A molecular diagnosis method using real-time PCR for quantification and detection of Fusarium oxysporum f. sp. cubense race 4

The Fusarium genus causes devastating plant diseases worldwide, in which Fusarium oxysporum is the most serious crop pathogen. Disease monitoring is the basis of integrated pest management of any disease. The lack of rapid, accurate, and reliable device to detect and identify plant pathogens is one of the main limitations in integrated disease management. This study describes an efficient and quantifiable diagnosis method for the specific detection of F. oxysporum f. sp. cubense (Foc) race 4 in field-infected banana. With the optimized PCR parameters using the SCAR (sequence characterized amplified region) primers FocSc-1/FocSc-2 and a real-time PCR strategy, the developed method showed high reproducibility and was very sensitive to detect extremely low quantities of Foc genomic DNA (gDNA). We also found that Foc gDNA in severely symptomatic banana pseudostems and leaves were 6946-fold and 26.69-fold more than in those of mild-symptomatic banana, respectively.     

A loop-mediated isothermal amplification (LAMP) assay based on unique markers derived from genotyping by sequencing data for rapid in planta diagnosis of Panama disease caused by Tropical Race 4 in banana

The socio-economic impact of Fusarium odoratissimum, which is colloquially called tropical race 4 (TR4), is escalating as this fungal pathogen spreads to new banana-growing areas. Hence, the development of simple, reliable and rapid detection technologies is indispensable for implementing quarantine measures. Here, a versatile loop-mediated isothermal amplification (LAMP) assay has been developed that is applicable under field and laboratory conditions. DNA markers unique to TR4 isolates were obtained by diversity arrays technology sequencing (DArTseq), a genotyping by sequencing technology that was conducted on 27 genotypes, comprising 24 previously reported vegetative compatibility groups (VCGs) and three TR4 isolates. The developed LAMP TR4 assay was successfully tested using 22 TR4 isolates and 45 non-target fungal and bacterial isolates, as well as on infected plants under greenhouse and field conditions. The detection limit was 1 pg µL⁻¹ pure TR4 DNA or 10² copies plasmid-localized TR4 unique sequence (SeqA) per reaction, which was not affected by background DNA in complex samples. The LAMP TR4 assay offers a powerful tool for the routine and unambiguous identification of banana plants infected with TR4, contributing to advanced diagnosis in field situations and monitoring of fusarium wilt.     

Development of a loop-mediated isothermal amplification assay for sensitive and specific detection of <Emphasis Type="Italic">Fusarium oxysporum</Emphasis> f. sp. <Emphasis Type="Italic">cucumerinum</Emphasis> Owen

Fusarium wilt, caused by Fusarium oxysporum f. sp. cucumerinum Owen (FOC), is a destructive disease affecting cucumber production worldwide. Developing an accurate and reliable method for detection of FOC is important for disease prediction and control. In this study, a loop-mediated isothermal amplification (LAMP) assay was developed and validated for specific and sensitive detection of FOC. Four LAMP primers were designed based on the sequence of the FOC-specific random amplified polymorphic DNA (RAPD) marker OPZ-12₈₆₅. LAMP reactions were performed at different temperatures and for different durations, and the optimal temperature and duration were 63 °C for 60 min, respectively. Hence, a LAMP assay for detection of FOC was established. The specificity of the LAMP method was evaluated against 119 isolates of FOC and other pathogens, and only FOC isolates yielded positive results. In sensitivity tests, the lowest concentration of genomic DNA required for the LAMP assay was 10 fg in a 25 μL reaction. The LAMP assay was successfully applied to detect FOC in cucumber tissues and soil from infested fields, and the positive ratios of LAMP, PCR, and traditional tissue isolation for detecting FOC from diseased cucumber root samples were100%, 86.6 and 83.3%, respectively. Therefore, the LAMP assay developed herein should serve as a simple, cost-effective, rapid, highly specific, and sensitive tool for the visual detection of FOC and contribute to improved disease management.     

Development of a molecular marker for specific detection of <Emphasis Type="Italic">Fusarium oxysporum</Emphasis> f. sp. <Emphasis Type="Italic">cubense</Emphasis> race 4

Fusarium oxysporum f. sp. cubense is the causal agent of Panama disease of banana. A rapid and reliable diagnosis is the foundation of integrated disease management practices in commodity crops. For this diagnostic purpose, we have developed a reliable molecular method to detect Foc race 4 isolates in Taiwan. By PCR amplification, the primer set Foc-1/Foc-2 derived from the sequence of a random primer OP-A02 amplified fragment produced a 242 bp size DNA fragment which was specific to Foc race 4. With the optimized PCR parameters, the molecular method was sensitive and could detect small quantities of Foc DNA as low as 10 pg in 50 to 2,000 ng host genomic DNA with high efficiency. We also demonstrated that by using our PCR assay with Foc-1/Foc-2 primer set, Foc race 4 could be easily distinguished from other Foc races 1 and 2, and separated other formae speciales of F. oxysporum. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Detection of Pythium aphanidermatum in tomato using loop-mediated isothermal amplification (LAMP) with species-specific primers

A loop-mediated isothermal amplification (LAMP) reaction with a primer set designed from the rDNA ITS sequence of P. aphanidermatum was developed. Results of a specificity test using 57 strains of Pythium spp. indicated that the LAMP assay gave no cross reactions in other 39 Pythium species, 11 strains of Phytophthora spp. and eight other soil borne pathogens. The detection limit was 10 fg of genomic DNA, which was ten times the sensitivity of the polymerase chain reaction. The LAMP assay was applied to hydroponic solution samples from tomato fields, and the results were compared to those of the conventional plating method. LAMP was observed to be effective for the specific detection of P. aphanidermatum. Furthermore, P. aphanidermatum was detected directly in tomato roots infected with P. aphanidermatum without DNA extraction. The LAMP method established in this study is a simple, sensitive and rapid tool for the detection of P. aphanidermatum.     

Visual detection of <Emphasis Type="Italic">Didymella bryoniae</Emphasis> in cucurbit seeds using a loop-mediated isothermal amplification assay

A method was developed using a Loop-mediated isothermal amplification assay (LAMP) for detecting Didymella bryoniae in cucurbit seeds. The LAMP primers were designed based on the DNA-dependent RNA polymerase II RPB140 gene (RPB2) from D. bryoniae. Calcein was used as an indicator for the endpoint visual detection of DNA amplification. The LAMP assay was conducted in isothermal (65 °C) conditions within 1 h. The detection threshold of the LAMP assay was 10 pg of genomic DNA and D. bryoniae was detected in 100 % of artificially infested seedlots with 0.05 % infestation or greater. With the LAMP assay, 16 of 60 watermelon and muskmelon seedlots collected from Xinjang province were determined to be positive for D. bryoniae. In contrast, a real-time PCR assay determined that 11 of the 60 seedlots from Xinjiang province were positive for the pathogen. These results showed that the LAMP technique was simple, rapid and well suited for detecting D. bryoniae DNA, especially in seed health testing.     

A molecular diagnostic for tropical race 4 of the banana fusarium wilt pathogen

This study analysed genomic variation of the translation elongation factor 1α (TEF‐1α) and the intergenic spacer region (IGS) of the nuclear ribosomal operon of Fusarium oxysporum f. sp. cubense (Foc) isolates, from different banana production areas, representing strains within the known races, comprising 20 vegetative compatibility groups (VCG). Based on two single nucleotide polymorphisms present in the IGS region, a PCR‐based diagnostic tool was developed to specifically detect isolates from VCG 01213, also called tropical race 4 (TR4), which is currently a major concern in global banana production. Validation involved TR4 isolates, as well as Foc isolates from 19 other VCGs, other fungal plant pathogens and DNA samples from infected tissues of the Cavendish banana cultivar Grand Naine (AAA). Subsequently, a multiplex PCR was developed for fungal or plant samples that also discriminated Musa acuminata and M. balbisiana genotypes. It was concluded that this diagnostic procedure is currently the best option for the rapid and reliable detection and monitoring of TR4 to support eradication and quarantine strategies.     

Sequence variation in the putative effector gene SIX8 facilitates molecular differentiation of Fusarium oxysporum f. sp. cubense

Fusarium oxysporum f. sp. cubense (Foc), causal agent of fusarium wilt of banana, is among the most destructive pathogens of banana and plantain. The development of a molecular diagnostic capable of reliably distinguishing between the various races of the pathogen is of key importance to disease management. However, attempts to distinguish isolates using the standard molecular loci typically used for fungal phylogenetics have been complicated by a poor correlation between phylogeny and pathogenicity. Among the available alternative loci are several putative effector genes, known as SIX genes, which have been successfully used to differentiate the three races of F. oxysporum f. sp. lycopersici. In this study, an international collection of Foc isolates was screened for the presence of the putative effector SIX8. Using a PCR and sequencing approach, variation in Foc‐SIX8 was identified which allowed race 4 to be differentiated from race 1 and 2 isolates, and tropical and subtropical race 4 isolates to be distinguished from one another.     

大蕉枯萎病病原菌鉴定及TEF-1α序列分析

 近年来,大蕉枯萎病在广东省东莞市发生严重,为了有效控制病害发生蔓延,生产上急需明确大蕉枯萎病的病原。本研究收集了我国华南地区的12株大蕉枯萎病病原菌及19株包括1号及4号生理小种的单孢菌株,以来源于澳大利亚的1号、2号、3号和亚热带4号生理小种以及4株非病原尖孢镰孢菌作对照,通过病原菌形态鉴定、致病性测定、4号小种(Foc 4)及热带4号小种(TR4)的分子特异检测、以及基于翻译延伸因子(TEF-1α)序列的系统发育分析,对大蕉枯萎病病原菌进行鉴定。同时,对我国华南地区不同来源的香蕉枯萎病病原菌的遗传发育关系及致病性分化情况进行了研究。结果表明:(1)引起大蕉枯萎病的病原菌主要是1号生理小种或者是与1号生理小种亲缘关系较近的一个新的系统发育谱系,该谱系可能为 1 号生理小种变异演化而来;(2)大蕉枯萎病病原菌对大蕉和粉蕉都有较强的致病力,但不能侵染香蕉;我国的1号小种存在一定的分化,其中有一个类群只能感染粉蕉,另一个类群既能感染粉蕉也能感染大蕉;(3)大蕉与粉蕉枯萎病的病原菌在致病性及遗传发育关系上都存在一定的交叉和分化。     

Rapid detection of Fusarium oxysporum f. sp. lactucae on soil,lettuce seeds and plants using loop‐mediated isothermal amplification

Fusarium oxysporum f. sp. lactucae (FOL) is a soil‐ and seedborne pathogen and the causal agent of fusarium wilt on lettuce. Four races have been identified within FOL, with different worldwide distribution. Several molecular techniques have been used to detect and identify this pathogen; however, not all of them have the optimal characteristics in terms of sensitivity to perform FOL detection in plant and seed material. A loop‐mediated isothermal amplification (LAMP) assay was developed based on the sequence‐characterized amplified region (SCAR) obtained in a previous rapid amplification of polymorphic DNA (RAPD) study. The LAMP assay has been validated according to the EPPO standard PM7/98. The LAMP assay was tested with lettuce seeds, soil and plant material, and can be used successfully to amplify DNA from each of these matrices. In seed lots artificially inoculated with FOL, the detection limit of the LAMP test was 0.004% infected seed.     

香蕉条斑病毒LAMP快速检测方法的建立

 环介导等温扩增（loop-mediated isothermal amplification,LAMP）是一种特异、灵敏、快速的新型基因检测技术。本研究以香蕉条斑病毒（Banana streak virus,BSV）ORF3保守区域为基础针对6个特定区域设计并筛选了4条LAMP扩增引物,通过对LAMP反应中MgSO₄、dNTPs、Betaine等主要试剂浓度进行优化,建立了香蕉BSV的LAMP检测方法,63℃反应90 min后通过在反应产物中添加SYBR Green Ⅰ染料后颜色的变化,肉眼即可判断检测结果。LAMP具有极高的检测特异性和灵敏性,其检测下限约为3.2 ng·μL^-1,是PCR检测灵敏度的25倍,能快速、准确地对疑似样品进行检测,本研究对华南地区部分疑似样品的检测结果显示LAMP阳性检出率比PCR检出率高。本文建立的BSV LAMP检测方法是对BSV检测方法的拓展和延伸,为香蕉病毒的快速检测提供技术保障。     

Development and evaluation of a loop-mediated isothermal amplification assay for detection of Erwinia amylovora based on chromosomal DNA

A reliable and rapid pathogen detection protocol that utilizes loop-mediated isothermal amplification (LAMP) was developed for detection of Erwinia amylovora, the casual agent of fire blight. The six LAMP primers applied were derived from the highly conserved fragment of the chromosomally amsH gene. Despite the proposed LAMP as well as nested PCR presenting equal values of sensitivity (2?×?10¹?CFU/ml or more) for pure cultures, as compared with conventional PCR (2?×?10³?CFU/ml), both methods were together superior. The specificity assay also showed that the LAMP protocol is species-specific for detection of E. amylovora even in inter-species analysis. Meanwhile, when all 208 naturally infected samples were examined, the specificity value of LAMP was 84%, while conventional and nested PCR could detect only 59% and 73% of the whole collection. Significantly, an independent behaviour versus host plant as well as each strain origin was also observed regarding the current LAMP method as well as other two PCR-based methods. All the results, overall, indicated that the LAMP offers an interesting novel and convenient assay format for the quick and specific chromosomal detection and diagnostic tool of recognition of E. amylovora and therefore presents an alternative to PCR-based assays.     

Nonspecific toxins as components of a host‐specific culture filtrate from Fusarium oxysporum f. sp. cubense race 1

Bananas and plantains (Musa spp.) are among the most important crops in the world providing staple food for hundreds of millions of people. However, banana production has been devastated by fungal infestations caused by Fusarium oxysporum f. sp. cubense (Foc). Despite the fact that there is very little known on the role of microbial metabolites in the molecular mechanism of Foc infections, it has been proposed that the toxins fusaric acid and beauvericin produced by Foc play an important role during pathogenesis. The aim of this contribution was to study the toxic components of culture filtrates (CF) of Foc and to isolate the extracellular microbial metabolites involved in the plant response. An in vitro bioassay was used to evaluate the production of phytotoxic metabolites as well as the specificity of culture from a strain of Foc belonging to VCG 01210 (race 1). A host‐specific CF was obtained and the phytotoxic compounds characterized as fusaric acid, beauvericin and fumonisin B1. Despite the presence of these nonspecific toxins, a water‐soluble extract from the CF induced protection to the main phytotoxic fraction, measured by lesion area. This hydrophilic fraction induced a fast and strong response of just jasmonic acid (JA)‐dependent defence genes rather than salicylic acid (SA)‐ and ethylene (ET)‐response genes in resistant cultivars. Extracellular proteins isolated from CF of Foc provide an important source for further investigations on the molecular basis of the interaction between Foc and banana.     

Rapid loop-mediated isothermal amplification assays for grapevine yellows phytoplasmas on crude leaf-vein homogenate has the same performance as qPCR

A fluorescence-based real-time loop-mediated isothermal amplification (LAMP) assay for ‘Candidatus Phytoplasama solani’ (Bois noir phytoplasma; BNp) detection was developed and optimised for rapid laboratory and on-site BNp detection. This assay is highly specific, rapid and as sensitive as qPCR. It was validated according to European and Mediterranean Plant Protection Organisation recommendations. In addition, 286 grapevine leaf samples from the 2015 growing season were tested with this new real-time LAMP assay and an assay previously developed for detection of Flavescence dorée phytoplasma (FDp). These LAMP assays for detection of both BNp and FDp used without any DNA extraction step, which is a required step for qPCR analysis, were comparably effective to qPCR, and positive results were obtained in less than 35 min.     

Rapid diagnosis of soybean anthracnose caused by <Emphasis Type="Italic">Colletotrichum truncatum</Emphasis> using a loop-mediated isothermal amplification (LAMP) assay

A loop-mediated isothermal amplification (LAMP) assay that directly detects Colletotrichum truncatum in diseased soybean tissues is described, thus allowing rapid diagnosis of soybean anthracnose. Using the target gene Rpb1 (that codes for the large subunit of RNA polymerase II), we designed and screened a set of species-specific primers allowing amplification at 62 °C over 70 min. After addition of SYBR Green I to the LAMP reaction products, a yellow-green color (visible to the unaided eye) developed only in the presence of C. truncatum. The detection limit of the LAMP assay was 100 pg (per μL genomic DNA). The Rpb1-Ct-LAMP assay has been successfully used to diagnose soybean anthracnose in field samples collected from Jiangsu, Anhui and Hubei provinces of China, and to detect C. truncatum in soybean seeds from farmers’ markets. Our results show that the Rpb1-Ct-LAMP assay is a useful and convenient method for detecting C. truncatum, and thus for diagnosis of soybean anthracnose.     

A loop mediated isothermal amplification (LAMP) assay for rapid and reliable detection of <Emphasis Type="Italic">Anguina wevelli</Emphasis>, a grass parasitic nematode

Anguina wevelli is a pathogenic grass parasitic nematode, however it is difficult to identify based simply on morphology. This study developed a loop-mediated isothermal amplification (LAMP) assay to detect A. wevelli. The LAMP method developed could specifically detect A. wevelli in 45 min, and the detection limit was 1/80000 of the total DNA extracted from a single juvenile (J2), an equivalent of 2.5 pg of DNA. This is the first report of the detection of Anguina spp. by using a LAMP-based method.     

Development and evaluation of specific PCR and LAMP assays for the rapid detection of Phytophthora melonis

Phytophthora melonis is a widespread and devastating pathogen for the Cucurbitaceae family. Early and accurate detection of P. melonis is essential to control the disease in the field. To establish a simple, visual, and rapid detection system for P. melonis, we developed nested polymerase chain reaction (PCR) and loop-mediated isothermal amplification (LAMP) systems based on the Ras-related protein (Ypt1) gene. All 36 isolates of P. melonis, from geographically distinct counties in China, yielded positive detection results on LAMP or nested PCR assays. No cross reaction was observed with other oomycetes or fungal pathogens. A sensitivity assay showed that both methods had a detection limit of 10 fg genomic DNA. We also detected P. melonis in diseased cucumber tissues and soils, and evaluated positive detection rates using LAMP, nested PCR, and conventional isolation methods. The results suggest that the LAMP assay has the greatest potential for active detection of P. melonis in regions that are at risk of contracting the disease, and for use in resource-poor settings.     

Back to the roots: Understanding banana below-ground interactions is crucial for effective management of Fusarium wilt

Global banana production is affected by Fusarium wilt, a devastating disease caused by the soilborne root-infecting fungus, Fusarium oxysporum f. sp. cubense (Foc). Fusarium wilt is notoriously difficult to manage because infection arises through complex below-ground interactions between Foc, the plant, and the soil microbiome in the root–soil interface, defined as the rhizosphere. Interactions in the rhizosphere play a pivotal role in processes associated with pathogen development and plant health. Modulation of these processes through manipulation and management of the banana rhizosphere provides an auspicious prospect for management of Fusarium wilt. Yet, a fundamental understanding of interactions in the banana rhizosphere is still lacking. The objective of this review is to discuss the state-of-the-art of the relatively scant data available on banana below-ground interactions in relation to Fusarium wilt and, as a result, to highlight key research gaps. Specifically, we seek to understand (a) the biology of Foc and its interaction with banana; (b) the ecology of Foc, including the role of root-exuded metabolites in rhizosphere interactions; and (c) soil management practices and how they modulate Fusarium wilt. A better understanding of molecular and ecological factors influencing banana below-ground interactions has implications for the development of targeted interventions in the management of Fusarium wilt through manipulation of the banana rhizosphere.     

香蕉枯萎病菌myosin-1基因的功能分析及外施dsRNA介导的抗性评估

 香蕉枯萎病是由尖孢镰刀菌古巴专化型(Fusarium oxysporum f. sp. cubense,Foc)引起的香蕉毁灭性土传病害,其中 4号生理小种(Foc4)能感染几乎所有的香蕉品系,危害最严重。SMART在线软件分析myosin-1基因具有肌球蛋白马达蛋白(myosin motor domain, MMD),肌动蛋白尾结构TH1(myosin tail)和 Src家族同源结构域SH3(src homology domain 3),与禾谷镰刀菌中氰烯菌酯靶标基因myosin-5具高度的蛋白同源性,相似性高达83%。利用Split-marker基因重组技术获得Foc4的myosin-1基因敲除突变体,Δmyosin-1突变株丧失了对氰烯菌酯的敏感性,菌丝生长缓慢,产孢量减少且孢子畸形,对香蕉致病力严重下降,证实myosin-1是氰烯菌酯在Foc4中的作用靶标基因。外施靶向myosin-1体外转录的dsRNA,能抑制菌丝的生长,降低菌丝活性;菌丝膨胀扭曲分枝增多,出现典型的球状结构,与氰烯菌酯处理后的表型一致。在盆栽活体人工接种实验中,体外施用dsRNA可以明显抑制枯萎病外部症状的发展,推迟发病时间,赋予寄主抗性,结果说明体外施用dsRNA可以作为新型杀菌剂防治香蕉枯萎病。综上,myosin-1基因作为氰烯菌酯在Foc4中的靶标基因具有高度的序列保守,在调控菌丝生长发育,产孢以及致病力等方面发挥重要作用,而外施dsRNA具有防治香蕉枯萎菌的巨大潜力。     

Vertical distribution of resting spores of <Emphasis Type="Italic">Plasmodiophora brassicae</Emphasis> in soil

Pratylenchus zeae parasitizes various crops and damages the host roots, resulting in decreased yield and quality of the host plants. Alignments of mitochondrial DNA (mtDNA) Cytochrome Oxidase I (COΙ) sequences revealed the genetic variation among Pratylenchus species. The results indicated 0.2–2.4% intraspecific variations for mtDNA COI sequences among eight P. zeae populations, and 25.4–35.1% interspecific variations between P. zeae and other Pratylenchus species. Based on the mtDNA COΙ region, a loop-mediated isothermal amplification (LAMP) assay was developed for the rapid and specific detection of P. zeae. The optimal conditions for the LAMP assay were 64 °C for 40 min. The LAMP products were confirmed using conventional polymerase chain reaction (PCR), analysis with the restriction enzyme Bam HI and visual inspection by adding SYBR Green I to the products. The LAMP assay could detect P. zeae populations from different hosts and different geographical origins specifically. The LAMP assay was also sensitive, detecting 0.1 individual P. zeae, which was 10 times more sensitive than conventional PCR. This is the first report of the detection of Pratylenchus spp. using LAMP. In addition, the results also suggested that use of the COI gene might allow for good resolution at the Pratylenchus species level.