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Prepublished online as a Blood First Edition Paper on April 17, 2002; DOI 10.1182/blood-2002-01-0136.
HEMATOPOIESIS
From the Departments of Hematology and Rheumatology,
Clinical Immunology and Allergiology of the University of Crete School
of Medicine, Heraklion, Crete, Greece.
Circumstantial evidence has implicated tumor necrosis factor Substantial evidence indicates that inflammatory
cytokines subserve a crucial role in joint destruction and disease
propagation in rheumatoid arthritis (RA).1 Among these
cytokines, tumor necrosis factor The successful effect of therapeutic blockade of TNF- The availability of cA2 and its beneficial effect in patients with RA
provides the opportunity to directly address the role of TNF- Patients
Peripheral blood samples
BM samples The BM samples from posterior iliac crest were aspirated at baseline and after 6 doses of cA2. BM cells were immediately diluted 1:1 in Iscoves modified Dulbecco medium (IMDM; Gibco BRL, Life Technologies, Palsley, Scotland), supplemented with 100 IU/mL penicillin-streptomycin (PS; Gibco BRL, Life Technologies) and 10 IU/mL preservative-free heparin (Sigma, St Louis, MO). Diluted BM samples were centrifuged on Lymphoprep (Nycomed Pharma, Oslo, Norway; density 1.077 g/cm3) at 400g for 30 minutes at room temperature to obtain the BM mononuclear cells (BMMCs). Cell number and viability were assessed after staining with trypan blue.Purification of CD34+ cells CD34+ cells were isolated from BMMCs by indirect magnetic labeling (magnetic activated cell sorting; MACS isolation kit, Miltenyi Biotec, Bergisch Gladbach, Germany) according to the manufacturer's protocol. In each experiment, purity of CD34+ cells was more than 96% as estimated by flow cytometry.Clonogenic progenitor cell assays We cultured 105 BMMCs or 3 × 103 CD34+ cells in 1 mL culture medium supplemented with 30% fetal calf serum (FCS; Gibco BRL, Life Technologies), 1% bovine serum albumin (BSA; Gibco BRL, Life Technologies), 10 4 M
mercaptoethanol (Sigma), 0.075% sodium bicarbonate (Gibco BRL, Life
Technologies), 2 mM L-glutamine (Sigma), and 0.9%
methylcellulose (Stem Cell Technologies, Vancouver, BC, Canada), in the
presence of 5 ng granulocyte-macrophage colony-stimulating factor (R & D Systems), 50 ng IL-3 (R & D Systems), and 2 IU EPO (Janssen-Ciliag, Athens, Greece). Cultures were set up in duplicate in 35-mm Petri dishes and incubated at 37°C in 5% CO2 fully humidified
atmosphere. On day 14, erythroid-burst forming units (BFU-Es) were
identified and scored according to established criteria.16
When mentioned, a mouse antihuman TNF- monoclonal neutralizing
antibody (R & D Systems) was added to the culture at a concentration of
1.8 µg/mL. According to the manufacturer, the neutralization
dose50 for this antibody is 0.02 to 0.04 µg/mL in the
presence of 0.25 ng/mL TNF-.
Long-term BM cultures Long-term BM cultures (LTBMCs) from 107 BMMCs were grown according to the standard technique17,18 in 10 mL IMDM supplemented with 10% FCS, 10% horse serum (Gibco BRL, Life Technologies), 100 IU/mL PS, 2 mmol L-glutamine, and 106 mol hydrocortisone sodium succinate (Sigma) and
incubated at 33°C in 5% CO2 fully humidified atmosphere.
At weekly intervals, cultures were fed by removing half of the medium
and replacing it with equal volume of fresh IMDM supplemented as above.
By allowing the formation of an adherent layer consisting mainly of
macrophages and cells of mesenchymal origin, this culture system has
been considered instrumental to evaluate the regulatory role of BM microenvironment on hematopoietic progenitor cell
growth.19 The adherent layer is usually confluent after 3 to 4 weeks and, at that time point, cell-free supernatants may be
harvested and stored at  70°C for cytokine quantification. In the
present study, TNF- concentration in the supernatants was
quantitated by means of a commercially available ELISA kit (Biosource
International, Camarillo, CA). According to the manufacturer,
the sensitivity of this assay is less than 0.09 pg/mL.
Immunophenotyping and 7-amino-actinomycin D staining Flow cytometry was used to identify the BM erythroid cells at different maturational stages. Specifically, aliquots of 100 µL BM cells were washed twice in phosphate-buffered saline (PBS)-1% FCS-0.05% azide and incubated with 40 µL human -globulin for 10 minutes on ice. Cells were then either stained with phycoerythrin (PE)-conjugated mouse antihuman CD34 mAb (QBEND-10; Immunotech, Marseille, France) and fluorescein isothiocyanate (FITC)-conjugated mouse antihuman transferrin receptor (CD71) mAb (YDJ1.2.2; Immunotech) or with PE-conjugated mouse antihuman glycophorin A (glycoA) mAb (11E4B7.6; Immunotech) and FITC-conjugated mouse antihuman CD36 mAb
(FA6.152; Immunotech) and incubated for 30 minutes on ice. Following 2 washes with PBS-1% FCS-0.05% azide, the cells were further stained
with 100 µL 7-amino-actinomycin D solution (7AAD; 200 µg/mL;
Calbiochem-Novabiochem, La Jolla, CA), suspended in 1 mL PBS and
incubated for 20 minutes on ice protected from light as previously
described.20 Following centrifugation, the supernatant was
removed, contaminating red cells were lysed with 0.12% formic acid,
and samples were fixed in 0.2% paraformaldehyde using the Q-prep reagent system (Coulter, Luton, England).21 Fixed
cells stained with the isotypic control antibodies but not with 7AAD, were used as negative controls.
Quantitative fluorescence analysis was performed in an Epics Elite
model flow cytometer (Coulter, Miami, FL) within 30 minutes of cell
fixation, using 5 parameters: forward light scattering, 90° left-side
light scattering, and triple-color immunofluorescence from FITC, PE,
and 7AAD. Spillover of each fluorescence into other fluorescence
detectors was electronically compensated to background levels by using
cells stained only with the respective fluorescence-labeled mAb or
7-AAD. List mode data were collected for 500 000 events and analyzed
using Epics Elite. After drawing a region around the cells with low
forward and low side scatter properties where erythroid progenitor and
precursor cells are included,22 2 scattergrams were
created by combining CD34 with CD71 fluorescence and glycoA with CD36
fluorescence gated in the above region. Finally, a scattergram was
generated by combining forward light scatter with 7AAD fluorescence to
quantitate 7AAD-negative (live), -dim (early apoptotic), and -bright
(late apoptotic) cells in the gates of
CD34+/CD71+,
CD36+/glycoA+, and
CD36
Incubation of normal bone marrow cells with recombinant human
TNF- (rhTNF-; R & D Systems) at a concentration of 10 ng/mL
and 20 ng/mL. Following a 48-hour incubation in 37°C in
5%CO2 fully humidified atmosphere, cells were washed twice
with PBS-1% FCS-0.05% azide, stained, and analyzed by flow cytometry
as described above.
Statistical analysis Numerical data were analyzed in the GraphPad Prism statistical PC program (GraphPad Software, San Diego, CA) by means of the nonparametric Mann-Whitney U test, the Student t test for paired samples, and the Pearson coefficient of correlation. One-way analysis of variance (ANOVA test) was used to define differences in the percentage of apoptotic cells obtained in cultures treated with various concentrations of rhTNF-. Homogeneity of the
populations studied was tested by means of the  2 test.
Flow cytometric analysis of BM erythroid cells The CD34+/CD71+ cell compartment includes the early erythroid progenitor cells, whereas the CD36 cell surface marker is expressed on erythroid progenitor and early precursor erythroid cells but is lost during the subsequent erythroid differentiation.23 GlycoA is expressed on mature erythroid cells but is not present on the early progenitors.22 Accordingly, the CD36+/glycoA+ and CD36/glycoA+ cells represent the early and
mature precursor cells of the erythroid development, respectively.
Flow cytometric analysis of BM erythroid cells in our patients is
presented in Table 2. Patients (n = 21)
had significantly lower numbers of CD34+/CD71+
cells compared to the healthy controls (n = 21,
P = .0011). The proportion of CD71+ cells
within the CD34+ cell fraction was significantly lower in
the patients (20.96 ± 11.58) compared to the controls
(33.21 ± 11.11, P = .0027), suggesting that the
reduction of the CD34+/CD71+ cells in RA
patients does not simply reflect the low number of total
CD34+ cells previously reported in RA5 but
concerns specifically the erythroid progenitors. The proportion of
glycoA+ cells was also significantly reduced in the
patients (86.43 ± 4.68) compared to the controls (90.84 ± 3.90,
P = .0020). This decrease was essentially due to the lower
proportion of the mature CD36
Apoptosis of the BM erythroid cells It has been previously shown that apoptotic control mechanisms contribute to the regulation of BM erythropoiesis.24 To explore whether the decrease of BM erythroid cells in RA patients is due to increased apoptotic cell death, we evaluated the percentage of apoptotic cells within the BM erythroid cell compartments (Figure 2). We found that patient (n = 21) CD34+/CD71+ and CD36+/glycoA+ cells contained a significantly higher proportion of apoptotic cells (7AADdim plus 7AADbright cells; 25.50% ± 18.44% and 42.87% ± 23.75%, respectively) compared to the healthy controls (n = 21; 11.36% ± 6.13% and 8.35% ± 6.76%, respectively; P = .0053 and P < .0001, respectively). In contrast, no statistically significant difference was found between patients and controls in the percentage of apoptotic cells detected in the CD36/glycoA+ cell compartment
(3.53% ± 4.54% and 2.29% ± 0.90%, respectively; P = .0671). In a subset analysis we found that RA patients
with ACD displayed significantly increased apoptosis within the
CD36+/glycoA+ cell fraction (50.88% ±
19.55%) and a trend toward higher apoptosis within the
CD34+/CD71+ cell compartment
(31.71% ± 21.72%), compared to the nonanemic patients
(34.44% ± 19.11% and 19.39% ± 11.41%, respectively;
P = .0412 and P = .1490, respectively).
Compared to the controls, however, both patient groups, the ACD and
nonanemic, displayed significantly increased proportions of apoptotic
cells within the CD34+/CD71+
(P = .008 and P = .047, respectively) and the
CD36+/glycoA+ (P < .0001 and
P = .0002, respectively) but not the
CD36/glycoA+ (P = .0775 and
P = .9490, respectively) cell compartments. Taken together, these data suggest that RA patients, particularly those with
ACD, display increased apoptosis in the BM erythroid progenitor and
early precursor cell compartments but not in the mature precursor cell population.
BFU-Es The frequency of BFU-Es in the BMMC fraction was evaluated in 26 patients with RA prior to cA2 treatment and in 24 healthy controls. Results are depicted in Figure 2. Of these patients, 14 had normal hemoglobin levels, whereas the remaining 12 had ACD. In the entire group of patients studied, the mean BFU-E number obtained by 106 BMMCs was significantly lower than the respective value obtained in the controls (200 ± 131 versus 420 ± 186, P < .0001). Compared to the controls, BFU-E numbers were significantly lower in both the nonanemic (268 ± 148 BFU-E/106 BMMCs, P = .021) and ACD (142 ± 81 BFU-E/106 BMMCs, P < .0001) groups of patients. Furthermore, BFU-E frequency was significantly lower in patients with ACD compared to the nonanemic patients (P = .022).To investigate whether the decreased BFU-E colony formation in RA patients is due to the lower number of erythroid progenitor cells in the BMMC fraction or is the consequence of an intrinsic progenitor cell defect, we evaluated the clonogenic potential of immunomagnetically sorted CD34+ BM cells. We found that the number of BFU-Es obtained by 5 × 104 CD34+ cells was significantly lower in the patients (147 ± 88, n = 12) compared to the controls (310 ± 107, n = 19; P = .0005) suggesting a defect in the clonogenic potential of patient progenitor cells possibly due to the presence of increased number of apoptotic cells. Endogenous EPO production Erythropoietin is the principal growth factor for maintaining erythroid progenitor cell survival. It has been demonstrated that deprivation of EPO induces apoptosis of immature erythroid colony-forming cells through down-regulation of Bcl-X(L) antiapoptotic protein.25 To investigate whether increased apoptosis of patient BM erythroid cells might be due to decreased endogenous EPO production, we evaluated EPO levels in 14 ACD or nonanemic RA patients. Results were compared to serum EPO levels of a reference group (55 healthy individuals or subjects with IDA). There was no statistically significant difference in hemoglobin levels between patients (mean, 11.70 ± 1.67 g/dL; range, 8.1-14.2 g/dL) and control subjects (mean, 12.54 ± 2.25 g/dL; range, 6.0-16.3 g/dL; P = .196). We found that EPO levels did not differ statistically between the RA group (mean, 20.75 ± 19.28 mIU/mL; range, 5.15-80.0 mIU/mL) and the reference group (mean, 21.63 ± 30.76 mIU/mL; range, 2.70-140 mIU/mL; P = .0688). EPO levels inversely correlated with hemoglobin values in both the RA group (r =0.808,
P < .001) and the reference group (r = 0.895,
P < .0001; Figure 3).
Furthermore, to characterize EPO production as appropriate or
inappropriate for a given hemoglobin value in our patients, we defined
the observed/predicted ln(EPO) ratio (O/P ratio) for each sample as
previously reported.26 The mean O/P ratio in the patients
(0.99 ± 0.12) was within the 95% confidence limits (0.95-1.08) of
the reference group (mean O/P ratio 1.01 ± 0.24,
P = .687) suggesting an adequate EPO production in our
patients and indicating that mechanism(s) independent of EPO
suppression are probably implicated in the apoptotic depletion of
patient BM erythroid cells.
TNF- in LTBMC supernatants from 26 of the
patients have been presented elsewhere.5 We have reported
that cytokine levels are significantly higher in RA patients
(17.87 ± 12.01 pg/mL) compared to the healthy controls
(6.28 ± 2.40 pg/mL; n = 11; P = .0005). In the
present study by further analyzing the data on the basis of patient
hemoglobin levels, we found that TNF- concentration was
significantly higher in the supernatants of patients with ACD
(n = 14) (22.68 ± 14.96 pg/mL) compared to the nonanemic patients
(n = 12; 13.14 ± 5.82 pg/mL; P = .0373). Both patient
groups, ACD and nonanemic, displayed significantly higher cytokine
levels compared to the control subjects (P = .0009 and
P = .0051). Individual TNF- values inversely correlated
with the values of hemoglobin (r = 0.436; P = .007)
and the number of BFU-Es (r = 0.530; P = .0009; Figure
4A and B, respectively) and positively
with the percentage of apoptotic CD34+/CD71+
(r = .708, P < .0001) and
CD36+/glycoA+ (r = 0.664,
P = .0001) cells in the entire group of subjects studied
(Figure 4C and D, respectively). In contrast, TNF- levels did not
correlate with the percentage of apoptotic
CD36/glycoA+ cells (r = 0.084,
P = .678). These data suggest that the increased local
TNF- production by BM stromal cells probably accounts for the
apoptotic depletion of patient erythroid progenitor and early precursor
cells and is possibly involved in the pathogenesis of ACD in
RA.
To further investigate this hypothesis we incubated normal BM cells
(n = 3) in the absence or presence of human rhTNF-
Effect of anti-TNF- on the BM erythroid cell homeostasis, we next examined the
effect of anti-TNF- treatment on the quantitative and functional characteristics of BM erythroid progenitor and precursor cells in RA
patients (n = 12) following 6 doses of cA2. Results were compared to
pretreatment values (Table 3). Changes in
TNF- concentration in LTBMC supernatants of these patients have been
previously reported.5 We have shown that the levels of the
cytokine decrease dramatically following treatment
(P = .0072). In the present study, we found that the
proportion of CD34+/CD71+ and
CD36/glycoA+ cells increased significantly
following treatment (P = .0006 and P = .022,
respectively) and this increase was associated with a significant
reduction in the percentage of apoptotic cells within the
CD34+/CD71+ and
CD36+/glycoA+ compartments
(P = .0011 and P = .0008, respectively). We
also found a significant increase in the number of BFU-Es obtained by
BMMCs of the patients after treatment (402 ± 147
BFU-E/106 BMMCs) compared to pretreatment values
(220 ± 153 BFU-E/106 BMMCs, P = .0049).
These data further corroborate the assumption of a TNF--induced
apoptotic depletion of BM erythroid cells in RA patients.
To further support these ex vivo findings, we next tested the effect of
the exogenous addition of an anti-TNF-
Effect of anti-TNF- treatment may influence the
systemic erythroid cell homeostasis, we examined the effect of 6 doses
of cA2 treatment on hemoglobin levels. Patient hemoglobin values at
baseline (n = 40) are shown in Table 1. Twenty-three (57.6%) of the
patients had anemia (mean hemoglobin value, 11.28 ± 1.12 g/dL).
Among anemic patients, 15 had ACD and 8 had IDA according to the
criteria described above. There was a female predominance in the
nonanemic and IDA groups compared to ACD patients (P < .05 and P < .01,
respectively);however, to our knowledge, this difference does not
affect any of the parameters investigated. The percentage of hemoglobin
changes in patient groups following cA2 treatment are depicted in
Figure 7. Overall, patients' hemoglobin increased significantly following treatment (mean 13.01 ± 1.30 g/dL;
P = .0004). As anticipated, there was a reduction in EPO levels (14.64 ± 8.65 mIU/mL) compared to baseline (21.38 ± 20.84 mIU/mL) in 12 patients studied; however, the difference obtained was
not statistically significant (P = .285). More
specifically, a significant increase of hemoglobin was observed in the
total group of anemic patients (mean, 12.57 ± 1.40 g/dL) compared to their baseline values (P = .00039). This increase was due
mainly to the significant increase obtained in the group of ACD
patients (mean, 12.88 ± 1.45 g/dL; P = .0032). A modest
improvement of anemia was also noted in RA patients with IDA (mean,
11.99 ± 1.16 g/dL), although the difference obtained from the
respective baseline values was not statistically significant
(P = .0705). These data confirm and extend previous
observations suggesting an improvement of anemia in RA patients
following treatment with cA2.11
Effect of anti-TNF- , other inflammatory cytokines such as
IL-1 and IL-6 may play a role in the pathogenesis of
ACD.27 By evaluating the changes of serum cytokine
levels in patients after treatment (n = 12), we found a significant
reduction in IL-6 values (10.17 ± 12.76 pg/mL) compared to
pretreatment values (18.22 ± 16.43 pg/mL, P = .0066).
Serum IL-1 levels also displayed a reduction following treatment
(0.82 ± 0.79 pg/mL), although the difference obtained was not
statistically significant compared to pretreatment levels
(1.41 ± 1.56 pg/mL, P = .223).
Anemia associated with RA has been considered the prototype of
ACD. Its pathogenesis is multifactorial but inflammatory cytokines, particularly TNF- The data of the present study confirm the beneficial effect of cA2 administration on anemia of patients with RA. Approximately 60% of our patients were anemic and among them 65% had ACD characteristics, highlighting the increased frequency of this condition in RA as previously reported.35 After 6 doses of cA2, a significant improvement of hemoglobin levels was observed in the total study group of patients compared to their baseline values. As expected, the most prominent increase was obtained in the group of ACD patients that was elevated to 14%. Based on previous reports suggesting that mechanisms independent of erythropoietin production and probably related to BM erythropoiesis underlie the recovery from ACD following cA2 treatment,11 we investigated the effect of such treatment in the quantitative and functional characteristics of BM erythroid cells in RA. At baseline, patients displayed a significant defect in the BM
erythroid cell reserve and function indicated by the low frequency of
erythroid progenitor and precursor cells, the low BFU-E colony formation by BM progenitor cells, and the increased apoptosis in the BM
erythroid progenitor and precursor cell compartments. These
abnormalities were associated with a markedly increased local TNF- Apoptotic mechanisms control erythropoiesis in normal and pathologic
conditions37-39 and adequate EPO production has been
demonstrated to protect erythroid progenitor cells from
apoptosis.25 In keeping with previous reports suggesting
normal EPO response to anemia in RA,11,40-42 our patients
displayed normal endogenous EPO production indicating that a
mechanism(s) other that EPO suppression affects BM erythroid cell
survival. On the basis of our recent findings that increased local
TNF- We next investigated the changes in BM homeostasis in the patients
following cA2 administration. On the basis of our hypothesis for a
TNF- In agreement with previous reports, we also found a significant
reduction in circulating IL-6 but not IL-1 | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
antibody therapy
Top
Abstract
Introduction
) Nonanemic subjects; (
) anemic subjects.
)
CD34+/CD71+, the early precursor (
)
CD36+/glycoA+, and late precursor (
