An adaptive evolutionary shift in Fusarium head blight pathogen populations is driving the rapid spread of more toxigenic Fusarium graminearum in North America

Analysis of Fusarium head blight (FHB) pathogen diversity revealed that 3ADON producing Fusarium graminearum are prevalent in North America and identified significant population structure associated with trichothecene chemotype differences (F(ST)>0.285; P<0.001). In addition, we identified a trichothecene chemotype cline in Canada and documented a recent and significant shift in FHB pathogen composition by demonstrating that the 3ADON chemotype frequency in western Canada increased more than 14-fold between 1998 and 2004. On average, isolates from 3ADON populations produced significantly (P<0.05) more trichothecene and had significantly (P<0.005) higher fecundity and growth rates than isolates from the 15ADON population. These results indicate that selection is driving the rapid spread of an introduced pathogen population that is more toxigenic and potentially more vigorous. The discovery of this previously unrecognized pathogen diversity has significant implications for food safety and cereal production in North America.     

An adaptive evolutionary shift in Fusarium head blight pathogen populations is driving the rapid spread of more toxigenic Fusarium graminearum in North America.

Analysis of Fusarium head blight (FHB) pathogen diversity revealed that 3ADON producing Fusarium graminearum are prevalent in North America and identified significant population structure associated with trichothecene chemotype differences (F(ST)>0.285; P<0.001). In addition, we identified a trichothecene chemotype cline in Canada and documented a recent and significant shift in FHB pathogen composition by demonstrating that the 3ADON chemotype frequency in western Canada increased more than 14-fold between 1998 and 2004. On average, isolates from 3ADON populations produced significantly (P<0.05) more trichothecene and had significantly (P<0.005) higher fecundity and growth rates than isolates from the 15ADON population. These results indicate that selection is driving the rapid spread of an introduced pathogen population that is more toxigenic and potentially more vigorous. The discovery of this previously unrecognized pathogen diversity has significant implications for food safety and cereal production in North America.     

On the trail of a cereal killer: recent advances in Fusarium graminearum pathogenomics and host resistance

The ascomycete fungal pathogen Fusarium graminearum (sexual stage: Gibberella zeae) causes the devastating head blight or scab disease on wheat and barley, and cob or ear rot disease on maize. Fusarium graminearum infection causes significant crop and quality losses. In addition to roles as virulence factors during pathogenesis, trichothecene mycotoxins (e.g. deoxynivalenol) produced by this pathogen constitute a significant threat to human and animal health if consumed in respective food or feed products. In the last few years, significant progress has been made towards a better understanding of the processes involved in F. graminearum pathogenesis, toxin biosynthesis and host resistance mechanisms through the use of high-throughput genomic and phenomic technologies. In this article, we briefly review these new advances and also discuss how future research can contribute to the development of sustainable plant protection strategies against this important plant pathogen.     

Coprinellus curtus (Hitoyo-take) prevents diseases of vegetables caused by pathogenic fungi

A strain of Coprinellus curtus (designated GM-21), a basidiomycete that suppressed bottom-rot disease of Chinese cabbage, 'pak-choi' (Brassica campestris), caused by the pathogen Rhizoctonia solani Pak-choi 2 was isolated. The mechanism of plant disease suppression was discovered to be hyphal interference, a combative fungal interaction between strain GM-21 and the pathogen. The antifungal spectrum of strain GM-21 was shown to include R. solani and Fusarium sp., i.e. strain GM-21 showed disease-suppressive ability against bottom-rot disease of lettuce and Rhizoctonia-patch disease of mascarene grass caused by strains of R. solani. In addition, clear evidence of hyphal interference between strain GM-21 and Fusarium pathogens that cause crown (foot) and root-rot disease of tomato and Fusarium wilt of melon, respectively, was demonstrated. It was thus considered that GM-21 is effective for suppressing soil-borne pathogens, and that GM-21 presents new possibilities for biological control of vegetable diseases.     

上海市进口火龙果软腐病病害分析

应用病原形态学和真菌rDNA-ITS分子标记及Fusarium oxysporum种特异性序列分析, 对引起上海市水果市场销售的进口火龙果软腐的市场病害进行了分离与鉴定, 明确了两种主要的致病真菌为尖孢镰刀菌(Fusarium oxysporum)和单隔镰刀菌(Fusarium dimerum)。其中, F. oxysporum为引起进口火龙果采后软腐的最主要病原真菌, 该菌最适生长温度和致病温度均为25 °C, 光照条件下的致病性强, 在15 °C和35 °C条件下致病性明显降低, 5 °C和45 °C条件下该菌无法正常生长和致病, 并且该菌还能够引起香蕉、番茄、葡萄等多种水果腐烂。系统研究引起进口火龙果采后软腐病病原真菌的生物学特性, 为进口火龙果采后病原真菌有效控制方法的制定提供了有益的参考。     

Silencing of the Ornithine Decarboxylase Gene of Fusarium oxysporum f. sp. lycopersici by Host-Induced RNAi Confers Resistance to Fusarium Wilt in Tomato

Plant Molecular Biology Reporter - Fusarium wilt caused by Fusarium oxysporum f. sp. lycopersici, a hemibiotrophic filamentous fungal pathogen is one of the important diseases of tomato. Recently,...     

甘肃大葱贮藏期镰孢菌腐烂病病原鉴定

【目的】大葱在贮藏期频繁发生镰孢菌腐烂病,损失严重。明确该病害病原种类对病害防治具有重要意义。【方法】利用组织分离法对采集自甘肃省兰州市(区)蔬菜市场的16份大葱贮藏期镰孢菌腐烂病病样进行病原物的分离、纯化培养,经单孢分离后根据形态学特征,再结合r DNA-ITS、EF-1a(tef)基因序列分析的方法进行鉴定。【结果】共分离得到80株镰孢菌,经鉴定分属3个种,即层出镰孢菌(Fusarium proliferatum)、尖孢镰孢菌(F.oxysporum)和燕麦镰孢菌(F.avenaceum),其中层出镰孢菌为大葱镰孢菌腐烂病的优势致病菌,分离频率为52.50%。对兰州白葱不同部位进行致病性测定,结果表明层出镰孢菌对大葱鳞茎的致病力最强,而燕麦镰孢菌对大葱鳞茎的致病力最弱。【结论】3种镰孢菌作为该病害的病原,属国内首次报道。     

Effect of water activity and temperature on competing abilities of Penicillium oxalicum against Fusarium oxysporum

The in vitro effect of water activity (0.995, 0.98, 0.95, 0.90 and 0.85) and temperature (25 and 15 degrees C) on competing abilities of the biocontrol agent Penicillium oxalicum against Fusarium oxysporum fsp. lycopersici, a tomato pathogen, and Fusarium oxysporum fsp. gladioli, a gladiolus pathogen, was evaluated. The aim of this study was to assess the suitability of P. oxalicum to be applied as a biocontrol agent against these phytopathogenic fungi. Plates were inoculated in two points with P. oxalicum and one of the Fusarium species. Two different approaches were taken into account: the growth rate of each isolate and the Dominance Index (ID). P. oxalicum showed higher growth rates under most of the conditions tested except for 0.995 aw at both temperatures and at 0.98 and 15 degrees C. Similarly, P. oxalicum was dominating at 25 degrees C and < or = 0.95 aw, and at 15 degrees C and < or = 0.90 aw, while under the other conditions studied, mutual inhibition situations were found. This indicates a high ability of this species to successfully compete over a wide range of conditions and consequently the potential of P. oxalicum as a biocontrol agent against these Fusarium species.     

Antagonistic effects of soil bacteria onFusarium oxysporum Schlecht f. sp.dianthi (Prill and Del.) Snyd. and Hans

Summary Fusarium oxysporum f. sp.dianthi, pathogenic on carnation plants is very sensitive toBacillus subtilis M51 inhibition.Fusarium oxysporum disease (fusariosis) is prevented for a period of two months after treatment of plants withBacillus subtilis M51. The persistence ofB. subtilis M51, marked for selenomycin resistance (MZ51) and inoculated on the roots of carnation cuttings was studied. Soil used was two types: naturally infested withFusarium oxysporum and free from this pathogen. Bacterial cells presence on the roots was detected by direct plating and the presence of the pathogen in the roots was investigated by histological assays. Evidence gathered by these procedures suggest that plant protection is dependent on the physical presence ofB. subtilis M51 cells on the roots.     

Global molecular surveillance reveals novel Fusarium head blight species and trichothecene toxin diversity

To expand our knowledge of Fusarium head blight (FHB) pathogen and trichothecene toxin diversity, a global collection of 2100 isolates was screened for novel genetic variation, resulting in the identification of 16 phylogenetically divergent FHB isolates. The affinities and taxonomic status of these novel isolates were evaluated via phylogenetic analyses of multilocus DNA sequence data (13 genes; 16.3 kb/strain) together with analyses of their morphology, pathogenicity to wheat, and trichothecene toxin potential. Based on the results of these analyses, we formally describe two novel species (Fusarium vorosii and Fusarium gerlachii) within the Fusarium graminearum species complex (Fg complex), and provide the first published report of Fg complex isolates with either a nivalenol or 3-acetyldeoxynivalenol chemotype within the U.S. In addition, we describe a highly divergent population of F. graminearum from the Gulf Coast of the U.S., and divergent isolates of F. acaciae-mearnsii from Australia and South Africa.     

Molecular Characterization of Fusarium oxysporum f. melongenae by ISSR and RAPD Markers on Eggplant

Fusarium oxysporum f. melongenae is a major soil-borne pathogen of eggplant (Solanum melongena). ISSR and RAPD markers were used to characterize Fusarium oxysporum f. melongenae isolates collected from eggplant fields in southern Turkey. Those isolates were not pathogenic to tomato. Pathogens were identified by their morphology, and their identity was confirmed by PCR amplification using the specific primer PF02-3. The isolates were classified into groups on the basis of ISSR and RAPD fingerprints, which showed a level of genetic specificity and diversity not previously identified in Fusarium oxysporum f. melongenae, suggesting that genetic differences are related to the pathogen in the Mediterranean region. The primers selected to characterize Fusarium oxysporum f. melongenae may be used to determine genetic differences and pathogen virulence. This study is the first to characterize eggplant F. oxysporum species using ISSR and RAPD.     

Quantitative Fusarium spp. and Microdochium spp. PCR assays to evaluate seed treatments for the control of Fusarium seedling blight of wheat

AIMS: To develop sensitive quantitative PCR assays for the two groups of pathogens responsible for Fusarium seedling blight in wheat: Fusarium group (Fusarium culmorum and Fusarium graminearum) and Microdochium group (Microdochium nivale and Microdochium majus); and to use the assays to assess performance of fungicide seed treatments against each group. METHODS AND RESULTS: Primers conserved between the species within each group were used to develop competitive PCR assays and used to quantify DNA of each group in wheat seed produced from inoculated field plots. Seed was used in seed treatment efficacy field experiments and the amount of DNA of each group was determined in emerged seedlings. The performance of treatments towards each group of pathogens was evaluated by comparison of the reduction in DNA in seedlings emerged from treated seed compared with untreated seed. CONCLUSIONS: DNA from the two groups of pathogens causing Fusarium seedling blight of wheat can be quantified separately using the competitive PCR assays. These assays show improved sensitivity compared with those previously reported for the individual species and allowed the quantification of pathogen DNA in seed and seedlings. Significant reductions in pathogen DNA were evident for each seed treatment. SIGNIFICANCE AND IMPACT OF THE STUDY: Quantification of DNA for each group allows the evaluation of seed treatment performance towards the two components of Fusarium seedling blight disease complex. The approach taken and the assays developed in this study will be of use for the study of other Fusarium disease complexes and their control. Based on the results reported here on the seedling stage of crop development, further studies that examine the control of seed-borne pathogens through fungicide seed treatments throughout the growing season are warranted.     

兔防御素NP-1基因在转基因番茄中表达的初步研究

兔防御素ＮＰ－１是α－防御素的一种,含３３个氨基酸残基。最初从兔子的多形核嗜中性细胞中分离出来。它对革兰氏阴性菌、革兰氏阳性菌、分枝杆菌、真菌、被膜病毒以及ＨＩＶ病毒都有不同程度的抑制作用。兔防御素ＮＰ－１所带阳离子较多,可抗不具代谢活性的靶细胞。实验中将兔防御素ＮＰ－１基因构建到植物表达载体中,通过根瘤农杆菌介导转入番茄,得到了转基因番茄植株。对转基因番茄植株进行了ＰＣＲ、Ｓｏｕｔｈｅｍ杂交、Ｎ     

Response of endophytic bacterial communities in banana tissue culture plantlets to Fusarium wilt pathogen infection

Endophytic bacteria reside within plant hosts without having pathogenic effects, and various endophytes have been found to functionally benefit plant disease suppressive ability. In this study, the influence of banana plant stress on the endophytic bacterial communities, which was achieved by infection with the wilt pathogen Fusarium oxysporum f. sp. cubense, was examined by cultivation-independent denaturing gradient gel electrophoresis analysis of 16S ribosomal DNA directly amplified from plant tissue DNA. Community analysis clearly demonstrated increased bacterial diversity in pathogen-infected plantlets compared to that in control plantlets. By sequencing, bands most similar to species of Bacillus and Pseudomonas showed high density in the pathogen-treated pattern. In vitro screening of the isolates for antagonistic activity against Fusarium wilt pathogen acquired three strains of endophytic bacteria which were found to match those species that obviously increased in the pathogen infection process; moreover, the most inhibitive strain could also interiorly colonize plantlets and perform antagonism. The evidence obtained from this work showed that antagonistic endophytic bacteria could be induced by the appearance of a host fungal pathogen and further be an ideal biological control agent to use in banana Fusarium wilt disease protection.     

Coumarin Utilization Patterns of Pathogenic Races of Fusaarium oxysporum Causing Vascular Wilt of Cotton

Fifty-six isolates of Fusarium oxysporum from wilted cotton plants were characterized by (a) hydrolysis of aesculin and (b) utilization of the products glucose and aesculetin. Aesculin and aesculetin agars provided a simple in vitro test that enabled differentiation of pathogenic races of the cotton wilt pathogen.     

Showcasing the application of synchrotron‐based X‐ray computed tomography in host–pathogen interactions: The role of wheat rachilla and rachis nodes in Type‐II resistance to Fusarium graminearum

Fusarium head blight, caused primarily by Fusarium graminearum (Fg), is one of the most devastating diseases of wheat. Host resistance in wheat is classified into five types (Type‐I to Type‐V), and a majority of moderately resistant genotypes carry Type‐II resistance (resistance to pathogen spread in the rachis) alleles, mainly from the Chinese cultivar Sumai 3. Histopathological studies in the past failed to identify the key tissue in the spike conferring resistance to pathogen spread, and most of the studies used destructive techniques, potentially damaging the tissue(s) under study. In the present study, nondestructive synchrotron‐based phase contrast X‐ray imaging and computed tomography techniques were used to confirm the part of the wheat spike conferring Type‐II resistance to Fg spread, thus showcasing the application of synchrotron‐based techniques to image host–pathogen interactions. Seven wheat genotypes of moderate resistance to Fusarium head blight were studied for changes in the void space volume fraction and grayscale/voxel intensity following Fg inoculation. Cell‐wall biopolymeric compounds were quantified using Fourier‐transform midinfrared spectroscopy for all genotype‐treatment combinations. The study revealed that the rachilla and rachis nodes together are structurally important in conferring Type‐II resistance. The structural reinforcement was not necessarily observed from lignin deposition but rather from an unknown mechanism.     

植物来源的镰刀菌抗性相关基因

镰刀菌是植物的重要病原真菌,其入侵植物体可引起镰刀菌病害,给农作物和其它植物的生产带来极大的危害。植物是抗性基因的重要来源之一,随着分子生物学技术的飞速发展,大量的镰刀菌相关抗性基因和抗性候选基因从不同的植物中被分离和鉴定,并应用于抗镰刀菌基因工程育种。对植物来源的镰刀菌抗性基因的种类及其作用机理、抗病候选基因、拟南芥-镰刀菌互作机制及基因调控进行了概述。