Complementation between mutants of Phycomyces deficient with respect to carotenogenesis

Summary White and red mutants of Phycomyces, derived from two independent wild types (yellow) by mutagenesis using nitrosoguanidine, either in a single step (26 white, 5 red mutants), or in two steps (10 white mutants, from one of the red mutants) were studied with respect to complementation in heterokaryons. The tests clearly establish the involvement of three and only three genes, here named carA, carB, and carB. The carA and the carR mutants are white, the carA mutants do not accumulate phytoene, the carB mutants do. The carR mutants are red and accumulate lycopene. The two step mutants are either carA and carR, or carB and carR double mutants. A few of the white mutants obtained in a single mutagenization step are affected in carA and carR. They may be polar mutants in an operon or accidental double mutants.     

Clustering and co-ordinated activation of carotenoid genes in Myxococcus xanthus by blue light

Blue light activates carotenoid production in the non-photosynthetic, Gram-negative bacterium Myxococcus xanthus. Light is known to stimulate the expression of two unlinked genes for carotenoid synthesis, carB and carC, through a mechanism in which the regulatory genes carA, carQ and carR take part. Genes carQ and carR are linked together at a separate locus, whereas carA is linked to carB. We have introduced Tn5 at various sites between carA and carB. Chemical analyses of the mutant strains demonstrate the presence in this region of a cluster of genes for carotenoid synthesis. Gene expression analysis strongly argues for most (or all) of the genes in the cluster being transcribed from a single, light-inducible promoter under the control of genes carA, carQ and carR.     

In vitro carotenogenesis by wild type and mutants of Phycomyces blakesleeanus

Cell extracts from shake cultures of the wild type and six mutant strains of Phycomyces converted [2-¹⁴C] MVA into carotenes, squalene and prenyl phosphates. Oxygen was required for the desaturation of phytoene. When compared with the wild type, cells extracts of carB and carR mutants are much less effective in phytoene dehydrogenation and lycopene cyclization, respectively. This confirms previous conclusions about the biochemical functions of the carB and carR genes, which were based on genetic and in vivo studies. CarA strain mutants accumulate, in vivo, much less β-carotene than the wild type. This correlates with a 10-fold decrease in carotenogenesis in vitro. The addition of retinol to incubations of cell extracts of the wild type and C2 strains stimulated β-carotene formation. Both carB and carR mutants show enhanced total carotenogenic activities in vitro and the carS mutant shows a higher β-carotene-synthesizing activity than the wild type. It is suggested that the feed-back regulatory mechanism known to control this pathway operates at the level of enzyme synthesis.     

Light-induced carotenogenesis in Myxococcus xanthus: light-dependent membrane sequestration of ECF sigma factor CarQ by anti-sigma factor CarR

Light-induced carotenogenesis in Myxococcus xanthus is under the control of the carQRS operon. CarQ, a proposed extracytoplasmic (ECF) RNA polymerase sigma factor, is required for expression of the operon and the carC gene that encodes phytoene dehydrogenase. CarR, an inner membrane protein in Escherichia coli, is essential for carQRS promoter inactivation in the dark. CarS is required for the light-dependent expression of the promoter of the carB gene cluster that encodes the rest of the structural genes for carotenogenesis. Regulation of carQRS is dependent on the stoichiometry of CarQ and CarR. Increasing the copy number of carQ over carR led to constitutive carotenogenesis, as did loss of translational coupling between carQ and carR. The severity of the constitutive phenotype depended on the distance between the uncoupled genes. When expressed in M. xanthus, a CarR:β-galactosidase fusion protein disappeared in the light. We propose that anti-sigma factor CarR sequesters CarQ to the membrane in the dark, but, in the light, loss of CarR leads to release of the sigma factor.     

Carotenoid Mutants of Mucor circinelloides

The wild-type of the filamentous fungus Mucor circinelloides accumulates the yellow pigment β-carotene. At a continuous blue-light fluence rate of 0.1 W/m² the β-carotene content increases about eight fold over the dark controls. Among the mutants isolated after exposure of spores to either N-methyl-N'-nitro-N-nitrosoguanidine or ICR-170, a red mutant accumulating lycopene, white mutants accumulating phytoene and white mutants without carotenoids were found. The biosynthesis of carotenoids in M. circinelloides shows similarities with that of the fungus Phycomyces blakesleeanus such as the presence of mutants in the same structural genes and the induction by light of the pathway. However, negative end-product regulation by β-carotene on the biosynthetic pathway, as in Phycomyces, is absent in M. circinelloides. In contrast to Phycomyces carB and carR mutants, carotenoids in corresponding mutants of M. circinelloides are photoinduced.     

Photocarotenogenesis in Phycomyces: Expression of the carB Gene Encoding Phytoene Dehydrogenase

Phycomyces blakesleeanus the biosynthesis of β-carotene is under the control of blue light. The light-controlled expression of the carB gene encoding phytoene dehydrogenase was investigated with slot blot and Northern analyses. After irradiation of mycelia with short pulses of blue light the amount of carB mRNA was stimulated transiently in the subsequent dark period. Depending on the energy fluence of the light pulse the mRNA increased about 3 to 5-fold after a latency of 2-5 min. Twenty minutes after the irradiation the amount of carB mRNA decreased again and reached, after 60 min, the dark level it had prior to the irradiation. A Northern analysis showed that the carB mRNA is unstable. After irradiation the full-length mRNA (2.2 kb) as well as degraded carB mRNA increased. The degradation was specific for the carB gene, because no degradation was observed for 25S rRNA or the mRNA of the pyrG gene. The rapid turnover as well as the degradation of the carB mRNA provide for an adaptive light control and appear to represent an essential feature of the regulation of the carotene pathway. Received 11 April 2000/ Accepted in revised form 30 November 2000     

Functional analysis of the Phycomyces carRA gene encoding the enzymes phytoene synthase and lycopene cyclase

Phycomyces carRA gene encodes a protein with two domains. Domain R is characterized by red carR mutants that accumulate lycopene. Domain A is characterized by white carA mutants that do not accumulate significant amounts of carotenoids. The carRA-encoded protein was identified as the lycopene cyclase and phytoene synthase enzyme by sequence homology with other proteins. However, no direct data showing the function of this protein have been reported so far. Different Mucor circinelloides mutants altered at the phytoene synthase, the lycopene cyclase or both activities were transformed with the Phycomyces carRA gene. Fully transcribed carRA mRNA molecules were detected by Northern assays in the transformants and the correct processing of the carRA messenger was verified by RT-PCR. These results showed that Phycomyces carRA gene was correctly expressed in Mucor. Carotenoids analysis in these transformants showed the presence of ß-carotene, absent in the untransformed strains, providing functional evidence that the Phycomyces carRA gene complements the M. circinelloides mutations. Co-transformation of the carRA cDNA in E. coli with different combinations of the carotenoid structural genes from Erwinia uredovora was also performed. Newly formed carotenoids were accumulated showing that the Phycomyces CarRA protein does contain lycopene cyclase and phytoene synthase activities. The heterologous expression of the carRA gene and the functional complementation of the mentioned activities are not very efficient in E. coli. However, the simultaneous presence of both carRA and carB gene products from Phycomyces increases the efficiency of these enzymes, presumably due to an interaction mechanism.     

Photoinduced accumulation of carotene in Phycomyces

Blue light stimulates the accumulation of beta-carotene (photocarotenogenesis) in the fungus Phycomyces blakesleeanus. To be effective, light must be given during a defined period of development, which immediately precedes the cessation of mycelial growth and the depletion of the glucose supply. The competence periods for photocarotenogenesis and photomorphogenesis in Phycomyces are the same when they are tested in the same mycelium. Photocarotenogenesis exhibits a two-step dependence on exposure, as if it resulted from the additon of two separate components with different thresholds and amplitudes. The low-exposure component produces a small beta-carotene accumulation, in comparison with that of dark-grown mycelia. The high-exposure component has a threshold of about 100 J· m^–2 blue light and produces a large beta-carotene accumulation, which is not saturated at 2·10⁶ J·m^–2. Exposure-response curves were obtained at 12 wavelengths from 347 to 567 nm. The action spectra of the two components share general similarities with one another and with those of other Phycomyces photoresponses. The small, but significant differences in the action spectra of the two components imply that the respective photosystems are not identical. Light stimulates the carotene pathway in the carB mutants, which contain the colourless precursor phytoene, but not beta-carotene. Carotenogenesis is not photoinducible in carA mutants, independently of their carotene content. This and other observations on various car mutants indicate that light prevents the normal inhibition of the pathway by the carA and carS gene products. The chromophore(s) for photocarotenogenesis are presumably flavins, and not carotenes.We thank Dr. A. Palit, C. Chmielewicz and D. Durant (same address as E.D.L.) and L.M. Corrochano, A. Fernández Estefane, and J. Córdoba López (same address as E.R.B.) for their help. This work was supported by grants from Comisión Asesora para Investigación Científica y Técnica and Comisión Interministerial para Ciencia y Tecnología to E.C.O.; from the National Institutes of Health and the National Science Foundation to E.D.L.; and from the U.S.-Spain Joint Committee for Scientific and Technological Cooperation to E.C.O. and E.D.L.     

ζ-Carotene and other carotenes in a Phycomyces mutant

Strain S442, a new mutant of the fungus Phycomyces blakesleeanus, has a greenish colour and a distinct green fluorescence under long-UV light. Carotene analyses reveal the presence of phytoene, ζ-carotene, phytofluene, an unidentified compound, and neurosporene (in descending order of abundance). Genetic analysis shows that the new mutation occurs at gene carB, whose protein product catalyses the four dehydrogenations of phytoene to lycopene via phytofluene, ζ-carotene, and neurosporene. S442 offers no indication of a specific ζ-carotene dehydrogenase. The residual dehydrogenase activity in S442 is inhibited by diphenylamine. The high ζ-carotene content makes S442 a good source of this compound.     

White mutants of Chlamydomonas reinhardtii are defective in phytoene synthase

Carotenoids play an integral and essential role in photosynthesis and photoprotection in plants and algae. A collection of Chlamydomonas reinhardtii mutants lacking carotenoids was characterized for pigment and tocopherol (vitamin E) composition, growth phenotypes under different light conditions, and the molecular basis of their mutant phenotype. The carotenoid-less mutants, or "white" mutants, were also deficient in chlorophylls but had approximately twice the tocopherol content of the wild type. White mutants grew in the dark but were unable to survive in the light, even under very low light conditions on acetate-containing medium. Genetic crosses and recombination tests revealed that all individual white mutants in the collection are alleles of a single gene, lts1, and the white phenotype was closely linked to a marker located in the phytoene synthase gene. DNA sequencing of the phytoene synthase gene from each of the mutants revealed nonsense, missense, frameshift, and splice site mutations. Transformation with a wild-type copy of the phytoene synthase gene was able to complement the lts1-210 mutation. Together, these results show that all the white mutants examined in this work are affected in the phytoene synthase gene.     

Excess carotenoids disturb prospective cell-to-cell recognition system in mating responses ofPhycomyces blakesleeanus

Carotenogenic mutants ofPhycomyces, which accumulate excess β-carotene or its intermediates, always failed in zygospore development. No improvement occurred when such mutants were mated together with a helper wild type of the same mating type against the wild type of the opposite mating type. Addition of excess synthesized pheromone, trisporin B, also failed to improve the zygospore development, though the mating response was significantly activated in the early stages and abundant zygophores were formed. Exceptional acceleration of the zygospore development under these experimental conditions occurred in a regulatory albino mutant (carA), which does not accumulate excess intermediate carotenoids. Chemically- or genetically-induced ovarproduction of β-carotene or lycopene also inhibited the zygospore development. These results imply that the zygospore development ofPhycomyces is maximal when the intracellular amount of β-carotene is optimal (=wild type), and that pheromones act mainly in the early stages of mating, while other factors such as the cell-to-cell recognition system may also be involved in the later stages. Intracellular accumulation of excess β-carotene or its intermediates probably disturb such later-stage factors.     

Maize w3 disrupts homogentisate solanesyl transferase (ZmHst) and reveals a plastoquinone‐9 independent path for phytoene desaturation and tocopherol accumulation in kernels

Maize white seedling 3 (w3) has been used to study carotenoid deficiency for almost 100 years, although the molecular basis of the mutation has remained unknown. Here we show that the w3 phenotype is caused by disruption of the maize gene for homogentisate solanesyl transferase (HST), which catalyzes the first and committed step in plastoquinone‐9 (PQ‐9) biosynthesis in the plastid. The resulting PQ‐9 deficiency prohibits photosynthetic electron transfer and eliminates PQ‐9 as an oxidant in the enzymatic desaturation of phytoene during carotenoid synthesis. As a result, light‐grown w3 seedlings are albino, deficient in colored carotenoids and accumulate high levels of phytoene. However, despite the absence of PQ‐9 for phytoene desaturation, dark‐grown w3 seedlings can produce abscisic acid (ABA) and homozygous w3 kernels accumulate sufficient carotenoids to generate ABA needed for seed maturation. The presence of ABA and low levels of carotenoids in w3 nulls indicates that phytoene desaturase is able to use an alternate oxidant cofactor, albeit less efficiently than PQ‐9. The observation that tocopherols and tocotrienols are modestly affected in w3 embryos and unaffected in w3 endosperm indicates that, unlike leaves, grain tissues deficient in PQ‐9 are not subject to severe photo‐oxidative stress. In addition to identifying the molecular basis for the maize w3 mutant, we: (1) show that low levels of phytoene desaturation can occur in w3 seedlings in the absence of PQ‐9; and (2) demonstrate that PQ‐9 and carotenoids are not required for vitamin E accumulation.     

Light-dependent switch from formation of poly-cis carotenes to all-trans carotenoids in the Scenedesmus mutant C-6D

The Scenedesmus obliquus mutant C-6D forms untypical poly-cis carotenes and lacks cyclic carotenoids when grown heterotrophically in the dark. After transfer to light, a very fast formation of usual all-trans carotenoids is observed leading to a phenotype very similar to the wild-type. Carotene analysis and quantitative kinetics of carotenoid changes after illumination in the presence of inhibitors which inhibit the three enzymes involved in carotene conversion showed isomerization of poly-cis carotenes, especially pro--carotene, to all-trans isomers. This result and consequently photoisomerization of pro--carotene in solution demonstrated that photoisomerization is the light-dependent mechanism leading to all-trans carotenoids in illuminated cultures. Now the different phenotypes of Scenedesmus C-6D can be explained by a single mutation of phytoene desaturase when photoisomerization of poly-cis carotenes is considered.Non-common abbreviations CPTA 2-(4-chlorophenylthio)-triethylamine HCL     

beta-Carotene accumulation induced by the cauliflower Or gene is not due to an increased capacity of biosynthesis

The cauliflower (Brassica oleracea L. var. botrytis) Or gene is a rare carotenoid gene mutation that confers a high level of beta-carotene accumulation in various tissues of the plant, turning them orange. To investigate the biochemical basis of Or-induced carotenogenesis, we examined the carotenoid biosynthesis by evaluating phytoene accumulation in the presence of norflurazon, an effective inhibitor of phytoene desaturase. Calli were generated from young seedlings of wild type and Or mutant plants. While the calli derived from wild type seedlings showed a pale green color, the calli derived from Or seedlings exhibited intense orange color, showing the Or mutant phenotype. Concomitantly, the Or calli accumulated significantly more carotenoids than the wild type controls. Upon treatment with norflurazon, both the wild type and Or calli synthesized significant amounts of phytoene. The phytoene accumulated at comparable levels and no major differences in carotenogenic gene expression were observed between the wild type and Or calli. These results suggest that Or-induced beta-carotene accumulation does not result from an increased capacity of carotenoid biosynthesis.     

High-Level Production of the Industrial Product Lycopene by the Photosynthetic Bacterium Rhodospirillum rubrum

The biosynthesis of the major carotenoid spirilloxanthin by the purple nonsulfur bacterium Rhodospirillum rubrum is thought to occur via a linear pathway proceeding through phytoene and, later, lycopene as intermediates. This assumption is based solely on early chemical evidence (B. H. Davies, Biochem. J. 116:93–99, 1970). In most purple bacteria, the desaturation of phytoene, catalyzed by the enzyme phytoene desaturase (CrtI), leads to neurosporene, involving only three dehydrogenation steps and not four as in the case of lycopene. We show here that the chromosomal insertion of a kanamycin resistance cassette into the crtC-crtD region of the partial carotenoid gene cluster, whose gene products are responsible for the downstream processing of lycopene, leads to the accumulation of the latter as the major carotenoid. We provide spectroscopic and biochemical evidence that in vivo, lycopene is incorporated into the light-harvesting complex 1 as efficiently as the methoxylated carotenoids spirilloxanthin (in the wild type) and 3,4,3′,4′-tetrahydrospirilloxanthin (in a crtD mutant), both under semiaerobic, chemoheterotrophic, and photosynthetic, anaerobic conditions. Quantitative growth experiments conducted in dark, semiaerobic conditions, using a growth medium for high cell density and high intracellular membrane levels, which are suitable for the conventional industrial production in the absence of light, yielded lycopene at up to 2 mg/g (dry weight) of cells or up to 15 mg/liter of culture. These values are comparable to those of many previously described Escherichia coli strains engineered for lycopene production. This study provides the first genetic proof that the R. rubrum CrtI produces lycopene exclusively as an end product.     

Are carotenoids the blue-light photoreceptor in the photoinduction of protoperithecia in Neurospora crassa?

A triple albino mutant of Neurospora crassa with a measured content of carotenoids absorbing at 470 nm less than 0.5% of that of the wild type (calculated value less than 8·10^-4%) had the same threshold for photoinduction of protoperithecia as the wild type when illuminated with monochromatic light at 471 nm. This is strong evidence against the hypothesis that the bulk of carotenoids are the blue-light photoreceptor for this phenomenon. However, it is impossible to exclude traces of carotenoids acting as the photoreceptor at less than 3·10^-12 M in a very efficient sensory transduction chain.Abbreviations A absorbance - al albino mutant - WT wild type