Isolation and culture of endothelial cells from human bone marrow

Summary : Adhesive interactions between haemopoietic progenitor cells and bone marrow sinusoidal endothelium are potentially important in the homing of these cells back to re-establish haemopoiesis following stem cell transplantation. A simple method for the isolation and culture of human bone marrow endothelial cells is described using bone marrow aspirates obtained from patients undergoing bone marrow harvests for autologous or syngeneic bone marrow transplantation. The method is based on the selective binding of the lectin Ulex europaeus agglutinin-1 (UEA-1) to endothelial cells. Magnetic Dynabeads coupled with UEA-1 were incubated with single cell suspensions of bone marrow following red cell lysis, and bound cells were isolated with a magnet. The isolated cells demonstrated positive immunofluorescence staining for von Willebrand factor. Cells were plated onto tissue culture flasks coated with extracellular matrix derived from human umbilical vein endothelial cells in an endothelial serum-free medium together with 5% fetal calf serum for 24h. Cells were then cultured in endothelial serum-free growth medium supplemented with 5% fetal calf serum, endothelial cell growth supplemented with 5% fetal calf serum, endothlial cell growth supplement and heparin. After 2–4 weeks in culture, two morphologically different cell populations can be identified. One has a polygonal spindle-shaped morphology with a rapid growth rat, the other a rounded morphology and a slow growth rate. Both population have a vasiculated cytoplasm. Positive immunostaining of the cells was demonstrated with a number of endothelial cell markers including von Willebrand factor, and antibodies to ICAM-1, VCAM-1, E-wlectin, CD31 and BMA120. Weibel-Palade bodies were observed by electron microscopy.
Culture of these cells will allow detailed in vitro studies of adhesion mechanisms in the homing of haemopoietic progenitor cells.     

Prolonged ex vivo culture of human bone marrow mesenchymal stem cells influences their supportive activity toward NOD/SCID-repopulating cells and committed progenitor cells of B lymphoid and myeloid lineages

Background

Bone marrow mesenchymal stem cells support proliferation and differentiation of hematopoietic progenitor cells in vitro. Since these cells constitute a rare subset of bone marrow cells, mesenchymal stem cell preparations for clinical purposes require a preparative step of ex vivo multiplication. The aim of our study was to analyze the influence of culture duration on mesenchymal stem cell supportive activity.

Design and Methods

Mesenchymal stem cells were expanded for up to ten passages. These cells and CD34+ cells were seeded in cytokine-free co-cultures after which the phenotype, clonogenic capacity and in vivo repopulating activity of harvested hematopoietic cells were assessed.

Results

Early passage mesenchymal stem cells supported hematopoietic progenitor cell expansion and differentiation toward both B lymphoid and myeloid lineages. Late passage mesenchymal stem cells did not support hematopoietic progenitor cell and myeloid cell outgrowth but maintained B-cell supportive ability. In vitro maintenance of NOD/SCID mouse repopulating cells cultured for 1 week in contact with mesenchymal stem cells was effective until the fourth passage of the mesenchymal cells and declined thereafter. The levels of engraftment of CD34⁺ cells in NOD/SCID mice was higher when these cells were co-injected with early passage mesenchymal stem cells; however mesenchymal cells expanded beyond nine passages were ineffective in promoting CD34⁺ cell engraftment. Non-contact cultures indicated that mesenchymal stem cell supportive activity involved diffusible factors. Among these, interleukins 6 and 8 contributed to the supportive activity of early passage mesenchymal stem cells but not to those of late passage cells. The phenotype, as well as fat, bone and cartilage differentiation capacity, of mesenchymal stem cells did not change during their culture.

Conclusions

Extended culture of mesenchymal stem cells alters the ability of these cells to support hematopoietic progenitor cells without causing concomitant changes in their phenotype or differentiation capacity.     

Long-term culture of human bone marrow cells.

A method has been described for the long-term culture of human bone marrow cells in liquid medium. Hematopoiesis, as measured by the production of granulocytic-macrophage progenitor cells (CFUc), continued for at least 20 weeks and was dependent upon the presence of a marrow-derived adherent layer of cells. As in the case of murine marrow liquid cultures, the adherent layer consisted of mononuclear phagocytic cells, endothelial cells, and lipid-laden adipocytes, the latter being essential for long-term hematopoiesis. Optimal growth conditions included McCoy's medium supplemented with fetal bovine serum, horse serum, and hydrocortisone and incubation at 33 degrees C. Horse serum in conjunction with hydrocortisone appeared essential for the growth of adipocytes.     

犬骨髓成年多能祖细胞诱导分化血管内皮细胞的实验研究

目的内皮细胞移植对损伤组织的修复治疗至关重要,本研究旨在探讨骨髓成年多能干细胞(MAPCs)体内外诱导分化血管内皮细胞的可行性.方法采用Percoll密度梯度法分离培养MAPCs.应用10 ng/ml血管内皮细胞生长因子(VEGF)对骨髓MAPCs进行体外诱导分化2～3周,使其定向分化成为血管内皮细胞.采用细胞形态学、细胞免疫组化以确定诱导分化的效果.将标记BrdU的MAPCs自体移植于犬心肌内,观察局部微环境对于骨髓MAPCs的分化能力.结果应用10 ng/ml VEGF孵育骨髓MAPCs 2～3周,可见MAPCs分化为血管内皮细胞:细胞形态呈鹅卵石样;形成血管样结构;细胞vWF免疫染色阳性.移植于心肌内的MAPCs在体内形成新生血管,血管内皮BrdU染色与vWF染色均阳性.结论骨髓MAPCs可在体外VEGF诱导下或在体内微环境作用下分化为成熟血管内皮细胞.骨髓MAPCs可为损伤组织的移植修复治疗提供内皮细胞资源.     

成人骨髓源内皮祖细胞的体外分离培养及鉴定

目的探讨成人骨髓源内皮祖细胞（EPCs）体外分离培养的可行性。方法抽取成年男性骨髓,体外全骨髓培养,传代后采用免疫微珠分选方法收集CD南细胞,EGM—MV2条件培养基诱导培养EPCs,观察细胞形态、生长情况;采用流式细胞技术检测分选细胞纯度,免疫荧光法检测EPCs特殊分子标志物CD34,CD133和VE-cadherin表达,透射电子显微镜观察分选细胞超微结构,UEA-1和Dil-ac-LDL双染色法检测分选细胞的吞噬功能。结果分选后细胞培养第3天出现集落样生长,集落边缘细胞形态伸展呈梭形或多边形,传代后呈现串珠样排列;培养至5～6d,细胞连接成大片条索状结构;CD34^＋、CD133^＋细胞百分率分别为24．13％、93．29％,其表面特异性表达CD133、CD34、VE-cadherin,具有EPCs形态特征,能吞噬Dil-ac-LDL并结合UEA-1。结论成人骨髓来源的EPCs经体外培养后形态、增殖率、生存能力、表面标志表达、功能等均较为稳定,可作为心血管组织工程种子细胞或用于干细胞治疗。     

Ex vivo culture rescues hematopoietic stem cells with long-term repopulating capacity following harvest from lethally irradiated mice

OBJECTIVE: High-dose ionizing radiation can cause lethal myeloablation in exposed individuals. We examined whether ex vivo culture could rescue hematopoietic stem cells with repopulating capacity following harvest from lethally irradiated animals. METHODS: We exposed B6.SJL mice to 1050 cGy, harvested their irradiated bone marrow (BM), and examined whether ex vivo culture of the irradiated BM mononuclear cells (MNC) with porcine microvascular endothelial cells (PMVEC) or cytokines alone could rescue hematopoietic cells with in vitro colony-forming activity, in vivo radioprotective capacity, and long-term repopulating potential. RESULTS: PMVEC coculture supported the recovery of fourfold and 80-fold greater numbers of total cells and colony-forming cells (CFC) compared to cyokines alone following 1050 cGy irradiation. All control mice irradiated with 1050 cGy died by day 30, as did mice transplanted with 1050 cGy-irradiated BM MNC. In contrast, transplantation of 1050 cGy-irradiated/PMVEC-cultured BM was fully radioprotective in 12 of 16 recipient mice (75%) exposed to 1050 cGy. Six of the 12 CD45.2+ mice (50%) transplanted with 1050 cGy-irradiated/PMVEC-cultured cells showed long-term (>6 months) multilineage repopulation derived from irradiated donor CD45.1+ cells. Surprisingly, transplantation of identical doses of 1050 cGy-irradiated/cytokine-cultured BM was also radioprotective in 50% of irradiated recipient mice and 50% of these mice demonstrated donor-derived repopulation. CONCLUSIONS: Fully functional BM stem and progenitor cells can be rescued following harvest from lethally irradiated animals via ex vivo culture with PMVEC or cytokines alone. This method can serve as a model for the rapid ex vivo rescue and transplantation of autologous BM progenitors in the treatment of victims of radiation injury.     

Ex vivo expansion of autologous bone marrow CD34(+) cells with porcine microvascular endothelial cells results in a graft capable of rescuing lethally irradiated baboons.

Hematopoietic stem cell (HSC) self-renewal in vitro has been reported to result in a diminished proliferative capacity or acquisition of a homing defect that might compromise marrow repopulation. Our group has demonstrated that human HSC expanded ex vivo in the presence of porcine microvascular endothelial cells (PMVEC) retain the capacity to competitively repopulate human bone fragments implanted in severe combined immunodeficiency (SCID) mice. To further test the marrow repopulating capacity of expanded stem cells, our laboratory has established a myeloablative, fractionated total body irradiation conditioning protocol for autologous marrow transplantation in baboons. A control animal, which received no transplant, as well as two animals, which received a suboptimal number of marrow mononuclear cells, died 37, 43, and 59 days postirradiation, respectively. Immunomagnetically selected CD34(+) marrow cells from two baboons were placed in PMVEC coculture with exogenous human cytokines. After 10 days of expansion, the grafts represented a 14-fold to 22-fold increase in cell number, a 4-fold to 5-fold expansion of CD34(+) cells, a 3-fold to 4-fold increase of colony-forming unit-granulocyte-macrophage (CFU-GM), and a 12-fold to 17-fold increase of cobblestone area-forming cells (CAFC) over input. Both baboons became transfusion independent by day 23 posttransplant and achieved absolute neutrophil count (ANC) >500/microL by day 25 +/- 1 and platelets >20,000/microL by day 29 +/- 2. This hematopoietic recovery was delayed in comparison to two animals that received either a graft consisting of freshly isolated, unexpanded CD34(+) cells or 175 x 10(6)/kg unfractionated marrow mononuclear cells. Analysis of the proliferative status of cells in PMVEC expansion cultures demonstrated that by 10 days, 99.8% of CD34(+) cells present in the cultures had undergone cycling, and that the population of cells expressing a CD34(+) CD38(-) phenotype in the cultures was also the result of active cell division. These data indicate that isolated bone marrow CD34(+) cells may undergo cell division during ex vivo expansion in the presence of endothelial cells to provide a graft capable of rescuing a myeloablated autologous host.     

Soluble factors elaborated by human brain endothelial cells induce the concomitant expansion of purified human BM CD34+CD38- cells and SCID-repopulating cells

The CD34(+)CD38- phenotype identifies a population in the bone marrow that is enriched in the steady state for hematopoietic stem cells (HSCs). Following ex vivo culture of CD34(+) cells, HSC content is difficult to measure since committed CD34(+)CD38+ progenitors down-regulate CD38 surface expression during culture. In this study, we sought to define the phenotype of human HSCs following ex vivo culture under conditions that support the expansion of human cells capable of repopulating non-obese diabetic/severe combined immunodeficiency (SCID)-repopulating cells (SRCs). Contact coculture of fluorescence-activated cell sorter (FACS)-sorted bone marrow (BM) CD34(+)CD38- cells with human brain endothelial cells (HUBECs) supported a 4.4-fold increase in CD34(+)CD38- cells with a concordant 3.6-fold increase in SRCs over 7 days. Noncontact HUBEC cultures and the addition of thrombopoietin, stem cell factor (SCF), and macrophage colony stimulating factor I receptor (Fms)-like tyrosine kinase 3 (Flt-3) ligand supported further increases in CD34(+)CD38- cells (6.4-fold and 13.1-fold), which correlated with significant increases in SRC activity. Moreover, cell-sorting studies performed on HUBEC-cultured populations demonstrated that SRCs were significantly enriched within the CD34(+)CD38- subset compared with the CD34(-)CD38- population after culture. These results indicate that human HSCs can be identified and characterized by phenotype following expansion culture. These studies also demonstrate that HUBEC-elaborated soluble factors mediate a unique and potent expansion of human HSCs.     

Sustained, retransplantable, multilineage engraftment of highly purified adult human bone marrow stem cells in vivo

Data from many laboratory and clinical investigations indicate that CD34+ cells comprise approximately 1% of human bone marrow (BM) mononuclear cells, including the progenitor cells of all the lymphohematopoietic lineages and lymphohematopoietic stem cells (stem cells). Because stem cells are an important but rare cell type in the CD34+ cell population, investigators have subdivided the CD34+ cell population to further enrich stem cells. The CD34+/CD38- cell subset comprises less than 10% of human CD34+ adult BM cells (equivalent to < 0.1% of marrow mononuclear cells), lacks lineage (lin) antigens, contains cells with in vitro replating capacity, and is predicted to be highly enriched for stem cells. The present investigation tested whether the CD34+/CD38- subset of adult human marrow generates human hematopoiesis after transfer to preimmune fetal sheep. CD34+/ CD38- cells purified from marrow using immunomagnetic microspheres or fluorescence-activated cell sorting generated easily detectable, long- term, multilineage human hematopoiesis in the human-fetal sheep in vivo model. In contrast, transfer of CD34+/CD38+ cells to preimmune fetal sheep generated only short-term human hematopoiesis, possibly suggesting that the CD34+/CD38+ cell population contains relatively early multipotent hematopoletic progenitor cells, but not stem cells. This work extends the prior in vitro evidence that the earliest cells in fetal and adult human marrow lack CD38 expression. In summary, the CD34+/ CD38- cell population has a high capacity for long-term multilineage hematopoietic engraftment, suggesting the presence of stem cells in this minor adult human marrow cell subset.     

Resveratrol increases the bone marrow hematopoietic stem and progenitor cell capacity

Resveratrol is a plant‐derived polyphenol that has shown protective effects against many disorders including, several types of cancers and other age‐associated diseases as well as blood disorders in cultured cells and/or animal models. However, whether resveratrol has any impact specifically on normal blood stem cells remains unknown. Here, we show that a 3‐week treatment of resveratrol increases the frequency and total numbers of normal bone marrow hematopoietic stem cells (HSC) without any impact on their competitive repopulation capacity. In addition, we show that resveratrol enhances the bone marrow multipotent progenitor capacity in vivo. These results have therapeutic value for disorders of hematopoietic stem and progenitor cells (HSPC) as well as for bone marrow transplantation settings. Am. J. Hematol. 89:E235–E238, 2014. © 2014 Wiley Periodicals, Inc.     

Growth stimulation of human bone marrow cells in agar culture by vascular cells

Human vascular cells are capable of stimulating granulopoiesis in agar culture of human bone marrow cells. This effect was obtained by including vein fragments in the culture or by using endothelial cells separated from the vein of human umbilical cords as feeder cells. Furthermore, the stimulatory capacity of conditioned medium obtained from cord veins was found to be highly active in comparison to that obtained from peripheral leukocytes. Endothelial cells within the bond marrow cavity are suggested as a local source of factors regulating granulopoiesis in humans in addition to the monocyte.     

Characterization of prothymocytes with cloning capacity in human bone marrow

The identity of human bone marrow (BM)-derived T cell precursors with colony forming capacity has led to controversy because of contamination with mature clonogenic T cells. We achieved 2 Log elimination of mature T cells from BM using a cocktail of monoclonal antibodies: CD2, CD3, CD4, CD6, and CD8 followed by two successive baby rabbit C' treatment. T cell depleted BM can generate colonies of CD2+, CD3+, Ti+, mostly CD4+, in the presence of PHA, rIL2, and a prothymocyte differentiating activity derived from phytohemagglutinin (PHA) induced mononuclear cells. These precursors could be enriched three- to sixfold by percoll gradient centrifugation and then significantly bypass the number of contaminant mature T cells as shown by limiting dilution analysis. Colony generation by marrow precursors was inhibited by the addition of autologous T cells. This inhibition was mostly caused by the T8+ subset. CFU-TL growth was dramatically inhibited by eliminating CD7+ cells suggesting their positivity for this surface marker. These precursors needed major histocompatibility complex (MHC) II-positive cells for optimal growth but lack DR themselves.     

Ex vivo hemodialysis culture of microbial and mammalian cells.

A small hemodialysis culture unit was developed which can be attached to an arterial-venous shunt and worn by an animal for days. The unit consists of a blood channel separated by a membrane from a dialysate chamber in which microbial or mammalian cells can be cultured. Bacterial multiplication proceeded first exponentially at the maximal rate and then arithmetically at a lesser, dialysis-limited rate. In a survey of 16 pathogenic microorganisms and five types of mammalian cell, results indicated that most of the aerobes grew well, but none of the obligate anaerobes grew at all. The separation of the culture from cellular and macromolecular host defense mechanisms allowed the cultivation of parasitic cells on an animal that was not naturally susceptible.     

ICAM-3 activation modulates cell-cell contacts of human bone marrow endothelial cells

The Ig-like cell adhesion molecule ICAM-3 is mainly expressed on human leukocytes and is involved in cell-cell interactions. Its expression on endothelium is observed during disorders such as Crohn's disease and in solid tumors. We found low but detectable expression of ICAM-3 on VE-cadherin-expressing cells from primary human bone marrow aspirates, i.e. endothelial cells, and on primary human endothelial cells from cord blood. Also, immortalized human umbilical cord endothelial cells and human bone marrow endothelial cells showed ICAM-3 expression. However, its function on human endothelium is not known. Surprisingly, activation of endothelial ICAM-3 by crosslinking with specific antibodies resulted in a drop in the electrical resistance of bone marrow endothelial monolayers. In line with this, immunocytochemical analysis showed a loss of endothelial cell-cell contacts after ICAM-3 crosslinking in HBMEC. Detailed biochemical analysis showed an association of moesin and in a later stage ezrin with ICAM-3 upon crosslinking in HBMEC. Moreover, ICAM-3 crosslinking induced the production of reactive oxygen species (ROS), which are known to be involved in the control of endothelial cell-cell contacts. In conclusion, we showed that ICAM-3 is expressed on human bone marrow endothelial cells and controls endothelial integrity via ROS-dependent signaling.     

Ex vivo expansion of human hematopoietic stem cells

There has been great interest in the ex vivo expansion of human long-term repopulating hematopoietic stem cells (LTR-HSCs) for a variety of clinical applications such as umbilical cord blood transplantation. The glucoprotein130 signal, activated by a complex of interleukin 6 (IL-6) and soluble IL-6 receptor (IL-6/sIL-6R), acts dramatically in synergy with the c-Kit or Flk2/Flt3 signal to expand immature human HSCs. We demonstrate a significant ex vivo expansion of human LTR-HSCs capable of repopulating in newly discovered nonobese diabetes/Shi-severe combined immunodeficient (NOD/Shi-SCID) mice. The proportion of human CD45+ cells in recipient marrow was 10 times higher in animals receiving the cultured cells with stem cell factor, Flk2/Flt3 ligand, thrombopoietin, and IL-6/sIL-6R than in those receiving comparable numbers of fresh cord blood CD34+ cells. The expansion rate provided by this combination was estimated to be 4.2-fold by a limiting dilution method. Addition of IL-3 to the culture with the cytokine combination abrogated the repopulating ability of the expanded cells. The culture method with the IL-6/sIL-6R complex and other cytokines may pave the way for ex vivo expansion of human transplantable HSCs suitable for clinical applications.     

Continuous long-term culture of human bone marrow

Summary Human bone marrow was cultured with alpha medium, 10^?6m hydrocortisone and a mixture of horse and fetal calf serum in a long-term liquid culture system. An adherent layer was formed which contained fat cells, macrophages, fibroblast-like and epithelioid cells. The layer harboured myeloid cells and their presumptive precursors whilst the nonadherent cells were composed of immature myeloid elements plus mature macrophages and granulocytes whose numbers were maintained for periods of up to 12 weeks. Experiments showed that the use of serum mixtures was superior to horse or fetal calf serum alone and successful culture was accompanied by early growth of the hydrocortisone-dependent fat cells in the adherent layer.     

Ex vivo expansion of human adult stem cells capable of primary and secondary hemopoietic reconstitution

OBJECTIVE: Ex vivo expansion of human hemopoietic stem cells (HSC) is an important issue in transplantation and gene therapy. Encouraging results have been obtained with cord blood, where extensive amplification of primitive progenitors was observed. So far, this goal has been elusive with adult cells, in which amplification of committed and mature cells, but not of long-term repopulating cells, has been described. METHODS: Adult normal bone marrow (BM) and mobilized peripheral blood (MPB) CD34(+) cells were cultured in a stroma-free liquid culture in the presence of Flt-3 ligand (FL), thrombopoietin (TPO), stem cell factor (SCF), interleukin-6 (IL-6), or interleukin-3 (IL-3). Suitable aliquots of cells were used to monitor cell production, clonogenic activity, LTC-IC output, and in vivo repopulating capacity. RESULTS: Here we report that BM and MPB HSC can be cultured in the presence of FL, TPO, SCF, and IL-6 for up to 10 weeks, during which time they proliferate and produce large numbers of committed progenitors (up to 3000-fold). Primitive NOD/SCID mouse repopulating stem cells (SRC) are expanded sixfold after 3 weeks (by limiting dilution studies) and retain the ability to repopulate secondary NOD/SCID mice after serial transplants. Substitution of IL-6 with IL-3 leads to a similarly high production of committed and differentiated cells but only to a transient (1 week) expansion of SRC(s), which do not possess secondary repopulation capacity. CONCLUSION: We report evidence to show that under appropriate culture conditions, adult human SRC can also be induced to expand with limited differentiation.     

Expression of interleukin-5 by human bone marrow microvascular endothelial cells: implications for the regulation of eosinophilopoiesis in vivo

We have shown that bone marrow microvascular endothelial cells (BMEC) support growth and differentiation of haemopoietic progenitors in vitro by elaboration of haemopoietic cytokines. Since generation of eosinophils can be observed in these coculture experiments, and BMEC do not produce interleukin (IL)-3, we evaluated BMEC for expression of IL-5, a specific growth factor for the eosinophilic lineage. Using RT-PCR, IL-5 mRNA was expressed by BMEC after stimulation (12 h) with lipopolysaccharide (LPS), IL-1, IL-2 and phorbol myristate acetate (PMA), but not by resting BMEC, after stimulation with TNF-α or interferon (IFN)-γ. Moreover, IFN-γ suppressed expression of IL-5 in response to LPS and IL-2. The identity of the PCR products was confirmed by restriction enzyme digestion, which resulted in fragments of the predicted size. T lymphocytes were not present in the endothelial cultures as demonstrated by absence of CD2 mRNA. Using a sensitive (1 pg/ml) ELISA assay, IL-5 was detected after 48 h incubation of BMEC with IL-2 (4.1 pg/10⁶ cells) or with a combination of LPS and IL-2 (4.8 pg). However, the number of eosinophils generated after 4 weeks coculture of CD34⁺ haemopoietic cells with BMEC was not increased by addition of IL-2. RT-PCR revealed that BMEC in coculture with haemopoietic cells expressed IL-5 even without addition of exogenous cytokines or stimulating agents. In conclusion, expression of IL-5 by BMEC can be stimulated by cytokines (IL-1, IL-2), LPS, PMA, and coculture with proliferating haemopoietic cells. Thus, BMEC may support proliferation and differentiation of eosinophils in the bone marrow. IFN-γ represents a cytokine with an inhibitory effect on IL-5 expression by BMEC. In addition, eosinophilia in response to circulating IL-2 or bacterial products (LPS) in vivo may be partially mediated by BMEC or vascular endothelium.