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The reaction of the superoxide ion with iron(III)protoporphyrin IX dimethyl ester perchlorate: Evidence for a stable dioxygen complex
Vol. 56, No. :3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
THE REACTION OF THE SDPEROXIDE ION WITH IRON(III)PROTOPORPHYRIN DIMSTHYL ESTER PERU&ORATE:
H. Allen Inorganic
IX
EVIDENCE FOR A STABLE DIOXYGEN COMPLEX.
0. Hill*, Chemistry
David R. Turner Laboratory, Oxford,
England.
and Georgio Istituto Received
Pellizer di Chimica,
December
Universita
di Trieste,
Italy,
7,1973
SUMMARY: The reaction of superoxide ion with one equivalent of iron(III)protoporphyrin IX dimethyl ester perchlorate in NNdimethylformsmide at -50% yields a complex with an absorption spectrum comparable to that of oxymyoglobin. The complex decomposes at -loo to iron(II)protoporphyrin IX dimethyl ester which does not react with oxygen.
The nature
of
continues the
the
to attract
role
of
the
been numerous chemistry
of
As part
metal
complexes.
proposal
we have
that
be formulated
study
the
the
reaction
biological interest
* Author
its by the
dioxygen
complexes
some aspects
in simpler
revival
of
(9)
superoxide IX dimethyl
with ester
should
@ 19 74 by Academic Press, Inc of reproduction in any form reserved.
There
have
of
the
complexes.
with
a number
heme proteins iron(III)
a simple perchlorate,
be addressed.
the
superof
of an earlier
coboglobins),
ion
to
of
(I)
to whom enquiries
iron
regard
chemistry
(7)
of the
derivatives
investigated
complexes.
reactions
739 Copyright AN rights
with
(61 in the
Intrigued
iron(III)protoporphyrin cloq-'
particularly the
systems
investigated
of
and hemoglobin
to reproduce
(3-5)
as superoxide
extensively
(1,2)
of myoglobin
in stabilising
of a continuing ion,
the
protein
these
complexes
attention
attempts
oxide
to
dioxygen
(8) could
(analgous we chose
to
heme derivative, ~e(III)(PPDEl]'
Vol. 56, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
1 II
‘
-T \ -5
. \
500
Fig.1.
(al
Absorption at -50%
(b)
RESULTS:
The spectrum
NN-dimethylformamide heme.
(11)
same solvent. in Figure of
the
compared lengths
of
various with
This
that
the visible
is
(2,12)
C104-
typical
(101 at
proteins,
the
product
-50%
with
in DMF
of this
740
I in dry spin
iron(III1
an electrochemically-
is
U.V.
2. Soret
shown
to those
vxyperoxidase
in Figure and the
in the
reaction similar
oxyhemoglobin,
a- and S-bands
-50%(----l
superoxide,(
has many features
of oxymyoglobin
of
of a high
tetrabutylammonium of
in DMF at
of a solution
rapidly
spectrum
oxy-heme
@e(III)(PPDEa+
of Fe(II)(PPDE)
I(a))
reacts
The spectrum
2(a).
of
spectrum
(DMF),
solution
of )
(Figure
Such a solution
prepared
spectrum (-
Absorption
11OO"m
700 703
and is
The wavebands
are
Vol.
56,
No.
3, 1974
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
10
10
:’ 0 “; ,
c;,
I
-5
.
\ 400
300
Fig.2.
(a)
Absorption
500
spectrum
(b)
Absorption at
similar;
-50°C,
the
importantly a pronounced
20%.
700 700
of
the
900
product
1lOOnm
of
the
reaction
between
superoxide
in
( -)
spectrum
(2,121
of oxymyoglobin
in water
pH 7
c----l
u-band there
i
and tetrabutylammonium
Fe(III)PPDE]+C104DMF at
\
6ca
is more is
shoulder
absorption
intense
than
in the
at 825 nm, compared
741
the .nfra-red
p-band
and most
in the
form
of
to 950 nm in oxymyoglobin.
Vol. 56, No. 3, 1974
BIOCHEMICAL
The absolute
intensities
oxymyoglobin
though
of closer
bands
of oxymyoglobin
bands
may be comparable
complex.
absorption different
of
to oxyperoxidase
the
product
maxima
(particularly
the
trans
to the
environment
of
reaction
is
revealed
in Figure
at a 1:l
ratio
of
I to
again
reaction
being
II,
a dioxygen
complex
ke(III)(PPDE)]+C104On warming I and II, Figure S.C.E
a solution the
l(b), in DMF.
Fig.3.
containing
spectrum prepared
changes
consistent
the
Titration superoxide
the
of
to one identical
product
reduction
of the
of@'e(III)PPDE)+ in DMF at
-5O'C.
742
of
the
of
the
effective stoichiometry is observed
product
of
dimethyl
+ Bu4N+ClO the
reaction
to that of
decomposition
C104-
the
may be due to
protoporphyrin
product
the
a dioxygen
an end-point
02Fe(PPDE)
in
simple
different
with
iron +
is
The overall
3 where
by electrochemical
Neither
the
heme,
+ Bu4N+0 2
strengths
bands)
and/or
of
since
and wavelengths
infra-red
the
However
reaction
width
oxygen
than
and in the
of the
in line
are lower
oscillator
in the heme proteins
that
RESEARCH COMMUNICATIONS
(1).
the
differences
of the
the
and p-bands
the
ligands
dielectric
the a-
are narrower,
Assuming
heme complex,
AND BIOPHYSICAL
with
4
the ester:
-
(1)
between
of Fe(IIl(PPDE) I at of
-0.4V the
Vs dioxygen
tetrabutylsmmonium
Vol. 56, No. 3, 1974
complex from
BIOCHEMICAL
nor Fe(II)(PPDEl
25'
to -50%
not
overall
paramagnetic
product
is
formulated
complex
of
iron(
former
latter
would
reaction
since,
be diamagnetic. the
complex
intensity
DISCUSSION:
The results
that
nucleophilic,
can displace porphyrin
iron
temperature. solvent
is
coordinate
dioxygen
might
and the superoxi.de
derivatives
since,
example,
for
precede
suggestive.
to lend
electron
formation Efforts
of the to
isolate
transfer complex. the
displace
with
a five-
decomposition in the
a five
coordinate
iron
dioxygen
complex
described
formulation
the
heme proteins
This
need
from
superoxide However
presumed
FCKNOWLEDGEMENT: We wish to thank the Science support and a Studentship to one of us (D.R.T.), R.J.P.Williams and Mr. P.Skyte for advice. 743
with
cannot
protein
to the of
of iron(II1).
added.
at low
react
the
I, and
complex
of the
of
with
being
resulting
product
the
support
analogouscomplexes
ion,
must
functions
of
has been
nucleophil it
immediate
of preparation
be thought
presumably
a poor
One of the
II
to decomposition
presumably
the
of
the
diminishes
superoxide
and the
being
in that
and presumably
superoxide
may be to make available
The method
herein
the
the
or a dioxygen
be expected
porphyrin
respect
though
ccmplex.
therefore
complex.
with
complex,
the
solvent
oxygen,
Fe(II)(PPDEj iron
proteins
the
stable
Molecular
from
the
suggest
of iron<1111
of a solution
of the
of
as a convenient of whether
coupled
spectrum
= 2.04;
serves
would
On titration
e.p.r.
(gl
irrespective
as a superoxide of
II
also
be antiferromagnetically
of
of
in DMF at -120°C)
when one-equivalent
might
reaction
spectrum
has vanished
of
at temperatures
(2)
resonance
a loss
would
intensity
the
oxygen
--) 02 + Fe(II)(PPDE)
= 2.009; g3 = 2.004, g2 method of following the
the
that
molecular
RESEARCH COMMUNICATIONS
reversible.
The electron
the
with
suggesting
02Fe(PPDE) is
react
AND BIOPHYSICAL
not
it
dioxygen
of this as
necessarily
be so
to iron(II1) is
at
least
complex
continue.
Research Council for and Drs. D.Dolphin,
heme
BIOCHEMICAL
Vol. 56, No. 3, 1974
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
REFERENCES 1.
Blumberg, W.E., Peisach, J.,Wittenberg, (1968) J.Biol.Chem., 243, 1854-1862.
2.
Antonini, E., and Brunori, M., Hemoglobin and Myoglobin in their reactions with ligands, Frontiers of Biology, Eds., Neuberger, A., and Tatum, E.L., (1971) 2l, North-Holland Publishing Co.,Amsterdam.
3.
Wang, J.H. (1962) Oxygenases, New York, p.469-516.
4.
Baldwin,
5.
Chang, 5811.
6.
Turner,
7.
Wittenberg, J.B., Wittenberg, B.A., Peisach, J., (1973) Proc.Nat.Acad.Sci. U.S.A. 67, 1846-1853.
8.
Weiss,
9.
Hoffman, B.M., 67, 637-643.
10.
Smith,
11.
Maricle,
12.
Bowen,
J.E., C.K.,
and Huff,
(1973)
(1964)
J.,
J.,
and Traylor,
D.R.,
II
D.L., W.S.,
and Hodgson, (1949)
(1973)
J.B.,
Press, 95,
J.Amer.Chem.Soc.,
5757-5759. 95,
5810-
Oxford. and Blumberg,
W.E.,
83-84.
and Petering,
D.W. and Williams,
Academic
J.Amer.Chem.Soc.,
Thesis
202,
and Wittenberg,
Hayaishi,O.,
(1973)
T.G.,
Part
Nature
Ed.
B.A.,
D.H.,
(1970)
R.J.P.
(1970)
J.Biol.Chem.
Structure
(1965),
W.G.,
179,
744
Proc.Nat.Acad.Sci.
Anal.Chem.
235-245.
U.S.A.
and Bonding 37,
'7,1-45.
1562-1565.
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
THE REACTION OF THE SDPEROXIDE ION WITH IRON(III)PROTOPORPHYRIN DIMSTHYL ESTER PERU&ORATE:
H. Allen Inorganic
IX
EVIDENCE FOR A STABLE DIOXYGEN COMPLEX.
0. Hill*, Chemistry
David R. Turner Laboratory, Oxford,
England.
and Georgio Istituto Received
Pellizer di Chimica,
December
Universita
di Trieste,
Italy,
7,1973
SUMMARY: The reaction of superoxide ion with one equivalent of iron(III)protoporphyrin IX dimethyl ester perchlorate in NNdimethylformsmide at -50% yields a complex with an absorption spectrum comparable to that of oxymyoglobin. The complex decomposes at -loo to iron(II)protoporphyrin IX dimethyl ester which does not react with oxygen.
The nature
of
continues the
the
to attract
role
of
the
been numerous chemistry
of
As part
metal
complexes.
proposal
we have
that
be formulated
study
the
the
reaction
biological interest
* Author
its by the
dioxygen
complexes
some aspects
in simpler
revival
of
(9)
superoxide IX dimethyl
with ester
should
@ 19 74 by Academic Press, Inc of reproduction in any form reserved.
There
have
of
the
complexes.
with
a number
heme proteins iron(III)
a simple perchlorate,
be addressed.
the
superof
of an earlier
coboglobins),
ion
to
of
(I)
to whom enquiries
iron
regard
chemistry
(7)
of the
derivatives
investigated
complexes.
reactions
739 Copyright AN rights
with
(61 in the
Intrigued
iron(III)protoporphyrin cloq-'
particularly the
systems
investigated
of
and hemoglobin
to reproduce
(3-5)
as superoxide
extensively
(1,2)
of myoglobin
in stabilising
of a continuing ion,
the
protein
these
complexes
attention
attempts
oxide
to
dioxygen
(8) could
(analgous we chose
to
heme derivative, ~e(III)(PPDEl]'
Vol. 56, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
1 II
‘
-T \ -5
. \
500
Fig.1.
(al
Absorption at -50%
(b)
RESULTS:
The spectrum
NN-dimethylformamide heme.
(11)
same solvent. in Figure of
the
compared lengths
of
various with
This
that
the visible
is
(2,12)
C104-
typical
(101 at
proteins,
the
product
-50%
with
in DMF
of this
740
I in dry spin
iron(III1
an electrochemically-
is
U.V.
2. Soret
shown
to those
vxyperoxidase
in Figure and the
in the
reaction similar
oxyhemoglobin,
a- and S-bands
-50%(----l
superoxide,(
has many features
of oxymyoglobin
of
of a high
tetrabutylammonium of
in DMF at
of a solution
rapidly
spectrum
oxy-heme
@e(III)(PPDEa+
of Fe(II)(PPDE)
I(a))
reacts
The spectrum
2(a).
of
spectrum
(DMF),
solution
of )
(Figure
Such a solution
prepared
spectrum (-
Absorption
11OO"m
700 703
and is
The wavebands
are
Vol.
56,
No.
3, 1974
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
10
10
:’ 0 “; ,
c;,
I
-5
.
\ 400
300
Fig.2.
(a)
Absorption
500
spectrum
(b)
Absorption at
similar;
-50°C,
the
importantly a pronounced
20%.
700 700
of
the
900
product
1lOOnm
of
the
reaction
between
superoxide
in
( -)
spectrum
(2,121
of oxymyoglobin
in water
pH 7
c----l
u-band there
i
and tetrabutylammonium
Fe(III)PPDE]+C104DMF at
\
6ca
is more is
shoulder
absorption
intense
than
in the
at 825 nm, compared
741
the .nfra-red
p-band
and most
in the
form
of
to 950 nm in oxymyoglobin.
Vol. 56, No. 3, 1974
BIOCHEMICAL
The absolute
intensities
oxymyoglobin
though
of closer
bands
of oxymyoglobin
bands
may be comparable
complex.
absorption different
of
to oxyperoxidase
the
product
maxima
(particularly
the
trans
to the
environment
of
reaction
is
revealed
in Figure
at a 1:l
ratio
of
I to
again
reaction
being
II,
a dioxygen
complex
ke(III)(PPDE)]+C104On warming I and II, Figure S.C.E
a solution the
l(b), in DMF.
Fig.3.
containing
spectrum prepared
changes
consistent
the
Titration superoxide
the
of
to one identical
product
reduction
of the
of@'e(III)PPDE)+ in DMF at
-5O'C.
742
of
the
of
the
effective stoichiometry is observed
product
of
dimethyl
+ Bu4N+ClO the
reaction
to that of
decomposition
C104-
the
may be due to
protoporphyrin
product
the
a dioxygen
an end-point
02Fe(PPDE)
in
simple
different
with
iron +
is
The overall
3 where
by electrochemical
Neither
the
heme,
+ Bu4N+0 2
strengths
bands)
and/or
of
since
and wavelengths
infra-red
the
However
reaction
width
oxygen
than
and in the
of the
in line
are lower
oscillator
in the heme proteins
that
RESEARCH COMMUNICATIONS
(1).
the
differences
of the
the
and p-bands
the
ligands
dielectric
the a-
are narrower,
Assuming
heme complex,
AND BIOPHYSICAL
with
4
the ester:
-
(1)
between
of Fe(IIl(PPDE) I at of
-0.4V the
Vs dioxygen
tetrabutylsmmonium
Vol. 56, No. 3, 1974
complex from
BIOCHEMICAL
nor Fe(II)(PPDEl
25'
to -50%
not
overall
paramagnetic
product
is
formulated
complex
of
iron(
former
latter
would
reaction
since,
be diamagnetic. the
complex
intensity
DISCUSSION:
The results
that
nucleophilic,
can displace porphyrin
iron
temperature. solvent
is
coordinate
dioxygen
might
and the superoxi.de
derivatives
since,
example,
for
precede
suggestive.
to lend
electron
formation Efforts
of the to
isolate
transfer complex. the
displace
with
a five-
decomposition in the
a five
coordinate
iron
dioxygen
complex
described
formulation
the
heme proteins
This
need
from
superoxide However
presumed
FCKNOWLEDGEMENT: We wish to thank the Science support and a Studentship to one of us (D.R.T.), R.J.P.Williams and Mr. P.Skyte for advice. 743
with
cannot
protein
to the of
of iron(II1).
added.
at low
react
the
I, and
complex
of the
of
with
being
resulting
product
the
support
analogouscomplexes
ion,
must
functions
of
has been
nucleophil it
immediate
of preparation
be thought
presumably
a poor
One of the
II
to decomposition
presumably
the
of
the
diminishes
superoxide
and the
being
in that
and presumably
superoxide
may be to make available
The method
herein
the
the
or a dioxygen
be expected
porphyrin
respect
though
ccmplex.
therefore
complex.
with
complex,
the
solvent
oxygen,
Fe(II)(PPDEj iron
proteins
the
stable
Molecular
from
the
suggest
of iron<1111
of a solution
of the
of
as a convenient of whether
coupled
spectrum
= 2.04;
serves
would
On titration
e.p.r.
(gl
irrespective
as a superoxide of
II
also
be antiferromagnetically
of
of
in DMF at -120°C)
when one-equivalent
might
reaction
spectrum
has vanished
of
at temperatures
(2)
resonance
a loss
would
intensity
the
oxygen
--) 02 + Fe(II)(PPDE)
= 2.009; g3 = 2.004, g2 method of following the
the
that
molecular
RESEARCH COMMUNICATIONS
reversible.
The electron
the
with
suggesting
02Fe(PPDE) is
react
AND BIOPHYSICAL
not
it
dioxygen
of this as
necessarily
be so
to iron(II1) is
at
least
complex
continue.
Research Council for and Drs. D.Dolphin,
heme
BIOCHEMICAL
Vol. 56, No. 3, 1974
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
REFERENCES 1.
Blumberg, W.E., Peisach, J.,Wittenberg, (1968) J.Biol.Chem., 243, 1854-1862.
2.
Antonini, E., and Brunori, M., Hemoglobin and Myoglobin in their reactions with ligands, Frontiers of Biology, Eds., Neuberger, A., and Tatum, E.L., (1971) 2l, North-Holland Publishing Co.,Amsterdam.
3.
Wang, J.H. (1962) Oxygenases, New York, p.469-516.
4.
Baldwin,
5.
Chang, 5811.
6.
Turner,
7.
Wittenberg, J.B., Wittenberg, B.A., Peisach, J., (1973) Proc.Nat.Acad.Sci. U.S.A. 67, 1846-1853.
8.
Weiss,
9.
Hoffman, B.M., 67, 637-643.
10.
Smith,
11.
Maricle,
12.
Bowen,
J.E., C.K.,
and Huff,
(1973)
(1964)
J.,
J.,
and Traylor,
D.R.,
II
D.L., W.S.,
and Hodgson, (1949)
(1973)
J.B.,
Press, 95,
J.Amer.Chem.Soc.,
5757-5759. 95,
5810-
Oxford. and Blumberg,
W.E.,
83-84.
and Petering,
D.W. and Williams,
Academic
J.Amer.Chem.Soc.,
Thesis
202,
and Wittenberg,
Hayaishi,O.,
(1973)
T.G.,
Part
Nature
Ed.
B.A.,
D.H.,
(1970)
R.J.P.
(1970)
J.Biol.Chem.
Structure
(1965),
W.G.,
179,
744
Proc.Nat.Acad.Sci.
Anal.Chem.
235-245.
U.S.A.
and Bonding 37,
'7,1-45.
1562-1565.