous production of CSF-1. The data indicate significant divergence of two biologic effects of X-irradiation on plateau-phase marrow stromal cells: physiologic function of adherence and CSF-1 production, versus proliferative integrity. This divergence of effects may be very relevant to understanding the mechanism of X-irradiation-associated marrow suppression and leukemogenesis.     

Overexpression of the MnSOD transgene product protects cryopreserved bone marrow hematopoietic progenitor cells from ionizing radiation

We determined whether manganese superoxide dismutase (MnSOD)-plasmid liposome (PL) transfection of C57BL/ 6NHsd mouse bone marrow protected cells irradiated at room temperature (24 degrees C) or in the cryopreserved state. MnSOD-overexpressing hematopoietic progenitor 2C6 cells were radioresistant compared to the parent 32D cl 3 cells when irradiated frozen or at 24 degrees C. Fresh whole marrow from mice injected intravenously with MnSOD-PL prior to explant as well as explanted marrow single cell suspensions transfected in vitro were irradiated at 24 degrees C or -80 degrees C. In vivo or in vitro transfection of marrow with MnSOD-PL produced significant radiation protection of irradiated marrow progenitor cells compared to controls at 24 degrees C or -80 degrees C. (in vivo transfection D(0) 2.19 +/- 0.21 at 24 degrees C, D(0) 2.10 +/- 0.07 at -80 degrees C compared to control D(0) 1.56 +/- 0.06 or 1.66 +/- 0.04, P = 0.047 and 0.017 respectively; in vitro transfection D(0) 2.35 +/- 0.11 at 24 degrees C, D(0) 3.42 +/- 0.13 at -80 degrees C compared to D(0) 1.81 +/- 0.01 or 2.53 +/- 0.05, P = 0.0087 and 0.0026, respectively). Thus the MnSOD transgene product protects frozen marrow cells as well as marrow cells irradiated at 24 degrees C.     

Structure and function of bone marrow environment

Bone marrow and spleen are the major hematopoietic tissue in adult mice. However, little is known about the specific mechanism regulating hematopoiesis within these tissues. Since Dexter et al. first described conditions to maintain bone marrow hematopoiesis, long term bone marrow culture (LTBMC) has been developed in order to analyze the mechanism of the maintenance of proliferation and differentiation of hematopoietic stem cells in vitro. Furthermore, several stromal cell lines which are able to support the growth and differentiation of hematopoietic lineage, has been established from LTBMC. Although it is well known that bone marrow stromal cell lines are able to produce colony stimulating factors, it has been suggested that the stromal cell factors which involve membrane bound moieties must have a key role in the regulation of hematopoiesis. We expect that monoclonal antibodies to the surface of bone marrow stromal cells could detect such a critical stroma-associated protein that bounds the cell surface of the bone marrow stroma.     

Xyloside effects on in vitro hematopoiesis: functional and biochemical studies

Xyloside supplementation of long-term bone marrow cultures (LTBMCs) has been reported to result in greatly enhanced proliferation of hematopoietic stem cells. This was presumed to be the result of xyloside-mediated perturbation of proteoglycan synthesis by marrow-derived stromal cells. To investigate this phenomenon, we first studied the effects of xyloside supplementation on proteoglycan synthesis by D2XRadII bone marrow stromal cells, which support hematopoietic stem cell proliferation in vitro. D2XRadII cells were precursor labelled with 35S-sulfate, and proteoglycans separated by ion exchange chromatography, isopyknic CsCl gradient centrifugation, and gel filtration HPLC. Xyloside-supplemented cultures showed an approximately fourfold increase in total 35S incorporation, mainly as free chondroitin-dermatan sulfate (CS/DS) glycosaminoglycan chains in the culture media. Both xyloside supplemented and nonsupplemented cultures synthesized DS1, DS2, and DS3 CS/DS proteoglycans as previously described. In contrast to previous reports, xyloside was found to inhibit hematopoietic cell growth in LTBMC. Inhibitory effects were observed both in cocultures of IL-3-dependent hematopoietic cell lines with supportive stromal cell lines and in primary murine LTBMCs. Xyloside was found to have a marked inhibitory effect on the growth of murine hematopoietic stem cells and IL-3-dependent hematopoietic cell lines in clonal assay systems and in suspension cultures. In contrast, dialyzed concentrated conditioned media from LTBMCs had no such inhibitory effects. These findings suggest that xyloside-mediated inhibition of hematopoietic cell growth in LTBMC resulted from a direct effect of xyloside on proteoglycan synthesis by hematopoietic cells.     

Interleukin-3 induces proliferation but not lymphokine activated killer activity from human and murine mononuclear cells

Recombinant IL-3 (rIL-3) is a potent colony stimulating factor capable of stimulating early hematopoietic pluripotential progenitor cells and of supporting the differentiation of multiple cells. IL-3 has also been shown to have effects on mature, differentiated circulating cells including eosinophils and T cells. We evaluated the role of exogenous rIL-3 in the generation of cells with LAK activity from murine splenocytes and human bone marrow, spleen, unseparated PBMC and purified null cell preparations. rIL-3 was unable to generate lytic activity from any of these populations by itself and appeared to decrease LAK activity in bone marrow cultures containing high dose IL-2, (bone marrow derived cells (n = 3) with LAK activity for fresh tumor, mean lytic units(LU) 94.6 +/- 63.5 vs 32.8 +/- 44.8 for IL-2 and IL-2 plus IL-3 cultures, respectively p2 less than 0.05). Unlike previous reports testing murine cells, IL-3 priming and subsequent culture in IL-2 of human unseparated bone marrow cells or human or murine splenocytes, failed to generate long-term cultures with lytic activity. IL-3 did, however, induce a dose dependent stimulation of bone marrow and null cell preparations (mean null cell stimulation (3H Thymidine incorporation) with IL-3, 436 +/- 168 cpm vs 9802 +/- 9799 cpm, for 0 vs 10(3) units of IL-3, respectively n = 4, p2 less than 0.05). Furthermore, in bone marrow, unseparated PBMC and null cell cultures, the addition of rIL-3 generated characteristic large blastic appearing cells with prominent basophilic granules.(ABSTRACT TRUNCATED AT 250 WORDS)     

Expression of CD23 by human bone marrow stromal cells.

CD23 is a surface antigen expressed by a variety of human hematopoietic cells and shown to display multiple biological functions. In present work, we assayed CD23 expression by human bone marrow (BM) or by stromal cells derived from this tissue. While freshly isolated BM-cells showed low CD23 expression, a subset of long term BM-culture (LTBMC)-derived stromal cells expressed CD23 mRNA at high levels in their steady state and secreted soluble CD23 in their culture supernatants. To assay the role of CD23 in LTBMC, these cultures were initiated in the presence of neutralizing anti-CD23 mAb. A dramatic decrease in total numbers of hematopoietic cells and CFU-GM recovery was observed in these cultures as compared to controls. These data suggest a role of CD23 expression in stroma cell functions and further confirm the ability of this antigen to regulate human hematopoietic cell development.     

Phenotypic and functional comparison of cultures of marrow-derived mesenchymal stem cells (MSCs) and stromal cells

Mesenchymal stem cells (MSCs) are a population of pluripotent cells within the bone marrow microenvironment defined by their ability to differentiate into cells of the osteogenic, chondrogenic, tendonogenic, adipogenic, and myogenic lineages. We have developed methodologies to isolate and culture-expand MSCs from human bone marrow, and in this study, we examined the MSC's role as a stromal cell precursor capable of supporting hematopoietic differentiation in vitro. We examined the morphology, phenotype, and in vitro function of cultures of MSCs and traditional marrow-derived stromal cells (MDSCs) from the same marrow sample. MSCs are morphologically distinct from MDSC cultures, and flow cytometric analyses show that MSCs are a homogeneous cell population devoid of hematopoietic cells. RT-PCR analysis of cytokine and growth factor mRNA in MSCs and MDSCs revealed a very similar pattern of mRNAs including IL-6, -7, -8, -11, -12, -14, and -15, M-CSF, Flt-3 ligand, and SCF. Steady-state levels of IL-11 and IL-12 mRNA were found to be greater in MSCs. Addition of IL-1α induced steady-state levels of G-CSF and GM-CSF mRNA in both cell preparations. In contrast, IL-1α induced IL-1α and LIF mRNA levels only in MSCs, further emphasizing phenotypic differences between MSCs and MDSCs. In long-term bone marrow culture (LTBMC), MSCs maintained the hematopoietic differentiation of CD34⁺ hematopoietic progenitor cells. Together, these data suggest that MSCs represent an important cellular component of the bone marrow microenvironment. J. Cell. Physiol. 176:57–66, 1998. © 1998 Wiley-Liss, Inc.     

Ex vivo expansion of primitive hematopoietic cells for cellular therapies: An overview

Sources of hematopoietic cells for bone marrow transplantation are limited by the supply of compatible donors, the possibility of viral infection, and autologous (patient) marrow that is depleted from prior chemo- or radiotherapy or has cancerous involvement. Anex vivo system to amplify hematopoietic progenitor cells could increase the number of patients eligible for autologous transplant, allow use of cord blood hematopoietic cells to repopulate an adult, reduce the amount of bone marrow and/or mobilized peripheral blood stem and progenitor cells required for transplantation, and reduce the time to white cell and platelet engraftment. The cloning of hematopoietic growth factors and the identification of appropriate conditions has enabled the development of successfulex vivo hematopoietic cell cultures. Purification systems based on the CD34 marker (which is expressed by the most primitive hematopoietic cells) have proven an essential tool for research and clinical applications. Present methods for hematopoietic cultures (HC) on stromal (i.e. accessory cells that support hematopoiesis) layers in flasks lack a well-controlled growth environment. Several bioreactor configurations have been investigated, and a first generation of reactors and cultures has reached the clinical trial stage. Our research suggests that perfusion conditions improve substantially the performance of hematopoietic reactors. We have designed and tested a perfusion bioreactor system which is suitable for the culture of non-adherent cells (without stromal cells) and readily scaleable for clinical therapies. Eliminating the stromal layer eliminates the need for a stromal cell donor, reduces culture time, and simplifies the culture system. In addition, we have compared the expansion characteristics of both mononuclear and CD34⁺ cells, since the latter are frequently assumed to give a superior performance for likely transplantation therapies.Abbreviations BFU0-E burst forming unit-erythroid - BM bone marrow - CB cord blood - CFU-C colony forming unit-culture - CFU-E colony forming unit-erythroid - CFU-F colony forming unit-fibroblast - CFU-GEMM colony forming unit-granulocyte, erythroid, macrophage, megakaryocyte - CFU-GM colony forming unit-granulocyte, macrophage - CFU-Mix colony forming unit-mixed (also known as CFU-GEMM) - CML chronic myeloid leukemia - CSF colony stimulating factor - DMSO dimethyl sulfoxide - ECM extracellular matrix - EPO erythropoietin - FL fetal liver - HC hematopoietic culture - LTBMC long-term bone marrow culture - LTC-IC long-term culture initiating cell - LTHC long-term hematopoietic culture - MNC mononuclear cells - PB peripheral blood     

Stromal cells derived from spleen or bone marrow support the proliferation of rat natural killer cells in long-term culture.

Rat nylon wool nonadherent bone marrow cells were propagated for up to 75 days in co-culture with stromal cells derived from either spleen or bone marrow. Interleukin (IL) 1 enhanced the ability of spleen stroma to support the long-term culture of natural killer (NK) cells, ostensibly by inducing these support cells to synthesize other cytokines. Flow cytometry studies indicated that the nylon wool separation procedure enriched the concentrations of mature NK cells from 7.9% to 38.1% for splenocytes and from 3.8% to 19.5% for bone marrow cells. Analyses of the adherent zones of suspended nylon screen NK cell cultures revealed substantial numbers of large granular lymphocytes that expressed NK 323+/MOM/3F12/F2- phenotypes. The presence of both mature and immature cells of the NK lineage in this matrix was inferred by the presence of both IL-2 receptor (IL-2R) positive and IL-2R negative, and OX-8+ and OX-8- NK 323+ cells over the greater than 4-month experimental period. Suspended nylon screen cultures displayed a greater potential for producing cytolytic cells than either co-cultures of bone marrow nonadherent cells on stroma monolayers or suspension cultures. The large granular lymphocytes produced in suspended nylon screen cultures could be transformed into active killers of YAC-1 targets by IL-2. In contrast to bone marrow nonadherent cells, more splenic nylon-wool-passed cells displayed a mature NK phenotype, but their proliferative potential and ability to be transformed into cytolytic cells by IL-2 decreased rapidly in culture. In the suspended nylon screen culture system, NK cells migrate from the underlying stroma in stages as they mature, retain their cytolytic potential, and manifest a capacity for self-renewal. Cultured cells were routinely dissociated into single cell suspensions via enzyme treatment and were reinoculated onto "fresh" nylon screen/stromal cell templates after passage through nylon wool columns. These co-cultures continued to generate cytolytic cells in numbers greater than those of the initial inoculum.     

Haemopoietic Inductive Capacity of Irradiated Stromal Cell Layers In Human Micro Long-Term Bone Marrow Cultures

Abstract. In a micro long-term bone marrow culture (LTBMC) system the effects of irradiation on confluent stromal cell layers were studied. In order to individually analyse the number of granulocyte-macrophage colony-forming cells (GM-CFC) per LTBMC a miniaturized human GM-CFC assay was established. the normalized GM-CFC numbers in the micro-assay compared well with data by the conventional GM-CFC assay. Pre-formed stromal cell layers were irradiated with doses up to 20 Gy and subsequently recharged with allogeneic bone marrow cells (BMC). Immediately before recharge the BMC were stromal cell-depleted by nylon wool filtration. When stromal cell-depleted BMC were inoculated on empty culture dishes, in vitro haemopoiesis rapidly declined. Sustained GM-CFC production, however, was seen when these cells were used as a second inoculum. It is concluded that irradiation doses of up to 20 Gy do not cause alteration of the haemopoietic inductive capacity of confluent stromal cell layers.     

Effect of cytokines on the proliferation/differentiation of stroma-initiating cells

A culture system that identifies the precursor of murine bone marrow fibroblastic stromal cells (stroma-initiating cells, SIC) has been developed. In this system, mature fibroblasts are depleted by adherence to plastic dishes and the nonadherent cells are seeded at a low density, which results in the formation of colonies composed of fibroblastic cells. Macrophage colony-stimulating factor (M-CSF) has been shown to accelerate the colony formation in the system. In this study, we examined the stroma-inducing activity of a number of cytokines. Neither granulocyte-CSF, stem cell factor, interleukin (IL)-1, IL-6, transforming growth factor, epidermal growth factor, insulin-like growth factor, platelet-derived growth factor, nor fibroblast growth factor showed the activity. Similarly, tumor necrosis factor (TNF) did not show any stroma-inducing activity, but the factor inhibited the stromal colony formation induced by M-CSF. In this study, we found that granulocyte/macrophage-CSF (GM-CSF) and IL-3, as well as M-CSF had the stroma-inducing activity. Neither an additive nor synergistic effect was observed when the three factors were assayed in various combinations. The stroma-inducing activity of M-CSF, GM-CSF and IL-3 was observed even if lineage-negative bone marrow cells were used as target cells, suggesting that mature hematopoietic cells such as macrophages and granulocytes were not involved in the induction of stromal colony formation by these factors. Our results raise the possibility that GM-CSF and IL-3 as well as M-CSF stimulate the proliferation or differentiation of the precursor of bone marrow fibroblastic stromal cells.     

Long-term effects of low-level 239Pu contamination on murine bone-marrow stem cells and their progeny

The effects of long-term internal contamination with 13.3 kBq kg-1 239Pu injected intravenously were studied in 10-week-old ICR (SPF) female mice. Radiosensitivity of spleen colony-forming units (CFU-S) and 125IUdR incorporating into proliferating cells of vertebral bone marrow and spleens were determined in plutonium-treated and control animals one year after nuclide injection. The CFU-S in 239Pu-treated mice were more sensitive to X-rays (D0 = 0.52 +/- 0.01 Gy) than in controls (D0 = 0.84 +/- 0.02 Gy). 125IUdR incorporation into bone marrow and spleen cells was reduced after plutonium contamination. At one year following plutonium injection, the occurrence of chromosome aberrations was evaluated in metaphase figures of femoral bone marrow cells. The frequency of aberrations increased early after plutonium treatment, at later intervals it tended to decrease but not below the control level. While the relative numbers of vertebral marrow CFU-S decreased significantly, but only to 86 per cent of normal, cellularity of vertebral bone marrow, peripheral blood counts and survival of 239Pu-treated mice did not differ from the control data.     

Haemopoietic inductive capacity of irradiated stromal cell layers in human micro long-term bone marrow cultures

In a micro long-term bone marrow culture (LTBMC) system the effects of irradiation on confluent stromal cell layers were studied. In order to individually analyse the number of granulocyte-macrophage colony-forming cells (GM-CFC) per LTBMC a miniaturized human GM-CFC assay was established. The normalized GM-CFC numbers in the micro-assay compared well with data by the conventional GM-CFC assay. Pre-formed stromal cell layers were irradiated with doses up to 20 Gy and subsequently recharged with allogeneic bone marrow cells (BMC). Immediately before recharge the BMC were stromal cell-depleted by nylon wool filtration. When stromal cell-depleted BMC were inoculated on empty culture dishes, in vitro haemopoiesis rapidly declined. Sustained GM-CFC production, however, was seen when these cells were used as a second inoculum. It is concluded that irradiation doses of up to 20 Gy do not cause alteration of the haemopoietic inductive capacity of confluent stromal cell layers.     

Increased radioresistance, g(2)/m checkpoint inhibition, and impaired migration of bone marrow stromal cell lines derived from Smad3(-/-) mice

Smad3 protein is a prominent member of the Tgfb receptor signaling pathway. Smad3(-/-) mice display decreased radiation-induced skin fibrosis, suggesting a defect in both Tgfb-mediated fibroblast proliferation and migration. We established bone marrow stromal cell lines from Smad3(-/-) mice and homozygous littermate(+/+) mice. Smad3(-/-) cells displayed a significant increase in radiation resistance with a D(0)=2.25+/- 0.14 Gy compared to Smad3(+/+) cells with a D(0)=1.75+/- 0.03 (P=0.023). Radioresistance was abrogated by reinsertion of the human SMAD3 transgene, resulting in a D(0)=1.49 0.10 (P=0.028) for Smad3(-/-)(3) cells. More Smad3(-/-) cells than Smad3(+/+) cells were in the G(2)/M phase; Smad3(-/-)(3) cells were similar to Smad3(+/+) cells. Smad3(+/+) cells exhibited increased apoptosis 24 h after 5 Gy (15%) or 8 Gy (43%) compared to less than 1% in Smad3(-/-) cells exposed to either dose. The movement of Smad3(-/-) cells, measured in an automated cell tracking system, was slower than that of Smad3(+/+) cells. Smad3(-/-)(3) cells resembled Smad3(+/+) cells. These studies establish concordance of a defective Tgfb signal transduction pathway, an increased proportion of G(2)/M cells, and radioresistance. The decreased migratory capacity of Smad3(-/-) cells in vitro correlates with decreased radiation fibrosis in vivo in mice deficient in Tgfb signaling.     

Response kinetics of radiation-induced micronucleated reticulocytes in human bone marrow culture

The frequency of micronucleated reticulocytes (MN-RETs) in the bone marrow or peripheral blood is a sensitive indicator of cytogenetic damage. While the kinetics of MN-RET induction in rodent models following irradiation has been investigated and reported, information about MN-RET induction of human bone marrow after radiation exposure is sparse. In this report, we describe a human long-term bone marrow culture (LTBMC), established in three-dimensional (3D) bioreactors, which sustains long-term erythropoiesis. Using this system, we measured the kinetics of human bone marrow red blood cell (RBC) and reticulocyte (RET) production, as well as the kinetics of human MN-RET induction following radiation exposure up to 6Gy. Human bone marrow established in the 3D bioreactor demonstrated an average percentage of RBCs among total viable cells peaking at 21% on day 21. The average percentage of RETs among total viable cells reached a maximum of 11% on day 14, and remained above 5% by day 28, suggesting that terminal erythroid differentiation was still active. Time- and dose-dependent induction of MN-RET by gamma radiation was observed in the human 3D LTBMC, with peak values occurring at approximately 3 days following 1Gy irradiation. A trend towards delayed peak to 3-5 days post-radiation was observed with radiation doses ≥2Gy. Our data reveal valuable information on the kinetics of radiation-induced MN-RET of human bone marrow cultured in the 3D bioreactor, a synthetic bioculture system, and suggest that this model may serve as a promising tool for studying MN-RET formation in human bone marrow, thereby providing opportunities to study bone marrow genotoxicity testing, mitigating agent effects, and other conditions that are not ordinarily feasible to experimental manipulation in vivo.