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The conversion of dihydroneopterin triphosphate to sepiapterin by an enzyme system from Drosophila melanogaster
Vol. 67, No. 3, 1975
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
THE CONVERSION OF DIHYDRONEOPTERIN TRIPHOSPHATE TO SEPIAPTERIN BY AN ENZYME SYSTEM FROM Drosophila Ching
Liang
Fan,
Gwen G. Krivi
melanogaster
and Gene M. Brown
Department of Biology Massachusetts Institute of Technology Cambridge, Mass. 02139
Received
Ott
ober IO,1975
Summary : The enzyme system for the synthesis of the pteridine pigment, sepiapterin, from 2-amino-4-hydroxy-6(D-erythro-1 ‘,2’,3’-trihydroxypropyl)7,8-dihydropteridine triphosphate (dihydroneo:teriniphosphate) has been found in extracts NADP+ or NADPH and Mg2+ are required for this enzyof Drosophila melanogaster. No sepiapterin is produced when dihydroneopterin is supmatic transfcrmation. plied as substrate in place of dihydroneopterin triphosphate. Introduction: produced
from
hydrolase known
Dihydroneopterin’ GTP in the presence
I to distinguish
to occur
this
and other compound
mediate
it
in Drosophila
of several
ranthopterin,
role
(9)
kinds
its
of H2-neopterin-PPP
enzyme,
(5)
of all
from
report
and the
in the
melanogaster. of pterins
present pterin,
paper
the
in
with trivial
the
name for Pterin
has that
Syrian
golden
large
quanti-
These
include
(the
support
finding
view
of GTP cyclo-
contains
further
(10)
(11)
and drosopterin
we provide
as a key intermediate is
--et al.
as eye pigments.
sepiapterin
In the p-resent
1 Dihydroneopterin or H2-neopterin 6-(lt,2’,3’-trihydroxypropyl)7,8-dihydropteridine. for 2-amino-4-hydroxypteridine.
animal
acid
that
that
a key inter-
This
of biopterin
(l)), (6).
is
(6) on the presence
mainly
II
expressed
H2-neopterin)
by Fukushima,
The latter
GTP cyclo-
of folic
pterins.
biosynthesis
of Fan and Brown
portion
view has been form,
observations
(or
to be
melanogaster
of the pterin
naturally-occurring
recent
known
GTP cyclohydrolase
and Drosophila
dephosphorylated
isoxanthopterin,
eye pigment).
plants
is
enzyme GTP cyclohydrolase
a similar
in bacteria,
an intermediate
and by the
hydrolase
pterin
is
from
(H2-neopterin-PPP)
to be a precursor
(or perhaps
some support
hamsters
ties
is known pterins
of the
(2-4),
in the biosynthesis
received suggest
it
in bacteria
H2-neopterin-PPP (7,8)
triphosphate
major for
the
one of
2-amino-4-hydroxyis the trivial
name
Vol. 67, No. 3, 1975
BIOCHEMICAL
these pigments, sepiapterin,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
can be synthesized from HZ-neopterin-PPP in the
presence of an enzyme system from Drosophila melanogaster. enzymatic transformation shown later
The nature of this
becomesapparent from the formulas of the compounds
in Fig. 3 of this paper.
Materials and Methods: [U-14C]GTP was purchased from Amersham-Searle Corp., phosphocellulose and ECTEOLA-cellulose from Gallard Schlesinger, and piperazineN,N'-bis(2-ethane-sulfonic acid) (PIPES) buffer from Calbiochem. Purified GTP cyclohydrolase I from g coli was supplied by John Yim of this laboratory. Sepiapterin was prepared (12) from sepia mutants of Drosophila melanogaster. Crude extracts of Drosophila melanogaster, strain Oregon-R (obtained from Dr. Linda Hall), were prepared as described earlier (6). Radioactive H2-neopterin PPPwas prepared enzymatically by incubation (overnight at 42' in a total volume of 1.0 ml) of 100 uM [U-14C]GTP (10' cpm), 100 mMPIPES buffer (pH 7.5), 100 mM KCl, 5 mMEDTA (pH 7.5), and 10 mM2-mercaptoethanol with enough purified GTP cyclohydrolase I to achieve at least 90"0 conversion of GTP to H2-neopterin-PPP (measured as described earlier (6)). The standard reaction mixture for the assay of sepiapterin synthesis contained per 0.2 ml total volume: 75 mMPIPES buffer (pH 7.5), 20 mMMgC12, 3.3 mMNADPH,0.1 ml of the incubated reaction mixture described above as a source of H2-neopterin-PPP, and Drosophila extract. After incubation for 1 hour at 42", 4 units of alkaline phosphatase (Worthington) and 0.1 pmole of sepiapterin were added and the incubation was continued for an additional 30 minutes. Each mixture was heated at 100" for 5 minutes and subjected to centrifugation. The resulting supernatant material was applied to a phosphocellulose column (1.1 x 50 cm). The column was developed at 4" with water. Fractions of 5.0 ml were collected at a rate of 15 ml per hour. A portion of each fraction was analyzed for radioactivity in a scintillation counter (Packard 3320). The fractions containing standard sepiapterin were yellow. Sepiapterin synthesis was estimated from the radioactivity in the region of elution from the column of standard sepiapterin. Thin layer chromatography was carried out (ascending technique) at room temperature with 13255 cellulose Eastman Chromagramsheets (S x 10 cm). Protein was determined by the method of Lowry, et -- al. (13) with bovine serum albumin as the standard. Results:
Preliminary
experiments indicated that a radioactive
the chromatographic properties by incubation of radioactive melanogaster.
of sepiapterin
substance with
could be produced enzymatically
H2-neopterin-PPP with a crude extract
of Drosophila
Similar experiments revealed that the addition of NADP+or NADPH
stimulated the production of the putative MgC12was also stimulatory.
The results
sepiapterin
by 2- to 3-fold and that
of an experiment devised to measure the
enzymatic conversion of H2-neopterin-PPP to this radioactive presence of a crude extract
are given in Fig. 1.
substance in the
In this experiment, both NADPH
and MgC12were included in the incubation mixture to promote maximal synthesis of the product.
The data presented in the figure
1048
represent the elution pattern
BIOCHEMICAL
Vol. 67, No. 3, 1975
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
3Ok 6
m ‘0- 20 ; 2 15 2 .z IO ::
8
0;
5 -I 0
0
100
200
300
400
Elution
500
Volume,
600
700
ml
pattern from phosphocellulose of an incubated reaction mixture. Fig. 1. Elution The standard reaction mixture was prepared to contain either a crude extract of Drosophila (2.8 mg of protein) or heated (at 100” for 5 minutes) extract. After incubation (1 hour at 42”) and treatment with phosphatase, sepiapterin (0.1 nmole) The mixtures were applied to individual was added to each mixture as a marker. columns and each was developed with water (650 ml) and then with 1% NH3. Portions (1.5 ml) of fractions were analyzed for radioactivity. The standard sepiapterin appeared as a yellow substance in the fractions collected in the 135-150 The elution pattern of the reaction mixture containing unheated exml region. tract is represented with closed circles (0) and that of the control mixture, containing heated extract, with open circles (0).
from
a phosphocellulose
tion
of
of the
14
C-labeled
elution
pterin.
phosphatase)
GTP .
also
contained
Peak 1 coincided radioactive small
quantities
extract.
Peak 3 sepia-
the positions
of elution
of guanosine
and
must have been remained (Peak
the
void
presumably were
H2-
during
the develop-
produced
enzymatical
of the
identities.
in the
from unreacted
identified
volume
radioactive
1049
(by treatment
as a contaminant
and oxidation
of unknown
of unknown
derived
6) was produced
substances
components
incuba-
of standard
xanthine,
with
and unheated
after
of elution
treatment
radioactive
present
the position
and neopterin
Peak 2 contained
of these
compounds heated
GTP that
by the phosphatase
All
several
with
from unreacted
column.
chromatography.
with
The guanosine
preparation,
ment of the
with
coincides
respectively.
H2-neopterin-PPP
tained
H2-neopterin-PPP
pattern
neopterin-PPP
from
of radioactive
Peaks 5 and 6 coincide
neopterin, with
column
by thin column
layer and con-
Peaks 4, 7 and 8
compounds.
Approximately
ly
Vol. 67, No. 3, 1975
BIOCHEMICAL
94% of the radioactivity
applied
radioactivity
with
Peaks
associated
1, 3, 4 and 7 (418,000
PPP consumed
during
the
the material fractions the
that
concentrated
(Table
I).
tic
to be presented that
supports
material
the
in Peak 3 of Fig. The presence
I.
material
in 0.075
ml water.
subjected
conclusion
that
remainder
1 will in crude
we obtained
this
extracts
Identification by Thin Product as Sepiapterin
paper
peak.
to dryness, (0.004
ml,
and the
enzyma-
experiment evidence
was sepiapterin.
radioactive
product
of sepiapterin
Layer
and pyridine
present
Chromatography
in solvent
of the
nucleotides
Enzymatic
system
Compound
1
2
3
4
5
6
Sepiapterin
0.40
0.39
0.24
0.48
0.49
0.40
0.40
0.39
0.24
0.49
0.50
0.40
product
cpm)
to as sepiapterin.
RF values
Enzymatic
and
11,000
spectrophotometric product
the
chromatography
In another
the
Peaks 1,
purpose,
sepiapterin
radioactive
of this
be referred
layer
was sepiapterin.
paper,
in
For this
Portions
of standard
in
of H2-neopterin
sepiapterin
concentrated
to thin
The
in Peak 3 was sepiapterin,
analyses.
combined,
the product
the amount
putative
1-8.
present
present
present
were
were
in this
in the
Peak 3, the
of RF values
that
later
For convenience,
Table
the peak
indicate
in
in Peaks
materials
radioactivity
to chromatographic
The coincidence
product
was recovered
equalled
Of the
for
was redissolved
of the
column
enzymatically-produced
radioactive
was subjected
residue
the
incubation.
the
constituting
to the
cpm) approximately
3, 4 and 7, 54% was accounted To confirm
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
NH3 (2:l); 2, l-propanol-ethylacetate-H20Solvent systems: 1, 1-propanol-1% (7:1:2); 3, 3% NH4Cl; 4, l-butanol-acetic acid-H20 (4:1:2); 5, l-propanol1% ammonium acetate (1:l); 6, ethanol-ammonium borate (pH 8.0, 5% as boric acid)-3% NH4Cl (2:l:l). Standard sepiapterin was observed as yellow fluorescent zones under ultraviolet light. To locate the radioactive enzymatic product, appropriate areas were scraped from the plate and transferred to vials, each containing 1.7 ml of H20 and 5.0 ml of ScintiVerse (Fisher and radioactivity was measured in a scintillation counter. Scientific Co.),
1050
Vol. 67, No. 3, 1975
interferred pterin
with and (b)
quirement with
BIOCHEMICAL
.
(a)
the
thesis
To circumvent
tion.
of the
these
was recovered
40 and 60% saturation This
degree
that
fraction
for
and kind
the production
of pyridine
we fractionated
most
of the
enzymatic
in the protein
fraction
and that
was used
RESEARCH COMMUNICATIONS
analysis
difficulties,
and found
of sepiapterin
between
spectrophotometric
an assessment
ammonium sulfate
AND BIOPHYSICAL
in the
no sepiapterin remainder
of the
of sepia
nucleotide
re-
the
crude
extract
activity
for
that
precipitated
the syn-
was present
in this
frac-
experiments
to be reported
below. The synthesis concentration replace
HZ-neopterin-PPP
produced
requirement, is
added
nucleotide
from HZ-neopterin-PPP
up to 14 mg/ml.
ammonium sulfate pterin
of sepiapterin
is
enzymatically
from
is not
mixtures.
are:
(a)
(b) no sepiapterin
omitted
(e) no sepiapterin
to reaction
observations
as substrate,
fraction
and
Other
was linear
the
reaction
phosphorylated, is produced
Neither
protein
H2-neopterin
cannot
is produced mixture, (d)
unless
with
(c)
Mg2+ is either
if the
the sepia-
an absolute
NADP+ or NADPH
NAD+ nor NADH can satisfy
this
pyridine
requirement.
250
300
350 Wave
400 Length,
450 nm
Fig. 2. Absorption spectrum of the enzymatic product. Six standard reaction mixtures were prepared (see text). After incubation, the mixtures were heated and subjected to centrifugation to remove insoluble material. The combined supernatant fractions were applied to a standard phosphocellulose column and the column was developed with H20. The fractions constituting the region of elution of sepiapterin were combined (40 ml) and concentrated to 3.0 ml. The resulting yellow solution was applied to an ECTEOLA-cellulose column (1.1 x 55 cm) . The column was developed with H20. The yellow fractions were combined (20 ml), concentrated (1 ml) and subjected to chromatography on a second phosphocellulose column. The resulting yellow fractions were combined (40 ml) and concentrated to 1 ml. The spectrum of this material in H20 was determined with a Perkin-Elmer spectrophotometer, Model 202.
1051
Vol. 67, No. 3, 1975
In order analysis, added
is
of the
an amount
The absorption
along that
the
the
drolase
(6),
and the
results
compound pterins. tial tally
is
quantities
and Akino
(14)
is
in this
in Drosophila. is
H
for
legend
in Fig.
strongly
to
to Fig.
sepiapterin. I,
melanogaster
the
paper
conversion
on the
support
than
sepiapterin or not
presently
under is not
contains
2, This,
indicates
formation
contention of all
to occur
pterins
investigation converted
the
latter
naturally-occurring
are known these
of sepiapterin
that
in substan-
are made enzymatiin our
to sepiapterin
I H
H
GTP cyclohy-
of GTP to H2-neopterin-PPP,
enzymatic
to the
Whether
HZ-neopterin
P
mixtures
given
in Table
in the biosynthesis
other
that
Drosophila
further
a key intermediate
Our observation
presented
in the
No
sepiapterin.
catalyzes
from H2-neopterin-PPP
reaction
product,
the enzyme that
pterins
of the
yellow
by Tsusue
and to each was
to 24 mg of protein.
of the purified
that
Several
equal
a spectrophotometric
prepared,
was as described
evidence
lend
were
fraction
The observation
from H2-neopterin-PPP
mixtures
for
product
chromatographic product
product
The processing
reported
reported
enzymatic
reaction
sepiapterin
that
enzymatic
Discussion:
of the
was included.
spectrum
with
with
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of ammonium sulfate
the putative
identical
enough standard
sepiapterin
purify 2.
to obtain
six
standard
BIOCHEMICAL
laboratory. by the
H+ In
reaction mechanism for the enzymatic conversion of a phosFig. 3. Possible phorylated form of H2-neopterin (I) to sepiapterin (V). @represents either one, two, or three phosphate residues. The carbon in compound I marked with an asterisk (*) is carbon 1’.
1052
Vol. 67, No. 3, 1975
enzyme system necessary occurs
of Drosophila
and suggests coincidently
how many of the neopterin
tionated
nor the
the
to produce
compound
sepiapterin
by the prior
a reduction
could (V).
might
should occurs
the pyridine
in the
of the
neopterin-PPP
for
the
and thus
provides
initial
By rearrangement,
NADP+, but
later
to regenerate proposed
through
might
this
a pyridine
involved
include
nucleotide,
group.
one might
expect
no oxidation
that or
knowledge
of the reaction
in the
and
to be facili-
More precise
and the mechanism
III
1’ to a keto
occurs
reaction.
include,
putative
does not
the NADP+ since
enzyme or enzymes
be involved. would
be expected
this
frac-
intermediates
for
on carbon if
H,I
or triphosphate)
mechanism
no role
of the OH group
H2-
neither
might
3.
know
the
of sepiapterin
reaction
require
since
pyrophosphate
step
yet
to allow
(or
be converted this
requirement
we do not
is
groups
and we have not yet
formation
Although
overall
of H2-neopterin
how many enzymes
in Fig.
then
in the
occur
nucleotide
the purification
to decide
shown
oxidation
Such an oxidation
reduction
II,
of phosphate
available,
of a phosphate
or a reduction
removal
to sepiapterin
has been
removal
but
need to be retained
directly
pathway
intermediate
an oxidation
tated
reaction
of sepiapterin,
groups
enough
form
of one or more of the phosphate
formation
phosphate
enzyme system
enzyme-bound
the
the
RESEARCH COMMUNICATIONS
a phosphorylated
removal
H2-neopterin-PP
step,
IV to give
the
to be converted
A plausible as a first
that
three
AND BIOPHYSICAL
shows that
with
moiety
neopterin-P
group
BIOCHEMICAL
must
conversion
about await
of H2-
to sepiapterin.
Acknowledgment: This work was supported by research grants from the National Institutes of Health (AM03442) and the National Science Foundation (GB33939). REFERENCES 1. Foor,
F.,
and Brown,
2. Burg,
A.W.,
G.M.
and Brown,
G.M.
3. Shiota,
T.,
and Palumbo,
4. Guroff,
G.,
and Strenkoski,
5. Mitsuda, H., Suzuki, l2-, 192-204. 6. Fan, 7. Burg,
C.L., A.W.,
and Brown, and Brown,
(1975)
Y.,
J.
(1966)
M.P.
G.M.
J.
(1966)
Tadera,
K.,
(1975)
Chem.,
Biochim.
(1965)
C.A.
G.M.
Biol.
Chem., Biol.
and Iwai,
Biochem.
(1968)
Biophys.
Biol. J.
J.
1053
Biol.
250,
3545-3551. Acta, 240,
Chem., F. (1966)
Genetics, Chem.,
117,
4449-4453. 241,
2220-2227.
J. Vitaminol.,
in press. 245,
275-278.
2349-2358.
Vol. 67, No. 3, 1975
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
8. Shiota, T., Jackson, R., and Baugh, C.M. (1970) in Chemistry and Biology of Pteridines (K. Iwai, M., Akino, M. Goto, and Y. Iwanami, eds.), Int'l. Academic Printing Co., Tokyo, pp. 265-279. 9. Heine, M.C., and Brown, G.M. (1975) Biochim. Biophys. Acta, in press. 10. Brown, G.M. (1971) Adv. in Enzymology, 35, 35-77. 11. Fukushima, K., Eto, I., Saliba, D., and Shiota, T. (1975) Biochem. Biophys. Res. Commun.,65, 644-651. 12. Fukishima, T. (1970) Arch. Biochem. Biophys., 139, 361-369. 13. Lowry, O.H., Rosebrough, N.J., Farr, A.L., and Randall, R.J. (1951) J. Chem., 193, 265-275. 14. Tsusue, M., and Akino, M. (1965) Zool. Mag., 74, 91-94.
1054
Biol.
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
THE CONVERSION OF DIHYDRONEOPTERIN TRIPHOSPHATE TO SEPIAPTERIN BY AN ENZYME SYSTEM FROM Drosophila Ching
Liang
Fan,
Gwen G. Krivi
melanogaster
and Gene M. Brown
Department of Biology Massachusetts Institute of Technology Cambridge, Mass. 02139
Received
Ott
ober IO,1975
Summary : The enzyme system for the synthesis of the pteridine pigment, sepiapterin, from 2-amino-4-hydroxy-6(D-erythro-1 ‘,2’,3’-trihydroxypropyl)7,8-dihydropteridine triphosphate (dihydroneo:teriniphosphate) has been found in extracts NADP+ or NADPH and Mg2+ are required for this enzyof Drosophila melanogaster. No sepiapterin is produced when dihydroneopterin is supmatic transfcrmation. plied as substrate in place of dihydroneopterin triphosphate. Introduction: produced
from
hydrolase known
Dihydroneopterin’ GTP in the presence
I to distinguish
to occur
this
and other compound
mediate
it
in Drosophila
of several
ranthopterin,
role
(9)
kinds
its
of H2-neopterin-PPP
enzyme,
(5)
of all
from
report
and the
in the
melanogaster. of pterins
present pterin,
paper
the
in
with trivial
the
name for Pterin
has that
Syrian
golden
large
quanti-
These
include
(the
support
finding
view
of GTP cyclo-
contains
further
(10)
(11)
and drosopterin
we provide
as a key intermediate is
--et al.
as eye pigments.
sepiapterin
In the p-resent
1 Dihydroneopterin or H2-neopterin 6-(lt,2’,3’-trihydroxypropyl)7,8-dihydropteridine. for 2-amino-4-hydroxypteridine.
animal
acid
that
that
a key inter-
This
of biopterin
(l)), (6).
is
(6) on the presence
mainly
II
expressed
H2-neopterin)
by Fukushima,
The latter
GTP cyclo-
of folic
pterins.
biosynthesis
of Fan and Brown
portion
view has been form,
observations
(or
to be
melanogaster
of the pterin
naturally-occurring
recent
known
GTP cyclohydrolase
and Drosophila
dephosphorylated
isoxanthopterin,
eye pigment).
plants
is
enzyme GTP cyclohydrolase
a similar
in bacteria,
an intermediate
and by the
hydrolase
pterin
is
from
(H2-neopterin-PPP)
to be a precursor
(or perhaps
some support
hamsters
ties
is known pterins
of the
(2-4),
in the biosynthesis
received suggest
it
in bacteria
H2-neopterin-PPP (7,8)
triphosphate
major for
the
one of
2-amino-4-hydroxyis the trivial
name
Vol. 67, No. 3, 1975
BIOCHEMICAL
these pigments, sepiapterin,
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
can be synthesized from HZ-neopterin-PPP in the
presence of an enzyme system from Drosophila melanogaster. enzymatic transformation shown later
The nature of this
becomesapparent from the formulas of the compounds
in Fig. 3 of this paper.
Materials and Methods: [U-14C]GTP was purchased from Amersham-Searle Corp., phosphocellulose and ECTEOLA-cellulose from Gallard Schlesinger, and piperazineN,N'-bis(2-ethane-sulfonic acid) (PIPES) buffer from Calbiochem. Purified GTP cyclohydrolase I from g coli was supplied by John Yim of this laboratory. Sepiapterin was prepared (12) from sepia mutants of Drosophila melanogaster. Crude extracts of Drosophila melanogaster, strain Oregon-R (obtained from Dr. Linda Hall), were prepared as described earlier (6). Radioactive H2-neopterin PPPwas prepared enzymatically by incubation (overnight at 42' in a total volume of 1.0 ml) of 100 uM [U-14C]GTP (10' cpm), 100 mMPIPES buffer (pH 7.5), 100 mM KCl, 5 mMEDTA (pH 7.5), and 10 mM2-mercaptoethanol with enough purified GTP cyclohydrolase I to achieve at least 90"0 conversion of GTP to H2-neopterin-PPP (measured as described earlier (6)). The standard reaction mixture for the assay of sepiapterin synthesis contained per 0.2 ml total volume: 75 mMPIPES buffer (pH 7.5), 20 mMMgC12, 3.3 mMNADPH,0.1 ml of the incubated reaction mixture described above as a source of H2-neopterin-PPP, and Drosophila extract. After incubation for 1 hour at 42", 4 units of alkaline phosphatase (Worthington) and 0.1 pmole of sepiapterin were added and the incubation was continued for an additional 30 minutes. Each mixture was heated at 100" for 5 minutes and subjected to centrifugation. The resulting supernatant material was applied to a phosphocellulose column (1.1 x 50 cm). The column was developed at 4" with water. Fractions of 5.0 ml were collected at a rate of 15 ml per hour. A portion of each fraction was analyzed for radioactivity in a scintillation counter (Packard 3320). The fractions containing standard sepiapterin were yellow. Sepiapterin synthesis was estimated from the radioactivity in the region of elution from the column of standard sepiapterin. Thin layer chromatography was carried out (ascending technique) at room temperature with 13255 cellulose Eastman Chromagramsheets (S x 10 cm). Protein was determined by the method of Lowry, et -- al. (13) with bovine serum albumin as the standard. Results:
Preliminary
experiments indicated that a radioactive
the chromatographic properties by incubation of radioactive melanogaster.
of sepiapterin
substance with
could be produced enzymatically
H2-neopterin-PPP with a crude extract
of Drosophila
Similar experiments revealed that the addition of NADP+or NADPH
stimulated the production of the putative MgC12was also stimulatory.
The results
sepiapterin
by 2- to 3-fold and that
of an experiment devised to measure the
enzymatic conversion of H2-neopterin-PPP to this radioactive presence of a crude extract
are given in Fig. 1.
substance in the
In this experiment, both NADPH
and MgC12were included in the incubation mixture to promote maximal synthesis of the product.
The data presented in the figure
1048
represent the elution pattern
BIOCHEMICAL
Vol. 67, No. 3, 1975
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
3Ok 6
m ‘0- 20 ; 2 15 2 .z IO ::
8
0;
5 -I 0
0
100
200
300
400
Elution
500
Volume,
600
700
ml
pattern from phosphocellulose of an incubated reaction mixture. Fig. 1. Elution The standard reaction mixture was prepared to contain either a crude extract of Drosophila (2.8 mg of protein) or heated (at 100” for 5 minutes) extract. After incubation (1 hour at 42”) and treatment with phosphatase, sepiapterin (0.1 nmole) The mixtures were applied to individual was added to each mixture as a marker. columns and each was developed with water (650 ml) and then with 1% NH3. Portions (1.5 ml) of fractions were analyzed for radioactivity. The standard sepiapterin appeared as a yellow substance in the fractions collected in the 135-150 The elution pattern of the reaction mixture containing unheated exml region. tract is represented with closed circles (0) and that of the control mixture, containing heated extract, with open circles (0).
from
a phosphocellulose
tion
of
of the
14
C-labeled
elution
pterin.
phosphatase)
GTP .
also
contained
Peak 1 coincided radioactive small
quantities
extract.
Peak 3 sepia-
the positions
of elution
of guanosine
and
must have been remained (Peak
the
void
presumably were
H2-
during
the develop-
produced
enzymatical
of the
identities.
in the
from unreacted
identified
volume
radioactive
1049
(by treatment
as a contaminant
and oxidation
of unknown
of unknown
derived
6) was produced
substances
components
incuba-
of standard
xanthine,
with
and unheated
after
of elution
treatment
radioactive
present
the position
and neopterin
Peak 2 contained
of these
compounds heated
GTP that
by the phosphatase
All
several
with
from unreacted
column.
chromatography.
with
The guanosine
preparation,
ment of the
with
coincides
respectively.
H2-neopterin-PPP
tained
H2-neopterin-PPP
pattern
neopterin-PPP
from
of radioactive
Peaks 5 and 6 coincide
neopterin, with
column
by thin column
layer and con-
Peaks 4, 7 and 8
compounds.
Approximately
ly
Vol. 67, No. 3, 1975
BIOCHEMICAL
94% of the radioactivity
applied
radioactivity
with
Peaks
associated
1, 3, 4 and 7 (418,000
PPP consumed
during
the
the material fractions the
that
concentrated
(Table
I).
tic
to be presented that
supports
material
the
in Peak 3 of Fig. The presence
I.
material
in 0.075
ml water.
subjected
conclusion
that
remainder
1 will in crude
we obtained
this
extracts
Identification by Thin Product as Sepiapterin
paper
peak.
to dryness, (0.004
ml,
and the
enzyma-
experiment evidence
was sepiapterin.
radioactive
product
of sepiapterin
Layer
and pyridine
present
Chromatography
in solvent
of the
nucleotides
Enzymatic
system
Compound
1
2
3
4
5
6
Sepiapterin
0.40
0.39
0.24
0.48
0.49
0.40
0.40
0.39
0.24
0.49
0.50
0.40
product
cpm)
to as sepiapterin.
RF values
Enzymatic
and
11,000
spectrophotometric product
the
chromatography
In another
the
Peaks 1,
purpose,
sepiapterin
radioactive
of this
be referred
layer
was sepiapterin.
paper,
in
For this
Portions
of standard
in
of H2-neopterin
sepiapterin
concentrated
to thin
The
in Peak 3 was sepiapterin,
analyses.
combined,
the product
the amount
putative
1-8.
present
present
present
were
were
in this
in the
Peak 3, the
of RF values
that
later
For convenience,
Table
the peak
indicate
in
in Peaks
materials
radioactivity
to chromatographic
The coincidence
product
was recovered
equalled
Of the
for
was redissolved
of the
column
enzymatically-produced
radioactive
was subjected
residue
the
incubation.
the
constituting
to the
cpm) approximately
3, 4 and 7, 54% was accounted To confirm
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
NH3 (2:l); 2, l-propanol-ethylacetate-H20Solvent systems: 1, 1-propanol-1% (7:1:2); 3, 3% NH4Cl; 4, l-butanol-acetic acid-H20 (4:1:2); 5, l-propanol1% ammonium acetate (1:l); 6, ethanol-ammonium borate (pH 8.0, 5% as boric acid)-3% NH4Cl (2:l:l). Standard sepiapterin was observed as yellow fluorescent zones under ultraviolet light. To locate the radioactive enzymatic product, appropriate areas were scraped from the plate and transferred to vials, each containing 1.7 ml of H20 and 5.0 ml of ScintiVerse (Fisher and radioactivity was measured in a scintillation counter. Scientific Co.),
1050
Vol. 67, No. 3, 1975
interferred pterin
with and (b)
quirement with
BIOCHEMICAL
.
(a)
the
thesis
To circumvent
tion.
of the
these
was recovered
40 and 60% saturation This
degree
that
fraction
for
and kind
the production
of pyridine
we fractionated
most
of the
enzymatic
in the protein
fraction
and that
was used
RESEARCH COMMUNICATIONS
analysis
difficulties,
and found
of sepiapterin
between
spectrophotometric
an assessment
ammonium sulfate
AND BIOPHYSICAL
in the
no sepiapterin remainder
of the
of sepia
nucleotide
re-
the
crude
extract
activity
for
that
precipitated
the syn-
was present
in this
frac-
experiments
to be reported
below. The synthesis concentration replace
HZ-neopterin-PPP
produced
requirement, is
added
nucleotide
from HZ-neopterin-PPP
up to 14 mg/ml.
ammonium sulfate pterin
of sepiapterin
is
enzymatically
from
is not
mixtures.
are:
(a)
(b) no sepiapterin
omitted
(e) no sepiapterin
to reaction
observations
as substrate,
fraction
and
Other
was linear
the
reaction
phosphorylated, is produced
Neither
protein
H2-neopterin
cannot
is produced mixture, (d)
unless
with
(c)
Mg2+ is either
if the
the sepia-
an absolute
NADP+ or NADPH
NAD+ nor NADH can satisfy
this
pyridine
requirement.
250
300
350 Wave
400 Length,
450 nm
Fig. 2. Absorption spectrum of the enzymatic product. Six standard reaction mixtures were prepared (see text). After incubation, the mixtures were heated and subjected to centrifugation to remove insoluble material. The combined supernatant fractions were applied to a standard phosphocellulose column and the column was developed with H20. The fractions constituting the region of elution of sepiapterin were combined (40 ml) and concentrated to 3.0 ml. The resulting yellow solution was applied to an ECTEOLA-cellulose column (1.1 x 55 cm) . The column was developed with H20. The yellow fractions were combined (20 ml), concentrated (1 ml) and subjected to chromatography on a second phosphocellulose column. The resulting yellow fractions were combined (40 ml) and concentrated to 1 ml. The spectrum of this material in H20 was determined with a Perkin-Elmer spectrophotometer, Model 202.
1051
Vol. 67, No. 3, 1975
In order analysis, added
is
of the
an amount
The absorption
along that
the
the
drolase
(6),
and the
results
compound pterins. tial tally
is
quantities
and Akino
(14)
is
in this
in Drosophila. is
H
for
legend
in Fig.
strongly
to
to Fig.
sepiapterin. I,
melanogaster
the
paper
conversion
on the
support
than
sepiapterin or not
presently
under is not
contains
2, This,
indicates
formation
contention of all
to occur
pterins
investigation converted
the
latter
naturally-occurring
are known these
of sepiapterin
that
in substan-
are made enzymatiin our
to sepiapterin
I H
H
GTP cyclohy-
of GTP to H2-neopterin-PPP,
enzymatic
to the
Whether
HZ-neopterin
P
mixtures
given
in Table
in the biosynthesis
other
that
Drosophila
further
a key intermediate
Our observation
presented
in the
No
sepiapterin.
catalyzes
from H2-neopterin-PPP
reaction
product,
the enzyme that
pterins
of the
yellow
by Tsusue
and to each was
to 24 mg of protein.
of the purified
that
Several
equal
a spectrophotometric
prepared,
was as described
evidence
lend
were
fraction
The observation
from H2-neopterin-PPP
mixtures
for
product
chromatographic product
product
The processing
reported
reported
enzymatic
reaction
sepiapterin
that
enzymatic
Discussion:
of the
was included.
spectrum
with
with
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
of ammonium sulfate
the putative
identical
enough standard
sepiapterin
purify 2.
to obtain
six
standard
BIOCHEMICAL
laboratory. by the
H+ In
reaction mechanism for the enzymatic conversion of a phosFig. 3. Possible phorylated form of H2-neopterin (I) to sepiapterin (V). @represents either one, two, or three phosphate residues. The carbon in compound I marked with an asterisk (*) is carbon 1’.
1052
Vol. 67, No. 3, 1975
enzyme system necessary occurs
of Drosophila
and suggests coincidently
how many of the neopterin
tionated
nor the
the
to produce
compound
sepiapterin
by the prior
a reduction
could (V).
might
should occurs
the pyridine
in the
of the
neopterin-PPP
for
the
and thus
provides
initial
By rearrangement,
NADP+, but
later
to regenerate proposed
through
might
this
a pyridine
involved
include
nucleotide,
group.
one might
expect
no oxidation
that or
knowledge
of the reaction
in the
and
to be facili-
More precise
and the mechanism
III
1’ to a keto
occurs
reaction.
include,
putative
does not
the NADP+ since
enzyme or enzymes
be involved. would
be expected
this
frac-
intermediates
for
on carbon if
H,I
or triphosphate)
mechanism
no role
of the OH group
H2-
neither
might
3.
know
the
of sepiapterin
reaction
require
since
pyrophosphate
step
yet
to allow
(or
be converted this
requirement
we do not
is
groups
and we have not yet
formation
Although
overall
of H2-neopterin
how many enzymes
in Fig.
then
in the
occur
nucleotide
the purification
to decide
shown
oxidation
Such an oxidation
reduction
II,
of phosphate
available,
of a phosphate
or a reduction
removal
to sepiapterin
has been
removal
but
need to be retained
directly
pathway
intermediate
an oxidation
tated
reaction
of sepiapterin,
groups
enough
form
of one or more of the phosphate
formation
phosphate
enzyme system
enzyme-bound
the
the
RESEARCH COMMUNICATIONS
a phosphorylated
removal
H2-neopterin-PP
step,
IV to give
the
to be converted
A plausible as a first
that
three
AND BIOPHYSICAL
shows that
with
moiety
neopterin-P
group
BIOCHEMICAL
must
conversion
about await
of H2-
to sepiapterin.
Acknowledgment: This work was supported by research grants from the National Institutes of Health (AM03442) and the National Science Foundation (GB33939). REFERENCES 1. Foor,
F.,
and Brown,
2. Burg,
A.W.,
G.M.
and Brown,
G.M.
3. Shiota,
T.,
and Palumbo,
4. Guroff,
G.,
and Strenkoski,
5. Mitsuda, H., Suzuki, l2-, 192-204. 6. Fan, 7. Burg,
C.L., A.W.,
and Brown, and Brown,
(1975)
Y.,
J.
(1966)
M.P.
G.M.
J.
(1966)
Tadera,
K.,
(1975)
Chem.,
Biochim.
(1965)
C.A.
G.M.
Biol.
Chem., Biol.
and Iwai,
Biochem.
(1968)
Biophys.
Biol. J.
J.
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250,
3545-3551. Acta, 240,
Chem., F. (1966)
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4449-4453. 241,
2220-2227.
J. Vitaminol.,
in press. 245,
275-278.
2349-2358.
Vol. 67, No. 3, 1975
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
8. Shiota, T., Jackson, R., and Baugh, C.M. (1970) in Chemistry and Biology of Pteridines (K. Iwai, M., Akino, M. Goto, and Y. Iwanami, eds.), Int'l. Academic Printing Co., Tokyo, pp. 265-279. 9. Heine, M.C., and Brown, G.M. (1975) Biochim. Biophys. Acta, in press. 10. Brown, G.M. (1971) Adv. in Enzymology, 35, 35-77. 11. Fukushima, K., Eto, I., Saliba, D., and Shiota, T. (1975) Biochem. Biophys. Res. Commun.,65, 644-651. 12. Fukishima, T. (1970) Arch. Biochem. Biophys., 139, 361-369. 13. Lowry, O.H., Rosebrough, N.J., Farr, A.L., and Randall, R.J. (1951) J. Chem., 193, 265-275. 14. Tsusue, M., and Akino, M. (1965) Zool. Mag., 74, 91-94.
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