A stromal-free,serum-free system to expand ex vivo hematopoietic stem cells from mobilized peripheral blood of patients with hematologic malignancies and healthy donors

Background aimsThe number of hematopoietic stem cells (HSCs) is critical for transplantation. The ex vivo expansion of mobilized peripheral blood (MPB) HSCs is of clinical value for reconstitution to meet clinical need.MethodsThis study proposed a simple, defined, stromal-free and serum-free culture system (SF-HSC medium) for clinical use, which is composed of Iscove's modified Dulbecco's medium, cytokine cocktails and serum substitutes. This study also characterized the cellular properties of expanded MPB CD133⁺ HSCs from patients with hematologic malignancies and healthy donors by surface antigen, colony-forming cell, long-term culture-initiating cell, gene expression and in vivo engraftment assays.ResultsThe expanded fold values of CD45⁺ white blood cells and CD34⁺, CD133⁺, CD34⁺CD38^?, CD133⁺CD38^?, CD34⁺CD133⁺, colony-forming and long-term culture-initiating cells at the end of 7-day culture from CD133⁺ MPB of hematologic malignancies were 9.4-fold, 5.9-fold, 4.0-fold, 35.8-fold, 21.9-fold, 3.8-fold, 11.8-fold and 6.7-fold, and values from healthy donor CD133⁺ MPB were 20.7-fold, 14.5-fold, 8.5-fold, 83.8-fold, 37.3-fold, 6.2-fold, 19.1-fold and 14.6-fold. The high enrichment of CD38^? cells, which were either CD34⁺ or CD133⁺, sustained the proliferation of early uncommitted HSCs. The expanded cells showed high levels of messenger RNA expression of HOBX4, ABCG2 and HTERT and had the in vivo ability to re-populate NOD/SCID mice.ConclusionsOur results demonstrated that an initial, limited number of MPB CD133⁺ HSCs could be expanded functionally in SF-HSC medium. We believe that this serum-free expansion technique can be employed in both basic research and clinical transplantation.     

Testosterone influences renal electrolyte excretion in SHR/y and WKY males

Background

Aldehyde dehydrogenase (ALDH) is a cytosolic enzyme highly expressed in hematopoietic precursors from cord blood and granulocyte-colony stimulating factor mobilized peripheral blood, as well as in bone marrow from patients with acute myeloblastic leukemia. As regards human normal bone marrow, detailed characterization of ALDH⁺ cells has been addressed by one single study (Gentry et al, 2007). The goal of our work was to provide new information about the dissection of normal bone marrow progenitor cells based upon the simultaneous detection by flow cytometry of ALDH and early hematopoietic antigens, with particular attention to the expression of ALDH on erythroid precursors. To this aim, we used three kinds of approach: i) multidimensional analytical flow cytometry, detecting ALDH and early hematopoietic antigens in normal bone marrow; ii) fluorescence activated cell sorting of distinct subpopulations of progenitor cells, followed by in vitro induction of erythroid differentiation; iii) detection of ALDH⁺ cellular subsets in bone marrow from pure red cell aplasia patients.

Results

In normal bone marrow, we identified three populations of cells, namely ALDH⁺CD34⁺, ALDH^-CD34⁺ and ALDH⁺CD34^- (median percentages were 0.52, 0.53 and 0.57, respectively). As compared to ALDH^-CD34⁺ cells, ALDH⁺CD34⁺ cells expressed the phenotypic profile of primitive hematopoietic progenitor cells, with brighter expression of CD117 and CD133, accompanied by lower display of CD38 and CD45RA. Of interest, ALDH⁺CD34^- population disclosed a straightforward erythroid commitment, on the basis of three orders of evidences. First of all, ALDH⁺CD34^- cells showed a CD71^bright, CD105⁺, CD45^- phenotype. Secondly, induction of differentiation experiments evidenced a clear-cut expression of glycophorin A (CD235a). Finally, ALDH⁺CD34^- precursors were not detectable in patients with pure red cell aplasia (PRCA).

Conclusion

Our study, comparing surface antigen expression of ALDH⁺/CD34⁺, ALDH^-/CD34⁺ and ALDH⁺/CD34^- progenitor cell subsets in human bone marrow, clearly indicated that ALDH⁺CD34^- cells are mainly committed towards erythropoiesis. To the best of our knowledge this finding is new and could be useful for basic studies about normal erythropoietic differentiation as well as for enabling the employment of ALDH as a red cell marker in polychromatic flow cytometry characterization of bone marrow from patients with aplastic anemia and myelodysplasia.     

Differences amid bone marrow and cord blood hematopoietic stem/progenitor cell division kinetics

Human hematopoietic stem/progenitor cells (HSC) isolated based upon specific patterns of CD34 and CD38 expression, despite phenotypically identical, were found to be functionally heterogeneous, raising the possibility that reversible expression of these antigens may occur during cellular activation and/or proliferation. In these studies, we combined PKH67 tracking with CD34/CD38 immunostaining to compare cell division kinetics between human bone marrow (BM) and cord blood (CB)‐derived HSC expanded in a serum‐free/stromal‐based system for 14 days (d), and correlated CD34 and CD38 expression with the cell divisional history. CB cells began dividing 24 h earlier than BM cells, and significantly higher numbers underwent mitosis during the time in culture. By d10, over 55% of the CB‐cells reached the ninth generation, whereas BM‐cells were mostly distributed between the fifth and seventh generation. By d14, all CB cells had undergone multiple cell divisions, while 0.7–3.8% of BM CD34⁺ cells remained quiescent. Furthermore, the percentage of BM cells expressing CD34 decreased from 60.8 ± 6.3% to 30.6 ± 6.7% prior to initiating division, suggesting that downmodulation of this antigen occurred before commencement of proliferation. Moreover, with BM, all primitive CD34⁺CD38^? cells present at the end of culture arose from proliferating CD34⁺CD38⁺ cells that downregulated CD38 expression, while in CB, a CD34⁺CD38^? population was maintained throughout culture. These studies show that BM and CB cells differ significantly in cell division kinetics and expression of CD34 and CD38, and that the inherent modulation of these antigens during ex vivo expansion may lead to erroneous quantification of the stem cell content of the expanded graft. J. Cell. Physiol. 220: 102–111, 2009. © 2009 Wiley‐Liss, Inc.     

9-O-acetylated sialic acids differentiating normal haematopoietic precursors from leukemic stem cells with high aldehyde dehydrogenase activity in children with acute lymphoblastic leukaemia

Childhood acute lymphoblastic leukaemia (ALL) originates from mutations in haematopoietic progenitor cells (HPCs). For high-risk patients, treated with intensified post-remission chemotherapy, haematopoietic stem cell (HSC) transplantation is considered. Autologous HSC transplantation needs improvisation till date. Previous studies established enhanced disease-associated expression of 9-O-acetylated sialoglycoproteins (Neu5,9Ac₂-GPs) on lymphoblasts of these patients at diagnosis, followed by its decrease with clinical remission and reappearance with relapse. Based on this differential expression of Neu5,9Ac₂-GPs, identification of a normal HPC population was targeted from patients at diagnosis. This study identifies two distinct haematopoietic progenitor populations from bone marrow of diagnostic ALL patients, exploring the differential expression of Neu5,9Ac₂-GPs with stem cell (CD34, CD90, CD117, CD133), haematopoietic (CD45), lineage-commitment (CD38) antigens and cytosolic aldehyde dehydrogenase (ALDH). Normal haematopoietic progenitor cells (ALDH⁺SSC^loCD45^hiNeu5,9Ac₂ -GPs^loCD34⁺CD38^?CD90⁺CD117⁺CD133⁺) differentiated into morphologically different, lineage-specific colonies, being crucial for autologous HSC transplantation while leukemic stem cells (ALDH⁺SSC^loCD45^loNeu5,9Ac₂ -GPs^hiCD34⁺CD38⁺CD90^?CD117^?CD133^?) lacking this ability can be potential targets for minimal residual disease detection and drug-targeted immunotherapy.     

Characterization of hematopoietic stem cell subsets from patients with multiple myeloma after mobilization with plerixafor

Background aimsPrevious studies have demonstrated that the combination of granulocyte–colony-stimulating factor (G-CSF) + plerixafor is more efficient in mobilizing CD34⁺ hematopoietic stem cells (HSC) into the peripheral blood than G-CSF alone. In this study we analyzed the impact of adding plerixafor to G-CSF upon the mobilization of different HSC subsets.MethodsWe characterized the immunophenotype of HSC subsets isolated from the peripheral blood of eight patients with multiple myeloma (MM) before and after treatment with plerixafor. All patients were supposed to collect stem cells prior to high-dose chemotherapy and consecutive autologous stem cell transplantation, and therefore received front-line mobilization with 4 days of G-CSF followed by a single dose of plerixafor. Samples of peripheral blood were analyzed comparatively by flow cytometry directly before and 12 h after administration of plerixafor.ResultsThe number of aldehyde dehydrogenase (ALDH)^bright and CD34⁺ cells was significantly higher after plerixafor treatment (1.2–5.0 and 1.5–6.0 times; both P < 0.01) and an enrichment of the very primitive CD34⁺ CD38^? and ALDH^bright CD34⁺ CD38^? HSC subsets was detectable. Additionally, two distinct ALDH⁺ subsets could be clearly distinguished. The small ALDH^high subset showed a higher number of CD34⁺ CD38^? cells in contrast to the total ALDH^bright subpopulation and probably represented a very primitive subpopulation of HSC.ConclusionsA combined staining of ALDH, CD34 and CD38 might represent a powerful tool for the identification of a very rare and primitive hematopoietic stem cell subset. The addition of plerixafor mobilized not only more CD34⁺ cells but was also able to increase the proportion of more primitive stem cell subsets.     

Placental/umbilical cord blood-derived mesenchymal stem cell-like stromal cells support hematopoietic recovery of X-irradiated human CD34+ cells

AimsThe potential of human mesenchymal stem cell-like stroma prepared from placental/umbilical cord blood for hematopoietic regeneration by X-irradiated hematopoietic stem cells is herein assessed.Main methodsPlacental/umbilical cord blood-derived mesenchymal stem cell-like stromal cells were applied to a regenerative ex vivo expansion of X-irradiated human CD34⁺ cells in a serum-free liquid culture supplemented with a combination of interleukine-3 plus stem cell factor plus thrombopoietin.Key findingsThe total number of cells and of lineage-committed myeloid hematopoietic progenitor cells generated in the co-culture of both non-irradiated and X-irradiated cells with stromal cells was significantly higher than those in the stroma-free culture. In addition, the number of CD34⁺ cells and CD34⁺/CD38^? cells, immature hematopoietic stem/progenitor cells also increased more than the stroma-free culture. The stromal cells produced various types of cytokines, although there was little difference between the co-cultures of non-irradiated and X-irradiated cells with stromal cells. Furthermore, when X-irradiated cells came in contact with stromal cells for 16 h before cytokine stimulation, a similar degree of hematopoiesis was observed, thus suggesting the critical role of cell-to-cell interaction.SignificanceThe present results showed the potential efficacy of human mesenchymal stem cell-like stroma for hematopoietic regeneration from irradiated hematopoietic stem/progenitor cells.     

Characterization of human embryonic stem cell-derived hematopoietic progenitor phenotype

Differentiation of human embryonic stem cells (hESCs) into hematopoietic lineages using various methods has been reported. However, the phenotype that precisely defines the hematopoietic progenitor compartment with clonogenic activities has yet to be determined. Here, we measured and characterized progenitor function of subfractions of cells prospectively isolated from human embryoid bodies (hEBs) during hematopoietic differentiation basing on surface markers CD45, CD34, CD43, and CD38. We report that hematopoietic progenitors predominantly resided in the CD45⁺ subset. CD43⁺ cells lacking CD45 expression were largely devoid of progenitor activity. However, progenitor activity and multipotentiality was more enriched in CD45⁺ cells co-expressing CD43. CD45⁺ subset co-expressing CD34 but lacking CD38 expression (CD45⁺CD34⁺CD38^-) were further enriched for CFU capacity compared to the CD45⁺CD34⁺CD38⁺ subset. Our study demonstrates a role of CD43 in enriching hematopoietic progenitors derived from hEBs and reveals a hierarchical organization of hESC-derived hematopoietic progenitor compartments defined by phenotypic markers.     

Metallothionein in human immunomagnetically selected CD34+ haematopoietic progenitor cells

Human umbilical CD34⁺ immature haematopoietic cells were rapidly and efficiently obtained from light density MNC (mononuclear cells) by MACS (magnetic cell sorting). An ex vivo expanded population of CD34⁺ was cultured in serum‐free medium supplemented with cytokines FL (flt3 ligand), SCF (stem cell factor) and TPO (thrombopoietin) in order to obtain a sufficient number of CD34⁺ cells. CD34⁺ cells expanded from cord blood for 7 days were demonstrated to increase in the absolute number of CD34⁺ cells by 5.12±2.47‐fold (mean±S.D., n=3). Flow cytometric analysis demonstrated that the percentage of CD34 antigen expression after expansion of the culture was 97.81±1.07%, whereas it was 69.39±10.37% in none‐expanded CD34⁺ cells (mean±S.D., n=3), thus defining a system that allowed extensive amplification accompanied by no maturation. MTs (metallothioneins), low molecular weight, cysteine‐rich metal‐binding proteins, exhibit various functions, including metal detoxification and homoeostasis. We here examined the expression pattern of functional members of the MT gene family in immature CD34⁺ cells and compared it with more mature CD34^? cells in order to strengthen the proposed function of MT in differentiation. Cells were cultured in RPMI 1640 medium, with or without different zinc supplements for 24 h. Relative quantitative expression of MT isogenes in the mature CD34^? cells was higher than in the immature CD34⁺ cells. IHC (immunohistochemical staining) revealed an increased MT protein biosynthesis in CD34^? cells, greater than in CD34⁺ cells. Therefore, the role of MT in differentiation of human haematopoietic progenitor cells from human cord blood is reported for the first time.     

Establishment of a Humanized APL Model via the Transplantation of PML-RARA-Transduced Human Common Myeloid Progenitors into Immunodeficient Mice

Recent advances in cancer biology have revealed that many malignancies possess a hierarchal system, and leukemic stem cells (LSC) or leukemia-initiating cells (LIC) appear to be obligatory for disease progression. Acute promyelocytic leukemia (APL), a subtype of acute myeloid leukemia characterized by the formation of a PML-RARα fusion protein, leads to the accumulation of abnormal promyelocytes. In order to understand the precise mechanisms involved in human APL leukemogenesis, we established a humanized in vivo APL model involving retroviral transduction of PML-RARA into CD34⁺ hematopoietic cells from human cord blood and transplantation of these cells into immunodeficient mice. The leukemia well recapitulated human APL, consisting of leukemic cells with abundant azurophilic abnormal granules in the cytoplasm, which expressed CD13, CD33 and CD117, but not HLA-DR and CD34, were clustered in the same category as human APL samples in the gene expression analysis, and demonstrated sensitivity to ATRA. As seen in human APL, the induced APL cells showed a low transplantation efficiency in the secondary recipients, which was also exhibited in the transplantations that were carried out using the sorted CD34⁻ fraction. In order to analyze the mechanisms underlying APL initiation and development, fractionated human cord blood was transduced with PML-RARA. Common myeloid progenitors (CMP) from CD34⁺/CD38⁺ cells developed APL. These findings demonstrate that CMP are a target fraction for PML-RARA in APL, whereas the resultant CD34⁻ APL cells may share the ability to maintain the tumor.     

CD133 immunomagnetic separation: effectiveness of the method for CD133(+) isolation from umbilical cord blood

Background aimsUmbilical cord blood (UCB) is a rich source of stem cells, the characterization and isolation of which requires specific stem cell markers and reliable and reproducible protocols.MethodsWe assessed CD133 isolation in 39 UCB samples, using a commercial immunomagnetic cell-sorting protocol, and, because of its non-reproducibility, we applied optimized protocols in an effort to improve it. These included extra-labeling of the selected CD133⁺ subpopulation and indirect labeling using anti-phycoerythrin (PE) microbeads, goat anti-mouse IgG microbeads or a combination of both. The CD34 isolation was used as a control.ResultsThe mononuclear cell fraction expressed 0.53 ± 0.06% CD133. The corresponding value for CD34 was 1.64 ± 0.15%. Following the manufacturer's instructions, the CD34 isolation resulted in a population expressing 93 ± 1.25% CD34 while, after the corresponding process, CD133⁺ expression ranged from 10% to 85% (median 60%). The optimized isolation protocols did not result in improved CD133⁺ yield. The variation in the purity of the CD133 population cannot be attributed to the different clones of CD133 used, because they do not cross-block, while other factors such as glycosylation, which could possibly interfere, do not apply in normal hematopoietic stem cells (HSC).ConclusionsCD34 isolation by the immunomagnetic method results in highly pure CD34⁺ population, while the efficient and reproducible yield of a pure CD133⁺ population is not feasible. Therefore quantification of the positive cells should follow each isolation procedure in order to confirm the number of CD133⁺ cells.     

The human placenta is a hematopoietic organ during the embryonic and fetal periods of development

We studied the potential role of the human placenta as a hematopoietic organ during embryonic and fetal development. Placental samples contained two cell populations—CD34⁺⁺CD45^low and CD34⁺CD45^low—that were found in chorionic villi and in the chorioamniotic membrane. CD34⁺⁺CD45^low cells express many cell surface antigens found on multipotent primitive hematopoietic progenitors and hematopoietic stem cells. CD34⁺⁺CD45^low cells contained colony-forming units culture (CFU-C) with myeloid and erythroid potential in clonogenic in vitro assays, and they generated CD56⁺ natural killer cells and CD19⁺CD20⁺sIgM⁺ B cells in polyclonal liquid cultures. CD34⁺CD45^low cells mostly comprised erythroid- and myeloid-committed progenitors, while CD34⁻ cells lacked CFU-C. The placenta-derived precursors were fetal in origin, as demonstrated by FISH using repeat-sequence chromosome-specific probes for X and Y. The number of CD34⁺⁺CD45^low cells increased with gestational age, but their density (cells per gram of tissue) peaked at 5-8 wk, decreasing more than sevenfold at the onset of the fetal phase (9 wk of gestation). In addition to multipotent progenitors, the placenta contained myeloid- and erythroid-committed progenitors indicative of active in situ hematopoiesis. These data suggest that the human placenta is an important hematopoietic organ, raising the possibility of banking placental hematopoietic stem cells along with cord blood for transplantation.     

Mobilization of CD34~+CD38~- hematopoietic stem cells after priming in acute myeloid leukemia

AIM: To evaluate quantitatively and qualitatively the different CD34+cell subsets after priming by chemotherapy granulocyte colony-stimulating factor(± G-CSF)in patients with acute myeloid leukemia.METHODS: Peripheral blood and bone marrow sampleswere harvested in 8 acute myeloid leukemia patients during and after induction chemotherapy. The CD34/CD38 cell profile was analyzed by multi-parameter flow cytometry. Adhesion profile was made using CXC chemokine receptor 4(CXCR4)(CD184), VLA-4(CD49d/CD29) and CD47.RESULTS: Chemotherapy ± G-CSF mobilized immature cells(CD34+CD38 population), while the more mature cells(CD34+CD38lowand CD34+CD38+populations) decreased progressively after treatment. Circulating CD34+cells tended to be more sensitive to chemotherapy after priming with G-CSF. CD34+cell mobilization was correlated with a gradual increase in CXCR4 and CD47expression, suggesting a role in cell protection and the capacity of homing back to the marrow.CONCLUSION: Chemotherapy ± G-CSF mobilizes into the circulation CD34+bone marrow cells, of which, the immature CD34+CD38-cell population. Further manipulations of these interactions may be a means with which to control the trafficking of leukemia stem cells to improve patients’ outcomes.     

Consistent bone marrow-derived cell mobilization following repeated short courses of granulocyte–colony-stimulating factor in patients with amyotrophic lateral sclerosis: results from a multicenter prospective trial

Background and aimsThe aim of this study was to evaluate and characterize the feasibility and safety of bone marrow-derived cell (BMC) mobilization following repeated courses of granulocyte–colony stimulating factor (G-CSF) in patients with amyotrophic lateral sclerosis (ALS).MethodsBetween January 2006 and March 2007, 26 ALS patients entered a multicenter trial that included four courses of BMC mobilization at 3-month intervals. In each course, G-CSF (5 μg/kg b.i.d.) was administered for four consecutive days; 18% mannitol was also given. Mobilization was monitored by flow cytometry analysis of circulating CD34⁺ cells and by in vitro colony assay for clonogenic progenitors. Co-expression by CD34⁺ cells of CD133, CD90, CD184, CD117 and CD31 was also assessed.ResultsTwenty patients completed the four-course schedule. One patient died and one refused to continue the program before starting the mobilization courses; four discontinued the study protocol because of disease progression. Overall, 89 G-CSF courses were delivered. There were two severe adverse events: one prolactinoma and one deep vein thrombosis. There were no discontinuations as a result of toxic complications. Circulating CD34⁺ cells were monitored during 85 G-CSF courses and were always markedly increased; the range of median peak values was 41–57/μL, with no significant differences among the four G-CSF courses. Circulating clonogenic progenitor levels paralleled CD34⁺ cell levels. Most mobilized CD34⁺ cells co-expressed stem cell markers, with a significant increase in CD133 co-expression.ConclusionsIt is feasible to deliver repeated courses of G-CSF to mobilize a substantial number of CD34⁺ cells in patients with ALS; mobilized BMC include immature cells with potential clinical usefulness.     

Frozen Cord Blood Hematopoietic Stem Cells Differentiate into Higher Numbers of Functional Natural Killer Cells In Vitro than Mobilized Hematopoietic Stem Cells or Freshly Isolated Cord Blood Hematopoietic Stem Cells

Adoptive natural killer (NK) cell therapy relies on the acquisition of large numbers of NK cells that are cytotoxic but not exhausted. NK cell differentiation from hematopoietic stem cells (HSC) has become an alluring option for NK cell therapy, with umbilical cord blood (UCB) and mobilized peripheral blood (PBCD34⁺) being the most accessible HSC sources as collection procedures are less invasive. In this study we compared the capacity of frozen or freshly isolated UCB hematopoietic stem cells (CBCD34⁺) and frozen PBCD34⁺ to generate NK cells in vitro. By modifying a previously published protocol, we showed that frozen CBCD34⁺ cultures generated higher NK cell numbers without loss of function compared to fresh CBCD34⁺ cultures. NK cells generated from CBCD34⁺ and PBCD34⁺ expressed low levels of killer-cell immunoglobulin-like receptors but high levels of activating receptors and of the myeloid marker CD33. However, blocking studies showed that CD33 expression did not impact on the functions of the generated cells. CBCD34⁺-NK cells exhibited increased capacity to secrete IFN-γ and kill K562 in vitro and in vivo as compared to PBCD34⁺-NK cells. Moreover, K562 killing by the generated NK cells could be further enhanced by IL-12 stimulation. Our data indicate that the use of frozen CBCD34⁺ for the production of NK cells in vitro results in higher cell numbers than PBCD34⁺, without jeopardizing their functionality, rendering them suitable for NK cell immunotherapy. The results presented here provide an optimal strategy to generate NK cells in vitro for immunotherapy that exhibit enhanced effector function when compared to alternate sources of HSC.     

Differential Gene Expression of Human CD34+ Hematopoietic Stem and Progenitor Cells Before and After Culture

Ex vivo expanded CD34⁺ hematopoietic stem and progenitor cells (HSPCs) have compromised homing and engraftment capacities. To investigate underlying mechanisms for functional changes of expanded HSPCs, we compared gene expression profiling of cultured and fresh CD34⁺ cells derived from cord blood using SMART-PCR and cDNA array: 20 genes were up-regulated while 25 genes were down-regulated in cultured CD34⁺ HSPCs. These differentially expressed genes are involved primarily in proliferation, differentiation, apoptosis, and homing. Revisions requested 27 September 2005; Revisions received 14 December 2005     

CD34+VEGFR‐3+ progenitor cells have a potential to differentiate towards lymphatic endothelial cells

Endothelial progenitor cells (EPCs) play an important role in postnatal neovascularization. However, it is poorly understood whether EPCs contribute to lymphangiogenesis. Here, we assessed differentiation of a novel population of EPCs towards lymphatic endothelial cells and their lymphatic formation. CD34⁺VEGFR‐3⁺ EPCs were isolated from mononuclear cells of human cord blood by fluorescence‐activated cell sorting. These cells expressed CD133 and displayed the phenotype of the endothelial cells. Cell colonies appeared at 7–10 days after incubation. The cells of the colonies grew rapidly and could be repeatedly subcultured. After induction with VEGF‐C for 2 weeks, CD34⁺VEGFR‐3⁺ EPCs could differentiate into lymphatic endothelial cells expressing specific markers 5′‐nucleotidase, LYVE‐1 and Prox‐1. The cells also expressed hyaluronan receptor CD44. The differentiated cells had properties of proliferation, migration and formation of lymphatic capillary‐like structures in three‐dimensional collagen gel and Matrigel. VEGF‐C enhanced VEGFR‐3 mRNA expression. After interfering with VEGFR‐3 siRNA, the effects of VEGF‐C were diminished. These results demonstrate that there is a population of CD34⁺VEGFR‐3⁺ EPCs with lymphatic potential in human cord blood. VEGF‐C/VEGFR‐3 signalling pathway mediates differentiation of CD34⁺VEGFR‐3⁺ EPCs towards lymphatic endothelial cells and lymphangiogenesis. Cord blood‐derived CD34⁺VEGFR‐3⁺ EPCs may be a reliable source in transplantation therapy for lymphatic regenerative diseases.     

Intrahepatic transplantation of CD34+ cord blood stem cells into newborn and adult NOD/SCID mice induce differential organ engraftment

In vivo studies concerning the function of human hematopoietic stem cells (HSC) are limited by relatively low levels of engraftment and the failure of the engrafted HSC preparations to differentiate into functional immune cells after systemic application. In the present paper we describe the effect of intrahepatically transplanted CD34⁺ cells from cord blood into the liver of newborn or adult NOD/SCID mice on organ engraftment and differentiation.Analyzing the short and long term time dependency of human cell recruitment into mouse organs after cell transplantation in the liver of newborn and adult NOD/SCID mice by RT-PCR and FACS analysis, a significantly high engraftment was found after transplantation into liver of newborn NOD/SCID mice compared to adult mice, with the highest level of 35% human cells in bone marrow and 4.9% human cells in spleen at day 70. These human cells showed CD19 B-cell, CD34 and CD38 hematopoietic and CD33 myeloid cell differentiation, but lacked any T-cell differentiation. HSC transplantation into liver of adult NOD/SCID mice resulted in minor recruitment of human cells from mouse liver to other mouse organs. The results indicate the usefulness of the intrahepatic application route into the liver of newborn NOD/SCID mice for the investigation of hematopoietic differentiation potential of CD34⁺ cord blood stem cell preparations.     

Evaluation of mobilized peripheral blood CD34+ cells from patients with severe coronary artery disease as a source of endothelial progenitor cells

Background aimsThe distinction between hematopoietic stem cells (HSC) and endothelial progenitor cells (EPC) is poorly defined. Co-expression of CD34 antigen with vascular endothelial growth factor (VEGF) receptor (VEGFR2) is currently used to define EPC (1).MethodsWe evaluated the phenotypic and genomic characteristics of peripheral blood-derived CD34⁺ cells in 22 granulocyte–colony-stimulating factor (G-CSF)-mobilized patients with severe coronary artery disease and assessed the influence of cell selection and storage on CD34⁺ cell characteristics.ResultsThe median CD34⁺ cell contents in the products before and after enrichment with the Isolex 300i Magnetic Cell Selection System were 0.2% and 82.5%, respectively. Cell-cycle analysis showed that 80% of CD34⁺ cells were in G0 stage; 70% of the isolated CD34⁺ cells co-expressed CD133, a marker for more immature progenitors. However, less than 5% of the isolated CD34⁺ cells co-expressed the notch receptor Jagged-1 (CD339) and only 2% of the isolated CD34⁺ population were positive for VEGFR2 (CD309). Molecular assessment of the isolated CD34⁺ cells demonstrated extremely low expression of VEGFR2 and endothelial nitric oxide synthase (eNOS) and high expression of VEGF-A. Overnight storage at 4°C did not significantly affect CD34⁺ cell counts and viability. Storage in liquid nitrogen for 7 weeks did not affect the percentage of CD34⁺ cells but was associated with a 26% drop in cell viability.ConclusionsWe have demonstrated that the majority of isolated CD34⁺ cells consist of immature and quiescent cells that lack prototypic markers of EPC. High VEGF-A gene expression might be one of the mechanisms for CD34⁺ cell-induced angiogenesis.