Limited engraftment capacity of bone marrow-derived mesenchymal cells following T-cell-depleted hematopoietic stem cell transplantation

The engraftment capacity of bone marrow-derived mesenchymal cells was investigated in 41 patients who had received a sex-mismatched, T-cell-depleted allograft from human leukocyte antigen (HLA)-matched or -mismatched family donors. Polymerase chain reaction (PCR) analysis of the human androgen receptor (HUMARA) or the amelogenin genes was used to detect donor-derived mesenchymal cells. Only 14 marrow samples (34%) from 41 consenting patients generated a marrow stromal layer adequate for PCR analysis. Monocyte-macrophage contamination of marrow stromal layers was reduced below the levels of sensitivity of HUMARA and amelogenin assays (5% and 3%, respectively) by repeated trypsinizations and treatment with the leucyl-leucine (leu-leu) methyl ester. Patients who received allografts from 12 female donors were analyzed by means of the HUMARA assay, and in 5 of 12 cases a partial female origin of stromal cells was demonstrated. Two patients who received allografts from male donors were analyzed by amplifying the amelogenin gene, and in both cases a partial male origin of stromal cells was shown. Fluorescent in situ hybridization analysis using a Y probe confirmed the results of PCR analysis and demonstrated in 2 cases the existence of a mixed chimerism at the stromal cell level. There was no statistical difference detected between the dose of fibroblast progenitors (colony-forming unit-F [CFU-F]) infused to patients with donor- or host-derived stromal cells (1.18 +/- 0.13 x 10(4)/kg vs 1. 19 +/- 0.19 x 10(4)/kg; P >/=.97). In conclusion, marrow stromal progenitors reinfused in patients receiving a T-cell-depleted allograft have a limited capacity of reconstituting marrow mesenchymal cells.     

Stromal cells in long-term murine bone marrow culture: FACS studies and origin of stromal cells in radiation chimeras

Adherent layers from hematopoietically active long-term bone marrow cultures (LTBMC), incubated with fluorescent beads, were analyzed for autofluorescence and phagocytic ability, using a fluorescence-activated cell sorter (FACS). Four groups of cells were separated from the adherent layers, including a group of large polygonal fibroblastoid stromal cells. Long-term chimeras were made by lethal irradiation of CBA/Ca (CBA) and C57Bl6/J (B6) mice and repopulation with phosphoglycerate kinase (PGK-1) alloenzyme-congenic bone marrow cells. Hematopoietically active LTBMC were established from such chimeras, and donor and host contributions of FACS-sorted adherent-layer cells were measured. While macrophages and other hematopoietic cells were of donor origin, the fibroblastoid stromal cells were mainly or entirely host derived.     

Morphological and functional characteristics of short-term and long-term bone marrow cultures in chronic myelogenous leukemia

Clonogenic capacity of bone marrow progenitors and stromal layers established from bone marrow of 12 patients with CML and 13 healthy controls were evaluated. The initial BFU-E and CFU-GM contents were slightly higher in the CML patients (p > 0.05) in contrast to CFU-GEMM. CFU-GEMM was lower in the patients compared to healthy controls (p < 0.001). In long-term cultures, the number of non-adherent cell population and total clonogenic progenitor cell content decreased gradually in both groups. Weekly evaluation of stromal confluency of adherent cells revealed that establishment of adherent stromal layer was slower in CML patients than in control samples (p < 0.05). At the end of fourth week, the number of samples presenting confluency was 41.7% in the CML group compared with 92.3% in the controls. The initial CD34 positive cell content of the bone marrow samples was similar in both groups. Although CD34 positive cell number in the adherent stromal layer was well preserved in the control group at the end of 4 weeks, this figure decreased significantly in the CML group. The numbers of total adherent cells as well as the total clonogenic progenitor content of adherent layer were also lower in the CML group (3.03% vs 98.2%). When normal CD34+ cells were cultured on IFN-alpha-treated stromal layer followed by the assessment of the long-term culture initiating cells, a reduced capacity to support hemopoietic growth was observed with IFN-alpha-treated normal stroma. This reduction was even higher when CML stroma was treated with IFN-alpha followed by the seeding of the normal CD34+ cells on this stromal layer (26.9% vs 42.8%). These findings show that stromal cells are abnormal in CML patients as well as the progenitor cells, and IFN-alpha treatment causes further defects of the stromal cells.     

Evidence for migration of donor bone marrow stromal cells into recipient thymus after bone marrow transplantation plus bone grafts: A role of stromal cells in positive selection

Intrathymic T-cell differentiation is characterized by two selection events: positive and negative selection. It has been shown that thymic epithelial cells in the cortex are involved in the positive selection, while macrophages and dendritic cells, derived from hemopoietic stem cells, are involved in the negative selection. Here we investigate whether donor-derived bone marrow stromal cells can migrate into the thymus and participate there in positive selection after bone marrow transplantation plus bone grafts (to recruit bone marrow stromal cells).Allogeneic bone marrow transplantation with or without bone grafts was carried out in the [C57BL/6-->C3H] combination. Fluorescence-activated cell sorter analyses of recipient thymic adherent cells showed that donor-type bone marrow stromal cells exist in the thymus of mice that received bone marrow plus bone grafts but not in the mice that received bone marrow cells alone. Histological examination using confocal microscopy also confirmed the existence of donor-type stromal cells in the thymus of mice that received bone marrow cells plus bones. Both T-cell proliferation and plaque-forming cell assays indicated that the T cells of such mice show donor-type major histocompatibility complex-restriction.These findings strongly suggest that stromal cells can migrate from the bone marrow to the thymus, where they participate in the positive selection of thymocytes.     

Correction of stromal cell defect after bone marrow transplantation in aplastic anaemia

Defects in stromal cell function have been demonstrated in a number of aplastic anaemia (AA) patients. Here we have studied a patient with severe AA and abnormal stromal cell function who underwent bone marrow transplantation (BMT). The objective of this study was to investigate the timing and the mechanism of correction of the stromal defect after transplantation. The patient, a 25-year-old woman with severe AA, underwent BMT from her brother. BM was obtained from the patient on five occasions: 2 weeks pre BMT, and 3, 8, 16 and 21 months post BMT. Stromal cells were grown to confluence and recharged with purified CD34+ cells from normal donors. The support of such cells, as assessed by weekly colony-forming assay (CFU) of non-adherent cells, was compared with that of stromal layers grown from normal BM. A novel technique of combined fluorescence in situ hybridization (FISH) and immunocytochemistry was used to determine the origin of specific stromal cell types on cytospins of stroma post BMT. Stromal function was defective at 2 weeks pre BMT and at 3 months post BMT, but returned to normal at 8 and 16 months post BMT. At 21 months post BMT, stromal fibroblasts and endothelial cells were shown to be of recipient origin, and macrophages and T cells were of donor origin. We present here evidence in a case of severe AA for defective stromal function before BMT and delayed normalization of function after BMT. This correlated with engraftment of donor macrophages and T cells, but not fibroblasts and endothelial cells.     

Effects of low dose rate irradiation on human marrow hematopoietic and microenvironmental cells: sparing effect upon survival of stromal and leukemic cells

The effects of different dose rates of in vitro irradiation on the proliferative capacity of marrow stromal, hematopoietic and leukemic colony-forming cells (CFC) are described. Marrow cell suspensions, HL-60 cells and trypsin-dispersed fibroblasts were irradiated at 5 or 45 cGy/min and then assayed for CFC. Irradiation at low (5 cGy/min) compared to high (45 cGy/min) dose rate showed a significant difference in survival of stromal and of HL-60 cells, but not of hematopoietic progenitors: the respective D0 values were 170 and 120 (p = 0.003) for marrow fibroblastic progenitors (CFU-F); 145 and 110 (p = 0.005) for passaged marrow fibroblasts (CFU-F); 170 and 140 (p = 0.045) for HL-60 cells; 85 and 85 for multipotential CFC (CFU-mix); 125 and 120 for erythroid progenitors (BFU-E); and 115 and 120 for granulomonopoietic progenitors (CFU-GM) (p = 0.5 for hematopoietic clonogenic cells). Marrow suspensions did not establish confluent stromal layers in long-term marrow cultures following irradiation with 600 cGy at 45 cGy/min, whereas after 840 cGy at 5 cGy/min confluent stromal layers were obtained. This indicates that low dose rate-sparing effect applies to all stromal cell progenitors. Confluent stromal layers derived from progenitors surviving irradiation sustained hematopoiesis as well as controls when co-cultured with fresh hematopoietic cells. Adherent layers in long-term marrow cultures irradiated after establishment with doses less than or equal to 1500 cGy at 5 or 45 cGy/min also showed normal hematopoietic supportive function when co-cultured with freshly isolated hematopoietic cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stromal-mediated down-regulation of CD13 in bone marrow cells originating from acute myeloid leukemia patients

The metallopeptidase CD13 is expressed on normal myeloid cells of monocytic and granulocytic origin and on the surface of leukemic blasts in most acute myeloid leukemias (AML). To study the mechanisms regulating lineage restricted CD13 expression in AML we determined normalised CD13 mRNA levels in bone marrow cells and peripheral blood cells of 27 AML patients. Cells of bone marrow origin had lower levels of normalised CD13 mRNA than cells of peripheral blood origin, even though fluorescence intensity and fraction of cells expressing CD13 on the surface was unchanged. In particular, AML patients with very low levels of normalised CD13 mRNA in bone marrow cells showed an increase in CD13 mRNA expression in peripheral blood. To evaluate the effects of bone marrow microenvironment on CD13 mRNA expression, we cultured leukemic myeloid cells with and without murine stromal cells. Bone marrow cells with high and low CD13 surface expression that entered the stromal layers all down-regulated CD13 mRNA expression as compared to cells in suspension above. For peripheral blood cells within stromal layers, CD13 mRNA expression was diminished in only 3 out of 6 cases. The ambiguous effect of stromal cells on peripheral blood cells may illustrate a differentiation-dependent response towards stroma. We determined the polyadenylation status of CD13 mRNA for 9 bone marrow aspirates and 7 peripheral blood samples. Polyadenylation was diminished in bone marrow cells from AML patients with low levels of normalised CD13 mRNA, raising the possibility of involvement of mRNA instability in regulation of CD13 mRNA expression in this subgroup of patients.     

Laboratory control in predicting clinical efficacy of T cell-depletion procedures used for prevention of graft-versus-host disease: importance of limiting dilution analysis

In an attempt to assess the usefulness of partial elimination of T lymphocytes from histocompatible donor bone marrow as a sole method of graft-versus-host disease prophylaxis in patients undergoing bone marrow transplantation, we compared in vitro and clinically the efficacy of two depletion protocols, each resulting in a different degree of T cell reduction. The protocols were based on complement-dependent T cell lysis induced either by one (T10B9) or two (T10B9 and T12A10) monoclonal antibodies, contributing respectively to 95% and 99% depletion of T cells defined functionally by limiting dilution analysis. Phenotypic analysis was unsuitable for detecting differences in the efficiency of the two depletion modalities due to very low numbers of residual OKT3-positive cells generally present. Of the 34 patients with advanced leukemias transplanted with marrow from HLA-matched sibling donors, 26 (ages 15-52) received two-antibody depleted grafts (group I) with subsequent incidence of severe acute graft-versus-host disease of 8% (in two of 24 engrafted). The T cell dose for two patients of this group whose grafts were directly evaluated by limiting dilution analysis was less than 2 x 10(5)/kg and presumably did not exceed 3.2 x 10(5)/kg for others, based on the depletion efficiency of the protocol estimated in additional small marrow samples. The remaining eight patients (ages 8-55) received one-antibody depleted grafts (group II) with 5-18 x 10(5) T cells/kg defined functionally in five grafts. Severe acute graft-versus-host disease (grade 3-4) developed in all seven engrafted subjects. Although with phenotypic analysis several grafts in this group revealed no residual T lymphocytes, they apparently carried doses of donor T cells not tolerable in a HLA-identical host unprotected by additional immunosuppression. Careful evaluation by functional T cell analysis should be considered in choosing a depletion protocol as a method for reducing the risk of graft-versus-host disease in allogeneic bone marrow transplantation.     

Donor origin of multipotent adult progenitor cells in radiation chimeras

Multipotent adult progenitor cells (MAPCs) are bone marrow-derived stem cells that have extensive in vitro expansion capacity and can differentiate in vivo and in vitro into tissue cells of all 3 germinal layers: ectoderm, mesoderm, and endoderm. The origin of MAPCs within bone marrow is unknown. MAPCs are believed to be derived from the bone marrow stroma compartment as they are isolated within the adherent cell component. Numerous studies of bone marrow chimeras in the human and the mouse point to a host origin of bone marrow stromal cells. Mesenchymal stem cells (MSCs), which coexist with stromal cells, have also been proven to be of host origin after allogeneic bone marrow transplantation in numerous studies. We report here that following syngeneic bone marrow transplants into lethally irradiated C57BL6 mice, MAPCs are of donor origin.     

Granulopoiesis-supporting effects of marrow stromal cells in continuous culture from patients with primary myelofibrosis

The granulopoiesis-supporting effects of marrow adherent cells from seven patients with primary myelofibrosis (PMF) were studied by a continuous allogeneic co-culture system in which the survival of donor granulocyte-macrophage colony-forming cells (CFU-GM) depends upon the supporting ability of adherent cells. Marrow adherent cells from all these seven patients were able to sustain the same number of CFU-GM as those from control subjects. Cytochemical studies showed that colonies grown from cells sustained on fibrous marrow adherent cell layers were predominantly neutrophilic, as were those in control cultures, although many eosinophil colonies grew from patients' bone marrow. These results indicate that marrow stromal cells from PMF patients function normally in their ability to support granulopoiesis.     

Radiobiological properties of the human hematopoietic microenvironment: contrasting sensitivities of proliferative capacity and hematopoietic function to in vitro irradiation

We describe the effects of in vitro irradiation on the proliferative capacity and hematopoietic supportive function of human marrow stromal cells. To assess the effects on the proliferative capacity of stromal progenitors and differentiated fibroblasts, marrow cell suspensions and trypsin-dispersed marrow fibroblasts were treated with a single dose of gamma radiation at 100 rad/min. Fibroblastic progenitors (CFU-F) showed an exponential decrease in colony formation with increasing doses of irradiation, with a Do slightly higher than that of granulomonopoietic progenitors (CFU-GM); Do values for CFU-F and CFU-GM were 130 and 115, respectively. However, although the CFU-F survival curve exhibited a shoulder (n = 1.3), the CFU-GM curve did not (n = 1.0), indicating that only fibroblastic progenitors have the potential to repair irradiation- induced damage. Passaged marrow fibroblast colony-forming cells also showed a shouldered exponential survival curve with a Do of 110 and n value of 1.4. Marrow stromal progenitors giving rise to adherent layers in long-term marrow cultures also demonstrated a highly radiosensitive proliferative capacity. Stromal layers derived from irradiated marrow suspensions failed to establish adherent layers after relatively low doses of irradiation (over 240 rad) in a dose-response manner. To assess any functional damage in stromal progenitors surviving irradiation, stromal layers derived from marrow suspensions irradiated up to 240 rad were cocultured with freshly isolated autologous hematopoietic cells and assayed for their capacity to support prolonged CFU-GM production. Confluent stromal layers derived from irradiated marrow suspensions sustained CFU-GM production as well as controls. To study the effects of irradiation on the hematopoietic supportive capacity of established marrow-derived stromal layers, 4 to 6-week-old adherent layers were irradiated as described and cocultured with autologous marrow cells enriched for colony-forming cells. Stromal layers irradiated up to 1,320 rad sustained prolonged CFU-GM production, indicating that the hematopoietic supportive function remained intact at this dose of irradiation. In conclusion, we demonstrated that the proliferative capacity of human marrow stromal progenitors, as well as that of their differentiated descendants, is quite sensitive to in vitro radiation, while the hematopoietic supportive function of differentiated stromal cells is relatively resistant to the effects of radiation.     

A Stro-1(+) human universal stromal feeder layer to expand/maintain human bone marrow hematopoietic stem/progenitor cells in a serum-free culture system

OBJECTIVE: To compare the ability of allogeneic versus autologous purified human Stro-1(+) mesenchymal stem cell (MSC) populations from different human donors to support the ex vivo expansion and maintenance of human hematopoietic stem/progenitor cells (HSCs). Furthermore, we compared the results obtained with MSC as a feeder layer to traditional allogeneic stromal layers grown in long-term bone marrow culture media (LT-ST). METHODS: Adult human bone marrow CD34(+)-enriched cells were cultured in serum-free medium for 2 to 3 weeks over the respective MSC-irradiated feeder layers or over traditional allogeneic LT- ST stromal layers in the presence of stem cell factor, basic fibroblast growth factor, leukemia inhibitory factor, and Flt-3 and analyzed every 2 to 4 days for expansion, phenotype, and clonogenic ability. RESULTS: There was a progressive expansion of total numbers of cells in all the experimental groups; however, allogeneic MSCs were more efficient at expanding CD34(+)CD38(-) cells and showed a higher clonogenic potential than both allogeneic LT-ST and autologous MSCs. The differentiative potential of cells cultured on both MSC and LT-ST was primarily shifted toward myeloid lineage; however, only MSCs were able to maintain/expand a CD7(+) population with lymphocytic potential. Importantly, transplantation into preimmune fetal sheep demonstrated that the HSCs cultured over MSCs retained their engraftment capability. CONCLUSION: These results indicate that purified Stro-1(+) MSCs may be used as a universal and reproducible stromal feeder layer to efficiently expand and maintain human bone marrow HSCs ex vivo.     

In vitro functions of stromal cells from human and mouse bone marrow

Human fibroblastoid cell strains obtained from primary bone marrow cultures and continuous stromal cell lines recently derived from mouse bone marrow were studied. The incidence of fibroblastoid precursors (CFU-F) varied considerably in human bone marrow samples, and no differences could be detected between marrows from a group of myelodysplastic patients (age range 70-82 years) and groups of age-matched controls or younger individuals. A lack of direct correlation between initial clonogenicity and ultimate capacity of fibroblastoid cells to grow in continuous culture was observed in both the normal and the myelodysplastic groups. Despite the apparently normal clonogenicity of CFU-F in patients with myelodysplastic syndromes, some of these marrows failed to grow when subcultured. Normal fibroblastoid cells at 10(4) per culture exhibited myelopoietic activities when cocultured with fresh bone marrow cells. At higher concentrations, these cells inhibited myeloid colony formation. Fibroblastoid cells from only one out of four myelodysplastic patients examined exhibited comparable inhibitory activity. The specificity of the inhibitor(s) was demonstrated by the lack of effect of fibroblastoid cells from normal human bone marrow on the clonogenicity of mouse erythroleukemia cells. Moreover, human foreskin fibroblasts were devoid of such inhibitory activity. These functions of cultured stromal cells may correlate with some of their activities in the bone marrow microenvironment.     

Characterization of cultured stromal layers derived from fetal and adult hemopoietic tissues

Cultured stromal layers grown from fetal and adult hemopoietic tissues reproduce, in vitro, features that typify their in vivo counterparts. Thus, fetal liver (FL) cultures consist predominantly of macrophages, and fetal bone marrow (FBM) cultures fail to form the fat cells that are characteristic of adult bone marrow (ABM) cells grown in the presence of methylprednisolone. Further investigation showed that the lack of fat cell formation in FBM cultures was not due to absence of steroid receptors because cells from the fibroblast component of FBM and ABM possess similar numbers of receptors of similar affinities. Phenotypically, the macrophages that occur in FL, FBM, and ABM stromal cultures are RFD7+, 3.9+ UCHM1, which identifies them as mature tissue macrophages. Also, they express HLA-DR, indicating an activated state and a potential for participating in hemopoietic cell regulation, at least in vitro. Functionally, stromal layers grown from adult bone marrow provide feeder layers for blast colony-forming cells (Bl-CFC). These Bl-CFC adhere to ABM stromal cells but not to FBM or stromal cells.     

Origin of Human Bone Marrow Fibroblasts

We investigated the origin of bone marrow fibroblasts in three bone marrow transplant recipients with aplastic anaemia and leukaemia who received grafts from HLA-identical siblings of opposite sex. The patients were conditioned for transplantation with high doses of cytotoxic drugs and 300–1000 rads total body irradiation. After transplantation, bone marrow cells wrere cultured in T flasks for 3 weeks and the adherent cells were then trypsinized and passaged weekly. After several passages the cells had the typical morphology and growth pattern of fibroblasts. Metaphases from these cells were all of recipient sex type. In contrast, haematopoietic cells and lymphocytes obtained at the same time were of donor sex type. Our findings indicate that the human bone marrow fibroblast is not derived from a precursor common to haematopoietic cells or lymphocytes. The bone marrow fibroblast appears to be a mesenchymal cell, unrelated to haematopoietic stem cells, which is capable of in vitro proliferation after as much as 1000 rads of total body irradiation.     

The effect of bone marrow transplantation on the osteoblastic differentiation of human bone marrow stromal cells.

Osteoporosis is a serious and relatively common complication of transplantation procedures. However, little is known about the exact mechanism or severity of osteoporosis complicated by bone marrow transplantation (BMT). We conducted both ex vivo and clinical studies to identify the mechanism and extent of bone loss after BMT. In a prospective clinical study, we intended to identify the changes in bone turnover markers and bone mineral density (BMD) after BMT. During a 1-yr follow-up, BMD was measured before BMT and 1 yr after BMT in 67 patients undergoing BMT. Biochemical markers of bone formation and resorption were measured in all patients at short-term intervals during the yearlong follow-up. In ex vivo study, we cultured human bone marrow cells of normal controls and BMT recipients in osteogenic medium and compared their osteogenic potential. Using a DNA fingerprinting method, we also investigated the origin of bone marrow stromal cells that were harvested 3-4 wk after BMT. In a clinical study of 67 patients undergoing BMT, the mean serum carboxy-terminal cross-linked telopeptide of type I collagen increased progressively until 4 wk after BMT. Thereafter, it began to decrease and reached basal values after 1 yr. Serum osteocalcin decreased progressively until 3 wk after BMT and reached basal values after 3 months. One year after BMT, lumbar spine BMD had decreased by 3.3% (P < 0.05), and total proximal femoral BMD had decreased by 8.9% (P < 0.001). For the ex vivo study, bone marrow was obtained from healthy donors (n = 7) and transplant recipients (n = 7). Then, mononuclear cells including marrow stromal cells were isolated and cultured to osteoblastic lineage. Alkaline phosphatase activities of each group were measured by the time course of secondary culture, and the mineralizing potentials were compared between the two groups. Cells cultured in our system showed characteristics of osteoblast-like cells differentiated from marrow stromal cells. They were initially in a fibroblastic-like spindle shape and became cuboidal with the formation of nodules that were later confluent. The cells were stained to both alkaline phosphatase histochemistry and Von Kossa histochemistry, demonstrating that these cells were of osteoblastic lineage differentiating from marrow stromal cells. The mean time required for the near-confluence in the primary culture was 15 and 22.9 d in healthy donors and transplant recipients, respectively (P = 0.003). Alkaline phosphatase activity was significantly lower in the bone marrow recipients than in the healthy donors at d 7 and 10 of the secondary cultures. The period at which peak activity of alkaline phosphatase was reached was also delayed in the osteoblasts derived from BMT recipient bone marrow compared with those of healthy donors. Using Von Kossa histochemistry, much more mineralization was observed in osteoblasts of healthy donors than those of BMT recipients. After BMT, although the peripheral mononuclear cells in the recipients were of donor origin, the bone marrow stromal cells were of recipient origin according to the PCR analysis using YNZ 22 mini-satellite probe. In conclusion, the differentiation of bone marrow stromal cells into osteoblasts was impaired after BMT, and this might contribute to post-BMT bone loss.     

Selection of two human bone marrow stromal cell subpopulations with different effects on the maintenance and differentiation of myeloid progenitor cells

The simple selection of two human bone marrow stromal cell populations is described. Adherent stromal cell layers were formed in primary cultures of low-density marrow cells. At time of confluence, persistent nonadherent cells were collected and transferred to new culture flasks, where they formed a secondary stromal layer. These primary and secondary stromal layers differed in their ability to support myelopoiesis, as tested by progenitor cell production after inoculation with fresh bone marrow cells. In the presence of primary stromal layers the number of granulocyte-macrophage colony-forming cells (GM-CFC) decreased gradually, but in the presence of secondary layers production of GM-CFC was evident during the first 3 weeks. The regulation of the two stromal types on hemopoietic cell proliferation and differentiation was investigated by determining the kinetics of the transitions within the differentiation sequence of three myeloid progenitor cells. Pre-CFC, day-14 CFC, and day-7 CFC were fractionated by cell sorting on the basis of forward light scatter and cocultured with the two stromal layer types. It was found that the decrease in CFC numbers in the presence of primary stromal layers could be explained by the stimulation of hemopoietic cells into rapid differentiation with loss of proliferative capacity at an early stage of culture. Secondary layers appeared to promote survival and self-renewal of later types of progenitor cells and to trigger more immature cells to proliferate and differentiate at a later time of culture.     

Interferon-alpha alters the distribution of CFU-GM between the adherent and nonadherent compartments in long-term cultures of chronic myeloid leukemia marrow

We studied the effect of recombinant interferon-alpha 2a (IFN alpha) on the interaction between stromal cells and granulocyte-macrophage colony-forming units (CFU-GM) from the marrow of normal individuals and chronic myeloid leukemia (CML) patients in chronic phase in long-term bone marrow cultures using preformed stromal layers. These stromal layers were established with marrow cells from normal allogeneic donors and grown to confluence in the presence or absence of IFN alpha at low concentration (100 U/ml). The number of CML CFU-GM localized within IFN alpha-treated stromal layers was significantly greater than the corresponding number localized within control stromal layers. Conversely, the distribution of normal CFU-GM between the adherent and nonadherent compartments was unaffected by IFN alpha treatment of the stromal layer. Preincubation of CML marrow cells with IFN alpha did not alter this distribution, so the observed effect of IFN alpha must be due to a primary action on stromal layers. Thus, in addition to its well known antiproliferative effect, IFN alpha enhances the capacity of marrow stromal cells to bind and/or retain CML progenitor cells, and the resulting restoration of normal regulatory control may be the basis for the selectivity of IFN alpha in CML.     

The origin of stromal cells in patients treated by bone marrow transplantation

The source of stromal cells following bone marrow transplantation has been investigated by culturing marrow cells obtained from patients who have a graft cells from a donor of the opposite sex. Two culture systems have been used for these studies. The first supports the proliferation of fibroblast colony-forming cells (F-CFC) and the formation of confluent layers of fibroblastoid cells; the second (the long-term bone marrow culture system) results in the formation of a complex and heterogeneous layer of adherent cells composed of fibroblasts, fat cells, endothelial cells, macrophages and 'blanket' cells. A survey of the work done using these culture systems shows that, although the issue of the transplantability of stromal cells remains controversial, it now seems reasonably certain that repopulation of the fibroblast component by donor cells is rare. In contrast, one study has shown that endothelial-like cells can engraft in transplant recipients. Another study has demonstrated a donor origin for the macrophages found in long-term cultures of marrow from transplanted patients. This finding might have been predicted because macrophages are derived from haemopoietic stem cells.     

Assessment of 8-methoxypsoralen and ultraviolet a light effects on human stroma generation and function

Photopheresis or extracorporeal photochemotherapy (ECP) is a new immunomodulatory therapy in which a patient's leukocytes are exposed extracorporeally to 8-methoxypsoralen (8-MOP) and ultraviolet A (UVA) light. Although it is used for the treatment of cutaneous T cell lymphoma, graft-versus-host disease, and several autoimmune diseases, with efficacy and safety reported in almost all studies, the mechanisms by which ECP exerts its beneficial effects are still unclear. As cellular targets of this procedure are numerous, we investigated the effects of 8-MOP and UVA light on stromal precursors and mature stromal layers. Human bone marrow stromal cell layers were established in long-term bone marrow culture medium from normal marrow mononuclear cells. Normal marrow mononuclear cells were incubated with 8-MOP and/or exposed to UVA light (PUVA treatment) before culturing. A control without 8-MOP and UVA was also included in the study. Apoptosis induction was evaluated using annexin V following 7 days after PUVA. After 4-6 weeks of culture, stromal layers were examined under a phase-contrast microscope to identify structural differences between PUVA-treated and control stroma. To determine whether PUVA treatment affected stromal regulation of adherent hematopoietic cell survival, mature stromal layers, incubated with 8-MOP and exposed to UVA light, were cocultured with nonadherent mononuclear cells from normal marrow. After 24 h, the percentage of apoptotic hematopoietic cell precursors was quantified by flow cytometry. This study provides evidences that the in vitro exposure of human stromal cell precursors to UVA light, in the presence of 8-MOP, inhibits stromal layer generation by inducing apoptosis, as evidenced by annexin V staining following 7 days of culture. Here, we show an additional cell target for this psoralen following UVA irradiation. However, in a second set of experiments, PUVA treatment did not affect the stromal capacity to support hematopoiesis in culture. Our results can contribute to a better definition of ECP mechanisms of action for future development of experimental designs and clinical applications of this intriguing procedure.