- Email: [email protected]
Prostaglandin H synthase: An example of enzymic symbiosis
Vol.
130.
July
31,
No. 2, 1985
8lOCHEMlCALAND8lOPHYSlCALRESEARCH
COMMUNICATIONS
1985
Pages
PROSTAGLANDIN Richard
J.
Department
Received
Kulmacz,
of
June
H SYNTHASE: James
Biological
AN EXAMPLE F.
Miller,
OF
Jr.,
ENZYMIC
and
SYMBIOSIS
William
Chemistry, University Chicago, Illinois 60680
of
918-923
E.N.
Illinois
Lands at
Chicago
19, 1985
Reaction conditions which promote the heme-dependent peroxidase activity of prostaglandin H synthase appear to stimulate the heme-dependent cyclooxygenase activity also present in the synthase, even though the cyclooxygenase requires hydroperoxide for activity. However, aspirin-treated synthase, which retains only peroxidase activity, inhibited the cyclooxygenase activity of untreated synthase in the manner observed with similar levels of glutathione peroxidase. Any stimulatory effect of the synthase peroxidase on the synthase cyclooxygenase is thus likely to involve an intramolecular mechanism. Participation of peroxidase intermediates (Compounds 1 and II) in the initiation of a cyclooxygenase free radical chain reaction may provide an intramolecular mechanism for stimulation of the 0 1985 Academic Press, Inc. synthase cyclooxygenase by the synthase peroxidase.
Prostaglandin
H synthase,
biosynthesis
of
enzymatic
a fatty
forms
the
hydroperoxide,
oxide
for
initiation The is
of
synthase
in
the
value
for
synthase
PGG2 prevents
cannot
mechanism result
lower
this
1 Abbreviations
more
-6
of
peroxide
PGH
efficient
positive used
synthase
are:
PGG2.
that prostaglandin
$1.50
0 I985 by Academic Press, Inc. of reproduction in any form reserved.
918
of
the
the
importance
of
the
With activity
of
that
actually of
is
removes
activities
sufficiently
We propose
initiation symbiosis
levels
the the
of
a Km the
hydroperoxides,
but
to
suppress
the
the
presence
of
affords cyclooxygenase cyclooxygenase 62;
which
hydroper-
two
peroxidase
high
levels
activity. in
of
the two
activity
M lipid that
in
exhibits
biosynthesis.
the of
-8
these
eicosanoid
M (1.2).
step
prostacyclins,
activity
because
accumulation
peroxidase for
of
0006-291X/85
10
cyclooxygenase
heme-dependent
Copyrighr All rights
an
effectively
endogenous
control
about
10
between
committed
(cyclooxygenase)
requires
interest
first
and
a peroxidase
relationship
overall
the
oxygenase
and
and
considerable
of
acid
PGG2', (l),
hydroperoxides.
catalyzes
thromboxanes,
prostglandins,
activities:
synthase
which
PGH.
an
it
the
intramolecular The
reaction. activity prostaglandin
of
PGH H.
Vol.
130,
No. 2, 1985
synthase than
is other
BIOCHEMICAL
a much fatty
acid
heme-dependent
METHODS
more
explosive
BIOPHYSICAL
amplifier
oxygenases,
peroxidase
AND
AND
such
of as
RESEARCH
lipid
COMMUNICATIONS
hydroperoxide
soybean
levels
lipoxygenase,
which
lack
a
activity.
MATERIALS
Acetylsalicylic acid and N,N,N'.N'-tetramethylphenylenediamine were obtained from Sigma Chemical Co., St. Louis, MO. Arachidonic acid was purchased from Nu Chek Preps, Inc., Elysian, MN, and was treated with sodium borohydride to reduce any contaminating peroxides. Hydrogen peroxide was from Fisher Scientific Company, Fair Lawn, NJ. Prostaglandin H synthase was purified as the apoenzyme (3) and reconstituted with hematin (4). Cyclooxygenase activity was assayed with a polarographic oxygen electrode in a reaction cuvette containing 3 ml of 0.1 M potassium phosphate, pH 7.2/0.67 mM phenol/O.10 mM arachidonate (3). Peroxidase activity was assayed with hydrogen peroxide as substrate and tetramethylphenylenediamine as cosubstrate (1). Protein was assayed as described by Peterson (5).
RESULTS
AND
The
cyclooxygenase-catalyzed
reactions,
appears
having for
DISCUSSION
a free the
to
radical
of
the
However,
several
synthase
has
radical
observations
activity as
by
similar The
peroxidase
action
as
of of
the
one
synthase
dimer
with
the
cyanide
seem the
is
provide in
the
peroxidase
of
H202
parallels
cyclooxygenase
cyclooxygenase
are
the and their
reaction
initiation
PGH
activity. increase
closely
of
first. of
cyclooxygenase
(1)
in enzyme
activity
effectiveness
the
same at
in
essential
a route
cosubstrates
substrates
oxygenase acids
paradoxical
protein's
relative
of
to
presence
peroxidase
initiators
(9);
interfered
and with
(3).
heme-containing reactions
process
the
many b)
and
cyclooxygenase-catalyzed intramolecular
a)
activity
levels
on
peroxidase
effectivenesss
both
that
(7.8);
hydroperoxides
c)
indicated effect
include:
cyclooxygenase
might
fatty
polyunsaturated
seems
The
activity
known
Hydroperoxide
it
reaction.
peroxidase
a stimulatory
and
all of
mechanism.
(1.6).
chain
like
(6).
autooxidation
reaction
reaction
observations
relative
the
chain
a peroxide-removing
lipid
resemble
cyclooxygenase
initiation
These
reaction
or
by the
peroxidase could
intermolecular cyclooxygenase
in
conceivably interactions on
919
another
stimulating occur
by of
dimer.
the
an peroxidase Possible
on
Vol.
130,
No. 2, 1985
intermolecular
processes
dimers,
production
(10)
would
of
AND
include
a diffusible
BIOPHYSICAL
direct
RESEARCH
contact
stimulant,
or
COMMUNICATIONS
between
removal
synthase
of
a toxic
byproduct
* To
determine
if
intermolecular of
BIOCHEMICAL
in
adding
only
synthase,
to
treated 1% of that
its
(2
aspirin
synthase
was
as
aspirin
would
of not
the
peroxidase
(1.1
the
JIM)
significantly
mol
Aspirin-Treated moluntreated
to
due
to
the
synthase
because during
decreased
in
untreated the
additional
and
not
such the
to
the
a level 30
Synthase Synthase
Fiqure 1: Inhibition of cyclooxygenase activity of PGH synthase by aspirin-treated PGH synthase. The cyclooxygenase activities of the indicated proportions of aspirin-treated synthase and untreated synthase 1.1 nM subunit) were assayed as described in the text. 920
the
Methods.
synthase)
it,
of
and
and
synthase with
90%
injected,
Materials
was
below
cuvette
synthase
along
inactivate
at
was
aspirin-treated
added
to
aspirin-treated
untreated
decrease
was
activity
nM subunit)
the
The
holoenzyme
reaction
aspirin-treated 1).
aspirin-treated
this
in
be activity
activity of
described (of
of
of (~50
cyclooxygenase
amounts
as
of
synthase
a cyclooxygenase
(Figure
aspirin
PGH
could
cyclooxygenase
form
the
Various
activity
activity
peroxidase on
the
Pure
synthase
ratio
the
effect in
leaving
determined
the
increased
the
reduce
into
untreated
peroxide-scavenging amount
to
while
cyclooxygenase fashion
small
mM)
activity
a linear
of
activity,
injected
before
observed
examined
treatment.
then
cyclooxygenase
effect
PGH synthase.
level
synthase'were
The
intact
initial
immediately
we
peroxidase
aspirin
before
stimulatory
nature,
the some
with
the
set
of
Vol.
130,
No. 2, 1985
used
to
assay
the
x-axis
mole
of
cyclooxygenase indicated
of
corresponded reasonably
(in
as
form
of
glutathione
are
interfere
The
with,
activity the
same
of of
did
of
untreated
when
the
than
augment,
need
be present
10 40
(1).
ratio
of
70
peroxidase not
stimulate, synthase,
evidence
therfore
points
peroxidase
dimer
peroxidases
per
about
synthase
synthase)
holoenzyme
heme-containing
rather
adding
only
to
cyclooxygenase
ratio
accumulated
curve
protein
ratio
activity
did.
in
the
aspirin-treated
cyclooxygenase
Other
cyclooxygenase.
Thus,
cyclooxygenase
present
treated
protein/protein
(1).
peroxidase of
of
the
peroxidase/cyclooxygenase
the
the
of
activity
glutathione
suppressed
intermediates
10 moles suppress
This
cyclooxygenase
the
a stimulation
to
the
the
instead
much to
to
suppressed
but
about
maximally
enzyme.
COMMUNICATIONS
Extrapolation
a peroxidase/cyclooxygenase
close
separately
of
could
untreated
to
(11).
a ratio
protein
the
BIOPHYSICALRESEARCH
activity
that
untreated
activity
that
BIOCHEMICALAND
with
of
the
a cell
initiation
of
would
also
tend
prostaglandin
formation. Because
only
catalytic
one
activity
heme (4).
it
seems
cyclooxygenase
by
the
peroxidase
cyclooxygenase
reactions
share
One 2,
where
in
the
possible
scheme
peroxidase of
mechanism
each
molecule
of
activating
another
reaction.
With
molecule
of
would
be
much
more
one
molecule
postulated
the
PGG2
such
as
than
that
hydroperoxide soybean
of
synthase
dimer another
(13),
921
proposed
Figure to
each
character be
of
which
(12)
of
the
accounting
of
chain a
action
acceleration
initiation
as
capable
involves
cyclooxygenase
which
serve
This
would
Such
perhaps
in
cyclooxygenase
during
initiation
shown
reaction.
hydroperoxide.
the
are
branched
in
forms.
is
II,
process,
a system
and
enzyme
I and
initiating
to
for lipoxygenase
one
the
peroxidase
intermediates
acceleration
regard
the
autoaccelerative,
a two-step
the in
of
cyclooxygenase
of
radical-chain
by
full
intermediate
Compounds
an
for
stimulation
common
sharing
dimer.
initiation
explosive
for
because
synthesized
synthase
order
of
occurs some
have
hydroperoxide,
second
that
cyclooxygenase
would
dimer
likely
intermediates,
initiation
reaction
for
per
would
required reaction,
such for
the
only as observed
be
Vol.
130,
BIOCHEMICALAND
No. 2, 1985
ROOH ROH
BIOPHYSICAL
ROOH
RESEARCH
COMMUNICATIONS
q ROOH
AH
/
Figure 2: A hypothetical mechanism for the stimulation of synthase cyclooxygenase activity by synthase peroxidase intermediates. The formal oxidation states of the heme iron of the synthase (E) are indicated by Roman numerals. ROOH: Lipid hydroperoxide; ROH: lipid alcohol; ROO: hydroperoxy radical; RH: polyunsaturated fatty acid; AH2: peroxidase cosubstrate; AH: oxidized cosubstrate.
differences
in
enzyme. via
kinetics
Alternatively,
Compounds
small
The
the
I or
amounts
oxygenase
of
II
retention in
explosive
the this
same
that survival
ACKNOWLEDGEMENT: Public Health the University
the
be
cyclooxygenase
much
than
the
non-heme
of
for
soybean
symbiotic
many
rapid
many
animals
the
soybean
cyclooxygenase sensitive
to of
of
two
these
suggests
two that
by
low
activities
catalyt the
sensi
amounts
provides
C
may
have
species.
This work was supported by Service (GM30509) and a Medical of Illinois at Chicago, College
3. 4. 5. 6.
Kulmacz, R-J., Lands, Ohki, S., Ogino, N., 254, 829-836 Kulmacz, R-J., Lands, Kulmacz, R.J., Lands, Peterson, G.L. (1979) Hemler, M.E., Lands,
W.E.M. Yamamoto, W.E.M. W.E.M. Anal. W.E.M.
tive
of
a grant from the United Scientist Fellowship of Medicine
States (JFM) from
REFERENCES 1. 2.
the
oxygenase.
formation
of
and
the
initiation
linkage
prostaglandin
combination
more
of
peroxide-dependent
iron
in
and
initiation
inherently
holoenzyme
value
the
peroxide-dependent
unusual
enhancement
hydroperoxide important
in of
the
may
between
hydroperoxide
reaction
activities and
reaction
(1983) S., (1985) (1984) Biochem. (1980)
922
Prostaglandins Hayaishi. 0.
25, (1979)
Prostaglandins
J. Biol. J.
100, Biol.
Chem. 201-220. Chem.
29, 259, 255,
531-540. J. Biol. 175-190. 6358-6363. 6253-6261.
Chem.
Vol. 130, No. 2, 1985
1. 8. 9. 10. 11. 12. 13.
BIOCHEMICAL
AND BIOPHYSICALRESEARCH
COMMUNICATIONS
Nugteren, D.H., Beerthuis, R.K., van Dorp, D.A. (1966) Rec. Trav. Chim. Pays-Bas 85, 405-419. Takeguchi, C., Kohno, E., Sih, C.J. (1971) Biochemistry 10, 2372-2376. Marshall, P.J., Kulmacz. R.J., Lands, W.E.M. (1984) in Oxygen Radicals in Chemistry and Biology (W. Bors, M. Saran, D. Tait, eds.), pp. 299-304, de Gruyter, Berlin. Egan, R.W., Paxton, J., Kuehl, F.A., Jr. (1976) J. Biol. Chem. 251, 7329-7335. Rome, L.H., Lands, W.E.M. (1975) Proc. Natl. Acad. Sci. USA 72, 4863-4865. Boudart, M. (1968) Kinetics of Chemical Processes, pp. 124-136, Prentice-Hall, Englewood Cliffs, NJ. (1972) J. Biol. Chem. 247, 1038-1047. Smith, W.L., Lands, W.E.M.
923
130.
July
31,
No. 2, 1985
8lOCHEMlCALAND8lOPHYSlCALRESEARCH
COMMUNICATIONS
1985
Pages
PROSTAGLANDIN Richard
J.
Department
Received
Kulmacz,
of
June
H SYNTHASE: James
Biological
AN EXAMPLE F.
Miller,
OF
Jr.,
ENZYMIC
and
SYMBIOSIS
William
Chemistry, University Chicago, Illinois 60680
of
918-923
E.N.
Illinois
Lands at
Chicago
19, 1985
Reaction conditions which promote the heme-dependent peroxidase activity of prostaglandin H synthase appear to stimulate the heme-dependent cyclooxygenase activity also present in the synthase, even though the cyclooxygenase requires hydroperoxide for activity. However, aspirin-treated synthase, which retains only peroxidase activity, inhibited the cyclooxygenase activity of untreated synthase in the manner observed with similar levels of glutathione peroxidase. Any stimulatory effect of the synthase peroxidase on the synthase cyclooxygenase is thus likely to involve an intramolecular mechanism. Participation of peroxidase intermediates (Compounds 1 and II) in the initiation of a cyclooxygenase free radical chain reaction may provide an intramolecular mechanism for stimulation of the 0 1985 Academic Press, Inc. synthase cyclooxygenase by the synthase peroxidase.
Prostaglandin
H synthase,
biosynthesis
of
enzymatic
a fatty
forms
the
hydroperoxide,
oxide
for
initiation The is
of
synthase
in
the
value
for
synthase
PGG2 prevents
cannot
mechanism result
lower
this
1 Abbreviations
more
-6
of
peroxide
PGH
efficient
positive used
synthase
are:
PGG2.
that prostaglandin
$1.50
0 I985 by Academic Press, Inc. of reproduction in any form reserved.
918
of
the
the
importance
of
the
With activity
of
that
actually of
is
removes
activities
sufficiently
We propose
initiation symbiosis
levels
the the
of
a Km the
hydroperoxides,
but
to
suppress
the
the
presence
of
affords cyclooxygenase cyclooxygenase 62;
which
hydroper-
two
peroxidase
high
levels
activity. in
of
the two
activity
M lipid that
in
exhibits
biosynthesis.
the of
-8
these
eicosanoid
M (1.2).
step
prostacyclins,
activity
because
accumulation
peroxidase for
of
0006-291X/85
10
cyclooxygenase
heme-dependent
Copyrighr All rights
an
effectively
endogenous
control
about
10
between
committed
(cyclooxygenase)
requires
interest
first
and
a peroxidase
relationship
overall
the
oxygenase
and
and
considerable
of
acid
PGG2', (l),
hydroperoxides.
catalyzes
thromboxanes,
prostglandins,
activities:
synthase
which
PGH.
an
it
the
intramolecular The
reaction. activity prostaglandin
of
PGH H.
Vol.
130,
No. 2, 1985
synthase than
is other
BIOCHEMICAL
a much fatty
acid
heme-dependent
METHODS
more
explosive
BIOPHYSICAL
amplifier
oxygenases,
peroxidase
AND
AND
such
of as
RESEARCH
lipid
COMMUNICATIONS
hydroperoxide
soybean
levels
lipoxygenase,
which
lack
a
activity.
MATERIALS
Acetylsalicylic acid and N,N,N'.N'-tetramethylphenylenediamine were obtained from Sigma Chemical Co., St. Louis, MO. Arachidonic acid was purchased from Nu Chek Preps, Inc., Elysian, MN, and was treated with sodium borohydride to reduce any contaminating peroxides. Hydrogen peroxide was from Fisher Scientific Company, Fair Lawn, NJ. Prostaglandin H synthase was purified as the apoenzyme (3) and reconstituted with hematin (4). Cyclooxygenase activity was assayed with a polarographic oxygen electrode in a reaction cuvette containing 3 ml of 0.1 M potassium phosphate, pH 7.2/0.67 mM phenol/O.10 mM arachidonate (3). Peroxidase activity was assayed with hydrogen peroxide as substrate and tetramethylphenylenediamine as cosubstrate (1). Protein was assayed as described by Peterson (5).
RESULTS
AND
The
cyclooxygenase-catalyzed
reactions,
appears
having for
DISCUSSION
a free the
to
radical
of
the
However,
several
synthase
has
radical
observations
activity as
by
similar The
peroxidase
action
as
of of
the
one
synthase
dimer
with
the
cyanide
seem the
is
provide in
the
peroxidase
of
H202
parallels
cyclooxygenase
cyclooxygenase
are
the and their
reaction
initiation
PGH
activity. increase
closely
of
first. of
cyclooxygenase
(1)
in enzyme
activity
effectiveness
the
same at
in
essential
a route
cosubstrates
substrates
oxygenase acids
paradoxical
protein's
relative
of
to
presence
peroxidase
initiators
(9);
interfered
and with
(3).
heme-containing reactions
process
the
many b)
and
cyclooxygenase-catalyzed intramolecular
a)
activity
levels
on
peroxidase
effectivenesss
both
that
(7.8);
hydroperoxides
c)
indicated effect
include:
cyclooxygenase
might
fatty
polyunsaturated
seems
The
activity
known
Hydroperoxide
it
reaction.
peroxidase
a stimulatory
and
all of
mechanism.
(1.6).
chain
like
(6).
autooxidation
reaction
reaction
observations
relative
the
chain
a peroxide-removing
lipid
resemble
cyclooxygenase
initiation
These
reaction
or
by the
peroxidase could
intermolecular cyclooxygenase
in
conceivably interactions on
919
another
stimulating occur
by of
dimer.
the
an peroxidase Possible
on
Vol.
130,
No. 2, 1985
intermolecular
processes
dimers,
production
(10)
would
of
AND
include
a diffusible
BIOPHYSICAL
direct
RESEARCH
contact
stimulant,
or
COMMUNICATIONS
between
removal
synthase
of
a toxic
byproduct
* To
determine
if
intermolecular of
BIOCHEMICAL
in
adding
only
synthase,
to
treated 1% of that
its
(2
aspirin
synthase
was
as
aspirin
would
of not
the
peroxidase
(1.1
the
JIM)
significantly
mol
Aspirin-Treated moluntreated
to
due
to
the
synthase
because during
decreased
in
untreated the
additional
and
not
such the
to
the
a level 30
Synthase Synthase
Fiqure 1: Inhibition of cyclooxygenase activity of PGH synthase by aspirin-treated PGH synthase. The cyclooxygenase activities of the indicated proportions of aspirin-treated synthase and untreated synthase 1.1 nM subunit) were assayed as described in the text. 920
the
Methods.
synthase)
it,
of
and
and
synthase with
90%
injected,
Materials
was
below
cuvette
synthase
along
inactivate
at
was
aspirin-treated
added
to
aspirin-treated
untreated
decrease
was
activity
nM subunit)
the
The
holoenzyme
reaction
aspirin-treated 1).
aspirin-treated
this
in
be activity
activity of
described (of
of
of (~50
cyclooxygenase
amounts
as
of
synthase
a cyclooxygenase
(Figure
aspirin
PGH
could
cyclooxygenase
form
the
Various
activity
activity
peroxidase on
the
Pure
synthase
ratio
the
effect in
leaving
determined
the
increased
the
reduce
into
untreated
peroxide-scavenging amount
to
while
cyclooxygenase fashion
small
mM)
activity
a linear
of
activity,
injected
before
observed
examined
treatment.
then
cyclooxygenase
effect
PGH synthase.
level
synthase'were
The
intact
initial
immediately
we
peroxidase
aspirin
before
stimulatory
nature,
the some
with
the
set
of
Vol.
130,
No. 2, 1985
used
to
assay
the
x-axis
mole
of
cyclooxygenase indicated
of
corresponded reasonably
(in
as
form
of
glutathione
are
interfere
The
with,
activity the
same
of of
did
of
untreated
when
the
than
augment,
need
be present
10 40
(1).
ratio
of
70
peroxidase not
stimulate, synthase,
evidence
therfore
points
peroxidase
dimer
peroxidases
per
about
synthase
synthase)
holoenzyme
heme-containing
rather
adding
only
to
cyclooxygenase
ratio
accumulated
curve
protein
ratio
activity
did.
in
the
aspirin-treated
cyclooxygenase
Other
cyclooxygenase.
Thus,
cyclooxygenase
present
treated
protein/protein
(1).
peroxidase of
of
the
peroxidase/cyclooxygenase
the
the
of
activity
glutathione
suppressed
intermediates
10 moles suppress
This
cyclooxygenase
the
a stimulation
to
the
the
instead
much to
to
suppressed
but
about
maximally
enzyme.
COMMUNICATIONS
Extrapolation
a peroxidase/cyclooxygenase
close
separately
of
could
untreated
to
(11).
a ratio
protein
the
BIOPHYSICALRESEARCH
activity
that
untreated
activity
that
BIOCHEMICALAND
with
of
the
a cell
initiation
of
would
also
tend
prostaglandin
formation. Because
only
catalytic
one
activity
heme (4).
it
seems
cyclooxygenase
by
the
peroxidase
cyclooxygenase
reactions
share
One 2,
where
in
the
possible
scheme
peroxidase of
mechanism
each
molecule
of
activating
another
reaction.
With
molecule
of
would
be
much
more
one
molecule
postulated
the
PGG2
such
as
than
that
hydroperoxide soybean
of
synthase
dimer another
(13),
921
proposed
Figure to
each
character be
of
which
(12)
of
the
accounting
of
chain a
action
acceleration
initiation
as
capable
involves
cyclooxygenase
which
serve
This
would
Such
perhaps
in
cyclooxygenase
during
initiation
shown
reaction.
hydroperoxide.
the
are
branched
in
forms.
is
II,
process,
a system
and
enzyme
I and
initiating
to
for lipoxygenase
one
the
peroxidase
intermediates
acceleration
regard
the
autoaccelerative,
a two-step
the in
of
cyclooxygenase
of
radical-chain
by
full
intermediate
Compounds
an
for
stimulation
common
sharing
dimer.
initiation
explosive
for
because
synthesized
synthase
order
of
occurs some
have
hydroperoxide,
second
that
cyclooxygenase
would
dimer
likely
intermediates,
initiation
reaction
for
per
would
required reaction,
such for
the
only as observed
be
Vol.
130,
BIOCHEMICALAND
No. 2, 1985
ROOH ROH
BIOPHYSICAL
ROOH
RESEARCH
COMMUNICATIONS
q ROOH
AH
/
Figure 2: A hypothetical mechanism for the stimulation of synthase cyclooxygenase activity by synthase peroxidase intermediates. The formal oxidation states of the heme iron of the synthase (E) are indicated by Roman numerals. ROOH: Lipid hydroperoxide; ROH: lipid alcohol; ROO: hydroperoxy radical; RH: polyunsaturated fatty acid; AH2: peroxidase cosubstrate; AH: oxidized cosubstrate.
differences
in
enzyme. via
kinetics
Alternatively,
Compounds
small
The
the
I or
amounts
oxygenase
of
II
retention in
explosive
the this
same
that survival
ACKNOWLEDGEMENT: Public Health the University
the
be
cyclooxygenase
much
than
the
non-heme
of
for
soybean
symbiotic
many
rapid
many
animals
the
soybean
cyclooxygenase sensitive
to of
of
two
these
suggests
two that
by
low
activities
catalyt the
sensi
amounts
provides
C
may
have
species.
This work was supported by Service (GM30509) and a Medical of Illinois at Chicago, College
3. 4. 5. 6.
Kulmacz, R-J., Lands, Ohki, S., Ogino, N., 254, 829-836 Kulmacz, R-J., Lands, Kulmacz, R.J., Lands, Peterson, G.L. (1979) Hemler, M.E., Lands,
W.E.M. Yamamoto, W.E.M. W.E.M. Anal. W.E.M.
tive
of
a grant from the United Scientist Fellowship of Medicine
States (JFM) from
REFERENCES 1. 2.
the
oxygenase.
formation
of
and
the
initiation
linkage
prostaglandin
combination
more
of
peroxide-dependent
iron
in
and
initiation
inherently
holoenzyme
value
the
peroxide-dependent
unusual
enhancement
hydroperoxide important
in of
the
may
between
hydroperoxide
reaction
activities and
reaction
(1983) S., (1985) (1984) Biochem. (1980)
922
Prostaglandins Hayaishi. 0.
25, (1979)
Prostaglandins
J. Biol. J.
100, Biol.
Chem. 201-220. Chem.
29, 259, 255,
531-540. J. Biol. 175-190. 6358-6363. 6253-6261.
Chem.
Vol. 130, No. 2, 1985
1. 8. 9. 10. 11. 12. 13.
BIOCHEMICAL
AND BIOPHYSICALRESEARCH
COMMUNICATIONS
Nugteren, D.H., Beerthuis, R.K., van Dorp, D.A. (1966) Rec. Trav. Chim. Pays-Bas 85, 405-419. Takeguchi, C., Kohno, E., Sih, C.J. (1971) Biochemistry 10, 2372-2376. Marshall, P.J., Kulmacz. R.J., Lands, W.E.M. (1984) in Oxygen Radicals in Chemistry and Biology (W. Bors, M. Saran, D. Tait, eds.), pp. 299-304, de Gruyter, Berlin. Egan, R.W., Paxton, J., Kuehl, F.A., Jr. (1976) J. Biol. Chem. 251, 7329-7335. Rome, L.H., Lands, W.E.M. (1975) Proc. Natl. Acad. Sci. USA 72, 4863-4865. Boudart, M. (1968) Kinetics of Chemical Processes, pp. 124-136, Prentice-Hall, Englewood Cliffs, NJ. (1972) J. Biol. Chem. 247, 1038-1047. Smith, W.L., Lands, W.E.M.
923