Effect of squalene on astaxanthin production by a mutant of Phaffia rhodozyma

The effect of different sesquiterpenes on carotenoid synthesis in Phaffia rhodozyma was studied. Addition of squalene to the culture medium resulted in a decrease in the echinenone and trans-astaxanthin concentrations, whereas -carotene remained unchanged. The role of squalene as an inhibitor of ketocarotenoid synthesis in Ph. rhodozyma is discussed.     

Astaxanthin production by a Phaffia rhodozyma mutant on grape juice

During fermenter cultivation of Phaffia rhodozyma on a grape juice medium, the presence of glucose initially delayed fructose utilization, although fructose was consumed before glucose depletion. Total pigment and astaxanthin production were growth associated and reached maximum values of 15.9 g/ml and 9.8 g/ml, respectively, after depletion of the carbon source. The total cellular pigment and astaxanthin content increased during the stationary growth phase due to a decrease in biomass, reaching final values of 2120 g/g and 1350 g/g, respectively, without the volumetric concentration in the culture changing. The final cell yield was 0.33 g/g sugar utilized. High sugar concentrations in shake-flasks as well as O₂ limitation decreased the astaxanthin content of the cells. Addition of yeast extract to a grape juice minimal medium markedly increased the maximum specific growth rate, total pigment and astaxanthin content of the cells. An excess of ammonia decreased the intracellular astaxanthin content, which reached a maximal value in cultures with no residual glucose or ammonia.The authors are with the Department of Microbiology and Biochemistry, University of the Orange Free State, P.O. Box 339, Bloemfontein 9300, South Africa;     

Batch cultivation and astaxanthin production by a mutant of the red yeast,Phaffia rhodozyma NCHU-FS501

Phaffia rhodozyma cells were treated with the mutagenic agent NTG several times and plated on yeast-malt agar containing -ionone as a selective medium. This mutagenesis of the yeast yielded a mutant (NCHU-FS501) with a total carotenoid content of 1454 g g^–1 dry biomass. Temperature and pH had only a slight effect on the volumetric pigment production by the red yeast, however astaxanthin yield and specific growth rate were influenced more significantly by temperature and pH. The optimum inoculum size, temperature and air flow rate for astaxanthin formation by the mutant in a bench-top fermentor were 7.5% (v/v), 22.5°C and 3.6 vvm, respectively. Glucose (1%, w/v) as carbon source yielded the highest volumetric astaxanthin production (6.72 g ml^–1). Peptone (15.8% total nitrogen) was the best nitrogen source for astaxanthin production (6.72 g ml^–1). Pigment formation by the mutant was further improved by increasing the glucose concentration to 3.5%, where the astaxanthin concentration was 16.33 m ml^–1. At 4.5% glucose or above astaxanthin formation was inhibited. Control of the pH of the fermentation broth did not improved pigment production.     

Ethanol increases carotenoid production in Phaffia rhodozyma

Addition of ethanol (0.2%) to cultures of the yeast Phaffia rhodozyma increased the specific rate of carotenoid production [(carotenoid)(cell mass)⁻¹(time)⁻¹]. The incremental increase in carotenoid synthesis with ethanol was highest in carotenoid-hyperproducing strains. Ethanol increased carotenoid production when it was added at various points during the lag and active growth phases. Ethanol increased alcohol dehydrogenase and hydroxy-methyl-glutaryl-CoA (HMG-CoA) reductase activities. Our results indicate that increased carotenoid production by ethanol is associated with induction of HMG-CoA reductase and possibly activation of oxidative metabolism. Received 24 December 1996/ Accepted in revised form 27 May 1997     

Influence of light on growth and pigmentation of the yeast Phaffia rhodozyma

Light and antimycin markedly affected growth and carotenoid synthesis by Phaffia rhodozyma. Exposure of the yeast to high light intensities on agar plates resulted in growth inhibition and decreased carotenoid synthesis. The carotenoid compositions of the yeast were also notably changed by light. -zeacarotene increased, whereas -carotene and xanthophylls decreased including astaxanthin, phoenicoxanthin, and 3-hydroxy-3, 4-didehydro-,-caroten-4-one (HDCO). In liquid medium, growth of the wild-type strain (UCD-FST-67-385) was inhibited by antimycin, but this inhibition was relieved by exposure to light. Light also stimulated carotenoid synthesis about twofold in these antimycin-treated cells. Light may have rescued growth by induction of an alternative oxidase system which facilitated electron disposal when the main respiratory chain was inhibited by antimycin. Isolation and characterization of the oxidase enzymes should be useful in strain development for increased carotenoid production.Abbreviations DCIP 2,6-dichlorophenol-indophenol - HDCO 3-hydroxy-3, 4-didehydro-,-caroten-4-one, PG-n-propyl gallate - SHAM salicylhydroxamic acid - TTFA thenoyltrifluoroacetone     

Biology of the red yeastXanthophyllomyces dendrorhous (Phaffia rhodozyma)

Phaffia rhodozyma is a red-pigmented basidiomycetous yeast that produces astaxanthin. Because of this property, it is fermented commercially on a large scale. Astaxanthin is used as a food colorant for fish, and as an antioxidant, it is potentially useful in the human pharmaceutical industry. This review summarizes the published biology of this yeast: its morphology and ultrastructure, organization of the cytoskeleton, and the nuclear and extrachromosomal genomes. Alteration of sexual and vegetative phases in the life cycle and its biotechnological importance are also described.     

响应面法对红法夫酵母合成虾青素主要影响因素的优化

在单因素试验确定了红法夫酵母生物合成虾青素培养基组份的基础上,用响应面法对其浓度进行优化。首先用分式析因设计评价了培养基的各组份对虾青素产量的影响,并找出主要影响因子为蔗糖和酵母粉,二者分别达到了极显著和显著水平。用最陡爬坡路径逼近最大响应区域后,运用旋转中心复合设计及响应面分析,确定了主要影响因子的最佳浓度。其中,蔗糖的最佳浓度为49.8g/L,酵母粉的浓度为9.6g/L。菌株在优化培养基中的虾青素产量为9861μg/L,比优化前增加了近1倍。     

Quantification of carotenoids in cells of Phaffia rhodozyma by autofluorescence

The distribution and intensity of autofluorescence caused by carotenoids in the yeast Phaffia rhodozyma was examined by laser confocal fluorescence microscopy. Carotenoid contents of individual yeast cells could be calculated from the value of autofluorescence/unit volume of yeast cell. The average level of fluorescence in highly fluorescing yeast cells was 15 mg carotenoid g^–1 yeast which was accepted as the maximum yield of carotenoid in P. rhodozyma. The method developed in this study is useful for the research of cell biology associated with the biological functions of carotenoids in individual cells.     

法夫酵母产虾青素的反复分批及反复分批补料发酵

以生物量和虾青素产量为指标,考察法夫酵母多批次半连续培养产虾青素的稳定性。实验结果显示,在摇瓶上分别以4 d和5 d为周期反复分批培养法夫酵母,虾青素产量呈现先增加再下降的趋势,但第2代至第7代虾青素产量仍高于第1代,并且4 d为周期的虾青素平均产量略高于5 d的。在5 L罐法夫酵母进行反复分批补料发酵中,不管是补加30％的葡萄糖还是补加30％的淀粉水解糖,第2个批次发酵的生物量和虾青素产量均达到第1个批次的水平,表明菌种稳定性较好。     

Increased astaxanthin production by a Phaffia rhodozyma mutant grown on date juice from Yucca fillifera

The wild strain and the astaxanthin-overproducing mutant strain 25–2 of Phaffia rhodozyma were analyzed in order to assess their ability to grow and synthesize astaxanthin in a minimal medium composed of g L⁻¹: KH₂PO₄ 2.0; MgSO₄ 0.5; CaCl₂ 0.1; urea 1.0 and supplemented with date juice of Yucca fillifera as a carbon source (yuca medium). The highest astaxanthin production (6170 μg L⁻¹) was obtained at 22.5 g L⁻¹ of reducing sugars. The addition of yeast extract to the yuca medium at concentrations of 0.5–3.0 g L⁻¹ inhibited astaxanthin synthesis. The yuca medium supported a higher production of astaxanthin, 2.5-fold more than that observed in the YM medium. Journal of Industrial Microbiology & Biotechnology (2000) 24, 187–190. Received 14 July 1999/ Accepted in revised form 02 December 1999     

Carbon-source assimilation pattern of the astaxanthin-producing yeast Phaffia rhodozyma

Eleven Phaffia rhodozyma strains were assayed for their ability to utilize 99 compounds as single carbon source. Some of them showed modified coloration compared to colonies of the same strain grown on glucose medium.     

Improvement of astaxanthin production by a newly isolated Phaffia rhodozyma mutant with low-energy ion beam implantation

Aims: Isolation, characterization and identification of Phaffia sp. ZJB 00010, and improvement of astaxanthin production with low‐energy ion beam implantation. Methods and Results: A strain of ZJB 00010, capable of producing astaxanthin, was isolated and identified as Phaffia rhodozyma, based on its physiological and biochemical characteristics as well as its internal transcribed spacer (ITS) rDNA gene sequence analysis. With low‐energy ion beam implantation, this wild‐type strain was bred for improving the yield of astaxanthin. After ion beam implantation, the best mutant, E5042, was obtained. The production of astaxanthin in E5042 was 2512 μg g^?1 (dry cell weight, DCW), while the wild‐type strain was about 1114 μg g^?1 (DCW), an increase of 125·5%. Moreover, the fermentation conditions of mutant E5042 for producing astaxanthin were optimized. The astaxanthin production under the optimized conditions was upscaled and studied in a 50‐l fermentor. Conclusions: A genetically stable mutant strain with high yield of astaxanthin was obtained using low‐energy ion beam implantation. This mutant may be a suitable candidate for the industrial‐scale production of astaxanthin. Significance and Impact of the Study: Astaxanthin production in Phaffia rhodozyma could be fficiently improved by low‐energy ion beam implantation, which is a new technology in the mutant breeding of micro‐organisms. The mutant obtained in this work could potentially be utilized in industrial production of astaxanthin.     

Growth kinetics and astaxanthin production of Phaffia rhodozyma on glycerol as a carbon source during batch fermentation

Glycerol was studied as a substrate for astaxanthin by Phaffia rhodozyma PR 190. With co-utilisation of yeast extract and peptone, the maximum specific growth rate was 0.24 ± 0.02 h–1. Astaxanthin percentage in total pigment is constant (0.78 mg/g) and its yield from glycerol is always 0.97 mg/g. The yield of biomass from glycerol alone is 0.50 ± 0.02 g/g. The specific rate of astaxanthin production versus the cell growth rate reached a maximum for an optimal specific growth rate of 0.075 h–1. For this optimal value, the maximum specific astaxanthin production rate is 0.09 ± 0.01 mg/g.h. The best astaxanthin results were : 33.7 mg/l, 0.2 mg/l.h and 1.8 mg/g yeast after a fermentation term of 168 hours. Our results suggest a strategy of astaxanthin production in fed batch culture or chemostat at a growth rate of 0.075 h–1. © Rapid Science Ltd. 1998     

Growth and carotenoid production by pH-stat cultures of Phaffia rhodozyma

To optimize biomass and carotenoid production by Phaffia rhodozyma in pH-stat cultures, two methods of feeding glucose were studied. In the first method, which is comparatively simple to operate, the glucose feeding set point (pH 5.02) was higher than the culture pH (5.00) and P. rhodozyma grew at a low specific growth rate (=0.055 h^–1). In the second method, the glucose feeding set point (pH 4.98) was lower than the culture pH (5.00) and the yeast grew at a specific growth rate of =0.095 h^–1. With the second method of glucose feeding, which is more complex and in order to prevent overfeeding of glucose, a time interval was added to the control strategy of the glucose pump and allowed to expire before the next dose of glucose was added. The length of the time interval affected biomass and carotenoid production. A critical time interval (T_c) was defined. In pH-stat cultures of P. rhodozyma, it was found that if the time interval was set longer than the critical time interval, the yeast did not grow.     

Selection and evaluation of astaxanthin-overproducing mutants of Phaffia rhodozyma

Mutagenesis of Phaffia rhodozyma with NTG yielded a mutant with an astaxanthin content of 1688 g (g dry biomass)^-1, a cell yield coefficient of 0.47 on glucose and a maximum specific growth rate of 0.12 h^-1. Re-mutation of the mutant decreased the cell yield and maximum specific growth rate but increased the astaxanthin content. The use of mannitol or succinate as carbon sources enhanced pigmentation, yielding astaxanthin contents of 1973 g g^-1 and 1926 g g^-1, respectively. The use of valine as sole nitrogen source also increased astaxanthin production, but severely decreased the maximum specific growth rate and cell yield coefficient. The optimum pH for growth of P. rhodozyma was between pH 4.5 and 5.5, whereas the astaxanthin content remained constant above pH 3.     

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.     

On-line monitoring of Phaffia rhodozyma fed-batch process with in situ dispersive Raman spectroscopy

Since the yeast Phaffia rhodozyma was first described some 35 years ago, there has been significant interest in the development of commercial processes to exploit its ability to produce carotenoids (approximately 80% astaxanthin). However, the optimal conditions for carotenoid production are not well understood. A key limitation has been the lack of an appropriate sensor for on-line carotenoid quantification. In this study, an in situ Raman spectroscopy probe was used to monitor intracellular carotenoid production for three consecutive P. rhodozyma fed-batch experiments. Raman spectroscopy is particularly well suited to the study of carotenoids due to a resonance effect, which greatly enhances the intensity of the three fundamental carotenoid bands, nu(1) (1513 cm(-1), C(-) (-)C stretch), nu(2) (1154 cm(-1), C-C stretch), and nu(3) (1003 cm(-1), CH(3) rock). For all three cultures, the peak height of these bands was linearly correlated with intracellular carotenoid content (1 to 45 mg/L) to a precision of better than 5%, and the correlation from one experiment was directly applicable to others.     

Carotenoids protectPhaffia rhodozyma against singlet oxygen damage

Summary The only known habitat of the astaxanthin-containingPhaffia rhodozyma is in slime fluxes of deciduous trees at high altitudes. In this habitat, the function of carotenoids inP. rhodozyma is probably to provide protection against photogenerated antifungal substances in the tree flux such as singlet oxygen (¹O₂). To investigate the role of carotenoids inP. rhodozyma, genetic selections were employed to determine if carotenogenic yeast strains ofP. rhodozyma have enhanced ability to quench¹O₂. Singlet oxygen was generated in liquid culture by the interaction of visible light (-550 nm) with the photosensitizer rose bengal or by the activation of -terthienyl with ultraviolet light (=366 nm). In each case the treatments selected for growth of pigmented strains ofP. rhodozyma. Albino (carotenoid-less) or yellow (-carotene producing) strains grew less well in media containing¹O₂. Addition of the¹O₂ quencher sodium azide to the medium with -terthienyl allowed growth of non-pigmented strains. Since the ecological niche ofP. rhodozyma is highly specific, we investigated whether extracts of birch trees (Betula), the original source ofP. rhodozyma, contained a compound that would select for pigmented populations of the yeast. WhenP. rhodozyma strains were exposed to ethyl acetate extracts ofBetula papyrifera excited with 366 nm ultraviolet light, only pigmented cells were able to grow. These results suggest that carotenogenesis developed inP. rhodozyma in response to the presence of photoactivatable antifungal compounds produced by the host tree.This paper is dedicated to Professor Herman Jan Phaff in honor of his 50 years of active research which still continues.     

Use of n-hexadecane as an oxygen vector to improve Phaffia rhodozyma growth and carotenoid production in shake-flask cultures

AIMS: To identify beneficial oxygen vectors for Phaffia rhodozyma in liquid cultures, and to evaluate their use to improve the oxygen transfer and carotenoid production in the yeast cultures. METHODS AND RESULTS: Several liquid hydrocarbons were tested as oxygen vectors for improving the yeast growth and carotenoid production in shake-flask cultures of P. rhodozyma. While all nontoxic organic liquids (Log P: > or =5.6) showed a positive effect, n-hexadecane was proved to be the most beneficial for the yeast growth and carotenoid production. The addition of 9% (v/v) n-hexadecane to the liquid medium at the time of inoculation was found to be optimal, increasing the carotenoid yield by 58% (14.5 mg l(-1) vs 9.2 g l(-1) in the control) and the oxygen transfer rate (OTR) by 90%. CONCLUSIONS: The addition of n-hexadecane to shake-flask cultures of P. rhodozyma significantly improved the oxygen transfer in culture, thus increasing the carotenoid production. SIGNIFICANCE AND IMPACT OF THE STUDY: Use of organic oxygen vectors such as n-hexadecane may be a simple and useful means for enhancing oxygen transfer and carotenoid production in liquid fermentation of P. rhodozyma.