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The stimulation of partially purified bovine caudate tyrosine hydroxylase by phosphatidyl-L-serine
Vol. 59, No. 4, 1974
THE
BIOCHEMICAL
STIMULATION
AND BIOPHYSICAL
OF PARTIALLY HYDROXYLASE T.
PURIFIED BOVINE CAUDATE BY PHOSPHATIDYL-L-SERINE
Lloyd
and
National Institute Laboratory Building Bethesda,
Received
July
2,
RESEARCH COMMUNICATIONS
S.
TYROSINE
Kaufman
of Mental Health Neurochemistry 36, Room 3D-30 Maryland 20014 of
1974
SUMMARY. A new procedure has been developed for the purification of tyrosine hydroxylase from bovine caudate nucleus. This procedure yields a soluble and stable enzyme which has been purified 50-fold from an acetone powder extract. The enzyme is stimulated greater than 3-fold by phosphatidyl-L-serine and other polyanions which lower the Km of the enzyme for the pterin cofactor. Substrate inhibition and an ability to readily hydroxylate phenylalanine in the presence of tetrahydrobiopterin have also been observed with this preparation. Although
INTRODUCTION. tissue
has been documented
has not have
been
it
proteases
for
bovine
to
caudate
Our interest
in the
hydroxylase
We have
that
lated observed
by certain with
phenylalanine
tyrosine
Copyright All rights
appears
hydroxylase
a soluble
of
the
tyrosine
(6) than
to
@ 1974 by Awdemic Press, Inc. of reproduction in uny form reserved.
to that that
with
here
the
were
a relatively tyrosine
simple hydroxylase
with
fold
hydroxylase
caudate of rat
liver
effect,
The mechanism
observed
with
than
that
thus
of this on crude
on phenylalanine
(4,5).
be stimu-
can also
examined
heparin
tyrosine
by lysolecithin
is much less
phospholipids
lysolecithin
1262
or
which
activity
20-50
stimulation
greatest
analagous
that
Of the
particles
polyanions.
about
the
tissue studies
with
in preparations
and stable
observation
although
this
of detergents
of phospholipids
caudate
system
Earlier
action
We report
hydroxylase.
produces to be more
resulted
be stimulated
activity
from
associated
by the
by certain
our previous
enzyme
is largely
interaction
phospholipids,
phosphatidyl-L-serine lation
stimulation
the
nervous
characterized.
only
of
in central
(l),
irreversibly.
could
the
brain
however,
possible
from
phenylalanine found
from
purification
and its
stemmed
a decade
solubilized
aggregate
a 50-fold
hydroxylase
enzyme
Such procedures,
or tended
procedure
the
activity
or adequately
be partially
(2,3).
unstable
nearly
purified
that
could
hydroxylase
for
extensively
demonstrated
and that
from
tyrosine
far, stimubrain
hydroxlase
BIOCHEMICAL
Vol. 59, No. 4, 1974
MATERIALS AND MFTHODS. L-tyrosine
(14c)
Nuclear
e L-(3,5-3H
chemical
Center
L-Phenylalanine
unifomy tyrosine),
Aldrich
were
30 Ci/mmole,
and purified
according
Co.
in this
laboratory
(8,9).
Boehringer
~annhe~
from
and Nephew Research,
Crystalline Corp.
prepaxed
each
aay by sonication
from
the
commercial
L-tyrosine
hydroxylase
activity
of the
0.95-2.20
nmoles
shakex. acid.
2.0
assay
compounds
from
tyrosine
Harlow,
nmoles
Amersham
Radio-
(7).
The
purchased
according
was purchased NSD-lO$,
Essex,
EngIana-
and from All
was performed
from
Supelco; other
(6-MPH,,)
to published from
the
wes a kind
gift
Phosphatidyl-L-serine fresh
compounds
as previously
50 umoles
solutions were
obtained
0.50
umoles
to be assayed
potassium
liver
and water
was terminated
to be linear
used
was for
by the
10 min
addition
with
to
time
of
20.0
nmoles
specified),
0.50
ml. 1
The specific
in the
kinetic
studies
at 37'
of
reductase
otherwise
0.50
up to
(10). (pH 6,1),
phosphate
dihydropteridine
6-MPH& (unless
preparations
Incubation
described
(3 X 105 cpm),
TPNH and sheep
hydroxylase
was found
New Rngland
et aI.
Milstien
3,5-3H-L-tyrosine
DOPA/mg/min.
the
were
inhibitor,
contained:
fraction
the
was
in a metabolic
ml 10% trichloroacetie
20 min and with
protein
mg/ml.
When lb C-tyrosine tyrosine
from
and 6-methyltetrahydropterin
Sheldon
in water.
assay
catalase>
The reaction This
up to
0.25
2000 units
tyrosine
obtained
and
available,
containing
(or
(BHb)
Biochemicals
sources
mixture
2-mercaptoethanol in excess),
General
hydroxylase
incubation
nmoles
384 mCi/mmole,
of Ikeda
in suspension
Ltd.,
were
0.05
method
The decarboxylase
both
A standard
to the
catalase
from
The tyrosine
were
labeled,
was obtained
by Dr.
was purchased
best
uniformly
Tetrahydrobiopterin
procedures
Smith
RESEARCH COMMUNICATIONS
(DMPH4) and 3-iodo-L-tyrosine
Chemical
synthesized
(14C)
368 rn~i/~ole,
labeled,
6,74imethyltetrahydropterin, the
AND BIOPHYSICAL
formation after
or 1' C-phenylalanine were
they
measured
had been
were
used
by determination separated
as substrates,
of radioactivity
by thin-layer
1 The results described in this report were obtained regenerating system for the cofactor, although equivalent in each case tith the enzymatic regenerating system.
1263
chromatography
with the results
DOPA and in these of the
super-
chem%caI were obtained
Vol.
59,
natant
No.
4, 1974
fractions
utilizing
BIOCHEMICAL
from
the
solvent
by the
procedure
standard
(11).
AND
reaction
mixtures
system:
n-propanol:NHbOH:H20;
of Lowry
et al. --
(Eastman
with
the
The 3-iodo-L-tyrosine-substituted to
a previous
report
from
Cuatrecasas
(13).
after
which
15 mg of
at 4’
for
the
uncoupled
of
The extract was subjected
phosphate
was washed
tyrosine
M TRIS-chloride,
chromatography
at pH 10, with
elution
M potassium
phosphate, of the
by an ammonium
sulfate
fractionation
aqueous
elsewhere.
extracts
resultant be about
We have
soluble
and stable
40% pure
by disc-gel
RESULTS AND DISCUSSION. of
solubilized
presence
1 shows that
substrate
substrate;
We have
by a 04.3 of the
a lo-20%
tyrosine
previously
bovine but
caudate
LB, and mixed
an aqueous
of
extract
techniques
(14).
4B, the
active
material
fraction
on calcium
hydroxylase
activity
was chromatography M KC1 gradient)
hydroxylase
followed
procedure
purifications recovery
on
was precipitated
purification
of
will
50-fold
over
The
of activity.
hydroxylase
inhibition
reported
adrenal not
tyrosine
inhibition
no substrate
of
has been estimated
to
electrophoresis.
of tetrahydrobiopterin, Purified
the
caudate
procedure
was added
active
step
achieved
with
according
and 1 mM dithiothreitol)
of tyrosine
The detailed
tissue
and particulate
DMPHb (12).
of the
The third
routinely
as the
by standard
Sepharose
portion
(most
albumin
of Sepharose
from
8% sucrose,
substituted
saturation).
of caudate
was purified
enzyme peak
was determined
gel.
pH 8.6,
major
Protein
general
gel
sheets
to be 8.4% by measurement
was prepared
pH 6.8.
(elution
be reported
powder
of the
25 and 40 percent
the
by fractionation
DEAE-cellulose
between
was found
from
on the
followed
the
150 mg CNBr/ml
hydroxylase
0.02
gel,
by 0.025
of coupling
The acetone
to
following
with
(#6064)
was synthesized
per ml of activated
powder. (in
eluted
which
caudate
an acetone
being
The extent
ligand
The bovine
(12)
3-iodo-L-tyrosine
serum
4B gel
COMMUNICATIONS
cellulose
8:l:l).
use of bovine
laboratory
was activated
RESEARCH
precoated
Sepharose
this
The gel
20 hrs.
BIOPHYSICAL
occurs
medulla
in the
occurs
1264
inhibition
tyrosine
presence
hydroxylase above
marked
of the
shows similar 0.05
hydroxylase synthetic
in the cofactor,
behavior.
mM when tyrosine
when phenylalanine
by tyrosine
is is used
Figure used
as
as the
Vol. 59, No. 4, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
r
050
[M]
SU3STRATE
Figure 1. Effect of Substrate Concentration on Bovine Caudate Tyrosine Hydroxylase Activity in the Presence of 260 nM Tetrahydrobiopterin. Constant specific activity 14C-ty7cosine 2n # 14C-phenylalanine was used in this experiment (41.6 pCt/umole}, NSD 1034 at 10K was included %n the assays to prevent decarboxylation of the DOPA. Reaction products were isolated by thin-layer chromatography as described in M2terials and Nethods. After chromatography, the separated amino acids were visualized by spraying with ninhydrin, the chromatogram channels cut into 0.5 cm strips and the radioactivity determined by liquid scintillation spectrometry. The solvent system routinely yielded Rf values of 0.66, 0.39 and 0.13 for phenylalanine, tyrosine and DOPA, respectively. Tyrosine hydroxylase activity is expressed as nmoILes product formed in 10 ul of a 110 ul incubation mixture which contained 0.35 mg tyrosine hydroxylase preparation.
substrate the
up to
possibly
tyrosine, system,
it since
phospholipids out
mM phenylalanine.
physiological is
a potential
inhibition
The dramatic
ried
0.40
not
yet
established
of the
substrate
Inhibition
observed
regulatory
mechanism
for
adrenergic
nervous
occurs
stimulation
purified
we have
significance
has been previously with
Although
caudate
just of rat
above
tissue
liver
phenylalanine
reported tyrosine
the
(4,5). hydroxylase,
1265
levels
of tyrosine
(15).
hydroxylase
by several
When a similar only
survey
phosphatidyl-L-serine
with
was carwas
Vol.
59,
No.
4, 1974
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Figure 2. Effect of Phosphatidyl-L-Serine on Bovine Caudate Tyrosine Hydroxylase Activity. The assay was performed in the presence of 50 uM 6-MPH4. The control value of 100 percent was the formation of 0.52 nmoles DOPA/lO min in the absence of any phosphatidyl-L-serine. The tritium-release assay was used as described in Materials and Methods with 0.50 mg tyrosine hydroxylase preparation/ml.
found
to
in Fig.
stimulate 2 where
it
can be seen that
phospholipid.
The nature
concentration
of enzyme,
of this
by about
b-fold.
conditions.
Km's of Km for
(Fig.
tyrosine A recent
hydroxylase
in the
has been
on Vrna
were
to the
series
of reports
by heparin
have
of either on the
described
activity
a slight
1266
of
presence
out
or absence the
of this
Km of the under
in reducing phospholipid
Km of tyrosine.
of
crude
pH dependence
of pterin these
6,'7-DMF'H4 or ~-MPH,+,
with effect
as a
rat
their
Km
on the The apparent
6,7-DMPH4 or 6-MPH4 is 0.076 stimulation
0.4 mM
as a function
has been observed
on the
at
and of pH.
a similar
had no effect
studied
decreases
effect
is presented
achieved
hydroxylase
carried
In contrast
presence
is
phospholipid
to have
it
stimulation
in the
was observed
tetrahydropterins,
stimulation
3) of tyrosine
effect
studies
b-fold
tyrosine
the
No appreciable
b-fold.
maximal
concentration
When identical
by 3 to
3 to
stimulation
shows that
phosphatidyl-L-serine values
plot
of tetrahydrobiopterin
phosphatidyl-L-serine
the
tetrahydropterin,
The Lineweaver-Burk function
A typical
significantly.
brain
of this
mM. tyrosine stimulation
(16,
Vol. 59, No. 4, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
PS 20
1
7
1 I
0
! 2
V[Bti4],
, 3
, 4
1 5
1 6
mM
Figure 3. Determination of the K,,, of Bovine Caudate Tyrosine Hydroxylase for Tetrahydrobiopterin 1~ the Presence and Absence of Phosphatidyl-L-Serine. The velocity is expressed as concentration of 3,5-3H-tyros2.ne was 50 $.iM. Reaction nmoles DOPA formed in 10 min. The tritium-release assay used as described in Material.s and Methods with 0.50 mg tyrosine hydroxylase preparation/ml.
171.
The activity
of purified
presence
of either
Fig,
4.
Although
rat
brain
with
the
60 pg/m.l heparin
tyrosine bovine
potassium
tt
naturally
to
the
was essential occurring
the
5.9 to
to pterin
to
shtft
6.1,
this
buffer.
as a function is
pH optimum
effect
was not
of 6.0
for
of pH ln the shown
from
6.0-6.1
observed
in either
to
j.n
soluble
100 mM
Phosphatidyl-L-serine,
however,
6.6-6.8
in either
buffer. of rat
brain
presence
of the
synthetic
investigate
this
stimulation
cofactor.
the
had a pH optimum
enzyme pH optimum
stimulation
in the
hydroxylase
or 0.4 mM phosphaticlyl-L-serine
50 mM TRIS-acetate
or TRIS-acetate
heparin only
from
enzyme which
shift
phosphate
been reported that
or
tyr&ine
has been reported
caudate
has been observed
Since
heparin
hydroxylase
phosphate
potassium
caudate
tyrosine
hydroxylase
cofactor, in the
When tetrahydrobiopterin
1267
has previously
DMPH4, we thought presence was used
of a as the
Vol. 59, No. 4, 1974
BlOCHEMiCAl
AND B~OPHYSICAL RESEARCH COMMUNICATIONS
20I al6l4-
0402I
54
!
1
58
62
!
,
66 70 PH
1
1
74
78
Figure 4. The Effect of pH on Stimulation of Bovine Caudate Tyrosine Hydroxylase by Phosphatidyl-L-Serine or Heparin. All incubations were done in the presence of 100 uM 6-MPH4, 50 UM 3,5-3H-tyrosine, and 100 mM potassium phosphate buffer at the indicated pH values. The concentration of phosphatidyl-L-serine used was 0.40 mM; 60 ng heparin/nii was used for the assays containing the latter compound. Reaction velocity is expressed as nmoles DOPA formed/l0 min. The tritiumrelease assay was used as described in Materials and Methods with 0.64 mg tyrosine hydroxylase preparation/ml.
cofactor
in
studies
pH dependence in the
identical
was observed,
pH optimum
preliminary caudate L-serine, increases
from
studies, tyrosine
V
max
The value
i.e.,
we have
polyanion
one described
no shift
also
observed
only
presence
presence a 3-4
by poly-L-glutamic not
in Fig.
in the
pH 6.1 to 6.6 in the
hydroxylase
this
to the
decreases
the
fold
4, virtually
the
of heparin
same
and a shift
of phosphatidyl-L-serine. stimulation
acid.
In contrast
Km for
the
In
of bovine to phosphatidyl-
cofactor,
but
also
2 *
of
0.22
mM for
the
Km of brain
TH for
BHk in the
absence
of
2Although Kuczenski and Mandell (6) have concluded that the heparin activation of brain tyrosine hydroxylase is a highly specific effect, detailed studies of the activation by other anions, including the effect of polyglutamate described above, strongly indicate that activation is non-specific, being related primarily to the charge density of the anion (I. Katz and S. Kaufman, unpublished results).
1268
Vol.
59,
No.
4, 1974
BIOCHEMICAL
phosphatidyl-L-serine
is about
of BHb (18)
uniform
(assuming
question
about
how tyrosine
cofactor
levels
apparently
that
phosphatidyl-L-serine
this
apparent
likely
candidates
important
role
tissue
so far
in the
below
Although
or other regulation
higher
than
distribution).
hydroxylase
as naturally
BIOPHYSICAL
200 times
decreases
discrepancy.
phosphatidyl-L-serine
AND
RESEARCH
the
reported
This
in this
the
Km value.
the
BHk Km four-fold
heparin
occurring endogenous
tissue
cerebral
of central
adrenergic
levels raises
with
may partially
of brain
a
pterin
The finding
or poly-L-glutamic
modifiers
tissue
observation
can function cofactor
COMMUNICATIONS
acid tyrosine
phospholipids
explain are not hydroxylase,
may play
an
activity.
REFERENCES 1. 2. Z: 2: 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.
Nagatsu, T., Levitt, M. and Udenfriend, S., J. Biol. Chem. a, 2910rzg1-r , 1964. Poillon, W.N., Biochem. Biophys. Res. Commun. g, 64-70, 1971. Nagatsu, T., Sudo, Y. and Nagatsu, I., J. Neurochem. l.8, 217+218g, 1971. Fisher, D.B. and Kaufman, S., J. Biol. Chem. 247, 2250-2253, 1972. Fisher, D.B. and Kaufman, S., J. Biol. Chem. m, 4345-4353, 1973. Kuczenski, R.T. and Mandell, A.J., J. Neurochem. I& 131-137, 1972. Ikeda, M., Fahien, M. and Udenfriend, S., J. Biol. Chem. 2& 4452-4456, 1966. Storm, C.B., Shiman, R. and Kaufman, S., J. Org. Chem. 3&, 3925-3927, 1973. Andrews, K.J.M., Barber, W.E. and Tong, B.P., J. Chem. Sot.(c), 928+X0, 1969. Lloyd, T., Mori, T. and Kaufman, S., Biochemistry g, 2330-2336, 1971. Lowry, O.H., Rosebrough, N.J., Farr, A.L. and Randall, R.J., J. Biol. Chem. 193, 265-275, 1951. Oman, R., Akino, M. and Kaufman, S., J. Biol. Chem. 2& 1330-1340, 1971. Cuatrecasas, P., J. Biol. Chem. 2& ?,OFg-3065, 1970. Tabor, H., Methods in Enzymology, vol. 1, Academic Press, New York pp. 609-610, 1955. Kandera, J., Levi, G. and Lajtha, A., Arch. Biochem. Biophys. &, 24g-z6o, 1968. Kuczenski, R., J. Biol. Chem. N, 5074-5080, 1973. J. Biol. Chem. x, 3114-3122, 1972. Kuczenski, R. and Mandell, A.J., (W. Pfleiderer and E.C. Taylor, eds.), Rembold, H., in Pteridine Chemistr The MacMillan Co., New York, pp. 4 5-484, 1964.
1269
THE
BIOCHEMICAL
STIMULATION
AND BIOPHYSICAL
OF PARTIALLY HYDROXYLASE T.
PURIFIED BOVINE CAUDATE BY PHOSPHATIDYL-L-SERINE
Lloyd
and
National Institute Laboratory Building Bethesda,
Received
July
2,
RESEARCH COMMUNICATIONS
S.
TYROSINE
Kaufman
of Mental Health Neurochemistry 36, Room 3D-30 Maryland 20014 of
1974
SUMMARY. A new procedure has been developed for the purification of tyrosine hydroxylase from bovine caudate nucleus. This procedure yields a soluble and stable enzyme which has been purified 50-fold from an acetone powder extract. The enzyme is stimulated greater than 3-fold by phosphatidyl-L-serine and other polyanions which lower the Km of the enzyme for the pterin cofactor. Substrate inhibition and an ability to readily hydroxylate phenylalanine in the presence of tetrahydrobiopterin have also been observed with this preparation. Although
INTRODUCTION. tissue
has been documented
has not have
been
it
proteases
for
bovine
to
caudate
Our interest
in the
hydroxylase
We have
that
lated observed
by certain with
phenylalanine
tyrosine
Copyright All rights
appears
hydroxylase
a soluble
of
the
tyrosine
(6) than
to
@ 1974 by Awdemic Press, Inc. of reproduction in uny form reserved.
to that that
with
here
the
were
a relatively tyrosine
simple hydroxylase
with
fold
hydroxylase
caudate of rat
liver
effect,
The mechanism
observed
with
than
that
thus
of this on crude
on phenylalanine
(4,5).
be stimu-
can also
examined
heparin
tyrosine
by lysolecithin
is much less
phospholipids
lysolecithin
1262
or
which
activity
20-50
stimulation
greatest
analagous
that
Of the
particles
polyanions.
about
the
tissue studies
with
in preparations
and stable
observation
although
this
of detergents
of phospholipids
caudate
system
Earlier
action
We report
hydroxylase.
produces to be more
resulted
be stimulated
activity
from
associated
by the
by certain
our previous
enzyme
is largely
interaction
phospholipids,
phosphatidyl-L-serine lation
stimulation
the
nervous
characterized.
only
of
in central
(l),
irreversibly.
could
the
brain
however,
possible
from
phenylalanine found
from
purification
and its
stemmed
a decade
solubilized
aggregate
a 50-fold
hydroxylase
enzyme
Such procedures,
or tended
procedure
the
activity
or adequately
be partially
(2,3).
unstable
nearly
purified
that
could
hydroxylase
for
extensively
demonstrated
and that
from
tyrosine
far, stimubrain
hydroxlase
BIOCHEMICAL
Vol. 59, No. 4, 1974
MATERIALS AND MFTHODS. L-tyrosine
(14c)
Nuclear
e L-(3,5-3H
chemical
Center
L-Phenylalanine
unifomy tyrosine),
Aldrich
were
30 Ci/mmole,
and purified
according
Co.
in this
laboratory
(8,9).
Boehringer
~annhe~
from
and Nephew Research,
Crystalline Corp.
prepaxed
each
aay by sonication
from
the
commercial
L-tyrosine
hydroxylase
activity
of the
0.95-2.20
nmoles
shakex. acid.
2.0
assay
compounds
from
tyrosine
Harlow,
nmoles
Amersham
Radio-
(7).
The
purchased
according
was purchased NSD-lO$,
Essex,
EngIana-
and from All
was performed
from
Supelco; other
(6-MPH,,)
to published from
the
wes a kind
gift
Phosphatidyl-L-serine fresh
compounds
as previously
50 umoles
solutions were
obtained
0.50
umoles
to be assayed
potassium
liver
and water
was terminated
to be linear
used
was for
by the
10 min
addition
with
to
time
of
20.0
nmoles
specified),
0.50
ml. 1
The specific
in the
kinetic
studies
at 37'
of
reductase
otherwise
0.50
up to
(10). (pH 6,1),
phosphate
dihydropteridine
6-MPH& (unless
preparations
Incubation
described
(3 X 105 cpm),
TPNH and sheep
hydroxylase
was found
New Rngland
et aI.
Milstien
3,5-3H-L-tyrosine
DOPA/mg/min.
the
were
inhibitor,
contained:
fraction
the
was
in a metabolic
ml 10% trichloroacetie
20 min and with
protein
mg/ml.
When lb C-tyrosine tyrosine
from
and 6-methyltetrahydropterin
Sheldon
in water.
assay
catalase>
The reaction This
up to
0.25
2000 units
tyrosine
obtained
and
available,
containing
(or
(BHb)
Biochemicals
sources
mixture
2-mercaptoethanol in excess),
General
hydroxylase
incubation
nmoles
384 mCi/mmole,
of Ikeda
in suspension
Ltd.,
were
0.05
method
The decarboxylase
both
A standard
to the
catalase
from
The tyrosine
were
labeled,
was obtained
by Dr.
was purchased
best
uniformly
Tetrahydrobiopterin
procedures
Smith
RESEARCH COMMUNICATIONS
(DMPH4) and 3-iodo-L-tyrosine
Chemical
synthesized
(14C)
368 rn~i/~ole,
labeled,
6,74imethyltetrahydropterin, the
AND BIOPHYSICAL
formation after
or 1' C-phenylalanine were
they
measured
had been
were
used
by determination separated
as substrates,
of radioactivity
by thin-layer
1 The results described in this report were obtained regenerating system for the cofactor, although equivalent in each case tith the enzymatic regenerating system.
1263
chromatography
with the results
DOPA and in these of the
super-
chem%caI were obtained
Vol.
59,
natant
No.
4, 1974
fractions
utilizing
BIOCHEMICAL
from
the
solvent
by the
procedure
standard
(11).
AND
reaction
mixtures
system:
n-propanol:NHbOH:H20;
of Lowry
et al. --
(Eastman
with
the
The 3-iodo-L-tyrosine-substituted to
a previous
report
from
Cuatrecasas
(13).
after
which
15 mg of
at 4’
for
the
uncoupled
of
The extract was subjected
phosphate
was washed
tyrosine
M TRIS-chloride,
chromatography
at pH 10, with
elution
M potassium
phosphate, of the
by an ammonium
sulfate
fractionation
aqueous
elsewhere.
extracts
resultant be about
We have
soluble
and stable
40% pure
by disc-gel
RESULTS AND DISCUSSION. of
solubilized
presence
1 shows that
substrate
substrate;
We have
by a 04.3 of the
a lo-20%
tyrosine
previously
bovine but
caudate
LB, and mixed
an aqueous
of
extract
techniques
(14).
4B, the
active
material
fraction
on calcium
hydroxylase
activity
was chromatography M KC1 gradient)
hydroxylase
followed
procedure
purifications recovery
on
was precipitated
purification
of
will
50-fold
over
The
of activity.
hydroxylase
inhibition
reported
adrenal not
tyrosine
inhibition
no substrate
of
has been estimated
to
electrophoresis.
of tetrahydrobiopterin, Purified
the
caudate
procedure
was added
active
step
achieved
with
according
and 1 mM dithiothreitol)
of tyrosine
The detailed
tissue
and particulate
DMPHb (12).
of the
The third
routinely
as the
by standard
Sepharose
portion
(most
albumin
of Sepharose
from
8% sucrose,
substituted
saturation).
of caudate
was purified
enzyme peak
was determined
gel.
pH 8.6,
major
Protein
general
gel
sheets
to be 8.4% by measurement
was prepared
pH 6.8.
(elution
be reported
powder
of the
25 and 40 percent
the
by fractionation
DEAE-cellulose
between
was found
from
on the
followed
the
150 mg CNBr/ml
hydroxylase
0.02
gel,
by 0.025
of coupling
The acetone
to
following
with
(#6064)
was synthesized
per ml of activated
powder. (in
eluted
which
caudate
an acetone
being
The extent
ligand
The bovine
(12)
3-iodo-L-tyrosine
serum
4B gel
COMMUNICATIONS
cellulose
8:l:l).
use of bovine
laboratory
was activated
RESEARCH
precoated
Sepharose
this
The gel
20 hrs.
BIOPHYSICAL
occurs
medulla
in the
occurs
1264
inhibition
tyrosine
presence
hydroxylase above
marked
of the
shows similar 0.05
hydroxylase synthetic
in the cofactor,
behavior.
mM when tyrosine
when phenylalanine
by tyrosine
is is used
Figure used
as
as the
Vol. 59, No. 4, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
r
050
[M]
SU3STRATE
Figure 1. Effect of Substrate Concentration on Bovine Caudate Tyrosine Hydroxylase Activity in the Presence of 260 nM Tetrahydrobiopterin. Constant specific activity 14C-ty7cosine 2n # 14C-phenylalanine was used in this experiment (41.6 pCt/umole}, NSD 1034 at 10K was included %n the assays to prevent decarboxylation of the DOPA. Reaction products were isolated by thin-layer chromatography as described in M2terials and Nethods. After chromatography, the separated amino acids were visualized by spraying with ninhydrin, the chromatogram channels cut into 0.5 cm strips and the radioactivity determined by liquid scintillation spectrometry. The solvent system routinely yielded Rf values of 0.66, 0.39 and 0.13 for phenylalanine, tyrosine and DOPA, respectively. Tyrosine hydroxylase activity is expressed as nmoILes product formed in 10 ul of a 110 ul incubation mixture which contained 0.35 mg tyrosine hydroxylase preparation.
substrate the
up to
possibly
tyrosine, system,
it since
phospholipids out
mM phenylalanine.
physiological is
a potential
inhibition
The dramatic
ried
0.40
not
yet
established
of the
substrate
Inhibition
observed
regulatory
mechanism
for
adrenergic
nervous
occurs
stimulation
purified
we have
significance
has been previously with
Although
caudate
just of rat
above
tissue
liver
phenylalanine
reported tyrosine
the
(4,5). hydroxylase,
1265
levels
of tyrosine
(15).
hydroxylase
by several
When a similar only
survey
phosphatidyl-L-serine
with
was carwas
Vol.
59,
No.
4, 1974
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Figure 2. Effect of Phosphatidyl-L-Serine on Bovine Caudate Tyrosine Hydroxylase Activity. The assay was performed in the presence of 50 uM 6-MPH4. The control value of 100 percent was the formation of 0.52 nmoles DOPA/lO min in the absence of any phosphatidyl-L-serine. The tritium-release assay was used as described in Materials and Methods with 0.50 mg tyrosine hydroxylase preparation/ml.
found
to
in Fig.
stimulate 2 where
it
can be seen that
phospholipid.
The nature
concentration
of enzyme,
of this
by about
b-fold.
conditions.
Km's of Km for
(Fig.
tyrosine A recent
hydroxylase
in the
has been
on Vrna
were
to the
series
of reports
by heparin
have
of either on the
described
activity
a slight
1266
of
presence
out
or absence the
of this
Km of the under
in reducing phospholipid
Km of tyrosine.
of
crude
pH dependence
of pterin these
6,'7-DMF'H4 or ~-MPH,+,
with effect
as a
rat
their
Km
on the The apparent
6,7-DMPH4 or 6-MPH4 is 0.076 stimulation
0.4 mM
as a function
has been observed
on the
at
and of pH.
a similar
had no effect
studied
decreases
effect
is presented
achieved
hydroxylase
carried
In contrast
presence
is
phospholipid
to have
it
stimulation
in the
was observed
tetrahydropterins,
stimulation
3) of tyrosine
effect
studies
b-fold
tyrosine
the
No appreciable
b-fold.
maximal
concentration
When identical
by 3 to
3 to
stimulation
shows that
phosphatidyl-L-serine values
plot
of tetrahydrobiopterin
phosphatidyl-L-serine
the
tetrahydropterin,
The Lineweaver-Burk function
A typical
significantly.
brain
of this
mM. tyrosine stimulation
(16,
Vol. 59, No. 4, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
PS 20
1
7
1 I
0
! 2
V[Bti4],
, 3
, 4
1 5
1 6
mM
Figure 3. Determination of the K,,, of Bovine Caudate Tyrosine Hydroxylase for Tetrahydrobiopterin 1~ the Presence and Absence of Phosphatidyl-L-Serine. The velocity is expressed as concentration of 3,5-3H-tyros2.ne was 50 $.iM. Reaction nmoles DOPA formed in 10 min. The tritium-release assay used as described in Material.s and Methods with 0.50 mg tyrosine hydroxylase preparation/ml.
171.
The activity
of purified
presence
of either
Fig,
4.
Although
rat
brain
with
the
60 pg/m.l heparin
tyrosine bovine
potassium
tt
naturally
to
the
was essential occurring
the
5.9 to
to pterin
to
shtft
6.1,
this
buffer.
as a function is
pH optimum
effect
was not
of 6.0
for
of pH ln the shown
from
6.0-6.1
observed
in either
to
j.n
soluble
100 mM
Phosphatidyl-L-serine,
however,
6.6-6.8
in either
buffer. of rat
brain
presence
of the
synthetic
investigate
this
stimulation
cofactor.
the
had a pH optimum
enzyme pH optimum
stimulation
in the
hydroxylase
or 0.4 mM phosphaticlyl-L-serine
50 mM TRIS-acetate
or TRIS-acetate
heparin only
from
enzyme which
shift
phosphate
been reported that
or
tyr&ine
has been reported
caudate
has been observed
Since
heparin
hydroxylase
phosphate
potassium
caudate
tyrosine
hydroxylase
cofactor, in the
When tetrahydrobiopterin
1267
has previously
DMPH4, we thought presence was used
of a as the
Vol. 59, No. 4, 1974
BlOCHEMiCAl
AND B~OPHYSICAL RESEARCH COMMUNICATIONS
20I al6l4-
0402I
54
!
1
58
62
!
,
66 70 PH
1
1
74
78
Figure 4. The Effect of pH on Stimulation of Bovine Caudate Tyrosine Hydroxylase by Phosphatidyl-L-Serine or Heparin. All incubations were done in the presence of 100 uM 6-MPH4, 50 UM 3,5-3H-tyrosine, and 100 mM potassium phosphate buffer at the indicated pH values. The concentration of phosphatidyl-L-serine used was 0.40 mM; 60 ng heparin/nii was used for the assays containing the latter compound. Reaction velocity is expressed as nmoles DOPA formed/l0 min. The tritiumrelease assay was used as described in Materials and Methods with 0.64 mg tyrosine hydroxylase preparation/ml.
cofactor
in
studies
pH dependence in the
identical
was observed,
pH optimum
preliminary caudate L-serine, increases
from
studies, tyrosine
V
max
The value
i.e.,
we have
polyanion
one described
no shift
also
observed
only
presence
presence a 3-4
by poly-L-glutamic not
in Fig.
in the
pH 6.1 to 6.6 in the
hydroxylase
this
to the
decreases
the
fold
4, virtually
the
of heparin
same
and a shift
of phosphatidyl-L-serine. stimulation
acid.
In contrast
Km for
the
In
of bovine to phosphatidyl-
cofactor,
but
also
2 *
of
0.22
mM for
the
Km of brain
TH for
BHk in the
absence
of
2Although Kuczenski and Mandell (6) have concluded that the heparin activation of brain tyrosine hydroxylase is a highly specific effect, detailed studies of the activation by other anions, including the effect of polyglutamate described above, strongly indicate that activation is non-specific, being related primarily to the charge density of the anion (I. Katz and S. Kaufman, unpublished results).
1268
Vol.
59,
No.
4, 1974
BIOCHEMICAL
phosphatidyl-L-serine
is about
of BHb (18)
uniform
(assuming
question
about
how tyrosine
cofactor
levels
apparently
that
phosphatidyl-L-serine
this
apparent
likely
candidates
important
role
tissue
so far
in the
below
Although
or other regulation
higher
than
distribution).
hydroxylase
as naturally
BIOPHYSICAL
200 times
decreases
discrepancy.
phosphatidyl-L-serine
AND
RESEARCH
the
reported
This
in this
the
Km value.
the
BHk Km four-fold
heparin
occurring endogenous
tissue
cerebral
of central
adrenergic
levels raises
with
may partially
of brain
a
pterin
The finding
or poly-L-glutamic
modifiers
tissue
observation
can function cofactor
COMMUNICATIONS
acid tyrosine
phospholipids
explain are not hydroxylase,
may play
an
activity.
REFERENCES 1. 2. Z: 2: 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.
Nagatsu, T., Levitt, M. and Udenfriend, S., J. Biol. Chem. a, 2910rzg1-r , 1964. Poillon, W.N., Biochem. Biophys. Res. Commun. g, 64-70, 1971. Nagatsu, T., Sudo, Y. and Nagatsu, I., J. Neurochem. l.8, 217+218g, 1971. Fisher, D.B. and Kaufman, S., J. Biol. Chem. 247, 2250-2253, 1972. Fisher, D.B. and Kaufman, S., J. Biol. Chem. m, 4345-4353, 1973. Kuczenski, R.T. and Mandell, A.J., J. Neurochem. I& 131-137, 1972. Ikeda, M., Fahien, M. and Udenfriend, S., J. Biol. Chem. 2& 4452-4456, 1966. Storm, C.B., Shiman, R. and Kaufman, S., J. Org. Chem. 3&, 3925-3927, 1973. Andrews, K.J.M., Barber, W.E. and Tong, B.P., J. Chem. Sot.(c), 928+X0, 1969. Lloyd, T., Mori, T. and Kaufman, S., Biochemistry g, 2330-2336, 1971. Lowry, O.H., Rosebrough, N.J., Farr, A.L. and Randall, R.J., J. Biol. Chem. 193, 265-275, 1951. Oman, R., Akino, M. and Kaufman, S., J. Biol. Chem. 2& 1330-1340, 1971. Cuatrecasas, P., J. Biol. Chem. 2& ?,OFg-3065, 1970. Tabor, H., Methods in Enzymology, vol. 1, Academic Press, New York pp. 609-610, 1955. Kandera, J., Levi, G. and Lajtha, A., Arch. Biochem. Biophys. &, 24g-z6o, 1968. Kuczenski, R., J. Biol. Chem. N, 5074-5080, 1973. J. Biol. Chem. x, 3114-3122, 1972. Kuczenski, R. and Mandell, A.J., (W. Pfleiderer and E.C. Taylor, eds.), Rembold, H., in Pteridine Chemistr The MacMillan Co., New York, pp. 4 5-484, 1964.
1269