Functional properties of diapophytoene and related desaturases of C30 and C40 carotenoid biosynthetic pathways

The desaturation reactions of C₃₀ carotenoids from diapophytoene to diaponeurosporene was investigated in vitro and by complementation in Escherichia coli. The expressed diapophytoene desaturase from Staphylococcus aureus inserts three double bonds in an FAD-dependent reaction. The enzyme is inhibited by diphenylamine. In the complementation experiment diapophytoene desaturase was able to convert C₄₀ phytoene to some extend but exhibited a high affinity to ζ-carotene. Comparison to the reaction of a phytoene desaturase from Rhodobacter capsulatus catalyzing a parallel three-step desaturation sequence with the corresponding C₄₀ carotenes revealed that this desaturase can also convert C₃₀ diapophytoene. Other homologous bacterial C₄₀ carotene desaturases could also utilize C₃₀ substrates, including one type of ζ-carotene desaturase which converted diaponeurosporene to diapolycopene. Further complementation experiments including the diapophytoene synthase gene from S. aureus revealed that the C₃₀ carotenogenic pathway is determined by this initial enzyme which is highly homologous to C₄₀ phytoene synthases.     

Progress on molecular breeding and metabolic engineering of biosynthesis pathways of C(30), C(35), C(40), C(45), C(50) carotenoids

At least 700 natural carotenoids have been characterized; they can be classified into C(30), C(40) and C(50) subfamilies. The first step of C(40) pathway is the combination of two molecules of geranylgeranyl pyrophosphate to synthesize phytoene by phytoene synthase (CrtB or PSY). Most natural carotenoids originate from different types and levels of desaturation by phytoene desaturase (CrtI or PDS+ZDS), cyclization by lycopene cyclase (CrtY or LYC) and other modifications by different modifying enzyme (CrtA, CrtU, CrtZ or BCH, CrtX, CrtO, etc.) of this C(40) backbone. The first step of C(30) pathway is the combination of two molecules of FDP to synthesize diapophytoene by diapophytoene synthase (CrtM). But natural C(30) pathway only goes through a few steps of desaturation to form diaponeurosporene by diapophytoene desaturase (CrtN). Natural C(50) carotenoid decaprenoxanthin is synthesized starting from the C(40) carotenoid lycopene by the addition of 2 C(5) units. Concerned the importance of carotenoids, more and more attention has been concentrated on achieving novel carotenoids. The method being used successfully is to construct carotenoids biosynthesis pathways by metabolic engineering. The strategy of metabolic engineering is to engineer a small number of stringent upstream enzymes (CrtB, CrtI, CrtY, CrtM, or CrtN), then use a lot of promiscuous downstream enzymes to obtain large number of novel carotenoids. Two key enzymes phytoene desaturase (CrtI(m)) and lycopene cyclase (CrtY(m)) have been modified and used with a series of downstream modifying enzymes with broad substrate specificity, such as monooxygenase (CrtA), carotene desaturase (CrtU), carotene hydroxylase (CrtZ), zeaxanthin glycosylase (CrtX) and carotene ketolase (CrtO) to extend successfully natural C(30) and C(40) pathways in E. coli. Existing C(30) synthase CrtM to synthesize carotenoids with different chain length have been engineered and a series of novel carotenoids have been achieved using downstream modifying enzymes. C(35) carotenoid biosynthesis pathway has been constructed in E. coli as described. C(45) and C(50) carotenoid biosynthesis pathways have also been constructed in E. coli, but it is still necessary to extend these two pathways. Those novel acyclic or cyclic carotenoids have a potential ability to protect against photooxidation and radical-mediated peroxidation reactions which makes them interesting pharmaceutical candidates.     

Bansformation of tobacco with a mutated cyanobacterial phytoene desaturase gene confers resistance to bleaching herbicides

Carotenoids are constituents of the photosynthetic apparatus and essential for plant survival because of their involvement in protection of chlorophylls against photooxidation. Certain classes of herbicides are interfering with carotenoid biosynthesis leading to pigment destruction and a bleached plant phenotype. One important target site for bleaching herbicides is the enzyme phytoene desaturase catalysing the desaturation of phytoene in zeta-carotene. This enzymatic reaction can be inhibited by norflurazon or fluridone. We have transformed tobacco with a mutated cyanobacterial phytoene desaturase gene (pds) derived from the Synechococcus PCC 7942 mutant NFZ4. Characterization of the resulting transformants revealed an up to 58 fold higher norflurazon resistance in comparison to wild type controls. The tolerance for fluridone was also increased 3 fold in the transgenics. Furthermore, the transformed tobacco maintained a higher level of D1 protein of photosystem II indicating a lower susceptibility to photooxidative damage in the presence of norflurazon. In contrast, the genetic manipulation did not confer herbicide resistance against zeta-carotene desaturase inhibitors.     

Characterization and molecular cloning of a flavoprotein catalyzing the synthesis of phytofluene and zeta-carotene in Capsicum chromoplasts.

In plants, zeta-carotene is the first visible carotenoid formed in the biosynthetic pathway through the following two-step desaturation reaction: phytoene-->phytofluene--> zeta-carotene. Using Capsicum annuum chromoplast membranes and the reconstitution system previously described [Camara, B., Bardat, F. & Monéger, R. (1982) Eur. J. Biochem. 127, 255-258], we have attempted to purify the desaturase(s) catalyzing these reactions. The two activities were coincidental during all the purification procedures. Only a single polypeptide with 56 +/- 2 kDa was detected by SDS/PAGE of all active fractions. The enzyme contained protein-bound FAD. Antibodies raised against the purified polypeptide selectively precipitated the phytoene and the phytofluene desaturase activities, thus demonstrating that the enzyme is a bifunctional flavoprotein. The antibodies were used to isolate a full-length cDNA clone from which was deduced the primary structure of the desaturase which contains a characteristic dinucleotide-binding site. Overexpression of the cDNA in Escherichia coli allowed the production of a recombinant desaturase which had all the properties of the chromoplast desaturase. The phytoene/phytofluene desaturase mRNA levels were extremely low in green fruits and increased slightly before detectable carotenoid synthesis and remained constant throughout ripening. However, the desaturase activity and protein levels were found to increase significantly during the chloroplast to chromoplast transition in C. annuum fruits.     

Evolution of carotene desaturation: the complication of a simple pathway

In a series of desaturation reactions, the trienoic structures of phytoene and diapophytoene are extended to a maximum of 15 or 11 conjugated double bonds, respectively. After the cloning of several genes from bacteria and eukaryotes, the desaturation reactions were first analyzed in a heterologous host by functional genetic complementation. In addition, different desaturases were heterologously expressed and the reactions studied in vitro. This revealed that in archaea, non-photosynthetic prokaryotes and fungi the desaturases differ significantly from convergently evolved desaturases in cyanobacteria, Chlorobaculum (old name Chlorobium) species and eukaryotic photosynthetic organisms including plants. Detailed analysis of the desaturation reactions including the determination of the substrates converted by the enzymes, the intermediates and the products formed in the reactions revealed the bacterial all-trans desaturation pathway catalyzed by a single enzyme and the cyanobacterial/plant type poly-cis desaturation pathway which involves two closely related desaturases. This indicates that in the course of evolution of carotenogenesis from bacteria via cyanobacteria to plants, the simple situation of one enzyme for the entire reaction sequence from phytoene to all-trans lycopene changed to a more complex process. Three individual enzymes, newly acquired phytoene and ζ-carotene desaturases, as well as a carotene isomerase which is phylogenetically related to CrtI are involved. Only the CrtI-type enzymes seem to have the property to catalyze cis to trans conversion of carotenes.     

Catalytic properties of an expressed and purified higher plant type zeta-carotene desaturase from Capsicum annuum.

The zeta-carotene desaturase from Capsicum annuum (EC 1.14.99.-) was expressed in Escherichia coli, purified and characterized biochemically. The enzyme acts as a monomer with lipophilic quinones as cofactors. Km values for the substrate zeta-carotene or the intermediate neurosporene in the two-step desaturation reaction are almost identical. Product analysis showed that different lycopene isomers are formed, including substantial amounts of the all-trans form, together with 7,7',9,9'-tetracis prolycopene via the corresponding neurosporene isomers. The application of different geometric isomers as substrates revealed that the zeta-carotene desaturase has no preference for certain isomers and that the nature of the isomers formed during catalysis depends strictly on the isomeric composition of the substrate.     

A single five-step desaturase is involved in the carotenoid biosynthesis pathway to beta-carotene and torulene in Neurospora crassa

Phytoene desaturase Al-1 from Neurospora crassa was expressed in Escherichia coli and an active enzyme was isolated which catalyzed the stepwise introduction of up to five double bonds into the substrate phytoene. The major reaction products were 3, 4-didehydrolycopene and lycopene. Several of the desaturation intermediates, zeta-carotene, neurosporene, and lycopene, were also accepted as a substrate by Al-1. In contrast to the structurally related bacterial enzymes, the cofactor involved in the dehydrogenation reaction was NAD for Al-1. In situ competition with a neurosporene- and lycopene-converting hydratase and cyclase indicated that these enzymes can divert intermediates of the desaturation sequence. Based on the in vitro and in vivo results, the organization of the phytoene desaturase from N. crassa was proposed as an assembly of identical protein units which are responsible for the multistep reaction. However, the spatial arrangement should be loose enough to allow an exchange of individual intermediates in both directions in and out of this complex. Since gamma-carotene is not accepted as a substrate by Al-1, the formation of torulene must proceed exclusively by the cyclization of 3,4-didehydrolycopene.     

Cooperation of two carotene desaturases in the production of lycopene in Myxococcus xanthus

In Myxococcus xanthus, all known carotenogenic genes are grouped together in the gene cluster carB-carA, except for one, crtIb (previously named carC). We show here that the first three genes of the carB operon, crtE, crtIa, and crtB, encode a geranygeranyl synthase, a phytoene desaturase, and a phytoene synthase, respectively. We demonstrate also that CrtIa possesses cis-to-trans isomerase activity, and is able to dehydrogenate phytoene, producing phytofluene and zeta-carotene. Unlike the majority of CrtI-type phytoene desaturases, CrtIa is unable to perform the four dehydrogenation events involved in converting phytoene to lycopene. CrtIb, on the other hand, is incapable of dehydrogenating phytoene and lacks cis-to-trans isomerase activity. However, the presence of both CrtIa and CrtIb allows the completion of the four desaturation steps that convert phytoene to lycopene. Therefore, we report a unique mechanism where two distinct CrtI-type desaturases cooperate to carry out the four desaturation steps required for lycopene formation. In addition, we show that there is a difference in substrate recognition between the two desaturases; CrtIa dehydrogenates carotenes in the cis conformation, whereas CrtIb dehydrogenates carotenes in the trans conformation.     

Identification of the carotenoid isomerase provides insight into carotenoid biosynthesis, prolamellar body formation, and photomorphogenesis

Carotenoids are essential photoprotective and antioxidant pigments synthesized by all photosynthetic organisms. Most carotenoid biosynthetic enzymes were thought to have evolved independently in bacteria and plants. For example, in bacteria, a single enzyme (CrtI) catalyzes the four desaturations leading from the colorless compound phytoene to the red compound lycopene, whereas plants require two desaturases (phytoene and zeta-carotene desaturases) that are unrelated to the bacterial enzyme. We have demonstrated that carotenoid desaturation in plants requires a third distinct enzyme activity, the carotenoid isomerase (CRTISO), which, unlike phytoene and zeta-carotene desaturases, apparently arose from a progenitor bacterial desaturase. The Arabidopsis CRTISO locus was identified by the partial inhibition of lutein synthesis in light-grown tissue and the accumulation of poly-cis-carotene precursors in dark-grown tissue of crtISO mutants. After positional cloning, enzymatic analysis of CRTISO expressed in Escherichia coli confirmed that the enzyme catalyzes the isomerization of poly-cis-carotenoids to all-trans-carotenoids. Etioplasts of dark-grown crtISO mutants accumulate acyclic poly-cis-carotenoids in place of cyclic all-trans-xanthophylls and also lack prolamellar bodies (PLBs), the lattice of tubular membranes that defines an etioplast. This demonstrates a requirement for carotenoid biosynthesis to form the PLB. The absence of PLBs in crtISO mutants demonstrates a function for this unique structure and carotenoids in facilitating chloroplast development during the first critical days of seedling germination and photomorphogenesis.     

Genetic dissection of carotenoid synthesis in arabidopsis defines plastoquinone as an essential component of phytoene desaturation.

Carotenoids are C40 tetraterpenoids synthesized by nuclear-encoded multienzyme complexes located in the plastids of higher plants. To understand further the components and mechanisms involved in carotenoid synthesis, we screened Arabidopsis for mutations that disrupt this pathway and cause accumulation of biosynthetic intermediates. Here, we report the identification and characterization of two nonallelic albino mutations, pds1 and pds2 (for phytoene desaturation), that are disrupted in phytoene desaturation and as a result accumulate phytoene, the first C40 compound of the pathway. Surprisingly, neither mutation maps to the locus encoding the phytoene desaturase enzyme, indicating that the products of at least three loci are required for phytoene desaturation in higher plants. Because phytoene desaturase catalyzes an oxidation reaction, it has been suggested that components of an electron transport chain may be involved in this reaction. Analysis of pds1 and pds2 shows that both mutants are plastoquinone and tocopherol deficient, in addition to their inability to desaturate phytoene. Separate steps of the plastoquinone/tocopherol biosynthetic pathway are affected by these two mutations. The pds1 mutation affects the enzyme 4-hydroxyphenylpyruvate dioxygenase because it can be rescued by growth on the product but not the substrate of this enzyme, homogentisic acid and 4-hydroxyphenylpyruvate, respectively. The pds2 mutation most likely affects the prenyl/phytyl transferase enzyme of this pathway. Because tocopherol-deficient mutants in the green alga Scenedesmus obliquus can synthesize carotenoids, our findings demonstrate conclusively that plastoquinone is an essential component in carotenoid synthesis. We propose a model for carotenoid synthesis in photosynthetic tissue whereby plastoquinone acts as an intermediate electron carrier between carotenoid desaturases and the photosynthetic electron transport chain.     

In vitro characterization of two different Phycomyces blakesleeanus mutants with impaired phytoene desaturation.

In vitro phytoene desaturation was investigated in two Phycomyces blakesleeanus mutants, C5 and S442, in which phytoene is accumulated instead of beta-carotene. For strain C5 but not strain S442 the phenotypic block of phytoene conversion could be overcome in vitro by the addition of Tween 40. Immunodetection of phytoene desaturase revealed in all cases the presence of a 40-kilodalton protein.     

Bleaching activity of 4-phenyl-3-(substituted benzylthio)-4H-1,2,4-triazoles

A variety of 4-aryl- and 4-alkyl-3-(substituted benzylthio)-4H-1,2,4-triazoles were prepared and evaluated for their bleaching activity by the lettuce seedling test. Among the series of tested compounds, 4-(3-fluorophenyl)-3-(4-trifluoromethylbenzylthio)-4H-1,2,4-triazole (39) exhibited the highest bleaching activity, causing complete bleaching symptoms at 10 microM. In the dark condition, compound 39 inhibited the formation of such carotenoids as beta-carotene, violaxanthin, neoxanthin and lutein, resulting in the formation of zeta-carotene, phytoene, phytofluene and beta-zeacarotene, which were not detected in the untreated control. Treatment by compound 39 at 50 microM resulted in the amount of accumulated zeta-carotene being seven-fold higher than that of phytoene, phytofluene and beta-zeacarotene. These results suggest that compound 39 might have interfered with desaturation, especially zeta-carotene desaturation, during carotenoid biosynthesis.     

Kinetic variations determine the product pattern of phytoene desaturase from Rubrivivax gelatinosus

In bacteria and fungi, the degree of carotenoid desaturation is determined by a single enzyme, the CrtI-type phytoene desaturase. In different organisms, this enzyme can carry out either three, four or even five desaturation steps. The purple bacterium Rubrivivax gelatinosus is the only known species in which reaction products of a 3-step and a 4-step desaturation (i.e. neurosporene and lycopene derivatives) accumulate simultaneously. The properties of this phytoene desaturation to catalyze neurosporene or lycopene were analyzed by heterologous complementations in Escherichia coli and by in vitro studies. They demonstrated that high enzyme concentrations or low phytoene supply favor the formation of lycopene. Under these conditions, CrtI from Rhodobacter spheroides can be forced in vitro to lycopene formation although this carotene is not synthesized in this species. All results can be explained by a model based on the competition between phytoene and neurosporene for the substrate binding site of phytoene desaturase. Mutations in CrtI from Rvi. gelatinosus have been generated resulting in increased lycopene formation in Escherichia coli. This modification in catalysis is due to increased amounts of CrtI protein.     

Why Is Golden Rice Golden (Yellow) Instead of Red?

The endosperm of Golden Rice (Oryza sativa) is yellow due to the accumulation of beta-carotene (provitamin A) and xanthophylls. The product of the two carotenoid biosynthesis transgenes used in Golden Rice, phytoene synthase (PSY) and the bacterial carotene desaturase (CRTI), is lycopene, which has a red color. The absence of lycopene in Golden Rice shows that the pathway proceeds beyond the transgenic end point and thus that the endogenous pathway must also be acting. By using TaqMan real-time PCR, we show in wild-type rice endosperm the mRNA expression of the relevant carotenoid biosynthetic enzymes encoding phytoene desaturase, zeta-carotene desaturase, carotene cis-trans-isomerase, beta-lycopene cyclase, and beta-carotene hydroxylase; only PSY mRNA was virtually absent. We show that the transgenic phenotype is not due to up-regulation of expression of the endogenous rice pathway in response to the transgenes, as was suggested to be the case in tomato (Lycopersicon esculentum) fruit, where CRTI expression resulted in a similar carotenoid phenomenon. This means that beta-carotene and xanthophyll formation in Golden Rice relies on the activity of constitutively expressed intrinsic rice genes (carotene cis-trans-isomerase, alpha/beta-lycopene cyclase, beta-carotene hydroxylase). PSY needs to be supplemented and the need for the CrtI transgene in Golden Rice is presumably due to insufficient activity of the phytoene desaturase and/or zeta-carotene desaturase enzyme in endosperm. The effect of CRTI expression was also investigated in leaves of transgenic rice and Arabidopsis (Arabidopsis thaliana). Here, again, the mRNA levels of intrinsic carotenogenic enzymes remained unaffected; nevertheless, the carotenoid pattern changed, showing a decrease in lutein, while the beta-carotene-derived xanthophylls increased. This shift correlated with CRTI-expression and is most likely governed at the enzyme level by lycopene-cis-trans-isomerism. Possible implications are discussed.     

Maize phytoene desaturase and zeta-carotene desaturase catalyse a poly-Z desaturation pathway: implications for genetic engineering of carotenoid content among cereal crops

Carotene desaturation, an essential step in the biosynthesis of coloured carotenoids, has received much attention (1) as a target of bleaching herbicide action, (2) as a determinant of geometric isomer states of carotenoids and their metabolites, and (3) as a key modulator of accumulation and structural variability of carotenoids. Having previously isolated and functionally characterized the cDNA encoding the first enzyme in maize carotene desaturation, phytoene desaturase (PDS), the isolation and functional characterization of the second desaturase, a maize endosperm cDNA (2265 bp) encoding zetacarotene (zeta-carotene) desaturase (ZDS) is reported here. Functional analysis of the concerted actions of maize PDS and ZDS ex situ showed these enzymes to mediate a poly-Z desaturation pathway to the predominate geometric isomer 7,9,7',9'-tetra-Z-lycopene (poly-Z-lycopene or prolycopene), and not the all-trans substrate required of the downstream lycopene cyclase enzymes. This finding suggests a rate-controlling isomerase associated with the carotene desaturases as a corollary of a default poly-Z carotenoid biosynthetic pathway active in planta for maize. Comparative gene analysis between maize and rice revealed that genes encoding PDS and ZDS are single copy; the Zds cDNA characterized here was mapped to maize chromosome 7S and vp9 is suggested as a candidate locus for the structural gene while y9 is ruled out. Classical genetic resources were used to dissect the desaturation steps further and hydroxyphenylpyruvate dioxygenase was linked to the vp2 locus, narrowing candidate loci for an obligate isomerase in maize to only a few. Since the first functional analysis of the paired carotene desaturases for a cereal crop is reported here, the implications for the genetic modification of the pro-vitamin A content in cereal crops such as rice and maize, are discussed.     

Expression and functional analysis of a gene cluster involved in the synthesis of decaprenoxanthin reveals the mechanisms for C50 carotenoid formation.

Corynebacterium glutamicum accumulates the C50 carotenoid decaprenoxanthin. Rescued DNA from transposon color mutants of this Gram-positive bacterium was used to clone the carotenoid biosynthetic gene cluster. By sequence comparison and functional complementation, the genes involved in the synthesis of carotenoids with 50 carbon atoms were identified. The genes crtE, encoding a geranylgeranyl pyrophosphate synthase, crtB, encoding a phytoene synthase, and crtI, encoding a phytoene desaturase, are responsible for the formation of lycopene. The products of three novel genes, crtYe and crtYf, with sequence similarities to heterodimeric lycopene cyclase crtYc and crtYd, together with crtEb which exhibits a prenyl transferase motif, were involved in the conversion of C40 acyclic lycopene to cyclic C50 carotenoids. Using functional complementation in Escherichia coli, it could be shown that the elongation of lycopene to the acyclic C50 carotenoid flavuxanthin by the addition of C5 isoprenoid units at positions C-2 and C-2' is catalyzed by the crtEb gene product. Subsequently, the gene products of crtYe and crtYf in a concerted action convert the acyclic flavuxanthin into the cyclic C50 carotene, decaprenoxanthin, forming two epsilon-ionone groups. The mechanisms, involving two individual steps for the formation of cyclic C50 carotenoids from lycopene, are proposed on the basis of these results.