(Received for publication, May 9, 1996, and in revised form, November 7, 1996)
From the We have investigated cell metabolism during
apoptosis in the murine interleukin-3 (IL-3)-dependent cell
line Bo and two derivative clones (B14 and B15) overexpressing human
bcl-2a. On removal of IL-3, Bo cells underwent apoptosis
within 8 h, whereas B14 and B15 cells were resistant for at least
24 h. Metabolically, Bo, B14, and B15 cells were indistinguishable
from each other. All were insensitive to mitochondrial poisons, derived
ATP entirely by glycolysis, and maintained similar mitochondrial
membrane potentials measured by rhodamine-123 fluorescence with or
without IL-3. All virtually ceased glycolysis and production of lactic
acid on IL-3 withdrawal but maintained intracellular [ATP] until in
Bo cultures the cells began to apoptose. B14 and B15 cells became
glycolytically arrested but maintained stable ATP levels during
protection from apoptosis. Depletion of intracellular ATP by uncoupling
the mitochondrial ATPase with 2,4-dinitrophenol or carbonyl cyanide
p-trifluoromethoxyphenylhydrazone induced apoptosis in Bo
cells with or without IL-3, but not in B14 or B15 cells.
bcl-2-overexpressing cells were recoverable with high
plating efficiency even after prolonged exposure to 2,4-dinitrophenol.
We conclude that IL-3 withdrawal leads to arrest of energy metabolism
in which ATP levels are maintained. In Bo cells this is followed by
apoptosis, whereas in bcl-2-overexpressing cells this state
is stably prolonged. ATP depletion is a strong apoptotic signal which
overrides IL-3 signaling in normal cells but is ineffective in
bcl-2-overexpressing cells. Prolonged metabolic arrest and
resistance to ATP depletion facilitated by bcl-2 are both
reversible. Persistent reversible metabolic dormancy would provide
cells with a survival advantage in nonsustainable environments (e.g. hypoxia or substrate lack) and suggests a mechanism
for the survival advantage displayed by cells overexpressing
bcl-2.
Apoptosis (programmed cell death) is thought to play a crucial
role in regulating cell growth (1, 2). Many cells, including hematopoietic cells (3), are susceptible to apoptosis induced by a wide
variety of agents and conditions such as serum deprivation, radiation,
heat shock, cytotoxic drugs, oncogene products, or lytic viruses
(4-9). Apoptosis is regulated by a number of genes, in particular
those of the bcl-2 family, originally identified with
follicular B-cell lymphoma (10). bcl-2a codes for a 26-kDa membrane-inserted protein that has been located in outer mitochondrial, endoplasmic reticulum, and nuclear membranes (11-13). Overexpression of the membrane-inserted form, but not the truncated free form (bcl-2b), protects many cells from apoptosis induced by
numerous noxious agents (4-9) and also confers a survival advantage on cells in vivo (9). bcl-2 has therefore been
considered a facilitatory gene for malignant change. Recently, a series
of bcl-2 homologs has been isolated (14, 15) whose activity
can be apoptosis-inducing or -suppressing, depending on their state of
dimerization with other members of the family. Other genes may also
play important accessory roles in apoptosis; for example,
c-myc and p53 (16-18). The mechanism of action
of bcl-2 is unknown. Although its location in mitochondrial
membranes suggests it may influence mitochondrial function, and recent
work suggests that mitochondria may contribute to early stages of
apoptosis induction, (19-21) cells depleted of mitochondrial DNA or
cultured in anaerobic conditions are still protected from apoptosis by
bcl-2 (22-24). bcl-2 has also been suggested to
protect cells from apoptosis by inhibiting lipid peroxidation induced
by free radicals (25, 26).
Recent work has shown that tumor cells expressing bcl-2 or
mutant p53 have a survival advantage in hypoxic conditions
(27), raising the question whether bcl-2 confers a survival
advantage by regulating metabolism and the synthesis or use of ATP. In
murine interleukin-3
(IL-3)1-dependent cells, ATP is
derived entirely from glycolysis (28), and apoptosis induced by IL-3
withdrawal is preceded by drastic reductions in lactic acid production
without changes in glucose transport (29, 30). These cells thus provide
a useful model for metabolic regulation induced by oncogenes including
bcl-2. We examined the possibility that in these cells
bcl-2 might either regulate ATP production independently of
the IL-3 signaling pathway or sustain them in a minimal but
metabolically active state. We found that bcl-2 expression
makes no difference to the cessation of energy metabolism normally
leading to apoptosis but facilitates a prolonged metabolically dormant
state from which cells recover with high efficiency.
The murine
IL-3-dependent pro-B line Bo and two independent derivative
clones B14 and B15 overexpressing human bcl-2 were kindly
made available by Dr. Mary Collins, Institute for Cancer Research,
London. Whereas Bo cells apoptose within 8 h after IL-3 withdrawal, both B14 and B15 cells arrest growth but remain viable for
several days and are refractory to further damage by radiation or
cytotoxic drugs (3). Cells were maintained as described previously (4)
in RPMI supplemented with 5% fetal bovine serum (Life Technologies,
Inc.) and 5% WEHI 3b-conditioned medium as a source of IL-3. For
experimental incubations, recombinant IL-3 was used at 100 units/ml.
Cells were used in the exponential phase at densities between 1 and
4 × 105 cells/ml. IL-3 was removed by centrifugation
(800 rpm × 5 min) and washing three times in prewarmed RPMI/fetal
bovine serum. For all experiments, washed cells were resuspended to a
known density of between 1 and 5 × 106 cells/ml in
RPMI/fetal bovine serum. Where cells were precultured in, and returned
to, medium containing N-acetylcysteine, all wash solutions
also contained N-acetylcysteine.
Cells were washed and recultured with and
without IL-3 and/or 2,4-dinitrophenol (DNP) for the times specified.
After washing, 104, 5 × 104 and
105 cells were plated in triplicate in 1 ml of RPMI, fetal
calf serum, 0.3% agarose supplemented with WEHI 3b-conditioned medium
and reincubated. Colonies were scored at 5 days.
N-Acetylcysteine (neutral injectable
solution Parvolax) was obtained from Evans Pharmaceuticals. DNP was
from BDH Ltd. Sodium cyanide, maleic acid diethyl ether, ATP, and
carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP)
were from Sigma. Antimycin A was from Boehringer Mannheim.
Dichlorofluorescein diacetate and rhodamine-123 were from Molecular
Probes Inc.
For rhodamine
staining, cells were centrifuged and resuspended in prewarmed Hanks'
solution with 0.1 µg/ml rhodamine-123, incubated 20 min, washed once
in Hanks solution, reincubated a further 20 min, and analyzed on a
Becton-Dickinson FACSCAN or Coulter Elite II flow sorter.
For flow
cytometric analysis of DNA profiles, cells were pelleted, resuspended
in DNA labeling solution (Coulter Electronics Inc.) according to the
manufacturer's instructions, and analyzed on a Coulter Epics II flow
cytometer.
For TUNEL assays, cells were deposited on slides using a Cytospin
centrifuge and fixed for 30 min at room temperature in 1% fresh
paraformaldehyde. TUNEL assays (Boehringer Mannheim) were performed
according to the manufacturer's instructions.
Cells were washed and
reincubated for the lengths of time indicated with additions as
described. DNA was prepared according to Ref. 4. Briefly,
105-106 cells were centrifuged and solubilized
in 200-500 µl of ice-cold lysis solution (10 mM Tris (pH
8), 150 mM NaCl, 1% sodium dodecyl sulfate, 0.1 mM EDTA). 200 µg/ml proteinase K (Sigma) was added and
the solution incubated overnight at 37 °C. Protein was extracted with phenol/chloroform/isoamyl alcohol (Sigma) and DNA precipitated with 0.10 volume of 3.5 M ammonium acetate and 2.5 volumes
of absolute alcohol at All
experiments were conducted with RPMI supplemented with 1% fetal bovine
serum dialyzed against two changes of phosphate-buffered saline and one
of RPMI. Exponential cells precultured overnight (final density,
2-4 × 105 cells/ml) were washed twice in prewarmed
medium, resuspended to a known density of 2-4 × 105
cells/ml, and reincubated with additions as shown. One-ml aliquots of
cell suspension in quadruplicate were layered onto 300 µl of silicone
oil overlaying 100 µl of 10% w/v perchloric acid, 20% w/v glycerol
in a 1.5-ml microcentrifuge tube and centrifuged for exactly 1 min at
room temperature. The supernatant was retained for lactic acid
determination while the silicone oil layer was removed, and after the
addition of 5 µl of universal indicator, the underlying perchloric
acid layer was neutralized by careful titration with 5 M
KOH, 0.5 M MOPS, 20 mM EDTA. The resulting KClO3 precipitate was removed by centrifugation and the
supernatant stored at Dichlorofluorescein
diacetate staining was used to detect intracellular free radicals (33).
Cells were removed directly from the culture and incubated for 30 min
with 5 µM dichlorofluorescein diacetate. The cells were
pelleted once, resuspended in fresh medium, and analyzed immediately on
a Coulter flow cytometer. For glutathione measurement, 4.5 × 106 cells were washed rapidly in ice-cold
phosphate-buffered saline, extracted into 10% w/v 5 Bo, B14, and B15 cells all
possess rapid population doubling times of 10-14 h in the presence of
IL-3 (data not shown). We wished first to exclude that bcl-2
overexpression may induce mitochondrial respiration, thereby
significantly increasing efficiency of ATP generation per unit of
glucose metabolized. Rhodamine-123 fluorescence was employed as a
marker of mitochondrial energization (35). Data are shown in Fig.
1 for Bo and B15 cells. There was no difference in basal
fluorescence between Bo and B15 exponential cells nor between cells
deprived of IL-3 and reincubated with or without IL-3 for several
hours. However, Bo, B14, and B15 cells depleted of IL-3 underwent
rounding of shape and volume contraction at 30 min. Bo cells commenced
to apoptose between 4 and 6 h, which coincided with a slight
relative decrease in rhodamine fluorescence compared with
bcl-2-expressing B15 cells (Fig. 1). This reduction in
mitochondrial membrane potential (Fig. 1) is consistent with changes in
permeability transition (21), but we were unable to demonstrate any
effect of cyclosporin A, an inhibitor of mitochondrial pore opening
(data not shown). Also, a significant proportion of Bo cells (5-10%)
became permeable to trypan blue at about 8 h, suggesting
alternatively that the dye change could be due to a general increase in
cell permeability. Comparison of B14 with B15 cells showed closely
similar profiles (Fig. 2). We noted, however, that all
cells, including Bo, kept undisturbed by further addition of materials
or washing showed a similar progressive decrease in rhodamine-123
retention over 6 h, but this was still unaffected by IL-3.
Confocal and fluorescence microscopy demonstrated that rhodamine-123
was located in the cytoplasmic region surrounding the nucleus in Bo,
B14, and B15 cells, consistent with mitochondrial localization, there
being no significant differences in whether or not IL-3 was present
(data not shown). To confirm that bcl-2 protection did not
involve mitochondrial activation, we incubated cells with cyanide (500 µM-50 mM) or antimycin A (50 ng/ml-5
µg/ml); cyanide inhibits cytochrome oxidase, antimycin A electron
flow through the cytochrome bc1 complex. Neither
induced nor accelerated apoptosis after 24 h, with or without
IL-3, as reported for other IL-3-dependent cells (30 and
data not shown), suggesting that induction of oxidative phosphorylation
was not involved in the regulation of apoptosis by
bcl-2.
Fig. 3
shows lactic acid production from two representative complete
experiments using Bo and B15 cells with measurements taken at different
time intervals. Two h after IL-3 withdrawal from both Bo and B15
cultures, lactate output declined to approximately 50% of controls
supplemented with IL-3 and stopped almost completely at about 8 h.
At 8 h, most Bo cells were visibly apoptosing, whereas B15 cells
maintained almost full viability over the subsequent 24 h.
However, no further production of lactic acid occurred from B15 cells
after 8 h, indicating that glycolytic flux in these cells was
arrested. Identical results were obtained from B14 cells (Table
I). Since Bo, B14, and B15 cells displayed identical
declines in glycolytic flux on IL-3 withdrawal, and B14 and B15 cells
established prolonged glycolytic arrest, bcl-2 could not
function by generating ATP through glycolysis in the absence of IL-3.
Since we also excluded generation of ATP by mitochondrial respiration,
we analyzed whether bcl-2 expression might activate or
sustain ATP-consuming pathways, for example "housekeeping" or
repair functions. Alternatively, enhanced survival could be due to
decreased consumption of ATP allowing cellular [ATP] to be
maintained. We therefore measured changes in cellular [ATP].
Glycolytic arrest in B14 and B15 cells and comparison of effects of DNP
and FCCP on glycolytic flux
Exeter University Clinical Science
Institute,
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
Acknowledgments
REFERENCES
Cell Lines and Culture
30 °C. Precipitated DNA was redissolved in 50-100 µl of TE (10 mM Tris, 1 mM EDTA, pH
7.4) and incubated with 10 units/ml DNase-free RNase (Sigma) for 30 min
at 37 °C. Known amounts of DNA (10 and 30 µg determined using
A260) were electrophoresed in 1.2% agarose gels
and visualized with ethidium bromide.
70 °C. Ten-µl aliquots were used for
measurements of ATP and ADP with the luciferase method (31). Lactic
acid was determined in 20-50 µl of each supernatant using lactic
dehydrogenase (Sigma) (32).
-sulfosalicylic
acid dihydrate (Sigma), and assayed for total glutathione by the
2-nitrothiobenzoic acid method (34). Standard curves were prepared from
authentic glutathione (Sigma).
Neither IL-3 Withdrawal nor bcl-2 Overexpression Induces
Mitochondrial Oxidative Metabolism
Fig. 1.
Rhodamine-123 fluorescence profiles of Bo and
B15 cells. x axis, relative fluorescence. y axis,
cell number. Panel A, profiles of Bo (shaded) and
B15 (open) cells at 0, 2, and 3 h after incubation
without IL-3. Panel B, comparative profiles of Bo
(left) and B15 (right) after 3 h without
IL-3 followed by readdition of 100 units/ml IL-3 for 2 h
(shaded) or without IL-3 (open).
[View Larger Version of this Image (21K GIF file)]
Fig. 2.
Rhodamine-123 fluorescence profiles comparing
B14 with B15. Panel A, after 2 h; panel B,
after 6 h. Plus sign, with IL-3; minus sign,
without IL-3. a and b, Bo; c and
d, B14; e and f, B15; g and
h, B14; i and j, B15. Note the absence
of an effect of IL-3. Both B14 and B15 (and Bo, data not shown) showed
progressive reduction of fluorescence with time which was unaffected by
IL-3.
[View Larger Version of this Image (27K GIF file)]
Fig. 3.
Effects of IL-3 withdrawal and uncoupler on
lactic acid production in Bo and B15 cells. L-Lactate
concentrations in the supernatant from incubations of Bo (left
panels) or B15 (right panels) cells were measured at
the times indicated as described under "Experimental Procedures."
Two separate experiments are shown, with each data point representing
the mean of duplicate determinations. , with IL-3;
, without
IL-3;
, with IL-3 with DNP;
, without IL-3 with DNP. The cell
concentration was 2 × 105/ml.
[View Larger Version of this Image (19K GIF file)]
Time
Lactic acid in
supernatant from 2 × 105 cells/ml
+IL-3
IL-3
+IL-3 + DNP
IL-3 + DNP
+IL-3 + FCCP
IL-3 + FCCP
h
mM
B14 cells
2
0.55
0.3
0.74
1.09
1.3
1.3
4
0.9
0.39
1.4
1.8
2
1.9
6
1.3
0.5
2.2
2.5
2.9
2.8
8
3.1
0.68
3.8
4.6
5.5
5
22
7.3
0.67
5.9
6
8.8
8
B15 cells
2
0.53
0.28
0.6
1.1
1.32
1.32
4
0.86
0.35
1.09
1.83
1.49
1.46
6
1.3
0.43
1.8
2.48
2.2
2.12
8
3.07
0.56
3.27
3.36
4.44
4.28
22
6.5
0.6
5.96
5.65
7.8
6.8
Data from seven individual experiments using B15 cells are summarized in Table II, each data point being from least three experiments. Values are given as percentages of initial values (t = 0) since (i) cells in IL-3 maintained proliferation, whereas those without IL-3 ceased, and (ii) the fractional increase in numbers after short periods of time could not be determined accurately. The basal ATP content of the cells was similar in both Bo and B15 cells (Table II) and comparable to values determined previously in other IL-3-dependent cells (30). In IL-3-supplemented Bo and B15 cells [ATP] continued to rise commensurate with continued growth and increased cell number. In IL-3-starved Bo and B15 cells, intracellular [ATP] followed early rises similar to that observed in IL-3-supplemented cells until Bo cells commenced to apoptose (at about 6 h). After this point ATP levels in Bo cells fell dramatically, which was attributable to general cell leakiness and apoptotic fragmentation. However, in IL-3-starved B15 cells, cellular ATP content plateaued after 8 h and remained almost unaltered over the next 20 h. bcl-2 protection therefore does not appear to induce, activate, or maintain ATP-depleting mechanisms for cell survival, but rather maintains [ATP]. The early rise in [ATP] during IL-3 withdrawal while lactic acid production (and therefore glycolysis) declines, and its subsequent plateauing in B15 cells, suggest also that IL-3 signaling regulates ATP demand, not its generation. Thus glycolytic down-regulation appears to follow reduction in ATP demand when IL-3 is withdrawn and [ATP] is maintained. Later, when ATP demand is abrogated altogether, glycolysis ceases. In preventing apoptosis, bcl-2 thus enables cells to establish a stable state of glycolytic and therefore energy arrest.
|
Cellular ADP content was also determined in parallel with ATP, but the lower intracellular concentration of this nucleotide made its accurate determination difficult. However, we obtained no evidence for consistent changes in ATP:ADP ratios accompanying IL-3 stimulation or bcl-2 overexpression.
ATP Depletion Induces ApoptosisOne explanation for the extended survival of bcl-2-protected cells might be that it inhibits ATP-consuming metabolic pathways whose unbalanced activity signals apoptosis but whose impact on gross [ATP] is too small to be measurable. If so, then imposition of an ATP-depleting reaction might be expected to accelerate apoptosis and overcome the protective effects of bcl-2. In the absence of oxidative phosphorylation, mitochondrial uncouplers can still lower intracellular ATP through reversal of the mitochondrial F0-F1-ATPase, thereby causing hydrolysis of glycolytically derived ATP. Such ATP depletion would also lead to up-regulation of glycolytic flux through feedback regulation and therefore produce an increase in output of lactic acid. We therefore induced such a state by adding mitochondrial uncouplers: DNP, which has been used in many studies to specifically lower intracellular ATP (e.g. 36), or FCCP, a potent uncoupler of the mitochondrial F0-F1-ATPase (37).
In the presence of IL-3, DNP lowered ATP by an average of 40% after
2 h compared with controls in both Bo and B15 cell lines (Table
II) and also raised ADP (data not shown). DNP also increased production
of lactic acid by up to nearly 4-fold with almost identical kinetics in
both lines (Fig. 3), confirming that uncoupling the mitochondrial
ATPase stimulated glycolytic flux as predicted. Almost identical
results were obtained using a different uncoupler, FCCP. Comparing the
effects of FCCP with DNP showed that FCCP was more effective in early
uncoupling (Table I) but that both lines responded almost identically
to both uncouplers and produced almost identical levels of lactate on a
per cell basis. In IL-3-starved Bo cells, enhanced lactic acid
production stopped when cells apoptosed. DNP and FCCP induced or
accelerated apoptosis in Bo cells even in the presence of IL-3. Such
cells displayed earlier typical membrane blebbing and nuclear/DNA
fragmentation shown by microscopy, TUNEL assays (Fig.
4), and DNA ladder gels (Fig. 5,
B, D, F, and H). TUNEL
assays detect in situ fragmented DNA through fluorescent end
labeling of fragmented DNA in intact nuclei. DNP increased the
proportion of TUNEL-positive cells from 10% in controls incubated without IL-3 for 6 h to nearly 50% (Fig. 4). In contrast, both B14 and B15 exhibited identical resistance to apoptosis with DNP and
FCCP. Whereas DNP decreased the ATP content in B15 cells to an extent
similar to that seen in Bo cells (Table II) they retained increased
viability with significantly less DNA fragmentation (Fig. 5,
C, E, and G), even in the absence of
IL-3. Both B14 and B15 cultures continued to generate increased lactic
acid throughout the 24-h period (Fig. 3 and Table I); but even after
24-h exposure to DNP in the absence of IL-3, DNA was still
significantly intact compared to with cells (Fig. 5, I).
The prolonged survival of bcl-2-overexpressing cells treated with DNP correlated with survival of clonogenic cells determined by agar colony assays (Table III). Whereas Bo cells from cultures preincubated for 24 h in DNP but without IL-3 generated no colonies at 5 days, B15 cultures similarly treated generated 40% of colonies of control cultures. Similarly, whereas almost no Bo cells survived DNP treatment in the presence of IL-3, B15 cells maintained nearly 70% of the control clonogenic cells. Colonies from DNP-treated B15 cultures were also the same size as controls, showing that any lag phase in recovery must have been very short. Thus our results show that although lowering ATP, even by a relatively modest amount, generates a strong apoptotic signal in Bo cells, it does not generate this signal in bcl-2-transfected cells, suggesting that focal ATP depletion may initiate apoptosis in Bo cells and that bcl-2 inhibits this step. Taken together, our results also imply that glucose and lactate transport and the glycolytic pathway are not disrupted by IL-3 withdrawal or uncouplers; furthermore, glycolysis is not operating at maximum capacity during growth stimulated by IL-3. Together with the data on maintenance of [ATP], it appears that bcl-2 does not act globally on energy metabolism, and bcl-2-overexpressing cells need neither generate nor use ATP to prolong their survival.
|
If cells become quiescent, this
might be reflected in decreased production of free radicals. Also,
previous reports suggest that bcl-2 might exert its
protective effect against apoptosis by decreasing free radical damage
(25, 26). The data in Fig. 6 suggest that this is
unlikely since cells exposed to the antioxidant N-acetylcysteine showed no protection from apoptosis. Thus,
at concentrations above 1 mM, N-acetylcysteine
accelerated apoptosis in IL-3-starved Bo cells judged both by
microscopic examination and by an increase in DNA laddering. Pregrowing
cultures in N-acetylcysteine for 24 or 48 h did not
affect this response (data not shown). However, bcl-2 cells
were resistant to N-acetylcysteine-induced apoptosis. Using
dichlorofluorescein diacetate, which detects principally hydrogen
peroxide but other reactive oxygen species (33), a small but
significant signal was generated in IL-3-supplemented cells but not in
IL-3 starved cells during the first 6 h. Reactive oxygen species
production was at least partly dependent on reduced glutathione levels
since maleic acid diethyl ether, an inhibitor of glutathione
S-transferase (39), depleted reduced glutathione by over
90% while significantly increasing reactive oxygen species (data not
shown). However, maleic acid diethyl ether did not accelerate progression of apoptosis. We therefore found that both Bo and B15 cells
could produce free radicals equally well, but these did not appear to
play a role in apoptosis induction in these cells.
In Bo cells, apoptosis induced by IL-3 withdrawal is preceded by rapid rounding of cells and decline in lactic acid production. However, this is not accompanied initially by intracellular ATP depletion. This suggests that removing IL-3 reduces the demand for ATP which in turn leads to a reduction in glycolytic flux and therefore lactate production. The constraint on glycolysis imposed by reduced ATP demand can, however, be reversed by activating the mitochondrial F0F1-ATPase with uncoupler. This reduces cellular ATP levels, stimulates glycolytic flux (probably regulated at the level of phosphofructokinase), and also accelerates apoptosis. IL-3 withdrawal therefore cannot directly affect glucose or lactate transport or enzymes regulating glycolysis; indeed, these cannot be saturated during normal growth as shown by the significant and immediate up-regulation of lactate production by ATP depletion. We also found no evidence that metabolic down-regulation induced by IL-3 withdrawal increases intracellular free radical concentrations; antioxidants in fact accelerated apoptosis. This would, however, be consistent with the recent observation that dATP or dADP may regulate apoptosis (40); antioxidants would be expected to increase reduced glutathione and thereby increase dNTPs via ribonucleotide reductase. We have also found that depletion of reduced glutathione inhibits some of the early stages of apoptosis in these cells.2
Surprisingly, we have found that in B14 and B15 cells overexpressing bcl-2, none of the preapoptotic characteristics of parental Bo cells undergoing apoptosis (cell rounding, maintenance of [ATP], down-regulation, and cessation of glycolysis) is altered. We obtained no evidence that bcl-2 initiates mitochondrial respiration nor that IL-3 signaling or its deprivation significantly affects mitochondrial membrane potential as proposed for a role in apoptosis induction (40). However, bcl-2-overexpressing cells are resistant to prolonged ATP depletion induced by mitochondrial uncouplers even in the absence of IL-3; although uncoupler produces identical sustained and increased glycolytic flux, apoptosis is still inhibited, and such cells can recover with high efficiency as revealed by clonal assays. B14 and B15 cells maintained in the absence of IL-3 therefore appear to have no requirement for ATP generation nor for significant ATP usage and appear to survive in an extended energetically arrested state.
This is the first study to show that prevention of apoptosis by bcl-2 facilitates a stable state of prolonged metabolic arrest in previously rapidly proliferating cells (cycle time approximately 11 h) within hours of the removal of growth factor stimulus (IL-3). The mechanism closely coupling IL-3 signaling to glycolysis is unknown. Prolonged and stable inertness may generate resistance to many different forms of stress (4-9) and explain the known survival advantage of tumor cells protected by bcl-2, particularly in hypoxic environments (27). In solid tumors, vasculature is disorganized and creates hydrostasis (41-43). This in turn leads to hypoxia and reduction in nutrient flows as well as inhibiting diffusion of cytotoxic drugs. Cells in such conditions are likely to be severely stressed. Possibly both IL-3 removal and ATP depletion could create a stress response in the cells used here, regulating cascades involving stress-activated kinases that are activated by diverse stresses such as heat shock, arsenite, and hyperosmotic stress (44-46) and also implicated in apoptosis induced by ceramide (47). However, taken together, our results with these cells are more consistent with a model in which apoptosis is dynamically inhibited by IL-3 signaling and related to an ATP-consuming inhibitory pathway, which, when switched off (as in IL-3 withdrawal), induces apoptosis. DNP mimics IL-3 withdrawal by making ATP unavailable locally to sustain this inhibitory pathway, whereas bcl-2 facilitates prolongation of an ATP-independent state wherein cellular [ATP] is maintained. Inhibition of apoptosis in B15 cells during ATP depletion therefore suggests that bcl-2 targets the apoptosis initiator. Tumor cells similarly maintained by bcl-2 in a stable metabolically dormant state would also be able to survive under adverse conditions but would readily revive when environments improved or when the cells became disseminated. Metabolic quiescence could therefore explain the survival advantage of tumor cells and how some metastatic deposits can remain dormant for prolonged periods of time. Although our cells are not directly comparable to those in solid tumors, and these findings may not be applicable to other cell types, we have shown that a mechanism does exist, facilitated by bcl-2, for significantly increasing survival via extending metabolic arrest.
We thank Professor M. Greaves (Institute for Cancer Research, London) for valuable assistance; Dr. M. Collins for supplying Bo, B14, and B15 cell lines; and I. Titley for performing the FACSCAN analyses. We thank K. Sondergaard and J. Jolly for technical assistance.