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Incorporation of labeled orthophosphate into nucleoside diphosphates
BIOCHEMICAL
Vol. 18, No. 4, 1965
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
INCORPORATION OF LABELEDORTHOPHOSPHATE INTO NUCLROSIDEDIPHOSPHATES* Bert Winter and Robert S. Bandurski Department of Botany and Plant Pathology Michigan State University East Lansing, Michigan ReceivedDecember
29, 1964
We wish to report fraction
on the presence of an enzyme in a particulate
of tobacco leaves which catalyzes
inorganic
phosphate
ability,
into ADP, UDP, CDP and GDP but has little,
to incorporate
attention
is directed
phosphates
Cl4 -labeled
or no
ADP or ATP into RNA. In addition
to the non-enzymatic
by impurities
P3'-purification
the exchange of P32-labeled
labeling
in P32-orthophosphate,
of nucleoside
and a procedure
for
described.
Methods and Results: Enzyme
Equal weights
preparation
and homogenizing
medium (0.04 M, NH4OH, 0.05 g Tris-free
FJmercaptoethanol) pH approximately
of tobacco leaves,
were ground in a mortar 8.6, was filtered
through
cheese cloth
and centri-
paper,
pellets
were suspended in 75 ml of a solution
H Tris,
pH 7.4,
at 50,000 X g. natant
fluid
were collected
then centrifuged
The slurry,
through
The resultant
centrifuged
*Supported, of Health,
was filtered
pellets
The
of 0.005 g MgCl2, 0.05
and centrifuged were discarded
for 2 hours at 105,000 X g.
for 25 minutes and the superThe pellets
and suspended in 4 ml of the above solution.
P32 purification diphosphates
fluid
at 105,000 X g for 2 hours.
0.005 g mercaptoethanol
sand
base and 0.005
and pestle.
The supernatant
fuged for 10 minutes at 7,000 X g.
quartz
Incubation
of unpurified
leads to incorporation
P32-Pi with nucleoside
of radioactivity
into
the diphos-
in part, by a research grant from The National Institutes United States Public Health Service, AM-05916. 512
Vol. 18, No. 4, 1965
BIOCHEMICAL
AND BIOPHYSICAL
is adsorbable
RESEARCH COMMUNlCATlONS
phates.
The radioactivity
tographs
with ADP, GDP and UDP plus CDP using 0.1 E phosphate
6.8/ammonium sulfate/n-propanol solvent
(Pabst,
1956).
onto charcoal
(100:60:2)
The labeling
and co-chromapH
as the chromatographic
is temperature
and time dependent
and has a pH optimum at 5.0. The impurity carrier-free
is eliminated
HCl concentration
heated to 100° for 10 minutes. is passed through
neutralized After
0.1 N.
Following
Pi and HCl and This mixture
dilution
After
the first
neutralization
and last
is eluted
is
Assay
to pH 7 the P32-Pi remains useable for
Owing to the presence of phosphatases
cedure was used to obtain and to demonstrate
that
such as that described the resultant
the specific all
the supernatant
fluid
After
by filtration
with a total elutions,
To a reaction
CDP and ADP are coincident.
stirring
pH 5 and
for 10 minutes,
and washed with 25 ml of 10 ml of H20.
of 5 ml of ethanol-l?H40H-H2O
and the combined supernatant
to Whatman 3 MM paper and subjected pH 3.3.
mixture,
To 0.9 ml of
pH 5 and, finally,
and adsorbed onto a filter
buffer,
pro-
of the diphosphates
was added 3.6 ml of 0.1 g phosphate,
H20, 15 ml of O.OlM phosphate,
using 3 successive
the following
removed by centrifugation.
was collected
was eluted
labeling.
1, was added 0.55 ml of E HC104 and
100 mg of acid-EDTA washed charcoal. the charcoal
activity
4 were labeled.
for Fig.
precipitate
with
10% of the radio-
6 weeks at 4O and does not cause non-enzymatic
evaporated
It
to pH 7 and adsorbed to a 0.5 gm column of Dowex l-X8-Cl.
activity.
charcoal
is
to 0.02 x HCl the
washing the column with H20, the radioactivity
at least
of
a 0.5 gm column of Dowex 50-X4-$.
4 ml of 0.05 g HCl, discarding
citrate
To 3 millicuries
P32-Pi are added 3 pmoles of unlabeled
water to make the final
solution
as follows.
paper disk.
separates
For most assays,
513
this
(50:1:49)
solutions,
The disk was stuck
to electrophoresis
This procedure
The
using 0.01 3
UDP and GDP, but was sufficient.
Vol. 18, No. 4, 1965
BIOCHEMICAL
When it was desired
to separate
Pi, which moves only slightly 1956) with isobutyric
CDP and ADP and to remove traces
acid/ammonia/water
pR 4.3 (57:4:39)
of electrophoresis.
method and radio-autography,
diphosphates
RESEARCH COMMUNICATIONS
ahead of UDP, chromatography
out at 90' to the direction sional
AND BIOPHYSICAL
were approximately
it
was demonstrated
equally
the UV absorbing
areas were cut out,
HCl for spectral
determination
labeled.
(Pabst, was carried two-dimen-
that
all
4
For quantification,
counted and then eluted
of purity
and Rf values of the diphosphates,
By this
of
and quantity.
with l
The mobilities
under our conditions,
are shown
below: Compound ADP CDP GDP UDP
Mobility
Time Course function
of time,
(cm.2sec '%olt'l) 8.7 x 10'5 8.7 x 10'5 12.4 x 10'5 16.5 x 10-5
The rate of incorporation is shown in Fig.
1.
Rf 0.44 0.38 0.23 0.20 of P32-Pi into GDP, as a
This experiment
was done by
0
0
30
60
90
120
150
180
Incubation Time (minutes) as a function of time. Each tube contained in 10. Na Acetate, pH 7.4, 50; MgC12, 4; EGle:f T$~-~~?~~~* !H47~~geac~; P32-potassium phosphate 5 (spkifit activity 5,~70'c/mpmole/min'l); enzyme, 0.2 ml ani water to a total volume of 0.55 ml. Reaction terminated and diphosphates isolated as described in text. Fig.
1.
Reaction
rate
Vol. 18, No. 4, 1965
BIOCHEMICAL
one-dimensional tion
is linear
this
time,
electrophoresis
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
and only GDP was measured.
with time up to 30 minutes
Pi and diphosphatas
and then levels
are not limiting
The reacoff.
At
nor has the enzyme
been inactivated. pH optimum
The rates
of incorporation
and ADP plus CDP are shown in Fig. at approximately
the same rate
2.
of P3*-Pi
All
for all
into UDP, GDP,
4 diphosphates
I-? concentrations
are labeled tested.
The
pH optimum is about 7.4.
10 r a !2
9
"D f0 8 ? a .r( N' ma !
* 7 6 5 4 3
i2 1 " 6.5
7.0
7.5
8.
0
6.5
7.0
PH
7.5
8.0
0-
PH
6.5
7.0
7.5
8.0
PE
Fig. 2. Reaction rate as a function of pH. Conditions as for Fig. 1, except the pH was adjusted to the indicated value, and incubation was for 30 min.
Enzyme concentration centration intervals
is shown in Fig.
Reaction 3.
employed, the reaction
rate as a function
Over the range tested, is a linear
centration.
515
function
of enzyme conand the time of enzyme con-
Vol. 18, No. 4, 1965
BIOCHEMICAL
AND BIOPHYSICAL
I
6.
60'
0
0.04
4
incubation
0.08 0.12 Enzyme (ml)
RESEARCH COMMUNICATIONS
0.16
0.20
0
120'
0.04
incubation
0.08
0.12
0.16
0.20
Enzyme(ml)
Fig. 3. Reaction rate as a function of enzyme concentration. Incubation conditions were as for Fig. 1, except enzyme concentration, as indicated. The optical density of the enzyme, prepared as described in the text, is 76 and 48 at 260 and 280 mu respectively. Non-reactivity were performed under varied three di-
of 8-Cl4 -ADP and ATP A large number of experiments
in which Cl4 -ADP or ATP were incubated conditions
of time and presence or absence of the other
or triphosphates.
the perchloric
The total
acid insoluble
This is negligible
with the enzyme
pellet
radioactivity
incorporated
into
ranged from zero to 0.02 mumoles.
compared to the phosphorolysis
reaction.
Discussion: The enzyme preparation P32-Pi into
nucleoside
not synthesize similar,
diphosphates,
polynucleotide
has been obtained
Alternatively
our preparation
phosphorylase-like tissues
described,
catalyzes
but under our conditions,
1963 and Hilmoe and Heppel,
of does
from C14-ADP. An enzyme, which may be from yeast (Grunberg-Manago, could be related
enzymes previously
(Brummond et al.,
incorporation
described
1957; Kessler
1963).
to the polynucleotide in plant
and animal
and Chen, 1964; Harris,
1957).
References: Anonymous, Pabst Laboratories, Circular OR. 10 (1956). Bruannond, D. O.,Staehelin,M.,and Ochoa,S.,J.Biol.Chem.,~,835(1957). Grunberg-Manago, M., Progr. Nucleic Acid Res., 1, 93 (1963). Harris, H., Proc. Royal Sot. (London) Ser. B, 158, 79 (1963). Hilmoe, R. J., and Heppel, L.A., J. Am. Chem. Sot., 79, 4810 (1957). Kessler, B. and Chen, D., Biochim. Biophys. Acta, 80, 533 (1964). 516
Vol. 18, No. 4, 1965
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
INCORPORATION OF LABELEDORTHOPHOSPHATE INTO NUCLROSIDEDIPHOSPHATES* Bert Winter and Robert S. Bandurski Department of Botany and Plant Pathology Michigan State University East Lansing, Michigan ReceivedDecember
29, 1964
We wish to report fraction
on the presence of an enzyme in a particulate
of tobacco leaves which catalyzes
inorganic
phosphate
ability,
into ADP, UDP, CDP and GDP but has little,
to incorporate
attention
is directed
phosphates
Cl4 -labeled
or no
ADP or ATP into RNA. In addition
to the non-enzymatic
by impurities
P3'-purification
the exchange of P32-labeled
labeling
in P32-orthophosphate,
of nucleoside
and a procedure
for
described.
Methods and Results: Enzyme
Equal weights
preparation
and homogenizing
medium (0.04 M, NH4OH, 0.05 g Tris-free
FJmercaptoethanol) pH approximately
of tobacco leaves,
were ground in a mortar 8.6, was filtered
through
cheese cloth
and centri-
paper,
pellets
were suspended in 75 ml of a solution
H Tris,
pH 7.4,
at 50,000 X g. natant
fluid
were collected
then centrifuged
The slurry,
through
The resultant
centrifuged
*Supported, of Health,
was filtered
pellets
The
of 0.005 g MgCl2, 0.05
and centrifuged were discarded
for 2 hours at 105,000 X g.
for 25 minutes and the superThe pellets
and suspended in 4 ml of the above solution.
P32 purification diphosphates
fluid
at 105,000 X g for 2 hours.
0.005 g mercaptoethanol
sand
base and 0.005
and pestle.
The supernatant
fuged for 10 minutes at 7,000 X g.
quartz
Incubation
of unpurified
leads to incorporation
P32-Pi with nucleoside
of radioactivity
into
the diphos-
in part, by a research grant from The National Institutes United States Public Health Service, AM-05916. 512
Vol. 18, No. 4, 1965
BIOCHEMICAL
AND BIOPHYSICAL
is adsorbable
RESEARCH COMMUNlCATlONS
phates.
The radioactivity
tographs
with ADP, GDP and UDP plus CDP using 0.1 E phosphate
6.8/ammonium sulfate/n-propanol solvent
(Pabst,
1956).
onto charcoal
(100:60:2)
The labeling
and co-chromapH
as the chromatographic
is temperature
and time dependent
and has a pH optimum at 5.0. The impurity carrier-free
is eliminated
HCl concentration
heated to 100° for 10 minutes. is passed through
neutralized After
0.1 N.
Following
Pi and HCl and This mixture
dilution
After
the first
neutralization
and last
is eluted
is
Assay
to pH 7 the P32-Pi remains useable for
Owing to the presence of phosphatases
cedure was used to obtain and to demonstrate
that
such as that described the resultant
the specific all
the supernatant
fluid
After
by filtration
with a total elutions,
To a reaction
CDP and ADP are coincident.
stirring
pH 5 and
for 10 minutes,
and washed with 25 ml of 10 ml of H20.
of 5 ml of ethanol-l?H40H-H2O
and the combined supernatant
to Whatman 3 MM paper and subjected pH 3.3.
mixture,
To 0.9 ml of
pH 5 and, finally,
and adsorbed onto a filter
buffer,
pro-
of the diphosphates
was added 3.6 ml of 0.1 g phosphate,
H20, 15 ml of O.OlM phosphate,
using 3 successive
the following
removed by centrifugation.
was collected
was eluted
labeling.
1, was added 0.55 ml of E HC104 and
100 mg of acid-EDTA washed charcoal. the charcoal
activity
4 were labeled.
for Fig.
precipitate
with
10% of the radio-
6 weeks at 4O and does not cause non-enzymatic
evaporated
It
to pH 7 and adsorbed to a 0.5 gm column of Dowex l-X8-Cl.
activity.
charcoal
is
to 0.02 x HCl the
washing the column with H20, the radioactivity
at least
of
a 0.5 gm column of Dowex 50-X4-$.
4 ml of 0.05 g HCl, discarding
citrate
To 3 millicuries
P32-Pi are added 3 pmoles of unlabeled
water to make the final
solution
as follows.
paper disk.
separates
For most assays,
513
this
(50:1:49)
solutions,
The disk was stuck
to electrophoresis
This procedure
The
using 0.01 3
UDP and GDP, but was sufficient.
Vol. 18, No. 4, 1965
BIOCHEMICAL
When it was desired
to separate
Pi, which moves only slightly 1956) with isobutyric
CDP and ADP and to remove traces
acid/ammonia/water
pR 4.3 (57:4:39)
of electrophoresis.
method and radio-autography,
diphosphates
RESEARCH COMMUNICATIONS
ahead of UDP, chromatography
out at 90' to the direction sional
AND BIOPHYSICAL
were approximately
it
was demonstrated
equally
the UV absorbing
areas were cut out,
HCl for spectral
determination
labeled.
(Pabst, was carried two-dimen-
that
all
4
For quantification,
counted and then eluted
of purity
and Rf values of the diphosphates,
By this
of
and quantity.
with l
The mobilities
under our conditions,
are shown
below: Compound ADP CDP GDP UDP
Mobility
Time Course function
of time,
(cm.2sec '%olt'l) 8.7 x 10'5 8.7 x 10'5 12.4 x 10'5 16.5 x 10-5
The rate of incorporation is shown in Fig.
1.
Rf 0.44 0.38 0.23 0.20 of P32-Pi into GDP, as a
This experiment
was done by
0
0
30
60
90
120
150
180
Incubation Time (minutes) as a function of time. Each tube contained in 10. Na Acetate, pH 7.4, 50; MgC12, 4; EGle:f T$~-~~?~~~* !H47~~geac~; P32-potassium phosphate 5 (spkifit activity 5,~70'c/mpmole/min'l); enzyme, 0.2 ml ani water to a total volume of 0.55 ml. Reaction terminated and diphosphates isolated as described in text. Fig.
1.
Reaction
rate
Vol. 18, No. 4, 1965
BIOCHEMICAL
one-dimensional tion
is linear
this
time,
electrophoresis
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
and only GDP was measured.
with time up to 30 minutes
Pi and diphosphatas
and then levels
are not limiting
The reacoff.
At
nor has the enzyme
been inactivated. pH optimum
The rates
of incorporation
and ADP plus CDP are shown in Fig. at approximately
the same rate
2.
of P3*-Pi
All
for all
into UDP, GDP,
4 diphosphates
I-? concentrations
are labeled tested.
The
pH optimum is about 7.4.
10 r a !2
9
"D f0 8 ? a .r( N' ma !
* 7 6 5 4 3
i2 1 " 6.5
7.0
7.5
8.
0
6.5
7.0
PH
7.5
8.0
0-
PH
6.5
7.0
7.5
8.0
PE
Fig. 2. Reaction rate as a function of pH. Conditions as for Fig. 1, except the pH was adjusted to the indicated value, and incubation was for 30 min.
Enzyme concentration centration intervals
is shown in Fig.
Reaction 3.
employed, the reaction
rate as a function
Over the range tested, is a linear
centration.
515
function
of enzyme conand the time of enzyme con-
Vol. 18, No. 4, 1965
BIOCHEMICAL
AND BIOPHYSICAL
I
6.
60'
0
0.04
4
incubation
0.08 0.12 Enzyme (ml)
RESEARCH COMMUNICATIONS
0.16
0.20
0
120'
0.04
incubation
0.08
0.12
0.16
0.20
Enzyme(ml)
Fig. 3. Reaction rate as a function of enzyme concentration. Incubation conditions were as for Fig. 1, except enzyme concentration, as indicated. The optical density of the enzyme, prepared as described in the text, is 76 and 48 at 260 and 280 mu respectively. Non-reactivity were performed under varied three di-
of 8-Cl4 -ADP and ATP A large number of experiments
in which Cl4 -ADP or ATP were incubated conditions
of time and presence or absence of the other
or triphosphates.
the perchloric
The total
acid insoluble
This is negligible
with the enzyme
pellet
radioactivity
incorporated
into
ranged from zero to 0.02 mumoles.
compared to the phosphorolysis
reaction.
Discussion: The enzyme preparation P32-Pi into
nucleoside
not synthesize similar,
diphosphates,
polynucleotide
has been obtained
Alternatively
our preparation
phosphorylase-like tissues
described,
catalyzes
but under our conditions,
1963 and Hilmoe and Heppel,
of does
from C14-ADP. An enzyme, which may be from yeast (Grunberg-Manago, could be related
enzymes previously
(Brummond et al.,
incorporation
described
1957; Kessler
1963).
to the polynucleotide in plant
and animal
and Chen, 1964; Harris,
1957).
References: Anonymous, Pabst Laboratories, Circular OR. 10 (1956). Bruannond, D. O.,Staehelin,M.,and Ochoa,S.,J.Biol.Chem.,~,835(1957). Grunberg-Manago, M., Progr. Nucleic Acid Res., 1, 93 (1963). Harris, H., Proc. Royal Sot. (London) Ser. B, 158, 79 (1963). Hilmoe, R. J., and Heppel, L.A., J. Am. Chem. Sot., 79, 4810 (1957). Kessler, B. and Chen, D., Biochim. Biophys. Acta, 80, 533 (1964). 516