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Reaction of polymer-heme complexes with carbon monoxide or molecular oxygen
Vol. 67, No. 3, 1975
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
REACTION OF POLYMER-HEME COMPLEXES WITH CARBON MONOXIDE OR MOLECULAR OXYGEN Eishun
Tsuchida,
Etsuo
Hasegawa,
Department of Polymer Waseda University,Tokyo
Received
July
Summary molecular
oxygen
were
monoxide
and its
studied
Hill's
on the
From the
In the reaction
with
polymer-ligands
except
the reaction
of the additive
of the
with
with
poly-L-lysine
oxygen,
poly-L-lysine
effects,
it
nay play
monoxide
It was found
studied.
was determined
molecular
polymer-ligand
carbon
or
and manometrically.
also
of the complex
for
results
conformation
curve
were
parameter
plots.
complexes
spectrophotometrically reactions
equilibrium
cooperative
However,other
Chemistry, 160,Japan
of some polymer-heme
of additives
carbon
Honda
25,1975
Interactions
Effects
and Kenji
it
the
was sigmoid
to be 2.1 by the
was also
showed
that
sigmoid.
no cooperativity.
was suggested
that
an important
part
reported
formations
a helical in raising
cooperativity. Introduction
The present
of heme with tion
and in
ture
of the Method pyridine, were
In this with
conformation
Structures photometrically
we report
and formation using
oxygen
that
polyethyleneimine
is,
and N,N-dimethylformamide constants
the method
at room tempera-
and discuss
polymer-heme on the
roles
found.
poly-L-lysine,
poly-4-vinyl-
of branching Hemin
were
and Dorough
= 0.42
)
( ferri-proto-
of Willstaetter
of heme complexes of Miller
forma-
a reversible
of these
(1,3).
by the method
complex
solvents
( degree
papers
of complexes
and found
in a cooperativity
) was prepared
(pH12.0)
(1,2,3)
interactions
or molecular
to the previous
IX chloride
in the
in organic
Polymer-ligands,
according
buffer
oxygen
complexes
of polymer-ligand
and branched-type
porphyrine
characteristics
molecular
monoxide
and Materials
prepared
Phosphate
with
communication,
carbon
recently
and their
of the polymer-heme
(1).
complexes
polymer-ligands the reaction
oxygenation
authors
(4).
0.05M
used as solvents.
were (5).
determined Absorption
spectroof
Vol.67,No.3,1975
carbon
BIOCHEMICAL
monoxide
manometer
or molecular
reaction
and Discussion
between
phosphate
after
axial
one with
of carbon
monoxide
complex
hyperbolic.
with
poly-L-lysine coefficient
of the poly-L-lysine line
l(B)
log(Y/(l-Y)) a cooperative
interaction
poly-L-lysine. observed
= log
As shown in the
between in Figure
absorption
plots
(6).
K + n log
PC0
heme complexes
of molecular
1
and Hill's unit-mole/l, molecular
Carbon plots
monoxide
(B) in phosphate
[hemelo= nitrogen
equilibrium
3.0 mmole/l,
was kept
constant
complex as
from
This
behavior
absorption
but for
large
curve
others
were
a reaction,n)
the slope
situated
value
of the indicated
on an a-helical reaction
was also
by the poly-L-lysine-heme
Pco(mmHg)
Figure
the
the
a cooperative
oxygen
optically
monoxide
parameter
to be 2.1
2, such
that
Only
of heme
heme in the absence
to be sigmoid,
(a cooperative
by Hill's
region
1 shows an absorption
complex.
system was determined
in Figure
while
on the
in a 0.05M
still
and carbon
Figure
was found
were
indicated
of poly-L-lysine of heme.
monoxide
bands
results
measured
in a Q-band
monoxide,
by a poly-L-lysine-heme
The flill's
straight
iron
were
and carbon observed
carbon
These
group
of a central
changes
with
active.
c-amino
spectra
and the absorption
reaction
was not
ligands
by the
by the use of a Warburg's
absorption complex
Spectral points
the
of poly-L-lysine is
Visible
(pH12.0).
isosbestic
even
formed
was determined
a poly-L-lysine-heme
buffer with
active
oxygen
RESEARCH COMMUNICATIONS
and by a spectrophotometer.
Results
occured
AND BIOPHYSICAL
complex,
log PC0
curve buffer Total
of poly-L-lysine-heme
(pH12.0) pressure
(760 mmHg).
865
at 25'C. of carbon
complex
[polylysine]o= monoxide
(A) 35.5
and
Vol. 67, No. 3, 1975
since
BIOCHEMICAL
n was equal
only
to 2.0.
in an equilibrium Subsequently,
were
studied.
This
revealed
reaction effects
but
of types
When random-coiled
and branched
were
since
behavior
dependent
on polymer-ligands
original
structure
of each complexes
axial
a cooperative
ligands
Therefore,
from
interaction
: (a)
a regular
of a heme complex
the fact
that
with
an a-helical
increased
after
the
partially
destroyed
chain
(3),
is,
it
1).
were
number
formation
in others
with
in the
in has two in Table
because
reaction.
in its
a
cooperative
and (b)
2 before
a struc-
Actually,
heme complex
although
it
had been
a heme due to steric
hinderance
8
Figure
2
Absorption
and the effect unit-rnnole/l, Total
pressure
of molecular
of additive [hemelo= of oxygen
oxygen
by poly-L-lysine-heme
polyethyleneglycole
6.0 mmole/l, and nitrogen
(0).
866
constant
complex
[polylysine]o=
[polyethyleneglycole]o= was kept
1.
former.
to cause
coordination
monoxide,
in
summarized
than
of a polymer-ligand
by the complex
Such a different
complex
may be important
carbon
was
of polymer-ligands
conformation
with
poly-4-vinylpyridine reaction
was retarded
of poly-L-lysine
conformations
by the differences
which system
oxygen
that
content
reaction
that
a poly-L-lysine-heme
by molecular
1 suggest
and their
and conformation
only
not
kinetics.
no cooperative , was small (Table
in a poly-L-lysine
reaction in Table
in an absorption
may be caused
the same polymer
The results
ture
reported,
was .rdised
used,
parameter
P5g was higher
ligand-exchange
also
a cooperativity
polymer-ligands,
polyethyleneimine,
As previously
that
RESEARCH COMMUNICATIONS
of polymer-ligands
observed
solution.
AND BIOPHYSICAL
(e)
45.5
60 unit-mmolell, (760
mmHg).
BIOCHEMICAL
Vol. 67, No. 3, 1975
between
heme and cylindrical
or reduction monoxide coordination chain
lysine-heme
complex
measurement
of solution
after
systems
act
aggregates,
were
in Table
Therefore,
but are
added 2.
able
cases,
was made to be instabilized no spectral
changes
Table
1
molecular Polymer-ligand
in
carbon complex
with
by polymer-heme
or
was
absorption
behavior polymers, to form decreased
an cl-helical
of polymer region
aggregates and after
absorption
of
(7). the
which polymer as
And addition
at 30°C
Solvent
Amax
n
poly-4-vinylpyridine
418
1.0
1 . 1x103M-1
DMF/MeOH
1.1
58
poly-L-lysine
431
2.0
2 . 5x108M-'
pH12 aq.
2.1
130
branched
424
1.0
7 . 5x104M-1
pH12 aq.
1.0
100
polyethyleneimine
of
conformation
before
complexes
in the
conformation.
poly-L-lysine
that
K(20'C)
by viscosity
parameter
on the
1 are formed,
in the poly-L-
When various
a cooperative
visible
number
may be caused
on the
was found
or branched
of polymer-ligand
structure
n
P50(mmHg)
n : Cooperative parameter ; n : Axial coordination number of heme complex K : Formation constant of heme complex ; DMF :N,N-dimethylformamide ; MeOH : methylalcohol ; DMF/MeOH=7/3(v/v) ; Xmax Absorption maximum of deoxy-heme complex
867
with
the polymer
was confirmed
changes
to interact
of polymer-ligands
oxygen
through
complex.
by the formation
was observed
Effects
it
of additives
it
with
of the
as expected
fact,
of random
to the system,
In these
formation
no cooperativity
by a poly-L-lysine-heme
as ligand
reaction
coordination
structure
and in
polymer-ligands
oxygen
axial
no conformational
the effects
the
a disappearence
in a poly-4-vinylpyridine
with
of the
occur
that
reaction.
we studied
molecular
shown
may not
concerning
Nextly,
do not
the
change
by the
in
However,
the complex
such a dynamical
that
a cooperative-binding
conformation. system,
structure
resulted
1,may initiate
regular
polyethyleneimine
caused
which
RESEARCH COMMUNICATIONS
(3),indicated
of a helical
oxygen,
number
with
so that
poly-L-lysine
of the strain
or molecular
AND BIOPHYSICAL
;
Vol. 67, No. 3, 1975
Table
2
BIOCHEMICAL
Effects
oxygen
of additives
on the
by poly-L-lysine-heme
Additives
2.0
130
polyethyleneglycole
1.3
62
polyglutamic
acid
1.7
80
sodium
chloride(O.lM)
1.7
14U
sodium
chloride(0.4M)
1.3
270
complex
was not affected
in a cooperative helical
shows that
at all
parameter
structure
tion
which
the
n 2.0
2.5~10~
2.0
4.6~10~
structure
of deoxy-heme
Therefore,
the decrease
by the instabilization
which
soln.
K(20°C)(M-2)
polymers.
may be caused
of molecular
at 30°C in PH 12 buffer
overall
by additive
of poly-L-lysine,
behavior
P50(mmHg)
None
polymers,
RESEARCH COMMUNICATIONS
absorption
complex
Cooperative parameter (n)
of additive
of an c1-
may mean a destruction
of an informa-
transfer. On the
other
monoxide ference
hand,when
or molecular
cause
potassium
cyanide
lysine-heme
Then,
constant
the
parameter
stability
structure
to cause
increase
of molecule species.
because
the
a ligand-exchange than
those
of the concentration while
salt
of sodium
chloride
of a heme complex.
can be explained
Generally,
in an aqueous
it solution
868
oxygen
the
is well becomes
a poly-Land carbon
absorption
complex.
Therefore,
due
of
with
on the
coordination
increased.
is,
difbut
concentration
of sodium
the axial
constant
That
of molecular
of neutral
This
absorbed
reaction
by a poly-L-lysine-heme
decreased,
of polypeptides
in size
strength
of carbon
was observed.
and an ionic
the effect
oxygen
and the formation
P50 by the addition
difference
ionic
we studied
was used in place
no cooperative-binding
was much higher
of molecular 2, with
erative
enough
cyanide
a neutral
may be the
complex
monoxide.
Table
oxygen,
between
essential
behavior
potassium
may not be due to the
to the difference
the
AND BIOPHYSICAL
As shown
chloride, number the
a coopwas kept
increase
by the
increase
known that instable
in
of in
a helical by adding
Vol.67,No.3,1975
sodium
chloride.
explained ligand
So the
by the
decrease
instabilization
AND BIOPHYSICAL
in a cooperative
RESEARCH COMMUNICATIONS
parameter
of an a-helical
observed
structure
may be
of the polymer-
by salt. This
from
system
consisting
the standpoint
studying It
BIOCHEMICAL
wiil
of poly-L-lysine
of a synthetic
factors
by both
be reported
in
Acnowledgment
The authors
For a Grant-in-Aid
model
experimental the near
and heme is of cooperative
and theoretical
extremely systems.
methods
interest We are now
of approach.
future. wish
to thank
the Ministry
of Education,
Japan,
(No. 911503).
-Rei 'erences 1.
Tsuchida,E.,
Honda,K.,
and Sata,H.
(1974)
Biopolymers
2.
Tsuchida,E.,
Honda,K.
, and Sata,H.
(1975)
Polymer
3.
Tsuchida,E.,
Honda,K.
, and Hasegawa,E.
(1975)
-13 2147-2159 J. L 498-504
Biochim.
Biophys.
Acta
393 483-495 4.
Willstaetter,R.
5.
Miller,J.R.
6.
For example: et al eds.) Tsuchida,E.,
(1950)
Ann.
and Dorough,C.D. Wyman,J. Vol.
19,
Honda,K.
(1964)
Chem. 365 197-202 (1952)
3. Amer.
in Advances
pp. 223-286,
Academic
, and Hasegawa,E.
in contribution
869
Chem. Sot.
in
-74 3977-3981 Chemistry (Anfinsen,C.B
Protein Press,
(1975)
New York
Biochim.
Biophys.
Acta
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
REACTION OF POLYMER-HEME COMPLEXES WITH CARBON MONOXIDE OR MOLECULAR OXYGEN Eishun
Tsuchida,
Etsuo
Hasegawa,
Department of Polymer Waseda University,Tokyo
Received
July
Summary molecular
oxygen
were
monoxide
and its
studied
Hill's
on the
From the
In the reaction
with
polymer-ligands
except
the reaction
of the additive
of the
with
with
poly-L-lysine
oxygen,
poly-L-lysine
effects,
it
nay play
monoxide
It was found
studied.
was determined
molecular
polymer-ligand
carbon
or
and manometrically.
also
of the complex
for
results
conformation
curve
were
parameter
plots.
complexes
spectrophotometrically reactions
equilibrium
cooperative
However,other
Chemistry, 160,Japan
of some polymer-heme
of additives
carbon
Honda
25,1975
Interactions
Effects
and Kenji
it
the
was sigmoid
to be 2.1 by the
was also
showed
that
sigmoid.
no cooperativity.
was suggested
that
an important
part
reported
formations
a helical in raising
cooperativity. Introduction
The present
of heme with tion
and in
ture
of the Method pyridine, were
In this with
conformation
Structures photometrically
we report
and formation using
oxygen
that
polyethyleneimine
is,
and N,N-dimethylformamide constants
the method
at room tempera-
and discuss
polymer-heme on the
roles
found.
poly-L-lysine,
poly-4-vinyl-
of branching Hemin
were
and Dorough
= 0.42
)
( ferri-proto-
of Willstaetter
of heme complexes of Miller
forma-
a reversible
of these
(1,3).
by the method
complex
solvents
( degree
papers
of complexes
and found
in a cooperativity
) was prepared
(pH12.0)
(1,2,3)
interactions
or molecular
to the previous
IX chloride
in the
in organic
Polymer-ligands,
according
buffer
oxygen
complexes
of polymer-ligand
and branched-type
porphyrine
characteristics
molecular
monoxide
and Materials
prepared
Phosphate
with
communication,
carbon
recently
and their
of the polymer-heme
(1).
complexes
polymer-ligands the reaction
oxygenation
authors
(4).
0.05M
used as solvents.
were (5).
determined Absorption
spectroof
Vol.67,No.3,1975
carbon
BIOCHEMICAL
monoxide
manometer
or molecular
reaction
and Discussion
between
phosphate
after
axial
one with
of carbon
monoxide
complex
hyperbolic.
with
poly-L-lysine coefficient
of the poly-L-lysine line
l(B)
log(Y/(l-Y)) a cooperative
interaction
poly-L-lysine. observed
= log
As shown in the
between in Figure
absorption
plots
(6).
K + n log
PC0
heme complexes
of molecular
1
and Hill's unit-mole/l, molecular
Carbon plots
monoxide
(B) in phosphate
[hemelo= nitrogen
equilibrium
3.0 mmole/l,
was kept
constant
complex as
from
This
behavior
absorption
but for
large
curve
others
were
a reaction,n)
the slope
situated
value
of the indicated
on an a-helical reaction
was also
by the poly-L-lysine-heme
Pco(mmHg)
Figure
the
the
a cooperative
oxygen
optically
monoxide
parameter
to be 2.1
2, such
that
Only
of heme
heme in the absence
to be sigmoid,
(a cooperative
by Hill's
region
1 shows an absorption
complex.
system was determined
in Figure
while
on the
in a 0.05M
still
and carbon
Figure
was found
were
indicated
of poly-L-lysine of heme.
monoxide
bands
results
measured
in a Q-band
monoxide,
by a poly-L-lysine-heme
The flill's
straight
iron
were
and carbon observed
carbon
These
group
of a central
changes
with
active.
c-amino
spectra
and the absorption
reaction
was not
ligands
by the
by the use of a Warburg's
absorption complex
Spectral points
the
of poly-L-lysine is
Visible
(pH12.0).
isosbestic
even
formed
was determined
a poly-L-lysine-heme
buffer with
active
oxygen
RESEARCH COMMUNICATIONS
and by a spectrophotometer.
Results
occured
AND BIOPHYSICAL
complex,
log PC0
curve buffer Total
of poly-L-lysine-heme
(pH12.0) pressure
(760 mmHg).
865
at 25'C. of carbon
complex
[polylysine]o= monoxide
(A) 35.5
and
Vol. 67, No. 3, 1975
since
BIOCHEMICAL
n was equal
only
to 2.0.
in an equilibrium Subsequently,
were
studied.
This
revealed
reaction effects
but
of types
When random-coiled
and branched
were
since
behavior
dependent
on polymer-ligands
original
structure
of each complexes
axial
a cooperative
ligands
Therefore,
from
interaction
: (a)
a regular
of a heme complex
the fact
that
with
an a-helical
increased
after
the
partially
destroyed
chain
(3),
is,
it
1).
were
number
formation
in others
with
in the
in has two in Table
because
reaction.
in its
a
cooperative
and (b)
2 before
a struc-
Actually,
heme complex
although
it
had been
a heme due to steric
hinderance
8
Figure
2
Absorption
and the effect unit-rnnole/l, Total
pressure
of molecular
of additive [hemelo= of oxygen
oxygen
by poly-L-lysine-heme
polyethyleneglycole
6.0 mmole/l, and nitrogen
(0).
866
constant
complex
[polylysine]o=
[polyethyleneglycole]o= was kept
1.
former.
to cause
coordination
monoxide,
in
summarized
than
of a polymer-ligand
by the complex
Such a different
complex
may be important
carbon
was
of polymer-ligands
conformation
with
poly-4-vinylpyridine reaction
was retarded
of poly-L-lysine
conformations
by the differences
which system
oxygen
that
content
reaction
that
a poly-L-lysine-heme
by molecular
1 suggest
and their
and conformation
only
not
kinetics.
no cooperative , was small (Table
in a poly-L-lysine
reaction in Table
in an absorption
may be caused
the same polymer
The results
ture
reported,
was .rdised
used,
parameter
P5g was higher
ligand-exchange
also
a cooperativity
polymer-ligands,
polyethyleneimine,
As previously
that
RESEARCH COMMUNICATIONS
of polymer-ligands
observed
solution.
AND BIOPHYSICAL
(e)
45.5
60 unit-mmolell, (760
mmHg).
BIOCHEMICAL
Vol. 67, No. 3, 1975
between
heme and cylindrical
or reduction monoxide coordination chain
lysine-heme
complex
measurement
of solution
after
systems
act
aggregates,
were
in Table
Therefore,
but are
added 2.
able
cases,
was made to be instabilized no spectral
changes
Table
1
molecular Polymer-ligand
in
carbon complex
with
by polymer-heme
or
was
absorption
behavior polymers, to form decreased
an cl-helical
of polymer region
aggregates and after
absorption
of
(7). the
which polymer as
And addition
at 30°C
Solvent
Amax
n
poly-4-vinylpyridine
418
1.0
1 . 1x103M-1
DMF/MeOH
1.1
58
poly-L-lysine
431
2.0
2 . 5x108M-'
pH12 aq.
2.1
130
branched
424
1.0
7 . 5x104M-1
pH12 aq.
1.0
100
polyethyleneimine
of
conformation
before
complexes
in the
conformation.
poly-L-lysine
that
K(20'C)
by viscosity
parameter
on the
1 are formed,
in the poly-L-
When various
a cooperative
visible
number
may be caused
on the
was found
or branched
of polymer-ligand
structure
n
P50(mmHg)
n : Cooperative parameter ; n : Axial coordination number of heme complex K : Formation constant of heme complex ; DMF :N,N-dimethylformamide ; MeOH : methylalcohol ; DMF/MeOH=7/3(v/v) ; Xmax Absorption maximum of deoxy-heme complex
867
with
the polymer
was confirmed
changes
to interact
of polymer-ligands
oxygen
through
complex.
by the formation
was observed
Effects
it
of additives
it
with
of the
as expected
fact,
of random
to the system,
In these
formation
no cooperativity
by a poly-L-lysine-heme
as ligand
reaction
coordination
structure
and in
polymer-ligands
oxygen
axial
no conformational
the effects
the
a disappearence
in a poly-4-vinylpyridine
with
of the
occur
that
reaction.
we studied
molecular
shown
may not
concerning
Nextly,
do not
the
change
by the
in
However,
the complex
such a dynamical
that
a cooperative-binding
conformation. system,
structure
resulted
1,may initiate
regular
polyethyleneimine
caused
which
RESEARCH COMMUNICATIONS
(3),indicated
of a helical
oxygen,
number
with
so that
poly-L-lysine
of the strain
or molecular
AND BIOPHYSICAL
;
Vol. 67, No. 3, 1975
Table
2
BIOCHEMICAL
Effects
oxygen
of additives
on the
by poly-L-lysine-heme
Additives
2.0
130
polyethyleneglycole
1.3
62
polyglutamic
acid
1.7
80
sodium
chloride(O.lM)
1.7
14U
sodium
chloride(0.4M)
1.3
270
complex
was not affected
in a cooperative helical
shows that
at all
parameter
structure
tion
which
the
n 2.0
2.5~10~
2.0
4.6~10~
structure
of deoxy-heme
Therefore,
the decrease
by the instabilization
which
soln.
K(20°C)(M-2)
polymers.
may be caused
of molecular
at 30°C in PH 12 buffer
overall
by additive
of poly-L-lysine,
behavior
P50(mmHg)
None
polymers,
RESEARCH COMMUNICATIONS
absorption
complex
Cooperative parameter (n)
of additive
of an c1-
may mean a destruction
of an informa-
transfer. On the
other
monoxide ference
hand,when
or molecular
cause
potassium
cyanide
lysine-heme
Then,
constant
the
parameter
stability
structure
to cause
increase
of molecule species.
because
the
a ligand-exchange than
those
of the concentration while
salt
of sodium
chloride
of a heme complex.
can be explained
Generally,
in an aqueous
it solution
868
oxygen
the
is well becomes
a poly-Land carbon
absorption
complex.
Therefore,
due
of
with
on the
coordination
increased.
is,
difbut
concentration
of sodium
the axial
constant
That
of molecular
of neutral
This
absorbed
reaction
by a poly-L-lysine-heme
decreased,
of polypeptides
in size
strength
of carbon
was observed.
and an ionic
the effect
oxygen
and the formation
P50 by the addition
difference
ionic
we studied
was used in place
no cooperative-binding
was much higher
of molecular 2, with
erative
enough
cyanide
a neutral
may be the
complex
monoxide.
Table
oxygen,
between
essential
behavior
potassium
may not be due to the
to the difference
the
AND BIOPHYSICAL
As shown
chloride, number the
a coopwas kept
increase
by the
increase
known that instable
in
of in
a helical by adding
Vol.67,No.3,1975
sodium
chloride.
explained ligand
So the
by the
decrease
instabilization
AND BIOPHYSICAL
in a cooperative
RESEARCH COMMUNICATIONS
parameter
of an a-helical
observed
structure
may be
of the polymer-
by salt. This
from
system
consisting
the standpoint
studying It
BIOCHEMICAL
wiil
of poly-L-lysine
of a synthetic
factors
by both
be reported
in
Acnowledgment
The authors
For a Grant-in-Aid
model
experimental the near
and heme is of cooperative
and theoretical
extremely systems.
methods
interest We are now
of approach.
future. wish
to thank
the Ministry
of Education,
Japan,
(No. 911503).
-Rei 'erences 1.
Tsuchida,E.,
Honda,K.,
and Sata,H.
(1974)
Biopolymers
2.
Tsuchida,E.,
Honda,K.
, and Sata,H.
(1975)
Polymer
3.
Tsuchida,E.,
Honda,K.
, and Hasegawa,E.
(1975)
-13 2147-2159 J. L 498-504
Biochim.
Biophys.
Acta
393 483-495 4.
Willstaetter,R.
5.
Miller,J.R.
6.
For example: et al eds.) Tsuchida,E.,
(1950)
Ann.
and Dorough,C.D. Wyman,J. Vol.
19,
Honda,K.
(1964)
Chem. 365 197-202 (1952)
3. Amer.
in Advances
pp. 223-286,
Academic
, and Hasegawa,E.
in contribution
869
Chem. Sot.
in
-74 3977-3981 Chemistry (Anfinsen,C.B
Protein Press,
(1975)
New York
Biochim.
Biophys.
Acta