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Acetyl phosphate utilization with animal and bacterial enzymes
Vol. 7, No. 5, 1962
PHOSPHATE UTILIZATION
ACETYL
WITH ANIMAL
S. Grisolia University
Received
of Kansas
January
and P. Harmon Center,
recent
studies
et al,
19621,
with
has become
AP,
evident
replacing
kinase
the
cocci
about
yield
after
petitive
to test
+ ATP +
postulating for
the
* Supported by a Grant
activity CP,
more
from
induction
(Slade
inhibition indeed
of ATP from glutamate,
partial
to the
acetyl not
the
activities
1958)
reversibility
of for
CP
Strain
DlU Group
D strepto-
and Slamp,
1952).
Com-
also
indicate
that
These
findings
led
perhaps
CP and ADP catalyzed
et al,
due to
as
AP could
This
phosphate,
purification,
acetokinase.
AG.
1:
identity
with
experiments
in which
kinase
reaction
with
likely
activities
both
carbamate
is probably
constant
(Metzenberg
reactions
Kansas
CP + ADP,
and remain
is
acetyl
marked
but
reactions
Synthesis
ing
12,
catalyzes
equal
arginine
other
that
since
for
kinase
requires
City
purified
and acetokinase,
substrate
carbamate
highly
phosphate,
contamination
and AP are does
that
carbamyl
acetokinase carbamate
Kansas
an enzyme
1) NH2cooit
ENZYMES*
26, 1%2
During (Grisolia
Medical
AND BACTERIAL
has been
replace
us
CP.
by CP synthetase the
two enzymatic
of CP synthesis
basis
for
sites according
accountto
2 and 3:
by Grant A-1855 National from the American Heart 357
Institutes AsSOCiatiOn.
of Health
and
Vol. 7, No. 5, 1962
BIOCHEMICAL
2) ATP + CO2
AG,
3) ATP + "active Carbamyl-P phosphate requires enzyme the
date
acetyl
form
uses AP about shown in
the
ATP and in
this
this
3 times
Table
+ NH3 s
catalyzes
glutamate;
RESEARCH COMMUNICATIONS
ADP + Pi + "active
C02"
synthetase
and ADP to
AND BIOPHYSICAL
is
faster
I and from
ADP + CP interaction case,
that
of as with
illustrated than
C02"
in
CP, in
acetyl CP,
it
I.
The
Table
as calculated
the
from
literature
(Caravaca
TABLE I ACETYL GLUTAMATE REQUIREMENT WITH FROG LIVER
FOR ACETYL PHOSPHATE UTILIZATION
CARBAMYL PHOSPHATE
Additions Enzyme
Protein
SYNTHETASE
poles Acetyl
mg
poles
0.4
0
0.4
10
0.8
0
0.8
10
1.6
0
1.6
10
Glutamate
AP transferred
Exp.
1
Exp.
2
0 0.9 0
0
2.4
1.6
0
0
4.0
2.2
Each tube contained the following in poles: Tris-ClpH 100; MgS04, 20; acetyl phosphate, 10; ADP, 10 and the indicated amount of carbamyl phosphate synthetase (Raijman and Grisolia, 1961). Tubes from experiment #l contained also 50 units of hexokinase and 50 poles of glucose (Mokrasch et al, 1960). 10 min incubation at 38O. 1.0 ml final volume. The above findings were confirmed in other experiments by measuring ATP formation (Mokrasch et al. 19601, and with rat liver CP synthetase. There 7.4,
was no demonstrable AP formation with the above system when AP was replaced by 100 poles of K acetate and the ADP by ATP, even when including 100 umoles of NH20H.
Vol. 7, No. 5, 1962
BIOCHEMICAL
and Grisolia, present
1960;
findings
mechanism of
containing
supplemented not
documented
0.6% the
rate
respectively, other
than
in Table ornithine
with
1958).
further
II,
the
It
appears
understanding
here with
However,
show that CP for
AP is
a substrate
transcarbamylase
ornithine.
indicating the
to
et al,
RESEARCH COMMUNICATIONS
that
the
of the
of CP synthetase.
As illustrated tions
Metzenberg
may serve
action
AND BIOPHYSICAL
rat that
AP is liver,
when they
parallel
frog
present
preparaare
experiments
used at about liver
AP utilization
transcarbamylase
with
is
12,
3 and
and bacteria due to
an enzyme
in the preparations.
e
TABLE II ORNITHINE RF,QUIREMENT FOR ACETYL PHOSPHATE UTILIZATION
WITH
ANIMAL AND BACTERIAL PREPARATIONS
poles
Enzyme source
and poles
Ap used
Ornithine Added 0 10
Rat Liver
Frog
Liver
Bacteria
0
0
0
4.1
7.4
5.4
Each tube contained the following in junoles: Tris-Cl-pH 7.4, 50 (100 for the experiments with frog liver enzyme); acetyl as indicated. 0.8 mg phosphate, 10; MgS04, 20 and L-ornithine protein from frog liver (Raijman and Grisolia, 1961), 0.9 mg rat liver mitochondria (Grisolia and Cohen, 1951), and 1.0 mg of bacterial ornithine transcarbamylase (Caravaca and Grisolia, 1960) was used when indicated. The incubation volume was 1.0 ml. phosphate utilization was measured as 10 min at 38O. Acetyl indicated in Table I. ,359
Vol. 7, No. 5, 1962
BIOCHEMICAL
The present utilization
findings
of AP for
The possibility acetylated
that with
demonstrate synthetic
aminoacids
evidence
demonstration the
recognition
case
for
AG and CP synthesis.
catalytic,
in for
enzymes
it
is
of AP synthesis
only
aspartate
other
is negative
However,
by CP synthetase.
brain other
of
for
purposes
AP by animal
our preliminary
the
AND BIOPHYSICAL
acetyl
with
first
ornithine
remains
open.
Indeed,
to
cofactor, the
presence
may be metabolic
aminoacids.
may be As indicated,
speculate
tissues
the
enzymes.
synthesis
attractive animal
time
animal
regarding
in
there
the
than
an unsuspected
suggests
RESEARCH COMMUNICATIONS
of AP that
may await as has been
the
of acetyl roles,
perhaps
e
REFERENCES Caravaca, J., and Grisolia, S., J. Biol. Chem., 235, 684 (1960). Grisolia, S., and Cohen, P. P., J. Biol. Chem., 191, 189 (1951). Grisolia, S., Caravaca, J., and Joyce, B. K., Biochim. et Biophys. Acta, 29, 432 (1958). Grisolia, S., Harmon, P., and Raijman, L., Biochim. et Biophys. Acta, in press (1962). Lipmann, F., and Tuttle, L. C., J. Biol. Chem., 159. 21 (1945). Metzenberg, R. L., Marshall, M., and Cohen, P. P., J. Biol. Chem., 233. 1560 (1958). Mokrasch, L.,C., Caravaca, J., and Grisolia, S., Biochim. et Biophys. Acta, 37. 422, (1960). Raijman, L., and Grisolia, S., Biochem. and Biophys. Research Communs ., & 262 (1961). Slade, H. D., and Slamp, W. C., J. Bact. 64. 455 (1952).
360
PHOSPHATE UTILIZATION
ACETYL
WITH ANIMAL
S. Grisolia University
Received
of Kansas
January
and P. Harmon Center,
recent
studies
et al,
19621,
with
has become
AP,
evident
replacing
kinase
the
cocci
about
yield
after
petitive
to test
+ ATP +
postulating for
the
* Supported by a Grant
activity CP,
more
from
induction
(Slade
inhibition indeed
of ATP from glutamate,
partial
to the
acetyl not
the
activities
1958)
reversibility
of for
CP
Strain
DlU Group
D strepto-
and Slamp,
1952).
Com-
also
indicate
that
These
findings
led
perhaps
CP and ADP catalyzed
et al,
due to
as
AP could
This
phosphate,
purification,
acetokinase.
AG.
1:
identity
with
experiments
in which
kinase
reaction
with
likely
activities
both
carbamate
is probably
constant
(Metzenberg
reactions
Kansas
CP + ADP,
and remain
is
acetyl
marked
but
reactions
Synthesis
ing
12,
catalyzes
equal
arginine
other
that
since
for
kinase
requires
City
purified
and acetokinase,
substrate
carbamate
highly
phosphate,
contamination
and AP are does
that
carbamyl
acetokinase carbamate
Kansas
an enzyme
1) NH2cooit
ENZYMES*
26, 1%2
During (Grisolia
Medical
AND BACTERIAL
has been
replace
us
CP.
by CP synthetase the
two enzymatic
of CP synthesis
basis
for
sites according
accountto
2 and 3:
by Grant A-1855 National from the American Heart 357
Institutes AsSOCiatiOn.
of Health
and
Vol. 7, No. 5, 1962
BIOCHEMICAL
2) ATP + CO2
AG,
3) ATP + "active Carbamyl-P phosphate requires enzyme the
date
acetyl
form
uses AP about shown in
the
ATP and in
this
this
3 times
Table
+ NH3 s
catalyzes
glutamate;
RESEARCH COMMUNICATIONS
ADP + Pi + "active
C02"
synthetase
and ADP to
AND BIOPHYSICAL
is
faster
I and from
ADP + CP interaction case,
that
of as with
illustrated than
C02"
in
CP, in
acetyl CP,
it
I.
The
Table
as calculated
the
from
literature
(Caravaca
TABLE I ACETYL GLUTAMATE REQUIREMENT WITH FROG LIVER
FOR ACETYL PHOSPHATE UTILIZATION
CARBAMYL PHOSPHATE
Additions Enzyme
Protein
SYNTHETASE
poles Acetyl
mg
poles
0.4
0
0.4
10
0.8
0
0.8
10
1.6
0
1.6
10
Glutamate
AP transferred
Exp.
1
Exp.
2
0 0.9 0
0
2.4
1.6
0
0
4.0
2.2
Each tube contained the following in poles: Tris-ClpH 100; MgS04, 20; acetyl phosphate, 10; ADP, 10 and the indicated amount of carbamyl phosphate synthetase (Raijman and Grisolia, 1961). Tubes from experiment #l contained also 50 units of hexokinase and 50 poles of glucose (Mokrasch et al, 1960). 10 min incubation at 38O. 1.0 ml final volume. The above findings were confirmed in other experiments by measuring ATP formation (Mokrasch et al. 19601, and with rat liver CP synthetase. There 7.4,
was no demonstrable AP formation with the above system when AP was replaced by 100 poles of K acetate and the ADP by ATP, even when including 100 umoles of NH20H.
Vol. 7, No. 5, 1962
BIOCHEMICAL
and Grisolia, present
1960;
findings
mechanism of
containing
supplemented not
documented
0.6% the
rate
respectively, other
than
in Table ornithine
with
1958).
further
II,
the
It
appears
understanding
here with
However,
show that CP for
AP is
a substrate
transcarbamylase
ornithine.
indicating the
to
et al,
RESEARCH COMMUNICATIONS
that
the
of the
of CP synthetase.
As illustrated tions
Metzenberg
may serve
action
AND BIOPHYSICAL
rat that
AP is liver,
when they
parallel
frog
present
preparaare
experiments
used at about liver
AP utilization
transcarbamylase
with
is
12,
3 and
and bacteria due to
an enzyme
in the preparations.
e
TABLE II ORNITHINE RF,QUIREMENT FOR ACETYL PHOSPHATE UTILIZATION
WITH
ANIMAL AND BACTERIAL PREPARATIONS
poles
Enzyme source
and poles
Ap used
Ornithine Added 0 10
Rat Liver
Frog
Liver
Bacteria
0
0
0
4.1
7.4
5.4
Each tube contained the following in junoles: Tris-Cl-pH 7.4, 50 (100 for the experiments with frog liver enzyme); acetyl as indicated. 0.8 mg phosphate, 10; MgS04, 20 and L-ornithine protein from frog liver (Raijman and Grisolia, 1961), 0.9 mg rat liver mitochondria (Grisolia and Cohen, 1951), and 1.0 mg of bacterial ornithine transcarbamylase (Caravaca and Grisolia, 1960) was used when indicated. The incubation volume was 1.0 ml. phosphate utilization was measured as 10 min at 38O. Acetyl indicated in Table I. ,359
Vol. 7, No. 5, 1962
BIOCHEMICAL
The present utilization
findings
of AP for
The possibility acetylated
that with
demonstrate synthetic
aminoacids
evidence
demonstration the
recognition
case
for
AG and CP synthesis.
catalytic,
in for
enzymes
it
is
of AP synthesis
only
aspartate
other
is negative
However,
by CP synthetase.
brain other
of
for
purposes
AP by animal
our preliminary
the
AND BIOPHYSICAL
acetyl
with
first
ornithine
remains
open.
Indeed,
to
cofactor, the
presence
may be metabolic
aminoacids.
may be As indicated,
speculate
tissues
the
enzymes.
synthesis
attractive animal
time
animal
regarding
in
there
the
than
an unsuspected
suggests
RESEARCH COMMUNICATIONS
of AP that
may await as has been
the
of acetyl roles,
perhaps
e
REFERENCES Caravaca, J., and Grisolia, S., J. Biol. Chem., 235, 684 (1960). Grisolia, S., and Cohen, P. P., J. Biol. Chem., 191, 189 (1951). Grisolia, S., Caravaca, J., and Joyce, B. K., Biochim. et Biophys. Acta, 29, 432 (1958). Grisolia, S., Harmon, P., and Raijman, L., Biochim. et Biophys. Acta, in press (1962). Lipmann, F., and Tuttle, L. C., J. Biol. Chem., 159. 21 (1945). Metzenberg, R. L., Marshall, M., and Cohen, P. P., J. Biol. Chem., 233. 1560 (1958). Mokrasch, L.,C., Caravaca, J., and Grisolia, S., Biochim. et Biophys. Acta, 37. 422, (1960). Raijman, L., and Grisolia, S., Biochem. and Biophys. Research Communs ., & 262 (1961). Slade, H. D., and Slamp, W. C., J. Bact. 64. 455 (1952).
360