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Phosphorylation of alkaline phosphatase (E. coli) with o- and p-nitrophenyl phosphate at ph <6
Vol. 28, No. 3, 1967
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
PHOSPHORYLATION OF ALKALINE PHOSPHATASE (E. coli) WITH o- AND p-NITROPHENYLPHOSPHATE AT pH ~6~ Wilmer K. Fife2 James Bryant Conant Laboratory Harvard University Cambridge, Massachusetts Received May 2, 1967 The phosphorylation
of alkaline
phate and glucose-6-phosphate
phosphatase
(E. coli)
has been studied
by several
1961, 1962; Schwartz and Lipmann, 1961; Levinthal Aldridge ever,
et al.,
1964; Pigretti
did not permit
phosphorylating number of active behavior
direct
sites
workers
These experiments,
of the reaction an accurate
on the enzyme nor a clear
(Engstrom,
1962; Schwartz,
et al.,
1965).
phos-
196 3; how-
between enzyme and determination
understanding
of the
of enzyme
in acid media.
phosylation
the preliminary
of alkaline
of lo+
determining
process.
in which phosphosphate3 at pH
methods.
This technique sites
At enzyme con-
amounts of nitrophenol
enzyme during a very rapid reaction
the number of active the interaction
of experiments
by spectrophotometric
to 10m5 g detectable
along with phosphorylated the steady-state
results
phosphatase by o- and p-nitrophenyl
was observed directly
centrations
tatively
observation
agent nor did they provide
This paper reports
3.9-5.7
and Milstein,
by inorganic
provides
are produced which precedes
an excellent
means of
on the enzyme and of studying
between inorganic
quanti-
phosphate and enzyme.
lThis work was supported by a research grant to Prof. the U. S. Public Health Service (GM04712).
F. H. Westheimer from
*National Institutes of Health Special Post-Doctoral Fellow (l-F3-GM-23,392-01) on leave from Muskingum College, New Concord, Ohio, 1965-66. 3Abbreviations:
o-NPP - Disodium o-nitrophenyl p-NPP - Disodium p-nitrophenyl
309
phosphate, phosphate.
Vol. 28, No. 3, 1967
BIOCHEMICAL AND BIOPHYSICAL
The data suggest but do not establish (1)
Alkaline
phosphatase
per dimeric (2)
unit
the following
(E. coli)
contains
conclusions:
two principal
active
sites
(M.W. 86,000).
The number of active
sites
dent of pH (3.9-5.7),
determined
but it
(o-NPP or p-NPP) and/or sites
RESEARCH COMMUNICATIONS
experimentally
is indepen-
is somewhat dependent on substrate
substrate
concentration.
(The number of
found was 1.7 * 0.1 at [o-NPP] = 5 X 10D5- 2 X 10q4 Fi,
[p-NPP 1 - 2 x 10-B & and 2.7 * 0.3 at [o-NPP] = 2 X 10m3 F&) (3)
During preincubation phosphate
blocks one of the two active
by substrate (4)
with enzyme at pH 4.65 (25' C), inorganic
but does not affect
Phosphorylated
sites
to phosphorylation
enzymic activity.
enzyme is more stable
than native
enzyme in acidic
media.
Exnerimental Materials tally
-- Alkaline
pure from Worthington
saturated
ammonium sulfate
by centrifugation 8.05,
months.
solution.
from a central
All other
metal ions,
(10-6-10-2B
substrate
chromatographi-
as a slurry
buffer
with 0.65 from the slurry (0.05 &, pH
which remained stable
for
phosphate was purchased from Sigma phosphate was prepared by the method
reagents
were "Reagent Grade" materials
by the manufacturer.
The distilled
supply and was shown to be free
of
water was
extraneous
effects
etc.).
Assay Procedure -- Aliquots pH 8.05),
stock solutions
Disodium o-nitrophenyl
and they were used as supplied
(adventitious
Corporation
in N-ethylmorpholine-HCl
to obtain
of Bessey and Love (1962).
was obtained
The enzyme was separated
Disodium p-nitrophenyl
Chemical Company.
obtained
(E. coli)
Biochemicals
and dissolved
u = 0.1 g [NaCl])
several
phosphatase
(10-5-10-3
of stock solutions
of enzyme (10-6-10-5
MJ, and in some experiments
were added to cuvettes
sodium phosphate
(1 cm. path) which contained
310
Ff,
sufficient
Vol. 28, No. 3, 1967
buffer4
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
to make 2.0 ml of reaction
pH 4.65 with or without substrate
inorganic
to complete the reaction
mixture.
When enzyme was preincubated
phosphate,
reaction
mixture.
In all
was initiated other
at
by adding
experiments
enzyme
was added last. The formation photometer.
of o- or pnitrophenol
was followed
(1 = 355 mn for o-nitrophenol
and 330 my for p-nitrophenol.)
Recording of absorbancy vs. time curves was started initiation (Figure
of reaction.
released
of nitrophenol
within
5-6 seconds after
of the absorbancy vs. time curves
1) to zero time gave absorbancy values
of nitrophenol centration
Extrapolation
with a Cary 15 spectro-
in an "instantaneous
from which the concentration
burst"
was calculated.
The con-
in the burst is assumed to be equal to the concen-
0.162
0.08
40 Time
60
80
100
(Seconds)
phosFig. 1. Alkaline phosphatase catalyzed hydrolysis of o-nitrophenyl phate at pH 4.65. [Enzyme] = 4.55 X lo+ M, [o-NPP] = 5.25 X 10-S 5, temperature = 25.04 * 0.05“ C. 4The buffers were all 0.05 g and were adjusted to an ionic strength of O.lFJ with sodium chloride. Their pH ranges are given below: Potassium Biphthalate - Hydrochloric Acid, pH 3.7-3.9; Acetic Acid - Sodium Acetate, pH 4.1-5.0; - Sodium Hydroxide, pH 5.2-5.7. Potassium Biphthalate
311
Vol. 28, No. 3, 1967
tration
BIOCHEMICAL
of active
activity5
sites
on the enzyme (Hartley
was determined
which remained linear
AND BIOPHYSICAL
to 100X reaction
Results A study of the effect phate on phosphorylation
in nearly
on substrate
cases.
concentration,
phosphatase
in this
of nitrophenol
all
The reaction
section,
burst)
(Figure
pH, and inorganic
(E. coli)
Both concentration
three active
sites
that
obtained
appear to depend
2). 6 The data obtained
with p-NPP can be
tive
studies
its
saturation
Although
the burst
concentrations.
with high concentrations
strong absorption
centration
(2 X 10m3 9
(2.7 f 0.3) and enzymic activity
at lower substrate
is puzzling,
it
increase
Unfortunately,
determined
of absorbancy vs. time curves and S is the substrate
The burst enzymic activity
earlier
increases
corroboraout due to
substrate relationship
conbe-
from the slopes
concentration)
by Heppel et al.
appears to be independent
than
pH 4.65).
with the biphasic velocity
Hownearly
higher
in burst with increasing
is consistent
work (pH ~6) and reported
data require
of p-NPP cannot be carried
tween V and V/S (where V is the reaction
this
phenomenon,
x10-3 M).
is clearly
at 330 mu (E 2 4 X 103r1cm-1,
the continued
of active
and enzymic activity
on the basis of the usual enzyme-substrate
at high 0-NPP concentrations
phos-
by o-NPP and PNPP
The same case can be made for some of the o-NPP data ([o-NPP] ever,
Enzymic
and Discussion
of alkaline
concentration
interpreted
1954).
at pH ~6.
of substrate
is summarized and discussed (magnitude
and Kilby,
from the slopes of the absorbancy vs. time curves
appears to be zero order in substrate
sites
RESEARCH COMMUNICATIONS
found in
(1962) (pH >7).
of pH over the range 3.9 to 5.7 and
smoothly with pH as expected
(Figure
3).
The low
'Enzymic activity is defined as the Slope of Absorbancy vs. Time Curve for NPP Hydrolysis divided by Enzyme Concentration (~-1 sec.-l). 6A good linear relationship between enzyme concentration and burst or enzymic activity was obtained with oNPP (1 X 10m3 MJ and p-NPP (1 X 10m4 @.
312
Vol. 28, No. 3, 1967
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
::h 800 2 $j 600 -4 400
4
2
6
[Substrate]
10
8
X lo4 (MJ
Fig. 2. Effect of substrate concentration on number of active sites ([Nitrophenol] in Burst/IEnzyme]) and enzymic activity (Slope of Absorbancy vs. Time Curve/[Enzyme)). [Enzyme] = 2-10 X low6 kl, pH = 4.68 * 0.05, Temperature = 25.04 * 0.05' C, Substrate: a-o-NPP, A-p-NPP. value
(1.6)
for the number of active
value for the difference It is interesting
that
somewhat from that
sites
extinction
at pH 5.7 is probably
coefficient
(E [o-NPPJ -E [o-nitrophenol]).
the pH dependence of o-NPP hydrolysis
phatase was studied
between phosphate ion and alkaline
by preincubating
in Figures 4 and 5.
lel
one another
active
sites
destruction
In the absence of inorganic
and loss of ensymic activity (Figure
4).
is decreasing of active
1965; Schlesinger,
sites
with increasing
This means that with time,
phos-
the enzyme at pH 4.65 for various
of time in the presence and absence of phosphate ion.
in burst
seems to differ
of p-NPP.
The nature of the interaction
trated
due to a poor
The results phosphate, preincubation
the concentration
are
lengths illus-
the decrease time paral-
of enzymic
a consequence which can be attributed
by acid (Schwartz,
1965).
313
1963; Pigrette
and Milstein,
to
Vol. 28, No. 3, 1967
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
1600
800
2.4 2.0 1.6 4.0
4.4
4.8
5.2
5.6
pH Dependence of Enzymic Activity (Slope of Absorbancy vs . Time Curve/[Enzyme]) and Number of Active Sites ([Nitrophenol] in Burst/[Enzyme]). [Enzyme] - 5 X 10m6 kI, Temperature - 25.04 * 0.05' C, Substrate: q -o-NPP-1.05 x 10-s M, A-p-~~~-2.02 x 1O-4 g.
8
16 Preincubation
24
32
40
Time (Min.)
of Enzyme at pH 4.65 in the Presence and Fig. 4. Effect of Preincubation [Enzyme] = 5 X lO%, Temperature = 25.04 f 0.05' C, Absence of Phosphate Ion. Substrate: p-NPP; 1.05 X low4 JJ. q [HPO,, = ] = 100 [Enzyme] 0 5 X 10B4 M; n [HP04 = I = 0.
314
Vol. 28, No. 3, 1967
h d” R u 2
8lOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
800 700 600
Fig. 5. Effect of Preincubation of Enzyme at pH 4.65 in the Presence and Absence of Phosphate Ion. [Enzyme] = 5 X 10s6 P-l, Temperature = 25.04 * APreincubation 0.05' C, Substrate: p-NPP, 1.05 X 10e4 a. q No Preincubation; Time = 5 min. Preincubation inorganic
of enzyme at pH 4.65 in the presence of a large excess of
phosphate
between the burst proximately
([IWO,, = ]/[Enzyme] and activity
one-half
the reference
somewhat the same fashion Enzymic activity, linearly dently (1963), sites
however, exhibits time.
enzyme against
value of 2 sites
falls
off
difference
rapidly
to ap-
(?) and then decreases in
containing
no phosphate.
no sudden drop but decreases slowly and The presence of inorganic
acid denaturation
as cited
phosphate
earlier
evi-
by Schwartz
but at the same time it causes a decrease in the number of active available
for instantaneous
sistent
with the observations
et aZ.,
(1962);
alkaline
The burst
as in the experiments
with preincubation protects
behavior.
= 100) produces a striking
phosphorylation.
These results
are con-
of Schwartz and Lipmann (1961) and Levinthal
namely, that only one phosphate ion was found attached
phosphatase
in experiments
with P32 labelled
315
inorganic
to
phosphate
Vol. 28, No. 3, 1967
BIOCHEMICAL AND BIOPHYSICAL
but the enzyme was shown to have two sites brium dialysis
of inorganic
for one preincubation
at [HP04 = ]/[Enzyme] phate the burst
[HPO,, = ]/[Enzyme] = 10.
mixtures
An increase
that
ratio
one-half
in inorganic
by phosphate
tion of phosphate tion
Although
phorylated behavior
at least
in acid media.
phosphate,
a potent
Levinthal,
1960),
hydrolyzed
described
two active
reached a plateau with inorganic
phos-
when enzyme was added
relative
to that
These results
ion is slow compared to
is noteworthy
that
combina-
compared to the acid denaturaenzyme against
above suggest that
sites
acid de-
solution
at the same rate. approximately
If this
phosphos-
aspects of enzymic
is the fact (Torriani,
the enzyme at pH <6.
for by making dephosphorylation process.
several
troublesome
in alkaline
does not inhibit
alkaline
of which one is rapidly
to clarify
Not the least
inhibitor
step in the hydrolysis hydrolyze
increased
4).
in acid media, they fail
be accounted
However, it
phosphate protects
the experiments
phatase contains
it
decrease in burst.
ion with enzyme must be fast
(Figure
was displayed
concentration
of enzyme by phosphate
process because inorganic
naturation
until
The
the same amount of inorganic
phosphate
ester.
way.
The activity
that obtained
which contained
phosphorylation
phosphorylation
5).
ratio
When enzyme was preincubated
was approximately
to reaction
(Figure
of enzyme produced a small but noticeable indicate
in equili-
in another
on [HPO,, = ]/[Enzyme]
time (5 minutes)
with increasing
phosphate.
phosphate
phosphate was illustrated
dependence of burst and activity
directly
for binding
studies.
The effect
sharply
RESEARCH COMMUNICATIONS
that
inorganic
1960; Garen and
This result
cannot
of the enzyme the rate-limiting
were the case, o-NPP and p-NPP should
The data (Figure
2) indicate
that p-NPP is
twice as fast as o-NPP at pH 4.65.
AcknowledPement The author is deeply indebted to Professor F. H. Westheimer for his numerous contributions to the development of this study.
316
Vol. 28, No. 3, 1967
BIOCHEMICAL AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
References Aldridge, W. N., Barman, T. E., and Gutfreund, Ii., Biochem. J., 92, 23C (1964) Bessey, 0. A., and Love, R. H., J. Biol. Chem., 196, 175 (1952). Engstrom, L., Biochim. Biophys. Acta, 52, 49 (1961); 55, 179 (1961); 56, 606 (1962). Engstrom, L., Ark. Kemi, l9, 129 (1962). Garen, A., and Levinthal, C., Biochim. Biophys. Acta, 2, 470 (1960). Hartley, B. S., and Kilby, E. A., Biochem. J., 56, 288 (1954). Heppel, L. A., Harkness, D. R., and Hilmore, R. J., J. Biol. Chem. Levinthal, C., Singer, E. R., and Fetherolf, K., Proc. Nat. Acad. Sci., 48, 1230 (1962). Pigretti, M. M., and Milstein, C., Biochem. J., 94, 106 (1965). Schlesinger, M. J., Subunit Structure of Proteins Biochemical and Genetic Aspects, Brookhaven Symposia in Biology: No. 17 (1964), pp. 70. Schlesinger, M. J., and Barrett, K. J., J. Biol. Chem., 240, 4284 (1965). Schwartz, J. H., Proc. Nat. Acad. Sci., 49, 872 (1963). Schwartz, J. H., and Lipmann, F., Proc. Nat. Acad. Sci., 47, 1996 (1961). Torriani, A., Biochim. Biophys. Acta, 38, 460 (1960).
317
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
PHOSPHORYLATION OF ALKALINE PHOSPHATASE (E. coli) WITH o- AND p-NITROPHENYLPHOSPHATE AT pH ~6~ Wilmer K. Fife2 James Bryant Conant Laboratory Harvard University Cambridge, Massachusetts Received May 2, 1967 The phosphorylation
of alkaline
phate and glucose-6-phosphate
phosphatase
(E. coli)
has been studied
by several
1961, 1962; Schwartz and Lipmann, 1961; Levinthal Aldridge ever,
et al.,
1964; Pigretti
did not permit
phosphorylating number of active behavior
direct
sites
workers
These experiments,
of the reaction an accurate
on the enzyme nor a clear
(Engstrom,
1962; Schwartz,
et al.,
1965).
phos-
196 3; how-
between enzyme and determination
understanding
of the
of enzyme
in acid media.
phosylation
the preliminary
of alkaline
of lo+
determining
process.
in which phosphosphate3 at pH
methods.
This technique sites
At enzyme con-
amounts of nitrophenol
enzyme during a very rapid reaction
the number of active the interaction
of experiments
by spectrophotometric
to 10m5 g detectable
along with phosphorylated the steady-state
results
phosphatase by o- and p-nitrophenyl
was observed directly
centrations
tatively
observation
agent nor did they provide
This paper reports
3.9-5.7
and Milstein,
by inorganic
provides
are produced which precedes
an excellent
means of
on the enzyme and of studying
between inorganic
quanti-
phosphate and enzyme.
lThis work was supported by a research grant to Prof. the U. S. Public Health Service (GM04712).
F. H. Westheimer from
*National Institutes of Health Special Post-Doctoral Fellow (l-F3-GM-23,392-01) on leave from Muskingum College, New Concord, Ohio, 1965-66. 3Abbreviations:
o-NPP - Disodium o-nitrophenyl p-NPP - Disodium p-nitrophenyl
309
phosphate, phosphate.
Vol. 28, No. 3, 1967
BIOCHEMICAL AND BIOPHYSICAL
The data suggest but do not establish (1)
Alkaline
phosphatase
per dimeric (2)
unit
the following
(E. coli)
contains
conclusions:
two principal
active
sites
(M.W. 86,000).
The number of active
sites
dent of pH (3.9-5.7),
determined
but it
(o-NPP or p-NPP) and/or sites
RESEARCH COMMUNICATIONS
experimentally
is indepen-
is somewhat dependent on substrate
substrate
concentration.
(The number of
found was 1.7 * 0.1 at [o-NPP] = 5 X 10D5- 2 X 10q4 Fi,
[p-NPP 1 - 2 x 10-B & and 2.7 * 0.3 at [o-NPP] = 2 X 10m3 F&) (3)
During preincubation phosphate
blocks one of the two active
by substrate (4)
with enzyme at pH 4.65 (25' C), inorganic
but does not affect
Phosphorylated
sites
to phosphorylation
enzymic activity.
enzyme is more stable
than native
enzyme in acidic
media.
Exnerimental Materials tally
-- Alkaline
pure from Worthington
saturated
ammonium sulfate
by centrifugation 8.05,
months.
solution.
from a central
All other
metal ions,
(10-6-10-2B
substrate
chromatographi-
as a slurry
buffer
with 0.65 from the slurry (0.05 &, pH
which remained stable
for
phosphate was purchased from Sigma phosphate was prepared by the method
reagents
were "Reagent Grade" materials
by the manufacturer.
The distilled
supply and was shown to be free
of
water was
extraneous
effects
etc.).
Assay Procedure -- Aliquots pH 8.05),
stock solutions
Disodium o-nitrophenyl
and they were used as supplied
(adventitious
Corporation
in N-ethylmorpholine-HCl
to obtain
of Bessey and Love (1962).
was obtained
The enzyme was separated
Disodium p-nitrophenyl
Chemical Company.
obtained
(E. coli)
Biochemicals
and dissolved
u = 0.1 g [NaCl])
several
phosphatase
(10-5-10-3
of stock solutions
of enzyme (10-6-10-5
MJ, and in some experiments
were added to cuvettes
sodium phosphate
(1 cm. path) which contained
310
Ff,
sufficient
Vol. 28, No. 3, 1967
buffer4
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
to make 2.0 ml of reaction
pH 4.65 with or without substrate
inorganic
to complete the reaction
mixture.
When enzyme was preincubated
phosphate,
reaction
mixture.
In all
was initiated other
at
by adding
experiments
enzyme
was added last. The formation photometer.
of o- or pnitrophenol
was followed
(1 = 355 mn for o-nitrophenol
and 330 my for p-nitrophenol.)
Recording of absorbancy vs. time curves was started initiation (Figure
of reaction.
released
of nitrophenol
within
5-6 seconds after
of the absorbancy vs. time curves
1) to zero time gave absorbancy values
of nitrophenol centration
Extrapolation
with a Cary 15 spectro-
in an "instantaneous
from which the concentration
burst"
was calculated.
The con-
in the burst is assumed to be equal to the concen-
0.162
0.08
40 Time
60
80
100
(Seconds)
phosFig. 1. Alkaline phosphatase catalyzed hydrolysis of o-nitrophenyl phate at pH 4.65. [Enzyme] = 4.55 X lo+ M, [o-NPP] = 5.25 X 10-S 5, temperature = 25.04 * 0.05“ C. 4The buffers were all 0.05 g and were adjusted to an ionic strength of O.lFJ with sodium chloride. Their pH ranges are given below: Potassium Biphthalate - Hydrochloric Acid, pH 3.7-3.9; Acetic Acid - Sodium Acetate, pH 4.1-5.0; - Sodium Hydroxide, pH 5.2-5.7. Potassium Biphthalate
311
Vol. 28, No. 3, 1967
tration
BIOCHEMICAL
of active
activity5
sites
on the enzyme (Hartley
was determined
which remained linear
AND BIOPHYSICAL
to 100X reaction
Results A study of the effect phate on phosphorylation
in nearly
on substrate
cases.
concentration,
phosphatase
in this
of nitrophenol
all
The reaction
section,
burst)
(Figure
pH, and inorganic
(E. coli)
Both concentration
three active
sites
that
obtained
appear to depend
2). 6 The data obtained
with p-NPP can be
tive
studies
its
saturation
Although
the burst
concentrations.
with high concentrations
strong absorption
centration
(2 X 10m3 9
(2.7 f 0.3) and enzymic activity
at lower substrate
is puzzling,
it
increase
Unfortunately,
determined
of absorbancy vs. time curves and S is the substrate
The burst enzymic activity
earlier
increases
corroboraout due to
substrate relationship
conbe-
from the slopes
concentration)
by Heppel et al.
appears to be independent
than
pH 4.65).
with the biphasic velocity
Hownearly
higher
in burst with increasing
is consistent
work (pH ~6) and reported
data require
of p-NPP cannot be carried
tween V and V/S (where V is the reaction
this
phenomenon,
x10-3 M).
is clearly
at 330 mu (E 2 4 X 103r1cm-1,
the continued
of active
and enzymic activity
on the basis of the usual enzyme-substrate
at high 0-NPP concentrations
phos-
by o-NPP and PNPP
The same case can be made for some of the o-NPP data ([o-NPP] ever,
Enzymic
and Discussion
of alkaline
concentration
interpreted
1954).
at pH ~6.
of substrate
is summarized and discussed (magnitude
and Kilby,
from the slopes of the absorbancy vs. time curves
appears to be zero order in substrate
sites
RESEARCH COMMUNICATIONS
found in
(1962) (pH >7).
of pH over the range 3.9 to 5.7 and
smoothly with pH as expected
(Figure
3).
The low
'Enzymic activity is defined as the Slope of Absorbancy vs. Time Curve for NPP Hydrolysis divided by Enzyme Concentration (~-1 sec.-l). 6A good linear relationship between enzyme concentration and burst or enzymic activity was obtained with oNPP (1 X 10m3 MJ and p-NPP (1 X 10m4 @.
312
Vol. 28, No. 3, 1967
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
::h 800 2 $j 600 -4 400
4
2
6
[Substrate]
10
8
X lo4 (MJ
Fig. 2. Effect of substrate concentration on number of active sites ([Nitrophenol] in Burst/IEnzyme]) and enzymic activity (Slope of Absorbancy vs. Time Curve/[Enzyme)). [Enzyme] = 2-10 X low6 kl, pH = 4.68 * 0.05, Temperature = 25.04 * 0.05' C, Substrate: a-o-NPP, A-p-NPP. value
(1.6)
for the number of active
value for the difference It is interesting
that
somewhat from that
sites
extinction
at pH 5.7 is probably
coefficient
(E [o-NPPJ -E [o-nitrophenol]).
the pH dependence of o-NPP hydrolysis
phatase was studied
between phosphate ion and alkaline
by preincubating
in Figures 4 and 5.
lel
one another
active
sites
destruction
In the absence of inorganic
and loss of ensymic activity (Figure
4).
is decreasing of active
1965; Schlesinger,
sites
with increasing
This means that with time,
phos-
the enzyme at pH 4.65 for various
of time in the presence and absence of phosphate ion.
in burst
seems to differ
of p-NPP.
The nature of the interaction
trated
due to a poor
The results phosphate, preincubation
the concentration
are
lengths illus-
the decrease time paral-
of enzymic
a consequence which can be attributed
by acid (Schwartz,
1965).
313
1963; Pigrette
and Milstein,
to
Vol. 28, No. 3, 1967
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
1600
800
2.4 2.0 1.6 4.0
4.4
4.8
5.2
5.6
pH Dependence of Enzymic Activity (Slope of Absorbancy vs . Time Curve/[Enzyme]) and Number of Active Sites ([Nitrophenol] in Burst/[Enzyme]). [Enzyme] - 5 X 10m6 kI, Temperature - 25.04 * 0.05' C, Substrate: q -o-NPP-1.05 x 10-s M, A-p-~~~-2.02 x 1O-4 g.
8
16 Preincubation
24
32
40
Time (Min.)
of Enzyme at pH 4.65 in the Presence and Fig. 4. Effect of Preincubation [Enzyme] = 5 X lO%, Temperature = 25.04 f 0.05' C, Absence of Phosphate Ion. Substrate: p-NPP; 1.05 X low4 JJ. q [HPO,, = ] = 100 [Enzyme] 0 5 X 10B4 M; n [HP04 = I = 0.
314
Vol. 28, No. 3, 1967
h d” R u 2
8lOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
800 700 600
Fig. 5. Effect of Preincubation of Enzyme at pH 4.65 in the Presence and Absence of Phosphate Ion. [Enzyme] = 5 X 10s6 P-l, Temperature = 25.04 * APreincubation 0.05' C, Substrate: p-NPP, 1.05 X 10e4 a. q No Preincubation; Time = 5 min. Preincubation inorganic
of enzyme at pH 4.65 in the presence of a large excess of
phosphate
between the burst proximately
([IWO,, = ]/[Enzyme] and activity
one-half
the reference
somewhat the same fashion Enzymic activity, linearly dently (1963), sites
however, exhibits time.
enzyme against
value of 2 sites
falls
off
difference
rapidly
to ap-
(?) and then decreases in
containing
no phosphate.
no sudden drop but decreases slowly and The presence of inorganic
acid denaturation
as cited
phosphate
earlier
evi-
by Schwartz
but at the same time it causes a decrease in the number of active available
for instantaneous
sistent
with the observations
et aZ.,
(1962);
alkaline
The burst
as in the experiments
with preincubation protects
behavior.
= 100) produces a striking
phosphorylation.
These results
are con-
of Schwartz and Lipmann (1961) and Levinthal
namely, that only one phosphate ion was found attached
phosphatase
in experiments
with P32 labelled
315
inorganic
to
phosphate
Vol. 28, No. 3, 1967
BIOCHEMICAL AND BIOPHYSICAL
but the enzyme was shown to have two sites brium dialysis
of inorganic
for one preincubation
at [HP04 = ]/[Enzyme] phate the burst
[HPO,, = ]/[Enzyme] = 10.
mixtures
An increase
that
ratio
one-half
in inorganic
by phosphate
tion of phosphate tion
Although
phorylated behavior
at least
in acid media.
phosphate,
a potent
Levinthal,
1960),
hydrolyzed
described
two active
reached a plateau with inorganic
phos-
when enzyme was added
relative
to that
These results
ion is slow compared to
is noteworthy
that
combina-
compared to the acid denaturaenzyme against
above suggest that
sites
acid de-
solution
at the same rate. approximately
If this
phosphos-
aspects of enzymic
is the fact (Torriani,
the enzyme at pH <6.
for by making dephosphorylation process.
several
troublesome
in alkaline
does not inhibit
alkaline
of which one is rapidly
to clarify
Not the least
inhibitor
step in the hydrolysis hydrolyze
increased
4).
in acid media, they fail
be accounted
However, it
phosphate protects
the experiments
phatase contains
it
decrease in burst.
ion with enzyme must be fast
(Figure
was displayed
concentration
of enzyme by phosphate
process because inorganic
naturation
until
The
the same amount of inorganic
phosphate
ester.
way.
The activity
that obtained
which contained
phosphorylation
phosphorylation
5).
ratio
When enzyme was preincubated
was approximately
to reaction
(Figure
of enzyme produced a small but noticeable indicate
in equili-
in another
on [HPO,, = ]/[Enzyme]
time (5 minutes)
with increasing
phosphate.
phosphate
phosphate was illustrated
dependence of burst and activity
directly
for binding
studies.
The effect
sharply
RESEARCH COMMUNICATIONS
that
inorganic
1960; Garen and
This result
cannot
of the enzyme the rate-limiting
were the case, o-NPP and p-NPP should
The data (Figure
2) indicate
that p-NPP is
twice as fast as o-NPP at pH 4.65.
AcknowledPement The author is deeply indebted to Professor F. H. Westheimer for his numerous contributions to the development of this study.
316
Vol. 28, No. 3, 1967
BIOCHEMICAL AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
References Aldridge, W. N., Barman, T. E., and Gutfreund, Ii., Biochem. J., 92, 23C (1964) Bessey, 0. A., and Love, R. H., J. Biol. Chem., 196, 175 (1952). Engstrom, L., Biochim. Biophys. Acta, 52, 49 (1961); 55, 179 (1961); 56, 606 (1962). Engstrom, L., Ark. Kemi, l9, 129 (1962). Garen, A., and Levinthal, C., Biochim. Biophys. Acta, 2, 470 (1960). Hartley, B. S., and Kilby, E. A., Biochem. J., 56, 288 (1954). Heppel, L. A., Harkness, D. R., and Hilmore, R. J., J. Biol. Chem. Levinthal, C., Singer, E. R., and Fetherolf, K., Proc. Nat. Acad. Sci., 48, 1230 (1962). Pigretti, M. M., and Milstein, C., Biochem. J., 94, 106 (1965). Schlesinger, M. J., Subunit Structure of Proteins Biochemical and Genetic Aspects, Brookhaven Symposia in Biology: No. 17 (1964), pp. 70. Schlesinger, M. J., and Barrett, K. J., J. Biol. Chem., 240, 4284 (1965). Schwartz, J. H., Proc. Nat. Acad. Sci., 49, 872 (1963). Schwartz, J. H., and Lipmann, F., Proc. Nat. Acad. Sci., 47, 1996 (1961). Torriani, A., Biochim. Biophys. Acta, 38, 460 (1960).
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