A genetic and biochemical approach to study trichothecene diversity in Fusarium sporotrichioides and Fusarium graminearum

The trichothecenes T-2 toxin and deoxynivalenol (DON) are natural fungal products that are toxic to both animals and plants. Their importance in the pathogenicity of Fusarium spp. on crop plants has inspired efforts to understand the genetic and biochemical mechanisms leading to trichothecene synthesis. In order to better understand T-2 toxin biosynthesis by Fusarium sporotrichioides and DON biosynthesis by F. graminearum, we compared the nucleotide sequence of the 23-kb core trichothecene gene cluster from each organism. This comparative genetic analysis allowed us to predict proteins encoded by two trichothecene genes, TRI9 and TRI10, that had not previously been described from either Fusarium species. Differences in gene structure also were correlated with differences in the types of trichothecenes that the two species produce. Gene disruption experiments showed that F. sporotrichioides TRI7 (FsTRI7) is required for acetylation of the oxygen on C-4 of T-2 toxin. Sequence analysis indicated that F. graminearum TRI7 (FgTRI7) is nonfunctional. This is consistent with the fact that the FgTRI7 product is not required for DON synthesis in F. graminearum because C-4 is not oxygenated.     

Fusarium Tri4 encodes a key multifunctional cytochrome P450 monooxygenase for four consecutive oxygenation steps in trichothecene biosynthesis

Fusarium Tri4 encodes a cytochrome P450 monooxygenase (CYP) for hydroxylation at C-2 of the first committed intermediate trichodiene (TDN) in the biosynthesis of trichothecenes. To examine whether this CYP further participates in subsequent oxygenation steps leading to isotrichotriol (4), we engineered Saccharomyces cerevisiae for de novo production of the early intermediates by introducing cDNAs of Fusarium graminearum Tri5 (FgTri5 encoding TDN synthase) and Tri4 (FgTri4). From a culture of the engineered yeast grown on induction medium (final pH 2.7), we identified two intermediates, 2alpha-hydroxytrichodiene (1) and 12,13-epoxy-9,10-trichoene-2alpha-ol (2), and a small amount of non-Fusarium trichothecene 12,13-epoxytrichothec-9-ene (EPT). Other intermediates isotrichodiol (3) and 4 were identified in the transgenic yeasts grown on phosphate-buffered induction medium (final pH 5.5-6.0). When Trichothecium roseum Tri4 (TrTri4) was used in place of FgTri4, 4 was not detected in the culture. The three intermediates, 1, 2, and 3, were converted to 4,15-diacetylnivalenol (4,15-diANIV) when fed to a toxin-deficient mutant of F. graminearum with the FgTri4+ genetic background (viz., by introducing a FgTri5- mutation), but were not metabolized by an FgTri4- mutant. These results provide unambiguous evidence that FgTri4 encodes a multifunctional CYP for epoxidation at C-12,13, hydroxylation at C-11, and hydroxylation at C-3 in addition to hydroxylation at C-2.     

Myrothecium roridum Tri4 encodes a multifunctional oxygenase required for three oxygenation steps

The biosyntheses of both macrocyclic trichothecenes in Myrothecium roridum and simple trichothecenes in Fusarium species begin with the cyclization of farnesyl pyrophosphate to form the sesquiterpene hydrocarbon trichodiene. A previous study showed that Myrothecium has a cluster of 3 genes that are homologous with Fusarium trichothecene genes: Tri4, a P450 oxygenase; Tri5, the sesquiterpene cyclase; and Tri6, a zinc-finger regulatory gene. Fusarium graminearum Tri4 (FgTri4) and M. roridum MrTri4 (MrTri4) have 66.9% identity. In this study, MrTri4 was expressed in Fusarium verticillioides. Liquid cultures of transformant strains expressing MrTri4 converted exogenous trichodiene to isotrichodiol, indicating that MrTri4 controls 3 oxygenation steps and that the product of MrTRI4 is isotrichodiol.     

Effects of different carbon sources on trichothecene production and Tri gene expression by Fusarium graminearum in liquid culture

Fusarium head blight caused by Fusarium graminearum is a disease of cereal crops that not only reduces crop yield and quality but also results in contamination with trichothecenes such as nivalenol and deoxynivalenol (DON). To analyze the trichothecene induction mechanism, effects of 12 carbon sources on the production of DON and 3-acetyldexynivalenol (3ADON) were examined in liquid cultures incubated with nine strains of 3ADON-producing F. graminearum. Significantly high levels of trichothecene (DON and 3ADON) production by sucrose, 1-kestose and nystose were commonly observed among all of the strains tested. On the other hand, the levels of trichothecene biosynthesis induced by the other carbon sources were strain-specific. Tri4 and Tri5 expressions were up-regulated in the sucrose-containing medium but not in glucose. Trichothecene accumulation in the sucrose-containing medium was not repressed by the addition of glucose, indicating that trichothecene production was not regulated by carbon catabolite repression. These findings suggest that F. graminearum recognizes sucrose molecules, activates Tri gene expression and induces trichothecene biosynthesis.     

小麦赤霉病镰孢菌毒素的生物合成及其分子调控

禾谷镰刀菌是小麦赤霉病的主要致病菌,其真菌次生代谢产生的单端孢霉烯类B型毒素,如雪腐镰刀菌烯醇(nivalenol,NIV)、脱氧雪腐镰刀菌烯醇(deoxynivalenol,DON)和其它乙酰化衍生物等污染小麦籽粒后对人畜健康构成威胁。综述了近年来国内外对小麦赤霉病镰孢菌单端孢霉烯类B型毒素生物合成的主要途径及分子调控研究进展,对毒素合成过程中的重要调控基因如TRI5、TRI7和TRI13在农业中的应用进行了阐述。     

长江流域禾谷镰孢菌群部分菌株系统发育学、产毒素化学型及致病力研究

从采集自长江流域引起小麦赤霉病的禾谷镰孢菌群(Fusarium graminearum clade)菌株中选取了31株,扩增并测定了这些菌株的EF-1α(translation elongation factor)、PHO(phosphate permease)基因序列,利用相关软件进行了系统发育分析。对这些菌株的产毒素化学型进行了分子检测。同时,用两个小麦品种(扬麦158和安农8455)测定了菌株的致病力。系统发育分析表明绝大多数菌株与F.asiaticum聚为一枝,只有一个菌株11027与F.graminearum聚类。30株F.asiaticum中有24株产脱氧雪腐镰孢菌烯醇(deoxynivalenol,DON)和3-乙酰脱氧雪腐镰孢菌烯醇(3-acetyldeoxynivalenol,3-AcDON),另外6株产雪腐镰孢菌烯醇(Nivalenol,NIV)。一株F.graminearum菌株11027产脱氧雪腐镰孢菌烯醇(DON)和15-乙酰脱氧雪腐镰孢菌烯醇(15-acetyldeoxynivalenol,15-AcDON)。在扬麦158上,菌株间的致病力分化较为明显,产NIV毒素的菌株致病力普遍较弱,强致病力的菌株都产3-AcDON毒素。结果表明在我国长江流域,产3-AcDON毒素的F.asiaticum是引起小麦赤霉病的优势种群,中抗赤霉病的小麦品种扬麦158可以有效评价菌株的致病力强弱。     

Disruption of TRI101, the gene encoding trichothecene 3-O-acetyltransferase, from Fusarium sporotrichioides

We screened a Fusarium sporotrichioides NRRL 3299 cDNA expression library in a toxin-sensitive Saccharomyces cerevisiae strain lacking a functional PDR5 gene. Fourteen yeast transformants were identified as resistant to the trichothecene 4,15-diacetoxyscirpenol, and each carried a cDNA encoding the trichothecene 3-O-acetyltransferase that is the F. sporotrichioides homolog of the Fusarium graminearum TRI101 gene. Mutants of F. sporotrichioides NRRL 3299 produced by disruption of TRI101 were altered in their abilities to synthesize T-2 toxin and accumulated isotrichodermol and small amounts of 3, 15-didecalonectrin and 3-decalonectrin, trichothecenes that are not observed in cultures of the parent strain. Our results indicate that TRI101 converts isotrichodermol to isotrichodermin and is required for the biosynthesis of T-2 toxin.     

Development of a PCR assay to detect the potential production of nivalenol in Fusarium poae

Fusarium species can produce mycotoxins, which can contaminate cereal-based food producing adverse effects for human and animal health. In recent years, the importance of Fusarium poae has increased within the Fusarium head blight complex. Fusarium poae is known to produce trichothecenes, especially nivalenol, a potent mycotoxin able to cause a variety of toxic effects. In this study, a specific primer pair was designed based on the tri7 gene to detect potential nivalenol-producing F.?poae isolates. A total of 125 F.?poae, four F.?cerealis, two F.?culmorum, one F.?langsethiae, one F.?sporotrichioides and seven F.?graminearum, plus F.?austroamericanum, F.?meridionale, F.?graminearum sensu stricto and F.?cortaderiae from the NRRL collection were analysed, and only F.?poae isolates gave a positive result for the presence of a 296-bp partial tri7 DNA fragment. Moreover, the primer set was tested from cereal seed samples where F.?poae and other Fusarium species with a negative result for the specific reaction ( F.?graminearum, F.?oxysporum, F.?chlamydosporum, F.?sporotrichioides, F.?equiseti and F.?acuminatum) were isolated, and the expected fragment was amplified. We developed a rapid and reliable PCR assay to detect potential nivalenol-producing F.?poae isolates.     

The velvet gene, FgVe1, affects fungal development and positively regulates trichothecene biosynthesis and pathogenicity in Fusarium graminearum

Trichothecenes are a group of toxic secondary metabolites produced mainly by Fusarium graminearum (teleomorph: Gibberella zeae) during the infection of crop plants, including wheat, maize, barley, oats, rye and rice. Some fungal genes involved in trichothecene biosynthesis have been shown to encode regulatory proteins. However, the global regulation of toxin biosynthesis is still enigmatic. In addition to the production of secondary metabolites belonging to the trichothecene family, F. graminearum produces the red pigment aurofusarin. The gene regulation underlying the production of aurofusarin is not well understood. The velvet gene (veA) is conserved in various genera of filamentous fungi. Recently, the veA gene from Aspergillus nidulans has been shown to be the key component of the velvet complex regulating development and secondary metabolism. Using blast analyses, we identified the velvet gene from F. graminearum, FgVe1. Disruption of FgVe1 causes several phenotypic effects. However, the complementation of this mutant with the FgVe1 gene restores the wild-type phenotypes. The in vitro phenotypes include hyperbranching of the mycelium, suppression of aerial hyphae formation, reduced hydrophobicity of the mycelium and highly reduced sporulation. Our data also show that FgVe1 modulates the production of the aurofusarin pigment and is essential for the expression of Tri genes and the production of trichothecenes. Pathogenicity studies performed on flowering wheat plants indicate that FgVe1 is a positive regulator of virulence in F. graminearum.     

Heterologous expression of two trichothecene P450 genes in Fusarium verticillioides

Fusarium graminearum Z-3639 and F. sporotrichioides NRRL3299 produce the trichothecene mycotoxins 15-acetyldeoxynivalenol and T-2 toxin, respectively. These toxins differ in oxygenation at C-4, C-7, and C-8. In F. sporotrichioides, Tri1 (FsTri1) controls C-8 hydroxylation. To determine the function of an apparent F. graminearum Tri1 (FgTri1) homolog, both FsTri1 and FgTri1 genes were heterologously expressed in the trichothecene-nonproducing species F. verticillioides by fusing the Tri1 coding regions to the promoter of the fumonisin biosynthetic gene FUM8. FsTri1 and FgTri1 have been partially characterized by disruption analysis, and the results from these analyses suggest that FsTri1 most likely has a single function but that FgTri1 may have two functions. Transgenic F. verticillioides carrying the FsTri1 (FvF8FsTri1) converted exogenous isotrichodermin and calonectrin to 8-hydroxyisotrichodermin and 8-hydroxycalonectrin, respectively. Transgenic F. verticillioides carrying FgTri1 (FvF8FgTri1) converted isotrichodermin to a mixture of 7-hydroxyisotrichodermin and 8-hydroxyisotrichodermin but converted calonectrin to a mixture of 7-hydroxycalonectrin, 8-hydroxycalonectrin, and 3,15-diacetyldeoxynivalenol. A fourth compound, 7,8-dihydroxycalonectrin, was identified in large-scale F. verticillioides FvF8FgTri1 cultures fed isotrichodermin. Our results indicate that FgTri1 controls both C-7 and C-8 hydroxylation but that FsTri1 controls only C-8 hydroxylation. Our studies also demonstrate that F. verticillioides can metabolize some trichothecenes by adding an acetyl group to C-3 or by removing acetyl groups from C-4 or C-15. In addition, wild-type F. verticillioides can convert 7,8-dihydroxycalonectrin to 3,15-diacetyldeoxynivalenol.     

Inactivation of a cytochrome P-450 is a determinant of trichothecene diversity in Fusarium species

Species of the genus Fusarium produce a great diversity of agriculturally important trichothecene toxins that differ from each other in their pattern of oxygenation and esterification. T-2 toxin, produced by Fusarium sporotrichioides, and nivalenol (NIV), produced by some strains of F. graminearum, contain an oxygen at the C-4 position. Deoxynivalenol (DON), produced by other strains of F. graminearum, lacks a C-4 oxygen. NIV and DON are identical except for this difference, whereas T-2 differs from these trichothecenes at three other carbon positions. Sequence and Northern analyses of the F. sporotrichioides genomic region upstream of the previously described core trichothecene gene cluster have extended the cluster by two genes: TRI13 and TRI14. TRI13 shares significant similarity with the cytochrome P-450 class of enzymes, but TRI14 does not share similarity with any previously characterized proteins. Gene disruption and fermentation studies in F. sporotrichioides indicate that TRI13 is required for the addition of the C-4 oxygen of T-2 toxin, but that TRI14 is not required for trichothecene biosynthesis. PCR and sequence analyses indicate that the TRI13 homolog is functional in NIV-producing strains of F. graminearum but nonfunctional in DON-producing strains of the fungus. These genetic observations are consistent with chemical observations that biosynthesis of T-2 toxin and NIV requires a C-4 hydroxylase while biosynthesis of DON does not.     

禾谷镰孢菌高产毒菌株的构建*

为研究禾谷镰孢菌Fusarium graminearum Schw.单端孢霉烯族毒素生物合成基因（产毒基因）在寄主体内的表达,作者构建了带报告基因GUS（(-葡糖苷酸酶基因）的质粒pGUSTRI6P5,并通过对野生型菌株的转化获得禾谷镰孢高产毒菌株。该质粒含有由TRI5（禾谷镰孢单端孢霉二烯合酶基因）启动子（TRI5 Prom）驱动的GUS基因编码区、潮霉素B抗性基因和拟枝孢镰孢F. sporotrichioides的产毒调控基因TRI6（FSTRI6）。用pGUSTRI6P5转化野生型菌株GZ3639后,在含潮霉素 B的培养基上选取抗性菌落,单孢分离获单孢菌株（转化子）。在GYEP（葡萄糖-酵母粉-蛋白胨）液体培养基上,转化子B4-1和B16-1的GUS比活力强,15-AcDON（15-乙酰脱氧雪腐镰刀菌烯醇）产量高,且两者呈正相关（相关系数（r）分别为0.9839和0.9523）。B4-1和B16-1两个转化子可作为研究禾谷镰孢与其寄主相互作用的工具菌株。     

中国小麦赤霉病菌优势种——禾谷镰刀菌产毒素能力的研究

试验测定了分离自中国小麦赤霉病常发生地区病麦穗上的47个禾谷镰刀菌(Fusariumgraminearum)菌株的产毒紊能力。结果表明,它们可以产生25种包括单端孢霉烯族化合物(Trichothecenes)、倍半萜类化合物(sesquiterpenes)、赤霉烯酮(Zearalenone)和丁烯羟酸内酯(Butenolide)等类的已知次生代谢物。这些菌株属于化学型 I,其中,来自我国温暖麦区的菌株都属化学型IA (deoxynivalenol,3-acetyl),并在气候冷凉地区发现化学型IB(de-oxynivalenol,15-acetyl)菌株。     

Population analysis of the Fusarium graminearum species complex from wheat in China show a shift to more aggressive isolates

A large number of Fusarium isolates was collected from blighted wheat spikes originating from 175 sampling sites, covering 15 provinces in China. Species and trichothecene chemotype determination by multilocus genotyping (MLGT) indicated that F. graminearum s. str. with the 15-acetyl deoxynivalenol (15ADON) chemotype and F. asiaticum with either the nivalenol (NIV) or the 3-acetyl deoxynivalenol (3ADON) chemotype were the dominant causal agents. Bayesian model-based clustering with allele data obtained with 12 variable number of tandem repeats (VNTR) markers, detected three genetic clusters that also show distinct chemotypes. High levels of population genetic differentiation and low levels of effective number of migrants were observed between these three clusters. Additional genotypic analyses revealed that F. graminearum s. str. and F. asiaticum are sympatric. In addition, composition analysis of these clusters indicated a biased gene flow from 3ADON to NIV producers in F. asiaticum. In phenotypic analyses, F. asiaticum that produce 3ADON revealed significant advantages over F. asiaticum that produce NIV in pathogenicity, growth rate, fecundity, conidial length, trichothecene accumulation and resistance to benzimidazole. These results suggest that natural selection drives the spread of a more vigorous, more toxigenic pathogen population which also shows higher levels of fungicide resistance.