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Effects of 1-methyl cyclohexane carboxylic acid (CCA) on cellular energetics in neuroblastoma cells
Vol. 103, No. 3,198l December
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 1044-1051
15, 1981
EFFECTS OF I-METHYL
CYCLOHEXANE CARBOXYLIC ACID (CCA)
ON CELLULAR ENERGETICS IN NEUROBLASTOMA CELLS Bernard Croizat, Francis Berthelot, Marie-Madeleine Portier, Hdlbne Ohayon* and Franqois
Gros
Laboratoire de Biochimie Cellulaire, CollQe de France, 75231 Paris Cedex 05, France, et *Service de Microscopic Electronique, Institut Pasteur, 75015 Paris, France
Received
October
30,1981
SUMMARY The level of cellular energetics has been estimated in neuroblastoma cells under dif erent culture conditions. The cellular accumulation of isomerase-2-deoxyp4 Cf D- glucose-6-phosphate was taken as reflecting glucose utilization. A considerably higher amount of radioactivity - 2.5 to 4 times - is found in CCA treated cells, as compared to other types of cultures, corresponding to a higher rate of deoxyglucose penetration and utilization. INTRODUCTION Cloned possess
cell
lines
many neuronal
culture,
the
properties
cells
neuronal
model
exhibit
for
since
its
injection
studying It
and anticonvulsive, differentiation proteins
cells in
dimensional stimulated
and methionine
expression
(4).
and control
to check,
(6). incorporation
that
by neurite
Synthesis into
were
[I-14C]D-glucose-6-phosphate
complex
0006-291X/81/231044-08$01.00/0 Copyright All righa
0
I981
by Academic Press, in any form
of reproducfion
Inc.
reserved.
acid
some insoluble 2-deoxy
(CCA),
antianoxic
CCA promotes
compared
the
vitro,
i.e.
extension
to be
terminal
carboxylic
of vimentin
; 2DG-6-P,
of
considered
in
effects,
We showed
cultures
are during
cyclohexane
as evidenced
electrophoregrams
they
has pharmacological
conditions
and biochemical
reason,
interesting
of 1 methyl
on the brain
CCA-treated
appropriate
physiological
For this
was thus
mouse neuroblastoma
Under
the genetic
the rat
of the cells from
(l-3).
neurone.
on neuroblastoma
the C-1300
morphological,
differentiation.
effect
from
characteristics
of the mature
a convenient
derived
a marked (5).
The
on two-
was strongly proteins, D-glucose-6-phos-
which
BIOCHEMICAL
Vol. 103, No. 3,198l
are presumably
membrane
was increased.
The synthesis
However,
molecular
course
these
effects
within
the cell.
effects
of anoxia
more generally, purpose,
by Sokoloff
(7,
initially second
the
complex
phosphate activity
reaction between isomerase
blastoma MATERIALS
cell
was not
possible
within
seemed that
cultures
it
rat might
brain
sections.
glucose
but
with here
brain
with
in
This Labelled
the biochemical
oxygen
culture
uptake
or, For that
complex
was used earlier
deoxyglucose
is
does not proceed second
beyond
reaction
is
and the hexose
the amount
with
the
cultures.
can be considered obtained
we used
against
viva
approach
of this
Consequently,
to other
the
[14C]2DG-6-P
IJ4C 3 deoxyglucose
the results
as compared
to correlate
influence
the process
the proteins
to the
such a correlation,
The product
accumulates.
modified.
related
of neuroblastoma
utilisstion.
phosphorylated
which
We report
to find
of the isomerase-_
of the pathway. the
the brain
energetics
rat like
co-precipitating activity.
it
of glucose
8) with
metabolized
the
been clearly
accumulation
as a measure
was also
not yet
CCA protects
the cellular
the cellular
was taken
it
(4),
the cytoskeleton,
have
the drug
Since
with
and isotubulins
In an attempt
approach.
RESEARCH COMMUNICATIONS
associated
of actin
Moreover, of
BIOPHYSICAL
proteins
events
effects
a more direct
cell
bound
of neurogenesis.
pharmacological
AND
of radioas a measure
CCA-treated
of
neuro-
conditions.
AND METHODS
Cell culture. We used the NIE-115 clone from mouse neuroblastoma C-1300. The conditions of culture have been previously described (9). The cells were grown attached to a Falcon culture dish. They extend neurites when the serum is withdrawn from the medium or when CCA or Me2SO is added to the serum-containing medium. Cells kept in the serum-containing medium in the absence of drug were either grown in logarithmic phase or maintained at confluence in a stationary phase. I mg/ ml order to (4). The incubation every 24
Drug treatment. CCA-----------T----treated cultures. The CCA concentration was -of medium (6 x lo-3 M). This high concentration was selected in correspond to those previously used in pharmacological studies cells were maintained for three days in these conditions prior to with [14C]deoxyglucose. Cultures were changed with fresh medium hours.
Me2SO treated cultures. Cultures were kept for seven days in -- :-:---------------3 medium contarning 2 % Me2SO prror to labeling in the same medium. The medium was changed every 24 hours.
1045
BIOCHEMICAL
Vol. 103, No. 3,198l
AND
BIOPHYSICAL
50
RESEARCH
100
COMMUNICATIONS
t (min.)
FIG. 1. Cellular incorporation of [14C]2-deoxyglucose. Total radioactivity was measured in the 12 000 8 supernatant and normalised to 106 cells. Cells Each value is the average of four were counted with a haemocytometer. successive countings. M CCA treated cells ; serum free cultures ; Me2SO treated cells ;A ---A growing cells in logarithmic phase ; A---I confluent cells in stationary phase.
[14C]deoxyglucose labeling and samples preparation and treatment. Media were renewed 30 minutes prior to the addition of 1 uCi/ml of 2-deoxv [l-14C]D-glucose (57 mCi / mmole) (Amersham). The 10 cm dishes were inocul-ated so that they contained about 2.5 x 106 cells at the time of deoxyglucose incorporation for every type of culture except for confluent cells in stationary phase which contained 2 x lo7 cells. Deoxyglucose incorporation ranged from 10 minutes to 90 minutes. The dishes were then placed on ice, rinsed with cold saline buffer : Tris-HCl 10s2 M pH 7.6, NaCl 0.25 M, MgC12 10-2Mand lysed with Nonidet P-40. After centrifugation for 10 minutes at 12 000 8, 200 1.11 samples of the supernatant were collected : i) some samples were directly counted in Bray scintillation mixture to account for total cell radioactivity ; ii) other samples were added with 1.8 ml ethanol. After 10 minutes at 0°C the ethanol precipitate was spun down for 20 minutes at 16 000 &. The pellet was resuspended in 0.5 ml Tris/NaCl/Mg buffer and counted in 5 ml Bray scintillation mixture to account for the radioactivity bound to proteins. 2DG and 2DG-6-P are not ethanol precipitable. Consequently the radioactivity in the precipita e corresponds to the 14C actually bound t,o protein, i.e. to the isomerasecomplex. E. 14C 3 2DG-6-P RESULTS Two cells
in
types
logarithmic
[14,]2DG
of
non-differentiated phase,
uptake.
ii)
Fig.
cultures non-dividing
1 shows
1046
cells
the
kinetics
were
employed
kept
of
in
stationary
2-deoxyglucose
: i)
growing phase.
BIOCHEMICAL
Vol. 103, No. 3,198l
AND
0
FIG. 2. Measurement ated to A---A
as measured
more rapid tions.
precipitated
kinetics
After
growing
cells versus
corresponds
t(min.)
radioactivity.
penetration,
and twice
Ethanol
as high
those
precipit-
the amount
as in confluent
from
is very
2DG-6-P
to account its
for
the
phosphorylation
cells
three
shown
on fig.
was also
found
in
cells
and its
1047
was and in
(48 000 cpm per
IO6
14 C radioactivity
isomerase-2DG-6-P
complex.
the activity
of glucose
Total
radioactivity
may be
binding formation.
2. A considerably
the CCA-treated
free
condi-
since
successive
p4 CI 2DG- 6-P complex
are
(8).
the other
in serum
times
markedly
of radioactivity
: 2DG, 2DG-6-P,
low in nervous
with
and total
may be neglected
various
expressed
obtained
in Me2S0 treated,
molecules
after
to CCA cultures
that
than
radioactivity
15 000 and 25 000 respectively),
Isomeraseprecipitation
corresponding
in CCA cells
formed
assumed
cell
of incubation,
to different
phosphatase
total
of 2DG uptake
90 minutes
higher
Products
by counting
The curve
3 times
fraction
of ethanol
loo
COMMUNICATIONS
from the 12 000 8 supernatant was measured and normalised 106 cells. CCA treated cells. o-----d serum free cultures ; He2SO treated cells ; a---Agrowing cells in logarithmic phase ; confluent cells in stationary phase.
of incubation.
then
50
RESEARCH
radioactivity
uptake,
cells
BIOPHYSICAL
cells.
metabolic
steps
i.e.
2DG
to isomerase. The results higher
uptake
The yield
of ethanol into
of ethanol
this
BIOCHEMICAL
Vol. 103, No. 3,1981
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
TABLE I. Percent of the cellular [14C]2DG recovered the isomerase-p4C]2DG-6-P complex
IO min
60 min
45.9
50.3
cells
30.2
37
cultures
18.6
37.3
27.7
40.3
36.9
44.4
CCA treated
cells
Me2SO treated Serum free Growing
cells
Confluent
as
(log.
cells
phase)
(stat.
phase)
These percentages were calculated by dividing the values from fig. 2 (c.p.m. in the ethanol precipitate from 12 000 g supernatant) by the corresponding values from fig. 1 (c.p.m. in the 12 000 4 aupernatant). See RESULTS.
precipitation
is
less
considered
as minimal
of precipitation
total
radioactivity
table
I indicate
ly higher
comparable
for
that,
shown
it
in fig.
culture
time
studied,
cells.
That
means that
independent
of the effect
the yield so that
radioactivity
populations.
at every
that
conditions,
of ethanol-precipitated cell
2 must be
may be assumed
the various
in the different
in CCA treated
the cell
Nevertheless,
the percentages
by CCA treatment, through
100 % and the values
values.
is
one may compare
than
this
versus
The results percentage
complex
is
shown in significant-
formation
is
enhanced
of CCA on the penetration
of 2DG
membrane.
DISCUSSION In this designed
by Sokoloff
various
physiological
markedly
increased
CCA-treated cell
shown)
cells
energetics.
number,
study
but were
neuronal
to evaluate
accumulation ; this
expressed
we have used
cerebral
The main
activity
result [
expressed
as a function
similar.
1048
here
here
14 C 2DG-6-P 1
may be assumed
are
the elegant
method
in response
reported
of the isomerase-
accumulation
The 14 C counts
cells,
local
conditions.
the results very
with
to
concerns complex
in the
to reflect
the level
as a function
of cell
of protein
content
the
(data
of
not
BIOCHEMICAL
Vol. 103, No. 3,198l
Many variables We have paid
specific
ii)
cell
effects
Both
attention replication,
to obtain
and CCA-treated these
agents
Measurements
were
i.e.
cells
allows
morphogenesis,
also
inducers.
induction
made in
in logarithmic
phase
and iiii) were
in altered
added
to occur
two types
culture
by
trophic
condi-
cultures.
in a 7.5 % fetal in the absence
calf
of inducers.
of non-differentiated and confluent
the
induced
to Me2 SO treated
were
growth
energetics.
trophic
Cultures
morphogenesis compared
COMMUNICATIONS
of cellular
neuronal
were
normal
levels
of i)
neuronal
cultures
RESEARCH
to the effects iii)
of neuronal
serum medium which
growing
to the
of the differentiation
serum deprivation tions,
BIOPHYSICAL
may contribute
a particular
conditions,
AND
cultures,
cells
in a stationary
phase. The level
of cell
and the accumulation P igher
cells
stationary
to promote to its
found
between
a complete
stimulation
medium.
the "confluent
These
deoxyglucose
cells"
correspond
(10,
increases
in the oxygen
in neuroblastoma deprivation measurements approach. by classical
cells
as compared may reveal Morphological agentshas
14
[
is
in confluent
level.
CCA appears
cells
Thus,
from glucose
to a different
penetr-
difference and cells
the effect
cells
3 to 4 times with
No significant
emphasize
CI 2DG uptake
of cultures,
pathway
cellular
was
growing
in
due to CCA. The
may reflect
of Walum et al. who observed
cells"
In contrast
types
serum deprived
observations
the
complex,
an intermediate
cells,
observed
uptake
other
of the metabolic
situation
phase
in all
to D-fructose-6-P.
Me2S0 treated
from
1y4CeI 2DG-6-P
reaching
isomerisation
intermediate
"stationary
than
cells
a global
ation
estimated
of the isomerase-
in CCA-treated
confluent
energetics,
the fact
state
from
a decrease
that
the
in the
11).
to our
results,
Nissen
uptake,measured that
minor
grown
changes
been
reported
to differentiate
in a complete that
differentiation also
(12)
by a micromanometric
had been induced
to cells
et al.
are not measured
induced reported
1049
medium
small
technique, by serum (13). with
These our
by serum deprivation
to be accompanied
by minor
or changes
BIOCHEMICAL
Vol. 103, No. 3,198l
at
the level
of mRNAs and proteins It
metabolism
is
significantly
is
drastically
synthesis
ation).
classical
that
membrane
effects
that
Several
that
neuroblastoma
and that
a fundamental
role
in
are not neuronal
the burst triggering
not
shown).
bound
CCA also
after usually
CCA-treated
energetics
cells
to oligomycin stimulates
the
and cytoskeleton addition screened
by CCA (manuscript
a more complete
the neuronal
in the ultra-
resistance
proteins
observed
in cell
in neuroblastoma
For example,
and their
induced
CCA promotes
changes
by modifications
markers,
are markedly
agents,
We believe
drastic
microscopy.
(data
RESEARCH COMMUNICATIONS
14, 15).
more mitochondria
serum deprivation. with
by electron
increased
(6),
(9,
to note
of some insoluble
components
BIOPHYSICAL
by CCA are accompanied
as observed
contain also
interesting
induced
structure
AND
neuronal reported
of Me2 SO or in studies in preparexpression here
in
may play
differentiation.
ACKNOWLEDGMENTS This work Fransoise Perrot for typing the manuscript.
has been supported by a grant from SANOFI. We thank her excellent technical assistance and Denise Baron
for
REFERENCES 1. Augusti-Tocco, G. and Sato, G. (1969) Proc. Natl. Acad. Sci. USA 66, 311-315. 2. Schubert, D., Humphreys, S., De Vitry, F. and Jacob, F. (1971) Develop. Biol. 25, 514-546. 3. MC Morrz, F.A., Koller, A.R., Moore, B.W. and Perumal, A.S. (1974) J. Cell Physiol. 3, 473-480. 4. Simard, J., Ferrandes, B., Lacolle, J.Y. and Eymard, P. (1978) Satellite Symposium on cerebra-vascular diseases, Reims, France. 5. Croizat, B., Berthelot, F., Ferrandes, B., Eymard, P., Sahuquillo, C. and Gros, F. (1979) Compt. Rend. Acad. SC. Paris 289 S&D, 1283-1286. 6. Portier, M.M., Eddg, B., Berthelot, F., Croizat, B. and Gros, F. (1980) Biochem. Biophys. Res. Commun. 96, 1610-1618. 7. Kennedy, C., Des Rosiers, M.H., Sakurada, O., Shinohara, M., Reivich, M., Jehle, J.W. and Sokoloff, L. (1976) Proc. Natl. Acad. Sci. USA 2, 4230-4234. 8. Sokoloff, L., Reivich, M., Kennedy, C., Des Rosiers, M.H., Patlak, C.S., Pettigrew, K.D., Sakurada, 0. and Shinohara, M. (1977) J. Neurochem. 28, 897-916. 9. Croizat, B., Berthelot, F., Felsani, A. and Gros, F. (1977) Eur. J. Biochem. 76, 405-412. 10. Edstriim, M., Kanje, M. and Walum, E. (1976) Exntl. Cell Res. 97, 6-14.
1050
Vol. 103, No. 3,198l
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
11. Walum, E. and Edstrgm, A. (1976) Exptl. Cell Res. 97, 15-22. 12. Nissen, C., Ciesielski-Treska, J., Hertz, L. and Mandel, P. (1973) J. Neurochem. 0, 1029-1035. 13. Hertz, L. (1966) J. Neurochem. 13, 1373-1387. 14. Felsani, A., Berthelot, F., Gros, F. and Croizat, B. (1978) Eur. J.. Biochem. 92, 569-577. 15. Grouse, L.D., Schrier, B.K., Letendre, C.H., Zubairi, M.Y. and Nelson, P.G. (1980) J. Biol. Chem. -255, 3871-3877.
1051
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages 1044-1051
15, 1981
EFFECTS OF I-METHYL
CYCLOHEXANE CARBOXYLIC ACID (CCA)
ON CELLULAR ENERGETICS IN NEUROBLASTOMA CELLS Bernard Croizat, Francis Berthelot, Marie-Madeleine Portier, Hdlbne Ohayon* and Franqois
Gros
Laboratoire de Biochimie Cellulaire, CollQe de France, 75231 Paris Cedex 05, France, et *Service de Microscopic Electronique, Institut Pasteur, 75015 Paris, France
Received
October
30,1981
SUMMARY The level of cellular energetics has been estimated in neuroblastoma cells under dif erent culture conditions. The cellular accumulation of isomerase-2-deoxyp4 Cf D- glucose-6-phosphate was taken as reflecting glucose utilization. A considerably higher amount of radioactivity - 2.5 to 4 times - is found in CCA treated cells, as compared to other types of cultures, corresponding to a higher rate of deoxyglucose penetration and utilization. INTRODUCTION Cloned possess
cell
lines
many neuronal
culture,
the
properties
cells
neuronal
model
exhibit
for
since
its
injection
studying It
and anticonvulsive, differentiation proteins
cells in
dimensional stimulated
and methionine
expression
(4).
and control
to check,
(6). incorporation
that
by neurite
Synthesis into
were
[I-14C]D-glucose-6-phosphate
complex
0006-291X/81/231044-08$01.00/0 Copyright All righa
0
I981
by Academic Press, in any form
of reproducfion
Inc.
reserved.
acid
some insoluble 2-deoxy
(CCA),
antianoxic
CCA promotes
compared
the
vitro,
i.e.
extension
to be
terminal
carboxylic
of vimentin
; 2DG-6-P,
of
considered
in
effects,
We showed
cultures
are during
cyclohexane
as evidenced
electrophoregrams
they
has pharmacological
conditions
and biochemical
reason,
interesting
of 1 methyl
on the brain
CCA-treated
appropriate
physiological
For this
was thus
mouse neuroblastoma
Under
the genetic
the rat
of the cells from
(l-3).
neurone.
on neuroblastoma
the C-1300
morphological,
differentiation.
effect
from
characteristics
of the mature
a convenient
derived
a marked (5).
The
on two-
was strongly proteins, D-glucose-6-phos-
which
BIOCHEMICAL
Vol. 103, No. 3,198l
are presumably
membrane
was increased.
The synthesis
However,
molecular
course
these
effects
within
the cell.
effects
of anoxia
more generally, purpose,
by Sokoloff
(7,
initially second
the
complex
phosphate activity
reaction between isomerase
blastoma MATERIALS
cell
was not
possible
within
seemed that
cultures
it
rat might
brain
sections.
glucose
but
with here
brain
with
in
This Labelled
the biochemical
oxygen
culture
uptake
or, For that
complex
was used earlier
deoxyglucose
is
does not proceed second
beyond
reaction
is
and the hexose
the amount
with
the
cultures.
can be considered obtained
we used
against
viva
approach
of this
Consequently,
to other
the
[14C]2DG-6-P
IJ4C 3 deoxyglucose
the results
as compared
to correlate
influence
the process
the proteins
to the
such a correlation,
The product
accumulates.
modified.
related
of neuroblastoma
utilisstion.
phosphorylated
which
We report
to find
of the isomerase-_
of the pathway. the
the brain
energetics
rat like
co-precipitating activity.
it
of glucose
8) with
metabolized
the
been clearly
accumulation
as a measure
was also
not yet
CCA protects
the cellular
the cellular
was taken
it
(4),
the cytoskeleton,
have
the drug
Since
with
and isotubulins
In an attempt
approach.
RESEARCH COMMUNICATIONS
associated
of actin
Moreover, of
BIOPHYSICAL
proteins
events
effects
a more direct
cell
bound
of neurogenesis.
pharmacological
AND
of radioas a measure
CCA-treated
of
neuro-
conditions.
AND METHODS
Cell culture. We used the NIE-115 clone from mouse neuroblastoma C-1300. The conditions of culture have been previously described (9). The cells were grown attached to a Falcon culture dish. They extend neurites when the serum is withdrawn from the medium or when CCA or Me2SO is added to the serum-containing medium. Cells kept in the serum-containing medium in the absence of drug were either grown in logarithmic phase or maintained at confluence in a stationary phase. I mg/ ml order to (4). The incubation every 24
Drug treatment. CCA-----------T----treated cultures. The CCA concentration was -of medium (6 x lo-3 M). This high concentration was selected in correspond to those previously used in pharmacological studies cells were maintained for three days in these conditions prior to with [14C]deoxyglucose. Cultures were changed with fresh medium hours.
Me2SO treated cultures. Cultures were kept for seven days in -- :-:---------------3 medium contarning 2 % Me2SO prror to labeling in the same medium. The medium was changed every 24 hours.
1045
BIOCHEMICAL
Vol. 103, No. 3,198l
AND
BIOPHYSICAL
50
RESEARCH
100
COMMUNICATIONS
t (min.)
FIG. 1. Cellular incorporation of [14C]2-deoxyglucose. Total radioactivity was measured in the 12 000 8 supernatant and normalised to 106 cells. Cells Each value is the average of four were counted with a haemocytometer. successive countings. M CCA treated cells ; serum free cultures ; Me2SO treated cells ;A ---A growing cells in logarithmic phase ; A---I confluent cells in stationary phase.
[14C]deoxyglucose labeling and samples preparation and treatment. Media were renewed 30 minutes prior to the addition of 1 uCi/ml of 2-deoxv [l-14C]D-glucose (57 mCi / mmole) (Amersham). The 10 cm dishes were inocul-ated so that they contained about 2.5 x 106 cells at the time of deoxyglucose incorporation for every type of culture except for confluent cells in stationary phase which contained 2 x lo7 cells. Deoxyglucose incorporation ranged from 10 minutes to 90 minutes. The dishes were then placed on ice, rinsed with cold saline buffer : Tris-HCl 10s2 M pH 7.6, NaCl 0.25 M, MgC12 10-2Mand lysed with Nonidet P-40. After centrifugation for 10 minutes at 12 000 8, 200 1.11 samples of the supernatant were collected : i) some samples were directly counted in Bray scintillation mixture to account for total cell radioactivity ; ii) other samples were added with 1.8 ml ethanol. After 10 minutes at 0°C the ethanol precipitate was spun down for 20 minutes at 16 000 &. The pellet was resuspended in 0.5 ml Tris/NaCl/Mg buffer and counted in 5 ml Bray scintillation mixture to account for the radioactivity bound to proteins. 2DG and 2DG-6-P are not ethanol precipitable. Consequently the radioactivity in the precipita e corresponds to the 14C actually bound t,o protein, i.e. to the isomerasecomplex. E. 14C 3 2DG-6-P RESULTS Two cells
in
types
logarithmic
[14,]2DG
of
non-differentiated phase,
uptake.
ii)
Fig.
cultures non-dividing
1 shows
1046
cells
the
kinetics
were
employed
kept
of
in
stationary
2-deoxyglucose
: i)
growing phase.
BIOCHEMICAL
Vol. 103, No. 3,198l
AND
0
FIG. 2. Measurement ated to A---A
as measured
more rapid tions.
precipitated
kinetics
After
growing
cells versus
corresponds
t(min.)
radioactivity.
penetration,
and twice
Ethanol
as high
those
precipit-
the amount
as in confluent
from
is very
2DG-6-P
to account its
for
the
phosphorylation
cells
three
shown
on fig.
was also
found
in
cells
and its
1047
was and in
(48 000 cpm per
IO6
14 C radioactivity
isomerase-2DG-6-P
complex.
the activity
of glucose
Total
radioactivity
may be
binding formation.
2. A considerably
the CCA-treated
free
condi-
since
successive
p4 CI 2DG- 6-P complex
are
(8).
the other
in serum
times
markedly
of radioactivity
: 2DG, 2DG-6-P,
low in nervous
with
and total
may be neglected
various
expressed
obtained
in Me2S0 treated,
molecules
after
to CCA cultures
that
than
radioactivity
15 000 and 25 000 respectively),
Isomeraseprecipitation
corresponding
in CCA cells
formed
assumed
cell
of incubation,
to different
phosphatase
total
of 2DG uptake
90 minutes
higher
Products
by counting
The curve
3 times
fraction
of ethanol
loo
COMMUNICATIONS
from the 12 000 8 supernatant was measured and normalised 106 cells. CCA treated cells. o-----d serum free cultures ; He2SO treated cells ; a---Agrowing cells in logarithmic phase ; confluent cells in stationary phase.
of incubation.
then
50
RESEARCH
radioactivity
uptake,
cells
BIOPHYSICAL
cells.
metabolic
steps
i.e.
2DG
to isomerase. The results higher
uptake
The yield
of ethanol into
of ethanol
this
BIOCHEMICAL
Vol. 103, No. 3,1981
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
TABLE I. Percent of the cellular [14C]2DG recovered the isomerase-p4C]2DG-6-P complex
IO min
60 min
45.9
50.3
cells
30.2
37
cultures
18.6
37.3
27.7
40.3
36.9
44.4
CCA treated
cells
Me2SO treated Serum free Growing
cells
Confluent
as
(log.
cells
phase)
(stat.
phase)
These percentages were calculated by dividing the values from fig. 2 (c.p.m. in the ethanol precipitate from 12 000 g supernatant) by the corresponding values from fig. 1 (c.p.m. in the 12 000 4 aupernatant). See RESULTS.
precipitation
is
less
considered
as minimal
of precipitation
total
radioactivity
table
I indicate
ly higher
comparable
for
that,
shown
it
in fig.
culture
time
studied,
cells.
That
means that
independent
of the effect
the yield so that
radioactivity
populations.
at every
that
conditions,
of ethanol-precipitated cell
2 must be
may be assumed
the various
in the different
in CCA treated
the cell
Nevertheless,
the percentages
by CCA treatment, through
100 % and the values
values.
is
one may compare
than
this
versus
The results percentage
complex
is
shown in significant-
formation
is
enhanced
of CCA on the penetration
of 2DG
membrane.
DISCUSSION In this designed
by Sokoloff
various
physiological
markedly
increased
CCA-treated cell
shown)
cells
energetics.
number,
study
but were
neuronal
to evaluate
accumulation ; this
expressed
we have used
cerebral
The main
activity
result [
expressed
as a function
similar.
1048
here
here
14 C 2DG-6-P 1
may be assumed
are
the elegant
method
in response
reported
of the isomerase-
accumulation
The 14 C counts
cells,
local
conditions.
the results very
with
to
concerns complex
in the
to reflect
the level
as a function
of cell
of protein
content
the
(data
of
not
BIOCHEMICAL
Vol. 103, No. 3,198l
Many variables We have paid
specific
ii)
cell
effects
Both
attention replication,
to obtain
and CCA-treated these
agents
Measurements
were
i.e.
cells
allows
morphogenesis,
also
inducers.
induction
made in
in logarithmic
phase
and iiii) were
in altered
added
to occur
two types
culture
by
trophic
condi-
cultures.
in a 7.5 % fetal in the absence
calf
of inducers.
of non-differentiated and confluent
the
induced
to Me2 SO treated
were
growth
energetics.
trophic
Cultures
morphogenesis compared
COMMUNICATIONS
of cellular
neuronal
were
normal
levels
of i)
neuronal
cultures
RESEARCH
to the effects iii)
of neuronal
serum medium which
growing
to the
of the differentiation
serum deprivation tions,
BIOPHYSICAL
may contribute
a particular
conditions,
AND
cultures,
cells
in a stationary
phase. The level
of cell
and the accumulation P igher
cells
stationary
to promote to its
found
between
a complete
stimulation
medium.
the "confluent
These
deoxyglucose
cells"
correspond
(10,
increases
in the oxygen
in neuroblastoma deprivation measurements approach. by classical
cells
as compared may reveal Morphological agentshas
14
[
is
in confluent
level.
CCA appears
cells
Thus,
from glucose
to a different
penetr-
difference and cells
the effect
cells
3 to 4 times with
No significant
emphasize
CI 2DG uptake
of cultures,
pathway
cellular
was
growing
in
due to CCA. The
may reflect
of Walum et al. who observed
cells"
In contrast
types
serum deprived
observations
the
complex,
an intermediate
cells,
observed
uptake
other
of the metabolic
situation
phase
in all
to D-fructose-6-P.
Me2S0 treated
from
1y4CeI 2DG-6-P
reaching
isomerisation
intermediate
"stationary
than
cells
a global
ation
estimated
of the isomerase-
in CCA-treated
confluent
energetics,
the fact
state
from
a decrease
that
the
in the
11).
to our
results,
Nissen
uptake,measured that
minor
grown
changes
been
reported
to differentiate
in a complete that
differentiation also
(12)
by a micromanometric
had been induced
to cells
et al.
are not measured
induced reported
1049
medium
small
technique, by serum (13). with
These our
by serum deprivation
to be accompanied
by minor
or changes
BIOCHEMICAL
Vol. 103, No. 3,198l
at
the level
of mRNAs and proteins It
metabolism
is
significantly
is
drastically
synthesis
ation).
classical
that
membrane
effects
that
Several
that
neuroblastoma
and that
a fundamental
role
in
are not neuronal
the burst triggering
not
shown).
bound
CCA also
after usually
CCA-treated
energetics
cells
to oligomycin stimulates
the
and cytoskeleton addition screened
by CCA (manuscript
a more complete
the neuronal
in the ultra-
resistance
proteins
observed
in cell
in neuroblastoma
For example,
and their
induced
CCA promotes
changes
by modifications
markers,
are markedly
agents,
We believe
drastic
microscopy.
(data
RESEARCH COMMUNICATIONS
14, 15).
more mitochondria
serum deprivation. with
by electron
increased
(6),
(9,
to note
of some insoluble
components
BIOPHYSICAL
by CCA are accompanied
as observed
contain also
interesting
induced
structure
AND
neuronal reported
of Me2 SO or in studies in preparexpression here
in
may play
differentiation.
ACKNOWLEDGMENTS This work Fransoise Perrot for typing the manuscript.
has been supported by a grant from SANOFI. We thank her excellent technical assistance and Denise Baron
for
REFERENCES 1. Augusti-Tocco, G. and Sato, G. (1969) Proc. Natl. Acad. Sci. USA 66, 311-315. 2. Schubert, D., Humphreys, S., De Vitry, F. and Jacob, F. (1971) Develop. Biol. 25, 514-546. 3. MC Morrz, F.A., Koller, A.R., Moore, B.W. and Perumal, A.S. (1974) J. Cell Physiol. 3, 473-480. 4. Simard, J., Ferrandes, B., Lacolle, J.Y. and Eymard, P. (1978) Satellite Symposium on cerebra-vascular diseases, Reims, France. 5. Croizat, B., Berthelot, F., Ferrandes, B., Eymard, P., Sahuquillo, C. and Gros, F. (1979) Compt. Rend. Acad. SC. Paris 289 S&D, 1283-1286. 6. Portier, M.M., Eddg, B., Berthelot, F., Croizat, B. and Gros, F. (1980) Biochem. Biophys. Res. Commun. 96, 1610-1618. 7. Kennedy, C., Des Rosiers, M.H., Sakurada, O., Shinohara, M., Reivich, M., Jehle, J.W. and Sokoloff, L. (1976) Proc. Natl. Acad. Sci. USA 2, 4230-4234. 8. Sokoloff, L., Reivich, M., Kennedy, C., Des Rosiers, M.H., Patlak, C.S., Pettigrew, K.D., Sakurada, 0. and Shinohara, M. (1977) J. Neurochem. 28, 897-916. 9. Croizat, B., Berthelot, F., Felsani, A. and Gros, F. (1977) Eur. J. Biochem. 76, 405-412. 10. Edstriim, M., Kanje, M. and Walum, E. (1976) Exntl. Cell Res. 97, 6-14.
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BIOPHYSICAL
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11. Walum, E. and Edstrgm, A. (1976) Exptl. Cell Res. 97, 15-22. 12. Nissen, C., Ciesielski-Treska, J., Hertz, L. and Mandel, P. (1973) J. Neurochem. 0, 1029-1035. 13. Hertz, L. (1966) J. Neurochem. 13, 1373-1387. 14. Felsani, A., Berthelot, F., Gros, F. and Croizat, B. (1978) Eur. J.. Biochem. 92, 569-577. 15. Grouse, L.D., Schrier, B.K., Letendre, C.H., Zubairi, M.Y. and Nelson, P.G. (1980) J. Biol. Chem. -255, 3871-3877.
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