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RED CELLS
From the Unità Operativa Ematologia e Centro
Trapianto di Midollo Osseo, Ospedale di Muraglia, Azienda Ospedale 'S.
Salvatore' Pesaro, Italy; and the Division of Hematology,
Stanford University School of Medicine, Stanford, CA.
Beta-thalassemia major is characterized by ineffective
erythropoiesis leading to severe anemia and extensive erythroid
expansion. The ineffective erythropoiesis is in part due to accelerated
apoptosis of the thalassemic erythroid precursors; however, the extent
of apoptosis is surprisingly variable. To understand this variability as well as the fact that some patients undergoing allogeneic marrow transplantation are resistant to the myeloablative program, we attempted more quantitative analyses. Two groups of patients totaling 44 were studied, along with 25 healthy controls, and 7 patients with hemolysis and/or ineffective erythropoeisis. By 2 flow cytometric methods, thalassemic erythroid precursors underwent apoptosis at a rate
that was 3 to 4 times normal. Because thalassemic marrow has between 5- to 6-fold more erythroid precursors than healthy marrow, this
translated into an absolute increase in erythroid precursor apoptosis
of about 15-fold above our healthy controls. In searching for the
causes of the variability in thalassemic erythroid precursor
apoptosis, we discovered tight direct correlations between the
relative and absolute extent of apoptosis and the extent of erythroid
expansion as measured either by the absolute number of marrow erythroid
precursors or by serum soluble transferrin receptor levels. These
results could mean that the most extreme rates of erythroid
proliferation lend themselves to cellular errors that turn on apoptotic
programs. Alternatively, extreme rates of erythroid hyperplasia and
apoptosis might be characteristic of more severely affected patients.
Lastly, extreme erythroid hyperplasia could generate such numbers of
apoptotic erythroid precursors that marrow macrophages are overwhelmed,
leaving more apoptotic cells in the sample.
(Blood. 2000;96:3624-3629) Homozygous Patients
Group 1 patients.
Initially, 14 patients with severe Group 2 patients.
Bone marrow samples were obtained for clinical purposes from 30 patients with transfusion-dependent Isolation and harvesting of erythroid precursors. For group 1 patients, the marrow samples, still cold, arrived at Stanford after 36 to 48 hours and were subjected to Ficoll separation (Isoprep 1077; Robbins Scientific Corp, Sunnyvale, CA) to concentrate the cells and remove red blood cells (RBCs). Then the erythroid precursors were separated as before6 using CD45 negativity as the marker. However, rather than panning, magnetic bead column separation (Miltenyi Biotech, Auburn, CA) was used. CD45 micromagnetic beads were added to the suspension of marrow cells, incubated on ice for 30 minutes, then washed twice with phosphate-buffered saline (PBS) containing 0.5% FBS, and 1 mmol/L EDTA. The cells were then suspended in 0.5mL of the same buffer and passed through a Miltenyi magnetic column. Because the CD45 antigen is strongly expressed on leukocytes and monocytes, the immunobeads bind to these cells and not the erythroid precursors.6 Passing the suspension over a magnetic column binds the CD45 positive cells, whereas the CD45 negative erythroid precursors pass freely through the column from which they are collected and counted.For group 2 patients, the bone marrow mononuclear cells were immediately isolated by density gradient centrifugation using Ficoll-Hypaque (specific gravity 1.077) (Lymphoprep; Nyegard, Oslo, Norway) following standard methods of Ficoll-separation technique. The cells were washed twice with PBS containing 0.01% bovine serum albumin (BSA), and resuspended in PBS. Isolation of the erythroid precursors cells was accomplished by negative selection incubating 10 × 106 bone marrow cells, with 1 mg of anti-CD45 magnetic immunobeads (Immunotech International, Marseille, France), suspended in 1 mL of PBS supplemented with 30% fetal calf serum. The suspension was incubated 10 minutes at 4°C, mixing after 5 minutes. Marrow erythroid precursor differential counts (200 to 500 cells counted) were performed on the May-Grunwald-Giemsa cytospin preparations. Measurement of apoptosis by flow cytometry Group 1 patients. To be confident about the extent of apoptosis in the separated erythroid precursors, 2 methods were used. The well-studied Hoechst dye 33342 kinetically labels nuclei of cells undergoing apoptosis.9 To 0.5 mL containing 1 × 106 erythroid precursors, we added 10 µL of Hoechst 33342 (10 µg/mL) (Molecular Probes, Eugene, OR) and incubated the mixture for exactly 4 minutes at 37°C, after which the samples were immediately placed on ice. Just before flow cytometry 10 µL of propidium iodide (PI) (20 µg/mL) (R&D Systems, Minneapolis, MN) was added to identify dead cells (PI positive) as well as apoptotic cells (Hoechst 33342 positive). Apoptotic erythroid precursors were also identified and measured using fluorescein isothiocyanate-labeled Annexin V (FITC-AnV) (Boehringer, Mannheim, Germany) or Annexin V kit (R&D Systems). Annexin V (AnV) binds to phosphatidylserine that has moved from the inner to the outer leaflet of the plasma membrane phospholipid bilayer, a very early event in apoptosis.10-12 After washing twice with PBS, 1 × 106 CD45 negative cells were resuspended in 0.5 mL of binding buffer (10 mmol/L hepes/NaOH, pH 7.4,140 mmol/L NaCl, 2.5 mmol/L CaCl2). FITC-AnV was added to a final concentration of 0.5 µg/mL. Cells were incubated 10 minutes at room temperature. To identify the proportion of dead cells, 10 µL of the 20 µg/mL PI stock solution were added to the cell suspension. The mixture was then analyzed by flow cytometry. This assay allows us to discriminate alive erythroid precursors (AnV /PI), dead
precursors with a damaged plasma membrane
(AnV+/PI+), and apoptotic precursors with a
still functional plasma membrane barrier
(AnV+/PI).
Group 2 patients. Having established the fact that both methods produced similar results,13 we relied on the Annexin V method to which we added further measurements to identify the extent of the erythroid expansion as well as the other cellular components of the marrow. Apoptosis was evaluated by FACS analysis on the bone marrow erythroid precursors (CD45 negative), using FITC-AnV (Kit Bender MedSystems Diagnostic GmbH, Vein, Austria). After washing twice with PBS 5 × 105, CD45 negative cells were resuspended in 1 mL of binding buffer (10 mmol/L hepes/NaOH, pH 7.4, 140 mmol/L NaCl, 2.5 mmol/L CaCl2). FITC-AnV was added to 195 µL of the cell suspension to a final concentration of 1 µg/mL. Cells were incubated 10 minutes at room temperature, then washed once and resuspended in 190 µL of binding buffer. To identify the proportion of dead cells, 10 µL of the 20 µg/mL PI stock solution was added to the cell suspension, resulting in a final concentration of PI 1 µg/mL. The mixture was then analyzed by flow cytometry. Quantitative fluorescent analysis was performed using a FACScan (EPICS ELITE, Coulter, Hialeah, FL). From the analysis of forward and 90° light scatter, a gate was established to include all leukocytes. Ten thousand cellular events were recorded in all experiments at this gate. To calculate the total number of reactive cells per milliliter of bone marrow samples, the percentage of the reactive cells was multiplied by the total number of white bone marrow cells per milliliter of the sample. Measurement of the extent of erythroid expansion Erythroid expansion was evaluated both by FACS analysis on bone marrow mononuclear cells and by an enzyme-linked immunosorbent assay (ELISA) on peripheral blood sera.FACS analysis. Immunophenotypic analysis was performed using commercial mouse monoclonal antibodies conjugated to phycoerythrin or fluorescein directly against the following human leukocyte differentiation antigens: CD45 FITC (2D1, Becton Dickinson Immunocytometry System, San Jose, CA), CD71 FITC (YDJ.1.2.2 Immunotech International, Marseille, France), and CD16 PE (B73.1, Becton Dickinson Immunocytometry System). For each of the above, 500 000 cells were seeded into each tube and incubated for 20 minutes at 4°C with a saturating concentration of each conjugated monoclonal antibody, then washed twice. The samples were then analyzed by flow cytometry using the same procedure previously described. Serum samples and enzyme immunoassay.
Blood samples were obtained from the antecubital vein and left to clot
at room temperature, and then centrifuged and immediately aliquoted and
stored at Statistical analysis Data are expressed as mean ± SD unless otherwise specified.Groups were compared by Mann-Whitney U test. Correlation between 2 parameters were estimated by the Pearson coefficient of correlation and by linear regression analysis. All tests were 2-tailed and a significance level of .05 was used.
Marrow erythroid hyperplasia For these measurements, exactly 5 mL of marrow was aspirated. Nucleated marrow cells were counted by an automated cell counter. The absolute number of nucleated marrow cells was 45 ± 32 × 106 in the thalassemic patients and 16 ± 5 × 106 in the controls (P < .001). There were about 2.8 times as many marrow cells in the thalassemic samples. Moreover 21 of 30 patients showed an inverted M:E ratio as evaluated by the differential count of the bone marrow cells on the May-Grunwald-Giemsa-stained marrow films.14 The percentages of the nucleated marrow cells that are erythroid precursors determined by flow cytometry as detected either by CD45 negativity or by CD71 positivity (transferrin receptor), respectively, were as follows: 37 ± 15 for the thalassemics versus 19 ± 5 for the controls (P < .001), and 25 ± 17 for the thalassemics versus 9 ± 2 for the controls (P < .05). Proportionately, there are 2 to 3 times more erythroid precursors in the thalassemic samples. An erythroid precursor differential count was also performed. Thalassemic patients had a preponderance of younger forms as indicated by an increased percentage of basophilic erythroblasts (P < .015) and a decreased percentage of orthochromic erythroblasts (P < .005), when compared with controls (Figure 1). An increased number of CD16+ cells was also observed in thalassemic patients compared with controls (6.5 ± 3.3 versus 3.1 ± 1.4 × 106/mL, P < .005).
Apoptosis As before,6 cytologic analysis of the CD45 negative cell suspensions showed that at least 95% of the mononuclear cells present were erythroid precursors (not shown).Group 1 patients.
Figure
2
shows the flow cytometric analysis of bone marrow from a patient with
Group 2 patients.
Marrow aspirates of 30 more patients with
Correlation between erythroid hyperplasia and apoptosis In searching for an explanation for the variation in levels of apoptosis in the -thalassemic patients (Figure 3, Tables 1 and 2),
we observed tight direct correlations between both the relative (Figure
4) and absolute (Figure
5) numbers of apoptotic erythroid
precursors (CD45/AnV+) and the extent of
erythroid expansion as indicated by the absolute numbers of CD 45 negative erythroid precursors (r = 0.59,
P < .001; r = 0.92, P < .001,
respectively). When the relative and absolute numbers of apoptotic
erythroid precursors were plotted against the absolute number of CD71
positive marrow cells (an alternative marker of erythroid precursors),
similar tight direct correlations were obtained (not shown).
An indicator of overall erythropoietic activity that is independent of
the variations in marrow aspiration, sampling, and flow cytometry is
the serum level of soluble transferrin receptor15 (sTfR).
There was again a strong correlation between the extent of erythroid
expansion expressed by sTfR levels and both the proportion (Figure
6) and absolute numbers (not shown) of
thalassemic erythroid precursors undergoing apoptosis. No such
correlations between apoptosis and numbers of erythroid precursors were
observed in comparable studies on healthy control marrow samples (not
shown).
We had 3 aims in this study: (1) to discover the extent and
severity of apoptosis in the erythroid precursors of patients with
To extend and quantify our first qualitative demonstration of increased
apoptosis in These studies on group 1 patients, although providing requisite
quantitative data, uncovered interesting biologic problems. One was
that the extent of apoptosis was quite variable in patients who seemed
to be clinically and genotypically quite similar. The second was that
measurement of the percentage of erythroid precursors undergoing
apoptosis greatly underestimated the problem in To analyze these questions we needed a more quantitative approach to
the analysis of erythroid precursors in Therefore, we extended the study to group 2 patients specifically trying to assess the impact of the extent of erythroid expansion. Our results show that the extent of the thalassemic erythroid hyperplasia quantitatively evaluated by absolute counts of CD45 negativity and CD71 positivity, directly correlates with the relative and absolute extent of erythroid precursor apoptosis (Figures 4 and 5). The use of the soluble serum transferrin receptor level15 as an index of overall erythropoiesis showed similar direct correlations with the relative extent of apoptosis (Figure 6). An important question is whether increased erythroid apoptosis is a
specific pathophysiologic lesion in An important consideration is whether ineffective erythropoiesis is invariably characterized by increased erythroid apoptosis. There is morphologic evidence of increased erythroid apoptosis in congenital dyserythropoietic anemia18 in which erythropoiesis is ineffective. Ineffective hematopoiesis has been reported in 19 patients with myelodysplastic syndrome (7 RA, 7 RAEB, 5 RAEBt).19 However, in 2 reports on megaloblastic anemia encompassing 17 patients with folate or cobalamin deficiency, using methods similar to this20 and our prior study,21 there was no increase in erythroid apoptosis even though there was distinct evidence (increased PI+) of intramedullary erythroid cell death.20 Neither of our 2 patients with sideroblastic anemia showed an increased proportion of apoptotic erythroid precursors (Table 3). Therefore, the association of increased erythroid apoptosis with ineffective erythropoiesis is not invariable. There are several hypotheses, not mutually exclusive, which might explain why profound erythroid expansion should lead to a relative and absolute increase in thalassemic erythroid precursor apoptosis. When a cell line is forced by physiologic or pathologic mechanisms to increase its proliferative rate, the chances for errors increase, leading to aberrations that are detected by the affected cells, which then turn on their apoptotic programs.22,23 A second explanation is that we measure erythroid precursor apoptosis directly from our patients' marrow at a single point in time. However, one of the biologic aims of apoptosis is to identify damaged cells and remove them, thus limiting any damage such cells might do. Phosphatidylserine is translocated from the inner to the outer layer of the plasma membrane24,25 of apoptotic cells, where it can be recognized and the affected cells removed by macrophages.26,27 Therefore, our measurement of apoptosis is a composite of the erythroid precursors undergoing apoptosis at that moment versus the ability of marrow macrophages to remove them. At the higher levels of erythroid hyperplasia, the extent of apoptosis may exceed the ability of marrow macrophages to remove such cells, leading to higher apparent levels of apoptosis. The number of CD16+ cells (described in "Results"), many of which are macrophages, is increased 2-fold in the marrow of our thalassemic patients, and the in vitro capacity of macrophages to phagocytose thalassemic versus normal erythroid precursors is also increased 2-fold,28 leading to a possible quadrupling of phagocytic capacity. In contrast, the absolute increase in apoptosis in our patients is 14-fold. However, the activation or up-regulation of thalassemic phagocytes may further increase their effectiveness.29 This hypothesis does not explain the decreased number of orthochromic erythroblasts observed in our patients (Figure 1). A third explanation is that, for unclear reasons, the patients with greatly increased apoptosis and erythroid expansion have a more severe disease. It is not clear why patients with extreme erythroid hyperplasia may be resistant to the preparative myeloablative therapy and reject their graft. We are currently testing the role of hypertransfusion in the preparative program in such patients to reduce the extreme erythroid hyperplasia.
We thank Dr Locatelli for providing a bone marrow sample from a patient with sideroblastic anemia.
Submitted March 22, 2000; accepted July 24, 2000.
Preliminary reports of this work in progress were presented at the annual meetings of the American Society of Hematology in 1996, (Blood; 88 suppl 1, Abstract:2817, 1996), 1998 (Blood 92 suppl 1 Abstract 3134, 1998) and 1999 (Blood 94 suppl 1 Abstract 1868, 1999).
Supported by Fondazione Berloni contro la Talassemia, Pesaro, Italy, and a grant from the NIH RO1-DK 13682 (S.L.S.).
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
Reprints: Guido Lucarelli, Unità Operativa di Ematologia e Centro Trapianto di Midollo Osseo, Azienda Ospedale di Pesaro, 61100 Pesaro, Italy; e-mail: g.lucarelli{at}wnt.it.
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© 2000 by The American Society of Hematology.
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S. Gardenghi, M. F. Marongiu, P. Ramos, E. Guy, L. Breda, A. Chadburn, Y. Liu, N. Amariglio, G. Rechavi, E. A. Rachmilewitz, et al. Ineffective erythropoiesis in -thalassemia is characterized by increased iron absorption mediated by down-regulation of hepcidin and up-regulation of ferroportin Blood, June 1, 2007; 109(11): 5027 - 5035. [Abstract] [Full Text] [PDF]
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| Copyright © 2000 by American Society of Hematology Online ISSN: 1528-0020 | |||||||||
-thalassemia major
Top
Abstract
Introduction
versus 
80°C until assayed. Soluble transferrin receptor levels
were measured by a commercially available sandwich ELISA kit (Amgen
Diagnostics, Thousand Oaks, CA).
; thalassemics, 
. Mean values are shown within the
bars, and the error lines indicate the SD values.
