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Evidence for a new biosynthetic pathway of sphingomyelin in SV 40 transformed mouse cells
BIOCHEMICAL
Vol. 47, No. 6, 1972
EVIDENCE
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FOR A NEW BIOSYNTHETIC
PATHWAY OF SPHINGOMYELIN
IN
SV 40 TRANSFORMED MOUSE CELLS H.Diringer,
W.D.Marggraf,
Max-Planck-Institut
Received
fiir
M.A.Koch,
and F.A.Agderer
Virusforschung,
74 Tiibingen,
West-Germany.
May 8, 1972
SUMMARY
Sphingomyelin metabolism has been studied in logarithmically growing SV 40 transformed mouse fibroblasts.32P-phosphate and 3H-choline pulse chase experiments indicate that sphingomyelin is synthesized by an immediate transfer of phosphorylcholine from lecithin to sphingosine or N-acylsphingosine.
The biosynthesis
of the
two choline
containing
phospholipids,
have been reported
to be reactions
of
lecithin
and sphingomyelin,
cytidine
diphosphate
glyceride
and with
this
has been proved to be an important mechanism in 1 cells whereas in the case of sphingomyelin there is
activated
choline
N-acylsphingosine
(CDP-choline) respectively.
with For
diacyl
lecithin
pathway
mammalian only
weak evidence
Kennedy' which
such a reaction
investigated
was able
CDP-choline. all
for
an enzyme
to catalyze They obtained
naturally
occuring
An alternate
pathway
the
mechanism.
system
prepared
reaction
has been
threo exist
reported
system
where
sphingosylphosphorylcholine
and yielded
both
forms
of sphingomyelin.
this
communication
of
sphingomyelin
@ 1972. by Academic
liver
in
was acylated
that
the
biosynthesis
a route
different
of
those
reported
Press, Inc.
although
3,4 . erythro-form et al. 5 studying
evidence
follows
and
the
we present
1345 Copyright
rat
sphingomyelin
by Brady
an enzyme
In
from
and
of N-acylsphingosine
exclusively
sphingolipids
Scribney
when
BIOCHEMICAL
Vol. 47, No. 6, 1972
investigated likely
in
the
sine
logarithmically
transfer
growing
mammalian
of phosphorylcholine
or N-acylsphingosine
biosynthesis
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
is
in this
the
main,
cells.
from
lecithin
possibly
the
Most to sphingo-
only
way of
system.
For our
experiments we used a line of SV 40 transformed . which can be grown in suspension (STU 51A-232B)
cells
maintained
in
fresh
medium.
under
the
the
conditions
composition
the
used.
according
by appropriate
time
of this
of
Neither
lipid
the
unpublished
cells
the
phospholipid
with
was about
as determined
we performed
12 hours
content by the
is dependent
range
and can be
dilution
the
class
to Bartlett'
within
culture
(Diringer
growth
The doubling
rus content of
logarithmic
mouse
on the our
nor phospho-
cell
density
experiments
observations).
experiments with 32 P-phosphate showed that incorporation rate of 32 P into sphingomyelin was significantly retarded when compared to the 32 P incorporation into lecithin. Preliminary
These
pulse
findings
two lipids from
the
indicated either different turnover rates of these 32 or a P precursor of sphingomyelin which is different
CDP-choline.
turned
To decide
to pulse
between these two alternatives with 32 P-phosphate and tritiated
experiments
we
choline
tJH-methyl) following the kinetics during incorporation and chase. The 32 P chase was performed by a replacement of the phosphate to prevent
buffered
medium.
a possible
The chase
interference
of
with
'H-choline the
was omitted
logarithmic
growth
conditions. Cells
were grown
500 ml of growth calf
serum
in
and 1 mCi of about
in suspension medium
the
5% CO2 in
containing
presence
3H-choline air
with
starting
of
4.5
10% of heat
5 mCi of carrier
(17 Ci/m rapid
with
mol) stirring
1346
under
x lo*
cells
in
inactivated fetal 32 free P-phosphate
an atmosphere
in a 1 1 flask.
of After
Vol. 47, No. 6, 1972
12 hours
cells
4.0
Logarithmic
growth
hemocytometer
were
taken.
cellular
This
cell
in
and sphingomyelin
visualized
was removed
by centrifugation
was counted
in
counting
in
25 ml aliquots
to Folch
and the al. 7 .
et
by two dimensional
which
allows
the
(to be published).
Bartlett6.
of
thin-
clear
separation
The spots
individual
the
containing
were
lipids
data
radioactivity
bound
are plotted
logarithmically
according
given
in
this
to cellular
sphingomyelin calculated on the basis of diluted 32 P and 3H counts of lecithin and sphingomyelin experiment
versus
material
The phos-
was determined
radioactivity
Bray's
supernatant
Tri-Carb-Scintillation-Counter.
The absolute represent
lipid
a
between
by centrifugation
and the
a Packard
content
cation
dilution.
intervals
time
concentration
by autoradiography, scrapped off and eluted with 8 mixture containing 10% of water. The carrier
scintillation
phorus
a cell
was kept
separated
a system
give
by cell
according
were
250 ml of warm
to a 3 fold
concentration
were extracted
chromatography
to
was controlled
were harvested
phospholipids
of lecithin
meilium
At given
The cells
Individual
washed with
corresponds
of cells
cells/ml.
lipids
layer
in growth
and the
- 2.0 x lo6
0.4
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
were centrifuged,
and resuspended x lo 5 cells/ml.
medium
of
the
BIOCHEMICAL
to
communi-
lecithin
and
aliquots. of a typical time
(Figure
l).It
can be seen that after a period of rapid incorporation the curves of the 32 P as well as of the 3H uptake run about paralell to one another
in
each
lipid
activity
must
however,
the
those
sphingomyelin
labels in This
of
of
be incorporated incorporation
lecithin
sphingomyelin becomes
indicating
more
curves it
clear
of lecithin
becomes
steadily both
that in both cases the radioas 32 P-phosphoryl-3 H-choline. When,
labels
evident
decrease appear
when the
shortly
after
to increase
absolute 1347
are compared with that the 32 P and 3H the
chase
further.
radioactivities
are
while
Vol. 47, No. 6,1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I
.’
.’
m-.-m,. **-*d.\
;p
.
1 105
I II
/
I/
.
-.---I
--•-*-
/ :
-2.-m-.
.’
.I
A
,106
‘/ I
i
-0-d
.-t Z 5 K E ,o
q // 0 I
I
I
Chase
1 36
I
4
8
12
16
hours
Figure
of
in
lecithin
labels that
a linear
lecithin
after
of cell
24
26
32
lrol -t
growth
Semilogarithmic plot of incorporation of 32 P-phosphate (circles) and 3H-choline (squares) into lecithin (e,m ) and sphingomyelin (0 ,0 ) during logarithmic growth of STU 51A-232B mouse cells. Pulse period: O-12 hours.
1
plotted
20
versus
and sphingomyelin is
the
reached
chase.
(see Figure lecithin
phorylcholine
scale
3 hours
precursor
true
From this
and sphingomyelin pools.
Figure
2a the
are compared. The maximum and that of 32 P-sphingomyelin
The same holds 2b).
In
time.
the
for
observation must
have
When the
1348
maxima
it different
prolonged
32 P labels 32p,
of
20 hours
of the
3H
can be concluded immediate
phos-
incorporation
of
BIOCHEMICAL
Vol. 47, No. 6, 1972
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
a)
1I
1.5106 10 12
16
20
hours
Figure
24
26
32
cd cell growth
reaction
into of
sphingomyelin
phosphorylcholine
as discussed
by Kennedy'
one would
slope
radioactivity
curves
of the
radioactivity
obviously
not
the
Compartementation unlikely,
under
given
the pool
of
2.4
26
of cell
32
growth
CDP-choline since
growth
expect
36
-
result
begins
from
into
a distinct
of the
at that
to decrease.
the
lecithin
change
of sphingomyelin
time
This
the
is
pool
of sphingomyelin
two cell
cycles.
Such a big
phosphoryl-3H-choline
in the
as common precursor doubling
conditions
of lecithin
throughout
would
incorporation
lecithin
precursor
myelin
20
is
case. of
be rather
cursor
16
hours
32 P-phosphoryl-3H-choline
when the
12
Linear plot of (a) incorporation of 32 P-phosphate into lecjthin (0) and sphingomyelin (01 and (b) incorporation of H-choline into lecithin (m) and sphingomyelin (0) during logarithmic growth of STU 51A-232B mouse cells. Pulse period: O-12 hours.
2
reversed
10
36
-
time
was about
exhausted
precursor
experiment
lo fold is 1349
enough pool
to
cells
The pre-
3 hours
whereas
to
for
which
higher
lecithin.
mouse
12 hours.
within
is big
about
of the
appears
last
nearly 3zp,
contains
amounts Therefore
the
than
sphingo-
a transfer
Vol. 47, No. 6, 1972
Table
1
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
32 P-phosphate of 3H-choline to lecithin and sphingomyelin of STU 51A-232B mouse cells.
Ratios of absolute counts incorporated into cellular during logarithmic growth Pulse period: O-12 hours.
Quotient of of 3H/32 P-ratios Lecithin /Sphingomyelin
3 H/ 32 P-ratios of Lecithin Sphingomyelin
hours of cell growth
7.00 8.50 10.00 11.00 11.75 13.00 14.00 17.00 23.50 27.00
75.3 72.9 68.9 67.8 65.5 63.7 59.5 56.5 54.6 57.0
of phosphorylcholine
80.4 76.0 73.3 73.3 71.1 69.3 64.7 62.9 59.2 58.6
from
0.94 0.96 0.94 0.92 0.92 0.92 0.92 0.90 0.92 0.97
lecithin
to the
free
sphingosine can be suggested. To prove this 3 H/ 32 P ratios of lecithin and of sphingomyelin in table
1 for
various
times.
to 32 P-phosphate
at any time
Identical
two lipids
in
about
constant.
shortly
after
the
constant
the
Since the
the
chase
quotient
of
interpreted only in terms 32 P-phosphoryl-3H-choline %hen
lecithin
specific Zilversmit relationships:
is
the
between and the
while the
pools
which
listed
both
quotient
are nearly
of the in
precursor
of
lipids
must
1350
of 'HTcholine
7 and 27 hours
predicted activity
ratios
lecithin
were increasing lipids
are
for
the
can be long
living
unknown.
sphingomyelin obey
is
were decreasing
Other
such as lecithin
specific
are
ratios
cooperation.
have been the
the
those in sphingomyelin 3 H/ 32 P ratios of both
of direct
of
we calculated
the
radioactivities
immediate
radioactivities et al. 9 which at first
As expected
or N-acylated
the criteria
of
precursor-product
of the
precursor
will
Vol. 47, No. 6, 1972
be greater the
than
product.
precursor
of the
The point
activity
criteria
state
that
and product
specific the
BIOCHEMICAL
lecithin
cross
of Zilversmit In
Figure
the
limits
myelin
result
precursor myelin)
before
that
lecithin
is
one.
The participation
same moment
versus
error
in
from
a precursor
the
that curves
for
which
the
method
of Bartlett6
in Figure
cross
growth.
3, i.e.
of both the al. 9 . An
when the
the
its
than
et
product curve (sphingolo,11 maximum , would mean but
one immediate
not
the
immediate
precursor
would
b) /‘\* I/
hairs
Figure
3
\1
of16cell
&owOf-
Plots of specific radioactivities of 32 P-phosphate (a), and 3H-choline (b) incorporated into lecithin (I) and into sphingomyelin (0). Deviations indicate the absolute error. 1351
of of
the
case of sphingo-
determination
of sphingomyelin
of more
of cell
of Zilversmit
plots
attains
time
chemical
criteria
will
product
which
by the
of the
(lecithin) the
be the
than
activity/time
were plotted
predominantly
curve
specific
less
is a maximum. According to Reiner et al. 9 are not restricted to steady 32 3 the specific P and 3H activities of
of absolute
interpretation
the
will
small amounts of phospholipids 32 P and the 3H plots obey the extreme
subsequently
product
and sphingomyelin
Within
product,
at which
of the
systems.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
lo
BIOCHEMICAL
Vol. 47, No. 6, 1972
not
the criteria by Reiner lo . It
fit
is
cells
evident, is
of
sine.
The biosynthetic
other
investigators
biosynthesis ments
that
sphingomyelin
by a sofar
of phosphorylcholine
from
might
the
growing
immediate
to sphingosine of
sphingomyelin
in the enzyme
in
observed
contribute
of sphingomyelin
to demonstrate
not
lecithin
pathways 2,5
et al. 9 as has been emphasized
Zilversmit
therefore,
synthesized
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
activity
only cell
transfer
or N-acylsphingoas discussed
to a minor
system in
mammalian
a cell
part
to the
used by us.
Experi-
extract
progress. REFERENCES 1. 2. 3. 2 4: 8. 9. lo. 11.
Kennedy, E.P., Fed&ration Proc., 16, 847 (1957). Scribney, M., and Kennedy, E.P., J.Biol.Chem., 233, 1315 (1958). Carter, H.E., Fujino Y., J.Biol.Chem., 221, 879 (1956). Groom, V., Scribney, M., J.Lipid Res., 6, 220 (1965). Brady, P.O., Bradley, R.M., Young, O.M., Kaller,H., J.Biol.Chem., 240, PC 3693 (1965). Bartlett, G.R., J.Biol.Chem., 234, 466 (1959). Folch, J., Lees, M., Sloane Stanley, G.H., J.Biol.Chem., 226,497 (1957). Bray, G.A., Anal.Biochem.,l, 279 (1960). Zilversmit, D.B., Entenman, C., and Fishler, M.C., J.Gen.Physiol., 26, 325 (1943) . Reiner, J.M., Arch.Biochem.Biophys., 46, 53 (1953). Radin, N.S., Nucleonics, I, 51 (1947).
1352
by
are
in
Vol. 47, No. 6, 1972
EVIDENCE
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FOR A NEW BIOSYNTHETIC
PATHWAY OF SPHINGOMYELIN
IN
SV 40 TRANSFORMED MOUSE CELLS H.Diringer,
W.D.Marggraf,
Max-Planck-Institut
Received
fiir
M.A.Koch,
and F.A.Agderer
Virusforschung,
74 Tiibingen,
West-Germany.
May 8, 1972
SUMMARY
Sphingomyelin metabolism has been studied in logarithmically growing SV 40 transformed mouse fibroblasts.32P-phosphate and 3H-choline pulse chase experiments indicate that sphingomyelin is synthesized by an immediate transfer of phosphorylcholine from lecithin to sphingosine or N-acylsphingosine.
The biosynthesis
of the
two choline
containing
phospholipids,
have been reported
to be reactions
of
lecithin
and sphingomyelin,
cytidine
diphosphate
glyceride
and with
this
has been proved to be an important mechanism in 1 cells whereas in the case of sphingomyelin there is
activated
choline
N-acylsphingosine
(CDP-choline) respectively.
with For
diacyl
lecithin
pathway
mammalian only
weak evidence
Kennedy' which
such a reaction
investigated
was able
CDP-choline. all
for
an enzyme
to catalyze They obtained
naturally
occuring
An alternate
pathway
the
mechanism.
system
prepared
reaction
has been
threo exist
reported
system
where
sphingosylphosphorylcholine
and yielded
both
forms
of sphingomyelin.
this
communication
of
sphingomyelin
@ 1972. by Academic
liver
in
was acylated
that
the
biosynthesis
a route
different
of
those
reported
Press, Inc.
although
3,4 . erythro-form et al. 5 studying
evidence
follows
and
the
we present
1345 Copyright
rat
sphingomyelin
by Brady
an enzyme
In
from
and
of N-acylsphingosine
exclusively
sphingolipids
Scribney
when
BIOCHEMICAL
Vol. 47, No. 6, 1972
investigated likely
in
the
sine
logarithmically
transfer
growing
mammalian
of phosphorylcholine
or N-acylsphingosine
biosynthesis
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
is
in this
the
main,
cells.
from
lecithin
possibly
the
Most to sphingo-
only
way of
system.
For our
experiments we used a line of SV 40 transformed . which can be grown in suspension (STU 51A-232B)
cells
maintained
in
fresh
medium.
under
the
the
conditions
composition
the
used.
according
by appropriate
time
of this
of
Neither
lipid
the
unpublished
cells
the
phospholipid
with
was about
as determined
we performed
12 hours
content by the
is dependent
range
and can be
dilution
the
class
to Bartlett'
within
culture
(Diringer
growth
The doubling
rus content of
logarithmic
mouse
on the our
nor phospho-
cell
density
experiments
observations).
experiments with 32 P-phosphate showed that incorporation rate of 32 P into sphingomyelin was significantly retarded when compared to the 32 P incorporation into lecithin. Preliminary
These
pulse
findings
two lipids from
the
indicated either different turnover rates of these 32 or a P precursor of sphingomyelin which is different
CDP-choline.
turned
To decide
to pulse
between these two alternatives with 32 P-phosphate and tritiated
experiments
we
choline
tJH-methyl) following the kinetics during incorporation and chase. The 32 P chase was performed by a replacement of the phosphate to prevent
buffered
medium.
a possible
The chase
interference
of
with
'H-choline the
was omitted
logarithmic
growth
conditions. Cells
were grown
500 ml of growth calf
serum
in
and 1 mCi of about
in suspension medium
the
5% CO2 in
containing
presence
3H-choline air
with
starting
of
4.5
10% of heat
5 mCi of carrier
(17 Ci/m rapid
with
mol) stirring
1346
under
x lo*
cells
in
inactivated fetal 32 free P-phosphate
an atmosphere
in a 1 1 flask.
of After
Vol. 47, No. 6, 1972
12 hours
cells
4.0
Logarithmic
growth
hemocytometer
were
taken.
cellular
This
cell
in
and sphingomyelin
visualized
was removed
by centrifugation
was counted
in
counting
in
25 ml aliquots
to Folch
and the al. 7 .
et
by two dimensional
which
allows
the
(to be published).
Bartlett6.
of
thin-
clear
separation
The spots
individual
the
containing
were
lipids
data
radioactivity
bound
are plotted
logarithmically
according
given
in
this
to cellular
sphingomyelin calculated on the basis of diluted 32 P and 3H counts of lecithin and sphingomyelin experiment
versus
material
The phos-
was determined
radioactivity
Bray's
supernatant
Tri-Carb-Scintillation-Counter.
The absolute represent
lipid
a
between
by centrifugation
and the
a Packard
content
cation
dilution.
intervals
time
concentration
by autoradiography, scrapped off and eluted with 8 mixture containing 10% of water. The carrier
scintillation
phorus
a cell
was kept
separated
a system
give
by cell
according
were
250 ml of warm
to a 3 fold
concentration
were extracted
chromatography
to
was controlled
were harvested
phospholipids
of lecithin
meilium
At given
The cells
Individual
washed with
corresponds
of cells
cells/ml.
lipids
layer
in growth
and the
- 2.0 x lo6
0.4
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
were centrifuged,
and resuspended x lo 5 cells/ml.
medium
of
the
BIOCHEMICAL
to
communi-
lecithin
and
aliquots. of a typical time
(Figure
l).It
can be seen that after a period of rapid incorporation the curves of the 32 P as well as of the 3H uptake run about paralell to one another
in
each
lipid
activity
must
however,
the
those
sphingomyelin
labels in This
of
of
be incorporated incorporation
lecithin
sphingomyelin becomes
indicating
more
curves it
clear
of lecithin
becomes
steadily both
that in both cases the radioas 32 P-phosphoryl-3 H-choline. When,
labels
evident
decrease appear
when the
shortly
after
to increase
absolute 1347
are compared with that the 32 P and 3H the
chase
further.
radioactivities
are
while
Vol. 47, No. 6,1972
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
I
.’
.’
m-.-m,. **-*d.\
;p
.
1 105
I II
/
I/
.
-.---I
--•-*-
/ :
-2.-m-.
.’
.I
A
,106
‘/ I
i
-0-d
.-t Z 5 K E ,o
q // 0 I
I
I
Chase
1 36
I
4
8
12
16
hours
Figure
of
in
lecithin
labels that
a linear
lecithin
after
of cell
24
26
32
lrol -t
growth
Semilogarithmic plot of incorporation of 32 P-phosphate (circles) and 3H-choline (squares) into lecithin (e,m ) and sphingomyelin (0 ,0 ) during logarithmic growth of STU 51A-232B mouse cells. Pulse period: O-12 hours.
1
plotted
20
versus
and sphingomyelin is
the
reached
chase.
(see Figure lecithin
phorylcholine
scale
3 hours
precursor
true
From this
and sphingomyelin pools.
Figure
2a the
are compared. The maximum and that of 32 P-sphingomyelin
The same holds 2b).
In
time.
the
for
observation must
have
When the
1348
maxima
it different
prolonged
32 P labels 32p,
of
20 hours
of the
3H
can be concluded immediate
phos-
incorporation
of
BIOCHEMICAL
Vol. 47, No. 6, 1972
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
a)
1I
1.5106 10 12
16
20
hours
Figure
24
26
32
cd cell growth
reaction
into of
sphingomyelin
phosphorylcholine
as discussed
by Kennedy'
one would
slope
radioactivity
curves
of the
radioactivity
obviously
not
the
Compartementation unlikely,
under
given
the pool
of
2.4
26
of cell
32
growth
CDP-choline since
growth
expect
36
-
result
begins
from
into
a distinct
of the
at that
to decrease.
the
lecithin
change
of sphingomyelin
time
This
the
is
pool
of sphingomyelin
two cell
cycles.
Such a big
phosphoryl-3H-choline
in the
as common precursor doubling
conditions
of lecithin
throughout
would
incorporation
lecithin
precursor
myelin
20
is
case. of
be rather
cursor
16
hours
32 P-phosphoryl-3H-choline
when the
12
Linear plot of (a) incorporation of 32 P-phosphate into lecjthin (0) and sphingomyelin (01 and (b) incorporation of H-choline into lecithin (m) and sphingomyelin (0) during logarithmic growth of STU 51A-232B mouse cells. Pulse period: O-12 hours.
2
reversed
10
36
-
time
was about
exhausted
precursor
experiment
lo fold is 1349
enough pool
to
cells
The pre-
3 hours
whereas
to
for
which
higher
lecithin.
mouse
12 hours.
within
is big
about
of the
appears
last
nearly 3zp,
contains
amounts Therefore
the
than
sphingo-
a transfer
Vol. 47, No. 6, 1972
Table
1
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
32 P-phosphate of 3H-choline to lecithin and sphingomyelin of STU 51A-232B mouse cells.
Ratios of absolute counts incorporated into cellular during logarithmic growth Pulse period: O-12 hours.
Quotient of of 3H/32 P-ratios Lecithin /Sphingomyelin
3 H/ 32 P-ratios of Lecithin Sphingomyelin
hours of cell growth
7.00 8.50 10.00 11.00 11.75 13.00 14.00 17.00 23.50 27.00
75.3 72.9 68.9 67.8 65.5 63.7 59.5 56.5 54.6 57.0
of phosphorylcholine
80.4 76.0 73.3 73.3 71.1 69.3 64.7 62.9 59.2 58.6
from
0.94 0.96 0.94 0.92 0.92 0.92 0.92 0.90 0.92 0.97
lecithin
to the
free
sphingosine can be suggested. To prove this 3 H/ 32 P ratios of lecithin and of sphingomyelin in table
1 for
various
times.
to 32 P-phosphate
at any time
Identical
two lipids
in
about
constant.
shortly
after
the
constant
the
Since the
the
chase
quotient
of
interpreted only in terms 32 P-phosphoryl-3H-choline %hen
lecithin
specific Zilversmit relationships:
is
the
between and the
while the
pools
which
listed
both
quotient
are nearly
of the in
precursor
of
lipids
must
1350
of 'HTcholine
7 and 27 hours
predicted activity
ratios
lecithin
were increasing lipids
are
for
the
can be long
living
unknown.
sphingomyelin obey
is
were decreasing
Other
such as lecithin
specific
are
ratios
cooperation.
have been the
the
those in sphingomyelin 3 H/ 32 P ratios of both
of direct
of
we calculated
the
radioactivities
immediate
radioactivities et al. 9 which at first
As expected
or N-acylated
the criteria
of
precursor-product
of the
precursor
will
Vol. 47, No. 6, 1972
be greater the
than
product.
precursor
of the
The point
activity
criteria
state
that
and product
specific the
BIOCHEMICAL
lecithin
cross
of Zilversmit In
Figure
the
limits
myelin
result
precursor myelin)
before
that
lecithin
is
one.
The participation
same moment
versus
error
in
from
a precursor
the
that curves
for
which
the
method
of Bartlett6
in Figure
cross
growth.
3, i.e.
of both the al. 9 . An
when the
the
its
than
et
product curve (sphingolo,11 maximum , would mean but
one immediate
not
the
immediate
precursor
would
b) /‘\* I/
hairs
Figure
3
\1
of16cell
&owOf-
Plots of specific radioactivities of 32 P-phosphate (a), and 3H-choline (b) incorporated into lecithin (I) and into sphingomyelin (0). Deviations indicate the absolute error. 1351
of of
the
case of sphingo-
determination
of sphingomyelin
of more
of cell
of Zilversmit
plots
attains
time
chemical
criteria
will
product
which
by the
of the
(lecithin) the
be the
than
activity/time
were plotted
predominantly
curve
specific
less
is a maximum. According to Reiner et al. 9 are not restricted to steady 32 3 the specific P and 3H activities of
of absolute
interpretation
the
will
small amounts of phospholipids 32 P and the 3H plots obey the extreme
subsequently
product
and sphingomyelin
Within
product,
at which
of the
systems.
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
lo
BIOCHEMICAL
Vol. 47, No. 6, 1972
not
the criteria by Reiner lo . It
fit
is
cells
evident, is
of
sine.
The biosynthetic
other
investigators
biosynthesis ments
that
sphingomyelin
by a sofar
of phosphorylcholine
from
might
the
growing
immediate
to sphingosine of
sphingomyelin
in the enzyme
in
observed
contribute
of sphingomyelin
to demonstrate
not
lecithin
pathways 2,5
et al. 9 as has been emphasized
Zilversmit
therefore,
synthesized
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
activity
only cell
transfer
or N-acylsphingoas discussed
to a minor
system in
mammalian
a cell
part
to the
used by us.
Experi-
extract
progress. REFERENCES 1. 2. 3. 2 4: 8. 9. lo. 11.
Kennedy, E.P., Fed&ration Proc., 16, 847 (1957). Scribney, M., and Kennedy, E.P., J.Biol.Chem., 233, 1315 (1958). Carter, H.E., Fujino Y., J.Biol.Chem., 221, 879 (1956). Groom, V., Scribney, M., J.Lipid Res., 6, 220 (1965). Brady, P.O., Bradley, R.M., Young, O.M., Kaller,H., J.Biol.Chem., 240, PC 3693 (1965). Bartlett, G.R., J.Biol.Chem., 234, 466 (1959). Folch, J., Lees, M., Sloane Stanley, G.H., J.Biol.Chem., 226,497 (1957). Bray, G.A., Anal.Biochem.,l, 279 (1960). Zilversmit, D.B., Entenman, C., and Fishler, M.C., J.Gen.Physiol., 26, 325 (1943) . Reiner, J.M., Arch.Biochem.Biophys., 46, 53 (1953). Radin, N.S., Nucleonics, I, 51 (1947).
1352
by
are
in