Induced point mutations in the phytoene synthase 1 gene cause differences in carotenoid content during tomato fruit ripening

In tomato, carotenoids are important with regard to major breeding traits such as fruit colour and human health. The enzyme phytoene synthase (PSY1) directs metabolic flux towards carotenoid synthesis. Through TILLING (Targeting Induced Local Lesions IN Genomes), we have identified two point mutations in the Psy1 gene. The first mutation is a knockout allele (W180*) and the second mutation leads to an amino acid substitution (P192L). Plants carrying the Psy1 knockout allele show fruit with a yellow flesh colour similar to the r, r mutant, with no further change in colour during ripening. In the line with P192L substitution, fruit remain yellow until 3 days post-breaker and eventually turn red. Metabolite profiling verified the absence of carotenoids in the W180* line and thereby confirms that PSY1 is the only enzyme introducing substrate into the carotenoid pathway in ripening fruit. More subtle effects on carotenoid accumulation were observed in the P192L line with a delay in lycopene and β-carotene accumulation clearly linked to a very slow synthesis of phytoene. The observation of lutein degradation with ripening in both lines showed that lutein and its precursors are still synthesised in ripening fruit. Gene expression analysis of key genes involved in carotenoid biosynthesis revealed that expression levels of genes in the pathway are not feedback-regulated by low levels or absence of carotenoid compounds. Furthermore, protein secondary structure modelling indicated that the P192L mutation affects PSY1 activity through misfolding, leading to the low phytoene accumulation.     

Production of phytoene, a carotenoid, and induction of connexin 26 in transgenic mice carrying the phytoene synthase gene crtB

Carotenoids have been recognized as chemopreventive agents against human diseases, such as cancer and cardiovascular disease. Mammalians utilize carotenoids supplied from their food since they are unable to perform the de novo synthesis of carotenoids. We previously created mammalian cultured cells producing phytoene, a type of carotenoid, and showed that these cells acquired resistance against oxidative stress and oncogenic transformation. In the present study, we established a transgenic mouse line, carrying the crtB gene encoding phytoene synthase, which could produce phytoene endogenously. It was found that connexin 26 was induced in these phytoene-producing mice. Since it is known that carotenoids enhance gap junctional communication by inducing the expression of connexin genes, the present data suggest that the induction of connexin 26 in phytoene-producing mice may play a role in controlling cell-to-cell communication. Phytoene-producing mice provide a useful system in which to investigate the in vivo function of the carotenoid phytoene.     

Regulation and activation of phytoene synthase, a key enzyme in carotenoid biosynthesis, during photomorphogenesis

 During photomorphogenesis in higher plants, a coordinated increase occurs in the chlorophyll and carotenoid contents. The carotenoid level is under phytochrome control, as reflected by the light regulation of the mRNA level of phytoene synthase (PSY), the first enzyme in the carotenoid biosynthetic pathway. We investigated PSY protein levels, enzymatic activity and topological localization during photomorphogenesis. The results revealed that PSY protein levels and enzymatic activity increase during de-etiolation and that the enzyme is localized at thylakoid membranes in mature chloroplasts. However, under certain light conditions (e.g., far-red light) the increases in PSY mRNA and protein levels are not accompanied by an increase in enzymatic activity. Under those conditions, PSY is localized in the prolamellar body fraction in a mostly enzymatically inactive form. Subsequent illumination of dark-grown and/or in far-red light grown seedlings with white light causes the decay of these structures and a topological relocalization of PSY to developing thylakoids which results in its enzymatic activation. This light-dependent mechanism of enzymatic activation of PSY in carotenoid biosynthesis shares common features with the regulation of the NADPH:protochlorophyllide oxidoreductase, the first light-regulated enzyme in chlorophyll biosynthesis. The mechanism of regulation described here may contribute to ensuring a spatially and temporally coordinated increase in both carotenoid and chlorophyll contents. Received: 14 February 2000 / Accepted: 15 March 2000     

Profiles of gene family members related to carotenoid accumulation in citrus genus

Citrus fruit are an important reservoir of carotenoids. Numerous studies have been carried out to identify and profile the members of gene families involved in carotenoid biosynthetic pathway to explain the diversity of coloration in citrus fruit. It was found that gene expression analysis could not always explain the changes in carotenoid content and composition, indicating that other unknown genes and mechanisms should be operative. This review summarizes and updates the current knowledge on gene families involved in the citrus carotenoid biosynthetic pathway and their roles on the regulation of carotenoid biosynthesis, as well as provides insightful questions leading to future experimentation.     

Expression of phytoene synthase gene (Psy) is enhanced during fruit ripening of Cara Cara navel orange (Citrus sinensis Osbeck)

Citrus is an important fruit crop as regards accumulation of carotenoids. In plant carotenoid biosynthesis, phytoene synthase gene (Psy) plays a key role in catalyzing the head-to-head condensation of geranylgeranyl diphosphate molecules to produce colorless phytoene. In the present paper, we reported the phytoene contents determination and characterization of Psy during fruit ripening of “Washington” navel orange and its red-fleshed mutant “Cara Cara”. Results showed that phytoene was exclusively accumulated in peel and pulp of “Cara Cara”. Although phytoene was observed accumulating with fruit ripening of “Cara Cara”, the contents in pulp were 10 times higher than those in peel. The isolated two Psy cDNAs were both 1520 bp in full length, containing 436 deduced amino acid residues, with a different amino acid at 412th. Genomic hybridization results showed that one or two copies might be present in “Cara Cara” and “Washington” genomes. During “Cara Cara” and “Washington” fruit coloration, expression of Psy was observed to be up-regulated, as revealed by tissue specific profiles in the flavedo, albedo, segment membrane and juice sacs. However, Psy expression in albedo of “Cara Cara” was higher than that in “Washington”, as evidenced by phytoene accumulation in the peel.     

The effect of reduced activity of phytoene synthase on isoprenoid levels in tomato pericarp during fruit development and ripening

Carotenoids, gibberellins (GAs), sterols, abscisic acid and -amyrins were analysed in tomato (Lycopersicon esculentum Mill.) pericarp during fruit development and ripening. The contents of these isoprenoids in wild-type (cv. Ailsa Craig) fruit were compared with those in fruit of the carotenoid-deficient R-mutant and a transgenic plant containing antisense RNA to a phytoene synthase gene. In both carotenoid-deficient genotypes, a 14-fold reduction in carotene and twofold decrease in xanthophyll content, compared to the wild type, was found in ripe fruit. Immature green fruit from wild type and R-mutant plants contained similar amounts of the C₁₉-GAs, GA₁, and GA₂₀, and their C₂₀ precursor, GA₁₉. Immature fruit from the transgenic plants contained three- to fivefold higher contents of these GAs. In wild-type fruit at the mature green stage the contents of these GAs had decreased to < 10% of the levels in immature fruit. A similar decrease in GA₁₉ content occurred in the other genotypes. However, the contents of GA₁ and GA₂₀ in fruit from phytoene synthase antisense plants decreased only to 30% between the immature and mature green stages and did not decrease at all in R-mutant fruit. At the breaker and ripe stages, the contents of each GA were much reduced for all genotypes. The amount of abscisic acid was the same in immature fruit from all three genotypes, but, on ripening, the levels of this hormone in antisense and R-mutant fruit were ca. 50% of those in the wild type. Quantitative differences in the amounts of the triterpenoid -amyrins, total sterols, as well as individual sterols, such as campesterol, stigmasterol and sitosterol, were apparent between all three genotypes during development. Amounts of free sterols of wild type and antisense fruit were greatest during development and decreased during ripening, whereas the opposite was found in the R-mutant. This genotype also possessed less free sterol and more bound sterol in comparison to the other varieties. These data provide experimental evidence to support the concept of an integrated metabolic relationship amongst the isoprenoids.Abbreviations ABA abscisic acid - dpb days post breaker - FDP farnesyl diphosphate - GA gibberellin - GGDP geranyl-geranyl diphosphate We thank Mr. Paul Gaskin (Long Ashton Research Station) for the qualitative GC-MS of triterpenoids and Dr. R. Horgan (University of Wales, Aberystwyth) for a gift of [6-³H₂]ABA. The work was supported by a research grant (No. PG111/617) to P.M.B. from the Agricultural and Food Research Council to whom we express our thanks.     

The role of carotenoid cleavage dioxygenases in the regulation of carotenoid profiles during maturation in citrus fruit

To investigate the relationship between a carotenoid profile and gene expression for carotenoid cleavage dioxygenases, three citrus varieties that exhibit different 9-cis-violaxanthin levels in their juice sacs, Satsuma mandarin (Citrus unshiu Marc.; a variety accumulating a low level of 9-cis-violaxanthin), Valencia orange (Citrus sinensis Osbeck; variety accumulating a high level of 9-cis-violaxanthin), and Lisbon lemon (Citrus limon Burm.f.; a variety accumulating an undetectable level of 9-cis-violaxanthin) were used. Three cDNAs (CitCCD1, CitNCED2, and CitNCED3) were cloned. The recombinant CitCCD1 protein cleaved beta-cryptoxanthin, zeaxanthin, and all-trans-violaxanthin at the 9-10 and 9'-10' positions and 9-cis-violaxanthin at the 9'-10' position. The recombinant CitNCED2 and CitNCED3 proteins cleaved 9-cis-violaxanthin at the 11-12 position to form xanthoxin, a precursor of abscisic acid (ABA). The gene expression of CitCCD1 increased in the flavedos and juice sacs of the three varieties during maturation. In Satsuma mandarin, the gene expression of CitNCED2 and CitNCED3 increased noticeably, accompanying a massive accumulation of ABA in the flavedo and juice sacs. In Valencia orange, the gene expression of CitNCED3 increased with a slight elevation of the ABA level in the flavedo, whereas neither the gene expression of CitNCED2 nor the ABA level increased noticeably in the juice sacs. In Lisbon lemon, the gene expression of CitNCED2 increased remarkably, accompanying increases in the ABA level in the flavedo and juice sacs. These results suggest that, in the juice sacs, the efficient cleavage reaction for ABA synthesis reduces the 9-cis-violaxanthin level in Satsuma mandarin and Lisbon lemon, whereas the low cleavage reaction maintains the predominant 9-cis-violaxanthin accumulation in Valencia orange.     

Molecular cloning of a homologue of dad-1 gene in citrus: distinctive expression during fruit development

A cDNA homologue to the human defender against apoptotic death gene (dad-1), which is involved in programmed cell death, was isolated from satsuma mandarin (Citrus unshiu Marc.) fruit. It (Citdad-1-1) was 345 bp long, with a deduced protein sequence of 115 amino acids. Southern hybridization suggests that dad-1-related sequences are present as a small gene family in the citrus genome. Expression of Citdad-1-1 was progressively down-regulated in leaves as they matured, but not in juice sac/segment epidermis (edible part) towards fruit ripening. The role of dad-1 during citrus development is also discussed.