外源β-胡萝卜素、光照对青霉PT95菌株菌核分化和类胡萝卜素产率的影响

初步研究了外源β-胡萝卜素和光照对青霉PT5菌株菌核分化和类胡萝卜素产率的影响。结果表明,在培养基中加入外源β-胡萝卜素后,PT5菌株渗出液出现的时间、菌核出现的时间延迟了,但菌核成熟的时间没变。培养基中的外源β-胡萝卜素浓度越大,其渗出液、菌核出现的时间越迟。外源β-胡萝卜素亦能降低PT5菌株的脂质过氧化水平和菌核中的类胡萝卜素含量。高氧胁迫的光照培养条件有利于PT95菌株的菌核分化和色素在菌核中的积累;与低氧胁迫的黑暗培养条件相比,其菌核生物量和类胡萝卜素产率分别增加了18．7％和101％。以上实验结果表明,若想获得高的菌核生物量和类胡萝卜素产率,应该尽可能在高氧胁迫、无抗氧化剂存在的条件下培养PT5菌株。     

Sclerotial biomass and carotenoid yield of Penicillium sp. PT95 under oxidative growth conditions and in the presence of antioxidant ascorbic acid

AIMS: To determine the effect of oxidative stress and exogenous ascorbic acid on sclerotial biomass and carotenoid yield of Penicillium sp. PT95. METHODS: In this experiment, high oxidative stress was applied by the inclusion of FeSO(4) in the growth medium and exposure to light. Low oxidative stress was applied by omitting iron from the growth medium and by incubation in the dark. Supplementation of exogenous ascorbic acid (as antioxidant) to the basal medium caused a concentration-dependent delay of sclerotial differentiation (up to 48 h), decrease of sclerotial biomass (up to 40%) and reduction of carotenoid yield (up to 91%). On the contrary, the exogenous ascorbic acid also caused a concentration-dependent decrease of lipid peroxidation in colonies of this fungus. CONCLUSIONS: Under high oxidative stress growth condition, the sclerotial biomass and carotenoid yield of PT95 strain in each plate culture reached 305 mg and 32.94 microg, which were 1.23 and 3.71 times higher, respectively, than those at low oxidative stress growth condition. These data prompted us to consider that in order to attain higher sclerotial biomass and pigment yield, the strain PT95 should be grown under high oxidative stress and in the absence of antioxidants. SIGNIFICANCE AND IMPACT OF THE STUDY: These results suggest that strain PT95 may be used for solid-state fermentation of carotenoid production under high oxidative stress growth conditions.     

Effect of oxidative stress and exogenous beta-carotene on sclerotial differentiation and carotenoid yield of Penicillium sp. PT95

AIMS: To determine the effect of oxidative stress and exogenous beta-carotene on sclerotial differentiation and carotenoid yield of Penicillium sp. PT95. METHODS AND RESULTS: In this experiment, high oxidative stress was applied by inclusion of FeCl(3) (10 micromol l(-1)) in the growth medium and by light exposure. Low oxidative stress was applied by omitting iron from the growth medium and by incubation in the dark. Supplementation of exogenous beta-carotene (as antioxidant) to the basal medium caused a concentration-dependent delay of sclerotial differentiation (up to 72 h), decrease of sclerotial biomass (up to 43%) and reduction of carotenoid yield (up to 92%). On the contrary, the exogenous beta-carotene also caused a concentration-dependent decrease of lipid peroxidation in colonies of this fungus. CONCLUSIONS: Under high oxidative stress growth condition, the sclerotial biomass and carotenoid yield of PT95 strain in each plate culture reached 141 mg and 30.03 microg, which were 1.53 and 3.51 times higher respectively, than that at low oxidative stress growth condition. SIGNIFICANCE AND IMPACT OF THE STUDY: These data prompted us to consider that in order to attain higher sclerotial biomass and pigment yield, the strain PT95 should be grown under high oxidative stress and in the absence of antioxidants.     

Ascorbic acid might play a role in the sclerotial differentiation of Sclerotium rolfsii

Certain phytopathogenic fungi differentiate by forming sclerotia by an unclear biochemical mechanism. We have proposed that sclerotial differentiation might be regulated by fungal antioxidant defense. Part of this defense might be ascorbic acid, which in its reduced form is a well-known antioxidant. This natural antioxidant was studied in Sclerotium rolfsii in relation to oxidative-growth conditions, developmental stages and strain-differentiating ability. The transition of a sclerotial strain from the undifferentiated to the differentiated stage was accompanied by a sharp shift in the ratio of reduced/oxidized ascorbate toward the oxidized form. Ascorbate profiles and lipid peroxidation levels were different between the sclerotial strain grown under high- and low-oxidative stress conditions, as well as between a nonsclerotial S. rolfsii strain grown under high-oxidative stress conditions. In addition, the ratio of reduced/oxidized ascorbate in the nonsclerotial strain remained unchanged throughout growth. Lipid peroxidation under high-oxidative stress conditions in sclerotial S. rolfsii colonies one day before differentiation was 3.6-fold higher than in same-day colonies of this strain grown under low-oxidative stress conditions and 2.5-fold higher than in similar-day colonies of the nonsclerotial strain grown under high-oxidative stress conditions. Exogenous ascorbate caused a concentration-dependent reduction of lipid peroxidation and a proportional inhibition of the degree of sclerotial differentiation in the sclerotial strain grown under high-oxidative stress conditions by lowering its lipid peroxidation before differentiation to levels similar to the strain grown under low-oxidative stress conditions and to the nonsclerotial strain. Ascorbic acid might be produced by the sclerotial strain to reduce oxidative stress, although less efficiently than the nondifferenting strain. The data of this study support our theory that oxidative stress might be the triggering factor of sclerotial differentiation in phytopathogenic fungi.     

beta-Carotene production and its role in sclerotial differentiation of Sclerotium rolfsii

The fungus Sclerotium rolfsii produces beta-carotene, the main detected carotenoid, in levels dependent upon oxidative growth conditions and upon differentiation. beta-Carotene accumulation is 5-, 6.5-, and 6.7-fold higher in undifferentiated mycelia, sclerotia, and differentiated mycelia, respectively, at high than at low oxidative stress. It accumulates more in older than in younger mycelia and is 2-fold higher in differentiated than in undifferentiated mycelia. We propose that beta-carotene is formed possibly to help the fungus reduce oxidative stress that develops during growth. This is supported by the finding that exogenous beta-carotene at non-growth-inhibiting concentrations causes a concentration-dependent reduction of oxidative stress (lipid peroxidation) of undifferentiated mycelia, which results in an equally proportional reduction of sclerotial differentiation. The data of this study support our hypothesis that sclerotial differentiation is induced by oxidative stress.     

Effect of thiol redox state modulators on oxidative stress and sclerotial differentiation of the phytopathogenic fungus <Emphasis Type="Italic">Rhizoctonia solani</Emphasis>

This study showed that sclerotial differentiation in the filamentous phytopathogenic fungus Rhizoctonia solani is directly related to oxidative stress and thiol redox state (TRS). Sclerotial differentiation is modulated by the availability of non-cytotoxic −SH groups as was shown by the inhibition of sclerorial differentiation by the TRS modulator N-acetyl cysteine (AcCSH), and not necessarily with those of the TRS reduced components glutathione (GSH) and its precursor cysteine (CSH) as indicated by the GSH-biosynthesis inducer and inhibitor l-2–oxo-thiazolidine-4-carboxylate and l-buthionine-S,R-sulfoximine, respectively. Moreover, inhibition of sclerotial differentiation was accompanied by decrease of the high oxidative stress indicators, lipid peroxidation and DNA damage in the mycelial substrate where sclerotia initials are formed, which suggests that this phenomenon is related to oxidative stress as it is predicted by our theory on sclerotial differentiation.     

Sclerotial Formation of Polyporus umbellatus by Low Temperature Treatment under Artificial Conditions

Background

Polyporus umbellatus sclerotia have been used as a diuretic agent in China for over two thousand years. A shortage of the natural P. umbellatus has prompted researchers to induce sclerotial formation in the laboratory.

Methodology/Principal Finding

P. umbellatus cultivation in a sawdust-based substrate was investigated to evaluate the effect of low temperature conditions on sclerotial formation. A phenol-sulfuric acid method was employed to determine the polysaccharide content of wild P. umbellatus sclerotia and mycelia and sclerotia grown in low-temperature treatments. In addition, reactive oxygen species (ROS) content, expressed as the fluorescence intensity of mycelia during sclerotial differentiation was determined. Analysis of ROS generation and sclerotial formation in mycelia after treatment with the antioxidants such as diphenyleneiodonium chloride (DPI), apocynin (Apo), or vitamin C were studied. Furthermore, macroscopic and microscopic characteristics of sclerotial differentiation were observed. Sclerotia were not induced by continuous cultivation at 25°C. The polysaccharide content of the artificial sclerotia is 78% of that of wild sclerotia. In the low-temperature treatment group, the fluorescent intensity of ROS was higher than that of the room temperature (25°C) group which did not induce sclerotial formation all through the cultivation. The antioxidants DPI and Apo reduced ROS levels and did not induce sclerotial formation. Although the concentration-dependent effects of vitamin C (5–15 mg mL⁻¹) also reduced ROS generation and inhibited sclerotial formation, using a low concentration of vitamin C (1 mg mL⁻¹) successfully induced sclerotial differentiation and increased ROS production.

Conclusions/Significance

Exposure to low temperatures induced P. umbellatus sclerotial morphogenesis during cultivation. Low temperature treatment enhanced ROS in mycelia, which may be important in triggering sclerotial differentiation in P. umbellatus. Moreover, the application of antioxidants impaired ROS generation and inhibited sclerotial formation. Our findings may help to provide new insights into the biological mechanisms underlying sclerotial morphogenesis in P. umbellatus.     

Tolerance and stress response of sclerotiogenic <Emphasis Type="Italic">Aspergillus oryzae</Emphasis> G15 to copper and lead

Aspergillus oryzae G15 was cultured on Czapek yeast extract agar medium containing different concentrations of copper and lead to investigate the mechanisms sustaining metal tolerance. The effects of heavy metals on biomass, metal accumulation, metallothionein (MT), malondialdehyde (MDA), superoxide dismutase (SOD), catalase (CAT), and peroxidase (POD) were evaluated. Cu and Pb treatment remarkably delayed sclerotial maturation and inhibited mycelial growth, indicating the toxic effects of the metals. Cu decreased sclerotial biomass, whereas Pb led to an increase in sclerotial biomass. G15 bioadsorbed most Cu and Pb ions on the cell surface, revealing the involvement of the extracellular mechanism. Cu treatment significantly elevated MT level in mycelia, and Pb treatment at concentrations of 50–100 mg/L also caused an increase in MT content in mycelia. Both metals significantly increased MDA level in sclerotia. The variations in MT and MDA levels revealed the appearance of heavy metal-induced oxidative stress. The activities of SOD, CAT, and POD varied with heavy metal concentrations, which demonstrated that tolerance of G15 to Cu and Pb was associated with an efficient antioxidant defense system. In sum, the santioxidative detoxification system allowed the strain to survive in high concentrations of Cu and Pb. G15 depended mostly on sclerotial differentiation to defend against Pb stress.     

Role of Oxidative Stress in Sclerotial Differentiation and Aflatoxin B1 Biosynthesis in Aspergillus flavus

We show here that oxidative stress is involved in both sclerotial differentiation (SD) and aflatoxin B1 biosynthesis in Aspergillus flavus. Specifically, we observed that (i) oxidative stress regulates SD, as implied by its inhibition by antioxidant modulators of reactive oxygen species and thiol redox state, and that (ii) aflatoxin B1 biosynthesis and SD are comodulated by oxidative stress. However, aflatoxin B1 biosynthesis is inhibited by lower stress levels compared to SD, as shown by comparison to undifferentiated A. flavus. These same oxidative stress levels also characterize a mutant A. flavus strain, lacking the global regulatory gene veA. This mutant is unable to produce sclerotia and aflatoxin B1. (iii) Further, we show that hydrogen peroxide is the main modulator of A. flavus SD, as shown by its inhibition by both an irreversible inhibitor of catalase activity and a mimetic of superoxide dismutase activity. On the other hand, aflatoxin B1 biosynthesis is controlled by a wider array of oxidative stress factors, such as lipid hydroperoxide, superoxide, and hydroxyl and thiyl radicals.     

Cultivation studies on wild and hybrid strains of Pleurotus tuberregium (Fr.) Sing. on wheat straw substrate

Wild of strains Pleurotus tuberregium from Nigeria and the Australasian-Pacific regions and selected hybrids were studied to determine their growth and sclerotia production capacity on wheat straw substrate. Although the Australasian-Pacific strains showed faster growth rates, the wild strains from Nigeria performed better than the Australasian-Pacific strains in sclerotia yield. Under similar conditions, some hybrids had sclerotial yields that were higher than any wild strain. Our study showed the possibilities of using selected strains and the low cost methods adopted in this experiment, for the cultivation of sclerotia of P. tuberregium.     

ROS and trehalose regulate sclerotial development in Rhizoctonia solani AG-1 IA

Rhizoctonia solani AG-1 IA is the causal agent of rice sheath blight (RSB) and causes severe economic losses in rice-growing regions around the world. The sclerotia play an important role in the disease cycle of RSB. In this study, we report the effects of reactive oxygen species (ROS) and trehalose on the sclerotial development of R. solani AG-1 IA. Correlation was found between the level of ROS in R. solani AG-1 IA and sclerotial development. Moreover, we have shown the change of ROS-related enzymatic activities and oxidative burst occurs at the sclerotial initial stage. Six genes related to the ROS scavenging system were quantified in different sclerotial development stages by using quantitative RT-PCR technique, thereby confirming differential gene expression. Fluorescence microscopy analysis of ROS content in mycelia revealed that ROS were predominantly produced at the hyphal branches during the sclerotial initial stage. Furthermore, exogenous trehalose had a significant inhibitory effect on the activities of ROS-related enzymes and oxidative burst and led to a reduction in sclerotial dry weight. Taken together, the findings suggest that ROS has a promoting effect on the development of sclerotia, whereas trehalose serves as an inhibiting factor to sclerotial development in R. solani AG-1 IA.     

The role of ascorbic acid role in the differentiation of sclerotia in Sclerotinia minor

Sclerotinia minor in culture produces ascorbic acid in levels dependent on oxidative growth conditions and stage of development. During differentiation reduced/oxidized ascorbate ratio decreased by 12 and 6 fold at high and low oxidative stress, respectively. Exogenous ascorbate caused a concentration-dependent decrease of oxidative stress (lipid peroxidation), inhibition of sclerotial differentiation (up to 100%) and delay of differentiatlon (up to 10 days). Ascorbic acid may be produced to help the fungus reduce oxidative stress during growth. The data of this study support our theory proposing that oxidative stress is the inducing factor of sclerotial differentiation in fungi.This revised version was published online in October 2005 with corrections to the Cover Date.     

Increase in Endogenous and Exogenous Cyclic AMP Levels Inhibits Sclerotial Development in Sclerotinia sclerotiorum

Growth and development of a wild-type Sclerotinia sclerotiorum isolate were examined in the presence of various pharmacological compounds to investigate signal transduction pathways that influence the development of sclerotia. Compounds known to increase endogenous cyclic AMP (cAMP) levels in other organisms by inhibiting phosphodiesterase activity (caffeine and 3-isobutyl-1-methyl xanthine) or by activating adenylate cyclase (NaF) reduced or eliminated sclerotial development in S. sclerotiorum. Growth in the presence of 5 mM caffeine correlated with increased levels of endogenous cAMP in mycelia. In addition, incorporation of cAMP into the growth medium decreased or eliminated the production of sclerotia in a concentration-dependent manner and increased the accumulation of oxalic acid. Inhibition of sclerotial development was cAMP specific, as exogenous cyclic GMP, AMP, and ATP did not influence sclerotial development. Transfer of developing cultures to cAMP-containing medium at successive time points demonstrated that cAMP inhibits development prior to or during sclerotial initiation. Together, these results indicate that cAMP plays a role in the early transition between mycelial growth and sclerotial development.     

Isolation of a non-sclerotial mutant ofSclerotium rolfsii and its cellulolytic activity

A mutant strain EMS-1 ofSclerotium rolfsii lacking the ability to develop mature sclerotia was isolated following chemical mutagenesis of macerated sclerotia with ethyl methane-sulfonate. The mutant failed to form sclerotia even in the presence of lactose, threonine or iodo-acetic acid which promoted sclerotial development in the wild strain and the UV-8 mutant. EMS-1 exhibited higher (1.5 – 3.0 times) cellulase and hemicellulase activity compared to the wild strain. Possible correlation between sclerotial morphogenesis and cellulase and/or oxalic acid production is discussed.     

Oxidative Stress in Relation to Lipid Peroxidation, Sclerotial Development and Melanin Production by Sclerotium rolfsii

Melanin pigments constituted 13.9% of the chemical composition of the sclerotial walls of Sclerotium rolfsii and was associated with proteins, reducing sugars and amino acids. The lipid and ash contents in the sclerotial walls were double those in the hyphal walls of the fungus. Increasing age of the culture and maturation of the sclerotia were always accompanied by elevation of lipid peroxides and melanin pigments. Such behaviour may indicate that lipid peroxidation and melanin formation are operating in parallel during sclerotial biogenesis and maturation. These two processes depend on the theory of oxidative stress, as affected by growth conditions. Both processes could be stopped or sharply retarded when subjected to some antioxidant growth factors such as vitamins (ascorbic acid), micro-elements (selenium) and sulfhydryl compounds (glutathione). A clear relation between oxidative stress, myceliogenic germination and lytic activity via melanin production was observed. This finding appears promising in applying a new control measure against diseases caused by sclerotia-producing fungi without using traditional toxic fungicides.     

激光诱变青霉PT95原生质体选育类胡萝卜素高产菌株

采用激光对青霉PT95菌株的原生质体进行了诱变处理,选育到一株菌核生物量和类胡萝卜素含量均有显提高的突变菌株L05。与出发菌株相比,L05菌株的菌核生物量提高了98.6%,菌核中的类胡萝卜素含量提高了28.3%,在查氏平板上的类胡萝卜素产率提高了154.0%。所选育的L05菌株经3次传代培养,菌落没有发生扇形变异,菌核生物量和类胡萝卜素含量没有明显改变,说明该菌株具有良好的遗传稳定性。     

Oxidative stress and photoinhibition can be separated in the cyanobacterium Synechocystis sp. PCC 6803

Roles of oxidative stress and photoinhibition in high light acclimation were studied using a regulatory mutant of the cyanobacterium Synechocystis sp. PCC 6803. The mutant strain ΔsigCDE contains the stress responsive SigB as the only functional group 2 σ factor. The ?sigCDE strain grew more slowly than the control strain in methyl-viologen-induced oxidative stress. Furthermore, a fluorescence dye detecting H₂O₂, hydroxyl and peroxyl radicals and peroxynitrite, produced a stronger signal in ?sigCDE than in the control strain, and immunological detection of carbonylated residues showed more protein oxidation in ?sigCDE than in the control strain. These results indicate that ?sigCDE suffers from oxidative stress in standard conditions. The oxidative stress may be explained by the findings that ?sigCDE had a low content of glutathione and low amount of Flv3 protein functioning in the Mehler-like reaction. Although ?sigCDE suffers from oxidative stress, up-regulation of photoprotective carotenoids and Flv4, Sll2018, Flv2 proteins protected PSII against light induced damage by quenching singlet oxygen more efficiently in ?sigCDE than in the control strain in visible and in UV-A/B light. However, in UV-C light singlet oxygen is not produced and PSII damage occurred similarly in the ?sigCDE and control strains. According to our results, resistance against the light-induced damage of PSII alone does not lead to high light tolerance of the cells, but in addition efficient protection against oxidative stress would be required.     

青霉PT95菌固态发酵产生类胡萝卜素的研究

本文对青霉Ｐｅｎｉｃｉｌｌｉｕｍｓｐ．ＰＴ９５菌株在固态发酵条件下菌核内产生类胡萝卜素进行了初步研究。结果表明,在３种固态发酵培养基中,玉米粉培养基（ＳＭＡ）比麸皮２基和棉籽壳培养基更适合于ＰＴ９５菌株固态发酵产生类胡萝卜素。为了增加菌核干重和提高类胡萝卜素产率,ＳＭＡ中需要添加氮源、碳源和植物油。在所度的各种氮、碳源中,以硝酸钠和麦芽糖效果最佳。通过我试验确定了在培养基盐溶液中添加硝酸钠３ｇ／Ｌ     

Effect of glutathione biosynthesis-related modulators on the thiol redox state enzymes and on sclerotial differentiation of filamentous phytopathogenic fungi

In this study, sclerotial differentiation in filamentous phytopathogenic fungi, representing the four main types of sclerotia, was studied in relation to thiol redox state (TRS)-related enzymes and their substrates/products. TRS was altered by the general TRS modulator Ν-acetylcysteine (AcCSH) and by the glutathione (GSH) biosynthesis modulators l-oxo-thiazolidine-4-carboxylate (OTC), and l-buthionine-S,R-sulfoximine (BSO). This study showed that the four studied types of sclerotial differentiation are directly related with the antioxidant –SH groups of GSH and/or CSH, since the decrease of sclerotial differentiation concurred with an increase of these thiols by the GSH biosynthesis modulators AcCSH, OTC, and BSO. Supportive to that conclusion is the fact that, in general, the activities of the TRS-related enzymes GR/GPDH and Ttase decrease in the end of the undifferentiated stage due to the substitution of their antioxidant function by the antioxidant potential of the –SH group providers AcCSH and OTC. Moreover, it was found that BSO expectedly suppressed GSH biosynthesis in the tested fungi, and unexpectedly decreased their sclerotial differentiation by a dose-dependent manner typical for antioxidants. The possible antioxidant role of BSO was supported by the decrease it caused in the antioxidant enzymes GR/GPDH and Ttase. The results of this study are in accordance with our hypothesis that sclerotial differentiation in phytopathogenic fungi is induced by oxidative stress.     

Involvement of Ca2+ Channel Signalling in Sclerotial Formation of Polyporus umbellatus

Growth and morphogenesis transformation in Polyporus umbellatus were examined in the presence of various pharmacological compounds, to investigate signal transduction pathways that influence the development of sclerotia. Both the calcium channel blocker nifedipine and the calcium ionophor A23187 reduced sclerotial production in P. umbellatus; four classes of Ca²⁺ signal agent—including calcium chelators, calcium channel blockers, calcium ionophors and calmodulin inhibitors—were further studied. Among them, EGTA and BAPTA, as calcium chelators, exhibited a complete inhibitory effect on sclerotial formation, among the levels tested. Calcium channel blockers and calcium ionophors at the concentrations used in this study could not eliminate sclerotia formation completely, but did greatly reduce sclerotial production. Notoginsenoside in dosages >250 μg/ml produced a significant negative effect on mycelial growth, and it prevented sclerotial formation entirely at a dosage of 500 μg/ml; no other drug influenced vegetative growth at all. The calcium ionophor A23187 did not decrease sclerotial mean weight at low doses (20 nM); at higher doses (200 nM), however, sclerotial development was significantly reduced, albeit not completely halted. The CaM inhibitors (W-7 and chlorpromazine) could each completely stop sclerotial formation. Using Fluo-3/AM as the indicator of cytosolic free calcium, the Ca²⁺ content in the cytoplasm was found to have decreased significantly when hyphae were treated with different drugs, and there was no active Ca²⁺ signal in the sclerotial mycelium. In general, the results suggest that Ca²⁺ signal transduction may play an important role in sclerotial formation in P. umbellatus.