J Biol Chem, Vol. 275, Issue 17, 13012-13016, April 28, 2000
Human Cytosolic and Mitochondrial Folylpolyglutamate Synthetase
Are Electrophoretically Distinct
EXPRESSION IN ANTIFOLATE-SENSITIVE AND -RESISTANT HUMAN CELL
LINES*
John J.
McGuire
,
Cynthia A.
Russell, and
Malgorzata
Balinska§
From the Grace Cancer Drug Center, Roswell Park Cancer Institute,
Buffalo, New York 14263
 |
ABSTRACT |
Folylpolyglutamate synthetase (FPGS) activity in
CCRF-CEM human leukemia cells was found in the cytosolic (
67%
of total) and mitochondrial (22%) fractions. A polyclonal
antipeptide antibody (430Ab) to human FPGS specifically recognized
distinct immunoreactive bands (60 kDa) present in each
subcellular fraction. Human cytosolic FPGS (hcFPGS) migrated more
rapidly than mitochondrial FPGS (hmFPGS); their estimated difference in
molecular mass was 1 kDa. The human K562 acute nonlymphocytic leukemia
and the A253 and FaDu head and neck cancer cell lines also expressed
the two FPGS isoforms, and the ratio of hcFPGS to hmFPGS protein in
each cell line was similar. Since K562 and A253 cells are intrinsically
resistant to pulse methotrexate (MTX) exposure relative to CCRF-CEM and FaDu cells, respectively, because of decreased MTX polyglutamate synthesis (despite having similar levels of total FPGS activity expression), these data suggest that the natural difference in drug
sensitivity cannot be explained by compartmentalization of FPGS
activity. Higher expression of hmFPGS relative to hcFPGS was observed
in some sublines of CCRF-CEM with acquired MTX resistance suggesting
that differential expression of the hmFPGS isoform may contribute to
MTX resistance caused by decreased FPGS activity.
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INTRODUCTION |
It has been known for years that mitochondria have their own
folate-dependent enzymes and folylpolyglutamate pool, but
it has not been established how that pool is acquired or maintained (reviewed in Refs. 1-3). A central enzyme in establishing and maintaining folylpolyglutamate pools in whole cells is
folylpolyglutamate synthetase
(FPGS)1 (4, 5). Early studies
indicated that FPGS activity was present in both cytosol and
mitochondria (6, 7), suggesting that folate monoglutamates were
transport forms and that the essential (8) folate polyglutamate forms
were then synthesized independently in each compartment. Studies with
isolated mitochondria have confirmed that folate monoglutamates are
transported by a carrier-mediated facilitated-diffusion mechanism (9);
if folate polyglutamates pass the mitochondrial membrane, they do so
slowly, since the cytosolic and mitochondrial folate pools are not in
equilibrium (2, 10).
More detailed studies later showed the presence of FPGS activity in
Chinese hamster ovary (CHO) cell cytosol and mitochondria (2). The
function of FPGS within the two compartments has recently been studied.
Shane and co-workers (2, 11-13) studied CHO AUXB1 cells (which lack
expression of both cFPGS and mFPGS) transfected with Esherichia
coli or human FPGS that was expressed in either or both
compartments. In cells expressing cytosolic FPGS activity, mitochondrial folates were absent, and cells were auxotrophic for
glycine and methionine (12). However, cells expressing activity only in
mitochondria also contained cytosolic folates, although the levels were
low, and as a consequence, folate metabolism was not optimal. The
results indicate that both FPGS isoforms must be expressed to establish
normal folate metabolism and optimal growth. They also suggest that
cytosolic folylpolyglutamates cannot enter mitochondria, but the
mitochondrial folylpolyglutamate pool may exit to the cytosol (11), at
least slowly and to a limited extent.
The effect of the subcellular localization of FPGS on the mechanism of
action of the cancer chemotherapy drug methotrexate (MTX) was also
studied (14). Similar to our studies with acquired MTX resistance
through decreased MTX polyglutamate (MTXGn) accumulation (15, 16) and
with the nonpolyglutamylatable analog 
-FMTX (17, 18), the authors
(14) conclude that MTXGn and, thus, FPGS are not required during
continuous MTX exposure. Furthermore, the extent of metabolism to MTXGn
is dependent on FPGS level; thus, in pulse exposure, where MTXGn allows
intracellular retention in the absence of extracellular drug, MTX
sensitivity is directly related to FPGS level. In addition, the authors
(14) show that MTX does not enter mitochondria and does not affect the
pre-existing one-carbon pool in mitochondria, although its continued
presence can limit the further accumulation of folates in mitochondria.
Our work (15, 16) shows that decreased expression of FPGS activity and
protein (19) in whole cells can lead to very high levels of resistance
to pulse MTX exposure, a regimen similar to that employed for clinical
use of this drug. These findings and the observations that MTX is not
accessible to mitochondrial FPGS suggest the hypothesis that
selectively decreased expression of hcFPGS relative to hmFPGS could
lead to high level resistance to pulse MTX; cytosolic
folylpolyglutamate pools essential for growth would be supplied by slow
leakage from the mitochondria (11). We have explored this hypothesis
using activity assays and a recently developed 430Ab polyclonal
antipeptide antibody to hFPGS (19). In the course of these studies we
discovered that the two FPGS isoforms from whole cells exhibit
different electrophoretic mobilities, indicating a physico-chemical
difference between them that has not been reported previously.
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EXPERIMENTAL PROCEDURES |
Materials--
Bovine heart cytochrome c (type Va),
NADH, phenylmethylsulfonylfluoride, IGEPAL CA-630
((octylphenoxy)polyethoxyethanol), and Lubrol PX were from Sigma.
Benzamidine-HCl and Pefabloc protease inhibitors were from Calbiochem
and Roche Molecular Biochemicals, respectively. Other chemicals were
reagent grade or higher.
Cell Culture--
The CCRF-CEM human T-lymphoblastic leukemia
cell line (20) and FPGS-deficient, pulse MTX-resistant sublines R3,
R30, and R30dm were routinely cultured in RPMI 1640 containing 10%
horse serum (16); their generation times were 20-24 h. The
MTX-resistant subline R2 (defective MTX transport (21)) was cultured as
above, except that 1 µM MTX was also present; the
generation time of R2 was 19-20 h. K562 acute nonlymphoblastic
leukemia cell line, A253 (human submaxillary gland epidermoid
carcinoma) and FaDu (human pharyngeal squamous cell carcinoma) cell
lines (ATCC; Manassas, VA) were cultured in RPMI 1640 medium containing
10% fetal calf serum (both from Life Technologies, Inc.) as described
(22-24). Generation times of K562, A253, and FaDu were 20-23 h. Using
the GenProbe test, all cell lines were negative for
Mycoplasma contamination.
Isolation of Human Cytoplasmic and Mitochondrial
Fractions--
Based on results of Lin et al. (2) showing
that FPGS activity occurs only in the cytosolic and mitochondrial
compartments of CHO cells, a simple separation method was employed to
rapidly obtain these two subcellular fractions. Subcellular
fractionation of CCRF-CEM cells was performed essentially as described
(25); all operations were performed at 0-4 °C. Briefly,
logarithmically growing CCRF-CEM cells (3-5 × 105/ml; 4-6 × 108 cells total) were
harvested by centrifugation (1000 × gmax;
5 min), washed twice with iced 0.9% NaCl, and recovered by
centrifugation in a 12-ml graduated conical glass tube. The pellet was
loosened by tapping the tube, and five packed cell volumes of iced
hypotonic buffer (26) were added. Cells were resuspended by gentle
pipetting and allowed to swell for 5 min on ice, then transferred to an iced 7-ml Dounce homogenizer and disrupted with 15 strokes of the
tightest-fitting pestle. Microscopic examination at this point indicated that >99% of cells were lysed. The cell lysate was
transferred to an iced 12-ml conical glass centrifuge tube using a 5-ml
pipette and centrifuged for 6 min at 1000 × gmax to pellet nuclei and debris. The
postnuclear supernatant (PNS) was removed, and the pellet was
discarded. A sample of PNS was removed for activity assays (below), and
the remaining PNS was divided and further fractionated by
centrifugation for 1 h at 100,000 × gmax in a TL-100 tabletop Ultracentrifuge
(Beckman Instrument Co.). The supernatant (cytosolic fraction) was
removed for assay of FPGS, lactate dehydrogenase (LDH), and cytochrome
c oxidase (cyt c oxidase) and for Western immunoblot
analysis. The pellets contained intact mitochondria as well as other
membrane fragments, as confirmed by fixation of one pellet with
glutaraldehyde at room temperature and examination by light microscopy
(data not shown). One mitochondrial pellet (0.7-0.9 × 108 cell equivalents) was resuspended in 1 ml of isotonic
buffer (250 mM sucrose, 1 mM
Na2EDTA, 0.5 mM Pefabloc,
pH22 °C 6.9 (2)) to maintain mitochondrial integrity
until marker enzyme assay. Extraction buffer (100 mM
Tris-HCl, pH22 °C 8.85, 0.1 mM
Na2EDTA, pH22 °C 8.85, 1 mM
benzamidine-HCl, 0.5 mM Pefabloc, 50 mM
2-mercaptoethanol; 0.6 ml/108 cell equivalents) was added
to three pellets, and FPGS activity was released into the supernatant
by freezing and thawing twice in a dry ice/methanol bath followed by
centrifugation at 35,000 × g for 30 min. Protein
extraction buffer (50 mM Tris-HCl, pH 7.6, 120 mM NaCl, 0.5% IGEPAL CA-630, 1 mM
benzamidine-HCl, 0.5 mM Pefabloc, 0.75 ml/108
cell equivalents (27)) was added to one pellet to extract samples for
Western analysis (19).
Enzymes and Assays--
CCRF-CEM FPGS was partially purified
(28) and assayed (29) as described; one unit of activity incorporated 1 pmol of [3H]glutamate/h into the product. Cyt c oxidase
(a mitochondrial-specific marker) and LDH (a cytosolic marker) were
assayed essentially as described (30). One unit of cyt c oxidase
activity caused a one absorbance unit decrease/min at 550 nm (30); one
unit of LDH activity caused a one absorbance unit/min decrease at 340 nm (30). FPGS activity in PNS, cytosol, and mitochondrial fractions was
linear with respect to time and enzyme concentration under the
conditions tested. LDH activity was linear with respect to time and
enzyme in PNS and cytosol. Rates for cytochrome c oxidase activity in PNS and mitochondria were nonlinear with respect to time,
so the initial velocity was quantitated from the slope of the initial
portion of the reaction curve and used to verify enzyme linearity. Thus
cyt c oxidase activity in these fractions may be underestimates. LDH
activity in mitochondria and cyt c oxidase activity in cytosol was so
low that only the highest practicable enzyme concentration was tested.
Mixing of the cytosolic fraction with the mitochondrial fraction gave
102% and 103% of the expected LDH activity (n = 2)
and 106% and 111% of the expected cyt c oxidase activity
(n = 2). Mixing of cytosolic fraction with PNS gave
100% and 118% of the expected LDH activity (n = 2).
Mixing of the mitochondrial fraction and the PNS gave 91% and 112% of
the expected cyt c oxidase activity (n = 2). Similar
total activity, specific activity, and results of mixing studies were
obtained in preliminary experiments where only marker activities were assayed.
Western Immunoblots--
Western immunoblots of FPGS protein on
minigels was performed as described previously (19). High resolution
SDS-PAGE (17 cm wide × 16 cm long × 0.75 mm thick) was performed
in 7% acrylamide, 0.19% bisacrylamide separating gels with a 2-cm 4%
stacking gel in a Bio-Rad Protean IIxi apparatus. In later studies, 7%
acrylamide, 0.37% bisacrylamide separating gels were used to increase
resolution; under these conditions, different protein loads of the same
extract migrated at slightly different rates; thus molecular weight
determinations were less accurate. One lane contained Bio-Rad SDS-PAGE
molecular weight standards (high range, No. 161-0303). Proteins were
transferred from the gel to a polyvinylidene difluoride membrane
(Immobilon P; Millipore, Bedford, MA) in a Hoefer Transfor TE apparatus
at 30 V (constant) for 15 h using the same buffer system described for minigels (19), except that the apparatus temperature was maintained
at 4 °C by an external circulator. A second membrane was placed
behind the primary membrane during transfer; this membrane was stained
with 0.1% Fast Green FCF (20% methanol, 5% acetic acid) for 20 s and destained 3 times with 20% methanol, 5% acetic acid to check
for protein blow-through. Western analysis (below) of an unstained
secondary membrane showed that no FPGS passed through the primary
membrane under the conditions of electrotransfer. To detect
untransferred material, the residual gel was stained with 0.1%
Coomassie Brilliant Blue (40% methanol, 10% acetic acid) for 30 min
and destained in 40% methanol, 10% acetic acid.
Immunoblotting was performed as described previously (19). Most studies
used immunoaffinity-purified rabbit polyclonal 430Ab (19) elicited by a
multiple antigen peptide to residues 275-290 of the human FPGS
sequence (31); 430Ab was obtained during a pH 2.5 elution of the
immunoaffinity column. Some experiments, however, used 430Ab
immunoaffinity purified by an alternate means. Briefly, after pH 2.5 elution (19), the immunoaffinity column was rewashed with 10 mM Tris-HCl, pH 8.8, until equilibrated, and then the
column was eluted with 100 mM triethylamine-HCl, pH 11.5 (32). The resulting basic eluate (10 ml) was neutralized to pH 8.5 by the addition of 2 ml of 1 M Tris-HCl, pH 8.0, and concentrated by adsorption and elution from protein A-Sepharose (19).
After purification and concentration, 60% of the antibody originally in the serum was recovered in the low pH elution of the
immunoaffinity column (19). Only 12% of the antibody was recovered
from the basic elution, but this antibody reacted only with FPGS (data
not shown) and not with the nonspecific bands noted with the
acid-eluted antibody (19). Since this base-eluted antibody was obtained
in smaller amounts, it was used only in selected experiments despite
its greater specificity.
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RESULTS AND DISCUSSION |
Detection of hcFPGS and hmFPGS Activity and Protein--
FPGS
activity has been previously localized to both the cytosolic and
mitochondrial fractions of sheep liver, rat liver, and CHO cells (2, 6,
7). As part of our effort to explore the role of FPGS in antifolate
activity and resistance in human leukemia, we examined hcFPGS and
hmFPGS activity in CCRF-CEM human leukemia cells. Separation by
differential centrifugation of the cytosolic and mitochondrial
compartments from CCRF-CEM cells was achieved, as evidenced (Table
I) by the separation of the cytosolic (LDH) and mitochondrial (cyt c oxidase) marker activities; based on
these markers, fractions were also obtained in good overall yield (30).
FPGS activity was detected in the cytosolic and mitochondrial fractions
of the CCRF-CEM cell line (Table I). About 67% (range 63-71% in two
studies) of the total FPGS activity of the PNS was found in the
cytosol, and about 22% (range 19-24% in 2 studies) was found in the
mitochondria. The specific activity was approximately equal in the two
compartments, although it should be noted that the mitochondrial
fraction was not pure (see "Experimental Procedures"). Mixing of
PNS + cytosol or PNS + mitochondria gave 80% (range 79-81%;
n = 2) and 89% (range 70-107%; n = 2), respectively, of the expected FPGS activity, indicating the
validity of the activity measurements. Because of the low levels of
FPGS activity detected in assays of mitochondria, the latency of this
activity was not measured; FPGS from CHO cell mitochondria was latent, however (2).
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Table I
Subcellular distribution of FPGS from CCRF-CEM human leukemia cells
Mixing experiments ("Experimental Procedures") indicated that
inhibitors or activators of each activity were not present. The entire
experiment was repeated with similar results. Sp. Act., specific
activity.
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The proportion of activity in the two compartments of CCRF-CEM cells
differs slightly from those in rat liver (7), where about 75% was in
the cytosol and 13% in the mitochondria, and from CHO cells (2), where
about 50% was in each compartment. This may represent species or
tissue differences, but given the low measured activity in the
mitochondrial fraction, these differences may represent inaccuracy in
the measurements.
Western immunoblot analysis on minigels showed that polyclonal 430Ab,
developed to a deduced peptide of human FPGS (19), detected an
immunoreactive band at the appropriate (60 kDa) molecular mass in
each fraction (data not shown). Reaction with both isoforms was
expected, since the two isoforms are translated from mRNA species
derived from alternate transcription start sites within a single gene
(33-35), and the internal peptide used to elicit the antibody is
common to the isoforms (19).
High Resolution Western Immunoelectrophoretic Detection of hcFPGS
and hmFPGS--
High resolution SDS-PAGE analysis (Fig.
1) showed that the immunoreactive FPGS in
CCRF-CEM PNS actually appeared as a doublet and that the separated
cytosolic and mitochondrial fractions contained single immunoreactive
bands that corresponded to the lower and upper bands, respectively. A
mixture of cytosolic and mitochondrial fractions reproduced the doublet
of the PNS. Although the individual molecular weights of the hcFPGS and
hmFPGS as determined from 11 separate analyses were nearly identical
(60 kDa), within each experiment, the two always differed by 1 kDa.
Neither band was detected if 430Ab was preincubated with its cognate
multiple antigen peptide (19) or if an irrelevant IgG replaced 430Ab
(data not shown (19)). These data support a specific antibody
interaction with FPGS isoforms. Direct solubilization of intact
CCRF-CEM cells and subsequent Western analysis showed that both bands
were again detected (below), suggesting that the difference in mobility
is not a proteolysis artifact. Partially purified (23) CCRF-CEM FPGS
was also resolved into two species at high resolution (data not shown).
The biochemical basis of the difference in electrophoretic mobility is
currently under study.
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Fig. 1.
Western immunoblot analysis of human FPGS
from postnuclear supernatant, purified cytosol, and mitochondria from
CCRF-CEM cells after high resolution SDS-PAGE. The PNS (75 µg),
cytosolic (C; 75 µg), mitochondrial (M; 75 µg), and cytosolic + mitochondrial (75 µg each) fractions were
resolved by high resolution SDS-PAGE. Analysis of these samples was
repeated with similar results; the entire experiment was also repeated
with similar results.
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hcFPGS and hmFPGS in Other Human Cell Lines--
Whole cell
extracts of other human cell lines were analyzed (Fig.
2) to determine whether the different
mobilities of FPGS isoforms were specific to CCRF-CEM. K562 acute
nonlymphocytic leukemia cells and two HNSCC cell lines, A253 and FaDu,
displayed the same two isoforms. Thus the presence of the distinct
isoforms appears to be a general feature of FPGS in human cells. Since eukaryotic FPGS display significant homology (31, 33, 35, 36), this
phenomenon may be universal in eukaryotes. This could not be tested,
however, because the 430Ab was elicited to a peptide that is not
conserved across species.
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Fig. 2.
Western immunoblot detection of FPGS protein
in extracts of CCRF-CEM and K562 leukemia cells and in A253 and FaDu
HNSCC cells. Whole cell extracts (100 µg of protein) were
resolved by SDS-PAGE on a 16-cm separating gel, electrotransferred to
polyvinylidene difluoride, and visualized with anti-FPGS peptide
antibody 430Ab and chemiluminescent detection as described under
"Experimental Procedures." The two bands appear at 60 kDa. Note
that differences in signal intensity between cell lines do not indicate
quantitative differences in protein expression because of variability
in transfer efficiency and detection. Exposures shown are
representative of data from at least two extracts. Panel A,
expression of FPGS isoforms in CCRF-CEM and K562 leukemia cells.
Panel B, expression of FPGS isoforms in A253 and FaDu HNSCC
cells. Note that the apparent difference in migration in these samples
is a result of a small difference in the protein loaded in each lane
(see "Experimental Procedures").
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hcFPGS and hmFPGS in Drug Sensitivity and
Resistance--
Decreased antifolate polyglutamate accumulation is one
mechanism by which tumor cells can display natural resistance or
acquire resistance to pulse exposure to antifolates that require
polyglutamylation for retention (such as MTX) and/or resistance to
antifolates that require polyglutamylation for potent inhibition of
their target enzymes (reviewed in Ref. 37). This decreased
polyglutamate accumulation is often a result of decreased expression of
FPGS activity. In some cases, however, the difference in total cellular FPGS activity is small relative to the decrease in polyglutamylation of
the antifolate (e.g. Ref . 38). In this regard, it has been shown that MTX does not enter mitochondria (9, 14), but that mitochondrial folate polyglutamate forms may exit to the cytosol at a
slow rate and allow for cell viability in the absence of cFPGS (11).
This suggests that reduced hcFPGS activity with preservation of hmFPGS
activity would lead to resistance of cells to pulse exposure to drugs
like MTX; MTXGn would not accumulate in the cytosol, but the essential
cytosolic folylpolyglutamate pools would be supplied from the
mitochondria. Since most studies to date have examined only total cell
FPGS, if hcFPGS were selectively decreased, the effect on total
activity would be minimized, perhaps leading to the discordance between
MTXGn synthesis in intact cells and the FPGS activity measurements.
Because of the compartmentalization of (anti)folate metabolism in the
cell (1, 3), measurement of FPGS in both compartments is, thus,
essential. Since the two isoforms can be measured in high resolution
Western blots (above), this method was used to explore this hypothesis
without physically separating the mitochondrial and cytosolic compartments.
Relative expression of hcFPGS and hmFPGS was determined in pairs of
human cell lines that show widely different accumulation of MTXGn but
similar levels of total cellular FPGS activity measured in
vitro. CCRF-CEM (acute lymphoblastic leukemia) and FaDu (HNSCC) accumulate high levels of MTXGn relative to K562 (acute
nonlymphoblastic leukemia) and A253 (HNSCC), respectively, despite each
pair having similar FPGS levels (38, 39). Lower MTXGn accumulation
leads in each case to decreased sensitivity (i.e.
natural resistance) to pulse MTX exposure relative to its paired cell
line (24, 38).
The relative levels of hcFPGS compared with hmFPGS protein were similar
in these paired cell lines (Fig. 2; Table
II). The largest difference occurred
between CCRF-CEM and K562, but the difference indicates greater
relative expression of hcFPGS in the naturally resistant K562 line,
which should impart greater sensitivity, not resistance, to pulse MTX
relative to CCRF-CEM. These data suggest that the differences in
sensitivity to pulse MTX exposure of these cell pairs cannot be
explained by differential expression of one FPGS isoform and, hence,
not by compartmentalized MTX metabolism.
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Table II
Relative expression of cFPGS and mFPGS protein isoforms in cell lines
displaying MTX sensitivity and natural resistance
Western blots of whole cell extracts of cell lines, including the blots
of Fig. 2, were quantitated by densitometry, and the ratios of the
intensity of cFPGS and mFPGS were calculated. Values are averages
±S.D. of the number of individual exposures listed in parentheses and
are from at least two extracts prepared at different times, each of
which was analyzed in separate experiments.
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Relative expression of FPGS isoforms was also assessed in sublines of
CCRF-CEM with acquired MTX resistance (Fig.
3; Table III). The R2 subline (defective MTX
uptake (21)), which shows elevated FPGS activity (2-fold (40)),
displayed a slightly greater proportion of the activity in the cytosol.
R3 (moderate decrease of whole cell FPGS activity (16)) had no change
in relative expression of the isoforms despite the decrease in total FPGS activity in these cells. In contrast, R30 and its clonal progeny,
R30dm, both of which express very low total FPGS activity, have a
greater preservation of the mitochondrial isoform. These latter data
support the hypothesis that decreased relative expression of cFPGS may
contribute to resistance to pulse MTX exposure. The basis for this
difference in isoform expression is now under study.
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Fig. 3.
Western immunoblot detection of FPGS protein
in extracts of CCRF-CEM and MTX-resistant sublines. Whole cell
extracts were resolved by SDS-PAGE and analyzed as described in Fig. 2.
The two bands appear at 60 kDa. Each exposure shown is
representative of data from at least two extracts (except R2; one
extract analyzed in three separate experiments), each of which was
analyzed in separate experiments. Panel A, CCRF-CEM
versus R2 (50 µg of each). Panel B, CCRF-CEM
versus R3 (50 µg each). Panel C, CCRF-CEM (50 µg) versus R30 and R30dm (200 µg of each).
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Table III
Relative expression of cFPGS and mFPGS protein isoforms in CCRF-CEM
human leukemia and MTX-resistant sublines
Western blots of whole cell extracts of cell lines, including the blots
of Fig. 3, were quantitated by densitometry, and the ratios of the
intensity of cFPGS and mFPGS were calculated. Values are averages
±S.D. of the number of individual exposures listed in parentheses and
are from at least two extracts prepared at different times, each of
which was analyzed in separate experiments.
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ACKNOWLEDGEMENTS |
We thank Dr. Alexander Maccubbin of this
Center for providing the Lubrol PX detergent and Dr. Jennifer Black,
Director of the Roswell Park Cancer Institute Cell Analysis Facility,
for microscopic examination of the mitochondrial pellets.
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FOOTNOTES |
*
These studies were supported by National Institutes of
Health Grant (NCI) CA43500 (to J. J. M.) and Roswell Park Cancer
Institute Core Grant CA16056. A preliminary account of these studies
was presented at the 89th Annual Meeting of the American Association for Cancer Research, New Orleans, LA.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
To whom correspondence should be addressed: Grace Cancer Drug
Center, Roswell Park Cancer Institute, Elm and Carlton Sts., Buffalo,
NY 14263. Tel.: 716-845-8249; Fax; 716-845-8857; E-mail: mcguire@sc3101.med.buffalo.edu.
§
A visiting Scientist. Permanent address: Dept. of Cellular
Biochemistry, Nencki Institute of Experimental Biology, 3 Pasteur St.,
02-093 Warsaw, Poland.
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ABBREVIATIONS |
The abbreviations used are:
FPGS, folylpolyglutamate synthetase (EC 6.3.2.17);
hcFPGS, human cytosolic
FPGS;
hmFPGS, human mitochondrial FPGS;
HNSCC, head and neck squamous
cell carcinoma;
CHO, Chinese hamster ovary;
cyt c oxidase, cytochrome
c oxidase (EC 1.9.3.1);
LDH, lactate dehydrogenase (EC
1.1.1.27);
MTX, methotrexate (2,4-diamino-10-methylpteroylglutamic acid);
MTXGn, poly(-glutamyl) derivatives of MTX;
PNS, postnuclear
supernatant;
PAGE, polyacrylamide gel electrophoresis.
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