ISOLATION AND CHARACTERIZATION OF THE PHYTOENE DESATURASE GENE AS A POTENTIAL SELECTIVE MARKER FOR GENETIC ENGINEERING OF THE ASTAXANTHIN‐PRODUCING GREEN ALGA CHLORELLA ZOFINGIENSIS (CHLOROPHYTA)1

Phytoene desaturase (PDS) is a rate‐limiting enzyme in carotenoid biosynthesis. Algal PDS is inhibited by some herbicides, leading to the bleaching of the cells due to destruction of chl. Specific point mutations in PDS confer resistance to the herbicide norflurazon, suggesting that mutated PDS could be used as a dominant selectable marker for genetic engineering of algae, for which very few selective markers are available. In this study, we report the isolation and characterization of the PDS gene from the astaxanthin‐producing green alga Chlorella zofingiensis Dönz. The open reading frame (ORF) of this PDS gene, interrupted by six introns, encoded a polypeptide of 558 amino acid residues. The deduced protein sequence showed significant homology to phytoene desaturases of algae, cyanobacteria, and higher plants. Expression of the PDS gene in Escherichia coli demonstrated that the enzyme was able to convert phytoene to ζ‐carotene. The PDS gene in Chlorella was shown to be up‐regulated by high light and glucose treatment. With a single amino acid change (L516R), the mutated PDS‐L516R was still active and exhibited ～36‐fold greater resistance to the bleaching herbicide norflurazon than the unaltered enzyme. Thus, the modified PDS gene could be a useful tool for genetic engineering of carotenoid biosynthesis in C. zofingiensis and perhaps also in other algae.     

Abstracts of papers read at the Winter Meeting, 1962

The effect of a range of inhibitors on the carotenoid biosynthetic pathway of the microalga Haematococcus pluvialis has been studied during normal growth and during the induction of astaxanthin synthesis. Diflufenican and norflurazon had similar effects and resulted in the almost complete inhibition of secondary carotenoid synthesis together with a build up of the acyclic carotenoid precursor, phytoene. In contrast, the inhibitor CPTA blocked cyclisation of lycopene and was seen to act differentially on the β- and ?-cyclases. Both diphenylamine and 1-aminobenzotriazole had the effect of blocking the synthesis of astaxanthin and the other secondary carotenoids by preventing the introduction of oxygen functions. As a direct result treated cells accumulated large levels of β-carotene instead. Selective use of inhibitors of carotenogenesis demonstrated that the accumulated lycopene and β-carotene could act as a precursor for astaxanthin synthesis.     

The molecular basis of resistance to the herbicide norflurazon

We have cloned and sequenced a gene, pds, from the cyanobacterium Synechococcus PCC7942 that is responsible for resistance to the bleaching herbicide norflurazon. A point mutation in that gene, leading to an amino acid substitution from valine to glycine in its polypeptide product, was found to confer this resistance. Previous studies with herbicide-resistant mutants have indicated that this gene encodes phytoene desaturase (PDS), a key enzyme in the biosynthesis of carotenoids. A short amino acid sequence that is homologous to conserved motifs in the binding sites for NAD(H) and NADP(H) was identified in PDS, suggesting the involvement of these dinucleotides as cofactors in phytoene desaturation.     

Intragenic Enhancers and Suppressors of Phytoene Desaturase Mutations in Chlamydomonas reinhardtii

Photosynthetic organisms synthesize carotenoids for harvesting light energy, photoprotection, and maintaining the structure and function of photosynthetic membranes. A light-sensitive, phytoene-accumulating mutant, pds1-1, was isolated in Chlamydomonas reinhardtii and found to be genetically linked to the phytoene desaturase (PDS) gene. PDS catalyzes the second step in carotenoid biosynthesis-the conversion of phytoene to ζ-carotene. Decreased accumulation of downstream colored carotenoids suggested that the pds1-1 mutant is leaky for PDS activity. A screen for enhancers of the pds1-1 mutation yielded the pds1-2 allele, which completely lacks PDS activity. A second independent null mutant (pds1-3) was identified using DNA insertional mutagenesis. Both null mutants accumulate only phytoene and no other carotenoids. All three phytoene-accumulating mutants exhibited slower growth rates and reduced plating efficiency compared to wild-type cells and white phytoene synthase mutants. Insight into amino acid residues important for PDS activity was obtained through the characterization of intragenic suppressors of pds1-2. The suppressor mutants fell into three classes: revertants of the pds1-1 point mutation, mutations that changed PDS amino acid residue Pro64 to Phe, and mutations that converted PDS residue Lys90 to Met. Characterization of pds1-2 intragenic suppressors coupled with computational structure prediction of PDS suggest that amino acids at positions 90 and 143 are in close contact in the active PDS enzyme and have important roles in its structural stability and/or activity.     

Engineering of an endogenous phytoene desaturase gene as a dominant selectable marker for Chlamydomonas reinhardtii transformation and enhanced biosynthesis of carotenoids

A phytoene desaturase (PDS) gene was cloned and characterized from the unicellular green microalga Chlamydomonas reinhardtii. Functional complementation analysis revealed C. reinhardtii PDS (CrPDS) catalyzes the conversion of phytoene to the colored carotenoid ζ-carotene. A single amino acid substitution, L505F, enhanced its desaturation activity by 29%, as indicated by an in vitro enzymatic assay. In addition, CrPDS-L505F exhibited 27.7-fold higher resistance to the herbicide norflurazon. Glass bead-mediated delivery displayed a high transformation efficiency of C. reinhardtii with CrPDS-L505F, demonstrating clearly that the engineered endogenous CrPDS is a dominant selectable marker for C. reinhardtii and possibly for other green algae. Furthermore, the expression of PDS could enhance the intracellular carotenoid accumulation of transformants, opening up the possibility of engineering the carotenogenic pathway for improved carotenoid production in microalgae.     

Cloning of phytoene desaturase and expression analysis of carotenogenic genes in persimmon (<Emphasis Type="Italic">Diospyros kaki</Emphasis> L.) fruits

Persimmon is a commercially important fruit crop, and the fruit is rich in different kinds of bioactive compounds, among which carotenoids contribute significantly to its color and nutritional value. In this study, the cDNA of phytoene desaturase gene (PDS) was isolated by rapid amplification of cDNA ends (RACE) technique. Sequence analysis indicated that the full-length cDNA of PDS was 2064 bp, encoding 586 amino acids and containing one open reading frame (ORF) of 1761 bp. Homology analysis showed that DkPDS, which had been submitted in GenBank with accession number GU112527, shared high similarities of 80–86% with PDS cloned from other plants. Prediction of deduced proteins showed that there was no signal peptide and transmembrane topological structure in DkPDS. It was a hydrophilic and stable protein, and located in chloroplast. To examine the specific expression patterns of carotenogenic genes we had cloned from persimmon, including phytoene synthase (DkPSY), DkPDS, ζ-carotene desaturase (DkZDS), lycopene β-cyclase (DkLCYB) and β-carotene hydroxylase (DkBCH), real-time quantitative PCR (Q-PCR) was performed in flesh at five different developmental stages. The results revealed that the expression levels of DkPSY, DkPDS and DkZDS gradually increased. Nevertheless, the expression level of DkLCYB was very low and maintained relatively stable. The expression level of DkBCH was also at a low level from stage 1 to 4, and then reached the maximum at stage 5. In addition, the expression level of DkZDS was higher than that of other genes. Carotenoid detection demonstrated that both β-cryptoxanthin and total carotenoids increased with fruit development, and zeaxanthin had little change, but with a sudden increase in final stage.     

Astaxanthin production in transgenicArabidopsis with chyB gene encoding β;-carotene Hydroxylase

Oxycarotenoids, produced through the oxidation of carotenoids, play critical roles in plants. This reaction is mediated by a specific enzyme, β;-carotene hydroxylase, which adds hydroxyl groups to the β;-rings of carotenes. To investigate the effect of the β;-carotene hydroxylase gene (Chyb) on oxycarotenoid biosynthesis, we generated transgenicArabidopsis plants that over-expressedChyb under the control of a 35S promoter. Their levels of zeaxanthin and neoxanthin were two- to three-fold greater relative to the WT, while that of violaxanthin, a final product in the xanlthophyll pathway, was 1.3-fold higher than the control. In contrast, the amount of β;-carotene declined as much as 2.4-fold, depending on the particular transgenic line. Interestingly, astaxanthin was produced in the transgenics, but not in the WT. These data suggest that, with the aid of unknown factors in the host, carotenoids could be converted into metabolites in the astaxanthin biosynthetic pathway. Microarray analysis was used lo identify several genes that were consistently up-or down-regulated in transgenic chyB leaves compared with the controls. Here, we also discuss possible modifications in leaf carotenoids, and the importance of these data from a nutritional standpoint. These authors contributed equally to this work.     

MASSIVE ACCUMULATION OF PHYTOENE INDUCED BY NORFLURAZON IN DUNALIELLA BARDAWIL (CHLOROPHYCEAE) PREVENTS RECOVERY FROM PHOTOINHIBITION1

The effects of nanomolar to micromolar concentrations of the herbicide norflurazon were studied in Dunaliella bardawil Ben-Amotz et Avron, a β-carotene-accumulating halotolerant alga. The large amount of β-carotene which Dunaliella bardawil can contain, around 8% of the algal dry weight, is reduced to 0.2% by treatment with 100 nm norflurazon. Simultaneously, phytoene is accumulated to a similar level of about 8%. The gradual increase in phytoene content, in response to increasing norflurazon concentrations, corresponds to the decrease in β-carotene, with no evident change in other isoprenoid intermediates. Carotene-rich Dunaliella bardawil is substantially resistant to high-intensity photoinhibition. This resistance is lost in cells grown to contain low β-carotene and in the norflurazon-treated phytoene-rich cells. These observations are in agreement with the hypothesis that the accumulated β-carotene in Dunaliella bardawil protects the cells against injury by excessive irradiation.     

Genetic basis of microbial carotenogenesis

The synthesis of carotenoids begins with the formation of a phytoene from geranylgeranyl pyrophosphate, a well conserved step in all carotenogenic organisms and catalyzed by a phytoene synthase, an enzyme encoded by the crtB (spy) genes. The next step is the dehydrogenation of the phytoene, which is carried out by phytoene dehydrogenase. In organisms with oxygenic photosynthesis, this enzyme, which accomplishes two dehydrogenations, is encoded by the crtP genes. In organisms that lack oxygenic photosynthesis, dehydrogenation is carried out by an enzyme completely unrelated to the former one, which carries out four dehydrogenations and is encoded by the crtI genes. In organisms with oxygenic photosynthesis, dehydrogenation of the phytoene is accomplished by a ζ-carotene dehydrogenase encoded by the crtQ (zds) genes. In many carotenogenic organisms, the process is completed with the cyclization of lycopene. In organisms exhibiting oxygenic photosynthesis, this step is performed by a lycopene cyclase encoded by the crtL genes. In contrast, anoxygenic photosynthetic and non-photosynthetic organisms use a different lycopene cyclase, encoded by the crtY (lyc) genes. A third and unrelated type of lycopene β-cyclase has been described in certain bacteria and archaea. Fungi differ from the rest of non-photosynthetic organisms in that they have a bifunctional enzyme that displays both phytoene synthase and lycopene cyclase activity. Carotenoids can be modified by oxygen-containing functional groups, thus originating xanthophylls. Only two enzymes are necessary for the conversion of β-carotene into astaxanthin, using several ketocarotenoids as intermediates, in both prokaryotes and eukaryotes. These enzymes are a β-carotene hydroxylase (crtZ genes) and a β-carotene ketolase, encoded by the crtW (bacteria) or bkt (algae) genes. Electronic Publication     

Cloning of the astaxanthin synthase gene from Xanthophyllomyces dendrorhous (Phaffia rhodozyma) and its assignment as a β-carotene 3-hydroxylase/4-ketolase

A gene has been cloned from Xanthophyllomyces dendrorhous by complementation of astaxanthin formation in a β-carotene accumulating mutant. It consists of 3,166 bp and contains 17 introns. For the β-carotene mutant ATCC 96815, a single point mutation in the splicing sequence of intron 8 was found. The resulting improper splicing of the mRNA results in an inactive protein. The cDNA of this β-carotene oxygenase encodes a cytochrome P450 monooxygenase belonging to the 3A subfamily. P450-specific domains were identified including a cytochrome P450 and an oxygen binding motif. Electrons are provided by a cytochrome P450 reductase. Functional characterization of the enzyme by genetic modification of X. dendrorhous demonstrated that this P450 monooxygenase is multifunctional catalyzing all steps from β-carotene to astaxanthin formation by oxygenation of carbon 3 and 4. The reaction sequence is first 4-ketolation of β-carotene followed by 3-hydroxylation. A hydroxylation mechanism at allylic carbon atoms has been proposed for the generation of 4-keto and 3-hydroxy groups at both β-ionone ends.     

The biosynthetic pathway of carotenoids in the astaxanthin-producing green alga <Emphasis Type="Italic">Chlorella zofingiensis</Emphasis>

The carotenoid composition of the astaxanthin-producing green alga Chlorella zofingiensis was investigated using high-performance liquid chromatography. Astaxanthin, adonixanthin, and zeaxanthin are the major carotenoids in this alga. The pigment pattern was characterized during the accumulation period, and in response to diphenylamine (DPA), an inhibitor of carotenoid biosynthesis. An increase in zeaxanthin followed by a decrease in xanthophyll was seen after the induction of astaxanthin biosynthesis by glucose. This biphasic kinetics of zeaxanthin was parallel to the marked increase in adonixanthin (from 0 mg g⁻¹ to 0.21 mg g⁻¹) and astaxanthin (from 0.05 mg g⁻¹ to 0.35 mg g⁻¹) and decrease of β-carotene (from 0.30 mg g⁻¹ to 0.03 mg g⁻¹). More importantly, unlike the Haematococcus alga, in which there was a high β-carotene accumulation after DPA treatment, C. zofingiensis showed an accumulation of extra zeaxanthin instead of β-carotene after treatment of the cells with DPA. All these results observed in vivo studies corroborate the observations in vitro studies at the enzyme level that zeaxanthin is a substrate for the carotenoid oxygenase in C. zofingiensis. It is suggested that zeaxanthin might be an important intermediate and not an end product of the biosynthetic pathway of astaxanthin. Therefore, a new pathway for astaxanthin formation by C. zofingiensis, which is different from that of the other astaxanthin-producing microorganisms, is proposed. An understanding of the astaxanthin biosynthetic pathway may yield important information toward the optimization of astaxanthin production, especially for the improvement of astaxanthin through genetic manipulations.     

Production and optimization of carotenoid-enriched dried distiller’s grains with solubles by <Emphasis Type="Italic">Phaffia rhodozyma</Emphasis> and <Emphasis Type="Italic">Sporobolomyces roseus</Emphasis> fermentation of whole stillage

Whole stillage—a co-product of grain-based ethanol—is used as an animal feed in the form of dried distiller’s grain with solubles (DDGS). Since animals cannot synthesize carotenoids and animal feed is generally poor in carotenoids, about 30–120 ppm of total carotenoids are added to animal feed to improve animal health, enhance meat color and quality, and increase vitamin A levels in milk and meat. The main objective of this study was to produce carotenoid (astaxanthin and β-carotene)-enriched DDGS by submerged fermentation of whole stillage. Mono- and mixed cultures of red yeasts, Phaffia rhodozyma (ATCC 24202) and Sporobolomyces roseus (ATCC 28988), were used to produce astaxanthin and β-carotene. Media optimization was carried out in shake flasks using response surface methodology (RSM). Macro ingredients, namely whole stillage, corn steep liquor and glycerol, were fitted to a second-degree polynomial in RSM. Under optimized conditions, astaxanthin and β-carotene yields in mixed culture and P. rhodozyma monoculture were 5 and 278, 97, and 275 μg/g, respectively, while S. roseus produced 278 μg/g of β-carotene. Since the carotenoid yields are almost twice the quantity used in animal feed, the carotenoid-enriched DDGS has potential application as “value-added animal feed or feed blends.”     

Transformation of the Green Alga Haematococcus pluvialis with a Phytoene Desaturase for Accelerated Astaxanthin Biosynthesis

Astaxanthin is a high-value carotenoid which is used as a pigmentation source in fish aquaculture. Additionally, a beneficial role of astaxanthin as a food supplement for humans has been suggested. The unicellular alga Haematococcus pluvialis is a suitable biological source for astaxanthin production. In the context of the strong biotechnological relevance of H. pluvialis, we developed a genetic transformation protocol for metabolic engineering of this green alga. First, the gene coding for the carotenoid biosynthesis enzyme phytoene desaturase was isolated from H. pluvialis and modified by site-directed mutagenesis, changing the leucine codon at position 504 to an arginine codon. In an in vitro assay, the modified phytoene desaturase was still active in conversion of phytoene to ζ-carotene and exhibited 43-fold-higher resistance to the bleaching herbicide norflurazon. Upon biolistic transformation using the modified phytoene desaturase gene as a reporter and selection with norflurazon, integration into the nuclear genome of H. pluvialis and phytoene desaturase gene and protein expression were demonstrated by Southern, Northern, and Western blotting, respectively, in 11 transformants. Some of the transformants had a higher carotenoid content in the green state, which correlated with increased nonphotochemical quenching. This measurement of chlorophyll fluorescence can be used as a screening procedure for stable transformants. Stress induction of astaxanthin biosynthesis by high light showed that there was accelerated accumulation of astaxanthin in one of the transformants compared to the accumulation in the wild type. Our results strongly indicate that the modified phytoene desaturase gene is a useful tool for genetic engineering of carotenoid biosynthesis in H. pluvialis.