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In vitro carotenogenesis and characterization of the phytoene desaturase reaction inAnacystis
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS Pages 916-921
Vo1.163, No. 2, 1989
September 15,1989
In vitro
Carotenogenesis Desaturase
and C h a r a c t e r i z a t i o n of the Phytoene Reaction in Anacystis
Gerhard Sandmann and Susanne Kowalczyk
Lehrstuhl fur Physiologie und Biochemie der Pflanzen, Universit~t Konstanz, D-7750 Konstanz, FRG Received July 21, 1989 An in vitro system for carotenogenesis has been developed from the cyanobaeterium Anacystis. Precursor conversion is highly effective and almost no colored lhtermediates before R-carotene accumulate. These cell-free reactions have been employed to characterize the phyto~ne desaturation reaction. Phytoene desaturation is dependent on NAb(P) and oxygen but insensitive to inhibitors of plant-type monooxy~enases. This result suggests a hydride/proton transfer as mechanism ~or insertion of a double bond into phytoene. Furthermore, feed-back regulation of phytoene desaturase could be demonstrated for most of the subsequent carotenes. © i~89 Academic Press, Inc.
Carotenoids are synthesized in bacteria, fungi and photosynthetic eukaryotes. In photosynthetic organisms, carotenoids are essential for the function of the photosynthetic apparatus (i). Although the biosynthetic pathway is well established for decades, only a few in vitro systems are available to study formation of the whole carotene series in photosynthetic membranes (2). So far, the most efficient B-carotene synthesis in chloroplasts was achieved with intact spinach chloroplasts from photosynthates
(3) rather than with
solubilisates and isolated membranes from specific precursors
(4,5).
The most complete cell-free carotenogenlc system is the one from a unicellular cyanobacterium.
In two steps it is possible to form prenyl pyrophosphates
(6)
from mevalonic acid (MVA) as well as to convert geranylgeranyl pyrophosphate (GGPP) or phytoene via different carotene intermediates to R-carotene and further on to xanthophylls
(7,8).
In this report we present an in vitro carotenogenlc system from the cyanobacterium Anacystis.
It is advantageous for the study of the steps
that convert phytoene into R-carotene because of the very high conversion rates and an efficiency that prevents accumulation of intermediates under optimum conditions. This in vitro system comes nearest to the in vivo conditions in which no carotene precursors of R-carotene are detectable in photosynthetic membranes. We have used it to study the requirements of the phytoene-desaturase reaction and to draw conclusions on the mechanism of desaturation.
0006-291 X/89 $1.50 Copyright © 1989 by Academic Press, Inc. All rights of reproduction in any form reserved.
916
Vol. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
MATERIALS AND METHODS
Anacystls R2 (= Synechococcus PCC 7942) was cultivated as described for other unzcellular cyanobacterza ~7). The carotene-deficient Fusarium monlliforme SG4 was grown in a 2.4% potato-dextrose broth (w/v; Difco LaDoratorles, Detroit, USA) for 5 days and the carotene mutants of Phycomyces blakesleeanus C5 and C9 according to re(. (9). In vitro carotenogenesis was carried out according to a given procedure (6) with the following modifications: Anac~stis membranes were obtained by French-press treatment (500 bar) in 0.i M rrls-N~l Duffer, pH 8, containing 5 mM dithlothreltol. After centrifugation (12000 x g, 15 min) the pellet was resuspended in the same buffer and the membranes were ready for the assay. Alternatively, this suspension was brought to 1% by Tween 40 and stirred on ice for 30 min. The supernatant was used~f~r incubation. Fusarium SG4 was the source of I~C-GGPP synthesized from R - / 2 - z ~ C ~ m e v a l o n i c acid in most of the experiments. For experiments i ~ t a b l e I P ~ c o m y c e s C5 and C9 were used additionally for generation of ~ C - p h y t o e n e ana ~ ~-lycopene, respectively. After incubation with membranes equivalent to i00 - 120 ~g chlorophyll for 2 h in the l%ght at 30~C and hydrolysis of chlorophylls with 6% KOHofor 15 min at 60~C, the carotenes were partitioned into petrol (b.p. 40-60 Q) and separated by HPLC on a Spherosorb ODS 5 ~ column with acetonitrile/methanol~2-propanol 85:10:5 (v~v/v) as eluent ~I0). Radioactivity was continuously recorded by a radioactivity flow detector (Ramona LS). The radiochromatogram was recorded together with the absorbance of added tracer carotenes (phytoene, ~-carotene, lycopene a n d ~ - c a r o e n e ) by a programable Jasco UV/visible photospect~ometric detector, m o d e l ~ 2 0 1 . Comparison of both traces allows a clear identification of the radioactivity peaks of all intermediates in the pathway from phytoene to B-carotene. By recording of absorbance spectra at the slopes of the carotene peaks with a Phillps diode array detector PU 4021 we ensured that the HPLC system employed was able to separate all the carotenes mentioned. For further demonstration of radioactive purity of the separated carotenes we have occasionally collected the peak fractions and purified them further by TLC (AIoO 3 plates with 7% toluene in petrol (6)).Except for lycopene we found ~o increase of specific radioactivity which indicates that purity is sufficient. Only for lycopene subsequent purification from contaminants by TLC on silica gel G plates with 15% toluene in petrol was necessary. In the feed-back experiments 25 ~g of unlabeled carotenes (for source see re(. i0 ) were ~laced in I ml of acetone in the test tube, 100 ~i of a Tween-40 solution (2.5%, w/v) was added and the acetone evaporated in a stream of N O . Then the complete reaction mixture was transfered into this tube. Semi-~naerobic incubations were carried out in Thunberg tubes by evacuatin~ three times and Dur~ing each time with N~. Conversion rates for phytoene ~esaturase were calculated as the radioactivity ratio ~-carotene/phytoene + ~-carotene. Chlorophyll (II) and protein (12) was determined as described. The fungal mutants were from the Departamento de Genetica. Universidad de Sevilla, Spain. LAB 117682 (3-(l,2,4-triazolyl-l)-l-(4-chlorophenyl)4,4-dimethylpentan-l-one) was a gift from BASF Company, Limburgerhof, FRG.
RESULTS AND DISCUSSION
Attempts
have been made to characterize
formation and interconversion. co(actor
requirements
date (2). Experiments
the reactions
However,
and mechanisms to approach
of the phytoene
extract from the Fusarium mutant SG4 generates pyrophosphate.
This substrate
Alternatively,
14C-phytoene
subsequently
the Phycom~ces
or lycopene as substrates
Saponification hydrocarbons
of the products
to B-carotene
sequence
14C-geranylgeranyl
is converted
mutants
by the Anac~stis
C5 and C9 generated
for carotenogenesis,
and partitioning
(in this case carotenes
(6, 8) in which a soluble
respectively.
into petrol enriched only
and squalene)
and prenyl alcohols
including phytol in the organic phase. By HPLC the carotenes were completely separated and purified subsequently
to
this problem have been performed with a
coupled in vitro system as in previous investigations
membranes.
involved in carotene
little is known about the regulation,
except for lycopene which had to be chromatographed
by TLC to obtain this carotene
917
free from contaminants.
Vol. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
In Table I we have assayed the membrane-associated
steps in carotenogenesis
with a thylakoid preparation from Anacystis. From the substrates employed, GGPP was the first intermediate in the series which was converted to g-carotene. Also the other g-carotene precursors, phytoene and lycopene, were used as effective substrate for g-carotene biosynthesis by the membranes. When phytoene was the substrate, hardly any intermediates were detectable. This lack of intermediate accumulation may reflect the high intactness of the enzymes and their tight association which was not lost during the preparation of the membranes. A high structural order of the enzymes of the specific carotenogenic pathway has been proposed by several authors as a pre-requisite for their cooperation (I). In contrast to other intermediates phytoene was accumulated when GGPP was the substrate. Nevertheless, a conversion rate of more than 50% is comparably high for an in vitro system. Cell-free systems from other photosynthetic organisms exhibit much lower phytoene-desaturation activity or are even blocked behind phytoene (2,13).
Incubation in the dark resulted in a partial block behind ~-carotene. We regard this light effect as an in vitro artefact, especially as we observed complete disruption o f ~ - c a r o t e n e
desaturation
in membranes with conversion rates for
phytoene desaturase of only 40% or less (= moderate intact membranes) compared to a small degree of inhibition of d a r k , - c a r o t e n e membranes showed phytoene-converslon
Conversion of phytoene
desaturation when the
rates of 60 to 90%.
to g-carotene was very efficient provided that the
Anacystis membranes were resuspended in a buffer with comparably low ionic strength, e.g. 0.I M Tris (Table II). Increase in the Tris concentration to i M or treatment with the detergent Tween 40 for 30 min disrupted the biosynthetic chain b e h i n d g - c a r o t e n e
which was almost exclusively accumulated. Obviously,
the coupling of ~-carotene desaturase
to phytoene desaturase and/or the
Table I Carotenogenic activity of thylakoid membranes from Anacystis for various substrates
14C-labeled substrate MVA IPP GGPP Phytoene Lycopene
(i0~ (i0° (4 x (4 x (6 x
dpm) dp~) I0- dpm) I0~ dpm) 193 dpm)
Radioactivity in reaction products (dpm) Phytoene g-Carotene 0 0 6211 -
0 0 4155 6734 2881
MVA = mevalonic acid; IPP = isopentenyl pyrophosphate; GGPP = geranylgeranyl pyrophosphate.
918
Vol. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table II Optimization of the preparation for in vitro assay of the carotene biosynthetic chain with GGPP as substrate Radioactivity (dpm) incorporated into Phytoene ~-Carotene Lycopene g-Carotene
Preparation I. Soluble fraction 2. Membranes resuspended in 0.I M Tris buffer 3. Membranes resuspended in 1.0 M Tris buffer 4. Membrane solubilisate with I% Tween 40 5. as 2. but incubated in darkness
substrate
transfer
conditions
protein
of Table
phytoene-desaturation
repeated
6147
10655
164
308
6655
3508
199
766
step in the in vitro
phytoene
reactions
had no effect.
we can exclude
The stimulatory nucleotides
deplete
activity.
an oxidative
Under
and hydrogen mediator
as proposed
that we found
(table
whereas
to demonstrate
the membranes Phytoene
from
desaturation
decreased
this
the same experimental
by more
mechanism
fully supports
hydroxylation
than 70% (15). by NADP.
which includes
for the desaturation
reaction
on oxidized
In Comparing
a sequence
nicotine
an alternative
by other authors
(16,17).
mechanism
It should be
the same NAD(P) + and oxygen dependence
of
of phytoene.
reaction with NAD(P) + as an electron
919
was
117682 which are both inhibitors
on NADPH and inhibited
dehydrogenation
of a
An absolute
the monooxygenase-catalyzed
a possible
desaturation
desaturation
conditions
effect of oxygen and the dependence
of phytoene
with water elimination
is difficult
in Aphanocapsa
and water elimination
on the
for the insertion
phytoene
CO and LAB
this reaction was dependent
were formed.
mechanism
this reaction.
Semi-anaerobic
decreased
carotenes
to obtain information
to completely
to g-cryptoxanthin
these results, hydroxylation
nor colored
chain.
activity
a basic activity was observed
carotenogenic
Furthermore,
assay where unfavorable
of the biosynthetic
or hydroxylation
desaturase
3B).
0
showed no carotenogenic
did not affect
(table
both inhibitors
of ~-carotene
mentioned
248
are two alternatives
destroy
by one third.
of monooxygenase
involving
174
transferase)
washing-steps
also oxygen-dependent
addition,
5477
A dehydrogenation
of phytoene
nucleotides
conditions,
5012
III were performed
nucleotides
NAD(P) + requirement
reaction
3990
of either NAD or NADP supported
nicotine
nicotine
216
(14). With washed membranes
3A). Addition
because
104
Neither
reaction.
(dehydrogenase-electron
reduced
4519
from Anacystis
(dehydrogenase-monooxygenase) double bond
0
lead to a disconnection
fraction
with GGPP as the substrate.
The experiments
0
is the crucial
or manipulations
The soluble
0
for the
VoI. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table III Nucleotide dependence of phytoene desaturase (A) and interaction with monooxygenase inhibitors (B) Radioactivity (dpm) in Phytoene ~ -Carotene
Conditions A. no nicotine nucleotide + NAD + NADP + NADH + NADPH
% Conversion
1049 1212 1105 2219 1004
473 1304 1252 873 411
31 52 53 28 29
2307 5330 2249 1655
6055 4949 5329 4452
72 48 69 73
~o
Control Semi anaerobic Saturated with CO + 0.i mM LAB
Incubations were carried out wlth membranes resuspended in 1.0 M Tris buffer in the dark; in experiments A the membranes were washed once additionally before resuspension; nicotine-nueleotide concentrations were 1.5 mM.
subsequent
desaturation
step c a t a l y z e d
by~-carotene
desaturase
(data not
shown).
In vitro
phytoene
carotenes showed
from
desaturation
an i n h i b i t o r y
desaturated
lycopene
desaturation
effect.
Under
certain
is also e v i d e n t
in~-carotene
desaturase
these
as e x p e c t e d
strains
feed-back fungus
control
Phycomyces
Interference
Additions
pathway
of one or even conditions
reaction
was
bonds.
made
regulation
in S c e n e d e s m u s
but also already
with
by available the fully
A lower degree
rings
only~-carotene
has
affected
the carotenes
was o b s e r v e d
feed-back
e.g.
Not
desaturase
All
two ionone
from the m u t a t i o n
of phytoene in vitro
(18).
double
this
cells
IV).
decrease
Ii c o n j u g a t e d
in intact
thylakoids
(Table
The s t r o n g e s t
cotaining
or the p r e s e n c e
less e f f e c t i v e . desaturase
with A n a c y s t i s
the b i o s y n t h e t i c
inhibition of p h y t o e n e
mutants
blocked
is a c c u m u l a t e d
phytoene.
for
(9).
Table IV of carotenes with in vitro phytoene desaturatlon by feed-back inhibition
No carotene P-Carotene Lycopene ?-Carotene ~-Carotene
52 18 6 8 13
Incubations were carried out with membranes resuspended in 1.0 M Tris buffer in the dark; 25 ~g of carotenes were added.
920
in
A similar
been d e m o n s t r a t e d
% Conversion of phytoene
of
the
Vol. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Since membrane-bound phytoene desaturase has not been purified successfully, we have used crude membranes to elucidate the properties of this enzyme. For a more detailed characterization, however, an enzyme purified to homogeneity is indlspensible. Progress on the isolation of phytoene desaturase from spinach chloroplasts may be reported soon.
This work was supported by the Deutsche Forschungsgemeinschaft. Due thanks are expressed to Mrs. S. Kuhn for excellent technical assistance.
REFERENCES
I. Britto~ G. (1982) Physiol. Veg. 20, 735-755. 2. Bramle~ P. (1985) Adv. Lipid Res. 21. 243-279. 3. Schulze-Siebert, D. and Schultz, G. (1987) Plant Physiol.84, 1233-1237. 4. Kushwaha, S.C., Subbarayan, C., Becker, D.A. and Porter, J.W. (1969) J. Biol. Chem. 244, 3635-3642. 5. LHtke-Brinkhaus, F., Liedvogel, B., Kreuz, K. and Kleinig, H. (1982) P!anta 156, 176-180. 6. Sandmann, G. (1988) Meth. Enzymology 167, 329-335. 7. Clarke, I.E., Sandmann, G., Bramley, P.M. and B~ger, P. (1982) FEBS Lett. 140, 203-206. 8. Sqndmann, G. and Bramley, P.M. (1985) Planta 164, 259-263. 9. Bramley, P.M. and Davies, B.H. (1976) Phytoche~istry 15, 1913-1916. i0. E r n s t S. and Sandmann, G. (1988) Arch. Microbiol. 150, 590-594. ii. McKinney, G. (1941) J. Biol. Chem. 140, 315-322. 12. Fanger, B.O. (1987) Analyt. Biochem. 162, 11-17. 13. Bugy, M.J., Britton, G. and Goodwin, T.W. (1974) Phytochemistry 13, 125-129. 14. Massey, V. and Ghisla, S. (1983) in: Biological Oxidations (Sund, H. and Ullrich, V.,eds) pp. 114-139, Springer, Berlin. 13. Sandmann, G. and Bramley, P.M. (1985) Biochim. Biophys. Acta 843, 73-77. 16. Britton, G. (1979) Z. Naturforsch. 34c, 979-985. 17. Goodwin, T.W. (1983) Biochem. Soc. Transactions ii, 473-483. 18. Britton, G. and Powls, R. (1977) Phy~ochemistry 16, 1253-1255.
921
Vo1.163, No. 2, 1989
September 15,1989
In vitro
Carotenogenesis Desaturase
and C h a r a c t e r i z a t i o n of the Phytoene Reaction in Anacystis
Gerhard Sandmann and Susanne Kowalczyk
Lehrstuhl fur Physiologie und Biochemie der Pflanzen, Universit~t Konstanz, D-7750 Konstanz, FRG Received July 21, 1989 An in vitro system for carotenogenesis has been developed from the cyanobaeterium Anacystis. Precursor conversion is highly effective and almost no colored lhtermediates before R-carotene accumulate. These cell-free reactions have been employed to characterize the phyto~ne desaturation reaction. Phytoene desaturation is dependent on NAb(P) and oxygen but insensitive to inhibitors of plant-type monooxy~enases. This result suggests a hydride/proton transfer as mechanism ~or insertion of a double bond into phytoene. Furthermore, feed-back regulation of phytoene desaturase could be demonstrated for most of the subsequent carotenes. © i~89 Academic Press, Inc.
Carotenoids are synthesized in bacteria, fungi and photosynthetic eukaryotes. In photosynthetic organisms, carotenoids are essential for the function of the photosynthetic apparatus (i). Although the biosynthetic pathway is well established for decades, only a few in vitro systems are available to study formation of the whole carotene series in photosynthetic membranes (2). So far, the most efficient B-carotene synthesis in chloroplasts was achieved with intact spinach chloroplasts from photosynthates
(3) rather than with
solubilisates and isolated membranes from specific precursors
(4,5).
The most complete cell-free carotenogenlc system is the one from a unicellular cyanobacterium.
In two steps it is possible to form prenyl pyrophosphates
(6)
from mevalonic acid (MVA) as well as to convert geranylgeranyl pyrophosphate (GGPP) or phytoene via different carotene intermediates to R-carotene and further on to xanthophylls
(7,8).
In this report we present an in vitro carotenogenlc system from the cyanobacterium Anacystis.
It is advantageous for the study of the steps
that convert phytoene into R-carotene because of the very high conversion rates and an efficiency that prevents accumulation of intermediates under optimum conditions. This in vitro system comes nearest to the in vivo conditions in which no carotene precursors of R-carotene are detectable in photosynthetic membranes. We have used it to study the requirements of the phytoene-desaturase reaction and to draw conclusions on the mechanism of desaturation.
0006-291 X/89 $1.50 Copyright © 1989 by Academic Press, Inc. All rights of reproduction in any form reserved.
916
Vol. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
MATERIALS AND METHODS
Anacystls R2 (= Synechococcus PCC 7942) was cultivated as described for other unzcellular cyanobacterza ~7). The carotene-deficient Fusarium monlliforme SG4 was grown in a 2.4% potato-dextrose broth (w/v; Difco LaDoratorles, Detroit, USA) for 5 days and the carotene mutants of Phycomyces blakesleeanus C5 and C9 according to re(. (9). In vitro carotenogenesis was carried out according to a given procedure (6) with the following modifications: Anac~stis membranes were obtained by French-press treatment (500 bar) in 0.i M rrls-N~l Duffer, pH 8, containing 5 mM dithlothreltol. After centrifugation (12000 x g, 15 min) the pellet was resuspended in the same buffer and the membranes were ready for the assay. Alternatively, this suspension was brought to 1% by Tween 40 and stirred on ice for 30 min. The supernatant was used~f~r incubation. Fusarium SG4 was the source of I~C-GGPP synthesized from R - / 2 - z ~ C ~ m e v a l o n i c acid in most of the experiments. For experiments i ~ t a b l e I P ~ c o m y c e s C5 and C9 were used additionally for generation of ~ C - p h y t o e n e ana ~ ~-lycopene, respectively. After incubation with membranes equivalent to i00 - 120 ~g chlorophyll for 2 h in the l%ght at 30~C and hydrolysis of chlorophylls with 6% KOHofor 15 min at 60~C, the carotenes were partitioned into petrol (b.p. 40-60 Q) and separated by HPLC on a Spherosorb ODS 5 ~ column with acetonitrile/methanol~2-propanol 85:10:5 (v~v/v) as eluent ~I0). Radioactivity was continuously recorded by a radioactivity flow detector (Ramona LS). The radiochromatogram was recorded together with the absorbance of added tracer carotenes (phytoene, ~-carotene, lycopene a n d ~ - c a r o e n e ) by a programable Jasco UV/visible photospect~ometric detector, m o d e l ~ 2 0 1 . Comparison of both traces allows a clear identification of the radioactivity peaks of all intermediates in the pathway from phytoene to B-carotene. By recording of absorbance spectra at the slopes of the carotene peaks with a Phillps diode array detector PU 4021 we ensured that the HPLC system employed was able to separate all the carotenes mentioned. For further demonstration of radioactive purity of the separated carotenes we have occasionally collected the peak fractions and purified them further by TLC (AIoO 3 plates with 7% toluene in petrol (6)).Except for lycopene we found ~o increase of specific radioactivity which indicates that purity is sufficient. Only for lycopene subsequent purification from contaminants by TLC on silica gel G plates with 15% toluene in petrol was necessary. In the feed-back experiments 25 ~g of unlabeled carotenes (for source see re(. i0 ) were ~laced in I ml of acetone in the test tube, 100 ~i of a Tween-40 solution (2.5%, w/v) was added and the acetone evaporated in a stream of N O . Then the complete reaction mixture was transfered into this tube. Semi-~naerobic incubations were carried out in Thunberg tubes by evacuatin~ three times and Dur~ing each time with N~. Conversion rates for phytoene ~esaturase were calculated as the radioactivity ratio ~-carotene/phytoene + ~-carotene. Chlorophyll (II) and protein (12) was determined as described. The fungal mutants were from the Departamento de Genetica. Universidad de Sevilla, Spain. LAB 117682 (3-(l,2,4-triazolyl-l)-l-(4-chlorophenyl)4,4-dimethylpentan-l-one) was a gift from BASF Company, Limburgerhof, FRG.
RESULTS AND DISCUSSION
Attempts
have been made to characterize
formation and interconversion. co(actor
requirements
date (2). Experiments
the reactions
However,
and mechanisms to approach
of the phytoene
extract from the Fusarium mutant SG4 generates pyrophosphate.
This substrate
Alternatively,
14C-phytoene
subsequently
the Phycom~ces
or lycopene as substrates
Saponification hydrocarbons
of the products
to B-carotene
sequence
14C-geranylgeranyl
is converted
mutants
by the Anac~stis
C5 and C9 generated
for carotenogenesis,
and partitioning
(in this case carotenes
(6, 8) in which a soluble
respectively.
into petrol enriched only
and squalene)
and prenyl alcohols
including phytol in the organic phase. By HPLC the carotenes were completely separated and purified subsequently
to
this problem have been performed with a
coupled in vitro system as in previous investigations
membranes.
involved in carotene
little is known about the regulation,
except for lycopene which had to be chromatographed
by TLC to obtain this carotene
917
free from contaminants.
Vol. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
In Table I we have assayed the membrane-associated
steps in carotenogenesis
with a thylakoid preparation from Anacystis. From the substrates employed, GGPP was the first intermediate in the series which was converted to g-carotene. Also the other g-carotene precursors, phytoene and lycopene, were used as effective substrate for g-carotene biosynthesis by the membranes. When phytoene was the substrate, hardly any intermediates were detectable. This lack of intermediate accumulation may reflect the high intactness of the enzymes and their tight association which was not lost during the preparation of the membranes. A high structural order of the enzymes of the specific carotenogenic pathway has been proposed by several authors as a pre-requisite for their cooperation (I). In contrast to other intermediates phytoene was accumulated when GGPP was the substrate. Nevertheless, a conversion rate of more than 50% is comparably high for an in vitro system. Cell-free systems from other photosynthetic organisms exhibit much lower phytoene-desaturation activity or are even blocked behind phytoene (2,13).
Incubation in the dark resulted in a partial block behind ~-carotene. We regard this light effect as an in vitro artefact, especially as we observed complete disruption o f ~ - c a r o t e n e
desaturation
in membranes with conversion rates for
phytoene desaturase of only 40% or less (= moderate intact membranes) compared to a small degree of inhibition of d a r k , - c a r o t e n e membranes showed phytoene-converslon
Conversion of phytoene
desaturation when the
rates of 60 to 90%.
to g-carotene was very efficient provided that the
Anacystis membranes were resuspended in a buffer with comparably low ionic strength, e.g. 0.I M Tris (Table II). Increase in the Tris concentration to i M or treatment with the detergent Tween 40 for 30 min disrupted the biosynthetic chain b e h i n d g - c a r o t e n e
which was almost exclusively accumulated. Obviously,
the coupling of ~-carotene desaturase
to phytoene desaturase and/or the
Table I Carotenogenic activity of thylakoid membranes from Anacystis for various substrates
14C-labeled substrate MVA IPP GGPP Phytoene Lycopene
(i0~ (i0° (4 x (4 x (6 x
dpm) dp~) I0- dpm) I0~ dpm) 193 dpm)
Radioactivity in reaction products (dpm) Phytoene g-Carotene 0 0 6211 -
0 0 4155 6734 2881
MVA = mevalonic acid; IPP = isopentenyl pyrophosphate; GGPP = geranylgeranyl pyrophosphate.
918
Vol. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table II Optimization of the preparation for in vitro assay of the carotene biosynthetic chain with GGPP as substrate Radioactivity (dpm) incorporated into Phytoene ~-Carotene Lycopene g-Carotene
Preparation I. Soluble fraction 2. Membranes resuspended in 0.I M Tris buffer 3. Membranes resuspended in 1.0 M Tris buffer 4. Membrane solubilisate with I% Tween 40 5. as 2. but incubated in darkness
substrate
transfer
conditions
protein
of Table
phytoene-desaturation
repeated
6147
10655
164
308
6655
3508
199
766
step in the in vitro
phytoene
reactions
had no effect.
we can exclude
The stimulatory nucleotides
deplete
activity.
an oxidative
Under
and hydrogen mediator
as proposed
that we found
(table
whereas
to demonstrate
the membranes Phytoene
from
desaturation
decreased
this
the same experimental
by more
mechanism
fully supports
hydroxylation
than 70% (15). by NADP.
which includes
for the desaturation
reaction
on oxidized
In Comparing
a sequence
nicotine
an alternative
by other authors
(16,17).
mechanism
It should be
the same NAD(P) + and oxygen dependence
of
of phytoene.
reaction with NAD(P) + as an electron
919
was
117682 which are both inhibitors
on NADPH and inhibited
dehydrogenation
of a
An absolute
the monooxygenase-catalyzed
a possible
desaturation
desaturation
conditions
effect of oxygen and the dependence
of phytoene
with water elimination
is difficult
in Aphanocapsa
and water elimination
on the
for the insertion
phytoene
CO and LAB
this reaction was dependent
were formed.
mechanism
this reaction.
Semi-anaerobic
decreased
carotenes
to obtain information
to completely
to g-cryptoxanthin
these results, hydroxylation
nor colored
chain.
activity
a basic activity was observed
carotenogenic
Furthermore,
assay where unfavorable
of the biosynthetic
or hydroxylation
desaturase
3B).
0
showed no carotenogenic
did not affect
(table
both inhibitors
of ~-carotene
mentioned
248
are two alternatives
destroy
by one third.
of monooxygenase
involving
174
transferase)
washing-steps
also oxygen-dependent
addition,
5477
A dehydrogenation
of phytoene
nucleotides
conditions,
5012
III were performed
nucleotides
NAD(P) + requirement
reaction
3990
of either NAD or NADP supported
nicotine
nicotine
216
(14). With washed membranes
3A). Addition
because
104
Neither
reaction.
(dehydrogenase-electron
reduced
4519
from Anacystis
(dehydrogenase-monooxygenase) double bond
0
lead to a disconnection
fraction
with GGPP as the substrate.
The experiments
0
is the crucial
or manipulations
The soluble
0
for the
VoI. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Table III Nucleotide dependence of phytoene desaturase (A) and interaction with monooxygenase inhibitors (B) Radioactivity (dpm) in Phytoene ~ -Carotene
Conditions A. no nicotine nucleotide + NAD + NADP + NADH + NADPH
% Conversion
1049 1212 1105 2219 1004
473 1304 1252 873 411
31 52 53 28 29
2307 5330 2249 1655
6055 4949 5329 4452
72 48 69 73
~o
Control Semi anaerobic Saturated with CO + 0.i mM LAB
Incubations were carried out wlth membranes resuspended in 1.0 M Tris buffer in the dark; in experiments A the membranes were washed once additionally before resuspension; nicotine-nueleotide concentrations were 1.5 mM.
subsequent
desaturation
step c a t a l y z e d
by~-carotene
desaturase
(data not
shown).
In vitro
phytoene
carotenes showed
from
desaturation
an i n h i b i t o r y
desaturated
lycopene
desaturation
effect.
Under
certain
is also e v i d e n t
in~-carotene
desaturase
these
as e x p e c t e d
strains
feed-back fungus
control
Phycomyces
Interference
Additions
pathway
of one or even conditions
reaction
was
bonds.
made
regulation
in S c e n e d e s m u s
but also already
with
by available the fully
A lower degree
rings
only~-carotene
has
affected
the carotenes
was o b s e r v e d
feed-back
e.g.
Not
desaturase
All
two ionone
from the m u t a t i o n
of phytoene in vitro
(18).
double
this
cells
IV).
decrease
Ii c o n j u g a t e d
in intact
thylakoids
(Table
The s t r o n g e s t
cotaining
or the p r e s e n c e
less e f f e c t i v e . desaturase
with A n a c y s t i s
the b i o s y n t h e t i c
inhibition of p h y t o e n e
mutants
blocked
is a c c u m u l a t e d
phytoene.
for
(9).
Table IV of carotenes with in vitro phytoene desaturatlon by feed-back inhibition
No carotene P-Carotene Lycopene ?-Carotene ~-Carotene
52 18 6 8 13
Incubations were carried out with membranes resuspended in 1.0 M Tris buffer in the dark; 25 ~g of carotenes were added.
920
in
A similar
been d e m o n s t r a t e d
% Conversion of phytoene
of
the
Vol. 163, No. 2, 1989
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Since membrane-bound phytoene desaturase has not been purified successfully, we have used crude membranes to elucidate the properties of this enzyme. For a more detailed characterization, however, an enzyme purified to homogeneity is indlspensible. Progress on the isolation of phytoene desaturase from spinach chloroplasts may be reported soon.
This work was supported by the Deutsche Forschungsgemeinschaft. Due thanks are expressed to Mrs. S. Kuhn for excellent technical assistance.
REFERENCES
I. Britto~ G. (1982) Physiol. Veg. 20, 735-755. 2. Bramle~ P. (1985) Adv. Lipid Res. 21. 243-279. 3. Schulze-Siebert, D. and Schultz, G. (1987) Plant Physiol.84, 1233-1237. 4. Kushwaha, S.C., Subbarayan, C., Becker, D.A. and Porter, J.W. (1969) J. Biol. Chem. 244, 3635-3642. 5. LHtke-Brinkhaus, F., Liedvogel, B., Kreuz, K. and Kleinig, H. (1982) P!anta 156, 176-180. 6. Sandmann, G. (1988) Meth. Enzymology 167, 329-335. 7. Clarke, I.E., Sandmann, G., Bramley, P.M. and B~ger, P. (1982) FEBS Lett. 140, 203-206. 8. Sqndmann, G. and Bramley, P.M. (1985) Planta 164, 259-263. 9. Bramley, P.M. and Davies, B.H. (1976) Phytoche~istry 15, 1913-1916. i0. E r n s t S. and Sandmann, G. (1988) Arch. Microbiol. 150, 590-594. ii. McKinney, G. (1941) J. Biol. Chem. 140, 315-322. 12. Fanger, B.O. (1987) Analyt. Biochem. 162, 11-17. 13. Bugy, M.J., Britton, G. and Goodwin, T.W. (1974) Phytochemistry 13, 125-129. 14. Massey, V. and Ghisla, S. (1983) in: Biological Oxidations (Sund, H. and Ullrich, V.,eds) pp. 114-139, Springer, Berlin. 13. Sandmann, G. and Bramley, P.M. (1985) Biochim. Biophys. Acta 843, 73-77. 16. Britton, G. (1979) Z. Naturforsch. 34c, 979-985. 17. Goodwin, T.W. (1983) Biochem. Soc. Transactions ii, 473-483. 18. Britton, G. and Powls, R. (1977) Phy~ochemistry 16, 1253-1255.
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