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Accelerated Publication Journal of Biological Chemistry
Heme Oxygenase–2 Activated by Calcium-Calmodulin
Darren Boehning‡, Leela Sedaghat‡, Thomas W. Sedlak‡¶, and Solomon H. Snyder‡§¶║
‡Departments of Neuroscience, §Pharmacology and Molecular Sciences, and
¶Psychiatry and Behavioral Sciences, Johns Hopkins University School of Medicine,
725 N. Wolfe Street, Baltimore, MD 21205, USA
║To whom correspondence should be addressed: Department of Neuroscience, Johns
Hopkins University School of Medicine, 725 N. Wolfe Street, 813 WBSB, Baltimore, MD
21205. Tel.: 410-955-3024; Fax: 410-955-3623; E-mail: [email protected].
Character count: 27,868 Running title: Calcium-calmodulin activates HO2
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Summary
The heme oxygenase family of enzymes catalyzes the metabolism of heme to
biliverdin, ferrous iron, and carbon monoxide (CO). At least two isoforms exist, heme
oxygenase-1 (HO1) and heme oxygenase-2 (HO2), which are encoded by separate
genes. Heme oxygenase-2 is selectively enriched in neurons, and substantial evidence
suggests that HO2-derived CO functions as a neurotransmitter/neuromodulator.
However, a molecular mechanism for the rapid activation of HO2 during neuronal
activity has not been described. Through a yeast-2-hybrid screen we identified
calmodulin as a potential regulator of HO2 activity. Calmodulin binds with nanomolar
affinity to HO2 in a calcium-dependent manner via a canonical 1-10 motif, resulting in a
three fold increase in catalytic activity. Mutations within this motif block calmodulin
binding and calcium-dependent stimulation of enzyme activity in vitro and in intact cells.
The calcium mobilizing agents ionomycin and glutamate stimulate endogenous HO2
activity in primary cortical cultures, establishing in vivo relevance. Calcium-calmodulin
provides a mechanism for rapid and transient activation of HO2 during neuronal activity.
Introduction
Nitric oxide (NO)1 and carbon monoxide (CO) are increasingly appreciated as
neurotransmitters in the central and peripheral nervous system(1). Most
neurotransmitters are stored in synaptic vesicles with only a small percentage released
following each neuronal depolarization and large storage pools remaining for
succeeding neural volleys. Neither NO or CO are stored in vesicles so that their release
following neuronal depolarization is presumably coupled to activation of their respective
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biosynthetic enzymes, neuronal NO synthase (nNOS) and heme oxygenase-2 (HO2).
For NO, calcium influx into depolarized neurons binds to calmodulin, activating
nNOS(2). No mechanism for rapid activation of HO2 has yet been reported. Recently
we showed that CK2 (casein kinase-2) phosphorylates and activates HO2(3). In brain
cultures protein kinase C phosphorylates and activates CK2. Since protein kinase C
can be activated by calcium, neuronal depolarization and associated calcium entry
might activate protein kinase C to phosphorylate and activate CK2 which in turn
phosphorylates and activates HO2(3). However, it is not likely that this mechanism
would be rapid enough to provide CO for most instances of neurotransmission.
In the present study we report the binding of calmodulin to HO2 in a calcium-
dependent fashion. In response to calcium mobilization by ionomycin and the excitatory
neurotransmitter glutamate in neurons, we observe physiologic activation of HO2 and
formation of the heme metabolite, bilirubin. Thus, as with NO, CO formation in
neurotransmission reflects calcium-calmodulin activation of the biosynthetic enzyme.
Experimental Procedures
Yeast-2-hybrid Yeast 2-hybrid analysis was performed using the MATCHMAKER two-
hybrid system 3 (Clontech, Palo Alto, CA). Amino acids 1-292 of rat HO2 were cloned
by PCR into the EcoR1/Pst1 sites of pGBKT7 to express HO2 as a fusion with the
GAL4 DNA binding domain. Expression of the fusion protein was confirmed by western
blotting, and a rat brain cDNA library fused to the activating domain was transformed
into PJ69-4A yeast. Yeast transformants were grown on -Leu/-Trp/-Ade/-His plates. All
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colonies were re-streaked onto the same media containing X-α-gal, and colonies which
turned blue were sequenced.
Expression constructs- Rat HO2 amino acids 1-292 was cloned into the EcoRI/NotI
sites of glutathione-S-transferase (GST) expression vector pGEX 4T-2 (Amersham
Biosciences Corp, Piscataway, NJ) by PCR. Forward primer rHO2F was 5’-
TTGAATTCATGTCTTCAGAGGTGGAG, and reverse primer was 5’-
TTTTGCGGCCGCCTTCCTCAGCACAGCCAT. Rat HO2 1-90 and 1-55 were cloned
using rHO2F forward primer and reverse primers rHO90R (5-
TTTTGCGGCCGCGTGGTCCTTGTTGCGATC) and rHO55R (5-
AAGCGGCCGCTCATTTGACAAACTGGGTATT), respectively. Site-directed mutations
F56A, F56E, L57A, L57Q, F66A, and F66E in rat HO2 were introduced using the
QuickChange Site-directed Mutagenesis Kit (Stratagene, La Jolla, CA). Sequences of
the mutagenic primers are available as supplementary Table I. All mutations and were
confirmed by sequencing. Rat HO2 in pcDNA3.1 (Invitrogen, Carlsbad, CA) has been
described previously(3).
In vitro binding assays- Binding of GST fusion proteins to calmodulin was assayed by
rotating 20 µg of fusion protein with 20 µl of calmodulin-agarose (1.8 mg/ml; Sigma, St.
Louis, MO) for 1 hour at 4oC in buffer A (150 mM NaCl, 50 mM Tris [pH 7.8], 1% Triton,
1 mM EDTA +/- 5 mM CaCl2). The agarose beads were washed X 3 with 500 µls buffer
A +/- CaCl2. The washed beads were quenched directly with SDS sample buffer and
analyzed by SDS-PAGE. Western blotting was used to determine HO2 binding using
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either an anti-GST antibody (Sigma, St. Louis, MO) or in some cases an anti-HO2
antibody(4). Analysis of the site directed mutants was performed by incubating 2 µg of
GST fusion protein with 10 µg of purified calmodulin (Sigma) in 500 µl buffer A +/-
calcium. Interacting complexes were immobilized on GST-agarose, washed, and
analyzed by western blotting. Input of HO2 protein was analyzed by Ponceau S
staining, and pull-down of calmodulin was visualized with anti-calmodulin antibody
(Upstate Biotechnology, Charlottesville, VA).
Co-immunoprecipitation- Rat cortex was cut sagitally into left and right hemispheres,
and one hemisphere was homogenized in buffer A with calcium, and the other without
calcium in buffer A. Lysates were centrifuged at 10,000 xg, and the 100 µg of the
supernatant was pre-cleared of rat immunoglobulin with Pansorbin (EMD Biosciences,
San Diego, CA). Cleared lysates were immunoprecipitated with anti-HO2 antibody
overnight in the presence or absence of calcium. Where indicated, 10 µM of the peptide
calmodulin antagonist comprised of amino acids 290-309 of calmodulin-dependent
protein kinase II was included in the immunoprecipitation. Immunocomplexes were
washed and analyzed by SDS-PAGE, followed by immunoblotting with anti-HO2 and
anti-calmodulin.
Enzyme assays- Heme oxygenase activity was measured essentially as described
previously(3) with a modified assay buffer which consisted of 150 mM KCl, 50 mM
HEPES 7.5, 500 µM BAPTA, and 100 µM deferoxamine. Free calcium concentrations
were calibrated using a calcium-selective mini-electrode and confirmed using
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fluorescent dyes. Recombinant cytochrome P450 reductase (Sigma, St. Louis, MO),
1mM reduced β-nicotinamide adenine dinucleotide 2'-phosphate, and 15 µM
[55Fe]hemin (RI Consultants LLC, Hudson, NH) were added just prior to the start of each
assay. GST-HO2 was added at a concentration determined for each preparation to be
within the linear range of the assay. In some experiments, GST-HO2 was
phosphorylated for 1 hour at 30oC with recombinant CK2 as described elsewhere(3).
Bilirubin measurement- Approximately 107 cells were assayed for bilirubin formation in
triplicate per experiment, with each experiment repeated three times. Where indicated,
cells were pre-incubated with 20 µM calmidazolium chloride (CzCl; Biomol, Plymouth
Meeting, PA) prior to agonist addition. Agonists were applied for 10 min, after which an
equal volume of ethyl acetate was added and the cells were vortexed vigorously for 5
min to extract cellular bilirubin. Control plates without agonist treatment were quenched
at time zero (just before agonist addition) and after the 10 min time course. Samples
were centrifuged for 10 min at RT, and the organic phase was removed into a fresh tube
and evaporated under a nitrogen gas stream. The residue was resuspended in 50 mM
NaOH and the absorbance was measured at 440 nm. Bilirubin standards (0.05, 0.5,
5.0, and 25 nmoles) were freshly prepared in 50 mM NaOH and processed exactly as
the biological samples to generate a standard curve for quantitation of bilirubin
formation. A small aliquot of cells was saved from each condition for protein
measurement and western blotting. Bilirubin formation in HEK 293 cells was nominal
unless HO2 was transfected, demonstrating the validity of this assay for measuring HO2
activity. All manipulations were performed in dim light.
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Data Analysis- Non-linear curve fitting to the four parameter logistic equation
y=min+(max-min)/(1+(x/EC50)^Hillslope) was used to determine EC50 values using
SigmaPlot software (SPSS Science, Chicago, IL). Statistical significance was evaluated
using unpaired two-tailed t tests on data points from at least 3 separate experiments.
Data comparisons were deemed significant if p < 0.02.
Results and Discussion
In yeast 2-hybrid analysis utilizing HO2 without the C-terminal transmembrane
domain as bait, we identify calmodulin as a binding partner (Fig. 1). Analysis of the
primary sequence of HO2 using an algorithm to detect calmodulin binding sites (5)
indicates that the region encompassing amino acids 56-76 on the N-terminal region of
the protein was likely to bind calmodulin (Figure 1A). Manual inspection of this
sequence reveals three separate 1-10 consensus calmodulin binding motifs
encompassing amino acids 56-65, 57-66, and 66-75. The 1-10 motif is characterized by
bulky aromatic/hydrophobic residues at the 1st and 10th position on an alpha helix(6).
Heme oxygenase-1 (HO1) is a closely related inducible enzyme whose crystal structure
has been elucidated(7). Sequence alignment and mapping of the HO2 sequence onto
the HO1 structure reveals that only the 1-10 motif encompassing amino acids 66-75
resides on an alpha helix (Fig. 1A; Supplementary Figure 1). Thus, we predict that 1-
10 (66-75) is the primary binding site. To test this hypothesis, we examined the binding
of HO2 expressed as a glutathione-S-transferase (GST) fusion protein to calmodulin
immobilized on agarose beads (Fig. 1B). The full-length protein lacking the
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transmembrane domain, HO2(1-292), binds robustly in a calcium-dependent fashion to
calmodulin, as does HO2(1-90). By contrast, HO2(1-55), the N-terminal portion of the
enzyme lacking the predicted calmodulin binding consensus sequence, fails to bind
calmodulin-agarose. To elucidate which consensus 1-10 motif is responsible for binding
of HO2 to calmodulin, we performed site-directed mutagenesis (Fig. 1C). Mutation of
phenylalanine 56 to alanine or glutamic acid fails to alter calcium-dependent binding of
HO2 to calmodulin, suggesting that 1-10 (56-65) is not responsible for calmodulin
binding. Similarly, mutation of leucine 65 to alanine does not alter binding (data not
shown). Surprisingly, conversion of leucine 57 to alanine results in constitutive high-
affinity binding. Mutation of this residue to glutamine, the corresponding residue in
HO1, does not affect binding to calmodulin. In contrast, mutation of phenylalanine 66 to
either alanine or glutamic acid virtually abolishes binding. Combined with the lack of
effect of mutation L57Q and the presence of the 1-10 (66-75) motif on an alpha helix
(Supplementary Fig. 1), these data strongly suggest that calmodulin binds to 1-10 (66-
75).
One parallel between NOS and HO is the existence of discrete constitutive and
inducible forms of the enzymes. Inducible NOS (iNOS) is not normally activated by
stimuli that increase intracellular calcium, but instead new iNOS protein synthesis
occurs following stimuli such as endotoxin exposure(8-10). iNOS binds calmodulin at
low, physiologic calcium levels so that stimuli that increase intracellular calcium do not
alter enzyme activity(11). The inducible HO isoform, HO1, has 50% homology in the
sequence encompassing the 1-10 motif of HO2, but lacks one of the motif’s key amino
acids, phenylalanine 75 (Fig.1A). As predicted by the absence of this amino acid, we
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detect negligible binding of HO1 to calmodulin in the presence or absence of calcium
(Fig.1D).
To ascertain whether endogenous HO2 and calmodulin interact in mammalian
tissues, we conducted immunoprecipitation experiments from rat brain extracts (Fig.
1e). We observe robust, calcium-dependent co-immunoprecipitation of calmodulin with
HO2, which is reversed by calmodulin antagonist (Fig. 1e).
We demonstrate a direct requirement of calcium-calmodulin for HO2 catalytic
activity (Figure 2). Calcium stimulates HO2 in the presence of 100 nM calmodulin with
an EC50 of ~300 nM (Fig. 2a). This concentration is consistent with physiologic levels
which would occur during neuronal depolarization. Calmodulin potently stimulates
enzyme activity with an EC50 of 2 nM, similar to the potency of calmodulin in activating
nNOS(2) (Fig. 2b). Mutation of phenylalanine-66, a key amino acid in the 1-10 motif for
calmodulin binding (Fig. 1C), abolishes activation of the enzyme. The importance of
calmodulin is further substantiated by inhibition of HO2 activity with the calmodulin
antagonist calmidazolium with an IC50 of 8 µM, similar to its potency in blocking other
calmodulin-dependent processes(12-14). Another calmodulin antagonist, W7, also
inhibits the calcium-calmodulin dependent activation of HO2 (data not shown).
We wondered whether the phosphorylation of HO2 by CK2 synergizes with or
antagonizes calmodulin activation, and so examined the influence of calcium-calmodulin
on the unphosphorylated and the phosphorylated enzyme (Fig. 2d). The effect of CK2
pre-phosphorylation on calmodulin activation was examined at 10 nM and 10 µM
calcium. As reported previously(3), phosphorylation by CK2 triples enzyme activity at
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low calcium levels. No further stimulation occurs in the presence of calmodulin with
either 10 nM or 10 µM calcium.
To evaluate the role of calcium-calmodulin in regulating HO2 activity in intact
cells, we employed HEK 293 cells transfected with HO2 and primary cortical neuronal
cultures (Figure 3). In transfected HEK 293 cells, the calcium ionophore ionomycin
markedly activates the recombinant enzyme as evidenced by the increased production
of the HO2 metabolite bilirubin, with stimulation prevented by the calmodulin antagonist
calmidazolium (Fig. 3A). Mock transfected cells are not responsive to ionomycin, due to
low endogenous levels of HO2 (Fig. 3A, inset). HO2 with phenylalanine-66 mutated to
glutamate is not activated by ionomycin. In cortical cultures ionomycin increases
bilirubin formation 4.5 fold with stimulation blocked by calmidazolium (Fig. 3B). The
excitatory neurotransmitter glutamate also stimulates bilirubin formation, with stimulation
blocked by calmidazolium. Serotonin (10 µM) fails to stimulate bilirubin formation in
cortical cultures. Levels of bilirubin in serotonin-treated cultures, the same as in basal
cultures, are decreased by calmidazolium, indicating that calcium-calmodulin activation
of HO2 determines basal levels of bilirubin.
Our findings indicate a rapid activation of HO2 in intact cells by calcium-
calmodulin. How does this mechanism interface with HO2 activation by CK2? We did
not observe any influence of calcium-calmodulin upon CK2 activation of the enzyme.
CK2 phosphorylates HO2 at serine-78 (rat sequence), only 3 amino acids away from
the calmodulin binding site on the same alpha helix (Supplementary Fig. 1). We
hypothesize that conformational changes induced by calmodulin binding and by
phosphorylation of serine 78 are similar, and thus are not additive.
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Acute exposure of cortical neurons to the excitatory neurotransmitter glutamate
increased HO2 activity in a calcium-calmodulin dependent manner (Fig. 3B). Other
groups have shown that stimulation of metabotropic(15,16) and ionotropic(17-21)
glutamate receptors leads to increased CO production. Leffler et. al.(17) found in
cerebral microvessels that tyrosine kinase inhibitors blocked CO production in response
to glutamate, whereas manipulations of intracellular calcium had no effect. Notably,
ionomycin treatment in calcium-replete medium had no effect on CO production in the
microvessels, and depletion of internal calcium stores in calcium-free medium did not
affect CO production in response to glutamate. In that study, the microvessels were
exposed to 1 µM ionomycin and/or 100 µM glutamate for a minimum of 30 min while CO
was allowed to accumulate within the headspace. These manipulations would be
expected to cause secondary effects on cellular physiology, including induction of the
ER stress response and apoptosis. Therefore it is unclear if the actions of glutamate in
cerebral microvessels are truly calcium-independent. This discrepancy can also be
explained by glutamate activating a separate, calcium-independent pathway in
endothelial cells, requiring the activation of tyrosine kinases.
Activating HO2 by calcium-calmodulin in stimulated neurons presumably occurs
on a millisecond timescale, and thus is consistent with requirements for synaptic
transmission. Other physiologic processes regulated by CO are more long-term. For
instance, CO regulates long-term adaptation to odorant stimulation in olfactory
neurons(22,23), and mediates slow relaxation of the internal anal sphincter(3,24).
Conceivably CK2 phosphorylation mediates these longer-term activations of HO2.
Analogous differential roles for calcium-calmodulin-dependent and phosphorylation-
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dependent stimulations occur for endothelial NOS (eNOS). Thus, acetylcholine, by
releasing intracellular calcium, rapidly activates eNOS to initiate blood vessel relaxation,
whereas long-term relaxation mediated by shear stress and vascular endothelial growth
factor maintain vasodilation by activating Akt kinase to phosphorylate eNOS, increasing
enzyme activity in a calcium-independent fashion(25-27). Similarly, penile erection is
initiated by depolarization-induced calcium-calmodulin activation of nNOS (28,29) and
sustained by subsequent augmentation of phosphatidylinositol-3 kinase, which activates
Akt to phosphorylate and activate eNOS (29,30).
Acknowledgments
This work was supported by USPHS grant MH-18501 and DA-000266 and Research
Scientist Award DA-00074 (SHS), and National Research Service Award NS-043850
(DB). DB wishes to thank Julia and Alexandra Boehning for inspiration.
References
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Footnotes
1The abbreviations used are: CK2, casein kinase-2; CO, carbon monoxide; CzCl,
calmidazolium chloride; eNOS, endothelial nitric oxide synthase; GST, glutathione-S-
transferase; HEK, human embryonic kidney; HO2, heme oxygenase-2; HO1, heme
oxygenase-1; iNOS, inducible nitric oxide synthase; NO, nitric oxide; nNOS, neuronal
nitric oxide synthase.
Figure Legends
Figure 1 Calmodulin binds in a calcium-dependent manner to HO2 (A) Schematic
representation of rat HO2 illustrating the amino acids which encompass the CK2
phosphorylation site (S78), the catalytic core (Cat), the transmembrane helix (TM) and
the predicted calmodulin binding site (CaM). Sequence analysis of the calmodulin
binding site reveals three potential 1-10 calmodulin binding motifs (56-65, 57-66, and
66-75). Comparison of HO2 sequence to HO1 reveals only motif 66-75 resides on an
alpha helix (see supplementary figure 1). The CK2 phosphorylation site is indicated by
an asterisk in the alignment. (B) GST-HO2 constructs encoding amino acids 1-292, 1-
90, and 1-55 were tested for the ability to bind calmodulin-agarose in the presence or
absence of calcium. Load is 1/10 the input of fusion protein. (C) Pull-down of purified
calmodulin with GST-HO2 containing point mutations in the 1-10 binding motifs. Amino
acids are indicated by single letter notation, the number of the residue (rat HO2
sequence), and the amino acid it was replaced by. GST-HO2 was analyzed by
Ponceau S staining, and pull-down of calmodulin (CaM) was visualized by western
blotting of the same nitrocellulose sheet. (D) GST-HO2 or GST-HO1 were tested for
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the ability to bind calmodulin-agarose +/- calcium. Load is 1/10 the input of fusion
protein. (E) HO2 from rat brain was immunoprecipitated +/- calcium. Where indicated,
20 µM of the pseudo-substrate calmodulin antagonist CaM kinase II (290-309) was
added (CaM Inh.). Immunoprecipitates were analyzed by SDS-PAGE and western
blotting for HO2 and calmodulin. Lysate is 1/10 the amount offered for
immunoprecipitation.
Figure 2 Calmodulin stimulates HO2 activity in vitro (A) Wild-type GST-HO2 was
incubated with 100 nM calmodulin at various concentrations of calcium, and the
enzymatic activity of HO2 was examined. Enzyme activity was increased more than
three-fold in the presence of calmodulin, with an EC50 of 287 nM calcium (solid circles).
In the absence of calmodulin, calcium had no effect (open circles). The F66E mutant
retained basal catalytic activity, but was not activated by calcium-calmodulin (closed
triangles). (B) Wild-type GST-HO2 was incubated with 1.0 µM calcium and varying
concentrations of calmodulin (closed circles). The EC50 for activation by calmodulin was
2 nM. Calmodulin had no effect on the F66E mutant (closed triangles). (C) Effect of
the calmodulin antagonist calmidazolium chloride on the activity of HO2 assayed in the
presence of 100 nM calmodulin and 1.0 µM free calcium. Under these conditions,
calmidazolium chloride inhibited HO2 activity with an IC50 of 8.0 µM. (D) Effect of pre-
phosphorylation of HO2 with CK2 on the calcium sensitivity of enzyme activity in the
presence of 100 nM calmodulin. Enzyme activity was activated similarly at 10 nM and
10 µM calcium by CK2. Calcium-calmodulin activation at 10 µM calcium was not
additive to CK2 activation. Confirmation of phosphorylation efficiency was determined
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by western blotting of a small portion of the kinase reaction with phosphoserine
antibodies (inset; Zymed laboratories, San Francisco, CA). All data are pooled from at
least three separate determinations in duplicate. *p < 0.02
Figure 3 Calmodulin mediates rapid activation of HO2 in response to calcium
mobilizing agonists (A) HEK 293 cells were transfected with pcDNA3.1 (mock), rat
HO2, or F66E HO2. Bilirubin formation was measured in response to a 10 minute
stimulation with DMSO (none) or 1 µM ionomycin (iono) +/- 20 µM calmidazolium
chloride (CzCl). Mock transfected cells had no increase in bilirubin formation in
response to ionomycin, as expected from the low amounts of endogenous HO2 (inset).
Transfection of HO2 caused a ~4.5 fold increase in the rate of bilirubin formation in
response to ionomycin, which was blocked by CzCl. In contrast, cells transfected with
HO2 F66E were insensitive to ionomycin treatment. (B) Primary rat cortical neuronal
cultures were treated with DMSO (none), 1 µM ionomycin (iono), 100 µM glutamate
(glu), or 10 µM serotonin (5-HT) in the presence or absence of CzCl for 10 min and
bilirubin formation was determined as in panel A. Data are pooled from 6 separate
determinations performed in duplicate *p < 0.01
Supplementary Figure 1 Structure properties of HO2 amino acids 56 to 76
mapped onto the HO1 crystal structure (A) Location of HO2 amino acids F56 to F76
mapped onto the full HO1 crystal structure, and (B) residues F56 to the end of HO1
helix 3. The putative calmodulin binding region F56 to F76 is highlighted in yellow. The
CK2 phosphorylation site at Ser 78 (rat HO2 sequence) is also indicated (CK2-P,
highlighted in yellow). Mapping of the equivalent residues of HO2 onto the HO1
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18
structure was done by alignment with ClustalW (Higgins D., Thompson J., Gibson
T.Thompson J.D., Higgins D.G., Gibson T.J. (1994) Nucleic Acids Res. 22:4673-4680).
HO2 was confirmed to have a similar predicted secondary structure to HO1 within the
region of the calmodulin binding site using the PredictProtein server (B Rost and J Liu
(2003) Nucleic Acids Research 31(13): 3300-3304). The crystal structure of HO1
(MMDB accession # 13250) was manipulated with Cn3D version 4.0
(http://www.ncbi.nlm.nih.gov/Structure/CN3D/cn3d.shtml).
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Figure 1 Boehning et. al.
62
49
38
28
Ca :2+ - + - + - + Load
1-292GST-HO2: 1-901-90 1-55
AS78
N CTM
CatCaM
29256 76 145 177
B
C
Ca :2+
- - + + - +
CaM
Blot
Lysate
HO2 i.p.
17
HO2
Blot
- + - + CaM Inh.:
D
E
38
Ca :2+ - + - + - + - + - + - + - +
GST-HO2
WT F56A F56E L57A L57Q
1-55
F66A F66E
CaM
Ca :2+ - + - + Load
HO2 HO1
HO
2HO
1
62
49
1-29
2
HO2 (54-78) :
HO1 (35-59) :K FLKGN I KKELFKR FQKGQVTRDGFK
*DN
LATTALYFTYSLVMASLYH I YV
1-10 Motifs
α-helixcoil
Structure (HO1) :
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Figure 2 Boehning et. al.
B
A C
Calmodulin (nM)
0.001 0.01 0.1 1 10 100 1000 10000
50
100
150
200
250
EC50
= 2 nM
HO
2 a
ctivity
(pm
ole
s/m
g/m
in)
F66E
WT
[Ca 2+ ] (µM)
0.001 0.01 0.1 1.0 10 100 10000
100
200
300
400
500WT +CaM (100nM)
WT No CaM
EC50 = 287 nM
F66E +CaM (100nM)
HO
2 a
ctivity
(pm
ole
s/m
g/m
in)
Calmidazolium Chloride (µM)
0.001 0.01 0.1 1 10 100 1000
0
100
200
300
400
500
600
IC50
= 8.0µM
HO
2 a
ctivity
(pm
ole
s/m
g/m
in)
D
0
50
100
150
200
250
300
350
HO
2 a
ctivity
(pm
ole
s/m
g/m
in)
CK2 - - + + - - + + CaM - + - + - + - +
10 nM 10 µM
P-Ser - +
CK2
**
*
* *
Ca 2+
:
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Figure 3 Boehning et. al.
A
0
200
400
600
800
1000
Bili
rub
in f
orm
atio
n
(p
mo
les/m
g/m
in)
B
Agonist: none iono iono glu glu 5-HT 5-HT
+CzCl +CzCl +CzCl
*
*
Cortical Neurons
*
Treatment: none iono iono none iono iono +CzCl +CzCl
Mock HO2
none iono iono +CzCl
F66E
noneHO2F6
6E
Bili
rub
in f
orm
atio
n
(p
mo
les/m
g/m
in)
HEK 293
800
0
200
400
600
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Supplementary Table I Boehning et. al.
MUTAGENIC PRIMERS
Construct Forward primer sequence (5’-3’) F56A TTTGTCAAAGACGCCTTGAAAGGAAAC F56E TTTGTCAAAGACGAGTTGAAAGGAAAC L57A GTCAAAGACTTCGCGAAAGGAAACATT L57Q GTCAAAGACTTCCAGAAAGGAAACATT F66A AAGAAGGACCTAGCTAAGCTGGCCACC F66E AAGAAGGACCTAGAGAAGCTGGCCACC Mutations are indicated in bold. Reverse primers were the exact complement of the forward primer
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Supplementary Figure 1 Boehning et. al.
CK2-P
F56
K63
helix 3
helix 3
CK2-P
F56
K63
F76
A
B
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Darren Boehning, Leela Sedaghat, Thomas W. Sedlak and Solomon H. SnyderHeme oxygenase-2 activated by calcium-calmodulin
published online June 2, 2004J. Biol. Chem.
10.1074/jbc.C400222200Access the most updated version of this article at doi:
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Supplemental material:
http://www.jbc.org/content/suppl/2004/06/10/C400222200.DC1
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