Navarro A, Carbonell-Uberos F, Marín S, Miñana MD. Human adipose tissue contains erythroid progenitors expressing fetal hemoglobin. World J Stem Cells 2013; 5(4): 205-216 [PMID: 24179608 DOI: 10.4252/wjsc.v5.i4.205]
Corresponding Author of This Article
Dr. María Dolores Miñana, PhD, Regenerative Medicine Laboratory, Fundación Hospital General Universitario, Ave. Tres Cruces s/n, 46014 Valencia, Spain. minyana_mdo@gva.es
Research Domain of This Article
Hematology
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Original Article
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This article is an open-access article which was selected by an in-house editor and fully peer-reviewed by external reviewers. It is distributed in accordance with the Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license, which permits others to distribute, remix, adapt, build upon this work non-commercially, and license their derivative works on different terms, provided the original work is properly cited and the use is non-commercial. See: http://creativecommons.org/licenses/by-nc/4.0/
Amparo Navarro, María Dolores Miñana, Regenerative Medicine Laboratory, Fundación Hospital General Universitario, 46014 Valencia, Spain
Francisco Carbonell-Uberos, Immunohematology Service, Centro de Transfusiones, 46014 Valencia, Spain
Severiano Marín, Department of Plastic and Reconstructive Surgery, Consorcio Hospital General Universitario, 46014 Valencia, Spain
ORCID number: $[AuthorORCIDs]
Author contributions: Navarro A and Miñana MD performed the majority of the experiments, interpreted the data and critically revised the article; Marin S provided the samples, and was also involved in revising the manuscript; Carbonell-Uberos F was responsible for the flow cytometric analysis and critically revised the article; Miñana MD designed the study and wrote the article.
Supported by The Ministerio de Ciencia e Innovación, PI08/1716; Ministerio de Sanidad y Consumo, EMER07/005; and Consellería de Sanidad, Generalitat Valenciana, AP061/09 and AP069/10
Correspondence to: Dr. María Dolores Miñana, PhD, Regenerative Medicine Laboratory, Fundación Hospital General Universitario, Ave. Tres Cruces s/n, 46014 Valencia, Spain. minyana_mdo@gva.es
Telephone: +34-961-972146 Fax: +34-961-972145
Received: April 17, 2013 Revised: June 11, 2013 Accepted: August 12, 2013 Published online: October 26, 2013 Processing time: 196 Days and 20 Hours
Abstract
AIM: To investigate the origin of hematopoietic progenitors contained in the stromal vascular fraction (SVF) of human adipose tissue.
METHODS: Tissue samples obtained from lipectomies were subjected to enzymatic digestion with collagenase to obtain a single-cell suspension. The centrifuged cell pellet, termed SVF, was separated immunomagnetically into CD45+ and CD45- cells and cultured in serum-free medium containing hematopoietic cytokines. The freshly isolated and cultured cells were evaluated to determine their ability to form hematopoietic colony-forming units in clonogenic assays and for the expression of certain hematopoietic transcription factors by reverse transcription-polymerase chain reaction; the gene expression level was compared to that in CD34+ hematopoietic progenitor cells from cord blood (CB) and adult peripheral blood (PB). To characterize erythroid progenitors, burst-forming units-erythroid (BFU-E) were developed in a semisolid medium under different culture conditions, and the hemoglobin composition and globin gene expression in the erythroid colonies were determined.
RESULTS: The transcription factors SCL/TAL1, RUNX1, RUNX2 and GATA2 were expressed in both the CD45+ and CD45- SVF populations; however, in contrast to our observations in the CD34+ cells from CB and adult PB, GATA1 was not detected. Nevertheless, GATA1 could be detected in the SVF cells after seven days in culture, whereas its expression was upregulated in the CB CD34+ cells. The analysis of BFU-E-derived colonies revealed that virtually all erythroid cells produced by SVF cells expressed fetal hemoglobin, and the γ-globin mRNA levels ranged between those obtained in the adult- and neonatal-derived erythroid cells. Moreover, the SVF-derived erythroid cells synthesized similar levels of α- and β-globin mRNA, whereas the α-globin transcript levels were consistently higher those of β-globin in the cells derived from CB or PB CD34+ cells. Furthermore, although the cellular distribution of hemoglobin in the erythroid cells derived from the CD34+ cells obtained from hematopoietic tissues was dependent on the presence or absence of serum in the culture medium, this did not affect the SVF-derived erythroid cells.
CONCLUSION: Our results demonstrate that hematopoietic progenitors in SVF have molecular and functional features that differ from those exhibited by circulating progenitors, suggesting the possibility of a different origin.
Core tip: Stromal vascular fraction (SVF) from human adipose tissue contains mesodermal precursors with the ability to form mixed hematoendothelial colonies and hematopoietic colony-forming units, though this occurs at an extremely low frequency. It is well known that hematopoietic progenitors residing in the bone marrow are released into the circulation and enter peripheral tissues; therefore, the most plausible explanation for this hematopoietic activity is that these cells are actually circulating hematopoietic progenitors. However, it is also possible that they may originate from the adipose tissue itself. To address this hypothesis, we compared the expression levels of the most relevant hematopoietic transcription factors in cells isolated from SVF with their expression levels in CD34+ cells isolated from adult peripheral blood and cord blood. Moreover, because the composition of hemoglobin in erythroid cells varies depending on the origin of the hematopoietic progenitors and their ontogenic stage, burst-forming units-erythroid were developed in culture, and the hemoglobin composition and globin gene expression in erythroid colonies were determined. Our results provide evidence that erythroid progenitors contained in SVF exhibit features that differ from those of circulating progenitors. These findings should encourage further research on stem cells and the microenvironment of human adipose tissue.
Citation: Navarro A, Carbonell-Uberos F, Marín S, Miñana MD. Human adipose tissue contains erythroid progenitors expressing fetal hemoglobin. World J Stem Cells 2013; 5(4): 205-216
Adipogenesis and angiogenesis are two closely related processes during prenatal and postnatal life[1,2], and it has been proposed that CD34+CD31- cells are a common precursor for both adipocytes and endothelial cells[3]. In addition, angiogenesis is rapidly induced in growing adipose tissue[4-6]. Therefore, antiangiogenic factors could be potential targets for regulating fat cell development[7]. Because bone marrow-derived endothelial progenitor cells do not contribute significantly to neovascularization[8], endothelial cells must be present in the supportive stroma to enable the vascularization of the tissue. In support of this view, it has been reported that stromal-derived factor-1 produced by CD34+CD31+ cells induces the chemotaxis of CD34+CD31- cells expressing CXCR4 and leads to their differentiation into endothelial cells[9]. Moreover, a primitive population of CD34+CD90+ cells in human adipose tissue with a high proliferative capacity has been shown to be capable of differentiating into endothelial cells, even in the absence of angiogenic factors[10]. We also previously described, for the first time, the existence of a rare CD45-KDR+ cell population that exhibits hemangioblastic properties, as they give rise to hematoendothelial colonies[11]. These findings demonstrate the existence of mesodermal progenitors that can provide adipose tissue with endothelial progenitor cells when required. Additionally, CD45- cells produce hematopoietic colony-forming units (CFUs) when seeded in a methylcellulose-based medium[11]. Because adipose tissue is not hematopoietic in origin, it is possible that these CFUs are generated by circulating hematopoietic progenitors that target adipose tissue[12]. However, given that hemangioblasts are bipotent cells that give rise to endothelial and hematopoietic progenitor cells, it is tempting to speculate that these cells could be responsible for the production of these hematopoietic progenitors. To address this hypothesis, we examined the expression of genes directly involved in the process of hematopoiesis and analyzed the hemoglobin levels and globin gene expression in burst-forming units-erythroid (BFU-E)-derived colonies.
MATERIALS AND METHODS
Purification of human adipose tissue and cells
Human adipose tissue was obtained, after informed consent, from female patients between 30 and 40 years of age who were undergoing lipectomy at the University General Hospital of Valencia. The stromal vascular fraction (SVF) was obtained as previously described[11]. The SVF cells were labeled with anti-CD45 microbeads and separated into CD45+ and CD45- cells using a magnetic-activated cell sorting separation system (Miltenyi Biotec, GmbH, Bergisch Gladbach, Germany). In some experiments, the CD45- cells were separated on the basis of CD34 expression into CD45-CD34+ and CD45-CD34- subpopulations using anti-CD34 microbeads. To achieve a high degree of purity, the positive and negative cells were passed through a second column. After informed consent, cord blood (CB) samples were obtained from normal full-term deliveries, and peripheral blood (PB) samples were obtained from healthy adults between 20 and 50 years of age. The CD34+ cells were purified by positive selection using a CD34 Progenitor Cell Isolation Kit (Miltenyi Biotec). The purity of the isolated cells was determined by flow cytometry.
Short-term liquid culture
CD45+ and CD45- cells from the SVF and CB CD34+ cells were cultured in a serum-free medium (StemSpan; STEMCELL Technologies, SARL, Grenoble, France) in the presence of stem cell factor and Flt3-L (100 ng/mL each) in addition to thrombopoietin and interleukin-6 (20 ng/mL each) (R and D Systems, Abingdon, United Kingdom). The medium was supplemented with 40 μg/mL lipoproteins (MP Biomedicals LLC, Solon, OH, United States) and 1% bovine serum albumin (BSA). The SVF cells were plated at 5 × 105 cells/mL, and the CB cells were plated at 5 × 104 cells/mL. The cultures were incubated at 37 °C in a humidified atmosphere containing 5% CO2 and either 20% O2 or 5% O2. After seven days, the cells were harvested, counted and used for gene expression assays and clonogenic potential determination.
Clonogenic progenitor cell assay
The SVF CD45- and CD45+ cells (either freshly isolated or after seven days in liquid culture) and the CB or PB CD34+ cells were seeded in methylcellulose-based media with or without fetal bovine serum (Methocult GF H4435 or Methocult SF H4436; STEMCELL Technologies). Isolated or liquid-cultured SVF cells were plated at 5 × 105 cells per dish, and purified CD34+ cells were plated at 150 cells per dish. The cultures were incubated at 37 °C in a humidified atmosphere containing 5% CO2 and either 20% O2 or 5% O2. After 14-21 d, CFUs were scored according to their morphology using an inverted microscope.
Hemoglobin analysis
Individual BFU-E-derived colonies were selected from the semisolid cultures, pooled and washed. The cells were divided into two aliquots: one for FACS analysis to determine hemoglobin expression and the other globin gene expression analysis by real-time reverse transcription-polymerase chain reaction (RT-PCR). For the hemoglobin analysis, erythroid cells were fixed and permeabilized prior to staining with CD45-peridinin-chlorophyll protein complex, glycophorin A (CD235A) conjugated to allophycocyanin, fetal hemoglobin conjugated to FITC (all from BD Biosciences, Erembodegem, Belgium) and β-hemoglobin-PE (Santa Cruz Biotechnologies, Santa Cruz, CA, United States). The cells were analyzed using a FACSCanto II (BD Biosciences) with FACSDiva software (BD Biosciences).
Gene expression analysis
Total RNA was extracted using TRIzol Reagent and was subsequently treated with DNase(Deoxyribonuclease). cDNA was prepared using TaqMan Reverse Transcription Reagents. The real-time PCR experiments were performed using Mastermix and primers from Taqman Gene Expression Assays. All reagents and probes were purchased from Life Technologies (Foster City, CA, United States). The amplification protocol consisted of 95 °C for 10 min, followed by 40 cycles of 15 s at 95 °C and 1 min at 60 °C. Each reaction was performed in duplicate. For each sample, the cycle threshold (Ct) readings were determined using the Sequence Detection Software. All expression data were calculated relative to GAPDH controls as 2-∆Ct. The following primers were used: SCL/TAL1 (Hs001097987_m1), RUNX1 (Hs01021971_m1), RUNX2 (Hs01047978_m1), GATA1 (Hs01085823_m1), GATA2 (Hs00231119_m1), α-globin (HS00361191_g1), β-globin (HS00747223_g1) and γ-globin (HS00361131_g1).
Statistical analysis
Significant differences among the samples were tested using the Student t test or Mann-Whitney test where applicable. A P value less than 0.05 was considered statistically significant. The data were analyzed using GraphPad Prism Software 5.0 (GraphPad Software Inc., La Jolla, CA, United States).
RESULTS
SVF cells have hematopoietic activity in vitro
To demonstrate the presence of hematopoietic progenitor cells in human adipose tissue, SVF cells were separated into CD45+ and CD45- populations, and CD45- cells were further separated into CD45-CD34+ and CD45-CD34- populations (Figure 1). Clonogenic assays showed that the colony-forming ability of CD45- cells was restricted to CD34-expressing cells. As shown in Table 1, the CD45+ cells, which accounted for approximately 10%-20% of the SVF cells, generated four times more CFUs than their complementary CD45- cells; however, no differences in CFU distribution were found. Notably, this colony-forming ability was not affected by either serum deprivation or a low oxygen concentration (Table 1).
Table 1 Number of CFUs per 105 CD45+ or CD45- cells isolated from human adipose tissue stromal vascular fraction.
Figure 1 Purity of stromal vascular fraction populations.
Selected cell subsets from stromal vascular fraction were separated using specific monoclonal antibodies coupled to magnetic particles following magnetic cell separation technology. Representative dot plots of selected cells are shown. The numbers in the quadrants indicate the percentages of cells expressing the corresponding antigen. SVF: Stromal vascular fraction.
To evaluate the potential of hematopoietic progenitors to expand in vitro, SVF cells were cultured in a serum-free liquid medium containing early-acting cytokines for seven days and then tested for their colony-forming capacity. Under these culture conditions, the number of CFUs increased by approximately 7-fold in both the CD45+ and CD45- cell populations. Moreover, when the cells were cultured under hypoxic conditions (5% O2), the number of hematopoietic progenitors contained in the CD45- cell subset increased 3-fold over that under the normoxic condition (20% O2).
Hematopoietic transcription factors are expressed in SVF cells
To characterize the expression of hematopoietic progenitors in SVF, transcription factors involved in hematopoietic differentiation were analyzed by RT-PCR, and the gene expression levels were compared to those in the CD34+ cells from CB and from adult PB. As shown in Figure 2A, SCL/TAL1, RUNX1, RUNX2 and GATA2 were expressed at significantly higher levels in the SVF CD45+ cells than CD45- cells; however, GATA1 was not detected in either cell subset. When CD34+ hematopoietic cells were analyzed, the results showed that SCL/TAL1 and GATA2 were expressed at similar levels in the cells of neonatal and adult origin. However, the GATA1, RUNX1 and RUNX2 mRNA levels were significantly higher in the CD34+ cells from adult PB compared to CB (Figure 2A). We also compared the gene expression profiles of the SVF cells with those of the CD34+ cells from hematopoietic tissues and found that SCL/TAL1 and GATA2 were expressed at significantly higher levels in hematopoietic CD34+ cells than in SVF cells. However, the adult PB CD34+ cells expressed RUNX1 and RUNX2 at levels similar to the CD45- and CD45+ cells from SVF, respectively. Lastly, the SVF cells and CB CD34+ cells were cultured in liquid for seven days, and changes in their gene expression patterns were compared. The most important finding was that GATA1 could only be detected in the SVF cells after seven days of culture, whereas GATA1 expression was upregulated in the CB CD34+ cells. The SCL/TAL1, RUNX1 and GATA2 mRNA levels were decreased in all the cultured cells. Additionally, although RUNX2 gene expression was unchanged in both the CB cells and SVF CD45+ cells, its expression was slightly increased in the SVF CD45- cells (Figure 2B).
Figure 2 Hematopoietic transcription factors genes are expressed in isolated stromal vascular fraction cell populations.
A: Freshly isolated CD45+ and CD45- cells from stromal vascular fraction (SVF) and CD34+ cells from cord blood (CB) or adult peripheral blood (PB) were isolated via immunomagnetic methods and used for a gene expression analysis by reverse transcription-polymerase chain reaction (RT-PCR). The transcripts were normalized to glyceraldehyde-3-phosphate dehydrogenase (GAPDH); B: CB CD34+ cells and CD45+ and CD45- cells from the SVF were cultured in liquid serum-free medium containing early-acting cytokines for 7 d and then analyzed by RT-PCR to determine changes in the expression of selected genes. The transcripts were normalized to GAPDH, and the ratio between the gene quantity in cultured cells and the gene quantity in isolated cells was determined to yield a normalized fold change. CB CD34+ cells, n = 6-8; PB CD34+ cells, n = 3-4; SVF populations - CD45+ cells, n = 6; CD45- cells, n = 6. Levels of statistical significance: aP < 0.02, bP < 0.001. ND: Not detected. All samples were assayed in duplicate. SVF: Stromal vascular fraction; CB: Cord blood; PB: Peripheral blood; GAPD: Glyceraldehyde-3-phosphate dehydrogenase.
Erythroid cells derived from SVF express fetal hemoglobin
BFU-E-derived erythroid cells generated in semisolid culture from selected SVF cells or CB cells or PB CD34+ cells were analyzed for hemoglobin expression. As expected, virtually all the neonatal erythroid cells expressed fetal hemoglobin (HbF), whereas adult hemoglobin (HbA) was expressed in all the erythroid cells derived from adult PB CD34+ cells (Figure 3A and B). As shown in Figure 3E, the BFU-E-derived colonies generated from the SVF CD45- cells developed on a monolayer of stromal cells, whereas adherent cells were not found in the SVF CD45+ cell cultures. It is important to note that when the SVF-derived erythroid cells were analyzed, a high proportion of cells containing HbF together with HbA (HbF+HbA+) were observed; unexpectedly, some cells expressing only HbF (HbF+HbA-) and a very small proportion of cells expressing only HbA (HbF-HbA+) were also detected (Figure 3C).
Figure 3 Representative flow cytometric dot plots of hemoglobin expression in erythroid cells.
Burst-forming units-erythroid (BFU-E)-derived colonies were analyzed for HbF and HbA expression by flow cytometry after different lengths of time in culture. Erythroid cells generated from cord blood (CB) CD34+ cells (A), from peripheral blood (PB) CD34+ cells (B), and from stromal vascular fraction (SVF) cells (C). Representative fluorescence-activated cell sorting plots showing hemoglobin expression in circulating erythrocytes from CB and PB (D). Representative phase-contrast photomicrographs showing the morphological aspect of the BFU-Es generated from CD45- (left) and CD45+(right) cells isolated from SVF (E). HbF: Fetal hemoglobin; HbA: Adult hemoglobin; CB: Cord blood; PB: Peripheral blood.
The mean fluorescence intensity (MFI) of intracellular Hb-associated immunofluorescence was used to estimate the amount of intracellular hemoglobin per cell. However, because the majority of CB- and SVF-derived erythroid cells were growing in clusters containing a wide range of HbF and HbA levels, the samples were separated into two groups based on the MFI of HbF in the HbF+HbA+ cells. First, a comparison between the neonatal- and adult-derived erythroid cells was established. As shown in Table 2, the neonatal erythroid cells in group A exhibited the highest MFIs for HbF and HbA. The samples in group B exhibited an MFI for HbF similar to that observed in the adult-derived cells, but HbA was significantly lower in both, HbF+HbA+ and HbF-HbA+ cells compared to their corresponding adult-derived cells. Next, the MFIs of HbF and HbA in the SVF-derived cells were compared to those observed in the erythroid cells derived from the CD34+ hematopoietic cells from CB and adult PB. An analysis of the HbF+HbA- cells showed that HbF was expressed at similar and higher levels in the cells derived from the SVF CD45- population than in the neonatal cells corresponding to group A and B, respectively. In contrast, the erythroid cells derived from the SVF CD45+ population expressed HbF at a lower and similar intensity than the neonatal cells in group A and B, respectively. The expression level of HbF in the SVF HbF+HbA+ cells from group A was significantly lower than that observed in the cells of neonatal origin from the same group. However, the HbF expression level in the SVF-derived erythroid cells in group B was similar to that in both the neonatal and adult-derived erythroid cells of the same group.
Table 2 Mean fluorescence intensity of fetal hemoglobin and adult hemoglobin in hemoglobin-expressing erythroid cells.
Although the proportion of HbF-HbA+ cells in the SVF-derived erythroid colonies was very small, the MFI values showed that the cells from group B expressed HbA at levels similar to the adult-derived cells. However, no significant differences were found between the SVF-derived cells from group B and neonatal-derived cells in the same group. Lastly, an analysis of HbA in the SVF-derived HbF+HbA+ cells in group B revealed that HbA was expressed at similar levels (i.e., a similar MFI intensity) in the erythroid cells derived from CD45- progenitors and neonatal-derived cells in the same group. However, the MFI of HbA in the cells derived from CD45+ progenitors was similar to that of the adult-derived cells, suggesting that the erythroid progenitors contained within the CD45+ population must be at a later stage of maturation or differentiation.
MFI values were also used to estimate the contribution of HbF to the total hemoglobin levels. As shown in Table 2, the HbF/HbF + HbA ratio for erythroid cells derived from CB CD34+ cells was approximately 6.5- and 4.5-fold higher than that obtained for adult PB-derived cells, providing evidence for the neonatal origin of CB hematopoietic progenitors. The HbF/HbF + HbA ratio for the erythroid cells derived from SVF progenitors was between the levels obtained for the neonatal- and adult-derived cells.
In addition to our analysis at the cellular level, the expression of the globin gene was also examined. Interestingly, when the Ct values of the globin genes were normalized against GAPDH expression, the globin transcript levels in the erythroid cells derived from SVF or from CB varied widely. Therefore, three groups were defined on the basis of α-globin transcript levels (designated asI, II and III in Figure 4). We observed that the level of α-globin mRNA was always higher than that of β-globin in the erythroid cells generated from CD34+ cells from hematopoietic tissues (either CB or PB) (Figure 4A and D), whereas similar levels of α- and β-globin mRNA were observed in the SVF-derived erythroid cells (Figure 4B and C). As expected, the highest and lowest levels of γ-globin transcripts corresponded to neonatal- and adult-derived erythroid cells, respectively, whereas the erythroid cells generated from SVFs expressed γ-globin mRNA at levels ranging between those observed in the CB- and PB-derived cells (Figure 4A-D).
Figure 4 Analysis of globin gene expression in erythroid cells.
CD45+ and CD45- cells isolated from the stromal vascular fraction (SVF) and CD34+ cells from cord blood (CB) or adult peripheral blood (PB) were cultured in a methylcellulose-based medium, and burst-forming units-erythroid -derived erythroid cells were isolated at day 15 of culture to determine globin gene expression by reverse transcription-polymerase chain reaction. The transcripts were normalized to glyceraldehyde-3- phosphate dehydrogenase. Based on the α-globin levels, the values obtained for SVF- and CB-derived cells were placed into three groups (I, II and III). A: CB CD34+ cells, n = 10; B: SVF CD45- cells, n = 17; C: SVF CD45+ cells, n = 17; D: PB CD34+ cells, n = 4. All samples were assayed in duplicate.
The globin chain mRNA ratios were also calculated. As shown in Figure 5A, the α/(β + γ) globin ratio was 2.55 for the PB-derived cells and 0.55, 1.15 and 2.50 for CB-derived groups I, II and III, respectively. Additionally, the γ/(β + γ) globin ratios were 0.74, 0.57 and 0.56 for groupsI, II and III, respectively, though this ratio decreased to 0.04 in the PB-derived cells (Figure 5B).
Figure 5 Ratio of α to (β + γ) and of γ to (β + γ) globin mRNA in erythroid cells.
The values of transcript levels corresponding to the samples analyzed in Figure 4 were used to calculate the α/(β + γ) globin ratios (A) and γ/(β + γ ) globin ratios (B). The results are expressed as the mean ± SE. SVF: Stromal vascular fraction; CB: Cord blood; PB: Peripheral blood.
When erythroid cells derived from the SVF were analyzed, the α/(β + γ) globin gene mRNA ratios were very similar to those obtained in the CB-derived cells from groups I and II, ranging from 0.54 to 1.11 and from 0.56 to 0.87 in the cells derived from CD45- cells or CD45+ cells, respectively (Figure 5A). However, the γ/(β + γ) globin gene ratios were between those obtained for the CB- and PB-derived cells (Figure 5B).
Cellular distribution of hemoglobin in erythroid cells derived from SVF is not affected by serum deprivation
An analysis of the hemoglobin expression profile over the culture period showed that the proportion of HbF+HbA- cells gradually decreased and that HbF+HbA+ and HbF-HbA+ cells increased in the erythroid colonies generated from CB CD34+ progenitor cells (Figure 6A). Indeed, at the end of the culture period, the cellular distribution of hemoglobin was very similar to that exhibited by circulating erythrocytes in CB/placenta (Figure 3D). Therefore, this culture system recapitulates the neonatal pattern of hemoglobin expression in vivo. However, the cellular distribution of hemoglobin in the adult PB-derived erythroid colonies changed only slightly during the culture period. In contrast, in the cells derived from SVF, the most notable effect was a gradual decrease in the proportion of HbF+HbA- cells, which was accompanied by an increase in the proportion of the HbF-HbA+ cells. Therefore, at the end of the culture period, a large proportion of HbF+HbA+ cells continued to be observed in the erythroid colonies derived from both adult PB and SVF hematopoietic progenitors (Figure 6A).
Figure 6 Effects of time and cell culture conditions on the pattern of hemoglobin expression in erythroid cells.
Individual burst-forming units-erythroid (BFU-E)-derived colonies generated in a methylcellulose-based medium were selected, pooled and analyzed for hemoglobin expression by flow cytometry. A: The kinetics of HbF+HbA- cells, HbF-HbA+ cells and HbF+HbA+ cells of erythroid cells in the different cultures over time are given. From top to bottom: erythroid cells derived from cord blood (CB) CD34+ cells, from peripheral blood (PB) CD34+ cells, from stromal vascular fraction (SVF) CD45+ cells and from SVF CD45- cells. The results are expressed as the percentage of total Hb-expressing cells (CB CD34+ cells, n = 7; PB CD34+ cells, n = 4; SVF CD45+ cells, n = 10 and SVF CD45+cells, n = 10). The data are provided as the means ± SE; B: A parallel series of cultures were performed to examine the effect of serum deprivation and hypoxia (5% O2) on hemoglobin expression. Control cultures were grown under conditions of normoxia (20% O2) using a serum-containing medium. SVF cells, n = 10; CB CD34+ cells, n = 10; PB CD34+ cells, n = 4. BFU-E-derived erythroid cells were analyzed by flow cytometry for hemoglobin composition at day 15 of culture. The results are expressed as the percentage of total Hb-expressing cells. The data are provided as the mean ± SE. aP < 0.02, aP < 0.0001. ND: Not detected. CB: Cord blood; PB: Peripheral blood; SVF: Stromal vascular fraction.
The effect of serum deprivation and hypoxic conditions on hemoglobin expression was also examined. As shown in Figure 6B, when erythroid colonies derived from CB or PB CD34+ cells were developed in serum-free medium, a switch from HbF to HbA production was observed at the cellular level. Thus, the proportion of HbF+HbA+ cells was significantly decreased, whereas the proportion of HbF-HbA+ cells increased. However, no change in the proportion of HbF+HbA- cells was observed in the CB-derived colonies. Under these conditions, the cellular distribution of hemoglobin in the adult-derived erythroid cells was nearly identical to that observed in the circulating adult erythrocytes (Figure 3D). In sharp contrast, serum deprivation did not induce significant changes in the cellular distribution of hemoglobin in the erythroid colonies generated from SVF progenitors (Figure 6B). Serum deprivation also induced a dramatic reduction in the mRNA levels of all globins: the α- and β-globin transcript levels were reduced by approximately 90%-95% in erythroid cells derived from all three tissue sources. However, although the γ-globin transcript level was reduced by 95% in the SVF-derived erythroid cells, its level was decreased by 75% and 85% in the CB- and PB-derived cells, respectively.
Lastly, the effect of a low concentration of oxygen (5% O2) on hemoglobin synthesis was studied. As shown in Figure 6B, the erythroid colonies generated from CB CD34+ cells exhibited the same hemoglobin profile in both normoxia (20% O2) and hypoxia (5% O2). However, hypoxia induced a significant decrease in the proportion of HbF-HbA+ cells in the SVF erythroid cells, though no significant changes in HbF-expressing cell populations were observed.
When globin gene expression was analyzed, the results showed that the β-globin transcript level was significantly reduced (by approximately 55%, P < 0.05) in the CB-derived erythroid cells, whereas α- and γ-globin mRNA levels were only slightly decreased (by 20% and 25%, respectively). In contrast, α-globin expression was reduced (by approximately 45%, P < 0.04) in the erythroid cells derived from SVF, whereas the expression levels of β- and γ-globins were decreased and increased, respectively, by approximately 25%.
DISCUSSION
It is widely accepted that human hematopoietic stem and progenitor cells reside in the lineage (Lin)- fraction and are enriched in CD34+ cells that also express CD45 at moderate levels[13]. However, Lin-CD34-CD45- primitive hematopoietic cells with hematopoietic activity in vivo (with or without clonogenicity in in vitro assays) have recently been identified[14-18]. Although bone marrow is the primary site of hematopoiesis in adult humans, our group first described the presence of CD45- cells with hemangioblastic properties in human adipose tissue SVF[11]. Indeed, the finding that hematopoietic progenitors exist in adipose tissue is very exciting.
The present study shows that CD34-expressing cells are responsible for the ability of SVF-derived CD45- cells to produce CFUs and that the clonogenic efficiency of CD45- cells is significantly lower than that of their counterpart CD45+ cells. It has been proposed that adipose tissue in mouse models of obesity and in obese human subjects is in a hypoxic state[19,20]; thus, unlike circulating hematopoietic progenitors, hematopoietic progenitors in SVF may be exposed to mild hypoxia. Although hematopoietic stem cells are better preserved in culture under low O2 conditions compared to 20% O2[21-23] and hypoxia has been shown to be essential for the proliferation of embryonic hematopoietic progenitors[24], it remains controversial whether hematopoietic progenitors are better preserved or can be expanded under hypoxic conditions[23,25]. Herein, we show that hematopoietic progenitors derived from the SVF CD45- cell fraction, but not those derived from the SVF CD45+ cell fraction, were expanded under hypoxic conditions. These results could indicate that CD45- progenitors are at an earlier stage of differentiation than CD45+ progenitors.
In support of this hypothesis, the CD45+ cells expressed much higher levels of SCL/TAL1, GATA2, RUNX1 and RUNX2 compared to CD45- cells, which is consistent with their clonogenic potential. RUNX1 and RUNX2 mRNA levels were also significantly increased in the adult CD34+ cells compared to neonatal CD34+ cells. Because purified CD34+ cells include both hematopoietic stem and progenitor cells, these differences in gene expression could be explained by the higher number of proliferating hematopoietic progenitor cells in PB, as previously suggested[26-28]. However, GATA1 was unexpectedly not detected in either SVF population, in contrast to what was observed in the CD34+ cells from adult PB or CB. This finding was very surprising because GATA1, a late hematopoietic transcription factor, is directly involved in erythropoiesis[29] and the SVF cells were able to generate erythroid colonies. Importantly, after seven days in culture under conditions that facilitate the expansion of hematopoietic progenitor cells, GATA1 was detected in the SVF-derived cells and was overexpressed in the CD34+ neonatal cells. Moreover, GATA1 expression was higher in the PB CD34+ cells than in neonatal CD34+ cells, which was expected because GATA1 is upregulated in the later stages of commitment and differentiation[30-32]. Although GATA1 and GATA2 are essential in embryonic and adult hematopoiesis and the expression of GATA2 overlaps that of GATA1 in hematopoietic lineages[33], there are substantial differences between the GATA2 and GATA1 activities. GATA2 is highly expressed in quiescent hematopoietic stem cells and is necessary for their maintenance and expansion[34-36], whereas GATA1 is required for erythroid differentiation[29,32,36]. It has also been reported that the hematopoietic GATA factors are not functionally equivalent during adult hematopoiesis[37]. Therefore, differences in the expression levels of these key hematopoietic transcription factors between CD34+ cells from hematopoietic tissues and SVF cells lead us to suggest that these progenitors have a different origin.
To further characterize the hematopoietic function of the SVF-derived cells, we utilized the results from the study of BFU-E-derived colonies because the composition of hemoglobin in erythroid cells varies depending on the origin of the hematopoietic progenitors and their ontogenic stage[38-40]. HbF+HbA- cells were not only the most abundant cells in CB-derived erythroid colonies, but HbA was expressed at significantly lower levels in these cells compared to the adult PB-derived cells, indicating their early ontogenic stage. However, unlike the observations in the PB-derived erythroid cells, HbF was expressed by the majority of the erythroid cells produced by SVF progenitors, and γ-globin mRNA was more highly expressed in these cells than in the PB-derived cells.
Several important findings support the hypothesis that SVF hematopoietic progenitors may not have originated in the bone marrow. The first of these findings indicated that the mRNA level of α-globin was always higher than that of β-globin in the erythroid cells derived from hematopoietic tissues, which may be interpreted as a signature of their hematopoietic origin[41]. In contrast, α- and β-globins were synthesized at similar levels in SVF-derived cells.
The second of these findings is based on the different patterns of hemoglobin “switching” in response to culture conditions. As expected based on previous studies showing the serum-induced reversal of the hemoglobin switch[42-46], the erythroid progenitors from both adult and neonatal origin gave rise to a significantly higher proportion of HbF+HbA+ cells and a lower proportion of HbF-HbA+ cells when cultured in serum-containing medium. However, the profile of the hemoglobin synthesized by erythroid progenitors from the SVF was nearly identical in the presence or absence of serum.
Additionally, it is largely known that low oxygen concentrations affect erythropoiesis and the synthesis of the HbF[25,47-49]. Furthermore, in erythroid cells derived from erythroid progenitors from bone marrow or PB, it has been reported that the increase in HbF associated with hypoxia is concomitant with the early induction of γ-globin mRNA, and, in some circumstances, with the reduction of the β-globin mRNA, most likely as a consequence of the presence or absence of serum in the culture medium[49,50]. However, it has also been proposed that fetal and neonatal cells produce HbF irrespective of oxygen concentration[49]. Herein, we show that, although the neonatal-derived erythroid cells generated displayed the same hemoglobin profile under 20% O2 or 5% O2, importantly, β-globin expression was reduced by 55% in hypoxia, whereas γ-globin expression was not affected. However, in sharp contrast to the reactivation of HbF observed in the erythroid cells derived from adults, hypoxia did not induce an increase in the proportion of cells expressing HbF among the erythroid cells derived from SVF; rather, hypoxia caused a decrease in the number of cells expressing only HbA. A significant reduction in the level of α-globin, but not β-globin, was also observed.
Taken together, these results indicate the presence of early erythroid progenitors within the SVF and show that there are both differences in the regulation of globin gene expression at the transcriptional level and differences in the mechanisms that control the hemoglobin switch in these cells when compared to erythroid cells derived from hematopoietic tissues. Although this finding suggests that the origin of the early erythroid progenitors and therefore the origin of hematopoietic progenitors within the SVF is the adipose tissue rather than the hematopoietic tissue, this result is not conclusive. We cannot rule out that the adipose tissue niche might influence epigenetic patterns and the tissue-specific regulation of globin gene expression and hemoglobin production.
ACKNOWLEDGMENTS
The authors appreciate the technical assistance of the personnel in the Laboratory of Immunohematology and are especially grateful to Riol N for her expertise.
COMMENTS
Background
The authors’ previous observation of the existence of a small subset of CD45- cells in the stromal vascular fraction (SVF) of human adipose tissue with hemangioblastic properties in vitro and with the ability to produce hematopoietic colony-forming units led to the determination of the molecular and functional features of the hematopoietic progenitors contained in SVF.
Research frontiers
In this study, the authors demonstrated that the cellular distribution of hemoglobin and globin gene expression in the erythroid cells produced by the early erythroid progenitors in SVF are different from that observed in the erythroid cells derived from CD34+ hematopoietic progenitors from cord blood and adult peripheral blood, indicating a different origin of these cells. However, it is also possible that the adipose tissue niche might influence epigenetic patterns. Further studies on the basic biology of adipose-derived primitive mesodermal cells and the adipose tissue niche may be important for a better understanding of adult stem cells and for cell-based therapies.
Innovations and breakthroughs
Adipose tissue, similar to bone marrow, is derived from the embryonic mesoderm and contains a highly heterogeneous stromal cell population; however, unlike bone marrow, adipose is not a hematopoietic tissue. To our knowledge, this is the first report to demonstrate the existence of hematopoietic progenitors in human adipose tissue and reveal their characteristics at the cellular and molecular levels.
Applications
Evidence is provided that the erythroid progenitors contained in human adipose tissue are more primitive than those in the circulation and that the regulation of globin gene expression is tissue-specific. This study may provide new insights that will be helpful for elucidating the potential of adipose-derived primitive mesodermal cells and for understanding the characteristics and function of the adipose stem cell niche.
Terminology
Hematopoietic stem cells are responsible for the maintenance of all blood cell types and are characterized by their self-renewal capacity. These cells give rise to multipotent, oligopotent and unipotent hematopoietic progenitor cells. Burst-forming units-erythroid is the earliest erythroid progenitor responsible for erythrocyte generation.
Peer review
In the manuscript, the authors demonstrated that stromal vascular fraction of human adipose tissues expressed fetal hemoglobin. This is an interesting study. The methods of this study are reasonable and results are clear.
Footnotes
P- Reviewers Liu SH, Wang TH S- Editor Gou SX L- Editor A E- Editor Wu HL
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