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Blood, 15 July 2002, Vol. 100, No. 2, pp. 647-653
NEOPLASIA
Response of hairy cells to IFN- involves induction of
apoptosis through autocrine TNF- and protection by adhesion
Peter K. Baker,
Andrew R. Pettitt,
Joseph R. Slupsky,
Hai J. Chen,
Mark A. Glenn,
Mirko Zuzel, and
John C. Cawley
From the Department of Haematology, University of
Liverpool, United Kingdom.
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Abstract |
Although hairy cell leukemia is uniquely sensitive to
interferon- (IFN-), the biologic basis for this phenomenon
remains unclear. Here we examine the effects of IFN- on cultured
hairy cells (HCs), taking into account the possible modifying influence of cell adhesion. We make the novel observation that therapeutic concentrations of IFN- kill nonadherent HCs by inducing apoptosis. In keeping with the persistence of HCs in tissues during therapy, such
killing was inhibited by integrin-mediated adhesion to vitronectin or
fibronectin. Exposure of HCs to IFN- resulted in a marked increase
in tumor necrosis factor- (TNF-) secretion. Furthermore, blocking
antibodies to TNF-RI or TNF-RII protected HCs from
IFN--induced apoptosis, demonstrating that such killing
was mediated by TNF-. In the absence of IFN-, exogenous TNF-
did not induce HC apoptosis, showing that IFN- sensitized HCs to the
proapoptotic effect of autocrine TNF-. This sensitization to
TNF--induced killing was attributable to suppression of IAP
(inhibitors of apoptosis) production known to be regulated by the
cytoprotective nuclear factor- B-dependent arm of TNF-
signaling. Moreover, engagement of the receptors for fibronectin or
vitronectin prevented this IFN--induced down-regulation of
IAPs. Understanding of the signals involved in the combined effects of
IFN- and TNF- and abrogation of those induced by integrin
engagement offers the possibility of sensitizing other malignant cells
to IFN--induced killing and thereby extending the therapeutic
use of this cytokine.
(Blood. 2002;100:647-653)
© 2002 by The American Society of Hematology.
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Introduction |
The response of hairy cell leukemia (HCL) to
interferon- (IFN-) is one of the most dramatic and specific
effects in the whole of clinical oncology. Nevertheless, the mechanism
of action of IFN- in HCL remains unclear. The agent inhibits HC
proliferation induced in vitro,1-3 but there are no
reports that it shortens the survival of these cells in culture. It is
difficult to reconcile these observations with the fact that the clonal
expansion in HCL, as in other chronic lymphoproliferative disorders,
results mainly from prolonged cell survival rather than from increased proliferation.4 The aim of this study was to explore this
issue further.
Among malignant B cells, HCs are distinctive in being
constitutively highly activated cells and, in a number of previous
studies, we have shown that this activation is responsible for many of the characteristic features of the disease.5,6 For
example, HCs have constitutively activated adhesion molecules such as
integrins, with the result that these cells readily interact with
extracellular matrix (ECM) components without the need for exogenous
stimulation.7 Such interactions are likely to modify the
propensity of these cells to undergo apoptosis.
In HCL, treatment of patients with IFN- induces rapid disappearance
of HCs from blood. In contrast, the malignant cells remain in spleen
and bone marrow for much longer periods and may not become completely
eliminated from these tissues.8 Previous studies of the
effects of IFN- have shown that this cytokine increases autocrine
TNF- production and inhibits HC proliferation in response to cell
stimulation.3 However, these observations do not explain
the therapeutic effects of IFN-, because TNF- is described as an
autocrine rescue factor for HCs9 and because HCL is a
disease of prolonged cell survival rather than of increased proliferation.4
Therefore, a plausible explanation for the therapeutic effect of
IFN- in HCL is still lacking but is important for elucidating the
specific biologic properties of HCs and for understanding why IFN-
has a therapeutic effect in only a limited number of malignancies.
Here we examine how the combination of intrinsic and
adhesion-generated signals influences the response of HCs to IFN-.
We show for the first time that IFN- induces the apoptosis of HCs when they are deprived of the protective effects of cell adhesion. In
contrast, IFN- enhances the viability of chronic lymphocytic leukemia (CLL) cells cultured under identical conditions. We show that
HC killing induced by IFN- is mediated through a mechanism involving
the up-regulation of autocrine TNF- and sensitization of HCs to its
proapoptotic effect via down-regulation of inhibitors of apoptosis
(IAPs). Importantly, engagement of integrin receptors inhibits this
latter effect, although it causes a further increase in the production
of TNF-. These observations not only shed light on the mechanism of
action of IFN- in HCL but also are of potential relevance for
broadening the therapeutic applications of this cytokine.
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Materials and methods |
Patient samples
HCs were obtained from peripheral blood of patients with typical
disease as determined by clinical presentation, malignant-cell morphology, tartrate-resistant acid phosphatase positivity, and immunophenotype. Cells from CLL patients all displayed typical morphology, CD5 and CD23 positivity, and had low-level expression of
light chain-restricted surface immunoglobulin (Ig). All patients had
high white cell counts (> 30 × 109/L for HCL and
> 100 × 109/L for CLL). Mononuclear cells were
isolated from whole blood by centrifugation over Lymphoprep (Gibco,
Paisley, United Kingdom) and, when more than 95% CD19+,
were used without further purification. In some cases of HCL, contaminating T cells and any residual monocytes were removed by
incubating the mononuclear cell fraction with monoclonal anti-CD3 and
anti-CD11b followed by separation of antibody-coated cells with
magnetic beads (Miltenyi Biotech, Surrey, United Kingdom); such further
purification had no effect on any of the results obtained.
Reagents and antibodies
Adhesive proteins.
Vitronectin (VN) was purified from normal plasma by heparin-Sepharose
affinity chromatography according to the method of Yatohgo et
al.10 The purity was determined to be more than 95% using 8% sodium dodecyl sulfate-polyacrylamide gel electrophoresis
(SDS-PAGE) analysis and Coomassie blue staining. Fibronectin (FN) was
purchased from Sigma (Dorset, United Kingdom).
Antibodies and reagents.
The anti-CD95 antibodies (CH11 and ZB4) were purchased from Immunotech
(Marseille, France), the anti-CD120a (H398) and anti-CD120b (MR2-1)
from Serotec (Oxford, United Kingdom), and the anti-PARP-1 and
anti-CD95 ligand (anti-CD95L) (C-20) from Santa Cruz Biotechnology (Santa Cruz, CA). The anti-IAP-1 and anti-IAP-2 antibodies, the TNF- enzyme-linked immunosorbent assay kit, and the TNF- were purchased from R&D Systems Europe (Oxon, United Kingdom). The respective class-specific and nonspecific polyclonal control antibodies were purchased from Becton Dickinson (San Jose, CA), and the IFN- was from Wellcome (Beckenham, United Kingdom).
All other chemicals used were purchased from Sigma unless
otherwise stated.
Cell culture
HCL or CLL cells (106/mL) were cultured (37°C in
5% CO2) in RPMI plus 0.5% bovine serum albumin (BSA).
Culture vessels (Becton Dickinson) were precoated with VN or FN
overnight at 4°C or with poly(2-hydroxyethyl methacrylate) (polyHEMA)
for 48 hours at 37°C.
Detection of cell death
Mitochondrial depolarization.
Cultured cells were gently resuspended and 200 µL added to an equal
volume of 80 nM 3,3'-dihexyloxacarbocyanine iodide (DiOC6) in phosphate-buffered saline (PBS) containing 1% BSA. After 15 minutes
of incubation at 37°C, an equal volume of propidium iodide (PI) (10 µg/mL) was added. After 30 minutes of incubation on ice, the cells
were analyzed by flow cytometry. DiOC6 is a cell-permeable green fluorochrome that is selectively concentrated within the polarized mitochondria of live cells but not in the depolarized mitochondria of apoptotic cells.11 Because mitochondrial
depolarization is an early apoptotic event and cell-membrane disruption
a late one,12,13 double staining with DiOC6
and PI allows the identification of live
(DiOC6-bright/PI-dim), early apoptotic
(DiOC6-dim/PI-dim), and late apoptotic/necrotic
(DiOC6-dim/PI- bright) cells.14
DNA fragmentation.
DNA fragmentation was detected as previously described.15
Briefly, cells were gently centrifuged and resuspended in 400 µL of a
solution containing 0.1% Triton X-100, 0.1% sodium citrate, and 10 µg/mL PI. After 1 hour of incubation on ice, the cells were analyzed
by flow cytometry. DNA fragmentation is one of the hallmarks of
apoptosis and can be detected as a reduction in the PI staining of
permeabilized cells due to loss of fragmented DNA.14
PARP-1 cleavage.
A total of 2 × 106 cells were gently washed in PBS and
lysed in 100 µL buffer containing 62.5 mM Tris-HCl (pH 6.8), 2% SDS, 6 M urea, 5%  -mercaptoethanol, 10% glycerol, and 0.00125%
bromophenol blue. Lysates were sonicated for 15 seconds and heated at
65°C for 15 minutes before being subjected to SDS-PAGE and Western blotting. Membranes were blocked in 5% milk and sequentially reacted with an anti-PARP-1 mouse monoclonal antibody (mAb) and a
peroxidase-conjugated antimouse second-layer antibody (Transduction
Laboratories, Lexington, KY). Reactive protein bands were visualized
using the ECL system (Amersham, Buckinghamshire, United Kingdom).
During apoptosis, full-length PARP-1 is cleaved by caspases into a
characteristic 89-kd C-terminal fragment.16,17
Ethidium bromide and acridine orange staining.
To detect cell death in situ, cells were stained with a mixture of the
red fluorochrome ethidium bromide (EtBr) and the green fluorochrome
acridine orange (AO). A total of 50 µL PBS containing 100 µg/mL
EtBr, 100 µg/mL AO, 3% ethylenediaminetetraacetic acid, and 10%
bovine hemoglobin were added very slowly to the 150-µL cultures so as
not to disturb the cells. After incubating for 60 minutes at 37°C,
the cells were visualized using an inverted fluorescence microscope. AO
is preferentially taken up by live cells, whereas EtBr (like PI) is
excluded from live cells and stains dead cells.18
Fluorescence-activated cell sorter (FACS) analysis.
Washed cells were sequentially incubated with either primary mAb or
class-specific controls (30 minutes at room temperature) followed by a
fluorescein isothiocyanate-conjugated antimouse Ig second layer
(Becton Dickinson) (30 minutes at room temperature). Following each
incubation step, the cells were washed 3 times and then analyzed on a
FACScan (Becton Dickinson).
TNF- RNA isolation and reverse transcription-polymerase
chain reaction
Total RNA was extracted from approximately
5 × 106 cells cultured in the presence or absence of
IFN- (100 U/mL) using an RNeasy kit (Qiagen, Hilden, Germany).
Single-strand complementary DNA was synthesized from 0.7 µg total RNA
using the SUPERSCRIPT RNase H Reverse Transcriptase (Life
Technologies, Paisley, United Kingdom). The TNF- gene was
amplified from the synthesized complementary DNA by polymerase chain
reaction (PCR) using a human TNF- PCR primer pair (R&D Systems),
which generates a 414-base pair complementary DNA band. To normalize
the product, the human L27 ribosomal RNA gene was also amplified using
the sense primer, 5'-GACGCAAAGCTGTCATCGTG-3', and the antisense primer,
5'-GCAGTTTCTGGAAGAACCAC-3', (30 cycles, annealing at 60°C) which
generates a 344-base pair band. The amplified PCR products were
subjected to electrophoresis and visualized by EtBr staining. The
intensity of each band was scanned and analyzed with Phoretix 1 D
Advanced software (version 3.1).
IAP detection
Cultured HC samples were lysed in an equal volume of
double-strength Laemmli sample buffer. The whole cell lysates were
sonicated for 15 seconds and heated to 100°C for 5 minutes before
being subjected to SDS-PAGE and Western blotting. Membranes were
blocked, probed with an anti-IAP-1 mouse mAb, and visualized as
described above.
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Results |
IFN- induces the apoptosis of HCs but not CLL cells
We first sought to establish whether or not cultured HCs could be
killed by IFN-. To take into account the possibility that cell
adhesion might generate signals that inhibit IFN--induced killing,
the tissue culture plastic was coated with polyHEMA (a nontoxic
hydrophilic polymer that prevents cell adhesion). When HCs were
cultured in this way (Figure 1A,C),
IFN- induced progressive and concentration-dependent cell death as
detected by mitochondrial depolarization (loss of staining with
DiOC6 [Figure 1A]) and by increased cell membrane
permeability (increased staining with PI [Figure 1A]). Importantly,
IFN- produced a small increase in the proportion of cells with
depolarized mitochondria and an intact cell membrane
(DiOC6-dim/PI-dim [Figure 1A]), suggesting that the cells
were dying by apoptosis.19 To confirm that this was so,
cells were examined for PARP-1 cleavage and DNA fragmentation because
these events are specific to this mode of cell death. Exposure of HCs
to IFN- resulted in a marked increase in the number of cells with
fragmented DNA (detected as a reduced DNA content following
permeabilization [Figure 1B]). The cytokine also increased PARP-1
cleavage as detected by an increase in the ratio of p89 to full-length
PARP-1 (Figure 1D). These findings indicate that IFN--induced
killing was occurring, at least in part, by apoptosis.
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| Figure 1.
IFN- kills HCs by apoptosis.
HCs were cultured with or without IFN- (0-1000 U/mL as indicated) at
a density of 106/mL in RPMI plus 0.5% BSA in tissue
culture plates coated with polyHEMA. Cell death was measured by FACS
analysis of cells stained with DiOC6 and PI (A,C).
DiOC6 is selectively concentrated in polarized mitochondria
of live cells, whereas PI is excluded from such cells. Apoptosis was
detected as DNA fragmentation (B) or PARP-1 cleavage (D). A
representative example is shown from among the 4 cases tested. Although
IFN- produced dose-dependent killing in all 4 cases, the results
were not pooled because the time taken for appreciable killing differed
markedly between cases (6-14 days).
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We next sought to establish whether the proapoptotic effect of IFN-
in our culture system was specific to HCs. To do this, we examined the
effect of IFN- on the viability of tumor cells from patients with
B-cell CLL, another mature B-lymphoproliferative disorder. In complete
contrast to HCs, CLL cells cultured on polyHEMA were not killed by
IFN-; indeed, the agent enhanced cell survival to a variable extent
in all cases tested (Figure 2).
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| Figure 2.
IFN- does not induce CLL apoptosis.
CLL cells from 3 patients were cultured with or without 0 U/mL ( ),
10 U/mL ( ), and 100 U/mL ( ) IFN- at a density of
106/mL in RPMI plus 0.5% BSA in tissue culture plates
coated with polyHEMA. Cell death was measured by double staining with
DiOC6 and PI. The percentage of
DiOC6-positive/PI-negative (live) cells is
shown.
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HC adhesion to VN or FN inhibits IFN--induced
apoptosis
To the best of our knowledge, IFN- has not been shown in
previous studies to induce HC apoptosis. However, such studies have usually included fetal calf serum (FCS) in the culture medium and have
used plastic culture vessels that become coated with adhesive proteins
such as VN and FN present in the FCS. Compared with HCs cultured on
polyHEMA in BSA, HCs cultured in the FCS/untreated plastic system were
indeed resistant to IFN--induced killing (Figure
3). This observation is likely to explain
why the killing effect of IFN- on HCs has not been observed in
previous in vitro studies.
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| Figure 3.
FCS inhibits IFN--induced killing of HCs.
Cells were cultured with or without IFN- (0-100 U/mL as indicated)
at a density of 106/mL in 0.5% BSA or 10% FCS on uncoated
plastic. Cell lysates were separated by SDS-PAGE and Western blotted
for PARP-1. Because HCs adhere to plastic, apoptosis was measured by
PARP-1 cleavage because this method, unlike FACS analysis, does not
exclude adherent cells from analysis. The results are representative of
similar experiments performed with the cells of 4 different HCL
patients.
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Previous work from this laboratory has shown that the ECM of spleen and
bone marrow in patients with HCL contains substantial amounts of VN and
FN, respectively,6,20 and that HCs interact with these
proteins via specific integrin receptors.7 Because integrin engagement is capable of inhibiting apoptosis in other contexts,21 we postulated that the IFN--induced
killing of HCs might be inhibited by integrin-mediated attachment of
HCs to VN and/or FN. To examine this possibility, HCs were cultured on
plates that were precoated with these ECM proteins or with BSA as a
control surface. Measurement of cell death was performed by staining
cells in situ with combinations of AO and EtBr and by Western blotting
for PARP-1 cleavage. These methods were chosen because they enable both
adherent and nonadherent cells to be analyzed.
As expected, IFN--treated HCs cultured on BSA underwent extensive
apoptotic cell death as assessed by both methods (Figure 4). In contrast, HCs cultured on FN or VN
underwent very little IFN--induced killing. This shows that
IFN--induced apoptosis is inhibited by HC contact with these
adhesive proteins.
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| Figure 4.
Contact with immobilized VN or
FN inhibits the IFN--induced apoptosis of HCs.
Cells were cultured as in Figure 1 except that the plates were
precoated with VN or FN or with BSA as a control surface. After 6 days
of culture, cell death was measured by double staining with AO and EtBr
(A; dead cells appear red, while live cells are stained green)
and by PARP-1 cleavage (B). A representative example of the 3 cases
studied is shown. Original magnification × 100.
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To confirm that the antiapoptotic effect of FN and VN was mediated by
integrin engagement, we examined the effect of adding GRGDS peptide to
the culture medium. This molecule interferes with the binding of
RGD-containing ECM proteins such as FN and VN to specific binding sites
on their respective integrin receptors. GRGDS peptide markedly enhanced
the IFN--induced killing of HCs cultured on FN and VN but had no
effect on cells cultured on BSA (Figure
5). This indicates that the inhibition of
IFN--induced killing by ECM proteins is mediated by integrins. For
optimal signaling, these receptors are known to require extensive
cross-linking,21 which in our experiments is achieved
through interaction with ligand-coated plastic. Presumably, a similar
cross-linking effect occurs in vivo during cell binding to adhesive
proteins that have become part of the insoluble ECM of spleen and bone
marrow. This may explain why, in HCL patients treated with IFN-, HCs
rapidly disappear from blood but more slowly from spleen and bone
marrow.
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| Figure 5.
GRGDS peptide prevents inhibition of IFN--induced
killing by VN/FN.
HCs were cultured for 6 days as in Figure 4 but in the presence or
absence of GRGDS peptide (including 60 minutes of preincubation; 200 µM). Cell survival was measured by double staining with AO and EtBr.
The results are from 2 identical experiments using cells from 2 different HCL patients.
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CD95/CD95L is not involved in IFN--induced apoptosis of
HCs
In other cell types, IFN- can up-regulate CD95 (Fas) and/or its
ligand (CD95L)22,23 and may sensitize cells to
CD95-induced killing.24 Moreover, both CD95 and its ligand
expressed by a single cell type can influence cell survival by
homotypic cell interaction.25 We therefore examined the
potential role of CD95/CD95L in the IFN--induced killing of HCs.
Here we confirm that HCs are strongly CD95
positive26 and show that CD95L expression is very low or
negligible (Figure 6A). We also confirm
that CD95 ligation does not induce HC apoptosis (Figure 6B), although
such ligation induced killing of Jurkat cells27 (data not
shown). Moreover, in contrast to many other cell
types,28-31 HCs in the presence of IFN- failed to
up-regulate either CD95 (data not shown) or its ligand (Figure 6A), and
IFN- did not sensitize them to killing by CD95 ligation (data not
shown). Furthermore, a blocking CD95 mAb had no effect on HC survival in the presence of IFN- (Figure 6C). Taken together, these results exclude an involvement of CD95/CD95L in the IFN--induced apoptosis of HCs. IFN- increases the production of TNF- by HCs and
sensitizes them to the induction of apoptosis by this cytokine.
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| Figure 6.
CD95/CD95L does not mediate HC apoptosis.
Expression of surface CD95L was examined by FACS analysis (A) in
untreated (shaded histogram) and IFN--treated (open histogram) HCs.
(B) HCs were treated with CD95-agonist mAb (CH11; 200 ng/mL; ),
control IgM (200 ng/mL; ), or left untreated () and assessed for
viability. (C) IFN--treated HCs were incubated with CD95-blocking
mAb (ZB4; 500 ng/mL; ) or with class-specific control Ig (500 ng/mL;
) and compared with HCs cultured in the absence of IFN- ().
The percentages of viable DiOC6-positive/PI-negative cells
(B,C) are shown. The results are a representative of 4 experiments
involving cells from 2 different HCL patients. The results were similar
in all 4 experiments but were not pooled because, as in Figure 1, the
time taken for appreciable killing differed markedly between cases
(6-14 days).
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It has been reported that IFNs can also sensitize certain cells to
other death-inducing agents such as TNF-.32 Moreover, IFN- is known to increase TNF- production by HCs,33
and IFNs sensitize monocytes to the induction of apoptosis by
TNF-.34 Therefore, although TNF- is normally an
autocrine survival factor for HCs,9 it is possible that
IFN- may convert the effect of TNF- from an antiapoptotic to a
proapoptotic one.
We first confirmed that TNF- production by HCs on both polyHEMA and
VN is increased in the presence of IFN- (Figure
7). This increase was paralleled by an
increase in TNF- messenger RNA. Thus, culture of HCs on polyHEMA in
the presence of IFN- (100 U/mL) caused a 1.3-, 3.1-, and 4.5-fold
increase in TNF- messenger RNA relative to the controls at 6 hours,
24 hours, and 48 hours, respectively (data not shown). By incubating
IFN--treated HCs with blocking TNF receptor antibodies or control
nonspecific antibodies, we tested whether the TNF- produced was
responsible for induction of apoptosis by IFN-. Figure
8 shows that specific antireceptor
antibodies inhibited IFN--induced cell death, with anti-TNF
receptor I (CD120a) being slightly more effective than anti-TNF
receptor II (CD120b) antibody. The presence of IFN- did not
significantly alter the expression of either CD120a or CD120b (data not
shown), indicating that changes in receptor expression levels were not
responsible for HC killing. Furthermore, in the absence of IFN-,
exogenously added TNF- did not induce the death of HCs cultured in
suspension over an 8-day period, even when used at a concentration
100-fold greater than that found in supernatants of HCs cultured with
IFN- (data not shown). This suggests that the increased TNF-
production alone was not responsible for IFN--induced apoptosis.
Taken together, the above data show that HC treatment with IFN-
increases production of TNF- and, on a nonadherent surface, converts
the TNF- action from a survival-promoting to a proapoptotic one.
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| Figure 7.
IFN- modulates the production of autocrine TNF-.
Soluble TNF- was measured by enzyme-linked immunosorbent assay in
supernatants of HCs cultured on polyHEMA (A,C) or VN (B,D) in the
presence (dotted line) or absence (solid line) of IFN- (100 U/mL).
The results (means ± SEM of triplicate measurements) are from
experiments with HCs from 2 different patients.
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| Figure 8.
IFN- killing is dependent on autocrine TNF-
production.
HCs were cultured on polyHEMA in the presence (dotted line) or absence
(solid line) of IFN- (100 U/mL) together with isotype control
antibodies (diamonds) or specific anti-TNF-RI- (A; ) or
anti-TNF-RII- (B; ) blocking mAbs. Viability of HCs was
determined by FACS analysis of HCs stained with DiOC6 and
PI. The same experiment was performed with HCs from another patient,
with similar results.
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To establish why comparable cell killing was not observed in adherent
HCs, we then examined whether the rescue of these cells by VN from
IFN--induced killing is mediated by inhibition of TNF-
production. However, when HCs were cultured on VN, TNF- production
was increased rather than decreased (Figure 7). Moreover, addition of
IFN- to cells on VN caused a further increase in TNF- production
(Figure 7) without marked induction of apoptosis. Thus, although
TNF- production is important in the apoptotic effect of IFN-,
modulation of the TNF- effect by integrin signaling is able to
inhibit the proapoptotic effect of IFN-.
HC killing by IFN-, and the rescue from this killing by
adhesion, involves changes in IAP production
We next attempted to gain insight into the mechanism involved in
HC killing by IFN- and into how integrin signaling abrogates this
killing. TNF- may induce apoptosis via a pathway involving caspases
and, at the same time, protect cells through activation of nuclear
factor-B (NF-B).35 Transcriptional targets of
NF-B include cellular inhibitors of caspases known as IAPs.
We have therefore measured NF-B activation by electrophoretic
mobility shift assay (EMSA) and IAP production, by Western blotting, in HCs in the presence or absence of IFN-. Although we could not demonstrate an effect of IFN- on NF-B activation using EMSA (data
not shown), under conditions of HC killing by INF- (24-hour culture
on polyHEMA) IAP-1 production was markedly reduced (Figure 9). In contrast, when cells were cultured
on FN or VN this decrease in IAP-1 production was completely abrogated
(Figure 9). Similar results were observed for IAP-2 (data not shown).
Although EMSA did not demonstrate an effect of IFN- on NF-B
activation, the observed decrease in IAP production is nevertheless
likely to reflect an effect of this cytokine on the NF-B pathway.
Thus, it has been demonstrated that IFN- can attenuate gene
transcription by NFB without altering its DNA-binding
activity.32 The abrogation of IAP down-regulation by
integrin signaling is also likely to reflect an effect on NF-B
because integrins are also known to activate the NF-B
pathway.36-38 Because the prevention of IAP down-regulation by adhesion to ECM proteins protected cells from apoptosis, this may explain why, during IFN- treatment, HCs persist much longer within bone marrow and spleen than in peripheral
blood.
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| Figure 9.
Integrin engagement abrogates IFN--induced
IAP-1 down-regulation.
HCs were cultured for 24 hours on plates precoated with either
polyHEMA, FN, or VN with or without IFN- (100 U/mL). (A)
Whole cell lysates were separated by SDS-PAGE and Western blotted for
IAP-1 and then reprobed for -actin to control for sample loading.
(B) The mean and SEM determined from 2 identical experiments using
cells from 2 different HCL patients are shown. The density of the IAP-1
bands was corrected for differences in loading and related to the
amount of IAP-1 present in the cells before the onset of culture
(t0).
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Discussion |
One of the most striking features of HCL is its uniquely high
sensitivity to IFN-. Nevertheless, despite considerable general knowledge concerning IFN--induced signals,39,40 the
mechanism through which these signals specifically mediate the
therapeutic effect of this cytokine in HCL is unclear. We have
therefore examined the effects of IFN- on HCs in vitro. It is well
established that drug effects can be modulated by external
microenvironmental influences such as adhesion and cytokines.
Therefore, to eliminate such influences, we have cultured HCs on a
nonadhesive surface (polyHEMA) and substituted BSA for FCS. Using this
culture system, we now demonstrate the novel finding that IFN- kills
HCs through the induction of apoptosis.
To preserve cell viability, HCs have in the past been cultured using
standard tissue culture plates in the presence of FCS. Our results
indicate that such a culture system rescues cells from IFN--induced
apoptosis. Indeed, previous reports indicate that the presence of
IFN- under standard culture conditions only serves to limit HC
proliferative potential.1,41 In our experiments, despite
the absence of adhesion and FCS, good viability (> 80%) was
maintained for up to 14 days of culture. When serum is present in the
culture medium, HCs avidly adhere to the surface of the plastic vessel,
which is known to become coated by serum proteins that include integrin
ligands such as VN and FN. Cell binding to the surface-immobilized
adhesive proteins results in the extensive integrin cross-linking
required for optimal generation of survival signals. We therefore
coated tissue culture plastic with purified VN or FN and showed that
integrin engagement by these surface-immobilized proteins is sufficient
to rescue HCs from the apoptotic effect of IFN-. Although these
proteins are present in the circulation in soluble form, they are
abundant in tissues as part of the insoluble ECM of bone marrow and
splenic red pulp where HCs accumulate and from where these cells
disappear much more slowly during IFN- therapy.8 We
therefore propose that integrin receptor cross-linking by HC adhesion
to ECM is responsible for the persistence of malignant cells in these
organs during IFN- therapy long after they have disappeared from the blood.
We next studied the mechanism of the observed IFN--induced
apoptosis of HCs in the absence of environmental rescue. Several previous studies examining the killing of other cell types by IFN have
implicated CD95/CD95L.22,24,28,30,42 We therefore examined
the role of these proteins in the IFN--induced killing of HCs. Our
demonstration that CD95/CD95L is not involved suggests that HCs may
belong to the category of type II cells, which express CD95 but fail to
form the death-inducing signaling complex.43
We next considered the involvement of autocrine TNF- in the
effect of IFN- because this cytokine has been implicated in HC
survival9 and because IFN- is known to modulate HC
TNF- production.33 Early studies1 proposed
that autocrine TNF- has a cytoprotective effect on malignant B cells
and that IFN- has a beneficial therapeutic effect in HCL by
interrupting this autocrine growth factor loop through inhibition of
TNF- production. However, in accord with the more recent studies of
Billard et al44 and those of Jansen et al,45
we found that IFN- caused an increase in TNF- production by HCs.
Moreover, we demonstrate that blocking antibodies to TNF receptors
inhibit IFN--induced killing. This involvement of TNF- in the
IFN--induced killing of HCs could not be attributed to increased
TNF receptor expression because in our study we found that the levels
of both receptors (CD120a and CD120b) remained unchanged in the
presence of IFN-.
Because addition of exogenous TNF- had no death-inducing effects in
the absence of IFN-, the killing of HCs by IFN- could not be
attributed simply to increased TNF- production. Instead, our results
indicate that IFN- sensitizes HCs to the proapoptotic effect of
TNF-, a phenomenon that has also been observed in other cell
types.46,47 We therefore examined the mechanism by which IFN- and TNF- cosignaling induces HC death and how integrin signaling protects HCs from this killing.
Cell stimulation by TNF- can induce apoptosis through caspase
activation, but this effect can be suppressed through the concomitant induction of IAP synthesis through the NF-B pathway.48
Our study demonstrates that the induction of HC death by IFN-
involves suppression of IAP production and consequent sensitization of these cells to proapoptotic effects of TNF-. Moreover, our
experiments demonstrate that integrin engagement by FN and VN inhibits
IFN--induced killing of HCs and that the restoration of IAP
production is involved in this cytoprotective effect.
In conclusion, the present study clarifies the mechanism of action of
IFN- in HCL. We show for the first time that malignant HCs, when
deprived of adhesion, are killed by apoptosis in response to
therapeutically relevant concentrations of IFN-. This apoptosis is
mediated by increased autocrine TNF- production and by sensitization of HCs by IFN- to the death-inducing effect of such autocrine TNF-. Our novel observation that integrin engagement by adhesive proteins protects cells from the killing effects of combined IFN- and TNF- explains why in previous work where culture vessels become
coated with such proteins, no killing of HCs by IFN- was observed.
In addition, our findings explain why during IFN- therapy HCs
disappear rapidly from the blood but persist much longer in spleen and
bone marrow, where they are likely to be rescued by adhesion to ECM.
The challenge now is to elucidate the signaling basis of the modulation
of the action of TNF- by IFN- resulting in cell killing and
protection by integrin engagement from this killing. This could offer
the possibility of using pharmacologic manipulation of relevant signals
to extend the therapeutic use of IFN- to malignancies that are
currently resistant to the cytokine.
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Footnotes |
Submitted September 13, 2001; accepted March 14, 2002.
Supported by the Leukaemia Research Fund of the United Kingdom.
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: Peter K. Baker, Royal Liverpool University
Hospital, 3rd Floor, Duncan Building, Daulby Street, Liverpool, L69
3GA, United Kingdom; e-mail: pbaker{at}liv.ac.uk.
| |
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Abstract
Introduction