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.     

Development of a loop-mediated isothermal amplification assay for rapid and sensitive detection of Fusarium oxysporum f. sp. cubense race 4

Fusarium wilt (Panama disease), caused by the fungus Fusarium oxysporum f. sp. cubense race 4 (Foc race 4), is one of the most destructive diseases affecting banana (Musa). Early and accurate detection of Foc race 4 is essential to protect the banana industry. We developed a novel and highly specific loop-mediated isothermal amplification (LAMP) assay for the detection of Foc race 4 based on a SCAR marker sequence. The detection limit for this assay was 10 fg per 25 μl reaction in pure culture and DNA amplification was completed within 60 min. The assays detected 69 different isolates of Foc race 4 from geographically distinct counties in China, and no cross-reaction was observed with other fungal pathogens. When 26 infected and eight healthy looking but infested banana samples naturally from different fields were examined, the detection rate of LAMP was 100 %. The LAMP assay developed in this study was simple, fast, sensitive, and specific, and can be used in the field to detect Foc race 4 in infected banana plant tissue 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.     

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.     

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.     

Comparative analysis of pathogenic and nonpathogenic Fusarium oxysporum populations associated with banana on a farm in Minas Gerais,Brazil

Fusarium wilt is one of the most devastating diseases on banana. The causal agent, Fusarium oxysporum f. sp. cubense (Foc) is genetically diverse and its origin and virulence are poorly understood. In this study, pathogenic Foc isolates and nonpathogenic F. oxysporum isolates from Minas Gerais in Brazil were compared using EF‐1α and IGS sequences. This allowed the examination of the origin and evolutionary potential of Foc in a country outside the region of origin of the banana plant. Two different sequence types were found among Foc isolates. One appeared to be of local origin because it was identical to the sequence type of the largest group of nonpathogenic isolates. To explore if the ‘local’ Foc isolates had acquired pathogenicity either independently through coevolution with the host, or through horizontal gene transfer (HGT) of pathogenicity genes from other, probably introduced, Foc isolates, the presence and sequence of putative SIX effector genes were analysed. Homologues of SIX1, SIX3 and SIX8 were found. SIX1 sequences were identical and exclusively found in all pathogenic isolates, while variable ratios of sequences of multicopy gene SIX8 were found among nonpathogenic and different pathogenic isolates. This observation supports the HGT hypothesis. Horizontal transfer of genes between isolates of F. oxysporum has important implications for the development of reliable diagnostic tools and effective control measures. Full genome sequencing is required to confirm HGT and to further unravel the virulence mechanisms of forma specialis cubense.     

Fusarium oxysporum f. sp. canariensis: evidence for horizontal gene transfer of putative pathogenicity genes

Fusarium wilt is a serious disease of the date palm Phoenix canariensis, caused by Fusarium oxysporum f. sp. canariensis (Foc). A previous study that characterized and compared the genetic diversity of the Australian Foc population with international strains suggested that the Australian population may have had an independent evolutionary origin. The current study compared the species phylogeny of the Australian and international populations and determined that Foc is not monophyletic, separating into three supported lineages across the two phylogenetic species of the Fusarium oxysporum species complex. This confirms an independent evolutionary origin for Foc in Australia. However, phylogenetic analysis of the putative pathogenicity genes Secreted In Xylem (SIX) did not reveal any separation of the Australian and international Foc strains. Furthermore, there was very low SIX sequence diversity within Foc. Horizontal gene transfer is argued to be the most parsimonious explanation for the incongruence between the species and SIX gene phylogenies.     

Detection and quantification of Fusarium oxysporum f. sp. cucumerinum in environmental samples using a specific quantitative PCR assay

The rapid and reliable identification and quantification of pathogens is essential for the management of economically important plant diseases. Fusarium oxysporum f. sp. cucumerinum is the soil borne fungus responsible for Fusarium vascular wilt of cucumber. In this study, we report the development of a specific and reliable real-time quantitative PCR assay and the development of an ultra-sensitive diagnostic pseudo-nested PCR assay. The capacity of the PCR assays to accurately identify and quantify Fusarium oxysporum f. sp. cucumerinum was experimentally tested by the development of standard curves from serial dilutions of copy numbers in a range of complex environmental DNA samples. The amplification efficiency, sensitivity and reproducibility of the qPCR assays were not significantly affected by the presence of any of the non-target background DNA tested. In quantitative real-time PCR, as few as 100 copies could be reliably quantified, and in simple and pseudo-nested PCR as little as 10 pg and 10 fg, respectively, could be detected. This rapid and sensitive qPCR method can be used to facilitate investigations into plant–pathogen interactions, epidemiology, and disease management practices.     

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.     

Fusarium wilt of banana: biology,epidemiology and management

Fusarium oxysporum is a soil borne hyphomycete that causes vascular wilts in several crop plants. A variety of remedial measures such as the use of fungicides, soil amendments and biological antagonists have proved insufficient in controlling F. oxysporum. Ever since it was first reported in banana crop, the only effective control strategy known is planting of resistant cultivars. However, presumably due to the high mutation rates and rapid co-evolution with its host, Fusarium wilt has surmounted host defense barriers and has already begun infecting even the resistant Cavendish varieties that dominate export markets worldwide. Transgenic banana plants showing enhanced resistance to Fusarium wilt have been developed in recent past, but they remain largely confined to the laboratory. The importance of banana as source of food and income in developing countries world over and the need to develop Fusarium wilt tolerant cultivars by novel biotechnological approaches is detailed herein. In this communication, we review the biology and management of Fusarium wilt in banana with the aim of providing the baseline of information to encourage much needed research on integrated management of this destructive banana crop disease problem.     

Panama disease of banana occurred in Miyakojima Island,Okinawa, Japan

In 2016, in Miyakojima, Okinawa, Japan, banana plants (Musa?×?paradisiaca) ‘Shima-banana’ developed yellowing and wilt associated with vascular discoloration of the pseudostems. Fusarium oxysporum, identified based on morphological characters, was frequently isolated from the vascular tissue of the infected plant and reproduced the original symptoms on ‘Shima-banana’ after drench inoculation with a spore suspension. Thereby, we determined that the disease is Panama disease caused by F. oxysporum. This is the first official report of Panama disease (Panama-byo in Japanese) of banana in Japan.     

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。     

Genetic structure of Fusarium oxysporum f. sp. cubense in different regions from Brazil

Panama disease, caused by Fusarium oxysporum f. sp. cubense (Foc), is ranked among the most destructive diseases of banana. The use of resistant varieties is the most desirable and effective control measure. Information on the pathogen population structure is essential, as durability of the resistance and effective cultivar deployment are strongly linked to this structure. In this study, 214 Foc isolates from different banana producing states in three regions of Brazil (northeastern, southeastern and southern) were analysed. Initially, nine microsatellite markers (SSR) were tested, which revealed 52 distinct haplotypes distributed in the different geographical regions and cultivars. While amova analysis showed that 68·01% of the total variation occurred within states, correlation between genetic and geographical distances was only found in the southern region. Results indicated that isolates from different states comprise a single population, which is predominantly clonal. When isolates representing different haplotypes were inoculated in four banana cultivars, differences in severity were found, with the high severity values being caused by isolates from haplotypes H7, H31 and H41. The diversity found here points to the need for additional studies, as this characteristic may be related to Foc's evolutionary potential and possibly to its ability to overcome the resistance from breeding programme‐generated cultivars. This is the most comprehensive study on population biology of Foc in Brazil.     

Resistance sources to Fusarium oxysporum f. sp. cubense tropical race 4 in banana wild relatives

Target trait evaluation in crop wild relatives is an important prerequisite for efficiently using the potential useful genes located in this valuable germplasm. Over recent decades, Fusarium oxysporum f. sp. cubense tropical race 4 (Foc‐TR4) has seriously threatened worldwide banana plantations. Breeding new resistant cultivars from wild banana species is expected to provide invaluable additional resources. However, knowledge on resistance to Foc‐TR4 in wild Musa species is very limited. In this study, eight genotypes of wild banana relatives (Musa acuminata subsp. burmannica, M. balbisiana, M. basjoo, M. itinerans, M. nagensium, M. ruiliensis, M. velutina and M. yunnanensis) were characterized for resistance to Foc‐TR4 in both greenhouse and field conditions. Most wild bananas showed higher resistance levels to Foc‐TR4 than the reference cultivars ‘Brazilian’ (AAA, susceptible) and ‘Goldfinger’ (AAAB, moderate resistance). Among the wild species, M. balbisiana showed the highest levels of disease intensity followed by M. acuminata subsp. burmannica. Some individuals of M. yunnanensis, M. nagensium, M. ruiliensis and M. velutina showed low levels of rhizome discolouration in greenhouse conditions, but were resistant in the field. No symptoms were observed on M. basjoo and M. itinerans, suggesting higher levels of resistance to Foc‐TR4. The results revealed different sources of resistance to Foc‐TR4 in banana wild relatives, which constitute a valuable genetic resource for banana breeding programmes aiming to produce cultivars resistant to fusarium wilt.     

Development of molecular markers and probes based on TEF-1α, β-tubulin and ITS gene sequences for quantitative detection of Fusarium oxysporum f. sp. ciceris by using real-time PCR

Fusarium wilt (Fusarium oxysporum f. sp. ciceris) causes significant yield losses in chickpea worldwide. Faster, reliable and more specific molecular detection techniques were developed for the detection of Fusarium oxysporum f. sp. ciceris (Foc). The sequences obtained from multiple alignments of target genes, namely, translation elongation factor-1α (TEF-1α), β-tubulin, and internal transcribed spacer (ITS), were used to design Foc-specific markers/probes. One set of TEF-1α-based molecular marker, namely, SPα-F and R, two sets of β-tubulin-based markers, namely, SPβ1-F and R, and SPβ2-F and R, and one set of ITS gene, namely, SPT-F and R, were developed for the detection and quantification of Foc from diverse samples. The specificity and sensitivity of the designed molecular markers were evaluated through conventional and real-time PCR assays which differentiated the Foc from closely related species of Fusarium and other plant pathogens. In conventional PCR, the minimum detection limits of the markers ranged from 12.5 pg to 100 pg for genomic DNA of Foc and 0.5 ng to 10 ng for infected plant samples. In real-time PCR assay, the minimum detection limits of the markers ranged from 0.001 pg to 0.25 pg for genomic DNA of Foc and from 0.04 pg to 1.5 pg for the infected plant samples. Thus, the markers designed in the present study were found to be specific for Foc and can be used consistently for the detection and identification of Foc isolates. The probes developed from the two sets of markers, namely, SPα and SPβ2, also showed specificity with Foc.     

Functional analysis of the G-protein α subunits FGA1 and FGA3 in the banana pathogen Fusarium oxysporum f. sp. cubense

The asexual fungus Fusarium oxysporum f. sp. cubense (Foc) is the causal agent of fusarium wilt in bananas (Musa spp.). This fungus poses a threat to banana production throughout the world. Here, two Foc genes, fga1 and fga3, were functionally characterized. These genes encode proteins homologous to the G-protein α subunits GPA1 from Saccharomyces cerevisiae and MAGC from Magnaporthe grisea, respectively. The deletion of fga1 leads to a phenotypic defect in colony morphology and reductions in vegetative growth, conidiation and pathogenicity against the banana plant (Musa spp. cv. Brazil), which was not observed for the Δfga3 deletion mutant. Intriguingly, both Δfga1 and Δfga3 deletion mutants showed declines in intracellular cyclic AMP levels and increases in heat resistance, suggesting that FGA1 regulates growth, development, pathogenicity, and heat resistance, whereas FGA3 modulates heat resistance, potentially through the cAMP-dependent protein kinase A pathway. These findings offer insights into the roles of the G-protein α subunits in the development and pathogenicity of the fungus Foc.     

Evaluating the potential of soil management to reduce the effect of Fusarium oxysporum f. sp. cubense in banana (Musa AAA)

European Journal of Plant Pathology - Fusarium oxysporum f. sp. cubense (Foc) causes Fusarium wilt in banana (Musa AAA). Foc Race 1 devastated the subgroup Gros Michel during the first half of the...     

Carnation Fusarium wilt suppression in four composts

Fusarium wilt is now a major disease of carnation crops worldwide. Methyl bromide, which is used to remedy it, is environmentally unsafe. An alternative approach integrated into biological control is to grow crops in suppressive media. Suppressiveness of seven plant growth media to Fusarium oxysporum f. sp. dianthi was evaluated in bioassays with carnation (Dianthus cariophyllus) cv. Medea. These media were: (1) grape marc compost, (2) cork compost, (3) olive oil husk + cotton gin trash composted and mixed with rice husk, (4) spent mushroom compost mixed with peat, (5) coir fibre, (6) light peat and (7) vermiculite. In order to look for carnation Fusarium wilt suppressiveness indicators, growth medium pH and β-glucosidase activity were evaluated. Furthermore, F. oxysporum populations were measured in plant growth media at the beginning and end of bioassays. The compost media showed a range of suppressiveness in comparison with peat. Grape marc compost was the most effective plant growth medium in suppressing carnation Fusarium wilt. On the other hand coir fibre, peat and vermiculite were conducive for this disease. β-glucosidase activity and pH were positively correlated with disease severity as in other reports for tomato. Therefore, these two parameters are good indicators for carnation Fusarium wilt suppressiveness, and possibly for other F. oxysporum pathosystems. All composts showed similar F. oxysporum populations at the end of the bioassays to peat and vermiculite.     

Molecular characterization of Fusarium oxysporum f.sp. cichorii pathogenic on chicory (Cichorium intybus)

Fusarium oxysporum is a ubiquitous soilborne ascomycete responsible for vascular wilt in many plant species worldwide. This species comprises more than 120 putative host-specific formae speciales capable of causing marked economic losses. In summer 2009, wilt symptoms, including chlorosis and poor development of the root system, were observed on cultivars of chicory (Cichorium intybus) in northern Italy. The causal agent isolated from symptomatic tissues in this case was identified as F. oxysporum on the basis of both morphological features and molecular analyses. In this work, we attempted to characterize the isolates of F. oxysporum from C. intybus by both biological and molecular approaches. Pathogenicity trials performed on five species of the Asteraceae family with isolates of F. oxysporum from C. intybus indicated that the pathogen has a unique host range, infecting chicory only. Neither lettuce nor endive, lawn daisy or Paris daisy developed the disease. Five cultivars within C. intybus species were tested, and the cv. ??Clio?? was the most susceptible. Phylogenetic analyses relative to the ribosomal intergenic spacer (IGS) and translation elongation factor 1-alpha (EF1-??) assigned isolates pathogenic to chicory to a single cluster, distinct from other pathogenic F. oxysporum. In light of these findings, we propose to designate this organism as Fusarium oxysporum f.sp. cichorii.