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     

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.     

Functional analysis of multiple carotenogenic genes from <Emphasis Type="Italic">Lycium barbarum</Emphasis> and <Emphasis Type="Italic">Gentiana lutea</Emphasis> L. for their effects on β-carotene production in transgenic tobacco

Carotenoids are red, yellow and orange pigments, which are widely distributed in nature and are especially abundant in yellow-orange fruits and vegetables and dark green leafy vegetables. Carotenoids are essential for photosynthesis and photoprotection in plant life and also have different beneficial effects in humans and animals (van den Berg et al. 2000). For example, β-carotene plays an essential role as the main dietary source of vitamin A. To obtain further insight into β-carotene biosynthesis in two important economic plant species, Lycium barbarum and Gentiana lutea L., and to investigate and prioritize potential genetic engineering targets in the pathway, the effects of five carotenogenic genes from these two species, encoding proteins including geranylgeranyl diphosphate synthase, phytoene synthase and δ-carotene desaturase gene, lycopene β-cyclase, lycopene ε-cyclase were functionally analyzed in transgenic tobacco (Nicotiana tabacum) plants. All transgenic tobacco plants constitutively expressing these genes showed enhanced β-carotene contents in their leaves and flowers to different extents. The addictive effects of co-ordinate expression of double transgenes have also been investigated.     

Construction of new <Emphasis Type="Italic">Pichia pastoris</Emphasis> X-33 strains for production of lycopene and β-carotene

In this study, we used the non-carotenogenic yeast Pichia pastoris X33 as a receptor for β-carotene-encoding genes, in order to obtain new recombinant strains capable of producing different carotenoidic compounds. We designed and constructed two plasmids, pGAPZA-EBI* and pGAPZA-EBI*L*, containing the genes encoding lycopene and β-carotene, respectively. Plasmid pGAPZA-EBI*, expresses three genes, crtE, crtB, and crtI*, that encode three carotenogenic enzymes, geranylgeranyl diphosphate synthase, phytoene synthase, and phytoene desaturase, respectively. The other plasmid, pGAPZA-EBI*L*, carried not only the three genes above mentioned, but also the crtL* gene, that encodes lycopene β-cyclase. The genes crtE, crtB, and crtI were obtained from Erwinia uredovora, whereas crtL* was cloned from Ficus carica (JF279547). The plasmids were integrated into P. pastoris genomic DNA, and the resulting clones Pp-EBI and Pp-EBIL were selected for either lycopene or β-carotene production and purification, respectively. Cells of these strains were investigated for their carotenoid contents in YPD media. These carotenoids produced by the recombinant P. pastoris clones were qualitatively and quantitatively analyzed by high-resolution liquid chromatography, coupled to photodiode array detector. These analyses confirmed that the recombinant P. pastoris clones indeed produced either lycopene or β-carotene, according to the integrated vector, and productions of 1.141 μg of lycopene and 339 μg of β-carotene per gram of cells (dry weight) were achieved. To the best of our knowledge, this is the first time that P. pastoris has been genetically manipulated to produce β-carotene, thus providing an alternative source for large-scale biosynthesis of carotenoids.     

The effect of veratrole on carotenoid biosynthesis by Phycomyces blakesleeanus

A number of chemical compounds are known to affect the biosynthetic pathways of β-carotene. Both site-specific inhibitors as well as general stimulators of carotenogenesis have been described. It has been reported that veratrole enhances β-carotene synthesis when applied to agar cultures of Phycomyces blakesleeanus but we found no significant stimulation of β-carotene production in submerged culture. Moreover, veratrole in high concentrations (> 0.1% w/v), unlike diphenylamine, inhibits the formation of phytoene, resulting in an almost total block of carotenoid biosynthesis.     

Transgenic rice (Oryza sativa) endosperm expressing daffodil (Narcissus pseudonarcissus) phytoene synthase accumulates phytoene, a key intermediate of provitamin A biosynthesis

Rice ( Oryza sativa L.), the major food staple for more than two billion people, contains neither β-carotene (provitamin A) nor C₄₀ carotenoid precursors thereof in its endosperm. To improve the nutritional value of rice, genetic engineering was chosen as a means to introduce the ability to make β-carotene into rice endosperm tissue. Investigation of the biochemical properties of immature rice endosperm using [¹⁴C]-labelled substrates revealed the presence of geranyl geranyl diphosphate, the C₂₀ general isoprenoid precursor necessary for C₄₀ carotenoid biosynthesis. Phytoene synthase, which condenses two molecules of geranyl geranyl diphosphate, is the first of four specific enzymes necessary for β-carotene biosynthesis in plants. Therefore, the Japonica rice model variety Taipei 309 was transformed by microprojectile bombardment with a cDNA coding for phytoene synthase from daffodil ( Narcissus pseudonarcissus ) under the control of either a constitutive or an endosperm-specific promoter. In transgenic rice plants, the daffodil enzyme is active, as measured by the in vivo accumulation of phytoene in rice endosperm. Thus, it is demonstrated for the first time that it is in principle possible to engineer a critical step in provitamin A biosynthesis in a non-photosynthetic, carotenoid-lacking plant tissue. These results have important implications for longterm prospects of overcoming worldwide vitamin A deficiency.     

Carotenes from Mutants of the Dinoflagellate, Crypthecodinium cohnii

SYNOPSIS.
The carotenoid compositions of 15 nitrosoguanidine-induced mutants of Crypthecodinium cohnii , a heterotrophic dinoflagellate, were determined by chromatographic and mass spectral analyses. Wild-type C. cohnii grown with irradiation of 250 W/cm² visible light at 27 C synthesizes β-carotene (33%) and γ-carotene (67%) amounting to 0.083 mg/g dry wt. There are 4 types of carotenoid-deficient mutants: (I) albinos which synthesize no C₄₀-carotonoids: (II) albinos blocked at the level of phytoene desaturation; (III) cream-colored cells which accumulate mainly §–carotene, with phytoene and/or β-zeacarotene also present; and (IV) light-orange strains which synthesize reduced amounts of β-carotene and γ-carotene.
Dark-grown wild-type cells produced 35% as much carotenoids as light-grown cells. Inhibition studies revealed that diphenylamine (3 γ) caused phytoene accumulation; nicotine at 0.9 mM blocked the final cyclization, to cause γ-carotene to accumulate in wild-type cells. Inhibition by adenine and guanine (1.5 mM) of carotenogenesis was demonstrated for the first time in any system. The effect of these purines was similar to that of diphenylamine addition: phytoene desaturation was largely inhibited.
The carotenogenic system in this dinoflagellate is similar to that of green algae and higher plants, and is under nuclear genetic control.     

Marker-free transgenic (MFT) near-isogenic introgression lines (NIILs) of 'golden' indica rice (cv. IR64) with accumulation of provitamin A in the endosperm tissue

We have developed near-isogenic introgression lines (NIILs) of an elite indica rice cultivar (IR64) with the genes for β-carotene biosynthesis from dihaploid (DH) derivatives of golden japonica rice (cv. T309). A careful analysis of the DH lines indicated the integration of the genes of interest [phytoene synthase ( psy ) and phytoene desaturase ( crtI )] and the selectable marker gene (hygromycin phosphotransferase, hph ) in two unlinked loci. During subsequent crossing, progenies could be obtained carrying only the locus with psy and crtI , which was segregated independently from the locus containing the hph gene during meiotic segregation. The NIILs (BC₂F₂) showed maximum similarity with the recurrent parent cultivar IR64. Further, progenies of two NIILs were devoid of any fragments beyond the left or right border, including the chloramphenicol acetyltransferase ( cat ) antibiotic resistance gene of the transformation vector. Spectrophotometric readings showed the accumulation of up to 1.06 µg total carotenoids, including β-carotene, in 1 g of the endosperm. The accumulation of β-carotene was also evident from the clearly visible yellow colour of the polished seeds.     

Structural diversity and functional novelty of new carotenoid biosynthesis genes

Many new carotenoid synthesis genes have recently been identified through genomic sequencing or functional cloning. Some of them exhibit novel structures and/or novel functions. This review describes such examples in the families of lycopene β-cyclases, putative homologues of phytoene dehydrogenases and new carotenoid hydroxylases. Both the functionally novel lycopene β-monocyclases and structurally novel fusion-type of lycopene β-cyclases were described. Another newly discovered sequence of lycopene β-cyclase described might represent a new class of lycopene β-cyclases previously not identified in several cyanobacteria. Three examples of putative homologues of phytoene dehydrogenases were described, however, they were confirmed to encode different and/or new functions such as β-carotene ketolase, 4,4′-diapolycopene oxygenase or prolycopene isomerase. Two new carotenoid hydroxylase genes were described that encoded the new function of 2,2′-β-ionone ring hydroxylase or 3,3′-isorenieratene hydroxylase. Phylogenetic analysis of these genes shed light on their possible evolutionary origins. These new genes also provide tools for synthesis of novel and desirable carotenoids by genetic engineering.     

Search for the function of the nuclease NucM of Erwinia chrysanthemi

Abstract A screening procedure for carotenoid genes involving heterologous complementation with two different plasmid constructs was developed. The plasmids contained the crtE and crtB genes from Erwinia unredovora together with the phytoene desaturase gene from either Rhodobacter capsulatus or Synechococcus PCC 7942. Transformation in E. coli led to the accumulation of neurosporene and ζ-carotene, respectively. Co-transformation with an Anabaena plasmid library resulted in the isolation of the two plasmids, pZDS1 and pZDS1. Their gene products showed the ability to convert neurosporene and ζ-carotene into lycopene. In contrast, accumulated phytoene could not be converted. We conclude that the cloned gene codes for the carotenoid biosynthesis gene ζ-carotene desaturase ( zds ).     

Functional expression of the Erwinia uredovora carotenoid biosynthesis gene crtl in transgenic plants showing an increase of β-carotene biosynthesis activity and resistance to the bleaching herbicide norflurazon

Among the enzymes involved in carotenoid biosynthesis, phytoene desaturase is considered to be a rate-limiting enzyme in this pathway and is also the target of many bleaching herbicides. This enzyme shows diversity concerning its function and amino acid homology among various organisms. The phytoene desaturase gene crtl of Erwinia uredovora was expressed, the 5'-region of which was fused to the sequence for the transit peptide of a pea Rubisco small subunit, in tobacco plants under the control of the CaMV 35S promoter. This chimeric gene product was targeted into chloroplasts and processed in the transgenic plants. The production and processing of the corresponding protein could be demonstrated by Western blotting. Immunogold localization showed that the location of the gene product Crtl was preferentially in the thylakoids. A radioactive labeling study using the leaves demonstrated enhanced activity for the synthesis of β-carotene. In addition, the transgenic tobacco acquired elevated resistance to the bleaching herbicide norflurazon.     

Functional assignment of Erwinia herbicola Eho10 carotenoid genes expressed in Escherichia coli

Erwinia herbicola is a nonphotosynthetic bacterium that is yellow pigmented due to the presence of carotenoids. When the Erwinia carotenoid biosynthetic genes are expressed in Escherichia coli, this bacterium also displays a yellow phenotype. The DNA sequence of the plasmid pPL376, carrying the entire Erwinia carotenoid gene cluster, has been found to contain 12 open reading frames (ORFs). Six of the ORFs have been identified as carotenoid biosynthesis genes that code for all the enzymes required for conversion of farnesyl pyrophosphate (FPP) to zeaxanthin diglucoside via geranylgeranyl pyrophosphate, phytoene, lycopene, -carotene, and zeaxanthin. These enzymatic steps were assigned after disruption of each ORF by a specific mutation and analysis of the accumulated intermediates. Carotenoid intermediates were identified by the absorption spectra of the colored components and by high pressure liquid chromatographic analysis. The six carotenoid genes are arranged in at least two operons. The gene coding for -carotene hydroxylase is transcribed in the opposite direction from that of the other carotenoid genes and overlaps with the gene for phytoene synthase.     

The solubilization of carotenogenic enzymes of Phycomyces blakesleeanus

The effect of nine ionic and nine non-ionic detergents, over a 0.3–3.0% (w/v) concentration range, on the activity of the enzymes which convert [2-¹⁴C]mevalonic acid into phytoene (7,8,11,12,7′,8′,11′,12′-ψ,ψ-carotene) and β-carotene (β,β-carotene) has been investigated with cell extracts of the C115 carS42 mad-107(?) (β-carotene-accumulating) strain of Phycomyces blakesleeanus. The enzymes catalyzing the conversion of mevalonic acid into phytoene in the C115 and the C5 carB10(?) (phytoene-accumulating) strains of Phycomyces could be released from membranes with high molarity Tris-HCl buffer, but the other carotenogenic enzymes required solubilization with detergents. Enzymic activity was retained with only two ionic detergents (Zwittergents 3–8 and 3–10), whilst Tweens 40 and 60 were the least inhibitory of the non-ionic surfactants. Both Tween 60 and Zwittergent 3–08 solubilized almost 50% of the enzymic activities for the conversion of phytoene to β-carotene, but the former preparation was significantly more stable on storage at ?70°C.     

Activation and analysis of crypticcrt genes for carotenoid biosynthesis fromStreptomyces griseus

Genes encoding enzymes with sequence similarity to carotenoid biosynthetic enzymes of other organisms were cloned fromStreptomyces griseus JA3933 and transformed into the colourless (non-daunorubicin producing) mutantStreptomyces griseus IMET JA3933/956/2. Cells harbouring these genes showed an orange-red pigmentation, caused by the strongly hydrophobic, membrane-bound lycopene. The cloned fragment (9 kb) contained seven genes, four transcribed in one direction (crtEIBV) and three (crtYTU) transcribed convergently to them. Three of these genes encode polypeptides that resemble geranylgeranyl-pyrophosphate (GGPP) synthases (CrtE), phytoene synthases (PS) (CrtB) and phytoene dehydrogenases (PDH) (CrtI), respectively, of various bacteria. These enzymes are sufficient for the formation of lycopene.crtE alone was sufficient to induce zeaxanthin formation in anEscherichia coli clone containing thecrt gene cluster fromErwinia herbicola deleted forcrtE. The combination ofcrtE andcrtB led to formation of phytoene inS. griseus. The putativecrtEp promoter region was cloned and mapped by primer extension analysis. In a gel retardation experiment, this fragment was specifically shifted by an unknown protein. CrtY shows similarity to lycopene cyclases that convert lycopene into-carotene, CrtT resembles various methyltransferases and CrtU a dehydrogenase. We conclude that these genes are functionally intact, but not expressed (cryptic) in the wild-typeS. griseus strain.     

The site of carotenogenic enzymes in chromoplasts from Narcissus pseudonarcissus L.

The membranes from the chromoplasts of Narcissus pseudonarcissus L. which are derived from the inner envelope membrane are the site of -carotene synthesis from [1-¹⁴C]isopentenyl diphosphate. The enzymes involved are partly peripheral membrane proteins (prenyltransferase, phytoene synthase) and partly integral membrane proteins (cis-trans isomerase, dehydrogenase(s), cyclase(s)). Metabolic channeling is suggested.Abbreviations IPP isopentenyl diphosphate - GGPP geranylgeranyl diphosphate     

Evolution of plant nucleotide-sugar interconversion enzymes

Nucleotide-diphospho-sugars (NDP-sugars) are the building blocks of diverse polysaccharides and glycoconjugates in all organisms. In plants, 11 families of NDP-sugar interconversion enzymes (NSEs) have been identified, each of which interconverts one NDP-sugar to another. While the functions of these enzyme families have been characterized in various plants, very little is known about their evolution and origin. Our phylogenetic analyses indicate that all the 11 plant NSE families are distantly related and most of them originated from different progenitor genes, which have already diverged in ancient prokaryotes. For instance, all NSE families are found in the lower land plant mosses and most of them are also found in aquatic algae, implicating that they have already evolved to be capable of synthesizing all the 11 different NDP-sugars. Particularly interesting is that the evolution of RHM (UDP-L-rhamnose synthase) manifests the fusion of genes of three enzymatic activities in early eukaryotes in a rather intriguing manner. The plant NRS/ER (nucleotide-rhamnose synthase/epimerase-reductase), on the other hand, evolved much later from the ancient plant RHMs through losing the N-terminal domain. Based on these findings, an evolutionary model is proposed to explain the origin and evolution of different NSE families. For instance, the UGlcAE (UDP-D-glucuronic acid 4-epimerase) family is suggested to have evolved from some chlamydial bacteria. Our data also show considerably higher sequence diversity among NSE-like genes in modern prokaryotes, consistent with the higher sugar diversity found in prokaryotes. All the NSE families are widely found in plants and algae containing carbohydrate-rich cell walls, while sporadically found in animals, fungi and other eukaryotes, which do not have or have cell walls with distinct compositions. Results of this study were shown to be highly useful for identifying unknown genes for further experimental characterization to determine their functions in the synthesis of diverse glycosylated molecules.