Enhancement of carotenoid synthesis by fungal metabolites

Carotenoids, mainly the all-trans--carotene, may be produced by the fungus Phycomyces blakesleeanus under normal fermentation conditions. A number of chemical compounds that stimulate or inhibit fungal carotenogenesis have been reported earlier. A procedure for the screening of organisms that enhance carotenogenesis on co-culturing with P. blakesleeanus is described. A water-soluble stimulator of carotenogenesis was obtained from the fermentation broth of an unidentified Aspergillus sp. isolated from soil. The crude preparation appears to be ten times more potent than dimethylphthalate.     

INHIBITION OF ASTAXANTHIN SYNTHESIS UNDER HIGH IRRADIANCE DOES NOT ABOLISH TRIACYLGLYCEROL ACCUMULATION IN THE GREEN ALGA HAEMATOCOCCUS PLUVIALIS (CHLOROPHYCEAE)1

Under stress conditions, Haematococcus pluvialis Flotow accumulates fatty acid–esterified astaxanthin, in extraplastidial lipid globules. The enhanced accumulation of fatty acids, mainly in triacylglycerols (TAG), among which oleic acid predominates, is linearly correlated with that of astaxanthin. We used inhibitors of either carotenoid or lipid biosynthesis to assess the interrelationship between carotenogenesis and TAG accumulation under high light irradiance as the stress factor. The two carotenogenesis inhibitors used—norflurazon, an inhibitor of phytoene desaturase, and diphenylamine (DPA), an inhibitor of β‐carotene C‐4 oxygenase—suppressed the accumulation of astaxanthin in a concentration‐dependent manner. Concurrently, the accumulation of neutral lipids was significantly less affected. The lipid biosynthesis inhibitor sethoxydim, which inhibits acetyl‐CoA carboxylase, significantly decreased de novo fatty acid synthesis and, in concert, drastically inhibited astaxanthin formation. In the presence of various concentrations of the three inhibitors, the inhibition of astaxanthin was not accompanied by a proportional decrease in oleic acid, which was used as a marker for TAG fatty acids. When astaxanthin synthesis was completely inhibited, the volumetric content of oleic acid was about 60% of the control value when the two carotenogenesis inhibitors (0.05 μM norflurazon or 20 μM DPA) were used and 27% of the control when the lipid‐synthesis inhibitor (50 μM) was used. We suggest therefore that TAG accumulation under high irradiance is not tightly coupled with astaxanthin accumulation, although the correlation between these two processes was demonstrated earlier. Furthermore, we propose that the accumulation of a certain amount of TAG is a prerequisite for the initiation of fatty acid–esterified astaxanthin accumulation in lipid globules.     

Regulation of carotene synthesis in Phycomyces

Summary Threeindependent mutations of Phycomyces blakesleeanus resulting in overaccumulation of -carotene are recessive and belong to the same complementation group. The corresponding gene has been named carS. Evidence is presented that gene carS is not the same as gene carA, previously defined by mutations blocking carotene production. Vitamin A increases carotenogenesis in wild types and in carS mutants to about the same extent. Intersexual heterokaryosis increases carotenogenesis most prominently in carS genetic backgrounds (up to 300 times the production of the wild type in the same conditions). Vitamin A, intersexual heterokaryosis and carS mutations are thought to stimulate carotenogenesis through different mechanisms. It is suggested that the carS gene product participates in end-product regulation of the pathway.     

Coenzyme B12-dependent and independent photoregulation of carotenogenesis across Myxococcales

Light-induced carotenogenesis in Myxococcus xanthus is controlled by the B₁₂-based CarH repressor and photoreceptor, and by a separate intricate pathway involving singlet oxygen, the B₁₂-independent CarH paralogue CarA and various other proteins, some eukaryotic-like. Whether other myxobacteria conserve these pathways and undergo photoregulated carotenogenesis is unknown. Here, comparative analyses across 27 Myxococcales genomes identified carotenogenic genes, albeit arranged differently, with carH often in their genomic vicinity, in all three Myxococcales suborders. However, CarA and its associated factors were found exclusively in suborder Cystobacterineae, with carA-carH invariably in tandem in a syntenic carotenogenic operon, except for Cystobacter/Melittangium, which lack CarA but retain all other factors. We experimentally show B₁₂-mediated photoregulated carotenogenesis in representative myxobacteria, and a remarkably plastic CarH operator design and DNA binding across Myxococcales. Unlike the two characterized CarH from other phyla, which are tetrameric, Cystobacter CarH (the first myxobacterial homologue amenable to analysis in vitro) is a dimer that combines direct CarH-like B₁₂-based photoregulation with CarA-like DNA binding and inhibition by an antirepressor. This study provides new molecular insights into B₁₂-dependent photoreceptors. It further establishes the B₁₂-dependent pathway for photoregulated carotenogenesis as broadly prevalent across myxobacteria and its evolution, exclusively in one suborder, into a parallel complex B₁₂-independent circuit.     

Hyper-accumulation of astaxanthin in a green algaHaematococcus pluvialis at elevated temperatures

Summary When a green algaHaematococcus pluvialis was cultivated at 30°C, astaxanthin production was 3-fold more increased than at 20°C. With acetate supplementation to 30°C culture, the alga synthesized over 2-fold more carotenoid than without addition. Tiron, a radical scavenger, however, severely blocked the stimulated carotenogenesis, suggesting that endogenously generated active oxygen was responsible for the highly stimulated carotenogenesis. From these results, possible roles of the elevated cultivation temperatures for hyperaccumulation of astaxanthin were discussed.     

Improved growth of the red yeast, Phaffia rhodozyma (Xanthophyllomyces dendrorhous), in the presence of tricarboxylic acid cycle intermediates

Catabolites related to tricarboxylic acid cycle affected growth and carotenogenesis in Phaffia rhodozyma. Glutamate, glutamine, aspartate, asparagine and proline at 75 mM of N increased biomass from 2 g l^–1 to 2.9–4.7 g l^–1 but decreased carotenoid from 420 g g^–1 yeast to 200–260 g g^–1 yeast in strain 67-385. However, simple nitrogen sources did not decrease carotenoid formation. Tricarboxylic acid intermediates repressed carotenogenesis to a less degree than the corresponding amino acids. Carotenoid hyper-producing mutants were impaired in nitrogen utilization. These results indicated that nitrogen assimilation and the concentrations of tricarboxylic acid cycle intermediates are involved in regulation of carotenoid biosynthesis.     

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.     

GRAVITROPISM IN ABSCISIC-ACID DEFICIENT SEEDLINGS OF ZEA MAYS

We did not detect any abscisic acid (ABA) in roots or leaves of carotenoid-deficient mutants of Zea mays. Similarly, we did not detect any ABA in roots or leaves of seedlings treated with Fluridone (an inhibitor of carotenogenesis) even after subjecting them to polyethylene glycol (PEG)-induced moisture stress. Primary roots of untreated, Fluridone-treated, and mutant seedlings were strongly graviresponsive. These results suggest that 1) ABA is not necessary for positive gravitropism by primary roots of these cultivars of Z. mays, and 2) ABA is synthesized via the carotenoid pathway.     

Unique Carotenoids in the Terrestrial Cyanobacterium <Emphasis Type="Italic">Nostoc commune</Emphasis> NIES-24: 2-Hydroxymyxol 2′-Fucoside,Nostoxanthin and Canthaxanthin

Cyanobacteria produce some carotenoids. We identified the molecular structures, including the stereochemistry, of all the carotenoids in the terrestrial cyanobacterium, Nostoc commune NIES-24 (IAM M-13). The major carotenoid was β-carotene. Its hydroxyl derivatives were (3R)-β-cryptoxanthin, (3R,3′R)-zeaxanthin, (2R,3R,3′R)-caloxanthin, and (2R,3R,2′R,3′R)-nostoxanthin, and its keto derivatives were echinenone and canthaxanthin. The unique myxol glycosides were (3R,2′S)-myxol 2′-fucoside and (2R,3R,2′S)-2-hydroxymyxol 2′-fucoside. This is only the second species found to contain 2-hydroxymyxol. We propose possible carotenogenesis pathways based on our identification of the carotenoids: the hydroxyl pathway produced nostoxanthin via zeaxanthin from β-carotene, the keto pathway produced canthaxanthin from β-carotene, and the myxol pathway produced 2-hydroxymyxol 2′-fucoside via myxol 2′-fucoside. This cyanobacterium was found to contain many kinds of carotenoids and also displayed many carotenogenesis pathways, while other cyanobacteria lack some carotenoids and a part of carotenogenesis pathways compared with this cyanobacterium.     

A review of factors affecting biosynthesis of carotenoids by the order Mucorales

This is a review of factors affecting carotenogenesis by the order Mucorales which includes Phycomyces blakesleeanus, Choanephora cucurbitarum and Blakeslea trispora. The Mucorales have opposite sex types and when mated, -carotene production is increased 15 to 20 times. Trisporic acids are the substances produced upon mating which stimulate carotenogenesis. Structural analogs have been shown to mimic the actions of the trisporic acids. The common denominator of the stimulators is the ionone ring and the hydrocarbon side chain. Secondary metabolism is discussed as well as the use of food byproducts to stimulate, specifically, the production of -carotene by B. trispora.     

Mechanism of Photoregulated Carotenogenesis in Rhodotorula minuta III. Effect of Certain Nucleic Acid and Protein Inhibitors on Photoinduction of Carotenoid Biosynthesis

Inhibitors of protein and nucleic acid synthesis such as puromycin,cycloheximide, 5-fluorodeoxyuridine and 5-fluorouracil havebeen used to study the dark reactions involved in photoregulationof carotenogenesis in Rhodotorula minuta. The results indicatedthat as already reported in other organisms, carotenogenic enzymesare synthesized first and, in turn, synthesize carotenoids inthe dark. Synthesis of the carotenogenic enzymes was absolutelydependent on oxygen and came to an end within 6 hr at 26?C underaerobic conditions. Photoregulation of this synthesis may occurat the translational level. 5-Fluorodeoxyuridine and 5-fluorouracilacted as chemical inducers of carotenogenesis in Rh. minutagrown in the dark. However, the site of the action of thesechemicals was assumed to be different from that of light, becausethe chemical and light effects on the induction of carotenogenesiswere additive. (Received September 16, 1981; Accepted March 3, 1982)     

Astaxanthin biosynthesis enhanced by reactive oxygen species in the green algaHaematococcus pluvialis

The unicellular green algaHaematococcus pluvialis has recently attracted great interest due to its large amounts of ketocarotenoid astaxanthin, 3,3′-dihydroxy-β,β-carotene-4,4′-dione, widely used commercially as a source of pigment for aquaculture. In the life cycle ofH. pluvialis, astaxanthin biosynthesis is associated with a remarkable morphological change from green motile vegetative cells into red immotile cyst cells as the resting stage. In recent years we have studied this morphological process from two aspects: defining conditions governing astaxanthin biosynthesis and questioning the possible function of astaxanthin in protecting algal cells against environmental stress. Astaxanthin accumulation in cysts was induced by a variety of environmental conditions of oxidative stress caused by reactive oxygen species, intense light, drought, high salinity, and high temperature. In the adaptation to stress, abscisic acid induced by reactive oxygen species, would function as a hormone in algal morphogenesis from vegetative to cyst cells. Furthermore, measurements of bothin vitro andin vivo antioxidative activities of astaxanthin clearly demonstrated that tolerance to excessive reactive oxygen species is greater in astaxanthin-rich cysts than in astaxanthin-poor cysts or astaxanthin-less vegetative genesis and carotenogenesis, and the accumulated astaxanthin in cysts can function as a protective agent against oxidative stress damage. In this study, the physiological roles of astaxanthin in stress response and cell protection are reviewed.     

Proteomic and metabolomic analysis of the carotenogenic yeast Xanthophyllomyces dendrorhous using different carbon sources

Background

Astaxanthin is a potent antioxidant with increasing biotechnological interest. In Xanthophyllomyces dendrorhous, a natural source of this pigment, carotenogenesis is a complex process regulated through several mechanisms, including the carbon source. X. dendrorhous produces more astaxanthin when grown on a non-fermentable carbon source, while decreased astaxanthin production is observed in the presence of high glucose concentrations. In the present study, we used a comparative proteomic and metabolomic analysis to characterize the yeast response when cultured in minimal medium supplemented with glucose (fermentable) or succinate (non-fermentable).

Results

A total of 329 proteins were identified from the proteomic profiles, and most of these proteins were associated with carotenogenesis, lipid and carbohydrate metabolism, and redox and stress responses. The metabolite profiles revealed 92 metabolites primarily associated with glycolysis, the tricarboxylic acid cycle, amino acids, organic acids, sugars and phosphates. We determined the abundance of proteins and metabolites of the central pathways of yeast metabolism and examined the influence of these molecules on carotenogenesis.Similar to previous proteomic-stress response studies, we observed modulation of abundance from several redox, stress response, carbohydrate and lipid enzymes. Additionally, the accumulation of trehalose, absence of key ROS response enzymes, an increased abundance of the metabolites of the pentose phosphate pathway and tricarboxylic acid cycle suggested an association between the accumulation of astaxanthin and oxidative stress in the yeast. Moreover, we observed the increased abundance of late carotenogenesis enzymes during astaxanthin accumulation under succinate growth conditions.

Conclusions

The use of succinate as a carbon source in X. dendrorhous cultures increases the availability of acetyl-CoA for the astaxanthin production compared with glucose, likely reflecting the positive regulation of metabolic enzymes of the tricarboxylic acid and glyoxylate cycles. The high metabolite level generated in this pathway could increase the cellular respiration rate, producing reactive oxygen species, which induces carotenogenesis.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1484-6) contains supplementary material, which is available to authorized users.     

New mode of Dunaliella biotechnology: two-phase growth for β-carotene production

Attempts to adapt the laboratory experience of bi-phasic growth and carotenogenesis in Dunaliella to large-scale conditions were highly successful. Algae were initially cultivated in stage one for optimizing biomass production of cells containing a low β-carotene to chlorophyll ratio. The culture was then transferred to stage two, diluted to about one third and induced for carotenogenesis. The bi-phase cultivation increased β- carotene productivity to 450 mg m^-2 d^-1 in stage one and to 300 mg m^-2 d^-1 in stage two, compared to the relatively low productivity of below 200 mg β- carotene m^-2 d^-1, in the conventional one phase type of cultivation. The results indicate that a selected algal product can be promoted specifically by growth manipulation of the alga and its environment.     

Zinc and Fatty Acids in Depression

Polyunsaturated Fatty acids (PUFAs) seem to be helpful in the therapy of depression. Zinc (Zn) may be one co-factor contributing to their antidepressive effect. Zn acts lipid protective and is a constituent of fatty acid metabolism enzymes. In animals, an antidepressive effect of Zn was already demonstrated. Therefore, if and how Zn and PUFAs correlate in depressive patients or in individuals from the general population was investigated. Blood samples were collected from 88 depressive in-patients and 88 volunteers from the general population matched for age-group and gender (each 32 men and 56 women, 21–70 years) for measurement of Zn (colorimetric) and of 12 fatty acids (FAs) (by capillary gas-chromatography). Severity of depression in patients was assessed by Beck Depression Inventory (BDI) and Hamilton Depression Rating Scale (HDRS). Zn concentration was independent of age, gender and body-mass-index and significantly correlated with the severity of depression measured by BDI (r = 0.26; P = 0.034) in depressive patients,. HDRS was inversely correlated with gammalinolenic acid concentration (r = −0.24; P = 0.029). Median serum Zn concentration in depressive patients did not differ from control individuals. Zn was correlated with myristic acid concentration (r = 0.22; P < 0.05) in controls from the general population; and a negative correlation between Zn and dihomogammalinolenic acid concentration (r = −0.26; P < 0.05) was found in depressive inpatients. FA composition in serum significantly differed between depressive and healthy persons: Depressive patients had higher stearic and arachidonic acid (AA) concentration. Relative to AA, their eicosapentaenoic and docosapentaenoic acid concentration were diminished compared to the general populations group. These results do not confirm the hypothesis of a general lack of Zn in depressive disorders, but Zn concentrations differed dependent on comorbid disorders and severity of depression. In depressive patients and control persons Zn concentration is associated with different FAs indicating diverging metabolic pathways.