Comparative analysis uncovers the limitations of current molecular detection methods for Fusarium oxysporum f. sp. cubense race 4 strains

Authors: Freddy Magdama ^aff001; Lorena Monserrate-Maggi ^aff002; Lizette Serrano ^aff002; Daynet Sosa ^aff002; David M. Geiser ^aff001; María del Mar Jiménez-Gasco ^aff001
Authors place of work: Department of Plant Pathology and Environmental Microbiology, The Pennsylvania State University, University Park, Pennsylvania, United States of America ^aff001; Escuela Superior Politécnica del Litoral, ESPOL, Centro de Investigaciones Biotecnológicas del Ecuador, Campus Gustavo Galindo, Guayaquil, Ecuador ^aff002; Escuela Superior Politécnica del Litoral, ESPOL, Facultad de Ciencias de la Vida, Campus Gustavo Galindo, Guayaquil, Ecuador ^aff003
Published in the journal: PLoS ONE 14(9)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0222727

Summary

Fusarium oxysporum f. sp. cubense Tropical Race 4 (Foc TR4) is threatening banana production worldwide. Despite quarantine efforts, the pathogen continues to spread; thus, early diagnosis plays an essential role for the proper execution of contingency plans. Here, we assess the accuracy of four PCR-based molecular methods described in the literature for the identification and detection of race 4 strains, including Subtropical (Foc STR4) and Tropical Race 4 causing Fusarium wilt of banana. We screened a total of 302 isolates using these four markers, and performed phylogenetic analyses, Vegetative Compatibility Group (VCG) testing, sequence comparison, and pathogenicity tests for selected isolates. Our results show that three out of the four markers tested are not reliable for identification of Foc STR4 and TR4, as DNA from isolates from Ecuador, pathogenic and nonpathogenic to banana, obtained from different banana cultivars, displayed cross-reaction with these methods; that is, false positives can occur during the diagnostic process for race 4. Phylogenetic analyses, VCG testing, sequence comparison, and pathogenicity tests suggest the presence of non-target F. oxysporum isolates that share genomic regions with pathogenic strains but lack true pathogenicity to banana. The findings of this work are of foremost importance for international regulatory agencies performing surveillance tests in pathogen-free areas using the current diagnostic methods. We suggest the use of a genetic locus possibly related to virulence, previously identified by T-DNA, and amplified with primers W2987F/ W2987R, for diagnosis of Foc TR4 as the most reliable alternative. We urge the adoption of a more holistic view in the study of F. oxysporum as a plant pathogen that considers the biology and diversity of the species for the development of better diagnostic tools.

Keywords:

Phylogenetic analysis – Polymerase chain reaction – DNA sequence analysis – Fusarium – Pathogenesis – Bananas – Fusarium oxysporum – DNA isolation

Introduction

Bananas rank amongst the world’s most valuable primary agricultural commodity and are one of the top ten most important staple foods for countries in Southeast Asia, Africa, and Central and South America [1]. In 2013, the combined global production of bananas, including dessert and cooking bananas was approximately 140 million tons with a gross production value of USD $44.75 billion [1]. Most of this production, around 85%, is destined for local trade and family consumption, while the remaining 15% (worth USD $10.13 billion) is exported for the international market [1]. Over 95% of banana worldwide export production relies on a group of cultivars named Cavendish that includes commercially grown varieties such as ‘Grand Naine’ and ‘Williams’ [2]. These cultivars gradually replaced ‘Gros Michel’, the previous banana used for export purposes that succumbed to disease epidemics in Tropical America between 1900 and 1960 by Fusarium oxysporum f. sp. cubense (Foc) race 1 [3], the causal agent of Fusarium wilt of banana or Panama disease [4].

There are three well-known races of Foc identified by their pathogenicity to specific clonal triploid banana hosts [5–7]. Race 1 causes disease to 'Gros Michel' (AAA) and can also cause disease on other cultivars like ‘Silk’ (AAB), ‘Pome’ (AAB), ‘Pisang Awak’ (ABB) and ‘Maqueno’ (AAB) [8]. Race 2 affects cooking bananas, especially those in the Bluggoe subgroup (ABB) [9,10]. Race 4 has been known to cause disease on cultivars susceptible to race 1 and 2, and more importantly, members of the subgroup Cavendish (AAA). Race 4 is divided into two types; Subtropical Race 4 (Foc STR4), which is restricted to the subtropics were plants are exposed to stress conditions such us low temperatures and drought [7, 11] and Tropical Race 4 (Foc TR4), which causes disease under both tropical and subtropical conditions without predisposing factors [12–14]. Tropical Race 4 has the potential to cause catastrophic losses in the monoculture-based banana industry and become a life-changing event for 65 millions of people, particularly smallholder farmers [15].

The race structure in Foc is confusing and often inaccurate in delineating strains of Foc [16]. Several DNA-based studies have shown that races of Foc are not genetic related to each other or share a common ancestor [17–19]. It is currently widely accepted that Foc is composed of several independent lineages with a population structure mainly clonal [12, 17–20]. Foc diversity has also been assessed by means of vegetative compatibility, which delimits groups (Vegetative Compatibility Groups—VCGs) that align with clonal lineages. Foc comprises 24 VCGs [20, 21], distributed differentially across the globe [19]. Among those, the VCG-01213/16 comprises the group of strains referred to as Tropical Race 4 (Foc TR4). This race is spreading to new countries in the South part of Asia, including Laos, Vietnam, Myanmar, India and Pakistan, and outside of its native range in South East Asia, affecting also countries in Southern Africa (Mozambique) and Middle East (Oman, Jordan, Lebanon, and Israel) [22, 23]. Recent evidence shows that epidemics caused by Foc TR4 are the result of the movement of a single clone [20], although recent research tracking the spread of Foc TR4 in the Mekong Delta shows sequence variation within VCG 01213/16 [24]. Symptoms of Fusarium wilt in Cavendish have also been reported to be associated with VCGs 0124 and 0121 [19, 25, 26]. VCG-0121 is genetically closely related to VCG-01213/16 and may cause disease on Cavendish under tropical conditions [27]. In terms of management, there are still no available solutions for the present monoculture-based, large-scale agricultural system in which bananas are produced. Exclusion and prevention remain the most important and only effective measures to prevent the disease in countries where Foc TR4 has not been reported [26].

Fusarium wilt diagnosis has traditionally relied on the recognition of symptoms, mainly characterized by wilting and yellowing of the leaves, accompanied by the reddish-brown discoloration of the pseudostem of diseased bananas [28]. However, decisions made on these criteria may hamper all efforts for disease control since the pathogen has a long incubation period. That is, by the time symptoms are observed in the field, which may take several weeks, the pathogen can be dispersed to new areas. Foc can also remain undetected infecting asymptomatic hosts as an endophyte, or colonizing soil as a saprotroph [29]. Therefore, early detection based on DNA tools constitutes a key component for the efficient execution of contingency plans, including quarantine and eradication procedures. Over the last decade, several molecular methods have been developed for detection of race 4, including Foc STR4 and TR4 strains [30–38]. Among all, one PCR-based method, using the specific primers FocTR4-F/FocTR4-R has been adopted by the International Regional Organization for Agricultural Health (OIRSA) and the Food and Agriculture Organization of the United Nations (FAO) in their contingency plans for Latin America and Caribbean countries [31, 39–41]. This particular methodology targets Foc TR4 strains only (VCG-01213), due to the major risk they represent to Cavendish bananas. This molecular tool goes beyond pathogen detection on symptomatic tissue, and it is also implemented for detecting Foc TR4 in asymptomatic plants, soil, and water [20, 42]. However, all the proposed methods have been developed using only pathogenic isolates with few, if any, nonpathogenic isolate included in validation assays. Although the Fusarium oxysporum species complex (FOSC) entails pathogenic and nonpathogenic strains [29, 43], studies suggest that greater diversity is found in endophytic and saprotrophic populations, colonizing plants or present in the soil, respectively [44–46]. Considering that the diversity of F. oxysporum populations has been overlooked and there is a large number of methodologies available for Foc race 4 diagnostics, it is imperative to determine which one of these tests provide the most accurate and reliable results for activities related to monitoring and quarantine of F. oxysporum populations pathogenic to banana.

The main goal of this research was to assess the specificity of four detection methods previously developed for race 4 diagnostics, including STR4 and TR4 [30–33]. In this study, we screened 302 isolates obtained from banana, including pathogenic and endophytic, collected from Ecuador following a PCR approach. The genetic relationship of representative strains used in this study was analyzed by phylogenetic analysis. Validation of the PCR-based screening results included VCG analysis, sequence comparison, pathogenicity testing and detection of selected endophytes from artificially infested soil and infected banana plants of two cultivars.

Materials and methods

Fungal collection and DNA extraction

A collection of 302 isolates was analyzed in this study. The collection included 292 F. oxysporum isolates, including 130 putative pathogenic isolates obtained from symptomatic ‘Gros Michel’ banana plants showing Fusarium wilt symptoms (Fig 1A), and 162 putative endophytic isolates, obtained from asymptomatic Cavendish banana cultivars and other local banana cultivars from several provinces in the coastal area of Ecuador including Esmeraldas, Manabí, Guayas, Los Ríos, El Oro, Santo Domingo and Bolivar (S1 Table). Sampling sites included backyards, home-gardens, roadsides, abandoned farms and banana plantations. Sampling on private land was conducted after granted permission by the owner. Ten isolates of three other Fusarium species, also obtained from the roots of banana plants, were included in this study for comparison purposes. In addition, the reference strains O-2052 (VCG-01213), O-1966 (VCG-0120), and O-1968 (VCG-0123), obtained from the Fusarium Research Center at The Pennsylvania State University, and characterized as Foc TR4, STR4 and race 1, respectively, were included in this study. This study did not involve endangered species.

Single-spore isolates were grown in potato dextrose broth medium (PDB, Sigma-Aldrich^®, Saint Louis, USA) for approximately 7 days at 28°C in an orbital environ shaker-incubator (Lab-line instruments Inc., IL, USA) at 120 rpm. Fresh mycelium was harvested and dried out using autoclaved filter paper (Whatman^™, Amsterdam, UK) of which 200 mg were used for genomic DNA extraction using the DNeasy^® plant mini kit (Qiagen, Maryland, USA) following the manufacturer’s guidelines. The concentration and quality of the extracted DNA samples were estimated using a Nanodrop spectrophotometer-2000^™ (Thermo Fisher Scientific, Wilmington, USA) followed by gel electrophoresis. The amplification of the translation elongation factor one-alpha (TEF) gene was performed to assess the quality of the DNA extracted for all isolates and to corroborate their identity as F. oxysporum by comparing their TEF sequences to the Fusarium-ID database [47], and used for the phylogenetic analysis (specified in the section below).

Validation of molecular detection methods

A PCR-based screening was conducted using DNA from all isolates of our collection and four sets of primers; two targeting Foc STR4 strains, and two exclusively targeting Foc TR4. All the sequences of the primer sets used in this study are described in Table 1. PCR reactions were carried out using Choice Taq Mastermix^™ (Denville Scientific Inc., Massachusetts, USA) on 25 μL containing 1X reaction buffer, 0.5 μM of each primer, 5 ng of DNA, and sterile deionized water. The cycling conditions used for the primer sets Foc1/Foc2, Foc-F/Foc-R, FocTR4-F/FocTR4-R and W2987-F/W2987-R, were the same previously described by Lin et al. [30], Li et al. [32], Dita et al. [31], and Li et al. [33]. DNA from the strains O-2052 and O-1966 was used as template for positive controls for Foc TR4 (VCG-01213) and Foc STR4 (VCG-0120), respectively. Sterile deionized water was used as negative control.

**Tab. 1. Molecular markers and primers used in this study.**

Phylogenetic analyses

Phylogenetic analyses based on the TEF and the intergenic spacer region of the ribosomal DNA (IGS) were carried out to elucidate the phylogenetic relationship of selected 66 endophytic isolates representative of the sampled sites including five F. oxysporum endophytes EC5-LR-GM1, CAV017-EO, EE-E-03, EE-E-06, CAV052-EO that generated false positives with the specific primers FocTR4-F/FocTR4-R. The TEF region was amplified using the primer set ef1/ef2 following the PCR conditions recommended by Geiser et al. [47], and the IGS region using the primer set CNL12/CNS1 following the PCR conditions recommended by Appel and Gordon [48]. PCR reactions were carried out in 25 μL using 1X reaction buffer of Choice Taq Mastermix^™ (Denville Scientific Inc., Massachusetts, USA), 0.5 μM of each primer, 5 ng of gDNA and sterile deionized water. The resulting PCR products were visualized by gel electrophoresis and purified using ExoSAP-IT^™ (USB Affymetrix Corporation, Cleveland, USA) following the manufacturer’s instructions. All PCR products were sequenced by the Genomic Core facility of The Pennsylvania State University, University Park, PA, USA. TEF regions were sequenced using the same primers as for the PCR amplification while complete sequences for the IGS region were generated using primers PN22 [49], CNSa, iNL11 [50], U: 49–67 [48] and PNFo [51]. For both data sets, the alignments and editing of sequences were performed using the software GENEIOUS R8 v 8.0.5 (Biomatters, Auckland, NZ).

Phylogenies based on Maximum Parsimony (MP), Maximum Likelihood (ML) and Bayesian (BS) methods were inferred for the different data sets using PAUP v 4.0a [52], RAxMLGUI v 1.31 [53], and MrBayes v 3.2.6 [54], respectively. The heuristic search option with 1,000 random addition sequences and tree bisection-reconnection branch swapping was used to infer the most-parsimonious tree. Gaps were treated as missing data. The Consistency Index (CI) and Retention Index (RI) were calculated to indicate the amount of homoplasy present. Maximum likelihood reconstruction was run using the thorough bootstrap analysis and the ML search with 1,000 replicates. The Generalized Time Reversible Model with a Gamma distribution (GTRGAMMA) was used as the model for nucleotide substitution. Bayesian inference was run with a 10,000,000 generation Monte Carlo Markov chain method with a burn-in of 100,000 trees. The General Time Reversible model was selected as the most appropriate nucleotide evolution model for Bayesian analysis. Convergence and the effective sample size (ESS) were checked for each run. The TEF tree was rooted with Fusarium foetens NRRL 31847 and the IGS tree with F. foetens NRRL 31852. For comparative purposes, TEF and IGS sequences of all clonal lineages of Foc described by Fourie et al. [19] were incorporated into the analyses. In addition, putative race 1 Foc isolates EC15-E-GM1, EC44-M-GM2, EC14-G-GM1, EC28-LR-GM1 and EC8-O-GM1, obtained from symptomatic ‘Gros Michel’ bananas from Ecuador, were also included in this study. Sequences generated in this research were deposited in the GenBank database under accession numbers MK754073- MK754148 (TEF) and MK783034- MK783108 (IGS).

Determination of VCG group

The five isolates that generated a positive PCR amplification for Foc TR4 with the specific primers FocTR4-F/FocTR4-R were also tested for their capability to form a stable heterokaryon with nit mutants of the tester strains O-2052, O-1966, and O-1968, associated to the VCGs 01213, 0120 and 0123, respectively. Nitrate non-utilizing (nit) mutants were generated on media supplemented with potassium chlorate (KClO3, Sigma-Aldrich^®, Saint Louis, USA) at 4.5% [19], and incubated for 8–15 days at 27 °C. Colony mutants with a weak growth and no aerial mycelium were further characterized as nit-1, nit-3 or nit-M on media containing one of three sources of nitrogen [55–56]. Nit-mutants of each isolate were checked for self-incompatibility. VCG complementation was considered positive when the pairing of two nit-mutants resulted in dense aerial growth at the contact zone in minimal medium [55].

Pathogenicity testing

The five isolates used for VCG determination, were also employed to prepare spore suspensions for inoculation of banana plants. The reference strains O-2052 (VCG-01213), O-1968 (VCG-0123), characterized as Foc TR4 and R1, were used as positive and negative controls, respectively. For this, five plugs taken from the margin of actively growing cultures were inoculated in two 1,000-ml graduated laboratory bottles (VWR^®, Radnor, USA) containing 500 ml of autoclaved PDB. Two extra bottles were prepared containing only the liquid media for negative controls. Inoculated PDB was incubated at room temperature during 12 days in a shaker-incubator (Lab-line instruments Inc., IL, USA) at 120 rpm. Spore suspensions were passed through filter paper (Whatman^™, Amsterdam, UK) and adjusted to 1x10⁶ conidia/ml before inoculation. Tissue-cultured banana plants approximately six weeks old and 25-cm high, from two cultivars (‘Gros Michel’ and Cavendish ‘Gran Naine’), were inoculated with spore suspensions of each isolate following a root-dipping method [31]. Inoculated plants were placed in pots containing a mixture of autoclaved potting soil and potting mix in a 1:1(w/w) ratio. The experiments were performed following a completely randomized design with four replicates per treatment for the Cavendish experiment and three replicates per treatment for the ‘Gros Michel’ experiment, including positive and negative controls. Both experiments were conducted twice with independently produced inoculum and banana plants. Plants were incubated in growth chambers (Conviron^®, Winnipeg, Canada) with environmental conditions set at 28°C, 80% relative humidity, and 16/8 h light/dark photoperiod. After 30 days, plants were removed from their pots and cut in half using a sterilized scalpel for internal disease assessment. Internal discoloration of the rhizome was recorded using a five-point rating scale according to Ssali et al. [57] with some modifications where 0 = no discoloration, 1 = 1–15% tissue showing discoloration, 2 = 16–33% tissue showing discoloration, 3 = 34–50% tissue showing discoloration, 4 = more than 50% tissue showing discoloration, and 5 = totally decayed. The disease index (DI) was also calculated based on the formula DI = [Ʃ(score in the scale x frequency)/(total number of plants x maximum class in the scale)] x 100. Isolation of the inoculated strains was performed at the end of the experiments, placing surface disinfested plant tissues, from the rhizome and pseudostem of plants, in petri dishes containing Nash semi-selective media [58].

Assays for in-planta and soil detection

Banana tissue and inoculated soil derived from the pathogenicity tests, were subjected to Foc race 4 detection using the same sets of primers evaluated above. Upon completion of the pathogenicity tests, 30 days after inoculation, samples from each banana plant, from both cultivars, were taken from the rhizome and pseudostem using a sterilized scalpel. Samples from the pseudostem were taken 5 cm above the base of each plant. From each sample, three-subsamples of fresh tissue, 20 mg each, were used to extract total DNA using the DNeasy^® plant mini kit (Qiagen, Maryland, USA) following the manufacturer’s instructions. For soil analyses, a composite random sample of 1g of soil per treatment, from both experiments, was collected for DNA extraction and subjected to analysis. Total DNA was extracted using the PowerSoil^® DNA isolation kit (MO BIO Laboratories, Inc., Carlsbad, CA), using 0.25 gr of soil, following the manufacturer's guidelines. PCR cycling conditions were the same as the ones used with pure mycelia. In order to increase sensitivity, a nested-PCR was included into our analysis for processing plant materials, considering the IGS region as the primary target following the use of the primer set FocTR4-F/FocTR4-R for specific detection of Foc TR4. For soil detection, the primer set FocTR4-F/FocTR4-R was used in a duplex PCR with the primer set ef1/ef2. Multiplex PCR was used to detect fungal DNA in one single reaction and discriminate false negatives in soil samples. In addition to positive and negative controls, a sample containing DNA obtained from pure fungal mycelium (5 μL with approximately 20 ng/μL) from the O-2052 (TR4) strain, diluted in a background of total soil gDNA, was also incorporated into our analysis for comparison purposes.

Results

PCR-based methods for Foc race 4 identification

Among the four sets of primers evaluated, positive PCR reactions were obtained with three of them, including Foc-1/Foc-2 [30], Foc-F/Foc-R [32], and FocTR4-F/FocTR4-R [31] when tested with the target DNA (Fig 1B). For the primer sets Foc-1/Foc-2 and Foc-F/Foc-R, which target both Foc STR4 and TR4, 187 isolates collected from the coastal area of Ecuador resulted in positive amplifications from the 302 fungal isolates, similar to the positive controls O-1966 (VCG-0120) and O-2052 (VCG-01213). From the 187 isolates, 130 were pathogenic to banana and 57 were endophytic F. oxysporum (S1 Table). The primer set FocTR4-F/FocTR4-R, targeting Foc TR4, also resulted in positive amplifications when DNA from the five F. oxysporum endophytes EC5-LR-GM1, CAV017-EO, EE-E-03, EE-E-06, CAV052-EO was used (Fig 1B). No amplification was observed with the primer set W2987-F/W2987-R [33] that targets Foc TR4, except for the positive Foc TR4 control.

Genetic relationship among F. oxysporum isolates from Ecuador and Foc lineages

Selected isolates from the collection were employed to assess their phylogenetic relationship with previously described Foc lineages (Fig 2). The TEF dataset consisted of 100 taxa and 605 total characters, of which 54 were parsimony informative. All analyses (MP, ML and BS) resulted in three well-supported clades named as F1, F2 and F3 (Fig 2B). Endophytic F. oxysporum were distributed across the three clades. Foc genotypes were present only in clades F1 and F2, including Foc isolates EC15-E-GM1, EC44-M-GM2, EC14-G-GM1, EC28-LR-GM1 and EC8-O-GM1 from Ecuador regarded as race 1. The endophytic isolates that generated a positive PCR amplification for Foc TR4, using the primers FocTR4-F/FocTR4-R, where closely related to each other based on IGS. The isolates EC5-LR-GM1, CAV052-EO, EE-E-03 and EE-E-06, displayed the same TEF sequence and clustered together with pathogenic strains belonging to VCGs 0120, 01215, 01219, as well as with pathogenic isolates from Ecuador (Fig 2B). The isolate CAV017-EO was placed in a sub-clade together with isolates from VCGs 0126, 0122, and 01210, and with others F. oxysporum endophytes. None of the endophytes above mentioned were closely related to Foc TR4 strains based on the TEF phylogeny.

Phylogenetic relationships among <i>Fusarium oxysporum</i> isolates associated to banana. — **Fig. 2. Phylogenetic relationships among *Fusarium oxysporum* isolates associated to banana.**
(A) Most parsimonious tree (CI: 0.67; RI: 0.93) inferred from the IGS region showing the interrelationship of pathogenic and endophytic strains of F. *oxysporum*. Races of *Foc* and endophytic isolates are colored designated. The shadowed area emphasizes the isolates that generated false positive amplifications, grouped to the reference *Foc* TR4 strains (red dots). (B) One of nine most parsimonious trees (CI: 0.90; RI: 0.99) inferred from the TEF region placing F. *oxysporum* isolates from banana in three phylogenetic clades. Previously described pathogenic lineages of *Foc* [19] are in bold. Endophytic isolates associated with false positives (marked in green) differed with those of *Foc* TR4 represented in a single lineage (marked in red) according to TEF. Bootstrap values and posterior probabilities are shown in each tree.

The IGS sequence data set consisted of 100 taxa and 1,324 characters in total, of which 187 were parsimony-informative sites. The IGS phylogeny presented a different tree topology compared to the TEF phylogenetic tree. The five endophytes EC5-LR-GM1, CAV017-EO, EE-E-03, EE-E-06, CAV052-EO that generated positive PCR amplifications for Foc TR4 using primers FocTR4-F/FocTR4-R, were very closely related to Foc TR4 strains associated to VCG-01213 according to this region (Fig 2A). Sequence comparison of the entire IGS region (approximately 2,431 bp), revealed a 99.8% sequence similarity of all five endophytes with the reference Foc TR4 strain. Differences included five Single Nucleotide Polymorphisms (SNPs) from which one was an insertion at the position 334 (T) and four-point mutations at positions 702 (A/C), 820 (T/C), 1405 (T/G) and 1560 (G/A).

VCG analysis and pathogenicity tests

Nit-mutants from the five endophytes, EC5-LR-GM1, CAV017-EO, EE-E-03, EE-E-06, CAV052-EO, were not compatible with the tester strains O-2052 (VCG-01213), O-1966 (VCG-0120) and O-1968 (VCG-0123), belonging to Foc TR4, STR4 and race 1, respectively (Fig 1C). Self-compatibility of the tester strains was corroborated as a control measure by pairing nit-1 and nit-3 mutants with nit-M mutants of each strain resulting in a dense aerial growth at the contact zone in minimal medium. Fusarium wilt symptoms were not observed in any of the banana plants, either ‘Gran Naine’ or ‘Gros Michel’, inoculated with each of the five endophytes, EC5-LR-GM1, CAV017-EO, EE-E-03, EE-E-06, CAV052-EO, even at 30 days post-inoculation (Fig 1E and Table 2). Cross sections of pseudostems and rhizomes of all plants inoculated with spores of the five referred isolates did not show necrotic lesions, however F. oxysporum colonies were recovered from root and rhizome samples from those plants when plated on Nash-semi selective media at the end of each experiment. Plants used as positive controls started to show yellowing and wilting symptoms on the lower leaves from day 15, which later progress to all leaves. By the end of the experiment, the lower leaves of these plants were completely necrotic, and some detached from the pseudostem.

**Tab. 2. Pathogenicity tests and PCR screening with total genomic DNA from inoculated banana plants.**

Tests on plant and soil material

Similarly to the results obtained using pure fungal DNA, positive PCR amplifications reactions were also obtained from the rhizome and pseudostem of banana plants inoculated with EC5-LR-GM1, CAV017-EO, EE-E-03, EE-E-06, and CAV052-EO isolates. However, higher number of positive PCR reactions were generated with the nested-PCR approach implemented with the primer set FocTR4-F/FocTR4-R (Table 2). Reactions carried out with the primer set W2987-F/W2987-R did not yield any band amplification, except for the positive controls (Table 2). The screening of soil samples derived from pathogenicity tests, using the same four primers sets as described earlier confirmed results obtained from DNA from mycelium, and from inoculated plant material. Positive PCR amplifications were also obtained for soils inoculated with endophytic isolates EC5-LR-GM1, CAV017-EO, EE-E-03, EE-E-06, CAV052-EO, for primes sets FocTR4-F/FocTR4-R, Foc-F/Foc-R, and Foc1/Foc2, but not for W2987-F/W2987-R, which only generated positive amplifications with soil inoculated with isolate O-2052 (TR4). As expected, soil inoculated with isolate O-2052 (TR4) generated positive amplifications with all primer sets, whereas soil inoculated with isolate O-1968 (R1) generated positive amplifications only with TEF primers, used as control. No positive amplifications were detected in non-inoculated soil.

Discussion

The recent worldwide outbreaks of Fusarium wilt caused by Foc TR4 have proven to be a trans-continental threat of special importance for countries from central and west Africa, the Indian subcontinent and the Americas, where bananas are considered a valuable source of nutrients and calories for the subsistence of families and an important commodity crop [15,59]. For Latin America countries, a contingency plan for an eventual Foc TR4 outbreak was recently developed by the Regional Organization for Plant and Animal Health (OIRSA) in an effort to provide guidelines to National Plant Protection Organizations (NPPOs) on how to deal with a putative incursion of Foc TR4 in the region, including diagnostics, eradication and contention measures. Given the high risk that Foc TR4 represents, early detection and accurate diagnosis play a key role for the implementation of these strict quarantine measures upon detection of new outbreaks of the pathogen. In this regard, and equally important, a false positive is as potentially alarming and devastating for the banana industry as a false negative.

Over the last decades, all efforts to develop molecular markers for detection of Foc race 4 strains, including STR4 and TR4, have predominantly focused on the use of pathogenic strains [30–38], which in our view are just a small fraction of the population diversity; outliers rather than representatives of the species [44–46]. The high diversity present within the F. oxysporum species complex (FOSC), which has been underestimated [46], may pose a risk for such markers compromising their specificity; even more if within such diversity may be nonpathogenic strains, which could also contain the same genomic regions exploited for detection. Here, we describe the cross-reactivity of pathogenic and nonpathogenic F. oxysporum isolates from different banana cultivars from Ecuador with specific detection markers that target race 4 strains of Foc and highlight how diversity matters to avoid false positives. We also emphasize and encourage the adoption of a more holistic, ecological-based view of F. oxysporum during the process of developing PCR molecular-based detection methods by taking population diversity, including pathogens and endophytes, into account.

Comparisons between experiments confirmed that three out of four PCR methods are not reliable in detecting the taxa for which the methods were developed. Two of them, developed to detect Foc race 4 strains, including STR4 and TR4, cross-reacted with pathogenic isolates from Ecuador, as well as, with nonpathogenic isolates. A plausible explanation, for the cross reaction with pathogenic isolates of our collection, is that in Foc different pathogenic phenotypes are associated with strains of the same or similar genotypes found within the same VCG group [31]. An excellent example comes from the strains associated with VCG-0120. Strains of this VCG that cause disease on Cavendish in the subtropics may be classified as STR4, but in the tropics, where they are unable to cause disease on Cavendish, such as the case of Ecuador, are classified as race 1. This issue was observed in previous studies [31] but has now been further validated with our results. This raises concerns about the specificity of other methods proposed for the detection of race 4 strains [32, 34, 36, 38] developed based on the same RAPD sequence fragment OPA02₄₀₄ used by Lin et al. [30]. This marker was present in all isolates analyzed in this research. It is possible that the genomic regions used for the design of these primers, although thought to be exclusive to certain pathogenic strains, are part of the ‘core genomic’ regions also found in nonpathogenic isolates. These ‘core genomic’ regions contain genes essential for the growth and survival of the fungus, and unlikely to be associated with host-specific pathogenicity [60]. Therefore, they should not be relied upon to accurately identify pathogenic variants. Putative pathogenicity genes are present in ‘accessory genomic’ regions, which can be horizontally transferred in small supernumerary chromosomes [61]. Another explanation for these faulty diagnostic markers is that the diversity of F. oxysporum has been underestimated. Populations of F. oxysporum from soil and in association with plants as endophytes have been previously reported to be highly diverse [44–46]. However, the diversity of isolates used for the development and validation of these methods did not include endophytes from banana.

The primer set FocTR4-F/FocTR4-R, commonly used for quarantine procedures and Foc TR4 diagnostics [23], also cross-reacted with five F. oxysporum endophytes from Ecuador. These endophytes presented highly similar sequences of the IGS region with Foc TR4 strains. However, further phylogenetic comparison using TEF, a housekeeping gene commonly used to reflect the evolutionary history of Foc [19, 17, 62], showed that the same isolates were not related to Foc TR4 strains. For these reasons, we recommend that the regions exploited for the above-mentioned diagnostic markers, including the IGS, should no longer be used for detection of race 4 strains. Conversely, the primers developed by Li et al [33] accurately discriminated Foc TR4 from our complete collection, including pathogenic and endophytic isolates. This set of primers has also been shown to discriminate other pathogenic strains associated with other races of Foc [33]. This test represents a more reliable alternative for Foc TR4 strain identification since it was developed on a region putatively related to virulence [33]. Moreover, this same region has been further exploited for the detection of TR4-like strains, not only associated to VCG-01213 but also to VCG-0121 and proved to discriminate nonpathogenic isolates from a different country as well [63].

Our study assessed the results from the molecular screening more in-depth by performing additional testing methods, including VCG and pathogenicity tests. Although the use of these methods has been highly criticized due to their laborious and time-consuming nature [20, 31], their inclusion allowed us to confirm that the five endophytes that displayed positive results using the FocTR4-F/ FocTR4-R primer set, were not true Foc TR4. Based on our current findings, continuous in vitro testing for pathogenicity and VCG analysis should not be completely disregarded. Confirmatory tests should not be the exception but rather the norm, and thus used in parallel to determine a method’s robustness.

Our results also showed that false positives can occur if infected plant tissues and soil were the matrix used for detection. The low frequency of positive PCR reactions obtained from infected plant tissue, from the total number of samples tested in our work, may have been due to the low amount of fungal DNA present in the asymptomatic tissue taken for analysis. This hypothesis was confirmed with a higher frequency of positive PCR reactions obtained with a more sensitive approach (Nested-PCR). It is known that F. oxysporum is a good colonizer of roots and stems of plants [43, 46]. After initial infection of the root cortex, the passage of F. oxysporum to xylem vessels of plants and systemic growth may depend on the levels of quantitative resistance present in the host [29]. It is not clear if the colonization events detected by PCR in the pseudostem of plants occurred through colonization of the vascular tissue (xylem vessels) or were restricted to the parenchyma tissue or epidermis. Likewise, it is unknown if such colonization was due to host-specific interactions, or other predisposing conditions that might have hampered the defense system of the host and facilitated the colonization to upper parts of the plants. Despite this uncertainty, the largely unexplored, high diversity of F. oxysporum present in the soil and the roots of bananas plants [64], makes us wonder if similar genotypes to the ones found in this study could be also found in other geographic areas that may lead to false diagnosis. We speculate that this hypothesis might be feasible based on the recent occurrence of false positives obtained in one banana farm from Australia on March 28, 2015 [65]. The Mareeba farm was closed on April 3, 2015, after a positive Foc TR4 PCR reaction was obtained from the tissue of a Cavendish banana plant displaying wilting symptoms. The farm remained quarantined despite being found later that Foc TR4 was not present in the farm [65, 66]. We hypothesize that endophytes of F. oxysporum were present in the sample and cross-reacted with the primers tested. The Mareeba farm, as well as another banana farm in Tully, also impacted by the quarantine response to Foc TR4, have now been reimbursed a combined total of US $684,243, which was the net value forgone for the period in which they were unable to trade [67].

Concluding remarks

The recent outbreaks of Foc TR4 in new geographic locations suggest that pathogen dissemination will likely to continue if quarantine measures are inadequate [22, 23]. Thus, accurate identification of the pathogen is likewise necessary for activities related to successful quarantine, eradication, contention, and communication with banana producers at regional, national and international level. As shown in our work, one roadblock to the management of this pathogen is the generation of false positives that occur during the identification process. This is due not only to poor handling of the samples but also to the presence of non-targeted strains of F. oxysporum that are genetically similar but lack true pathogenicity. Yet, standardized protocols should be put in place to minimize the risk of contamination and favor reproducibility [63, 68]. This should be a warning for international regulatory agencies involved with plant sanitation and crop-protection. Surveillance procedures in soil and asymptomatic tissues, in areas where the pathogen is not yet reported that rely on currently accepted PCR-based detection methods for Foc TR4, should be carried out with caution or avoided. A better understanding of the population structure of F. oxysporum in each location should be a requirement before the adoption of any technology to minimize the risk of false positives. In the meantime, we recommend the use of the primer set W2987 F/ W2987 R [33] for identification of the VCG-01213, or the newly optimized FWB-TR4 test for detection of VCGs 01213 and 0121 [63], as molecular tools in the process of Foc TR4 diagnosis. Still, it is important to considerer that no technology is absolute, and no single method is completely reliable, as they all are impacted by the biology of the pathogen and its interaction with the host and environment [68]. For future diagnosis of Foc TR4 and to inform decisions, we recommend that each event should be analyzed in a systematic manner to enable an accurate interpretation of results, and to take a conservative approach.

Finally, race designation in Foc should be also reconsidered. Given the evidence of the acquisition of transferable elements between individuals within the species and the high genetic diversity characteristic of this group, the best tactic for characterizing pathogenic phenotypes should be based on strain designation rather than race approach [69]. This view is concurrent with the recent appraisal of pathogen regulation [70], where a gene-based biosecurity system proposed could more accurately assess biological risk than the conventional name-based current practices [70].

Supporting information

S1 Table [xlsx]
Isolates of and other spp. used in this study.

Zdroje

1. FAOSTAT. FAO statistical database. 2013. http://faostat3.fao.org/home/E

2. D'Hont A, Denoeud F, Aury JM, Baurens FC, Carreel F, Garsmeur O, et al. The banana (Musa acuminata) genome and the evolution of monocotyledonous plants. Nature. 2012; 488: 213–17. doi: 10.1038/nature11241 22801500

3. Stover RH. Fusarial wilt (Panama Disease) of bananas and other Musa species. Common-wealth Mycological Institute UK. 1962. p. 117

4. Ploetz RC. Panama Disease: An old nemesis rears its ugly head. Part1: The beginnings of the banana export trades. Plant Health Progress. 2005

5. Moore NY, Pegg KG, Allen RN, Irwin JAG. Vegetative compatibility and distribution of Fusarium oxysporum f.sp. cubense in Australia. Aust. J. Exp. Agric. 1993; 33:797–802.

6. Su EJ, Hwang SC, Ko WH. Fusarial wilt of Cavendish bananas in Taiwan. Plant Dis. 1986; 70:814–818.

7. Waiter BH, Stover RH. Studies on Fusarium wilt of bananas: VI. Variability and cultivar concept in Fusarium oxysporum f. sp. cubense. Can. J. Bot. 1960; 38:985–994.

8. Ploetz RC. Panama disease: An old nemesis rears its ugly head. Part2. The Cavendish era and beyond. Plant Health Progress. 2006

9. Su HJ, Chuang TY, Kong WS. Physiological race of Fusarial wilt fungus attacking Cavendish banana in Taiwan. Taiwan Banana. 1977; p. 21.

10. Ploetz RC. Fusarium wilt of banana is caused by several pathogens referred to as Fusarium oxysporum f. sp. cubense. Phytopathology. 2006; 96:653–656. doi: 10.1094/PHYTO-96-0653 18943184

11. Stover RH, Malo RH. The occurrence of fusarial wilt in normally resistant 'Dwarf Cavendish' banana. Plant Dis. 1972; 56:1000–1003.

12. Bentley S, Pegg KG, Moore NY, Davis RD, Buddenhagen IW. 1998. Genetic variation among vegetative compatibility groups of Fusarium oxysporum f. sp. cubense analyzed by DNA fingerprinting. Phytopathology. 1998; 88:1283–1293. doi: 10.1094/PHYTO.1998.88.12.1283 18944830

13. Pegg KG, Moore NY, Sorenson S. Variability in populations of Fusarium oxysporum f.sp. cubense from Asia/Pacific region. In: Jones DR, editor. The Improvement and Testing of Musa: A Global Partnership. Proceedings of the First Global Conference of the International Musa Testing program. INIBAP France; 1994. p. 70–82.

14. Pegg KG, Moore NY, Bentley S. Fusarium wilt of banana in Australia. Aust. J. Agric. Res. 1996; 47:637–650.

15. Karangwa P, Blomme G, Beed F, Niyongere C, Viljoen A. The distribution and incidence of banana Fusarium wilt in subsistence farming systems in east and central Africa. Crop Prot. 2016; 84:132–40.

16. Mostert D, Molina AB, Daniells J, Fourie G, Hermanto C, Chao CP, et al. The distribution and host range of the banana Fusarium wilt fungus, Fusarium oxysporum f.sp. cubense, in Asia. PLoS ONE. 2017; 12(7):e0181630. doi: 10.1371/journal.pone.0181630 28719631

17. O’Donnell K, Kistler HC, Cigelnik E, Ploetz RC. Multiple evolutionary origins of the fungus causing Panama disease of banana: concordant evidence from nuclear and mitochondrial gene genealogies. Proc Natl Acad Sci. 1998; 95:2044–49. doi: 10.1073/pnas.95.5.2044 9482835

18. Koenig RL, Ploetz RC, Kistler HC. Fusarium oxysporum f. sp. cubense consists of a small number of divergent and globally distributed clonal lineages. Phytopathology. 1997; 87:915–923. doi: 10.1094/PHYTO.1997.87.9.915 18945062

19. Fourie G, Steenkamp ET, Gordon TR, Viljoen A. Evolutionary relationships among the Fusarium oxysporum f. sp. cubense vegetative compatibility groups. Appl Environ Microbiol. 2009; 75:4770–81. doi: 10.1128/AEM.00370-09 19482953

20. Ordonez N, Seidl MF, Waalwijk C, Drenth A, Kilian A, Thomma BPHJ, et al. Worse comes to worst: Bananas and Panama disease—when plant and pathogen clones meet. PLoS Pathog. 2015; 11: 1–7. 26584184

21. Katan T. Current status of vegetative compatibility groups in Fusarium oxysporum. Phytoparasitica. 1999;27: 51–64.

22. Dita M, Barquero M, Heck D, Mizubuti ESG, Staver CP. Fusarium Wilt of Banana: Current Knowledge on Epidemiology and Research Needs Toward Sustainable Disease Management. Front Plant Sci. 2018; 9:1468. doi: 10.3389/fpls.2018.01468 30405651

23. Ploetz R, Freeman S, Konkol J, Al-Abed A, Naser Z, Shalan K, et al. Tropical race 4 of Panama disease in the Middle East. Phytoparasitica. 2015; 43:283–93.

24. Zheng S-J, García-Bastidas FA, Li X, Zeng L, Bai T, Xu S, et al. New Geographical Insights of the Latest Expansion of Fusarium oxysporum f.sp. cubense Tropical Race 4 Into the Greater Mekong Subregion. Front. Plant Sci. 2018; 9:457. doi: 10.3389/fpls.2018.00457 29686692

25. Daniells J, O’Neill W, Hermanto C, Ploetz R. Banana Varieties and Fusarium oxysporum f. sp. cubense in Indonesia—Observations from Fusarium Wilt Disease Databases. Acta Hort. 2011; 897:475–77.

26. Thangavelu R, Mustaffa MM. First report on the occurrence of a virulent strain of Fusarium wilt pathogen (Race-1) infecting Cavendish (AAA) group of Bananas in India. Plant Dis. 2010; 94:1379.

27. Groenewald S, Van Den Berg N, Marasas WF, Viljoen A. The application of high-throughput AFLP's in assessing genetic diversity in Fusarium oxysporum f. sp. cubense. Mycol Res. 2006;110: 297–05. doi: 10.1016/j.mycres.2005.10.004 16483757

28. Ploetz RC, Pegg KG. Fusarium wilt. In: Jones DR, editor. Diseases of Banana, Abacá and Enset. Wallingford: CABI Publishing; 2000. p. 143–159.

29. Gordon TR. Fusarium oxysporum and the Fusarium wilt Syndrome. Annu Rev Phytopathol. 2017;55: 1.1–1.17. doi: 10.1146/annurev-phyto-080615-095919 28489498

30. Lin Y-H, Chang J-Y, Liu E-T, Chao C-P, Huang J-W, Chang P-F. Development of a molecular marker for specific detection of Fusarium oxysporum f. sp. cubense race 4. Eur J Plant Pathol. 2009; 123(3):353–65.

31. Dita MA, Waalwijk C, Buddenhagen IW, Souza JT, Kema GHJ. A molecular diagnostic for tropical race 4 of the banana fusarium wilt pathogen. Plant Pathol. 2010; 59: 348–57.

32. Li B, Du J, Lan C, Liu P, Weng Q, Chen Q. Development of a loop-mediated isothermal amplification assay for rapid and sensitive detection of Fusarium oxysporum f. sp. cubense race 4. Eur J Plant Pathol. 2013; 135(4): 903–11.

33. Li M, Shi J, Xie X, Leng Y, Wang H, Xi P, et al. Identification and application of a unique genetic locus in diagnosis of Fusarium oxysporum f. sp. cubense tropical race 4. Can J Plant Pathol. 2013; 35(4):482–93.

34. Lin Y-H, Su C-C, Chao C-P, Chen C-Y, Chang C-J, Huang J-W, et al. A molecular diagnosis method using real-time PCR for quantification and detection of Fusarium oxysporum f. sp. cubense race 4. Eur J Plant Pathol. 2013; 135(2): 395–05.

35. Zhang X, Zhang H, Pu J, Qi Y, Yu Q, Xie Y, et al. Development of a Real-Time Fluorescence Loop- Mediated Isothermal Amplification Assay for Rapid and Quantitative Detection of Fusarium oxysporum f. sp. cubense Tropical Race 4 In Soil. PloS One. 2013;8(12): e82841. doi: 10.1371/journal.pone.0082841 24376590

36. Peng J, Zhang H, Chen F, Zhang X, Xie Y, Hou X, et al. Rapid and quantitative detection of Fusarium oxysporum f. sp. cubense race 4 in soil by real-time fluorescence loop-mediated isothermal amplification. J Appl Microbiol. 2014;117(6): 1740–9. doi: 10.1111/jam.12645 25200557

37. Yang L-L, Sun L-X, Ruan X-L, Qiu D-Y, Chen D-H, Cai X-Q, et al. Development of a single-tube duplex real-time fluorescence method for the rapid quantitative detection of Fusarium oxysporum f. sp. cubense race 1 (FOC1) and race 4 (FOC4) using TaqMan probes. Crop Protection. 2015; 68(0): 27–35.

38. Lin Y-H, Lin Y-J, Chang TD, Hong L, Chen T. Development of a TaqMan probe-based insulated isothermal polymerase chain reaction (iiPCR) assay for detection of Fusarium oxysporum f.sp. cubense race 4. PLoS One. 2016; 11:1–13.

39. Dita MA, Waalwijk C, Buddenhagen IW, Souza JT, Kema GHJ. A molecular diagnostic for tropical race 4 of the banana fusarium wilt pathogen. Erratum in: Plant Pathol. 2011; 60:384.

40. Dita MA, Echegoyén PE, Pérez LF. Plan de contingencia ante un brote de la raza 4 tropical de Fusarium oxysporum f.sp. cubense en un país de la OIRSA. 2013. San Salvador, El Salvador: OIRSA, 2013.

41. Pérez-Vicente L, Dita MA, Martínez-de la Parte E. Technical Manual. Prevention and diagnostic of Fusarium Wilt (Panama disease) of banana caused by Fusarium oxysporum f. sp. cubense Tropical Race 4 (TR4). Rome, Italy: FAO, 2014.

42. Dita MA, Waalwijk C, Mutua P, Daly A, Chang PFL, Corcolon BM, et al. Detecting Fusarium oxysporum f. sp. cubense tropical race 4 in soil and symptomless banana tissues. Acta hortic. 2013; (986):127–30.

43. Gordon TR, Martyn RD. The evolutionary biology of Fusarium oxysporum. Annu Rev Phytopathol. 1997;35: 111–28. doi: 10.1146/annurev.phyto.35.1.111 15012517

44. Balmas V, Migheli Q, Scherm B, Garau P, O’Donnell K, Ceccherelli G, et al. Multilocus phylogenetics show high levels of endemic fusaria inhabiting Sardinian soils (Tyrrhenian Islands). Mycologia. 2010;102: 803–12. 20648748

45. Laurence MH, Burgess LW, Summerell BA, Liew EC. High levels of diversity in Fusarium oxysporum from non-cultivated ecosystems in Australia. Fungal Biol. 2012;116: 289–97. doi: 10.1016/j.funbio.2011.11.011 22289774

46. Demers JE, Gugino BK, Jiménez-Gasco MM. Highly diverse endophytic and soil Fusarium oxysporum populations associated with field-grown tomato plants. Appl Environ Microbiol. 2015; 81(1):81–90. doi: 10.1128/AEM.02590-14 25304514

47. Geiser DM, Jiménez-Gasco MM, Kang S, Makalowska I, Veeraraghavan N, Ward TJ, et al. FUSARIUM-ID v.1.0: A DNA sequence database for identifying Fusarium. Eur J Plant Pathol. 2004; 110:473–79.

48. Appel DJ, Gordon TR. Relationships among pathogenic and nonpathogenic isolates of Fusarium oxysporum based on the partial sequence of the intergenic spacer region of the ribosomal DNA. Mol Plant Microbe Interact. 1996;9: 125–38. 8820752

49. Edel V, Steinberg C, Gautheron N, Recorbet G, Alabouvette C. Genetic diversity of Fusarium oxysporum populations isolated from different soils in France. FEMS Microbiol Ecol. 2001; 36(1): 61–71. doi: 10.1111/j.1574-6941.2001.tb00826.x 11377774

50. O’Donnell K, Gueidan C, Sink S, Johnston PR, Crous PW, Glenn A. et al. A two-locus DNA sequence database for typing plant and human pathogens within the Fusarium oxysporum species complex. Fungal Genet Biol. 2009;46: 936–48. doi: 10.1016/j.fgb.2009.08.006 19715767

51. Edel V, Steinberg C, Avelange I, Laguerre G, Alabouvette C. Comparison of three molecular methods for the characterization of Fusarium oxysporum strains. Phytopathology. 1995; 85: 579–85.

52. Swofford DL. “PAUP*. Phylogenetic Analysis Using Parsimony and Other Methods,” Version 4, Sinauer associates, Sunderland, Massachusetts, 2003.

53. Silvestro D, Michalak I. raxmlGUI: a graphical front-end for RAxML. Org Divers Evol. 2012; 12: 335–37.

54. Ronquist F, Huelsenbeck JP. MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinforma. 2003; 19(12): 1572–74.

55. Puhalla J. Classification of strains of Fusarium oxysporum on the basis of vegetative compatibility. Can J Bot.1985; 63:179–83.

56. Correll JC, Klittich CJR, Leslie JF. Nitrate non-utilizing mutants of Fusarium oxysporum and their use in vegetative compatibility tests. Phytopathology. 1987; 77: 1640–46.

57. Ssali RT, Kiggundu A, Lorenzen J, Karamura E, Tushemereirwe W, Viljoen A. Inheritance of resistance to Fusarium oxysporum f. sp. cubense race 1 in bananas. Euphytica. 2013; 194: 425–30.

58. Nash SM, Snyder WC. Quantitative estimations by plate counts of propagules of bean root rot Fusarium in fields soils. Phytopathology.1962; 52: 567–72.

59. Ploetz RC. Management of Fusarium wilt of banana: A review with special reference to tropical race 4. Crop Prot. 2015;73: 7–15.

60. Ma LJ. Horizontal chromosome transfer and rational strategies to manage Fusarium vascular wilt diseases. Mol Plant Pathol.2014;15: 763–66. doi: 10.1111/mpp.12171 25040107

61. Ma LJ, van der Does HC, Borkovich KA, Coleman JJ, Daboussi MJ, Di Pietro A, et al. Comparative genomics reveals mobile pathogenicity chromosomes in Fusarium. Nature.2010;464: 367–73. doi: 10.1038/nature08850 20237561

62. Visser M, Gordon T, Fourie G, Viljoen A. Characterisation of South African isolates of Fusarium oxysporum f.sp. cubense from Cavendish bananas. S Afr J Sci.2010; 106: 1–6.

63. Aguayo J, Mostert D, Fourrier-Jeandel C, Cerf-Wendling I, Hostachy B, Viljoen A, et al. Development of a hydrolysis probe-based real-time assay for the detection of tropical strains of Fusarium oxysporum f. sp. cubense race 4. PLoS ONE.2017; 12(2): e0171767. doi: 10.1371/journal.pone.0171767 28178348

64. Nel B, Steinberg C, Labuschagne N, Viljoen A. Isolation and characterization of nonpathogenic Fusarium oxysporum isolates from the Roots of healthy banana. Plant Pathol.2006; 55:207–16.

65. McKillop C. Independent review blames unreliable test, not Biosecurity Queensland, for false panama diagnosis. ABC Rural. 14 Feb 2016. http://www.abc.net.au/news/2016-02-15/review-clears-biosecurity-qld-in-false-panama-diagnosis/7168506.

66. McKillop C, Zonca C. Quarantine lifted on Mareeba banana farm suspected of having Panama disease. ABC Rural. 5 Mar 2015. http://www.abc.net.au/news/2015-03-05/panama-quarantine-lifted-on-mareeba-banana-farm/6480426.

67. Australian Banana News. August 2015. https://abgc.org.au/wp-content/uploads/2015/07/abgc_newsletter_aug_15_web.pdf.

68. Martin RR, Constable F, Tzanetakis IE. Quarantine regulations and the impact of modern detection methods. Annu Rev Phytopathol.2016; 54: 189–205. doi: 10.1146/annurev-phyto-080615-100105 27491434

69. Buddenhagen I. Understanding strain diversity in Fusarium oxysporum f.sp. cubense and history of introduction of Tropical race 4 to better manage banana production. Acta Hortic.2009; 828:193–204.

70. McTaggart AR, van der Nest MA, Steenkamp ET, Roux J, Slippers B, Shuey LS, et al. Fungal genomics challenges the dogma of name-based biosecurity. PLOS Pathog.2016; 12(5):12:e1005475. doi: 10.1371/journal.ppat.1005475 27149511