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Conversion of diglyceride to triglyceride by rat liver microsomes: A requirement for the 105,000 × g supernatant
BIOCHEMICAL
Vol. 58, No. 1, 1974
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
CONVERSION OF DIGLYCERIDETO TRIGLYCERIDEBY RAT LIVER MICROSOMES: A REQUIREMENT FOR THE 105,000 x g SUPERNATANTl Eric R. Manley2, Harold B. Skrdlant,
Elizabeth
Hansbury and Terence J. Scallen3
Departments of Chemistry and Biochemistry University of New Mexico Albuquerque, New Mexico 87131 Received
March
21,1974
This paper describes a requirement for the 105,000 x g supernatant of rat liver for the synthesis of triglyceride from diglyceride and palmityl coenzyme A by rat liver microsomes. ATP and magnesium chloride are also required. The incorporation of both ]l-14C]-palmityl coenzyme A and [l-l%]diolein into triglyceride has been observed. The 105,000 x g supernatant has no enzymatic activity for this reaction when incubated in the absence of microsomes. The supernatant contains a soluble, essential protein which is nondialyzable, heat sensitive, and destroyed by trypsin. Net synthesis of triglyceride has been demonstrated by chemical analysis. SUMMARY:
Work in this eral
substrate
rat liver,
laboratory
specific
over the last
proteins,
as having essential These soluble
present roles
in the microsomal biosynthesis
(l-5).
proteins
sterols
by the microsomal membranes, and it
operate
as carriers
are required
for water insoluble lipid
have chosen to study is the acylation
years has implicated
sev-
in the 105,000 x g supernatant4
sterols
phenomena might occur in other
several
substrates.
biosynthetic
of
for the synthesis
has been proposed that
of diglyceride
of
they
We reasoned that pathways.
of
similar
The reaction
we
to form triglyceride.
MATERIALSAND METHODS Chemicals:
[1-14C]-Diolein
CoA from New England Nuclear; from Sigma; Silicar
Science Laboratories;
tories,
London, Ontario.
3. 4. Copyright All rights
palmityl-CoA,
CC-7 Special
Applied
1. 2.
was obtained
from Dhom; [1-14C]-palmityltrypsin,
from Mallinckrodt;
and 1,2-diolein
and trypsin 1,2-dipalmitin
inhibitor from
from Serdary Research Labora-
This research was supported by NIH Grant AM 10,628-08. This work is part of a thesis being presented to the University of New Mexico in partial fulfillment of the requirements for the degree of Doctor of Philosophy. Reprint requests should be addressed to T.J. Scallen, Department of Biochemistry, School of Medicine, University of New Mexico, Albuquerque, New Mexico 87131. Abbreviation used: Slo5, 105,000 x g supernatant. 0 1974 by Academic Press, of reproduction in any form
Inc. reserved.
229
Vol. 58, No. 1, 1974
BIOCHEMICAL
AND BIOPHYSICAL
SlO5 and Microsome Preparation: 300 g) were sacrificed
by decapitation.
washed in ice cold potassium (0.1 mM).
The livers
cold buffer
were blotted
After
any residual
was removed with a pipet. fer,
fitting
This washing procedure
were carried
37' under an atmosphere of nitrogen phosphate
buffer
dioxane-propylene
5-10 ~1 of sodium acetate Extractions: form-methanol
a brief
buffer
Incubations
(7.5 ml).
were added as described After
fraction
was repeated
at
twice more.
in liquid
nitrogen,
loss of activity. shaker at
volume of 2 ml of potassium EDTA (0.1 mM).
Diglyceride
Palmityl-CoA
were stopped by the addition chloroform
was
was added in
The residue by silicic
of 1:2 chloro-
(2.5 ml) and water
procedure
the chloroform
was isolated
SlO5)
in fresh buf-
out in a Dubnoff
glycol.
in the extraction
centrifugation
(constituting
(0.1 M, pH 6.0).
Subsequently
under a stream of nitrogen. glyceride
in a final
(0.02 M, pH 7.4) containing
added in S-10 ~1 of 2:l
removed from the
and recentrifuged
separately
at -80' without
incubations
was centrifuged
was resuspended
Teflon pestle,
and they can be stored indefinitely All
The homo-
was discarded,
was carefully
pellet
washed microsomes were frozen
Incubations:
the pellet
were
at 105,000 x g for 60 minutes to remove
The microsomal
105,000 x g for 60 minutes. SlO5 and triply
Teflon pestle.
The clear middle fraction
homogenized with a tight
EDTA
at 20,000 x g for 15 minutes.
The supernatant
microsomes.
and
the livers
and the 20,000 x g supernatant
and recentrifuged
light
mincing with scissors,
was then centrifuged
at 105,000 x g for 60 minutes.
excised
(0.02 M, pH 7.4) containing
(1 mm clearance)
was discarded,
pellet
were immediately
at 1000 x g for 10 minutes,
and the 1000 x g supernatant
microsomal
Livers
(200-
dry, weighed and suspended in 2 ml of fresh
homogenized with a loose fitting genate was centrifuged
male Sprague-Dawley rats
phosphate buffer
per gram of tissue.
Again the pellet
Adult
RESEARCH COMMUNICATIONS
layer
(2.5 ml)
of Bligh and Dyer (6). was removed and dried
was taken up in toluene; acid chromatography
the tri-
as described
below. Chromatography: CC-7 Special)
Separations
columns (1 x 5 cm).
were carried
out on silicic
Toluene was the eluting 230
acid (Silicar solvent,
and 7 ml
Vol. 58, No. 1, 1974
fractions
were
column
in Fraction
Fatty
acids
unless
the
fatty
acids
BIOCHEMICAL
collected.
was changed
3375 liquid
ester
ether-toluene
6.
fractions
in which
measurements
In the
the
case
in one fraction.
counter.
of Esters:
from
2 through
in much later
together
scintillation
removed
in Fractions
radioactivity
was determined
and Alonzo
diethyl
RESEARCH COMMUNICATIONS
completely
separately
eluted
All
Determination
triglyceride Rapport
were
were
eluted
eluted
to 1:9
Counting:
Chemical
were
were
and diglycerides
Model
esters
Triglycerides
and diglycerides
Scintillation a Packard
Cholesterol
1.
solvent
AND BIOPHYSICAL
were
Counting
net
quantitatively
synthesis by the
performed
with
efficiency
was 82%.
experiment
(Table
hydroxamate
method
of
(7). RESULTS
As shown
in Table
CoA and diolein, triglyceride
only fraction
chloride
were
label
1 when microsomes
(21.4%)
added
incorporation
of
(Flask
1).
when SlO5,
the
S105 or ATP from
fall
to low
incubation
levels
detected
when SlO5 was incubated preparations
one preparation
another,
the
aration
dialysis
chloride.
added ATP nor
ATP and magnesium
of SlO5
After
simply full
We presume
Il-14C]-diolein
2 shows the into
that
5). absence
SlO5 have
given
chloride results triglyceride
observation
incorporation
to
of magnesium activity
was
results.
required,
and with
against
In any
was required.
can be induced
by addition is
Omission
different
chloride
16 hours
6).
omission
was not
can be restored this
(Flask
of
of microsomes.
requirements for
incorporation
slightly
chloride
in the
ATP and magnesium
No enzymatic
added magnesium
by dialysis
[l-14C]-palmitylwas observed
caused
while
in the
chloride
activity
of ATP and magnesium Table
of
(3.9%)
was seen mixture
(Flask
added magnesium
neither
event,
effect
with
substantial
2, 3 and 4),
produced
With
mixture,
incubation
(Flasks
a lesser
label
fraction
the
chloride
Different
However,
triglyceride
of either back
incubated
slight
to the
into
were
in any prep-
20 volumes
of buffer.
of ATP and magnesium
due to variable
endogenous
levels
in S105. of an experiment was monitored.
231
in which Again
the
incorporation
SlO5 was required
of for
4)
BIOCHEMICAL
Vol. 58, No. 1, 1974
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
TABLE 1 INCORPORATION OF 11-14C]-PALMITYL-CoA INTO TRIGLYCERIDEBY LIVER MICROSDMES: REQUIREMENTFOR S105, ATP AND MAGNESIUMCHLORIDE Incorporation of ]1-14C]-palmityl-CoA into triglyceride Flask
Additions
-%
nmoles
none
3.9
0.066
ATP + M&l2
4.6
0.078
S105
2.2
0.037
slos + MS12
1.9
0.032
S105 + ATP
10.7
0.182
S105 + ATP + MgC12
21.4
0.364
All lasks contained microsomes (1.9 mg protein), diolein (8.1 nmolesj and [l- 15Cl-palmityl-CoA (1.7 nmoles, 0.1 PCi) in a final volume of 2 ml of buffer. Flasks 2, 4 and 6 contained magnesium chloride (4 mM). Flasks 2, 5 and 6 contained ATP (4 mM). Flasks 3-6 contained S105 (17 mg protein).
TABLE 2 CONVERSIONOF Ii-14C]-DIOLEIN
TO TRIGLYCERIDE
Incorporation into Flask
of [1-14C]-diolein triglyceride
%
Additions
nmoles
1
none
1.0
0.010
2
palmityl-CoA
6.7
0.067
3
S105
25.9
0.259
4
SlO5 + palmityl-CoA
25.4
0.254
All flasks contained microsomes (1.9 mg protein), ATP and magnesium chloride (1 nmole, 0.1 I.&X) in a final volume of 2 ml of (4 mw, and [l-14C]-diolein buffer. Flasks 3 and 4 contained SlO5 (17 mg protein). Flasks 2 and 4 contained palmityl-CoA (10 nmoles).
triglyceride chloride again,
synthesis by this
by microsomes.
The requirement
system was the same as shown previously
when incubated
in the absence of microsomes,
matic activity. 232
for ATP and magnesium in Table 1.
S105 exhibited
Once
no enzy-
Vol. 58, No. 1, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
TABLE 3 TRYPSIN TREA'IMENTOF LIVER S105 Incorporation of [l-14C]-palmityl-CoA into triglyceride Additions
Flask 1
-%
nmoles
none
3.9
0.066
5105
26.3
0.447
Slo5 + trypsin
inhibitor
11.3
0.192
Slo5 + trypsin inhibitor
+ trypsin
1.5
0.025
All incubations and preincubations were carried out at 37' under nitrogen. Flask 1 received no preincubation. The Slo5 in Flask 2 was preincubated alone for 60 min. The SlO5 in Flask 3 was preincubated alone for 30 min at which time trypsin inhibitor (5 mg) was added and the preincubation was continued for an additional 30 min. In Flask 4 SlOs and trypsin (5 mg) were preincubated together for 30 min at which time trypsin inhibitor (5 mg) was added and the preincubation was continued for an additional 30 min. At the end of the preincubation period, microsomes (1.9 mg protein), ATP and magnesium chloride (4 mM), dipalmitin (7 nmoles), and [l-14C]-palmityl-CoA (1.7 nmoles, 0.1 i&i) were added to all flasks. The final incubation volume for all flasks was 2 ml. All flasks were then incubated for 60 min.
TABLE 4 NET SYNTHESISOF TRIGLYCERIDEFROM[1-14C]-PAWTYL-C~A Triglyceride
Triglyceride Incubation
nmoles
nmoles -
AND DIOLEIN
[1-14C]-palmityl-CoA incorporated
synthesized -%
-nmoles
-%
1
569
---
---
---
---
2
791
222
34.4
191
29.6
Each incubation consisted of five identical flasks. All flasks contained microsomes (1.9 mg protein), SlO5 (17 mg protein), and ATP and magnesium chloride (4 mM) in a final volume of 2 ml of buffer. Incubation 1 contained no added substrate. Incubation 2 contained a total of 645 nmoles of [1-14C]palmityl-CoA (0.645 Ki) and 405 nmoles of diolein. Evidence for the protein ble for the activation heat and trypsin 5 minutes,
of microsomal
treatments.
SlO5 lost
nature
of the component present triglyceride
synthesis
When heated in a boiling
a substantial
was obtained
water bath
amount (50-75%) of its
233
in S105 responsi-
capacity
(95')
by for
to activate
Vol. 58, No. 1, 1974
the conversion
of diglyceride
shows the results While trypsin it
is clear
BIOCHEMICAL
that
triglyceride
to triglyceride
of an experiment
inhibitor
synthesis
totally
tion thesis
but rather
Incubation
that
Table 3
with trypsin.
reaction
(Flask 3),
of S105 to activate
incorporation
an experiment
of label
palmitate
was designed
added diolein
no exogenously
added substrate.
2 as determined corresponded
for the
of such an
and added Il-C14]-palmityl-CoA.
in Incubation
Incuba-
The net syn-
chemically
closely
was due
with fatty
to test
Table 4 summarizes the results
or 34.4% of the added palmityl-CoA)
(222 nmoles
with the value deter-
(191 nmoles or 29.6% of the added [l-14C]-palmityl-CoA).
These data demonstrate
conclusively
ATP + magnesium chloride) diglyceride
in this
to exchange of labeled
1 contained
of triglyceride
mined isotopically
microsomes.
the ability
the possibility
of triglyceride.
2 contained
inhibitory
destroyed
acids of endogenous triglyceride,
experiment.
by liver
(Flask 4).
In order to eliminate
net synthesis
RESEARCH COMMUNICATIONS
in which SlO5 was incubated
was slightly
trypsin
not to net synthesis
AND BIOPHYSICAL
that
this
system (microsomes + S105 +
causes the net synthesis
of triglyceride
from
and palmityl-CoA. DISCUSSION
We have demonstrated
a requirement
for a soluble
105,000 x g supernatant
(5105) which is required
tyl-CoA
to triglyceride
and diglyceride
we have shown a requirement thesis
has been monitored
either
[l-14C]-palmityl-CoA
either
substrate,
incubated
there
by rat
by incorporation
liver
of label
or ]l-14C]-diolein is no enzymatic
complete system has been demonstrated
ticles
as their
microsomes.
activity
associated
by chemical
source of enzymes.
234
of palmiIn addition
Triglyceride
into triglyceride
Net synthesis
when they used chicken
in liver
liver
syn-
using
as the source of label.
Weiss, Kennedy and Kiyasu (8) did not report reaction
present
for the conversion
for ATP and magnesium chloride.
in the absence of microsomes.
ment for this
protein
Using
with S105 when
of triglyceride
analysis
of ester
a soluble
protein
by the linkages. require-
20,000 x g sedimented par-
Vol. 58, No. 1, 1974
BIOCHEMICAL
Smith, Sedgwick, Brindley by both rat liver conversion
(10) observed a soluble mitic
and cat intestinal
protein
requirement
phatidate
into
the protein
phosphohydrolase
Johnston,
Rao, Lowe and Schwarz
for the incorporation
triglycerides.
responsible
(EC 3.1.3.4),
for SlO5
mucosa microsomes in the
acid to glycerides.
acid or L-a-glycerophosphate
in both papers was that
RESEARCH COMMUNICATIONS
and Hiibscher (9) noted a requirement
mitochondria
of phosphatidic
AND BIOPHYSICAL
of either
The conclusion
for stimulation
which converts
pal-
drawn
was L-cr-phos-
phosphatidic
acid to
diglyceride. Such an explanation
is not possible
for the system which we have described
since phosphatidic
acid is not the substrate.
that
one or more proteins
SlO5 contains
synthesis
of triglycerides
It is possible
which operate
from water insoluble
that there
are substrate
sent in SlO5 which are essential strates
An alternative
for the synthesis
by microsomal membranes.
posal exists
for the synthesis
pounds (4).
Further
experiments
In fact
as carriers
precursors specific
explanation
by liver
soluble
are in progress
for the microsomes.
proteins
pre-
of most water insoluble
evidence compatible
of many different
is
with this
types of water insoluble to test
this
sub-
procom-
hypothesis.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10.
Scallen, T.J., Schuster, M.W., and Dhar, A.K. (1971) J. Biol. Chem. 246, 224-230. Scallen, T.J., Srikantaiah, M.V., Skrdlant, H.B., and Hansbury, E. (1972) FEBS Letters 25, 227-233. Seetharam, B., Gavey, K.L., Srikantaiah, M.V., Hansbury, E., and Scallen, T.J. (1973) Circulation 48, Suppl. IV, IV-253. M.V., Seetharam, B., Hansbury, E. and Gavey, Scallen, T.J., Srikantaiah, K.L. (1974) American Society of Biological Chemists Symposium on Metabolism of Membrane Lipids, Fed. Proc., in press. Seetharam, B., Hansbury, E., Srikantaiah, M.V., and Scallen, T.J. (1974) Fed. Proc., in press. Bligh, E.G., and Dyer, W.J. (1959) Can. J. Biochem. Physiol. 37, 911-917. Rapport, M.M., and Alonzo, N. (1955) J. Biol. Chem. 217, 193-198. Weiss, S.B., Kennedy, E-P., and Kiyasu, J.Y. (1960) J. Biol. Chem. 235, 40-44. Smith, M.E., Sedgwick, B., Brindley, D.N., and Hiibscher, G. (1967) European J. Biochem. 5, 70-77. Johnston, J.M., Rao, G.A., Lowe, P.A., and Schwarz, B.E. (1967) Lipids 2, 14-20.
235
Vol. 58, No. 1, 1974
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
CONVERSION OF DIGLYCERIDETO TRIGLYCERIDEBY RAT LIVER MICROSOMES: A REQUIREMENT FOR THE 105,000 x g SUPERNATANTl Eric R. Manley2, Harold B. Skrdlant,
Elizabeth
Hansbury and Terence J. Scallen3
Departments of Chemistry and Biochemistry University of New Mexico Albuquerque, New Mexico 87131 Received
March
21,1974
This paper describes a requirement for the 105,000 x g supernatant of rat liver for the synthesis of triglyceride from diglyceride and palmityl coenzyme A by rat liver microsomes. ATP and magnesium chloride are also required. The incorporation of both ]l-14C]-palmityl coenzyme A and [l-l%]diolein into triglyceride has been observed. The 105,000 x g supernatant has no enzymatic activity for this reaction when incubated in the absence of microsomes. The supernatant contains a soluble, essential protein which is nondialyzable, heat sensitive, and destroyed by trypsin. Net synthesis of triglyceride has been demonstrated by chemical analysis. SUMMARY:
Work in this eral
substrate
rat liver,
laboratory
specific
over the last
proteins,
as having essential These soluble
present roles
in the microsomal biosynthesis
(l-5).
proteins
sterols
by the microsomal membranes, and it
operate
as carriers
are required
for water insoluble lipid
have chosen to study is the acylation
years has implicated
sev-
in the 105,000 x g supernatant4
sterols
phenomena might occur in other
several
substrates.
biosynthetic
of
for the synthesis
has been proposed that
of diglyceride
of
they
We reasoned that pathways.
of
similar
The reaction
we
to form triglyceride.
MATERIALSAND METHODS Chemicals:
[1-14C]-Diolein
CoA from New England Nuclear; from Sigma; Silicar
Science Laboratories;
tories,
London, Ontario.
3. 4. Copyright All rights
palmityl-CoA,
CC-7 Special
Applied
1. 2.
was obtained
from Dhom; [1-14C]-palmityltrypsin,
from Mallinckrodt;
and 1,2-diolein
and trypsin 1,2-dipalmitin
inhibitor from
from Serdary Research Labora-
This research was supported by NIH Grant AM 10,628-08. This work is part of a thesis being presented to the University of New Mexico in partial fulfillment of the requirements for the degree of Doctor of Philosophy. Reprint requests should be addressed to T.J. Scallen, Department of Biochemistry, School of Medicine, University of New Mexico, Albuquerque, New Mexico 87131. Abbreviation used: Slo5, 105,000 x g supernatant. 0 1974 by Academic Press, of reproduction in any form
Inc. reserved.
229
Vol. 58, No. 1, 1974
BIOCHEMICAL
AND BIOPHYSICAL
SlO5 and Microsome Preparation: 300 g) were sacrificed
by decapitation.
washed in ice cold potassium (0.1 mM).
The livers
cold buffer
were blotted
After
any residual
was removed with a pipet. fer,
fitting
This washing procedure
were carried
37' under an atmosphere of nitrogen phosphate
buffer
dioxane-propylene
5-10 ~1 of sodium acetate Extractions: form-methanol
a brief
buffer
Incubations
(7.5 ml).
were added as described After
fraction
was repeated
at
twice more.
in liquid
nitrogen,
loss of activity. shaker at
volume of 2 ml of potassium EDTA (0.1 mM).
Diglyceride
Palmityl-CoA
were stopped by the addition chloroform
was
was added in
The residue by silicic
of 1:2 chloro-
(2.5 ml) and water
procedure
the chloroform
was isolated
SlO5)
in fresh buf-
out in a Dubnoff
glycol.
in the extraction
centrifugation
(constituting
(0.1 M, pH 6.0).
Subsequently
under a stream of nitrogen. glyceride
in a final
(0.02 M, pH 7.4) containing
added in S-10 ~1 of 2:l
removed from the
and recentrifuged
separately
at -80' without
incubations
was centrifuged
was resuspended
Teflon pestle,
and they can be stored indefinitely All
The homo-
was discarded,
was carefully
pellet
washed microsomes were frozen
Incubations:
the pellet
were
at 105,000 x g for 60 minutes to remove
The microsomal
105,000 x g for 60 minutes. SlO5 and triply
Teflon pestle.
The clear middle fraction
homogenized with a tight
EDTA
at 20,000 x g for 15 minutes.
The supernatant
microsomes.
and
the livers
and the 20,000 x g supernatant
and recentrifuged
light
mincing with scissors,
was then centrifuged
at 105,000 x g for 60 minutes.
excised
(0.02 M, pH 7.4) containing
(1 mm clearance)
was discarded,
pellet
were immediately
at 1000 x g for 10 minutes,
and the 1000 x g supernatant
microsomal
Livers
(200-
dry, weighed and suspended in 2 ml of fresh
homogenized with a loose fitting genate was centrifuged
male Sprague-Dawley rats
phosphate buffer
per gram of tissue.
Again the pellet
Adult
RESEARCH COMMUNICATIONS
layer
(2.5 ml)
of Bligh and Dyer (6). was removed and dried
was taken up in toluene; acid chromatography
the tri-
as described
below. Chromatography: CC-7 Special)
Separations
columns (1 x 5 cm).
were carried
out on silicic
Toluene was the eluting 230
acid (Silicar solvent,
and 7 ml
Vol. 58, No. 1, 1974
fractions
were
column
in Fraction
Fatty
acids
unless
the
fatty
acids
BIOCHEMICAL
collected.
was changed
3375 liquid
ester
ether-toluene
6.
fractions
in which
measurements
In the
the
case
in one fraction.
counter.
of Esters:
from
2 through
in much later
together
scintillation
removed
in Fractions
radioactivity
was determined
and Alonzo
diethyl
RESEARCH COMMUNICATIONS
completely
separately
eluted
All
Determination
triglyceride Rapport
were
were
eluted
eluted
to 1:9
Counting:
Chemical
were
were
and diglycerides
Model
esters
Triglycerides
and diglycerides
Scintillation a Packard
Cholesterol
1.
solvent
AND BIOPHYSICAL
were
Counting
net
quantitatively
synthesis by the
performed
with
efficiency
was 82%.
experiment
(Table
hydroxamate
method
of
(7). RESULTS
As shown
in Table
CoA and diolein, triglyceride
only fraction
chloride
were
label
1 when microsomes
(21.4%)
added
incorporation
of
(Flask
1).
when SlO5,
the
S105 or ATP from
fall
to low
incubation
levels
detected
when SlO5 was incubated preparations
one preparation
another,
the
aration
dialysis
chloride.
added ATP nor
ATP and magnesium
of SlO5
After
simply full
We presume
Il-14C]-diolein
2 shows the into
that
5). absence
SlO5 have
given
chloride results triglyceride
observation
incorporation
to
of magnesium activity
was
results.
required,
and with
against
In any
was required.
can be induced
by addition is
Omission
different
chloride
16 hours
6).
omission
was not
can be restored this
(Flask
of
of microsomes.
requirements for
incorporation
slightly
chloride
in the
ATP and magnesium
No enzymatic
added magnesium
by dialysis
[l-14C]-palmitylwas observed
caused
while
in the
chloride
activity
of ATP and magnesium Table
of
(3.9%)
was seen mixture
(Flask
added magnesium
neither
event,
effect
with
substantial
2, 3 and 4),
produced
With
mixture,
incubation
(Flasks
a lesser
label
fraction
the
chloride
Different
However,
triglyceride
of either back
incubated
slight
to the
into
were
in any prep-
20 volumes
of buffer.
of ATP and magnesium
due to variable
endogenous
levels
in S105. of an experiment was monitored.
231
in which Again
the
incorporation
SlO5 was required
of for
4)
BIOCHEMICAL
Vol. 58, No. 1, 1974
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
TABLE 1 INCORPORATION OF 11-14C]-PALMITYL-CoA INTO TRIGLYCERIDEBY LIVER MICROSDMES: REQUIREMENTFOR S105, ATP AND MAGNESIUMCHLORIDE Incorporation of ]1-14C]-palmityl-CoA into triglyceride Flask
Additions
-%
nmoles
none
3.9
0.066
ATP + M&l2
4.6
0.078
S105
2.2
0.037
slos + MS12
1.9
0.032
S105 + ATP
10.7
0.182
S105 + ATP + MgC12
21.4
0.364
All lasks contained microsomes (1.9 mg protein), diolein (8.1 nmolesj and [l- 15Cl-palmityl-CoA (1.7 nmoles, 0.1 PCi) in a final volume of 2 ml of buffer. Flasks 2, 4 and 6 contained magnesium chloride (4 mM). Flasks 2, 5 and 6 contained ATP (4 mM). Flasks 3-6 contained S105 (17 mg protein).
TABLE 2 CONVERSIONOF Ii-14C]-DIOLEIN
TO TRIGLYCERIDE
Incorporation into Flask
of [1-14C]-diolein triglyceride
%
Additions
nmoles
1
none
1.0
0.010
2
palmityl-CoA
6.7
0.067
3
S105
25.9
0.259
4
SlO5 + palmityl-CoA
25.4
0.254
All flasks contained microsomes (1.9 mg protein), ATP and magnesium chloride (1 nmole, 0.1 I.&X) in a final volume of 2 ml of (4 mw, and [l-14C]-diolein buffer. Flasks 3 and 4 contained SlO5 (17 mg protein). Flasks 2 and 4 contained palmityl-CoA (10 nmoles).
triglyceride chloride again,
synthesis by this
by microsomes.
The requirement
system was the same as shown previously
when incubated
in the absence of microsomes,
matic activity. 232
for ATP and magnesium in Table 1.
S105 exhibited
Once
no enzy-
Vol. 58, No. 1, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
TABLE 3 TRYPSIN TREA'IMENTOF LIVER S105 Incorporation of [l-14C]-palmityl-CoA into triglyceride Additions
Flask 1
-%
nmoles
none
3.9
0.066
5105
26.3
0.447
Slo5 + trypsin
inhibitor
11.3
0.192
Slo5 + trypsin inhibitor
+ trypsin
1.5
0.025
All incubations and preincubations were carried out at 37' under nitrogen. Flask 1 received no preincubation. The Slo5 in Flask 2 was preincubated alone for 60 min. The SlO5 in Flask 3 was preincubated alone for 30 min at which time trypsin inhibitor (5 mg) was added and the preincubation was continued for an additional 30 min. In Flask 4 SlOs and trypsin (5 mg) were preincubated together for 30 min at which time trypsin inhibitor (5 mg) was added and the preincubation was continued for an additional 30 min. At the end of the preincubation period, microsomes (1.9 mg protein), ATP and magnesium chloride (4 mM), dipalmitin (7 nmoles), and [l-14C]-palmityl-CoA (1.7 nmoles, 0.1 i&i) were added to all flasks. The final incubation volume for all flasks was 2 ml. All flasks were then incubated for 60 min.
TABLE 4 NET SYNTHESISOF TRIGLYCERIDEFROM[1-14C]-PAWTYL-C~A Triglyceride
Triglyceride Incubation
nmoles
nmoles -
AND DIOLEIN
[1-14C]-palmityl-CoA incorporated
synthesized -%
-nmoles
-%
1
569
---
---
---
---
2
791
222
34.4
191
29.6
Each incubation consisted of five identical flasks. All flasks contained microsomes (1.9 mg protein), SlO5 (17 mg protein), and ATP and magnesium chloride (4 mM) in a final volume of 2 ml of buffer. Incubation 1 contained no added substrate. Incubation 2 contained a total of 645 nmoles of [1-14C]palmityl-CoA (0.645 Ki) and 405 nmoles of diolein. Evidence for the protein ble for the activation heat and trypsin 5 minutes,
of microsomal
treatments.
SlO5 lost
nature
of the component present triglyceride
synthesis
When heated in a boiling
a substantial
was obtained
water bath
amount (50-75%) of its
233
in S105 responsi-
capacity
(95')
by for
to activate
Vol. 58, No. 1, 1974
the conversion
of diglyceride
shows the results While trypsin it
is clear
BIOCHEMICAL
that
triglyceride
to triglyceride
of an experiment
inhibitor
synthesis
totally
tion thesis
but rather
Incubation
that
Table 3
with trypsin.
reaction
(Flask 3),
of S105 to activate
incorporation
an experiment
of label
palmitate
was designed
added diolein
no exogenously
added substrate.
2 as determined corresponded
for the
of such an
and added Il-C14]-palmityl-CoA.
in Incubation
Incuba-
The net syn-
chemically
closely
was due
with fatty
to test
Table 4 summarizes the results
or 34.4% of the added palmityl-CoA)
(222 nmoles
with the value deter-
(191 nmoles or 29.6% of the added [l-14C]-palmityl-CoA).
These data demonstrate
conclusively
ATP + magnesium chloride) diglyceride
in this
to exchange of labeled
1 contained
of triglyceride
mined isotopically
microsomes.
the ability
the possibility
of triglyceride.
2 contained
inhibitory
destroyed
acids of endogenous triglyceride,
experiment.
by liver
(Flask 4).
In order to eliminate
net synthesis
RESEARCH COMMUNICATIONS
in which SlO5 was incubated
was slightly
trypsin
not to net synthesis
AND BIOPHYSICAL
that
this
system (microsomes + S105 +
causes the net synthesis
of triglyceride
from
and palmityl-CoA. DISCUSSION
We have demonstrated
a requirement
for a soluble
105,000 x g supernatant
(5105) which is required
tyl-CoA
to triglyceride
and diglyceride
we have shown a requirement thesis
has been monitored
either
[l-14C]-palmityl-CoA
either
substrate,
incubated
there
by rat
by incorporation
liver
of label
or ]l-14C]-diolein is no enzymatic
complete system has been demonstrated
ticles
as their
microsomes.
activity
associated
by chemical
source of enzymes.
234
of palmiIn addition
Triglyceride
into triglyceride
Net synthesis
when they used chicken
in liver
liver
syn-
using
as the source of label.
Weiss, Kennedy and Kiyasu (8) did not report reaction
present
for the conversion
for ATP and magnesium chloride.
in the absence of microsomes.
ment for this
protein
Using
with S105 when
of triglyceride
analysis
of ester
a soluble
protein
by the linkages. require-
20,000 x g sedimented par-
Vol. 58, No. 1, 1974
BIOCHEMICAL
Smith, Sedgwick, Brindley by both rat liver conversion
(10) observed a soluble mitic
and cat intestinal
protein
requirement
phatidate
into
the protein
phosphohydrolase
Johnston,
Rao, Lowe and Schwarz
for the incorporation
triglycerides.
responsible
(EC 3.1.3.4),
for SlO5
mucosa microsomes in the
acid to glycerides.
acid or L-a-glycerophosphate
in both papers was that
RESEARCH COMMUNICATIONS
and Hiibscher (9) noted a requirement
mitochondria
of phosphatidic
AND BIOPHYSICAL
of either
The conclusion
for stimulation
which converts
pal-
drawn
was L-cr-phos-
phosphatidic
acid to
diglyceride. Such an explanation
is not possible
for the system which we have described
since phosphatidic
acid is not the substrate.
that
one or more proteins
SlO5 contains
synthesis
of triglycerides
It is possible
which operate
from water insoluble
that there
are substrate
sent in SlO5 which are essential strates
An alternative
for the synthesis
by microsomal membranes.
posal exists
for the synthesis
pounds (4).
Further
experiments
In fact
as carriers
precursors specific
explanation
by liver
soluble
are in progress
for the microsomes.
proteins
pre-
of most water insoluble
evidence compatible
of many different
is
with this
types of water insoluble to test
this
sub-
procom-
hypothesis.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10.
Scallen, T.J., Schuster, M.W., and Dhar, A.K. (1971) J. Biol. Chem. 246, 224-230. Scallen, T.J., Srikantaiah, M.V., Skrdlant, H.B., and Hansbury, E. (1972) FEBS Letters 25, 227-233. Seetharam, B., Gavey, K.L., Srikantaiah, M.V., Hansbury, E., and Scallen, T.J. (1973) Circulation 48, Suppl. IV, IV-253. M.V., Seetharam, B., Hansbury, E. and Gavey, Scallen, T.J., Srikantaiah, K.L. (1974) American Society of Biological Chemists Symposium on Metabolism of Membrane Lipids, Fed. Proc., in press. Seetharam, B., Hansbury, E., Srikantaiah, M.V., and Scallen, T.J. (1974) Fed. Proc., in press. Bligh, E.G., and Dyer, W.J. (1959) Can. J. Biochem. Physiol. 37, 911-917. Rapport, M.M., and Alonzo, N. (1955) J. Biol. Chem. 217, 193-198. Weiss, S.B., Kennedy, E-P., and Kiyasu, J.Y. (1960) J. Biol. Chem. 235, 40-44. Smith, M.E., Sedgwick, B., Brindley, D.N., and Hiibscher, G. (1967) European J. Biochem. 5, 70-77. Johnston, J.M., Rao, G.A., Lowe, P.A., and Schwarz, B.E. (1967) Lipids 2, 14-20.
235