Trisporoids under the stimulation of carotenogenesis in Blakeslea trispora

The patterns of trisporoid synthesis in joint cultivation of Blakeslea trispora mates have been studied. The pair of the not-zygospore-forming carotenoid overproducer strains T(+) and T(?) was found to synthesize a large amount of trisporoids, which did not differ in biological activity from those in the wild type strains. While the ??-carotene synthesis stimulator ??-ionone increased the amount of trisporoids, the share of trisporic acids in their composition decreased considerably. The lycopene synthesis stimulator 2-amino-6-methylpyridine caused a decrease in the content of trisporoid which had no trisporic acids in their composition. Emergence of a new substance with the maximum absorption at 250 nm, which accounted for up to 45% of the sum of trisporoids, was a general regularity in the action of both stimulators. The combined action of these two effectors resulted in additional stimulation of lycopene synthesis and was accompanied by the disappearance of trisporic acids. The aggregate findings indicate that both carotenogenesis stimulators inhibit the synthesis of trisporic acids, i.e., their action is not mediated by stimulation of trisporoid synthesis.     

Chemical regulators of carotenogenesis by Blakeslea trispora

The activation of the carotene biosynthetic pathway in Blakeslea trispora was found to occur by trisporic acid and many other compounds such as abscisic acid, β-ionone, α-ionone and vitamin A which share significant structural similarity with trisporic acid. The magnitude of stimulatory activities of these effectors was in the order trisporic acid > abscisic acid > β-ionone > α-ionone > vitamin A. Comparison of structures and stimulatory activities of all the effectors indicated that the short length of the side chain and the presence of a keto group in the ring structure of the trisporic acid molecule contributed significantly to the biological activity towards carotenogenesis.     

Effects of amines on the carotenogenesis in Blakeslea trispora

Six amines profoundly affected carotenogenesis in Blakeslea trispora. When cultures were treated with the amines, namely 4-[β-(diethylamino)-ethoxy]-benzaldehyde, 4-[β-(diethylamino)-ethoxy]-acetophenone hydrochloride, 4-β-(diethylamino)-ethoxy]-benzophenone hydrochloride, triethylamine hydrochloride, α-diethylaminopropiophenone hydrochloride and tributylamine hydrochloride, an increase in the lycopene accumulation was observed. The modes of action of these amines appear to be similar to that of 2-(4-chlorophenylthio)triethylamine hydrochloride (CPTA); however, they difrer in relative effectiveness.     

Hormonal Interactions in Mucor mucedo and Blakeslea trispora

Evidence is presented that progametangia in both the plus and the minus mating types of Mucor mucedo can be induced by one substance, namely (-)-trisporic acid B. A method is described for the determination of the concentration of the sex factors (trisporone, trisporic acid B, trisporic acid C) in mated cultures of Mucorales by polarography. It can be demonstrated that the amount of plus mycelium is limiting for the production of the sex factors in Blakeslea trispora. It is shown that the minus type of this organism is able to synthesize the sex factors when incubated in the filtered medium of a mated culture. Cycloheximide and 5-fluorouracil inhibit strongly the sex factor production in a mated culture of B. trispora at any time. This result suggests that sexual activity comprises the synthesis of proteins which are involved in the production of the sex factors.     

Relationship Between Sexuality and Carotene Synthesis in Blakeslea trispora

When stimulated by equivalent amounts of progametangia-inducing hormones, cultures of the minus mating type of Blakeslea trispora produce about the same quantities of carotenoids as mated cultures of the fungus, which suggests that the stimulation of carotene synthesis during the sexual activity of mated cultures is the result of hormonal action. These hormones were isolated and purified. From spectroscopic analysis of purified samples, it appears that the hormones are identical with trisporic acids B and C. When both mating types of B. trispora were cultivated in one vessel but were kept apart by membrane filters, the formation of sex hormones was not inhibited. Physical contact between the mating types is obviously not required for the induction of sexual activity. The sex hormones also formed in combined cultures of B. trispora-plus and Zygorhynchus moelleri (a homothallic species), but not in combined cultures of B. trispora-minus and Z. moelleri. This is evidence for the hypothesis that the hormones are produced by B. trispora-plus only.     

卡那霉素抗性基因在三孢布拉霉菌种中的表达

利用一个带有自主复制子,但缺失自身启动子的源于转座子Tn-5的卡那霉素抗性基因的质粒PVB32,在大肠杆菌中克隆丝状真菌三孢布拉霉DNA中有启动子功能的DNA片段;通过原生质体转化,获得了三孢布拉霉对卡那霉素抗性的表达,且抗性表现稳定,可通过孢子无性繁殖稳定遗传下去。     

Mutants of carotene production in Blakeslea trispora

The filamentous fungus Blakeslea trispora, an industrial carotene source, contains -carotene and precursors of its synthesis — phytoene, phytofluene, lycopene, and -carotene. Strain improvement through mutagenesis is difficult because all life stages are multinucleate. Mutants have been obtained following exposure of wild-type spores to N-methyl-N-nitro-N-nitrosoguanidine. Changes in the colour of the mycelia reflect variations in the accumulation of various precursors and the final product. Quantitative analysis of the mutants leads to the conclusion that the biosynthetic pathway is similar to that of the related fungus Phycomyces blakesleeanus, but the regulation is completely different. In particular, interruption of the pathway does not lead to overacummulation of precursors.     

三孢布拉霉发酵产番茄红素的研究进展

番茄红素是一种重要的类胡萝卜素,在生物体中具有抗氧化、抗衰老、提高免疫力等生理功能。虽然已经有部分企业实现了番茄红素的工业化生产,但产量仍然是制约三孢布拉霉发酵生产番茄红素的重要因素。在本实验室研究的基础上,本文结合近年来国内外学者的研究成果,从遗传育种、发酵工艺优化、化学调控等方面综述了提高三孢布拉霉中番茄红素产量的研究进展,并展望了未来的研究方向。     

微生物发酵产生的番茄红素的分离纯化

研究了三孢布拉霉(Blakeslea trispora)发酵产生的番茄红素的分离纯化方法。与植物源的番茄红素相比,真菌发酵产物中含有更多的油脂成分,且提取物中含有的一些同分异构体与产物性质类似而不易分离。实验采用溶剂抽提、大孔吸附树脂吸附法纯化以及结晶的方法可获得番茄红素晶体,纯度达70.9%,收率为64.6%。产品经重结晶后可获得纯度90%以上的番茄红素,经红外、核磁、质谱等证实与植物来源的番茄红素相一致。     

Blakeslea trispora mutants with a disrupted sexual process

Three groups of Blakeslea trispora (+) and (-) mutants were obtained and their phenotypical characteristics were studied as well as biochemical changes in the course of mating and the ability to synthesize carotenoids when the sexual process of these mutants was disordered. The first group of mutants synthesized carotenoids at the control level, the second group produced them below the control level, and the third group accumulated less than 1% of carotenoids as compared to the control. The difference in the yields of carotenoids among the three groups of mutants in the mated culture is attributed to the presence (or absence) of the ability to synthesize trisporic acids in them.     

Activation of the biosynthesis of carotenoids by Blakeslea trispora

The research carried out by several scientists has made possible the industrial preparation of β-carotene by fermentation. A fungus, Blakeslea trispora, abundantly synthesizes carotenoids when its two opposite forms are cultivated together in a special fatty medium. When ionones or other natural substances are introduced into the culture, a very obvious increase in the biosynthesis of carotenoids, more specifically of β-carotene, is obtained. Our own work has shown that; (1) several synthetic products chemically related to β-ionone, such as 2,6,6-trimethyl-l-acetyleyelohexene, can advantageously replace either partially or totally the ionones as inductors of the biosysnthesis of β-carotene; (2) various nitrogen-containing substances when added to the culture medium can considerably enhance the biosysnthesis of carotenoids while sometimes very specically orienting it. Their action comes on top of that of the ionones or their substitutes; actually this action is unexplained. Thus certain amides, imides, lactams, hydrazides, or substituted pyradines, and in particular succinimide and isonicotinoylhydrazine, have produced a two or threefold increase in the quantity of β-carotene present in the culture media of Blackeslea trispora. Conversely some heterocyclic substances such as pyridine itself or imidazole totally inhibit the biosysnthesis of β-carotene but induce the production of very important quantities of lycopene.