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Control of heme synthesis by feedback inhibition
Vol. 18, No. 2, 1965
BIOCHEMICAL AND BIOPHYSICALRESEARCHCOMMJNICATIONS
CONTROL OF HEME SYNTHESIS BY FEEDBACK INHIBITION Doris
Karibian
and Irving
Department of Medicine, Albert and Bronx Municipal Hospital
ReceivedNovember18,
al,
1958)
involved animal
provides the
cells.
regulation
the
acid
bilinogen
(PBG) was less
bacterium,
catalyzes
however,
was observed
pointed
to ALI
In the
studies
incorporation
The results feedback
rabbit
suggest inhibition
that in
here
the
conversion 243
in
from
This
enzyme
the
form
cells
site
for in
of
this
by hdn
have
These
negative
this
effects
feed-
bacterium. of hemin
into
on
heme in
been
mechanism,
of glycine
porpho-
precursor.
and ALA-4-Cl4
control
A to
The enzyme ALA
was the
(reticulocytes) a similar
processes
synthetase
synthesis
by hemin
et
shown that
intact
as the
14
of glycine-2-C
the
of ALA to
not ALA,
reported
erythrocytes
1954).
of porphyrin
synthesis
Morel1
and succinyl-coenzyme
With
synthetase
of porphyrin
have
condensation
but
of
by hemin.
(Shemin,
inhibition
synthesize
mechanism
(ALA)
inhibited
inhibited.
when glycine,
control
immature
the
study
(1962) acid
to 1950,
biosynthetic
of glycine
deltaaminolevulinic
et al,
the
and Lascelles
condensation
which
the
for
are
cells
Shemin
of this
spheroides
dehydrase
back
1950,
of deltaaminolevulinic
catalyzes
College of Medicine New York, New York
erythroid
an opportunity
Rhodopseudomonas
findings
immature
et al,
Burnham
preparations
form
of
(London
in
Einstein Center,
1964
The capacity heme --in vitro
M. London
examined. involving
to ALA,
is
Vol. 18, No. 2, 1965
operative
in
BIOCHEMICAL
these
animal
Methods: were
bled
(about
were
centrifugation.
produced
reticulocytoses
tiorsplus
one ml
containing
the
in
15-20%.
were
added
following:
0.76%
0.02
buffer,
When a lysate
distilled
adjusted
with
the
saline
lysate;
incubation.
0.8
to
cpm/umole
ml
1.0
to of
give the
The tubes
were
95% 02-5%
co2.
I
.
mg per
or ALA-4-C14,
solution 0.12
of
ml
total
(1)
hemin
umole
volume
At
the
in
KCl,
pH 7.8
of 1.2
cell
14
1.6
solution
without
a 37O water
bath
incubation,
MgC12.6H20,
they
was and
suspensions. in
mixture
cell
In hemin room were
12
suspension
or
and streptoof
umole
cpm/umole;
in
cells
and plasma
, 0.25
ml.
of
tonicity
penicillin
4 x lo5 to
solution
the
solution
glycine-2-C
prepara-
volumes
The incubation
of
end of
cell
or K2HP04 - KH2P04
1 minute,
of
cells
0.15%
equal
whole
and
bleeding
a saline
aliquots . solution'; (3)
0.5
of
8 ml of
1 ml
(4)
packed
such
0.039%
rabbits
3 days)
One ml of
as for
ml;
KOH-buffer-HCl incubated
ml of
saline
of
least
series
for
concentrated
Conditions
0.12
l-3
to
mixed
added
(2)
mycin
were
included:
at
was required,
were
tubes
top
buffer,
solution
conical
ml
lo-fold
for
NaCl,
M Tris-HCl
water
New Zealand
prolonged
of
100 mg% glucose,
and cold
the
More
plasma
pH 7.4.
Preparations. 30 ml daily
obtained
following
RESEARCH COMMUNICATIONS
cells.
Reticulocvte
repeatedly
reticulocytes
AND BIOPHYSICAL
(5)
control
8 x lo5 saline samples,
was added. air chilled
or in in
ice,
Hemin solution: (a) 1.2 mg hemin was dissolved in 0.1 ml 1N KOH and diluted with 1.0 ml freshly boiled distilled H 0 and 0.1 ml 0.08 ml 1N HCl was ad 8 ed with mix1M tris or phosphate buffer: ing and the volume was made up to 2 ml with H20; (b) for higher concentrations, 8 mg hemin was dissolved in twice the above volumes of KOH, buffer and HCl and the volume was again made The final concentration of hemin when up to 2 ml with H 0. 0.12 ml of solute -8 n (a) was present in an incubation mixture of 1.2 ml was 1 x lOa M.
244
Vol. 18, No. 2, 1965
and 10 ml of ~20)
BIOCHEMICAL
cold
was added
solution,
cell
lysate
to provide
equal
experimental
red
in
to
glacial
that
which
was added
from
pyridine-chloroform,
infinite
acetic
acid
to
duplicate
with
(Fischer,
Nearly
agreement
the
+ 5 per
% Change
from
1 vol
Hemin added
hemolysate It
to
in
the
after
treatment
was recrystallized was measured
experiments
Effect of Hemin on Utilization for Heme Synthesis in Intact
were
carried
at
out
in
cent.
I
of Glycine-2-C and Lysed Rabbit
14
of Glycine-2-C into Heme
and
samples.
radioactivity
Table
Incorporation
control
1941).
all
within
cells
had been
the
from
and its
thickness.
packed
heme as carrier.
Hemin was crystallized with
RESEARCH COMMUNICATIONS
(1 vol
unlabeled
amount
samples,
AND BIOPHYSICAL
14
Incorporation into
Control
% Change
and ALA-4-C14 Reticulocytes
14
of ALA-4-C Heme from
Control
42
21
Mean change
-48.6
-12.2
S.E.
+ 3.00
+ 4.84
Number
of
experiments
p < .OOl
Results: on the by the tions
utilization
intact
Table of
and lysed
percentage to which
I presents
no hemin
14
glycine-2-C
rabbit
change
.05>p).O2
the
effects
and ALA-4-C
reticulocytes.
from
the
245
14
values At
this
added
for
The data
control
was added.
of
hemin
heme synthesis are
obtained concentration
recorded in
as
prepara(1 x 10m4M)
Vol. 18, No. 2, 1965
BIOCHEMICAL AND BIOPHYSICALRESEARCHCOMMUNICATIONS
the
on the
effect
tory
of hemin
in all
but
inhibition
of nearly
mean effect tion
of
one of
of hemin
only
12 per
nificance.
the
and in
42 experiments. cent
on the
utilization
cent
hemin
instances
was an
significant.
The
of ALA-4-C 14 was an inhibi-
and was of only
several
was inhibi-
The mean effect
and is highly
of added
14
of glycine-2-C
50 per
The effects
variable
utilization
marginal
statistical
on utilization
enhanced
sig-
of ALA were
synthesis
of heme was
observed. Figure on the
1 shows the
synthesis
effect
of heme from
of concentration
glycine
in
intact
of added rabbit
hemin
reticulocytes
d E iooe 86 1
60 fL
;
60-
Y g :
\ %
-*
-\
.N
.0
HEME *z
40-
5 :F
20-
% LI:
0
Preincubotion Incubation
I I x10-4
The effect utilization
I
I 3x10-%4
is
creased
at higher
appreciable
Figure throughout
2.
at
1 x 10
-4
M and is progressively
on the
in-
concentrations,
The effects incubation
4xlO-‘M
OF HEMIN
of various concentrations of added hemin of glycine-2-C14 for heme synthesis.
Inhibition
term
-------.
2x10-4
CONCENTRATION
1.
-5
2 hours
I 5X165M
--.- \
with HemIn 30’
of hemin
and in
a short-term
The inhibitory a 24-hour
on the
period
effect of
synthesis
incubation occurs
incubation.
rapidly
of heme in a longare presented and is
in
demonstrable
BIOCHEMICAL AND BlOPHYSlCALRESEARCHCOMMUNICATIONS
Vol. 18, No. 2, 1965
;E1400 F 5 2 1000
1000 c5
/
N \ 1200
3 1200 B
-CONTROL
P
800
E 3 600 2 =
400 200 4
2.
8
12
16 20 HOURS
Inhibitory effect for hema synthesis.
24
7.90
in
isotonic
and in Tris-NaCl
was observed inhibitory pH which
at pH 7.3-7.4 effect
the
was observed
added
range
to 8.70.
absence
The results
inhibition
heme synthesis
in
by hemin rabbit
of
hemin
was
of pH 6.35 Maximal
added
over
inhibition
by hemin which
precede
of these of
the
reticulocytes;
of ADA was variable
reactions
the
72
the
synthesis
hemin. full
to
The
range
of
was studied.
significant
of
pH 7.25 in
of hemin
Discussion:
tion
buffer,
in
1
60
of glycine-2-$*
and without
buffer
/
36 48 MINUTES
on utilization
of heme with
phosphate
I
w1
31
of hemin
The synthesis studied
28
and less appears the
studies
utilization the
therefore
formation
of glycine
effect
significant.
indicate
on the
+ Glycine
of ADA: -co2 ?o(
Pyridoxal Phosphate
247
site
among the
ADA Synthetase Succinyl-CoA
utiliza-
The principal to be found
for
-amino 4 -Keto adipic acid (=w
*
ALA
Vol. 18, No. 2, 1965
8lOCHEMlCAL AND 8lOPHYSlCAL RESEARCHCOMMUNICATIONS
These activation the
of
reactions
glycine,
condensation
of
by ALA synthetase, to
form
tion
ALA.
of
these very
It
readily;
in
form
ANA,
possible
hemin
but
the
that
rabbit
of
succinate,
the
system;
catalyzed
decarboxylation
of ARA
may inhibit
the is
activa-
available
on
The decarboxylation
of ARA occurs
but
that
it
is
possible,
of AKA to ALA.
a site
succinate,
phosphate
no information
and Lascelles
likely
and
and the
that
conversion
of Burnham
synthesis
glycine
seems unlikely,
the
seems most
activated
at present. it
activation
by a pyridoxal
or glycine,
possibilities
may influence
it
is
the
probably
to
succinate
studies
include
In
the
hemin
light
of
in Rhodopseudomonas
spheroides,
of
of
feedback
reticulocyte
is
control
at
the
level
the
heme
of ALA
synthetase.
which
the
The concentration
of
hemin
inhibitory
is
observed
extent
to which
of
binding
its
note in
that
effect the
within
free
at
of
this
a mechanism
Coupled
with
the
globin
(Bruns
in
coordination
of
the
are
order
feedback
affords
a grant
cell
concentration
Negative
the
the
for
the
stimulatory
and London),
This work the Office
of
the
unknown,
the
not
reticulocyte
cell
known.
It
is
of
10B4M,
in
Rhodopseudomonas of
regulation effect
of
control
synthesis
present
is in
the extent
relevant
to
porphyrin spheroides.
heme synthesis
by heme
of porphyrin
synthesis.
hemin
synthesis
on the
of
may participate
heme and of
globin.
was supported by USPHS grant HE-02803 of Naval Research Nonr 4094. 248
at
reticulocytes
can inhibit
mechanism of
since
and the
which
control
this
the
is
can penetrate
protoporphyrin,
a concentration
synthesis
hemin
within
and
Vol. 18, No. 2, 1965
BIOCHEMICAL AND BIOPHYSICALRESEARCHCOMMUNICATIONS
BrUnB, G.P. and London, 1.X. (accompanying paper) Burnham, B.F. and Lascelles, J., Biochem. J. 87, 462 (1963) Fischer, H., Org. syntheses 2l, 53 (1941) London, 1.X., Shemin, D. and Rittenberg, D., J. Biol. Chem. 183, 749 (1950) MOrell, H., Savoie, J.C. and London, 1.X., J. Biol. Chem. 233, 923 (1958) shemin, D., The Harvey Lectures, Series 50 (1954-1955) (Academic Press Inc., New York, 1956) p. 258 Shemin, I)., London, 1.X. and Rittenberg, D., J. Biol. Chem. 183, 757 (1950)
249
BIOCHEMICAL AND BIOPHYSICALRESEARCHCOMMJNICATIONS
CONTROL OF HEME SYNTHESIS BY FEEDBACK INHIBITION Doris
Karibian
and Irving
Department of Medicine, Albert and Bronx Municipal Hospital
ReceivedNovember18,
al,
1958)
involved animal
provides the
cells.
regulation
the
acid
bilinogen
(PBG) was less
bacterium,
catalyzes
however,
was observed
pointed
to ALI
In the
studies
incorporation
The results feedback
rabbit
suggest inhibition
that in
here
the
conversion 243
in
from
This
enzyme
the
form
cells
site
for in
of
this
by hdn
have
These
negative
this
effects
feed-
bacterium. of hemin
into
on
heme in
been
mechanism,
of glycine
porpho-
precursor.
and ALA-4-Cl4
control
A to
The enzyme ALA
was the
(reticulocytes) a similar
processes
synthetase
synthesis
by hemin
et
shown that
intact
as the
14
of glycine-2-C
the
of ALA to
not ALA,
reported
erythrocytes
1954).
of porphyrin
synthesis
Morel1
and succinyl-coenzyme
With
synthetase
of porphyrin
have
condensation
but
of
by hemin.
(Shemin,
inhibition
synthesize
mechanism
(ALA)
inhibited
inhibited.
when glycine,
control
immature
the
study
(1962) acid
to 1950,
biosynthetic
of glycine
deltaaminolevulinic
et al,
the
and Lascelles
condensation
which
the
for
are
cells
Shemin
of this
spheroides
dehydrase
back
1950,
of deltaaminolevulinic
catalyzes
College of Medicine New York, New York
erythroid
an opportunity
Rhodopseudomonas
findings
immature
et al,
Burnham
preparations
form
of
(London
in
Einstein Center,
1964
The capacity heme --in vitro
M. London
examined. involving
to ALA,
is
Vol. 18, No. 2, 1965
operative
in
BIOCHEMICAL
these
animal
Methods: were
bled
(about
were
centrifugation.
produced
reticulocytoses
tiorsplus
one ml
containing
the
in
15-20%.
were
added
following:
0.76%
0.02
buffer,
When a lysate
distilled
adjusted
with
the
saline
lysate;
incubation.
0.8
to
cpm/umole
ml
1.0
to of
give the
The tubes
were
95% 02-5%
co2.
I
.
mg per
or ALA-4-C14,
solution 0.12
of
ml
total
(1)
hemin
umole
volume
At
the
in
KCl,
pH 7.8
of 1.2
cell
14
1.6
solution
without
a 37O water
bath
incubation,
MgC12.6H20,
they
was and
suspensions. in
mixture
cell
In hemin room were
12
suspension
or
and streptoof
umole
cpm/umole;
in
cells
and plasma
, 0.25
ml.
of
tonicity
penicillin
4 x lo5 to
solution
the
solution
glycine-2-C
prepara-
volumes
The incubation
of
end of
cell
or K2HP04 - KH2P04
1 minute,
of
cells
0.15%
equal
whole
and
bleeding
a saline
aliquots . solution'; (3)
0.5
of
8 ml of
1 ml
(4)
packed
such
0.039%
rabbits
3 days)
One ml of
as for
ml;
KOH-buffer-HCl incubated
ml of
saline
of
least
series
for
concentrated
Conditions
0.12
l-3
to
mixed
added
(2)
mycin
were
included:
at
was required,
were
tubes
top
buffer,
solution
conical
ml
lo-fold
for
NaCl,
M Tris-HCl
water
New Zealand
prolonged
of
100 mg% glucose,
and cold
the
More
plasma
pH 7.4.
Preparations. 30 ml daily
obtained
following
RESEARCH COMMUNICATIONS
cells.
Reticulocvte
repeatedly
reticulocytes
AND BIOPHYSICAL
(5)
control
8 x lo5 saline samples,
was added. air chilled
or in in
ice,
Hemin solution: (a) 1.2 mg hemin was dissolved in 0.1 ml 1N KOH and diluted with 1.0 ml freshly boiled distilled H 0 and 0.1 ml 0.08 ml 1N HCl was ad 8 ed with mix1M tris or phosphate buffer: ing and the volume was made up to 2 ml with H20; (b) for higher concentrations, 8 mg hemin was dissolved in twice the above volumes of KOH, buffer and HCl and the volume was again made The final concentration of hemin when up to 2 ml with H 0. 0.12 ml of solute -8 n (a) was present in an incubation mixture of 1.2 ml was 1 x lOa M.
244
Vol. 18, No. 2, 1965
and 10 ml of ~20)
BIOCHEMICAL
cold
was added
solution,
cell
lysate
to provide
equal
experimental
red
in
to
glacial
that
which
was added
from
pyridine-chloroform,
infinite
acetic
acid
to
duplicate
with
(Fischer,
Nearly
agreement
the
+ 5 per
% Change
from
1 vol
Hemin added
hemolysate It
to
in
the
after
treatment
was recrystallized was measured
experiments
Effect of Hemin on Utilization for Heme Synthesis in Intact
were
carried
at
out
in
cent.
I
of Glycine-2-C and Lysed Rabbit
14
of Glycine-2-C into Heme
and
samples.
radioactivity
Table
Incorporation
control
1941).
all
within
cells
had been
the
from
and its
thickness.
packed
heme as carrier.
Hemin was crystallized with
RESEARCH COMMUNICATIONS
(1 vol
unlabeled
amount
samples,
AND BIOPHYSICAL
14
Incorporation into
Control
% Change
and ALA-4-C14 Reticulocytes
14
of ALA-4-C Heme from
Control
42
21
Mean change
-48.6
-12.2
S.E.
+ 3.00
+ 4.84
Number
of
experiments
p < .OOl
Results: on the by the tions
utilization
intact
Table of
and lysed
percentage to which
I presents
no hemin
14
glycine-2-C
rabbit
change
.05>p).O2
the
effects
and ALA-4-C
reticulocytes.
from
the
245
14
values At
this
added
for
The data
control
was added.
of
hemin
heme synthesis are
obtained concentration
recorded in
as
prepara(1 x 10m4M)
Vol. 18, No. 2, 1965
BIOCHEMICAL AND BIOPHYSICALRESEARCHCOMMUNICATIONS
the
on the
effect
tory
of hemin
in all
but
inhibition
of nearly
mean effect tion
of
one of
of hemin
only
12 per
nificance.
the
and in
42 experiments. cent
on the
utilization
cent
hemin
instances
was an
significant.
The
of ALA-4-C 14 was an inhibi-
and was of only
several
was inhibi-
The mean effect
and is highly
of added
14
of glycine-2-C
50 per
The effects
variable
utilization
marginal
statistical
on utilization
enhanced
sig-
of ALA were
synthesis
of heme was
observed. Figure on the
1 shows the
synthesis
effect
of heme from
of concentration
glycine
in
intact
of added rabbit
hemin
reticulocytes
d E iooe 86 1
60 fL
;
60-
Y g :
\ %
-*
-\
.N
.0
HEME *z
40-
5 :F
20-
% LI:
0
Preincubotion Incubation
I I x10-4
The effect utilization
I
I 3x10-%4
is
creased
at higher
appreciable
Figure throughout
2.
at
1 x 10
-4
M and is progressively
on the
in-
concentrations,
The effects incubation
4xlO-‘M
OF HEMIN
of various concentrations of added hemin of glycine-2-C14 for heme synthesis.
Inhibition
term
-------.
2x10-4
CONCENTRATION
1.
-5
2 hours
I 5X165M
--.- \
with HemIn 30’
of hemin
and in
a short-term
The inhibitory a 24-hour
on the
period
effect of
synthesis
incubation occurs
incubation.
rapidly
of heme in a longare presented and is
in
demonstrable
BIOCHEMICAL AND BlOPHYSlCALRESEARCHCOMMUNICATIONS
Vol. 18, No. 2, 1965
;E1400 F 5 2 1000
1000 c5
/
N \ 1200
3 1200 B
-CONTROL
P
800
E 3 600 2 =
400 200 4
2.
8
12
16 20 HOURS
Inhibitory effect for hema synthesis.
24
7.90
in
isotonic
and in Tris-NaCl
was observed inhibitory pH which
at pH 7.3-7.4 effect
the
was observed
added
range
to 8.70.
absence
The results
inhibition
heme synthesis
in
by hemin rabbit
of
hemin
was
of pH 6.35 Maximal
added
over
inhibition
by hemin which
precede
of these of
the
reticulocytes;
of ADA was variable
reactions
the
72
the
synthesis
hemin. full
to
The
range
of
was studied.
significant
of
pH 7.25 in
of hemin
Discussion:
tion
buffer,
in
1
60
of glycine-2-$*
and without
buffer
/
36 48 MINUTES
on utilization
of heme with
phosphate
I
w1
31
of hemin
The synthesis studied
28
and less appears the
studies
utilization the
therefore
formation
of glycine
effect
significant.
indicate
on the
+ Glycine
of ADA: -co2 ?o(
Pyridoxal Phosphate
247
site
among the
ADA Synthetase Succinyl-CoA
utiliza-
The principal to be found
for
-amino 4 -Keto adipic acid (=w
*
ALA
Vol. 18, No. 2, 1965
8lOCHEMlCAL AND 8lOPHYSlCAL RESEARCHCOMMUNICATIONS
These activation the
of
reactions
glycine,
condensation
of
by ALA synthetase, to
form
tion
ALA.
of
these very
It
readily;
in
form
ANA,
possible
hemin
but
the
that
rabbit
of
succinate,
the
system;
catalyzed
decarboxylation
of ARA
may inhibit
the is
activa-
available
on
The decarboxylation
of ARA occurs
but
that
it
is
possible,
of AKA to ALA.
a site
succinate,
phosphate
no information
and Lascelles
likely
and
and the
that
conversion
of Burnham
synthesis
glycine
seems unlikely,
the
seems most
activated
at present. it
activation
by a pyridoxal
or glycine,
possibilities
may influence
it
is
the
probably
to
succinate
studies
include
In
the
hemin
light
of
in Rhodopseudomonas
spheroides,
of
of
feedback
reticulocyte
is
control
at
the
level
the
heme
of ALA
synthetase.
which
the
The concentration
of
hemin
inhibitory
is
observed
extent
to which
of
binding
its
note in
that
effect the
within
free
at
of
this
a mechanism
Coupled
with
the
globin
(Bruns
in
coordination
of
the
are
order
feedback
affords
a grant
cell
concentration
Negative
the
the
for
the
stimulatory
and London),
This work the Office
of
the
unknown,
the
not
reticulocyte
cell
known.
It
is
of
10B4M,
in
Rhodopseudomonas of
regulation effect
of
control
synthesis
present
is in
the extent
relevant
to
porphyrin spheroides.
heme synthesis
by heme
of porphyrin
synthesis.
hemin
synthesis
on the
of
may participate
heme and of
globin.
was supported by USPHS grant HE-02803 of Naval Research Nonr 4094. 248
at
reticulocytes
can inhibit
mechanism of
since
and the
which
control
this
the
is
can penetrate
protoporphyrin,
a concentration
synthesis
hemin
within
and
Vol. 18, No. 2, 1965
BIOCHEMICAL AND BIOPHYSICALRESEARCHCOMMUNICATIONS
BrUnB, G.P. and London, 1.X. (accompanying paper) Burnham, B.F. and Lascelles, J., Biochem. J. 87, 462 (1963) Fischer, H., Org. syntheses 2l, 53 (1941) London, 1.X., Shemin, D. and Rittenberg, D., J. Biol. Chem. 183, 749 (1950) MOrell, H., Savoie, J.C. and London, 1.X., J. Biol. Chem. 233, 923 (1958) shemin, D., The Harvey Lectures, Series 50 (1954-1955) (Academic Press Inc., New York, 1956) p. 258 Shemin, I)., London, 1.X. and Rittenberg, D., J. Biol. Chem. 183, 757 (1950)
249