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Reversible dissociation of zinc in bovine carbonic anhydrase
Vol.‘2, No. 3 BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REVERSIBLE
DISSOCIATION
OF ZINC IN BOVINE CARBONIC ANHYDRASE
Sven Lindskog Institute
March 1960
and Bo G. Malmstrijm
of Biochemistry, Uppsala,
University Sweden
of Uppsala,
Received February 24, 1960 Keilin
and Mann (1940)
(CA) is a zinc rious
laboratories
ters,
1959)
mogeneous
varies
but recent
since
Zn at neutral
Watts
and Wormall,
sible
on destruction
ters,
1959).
within
reversibly
chelating
agents,
of the protein
at
remove
it
(Tupper,
has only
possible
been posand Pe-
to dissociate
enzyme at pH 5 in the presence
a loss
it
radioac-
low pH (see Keller
now found
of
attached
with
of a month
such as l,lO-phenanthroline
by addition
presence
is firmly
is no exchange
of the metal
from the
the
and Peon a ho-
does not
1951).
however,
1960)
The metal
a period
of Zn causes
regained
(Lindskog,
pH even during Removal
from va-
(see Keller
electrodialysis
and there
anhydrase
reported
has revealed
of enzyme.
1941),
carbonic
a wide range work
extensive
We have,
the metal
be fully
content
of the protein
and Mendive,
The removal
The zinc
analytical
preparation
to the protein
tive
that
metalloenzyme.
one atom of Zn per molecule
(Scott
demonstrated
of
(OP) or citrate.
of activity,
which,
however,
can
of Zn. Experimental
Bovine skog
(1960).
by dialysis zinc
erythrocyte The protein
against
(see Lindskog,
the calorimetric
CA was prepared was freed
OP at neutral 1960).
procedure
by the method
of extraneous pH, which
The enzyme activity described 213
previously
metals
causes
of Lind(CU, Fe)
no loss
was estimated (Lindskog,
of by 1960)
Vol. 2, No. 3 BIOCHEMICAL
except
that
of Beers
a two-channel
que used for
stopped-flow
was employed.
(1956),
scribed
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
.exchange
(Malmstrom,
estimated
with
the Y-ray
activity
1953).
scintillation
tions
of known concentration,
stock
solution
prepared
The loss of activity 4O against
in
Fig.
acetate 1. At given
activity in
solution
Since
cent of
2.10 -3 fi,
as the control added
metal
cannot
could
In
to the
to reactivate
the
removal
the
addition,
taking ments, enzyme,
against
when standing buffer
without
in a final
inactivated
metal
containing
to the same activity (Co +2 , Ni +2,
ions
enzyme under
of OP, acting
concentration
CA samples
reactivated
as per
the
Cd+2)
same conditions,
as an inhibitor,
by the
be involved. loss
of activity
be due to factors
direct
slowly
and the CA
have been expressed
cases Other
is a strong
give
activity
When Zn++,
at
10 -3 3 OP is shown
were removed
dialysis
1).
a simple
While
tion
(Fig.
failed
so that
CA loses
enzyme was in all
same
of CA is dialyzed
aliquots
activity.
was added
of the
experiments.
containing
and the activities
of the control
OP, the
pH 5.0,
at pH 5, a control
OP was included,
of Ln 65 solu-
and Discussion
intervals,
measured.
by comparing
a series
when a solution
buffer,
of in 65 was
by dilution
the exchange
Results
has been de-
(Baird-Atomic) with
to that techni-
The concentration
samples
as used in
dialysis
measurements
counter
of l-ml.
similar
The equilibrium
the radioactive
earlier
apparatus,
March 1960
evidence
place
in
extraneous details
other
indication
exchange
in the than that
studies that
removal
a loss
of chelating
Zn 65 was added of concentrations
of Zn,
removal
is involved. in Table
I,
of the metal is
agents.
given
described
the reactiva-
of the metal
to exchange being
214
just
Zn 65 , summarized
with
a reversible
the presence
experiment
with
In these
experi-
the Zn in the
in the table.
An
Vol. 2, No. 3 BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
70 time
Dialysis
Fig. 1. Loss and regain of CA activity OP. Three ml. of a 0.07 $ CA solution
March 1960
20 (dcrys) during dialyzed
dialysis against at 4' against
100 ml. of 0.05 i acetate buffer, pH 5.0, containing 10 -3 -M OP, with change of dialysis liquid every 24 hrs. The lower curve (dialyzed): activity as a function of dialysis time. The upper curve (reactivated): activity after addition of Zn ++ in a final concentration of 2*10e3 -'M
uptake
of radioactive
compartments
Zn was observed
of the dialysis
about 2 weeks while The concentrations the radioactivity corrected However,
for
dialysis
cells.
given
of the extraneous dilution
Zn analyses
thus demonstrating
This
equilibrium
at equilibrium
in the protein-containing uptake
is established
exchange,
in 48 brs.
Zn added and are thus not
such a dilution
and a correction 215
for
in Table I are based on
from the non-radioactive showed that
continued
Zn in the enzyme. had taken
place,
has been applied
Vol. 2, No. 3 BIOCHEMICAL
in calculating of enzyme; neous
the average a complete
albumin
proteins
of varying
complex;
(metalloenzyme), could
tidase
zinc
be detected
1953)
under
to albumin
with
(1958).
equilibrium
was established
namely
and enolase very
1952),
as fast
while
serum enolase
No bin-
carboxypep-
similar
to that
of Vallee,
in contrast
Table
bovine
the same conditions.
of binding
However,
to a number
and carboxypeptidase
the observations
and Neurath
and extra-
Zn++ binding
affinity,
Malmstrdm,
(CP) showed a degree
intrinsic
Gurd and Goodman,
was measured
CA, in accordance
between
binding;
March 1960
(0) of Zn++ bound per molecule
For comparison,
(non-specific
(metal-enzyme
number
equilibration
Zn was assumed.
of other
ding
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Rupley,
to the case with
as the
of
dialysis
Coombs CA,
equilibrium.
I
Equilibrium dialysis of CA In the presence of chelating agents at pH 5.0 and 4'
Dialysis
medium
0.1 5 nitrate buffer, 1 M NaCl 0.05 E acetate buffer, 2.5010 -4 E OP
The experiments conditions,
Enzyme cont. (molar)
of the metal
versible
dissociation
3
10.10'5
5.5.10-5
2.5.10~~
0.68
6.g.10-5
9.4.10-5
7.2-10~~
0.45
described
demonstrate
Zn can be reversibly
removal
Extraneous Ln'+ cont. (molar) Protein Non-protein camp. cow
results
that,
dissociated in a loss
216
from
of activity.
of Zn in a metalloenzyme
under
certain
CA, and that Such a re-
has previously
Vol. 2, No. 3 BIOCHEMICAL
been accomplished ding
strength
appears
by Vallee in the
in the rate
of various
than
very
The studies
with
March 1960
CP. While
similar,
the bin-
the Zn++ in CP
in CA, as evidenced
of equilibration
chelating
published
(1958)
--et al.
two enzymesis
more “available”
rences
and in the
by the diffeinhibiting
effects
agents. are being
extended
and a complete
report
will
be
elsewhere.
This Swedish tutes
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
investigation
has been supported
Natural
Science
of Health,
U.S.
Research Public
by grants
Council
Health
from
the
and the National
Service
Insti-
(RG-6542).
References Beers,
R.F.,
Gurd,
F.R.N.,
(1952
1
Jr.,
Biochem.
and Goodman,
D.,
and Mann,
Keller,
H.,
and Peters,
S.,
Malmstrijm,
T.,
J. Am. Chem. Sot.,
Biochem. U.H.,
Biochim.
B.G.,
Scott,
D.A.,
Tupper,
R.,
Vallee,
D.S.,
492 (1956). 74,
670
J.,
34,
1163 (1940).
Hoppe-Seyler's
Z. physiol.
Chem.,
228 (1959).
Lindskog,
429
62,
l
Keilin,
317,
J.,
Arch.
Biophys.
Acta,
Biochem.
and Biophys.,
and Mendive, Watts,
(1951)
B.L.,
Chem. Sot.,
J.R.,
in press
J. Biol.
and Wormall,
R.W.E.,
5,
Chem., A.,
(1960). 345 (1953). I&,
Biochem.
445 (1941). J.,
50,
l
Rupley, -80,
J. A., 4750
Coombs,
(1958).
217
T.L.,
and Neurath,
H.,
J. Am.
REVERSIBLE
DISSOCIATION
OF ZINC IN BOVINE CARBONIC ANHYDRASE
Sven Lindskog Institute
March 1960
and Bo G. Malmstrijm
of Biochemistry, Uppsala,
University Sweden
of Uppsala,
Received February 24, 1960 Keilin
and Mann (1940)
(CA) is a zinc rious
laboratories
ters,
1959)
mogeneous
varies
but recent
since
Zn at neutral
Watts
and Wormall,
sible
on destruction
ters,
1959).
within
reversibly
chelating
agents,
of the protein
at
remove
it
(Tupper,
has only
possible
been posand Pe-
to dissociate
enzyme at pH 5 in the presence
a loss
it
radioac-
low pH (see Keller
now found
of
attached
with
of a month
such as l,lO-phenanthroline
by addition
presence
is firmly
is no exchange
of the metal
from the
the
and Peon a ho-
does not
1951).
however,
1960)
The metal
a period
of Zn causes
regained
(Lindskog,
pH even during Removal
from va-
(see Keller
electrodialysis
and there
anhydrase
reported
has revealed
of enzyme.
1941),
carbonic
a wide range work
extensive
We have,
the metal
be fully
content
of the protein
and Mendive,
The removal
The zinc
analytical
preparation
to the protein
tive
that
metalloenzyme.
one atom of Zn per molecule
(Scott
demonstrated
of
(OP) or citrate.
of activity,
which,
however,
can
of Zn. Experimental
Bovine skog
(1960).
by dialysis zinc
erythrocyte The protein
against
(see Lindskog,
the calorimetric
CA was prepared was freed
OP at neutral 1960).
procedure
by the method
of extraneous pH, which
The enzyme activity described 213
previously
metals
causes
of Lind(CU, Fe)
no loss
was estimated (Lindskog,
of by 1960)
Vol. 2, No. 3 BIOCHEMICAL
except
that
of Beers
a two-channel
que used for
stopped-flow
was employed.
(1956),
scribed
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
.exchange
(Malmstrom,
estimated
with
the Y-ray
activity
1953).
scintillation
tions
of known concentration,
stock
solution
prepared
The loss of activity 4O against
in
Fig.
acetate 1. At given
activity in
solution
Since
cent of
2.10 -3 fi,
as the control added
metal
cannot
could
In
to the
to reactivate
the
removal
the
addition,
taking ments, enzyme,
against
when standing buffer
without
in a final
inactivated
metal
containing
to the same activity (Co +2 , Ni +2,
ions
enzyme under
of OP, acting
concentration
CA samples
reactivated
as per
the
Cd+2)
same conditions,
as an inhibitor,
by the
be involved. loss
of activity
be due to factors
direct
slowly
and the CA
have been expressed
cases Other
is a strong
give
activity
When Zn++,
at
10 -3 3 OP is shown
were removed
dialysis
1).
a simple
While
tion
(Fig.
failed
so that
CA loses
enzyme was in all
same
of CA is dialyzed
aliquots
activity.
was added
of the
experiments.
containing
and the activities
of the control
OP, the
pH 5.0,
at pH 5, a control
OP was included,
of Ln 65 solu-
and Discussion
intervals,
measured.
by comparing
a series
when a solution
buffer,
of in 65 was
by dilution
the exchange
Results
has been de-
(Baird-Atomic) with
to that techni-
The concentration
samples
as used in
dialysis
measurements
counter
of l-ml.
similar
The equilibrium
the radioactive
earlier
apparatus,
March 1960
evidence
place
in
extraneous details
other
indication
exchange
in the than that
studies that
removal
a loss
of chelating
Zn 65 was added of concentrations
of Zn,
removal
is involved. in Table
I,
of the metal is
agents.
given
described
the reactiva-
of the metal
to exchange being
214
just
Zn 65 , summarized
with
a reversible
the presence
experiment
with
In these
experi-
the Zn in the
in the table.
An
Vol. 2, No. 3 BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
70 time
Dialysis
Fig. 1. Loss and regain of CA activity OP. Three ml. of a 0.07 $ CA solution
March 1960
20 (dcrys) during dialyzed
dialysis against at 4' against
100 ml. of 0.05 i acetate buffer, pH 5.0, containing 10 -3 -M OP, with change of dialysis liquid every 24 hrs. The lower curve (dialyzed): activity as a function of dialysis time. The upper curve (reactivated): activity after addition of Zn ++ in a final concentration of 2*10e3 -'M
uptake
of radioactive
compartments
Zn was observed
of the dialysis
about 2 weeks while The concentrations the radioactivity corrected However,
for
dialysis
cells.
given
of the extraneous dilution
Zn analyses
thus demonstrating
This
equilibrium
at equilibrium
in the protein-containing uptake
is established
exchange,
in 48 brs.
Zn added and are thus not
such a dilution
and a correction 215
for
in Table I are based on
from the non-radioactive showed that
continued
Zn in the enzyme. had taken
place,
has been applied
Vol. 2, No. 3 BIOCHEMICAL
in calculating of enzyme; neous
the average a complete
albumin
proteins
of varying
complex;
(metalloenzyme), could
tidase
zinc
be detected
1953)
under
to albumin
with
(1958).
equilibrium
was established
namely
and enolase very
1952),
as fast
while
serum enolase
No bin-
carboxypep-
similar
to that
of Vallee,
in contrast
Table
bovine
the same conditions.
of binding
However,
to a number
and carboxypeptidase
the observations
and Neurath
and extra-
Zn++ binding
affinity,
Malmstrdm,
(CP) showed a degree
intrinsic
Gurd and Goodman,
was measured
CA, in accordance
between
binding;
March 1960
(0) of Zn++ bound per molecule
For comparison,
(non-specific
(metal-enzyme
number
equilibration
Zn was assumed.
of other
ding
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Rupley,
to the case with
as the
of
dialysis
Coombs CA,
equilibrium.
I
Equilibrium dialysis of CA In the presence of chelating agents at pH 5.0 and 4'
Dialysis
medium
0.1 5 nitrate buffer, 1 M NaCl 0.05 E acetate buffer, 2.5010 -4 E OP
The experiments conditions,
Enzyme cont. (molar)
of the metal
versible
dissociation
3
10.10'5
5.5.10-5
2.5.10~~
0.68
6.g.10-5
9.4.10-5
7.2-10~~
0.45
described
demonstrate
Zn can be reversibly
removal
Extraneous Ln'+ cont. (molar) Protein Non-protein camp. cow
results
that,
dissociated in a loss
216
from
of activity.
of Zn in a metalloenzyme
under
certain
CA, and that Such a re-
has previously
Vol. 2, No. 3 BIOCHEMICAL
been accomplished ding
strength
appears
by Vallee in the
in the rate
of various
than
very
The studies
with
March 1960
CP. While
similar,
the bin-
the Zn++ in CP
in CA, as evidenced
of equilibration
chelating
published
(1958)
--et al.
two enzymesis
more “available”
rences
and in the
by the diffeinhibiting
effects
agents. are being
extended
and a complete
report
will
be
elsewhere.
This Swedish tutes
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
investigation
has been supported
Natural
Science
of Health,
U.S.
Research Public
by grants
Council
Health
from
the
and the National
Service
Insti-
(RG-6542).
References Beers,
R.F.,
Gurd,
F.R.N.,
(1952
1
Jr.,
Biochem.
and Goodman,
D.,
and Mann,
Keller,
H.,
and Peters,
S.,
Malmstrijm,
T.,
J. Am. Chem. Sot.,
Biochem. U.H.,
Biochim.
B.G.,
Scott,
D.A.,
Tupper,
R.,
Vallee,
D.S.,
492 (1956). 74,
670
J.,
34,
1163 (1940).
Hoppe-Seyler's
Z. physiol.
Chem.,
228 (1959).
Lindskog,
429
62,
l
Keilin,
317,
J.,
Arch.
Biophys.
Acta,
Biochem.
and Biophys.,
and Mendive, Watts,
(1951)
B.L.,
Chem. Sot.,
J.R.,
in press
J. Biol.
and Wormall,
R.W.E.,
5,
Chem., A.,
(1960). 345 (1953). I&,
Biochem.
445 (1941). J.,
50,
l
Rupley, -80,
J. A., 4750
Coombs,
(1958).
217
T.L.,
and Neurath,
H.,
J. Am.