Fusarium oxysporum f.sp. cubense (Foc) is considered one of the most devastating soilborne fungal pathogens of banana worldwide. Foc causing mortality to Cavendish group bananas, and belonging to the unique vegetative compatibility group (VCG) 01213/16 has been termed tropical race 4 (TR4) and has currently been renamed F. odoratissimum. The pathogen that was first detected approximately 50 years ago in South East Asia, has since spread to countries within the greater Mekong subregion and to Australia. Recently, the pathogen disseminated to India, Pakistan, Oman and Mozambique (Africa) and was identified in the South American continent in Colombia in 2019. In the Middle East, TR4 was first reported from Jordan and Lebanon, and later from Israel in 2016. In Israel, the pathogen was identified as TR4 by VCG tests, pathogenicity assays and molecular verification. The complete genomes of five representative TR4 isolates including two from Israel, one from Jordan, one from the Philippines, and one from Indonesia were sequenced, and single nucleotide polymorphisms (SNPs) analyses were conducted. SNPs were compared to 11 additional sequenced TR4 isolates, to determine the origin of the Israeli isolates. SNP detection and phylogeographical analyses determined that the Middle Eastern isolates are closely related, indicating that the pathogen most likely spread to Israel from Jordan, while those from Colombia are related to a representative isolate from Indonesia.
Banana (Musa spp.) is one of the most popular exported fruit and serves as a staple diet for millions of people worldwide1. In 2017, the approximate volume of global production reached 114 million tons totaling a gross value of about US$8 billion per year2. An estimated 15% of all production reaches international markets, most of which are from cultivars within the Cavendish subgroup. Cavendish cultivars are the most popularly grown and exported bananas worldwide today, due to their resistance to ‘Panama disease’ caused by the soil-borne fungus Fusarium oxysporum f.sp. cubense (Foc) race 1, that eliminated the susceptible ‘Gros Michel’ cultivar and related industry1,3.
‘Panama disease’ or Fusarium wilt, caused by F. o. f.sp. cubense (Foc) race 1, was first described in Australia in 18744. The pathogen destroyed the well-established ‘Gros Michel’ cultivar banana industry that was grown in monoculture plantations in the Americas, Africa and in the Far East during the 1900s5. Thus, Fusarium wilt became known as a pathogen of significant global importance. The cultivar ‘Gros Michel’ was subsequently replaced by resistant Cavendish group cultivars, however, the disease recurred approximately 50 years ago in the 1970’s in the southeast Asian continent and Australia with the detection of a new race of Foc, tropical race 4 (Foc TR4), causing mortality to Cavendish cultivars6. Since then the disease has spread throughout South-East Asia, to the Middle-East, India and Pakistan, and was recently discovered in the African continent in Mozambique in 20157,8. Foc TR4 was first detected in the south East Asian subcontinent of Taiwan in 1967, after most likely being introduced on infected plants from Indonesia9,10. The pathogen was then disseminated into the Chinese provinces of Fujian, Guangdong, Guangxi, Hainan and Yunnan11,12,13,14. The distribution of infected planting material and heavy farming equipment was probably the cause of further dissemination of the pathogen into the neighboring countries of Laos, Myanmar, Vietnam, and Cambodia8. The recent report of spread of TR4 into the Indian subcontinent is of major concern since India is the largest producer of bananas worldwide15. Approximately 70% production is of the Cavendish cultivar and the fruit is widely consumed and regarded as a staple diet5. However, the recent detection of TR4 in four plantations in the north of Colombia, published by García-Bastidas et al.16 and renamed as Fusarium odoratissimum, will likely have devastating consequences to the banana industry and exports worldwide.
In the Middle East, Foc TR4 has been reported from Lebanon17, Jordan18 and most recently from Israel19. In certain areas, TR4-infected bananas in Jordan are cultivated in very close proximity (1–10 km) to those of infected banana plots in Israel3. An additional banana cultivation area of 200 ha in Jericho, within the Palestinian Authority, is a region that also needs to be re-evaluated for the presence/absence of disease3. In Israel, Cavendish bananas are cultivated in the lower Carmel coastal plain (1200 ha.), western Galilee (600 ha.), western Negev (100 ha.) and Jordan valley (850 ha.). During July 2016, typical Fusarium wilt symptoms were observed in mature ‘Grande Naine’ Cavendish plants from Shfeya, Carmel coastal plain and 2 months later, in plants from Kibbutz Ein Gev, eastern shore of Lake Galilee19,20 (Fig. 1).
At the time, routine surveys in banana fields adjacent to infected areas, did not reveal any new cases of disease. However, during the summer and autumn of 2018, intensive surveillance operations discovered an additional outbreak in a number of plots close to some of the original locations (in the eastern/southern Lake Galilee area)20,21. As in previous cases, the infected sites were confined and placed under strict supervision of the Israeli NPPO. The affected plantations were fenced off, access restricted and entry allowed under strict quarantine conditions only. The spread of fungal spores in rainwater was restricted by ditches that were dug around fenced affected areas. The status of Fusarium oxysporum f. sp. cubense TR4 in Israel has been declared officially by the NPPO as: “actionable, under eradication”21.
According to a study by Zheng et al.8, a combination of classical morphological identification, phenotyping assays and sequence analyses revealed a very close relationship between the Foc TR4 isolates in the Greater Mekong Subregion (GMS), where intensive banana cultivation is conducted. Analyses of SNPs (Single Nucleotide Polymorphisms) allowed the researchers to determine the phylogeography of Foc TR4 across the GMS, Indian subcontinent, and certain areas in the Middle East, revealing three distinct Foc TR4 sub-lineages8. Genetic diversity of Foc populations can be determined by vegetative compatibility groupings (VCGs)22. Four representative groups of Foc were used to differentiate populations within a defined race lineage5. TR4 populations from different worldwide regions indicate that the pathogen is clonal and belongs to a single VCG 01213–01216 complex, thus serving as a reliable indicator for the presence of this specific pathogen3,5. Likewise, DNA molecular analyses including species-specific primer amplification and sequence analyses have been used reliably for the identification and verification of TR4 isolates from various affected areas23,24.
The Foc pathogens act as typical soilborne fungi. Resting spores of the pathogen can remain viable in soil for decades, thus limiting the cultivation of susceptible banana germplasm in infested soils1,3. The fungus penetrates the roots spreading to the vasculature, releasing toxins, and causing plants to secrete gelatinous substances that eventually causes wilting and mortality of the banana plant25. Vegetative propagation of planting material and reliance on nearly exclusively based ‘Cavendish’ lines that are susceptible to TR4 has threatened the production of export and local banana industries. Thus, prevention and management strategies at national and international levels must be implemented against this destructive disease that seriously threatens the global banana industry26,27. To date, no effective TR4 management methods are known and no alternative commercial banana clones resistant to the pathogen exist3, although transgenic clones transformed with a gene from TR4-resistant diploid bananas and a nematode-derived antiapoptosis gene remain disease free28, while silencing of vital fungal genes29 have been shown to confer efficient resistance against disease. Disease management has proven to be difficult, therefore, prevention is currently the main strategy to avoid new Foc TR4 incursions3,6.
In this study, we report on the presence and origin of Foc TR4 in Cavendish plantations in Israel and the Middle East. The main aims of this research were to determine the: 1) genetic diversity of the TR4 FOC isolates in Israel compared with representative worldwide isolates, and 2) geographic origin of the population in Israel using genome sequencing data, towards understanding the epidemiological impact of spread of the pathogen within the Middle East.
VCG characterization of isolates
VCG analysis was carried out using nit mutants produced from diagnostic isolates, paired with tester Nit M mutants generated in this research and with representative isolates obtained from A. Viljoen (Table 1). Heterokaryons were usually evident within 10 to 15 days. When mutants formed a prototrophic heterokaryon, their parent isolates were assigned to the same VCG. VCG analysis of monoconidial F. oxysporum isolates recovered from infected samples in Israel (FOC TR4-1, FOC TR4-5, FOC TR4-16, FOC TR4-18, FOC TR4-26, FOC TR4-27) compared with representative TR4 isolates (II5 from Indonesia, S1B8 from the Philippines and JV11 from Jordan), confirmed the presence of TR4 in Israel. Nit mutants from the diagnostic isolates anastomosed to form stable heterokaryons when paired with the TR4 Nit M testers on minimal media, thus confirming their identity as VCG 01213/16, unique for TR4. Representative isolates of different VCGs (CAV 095 and CAV 105 belonging to VCG 0120; CAV 188 belonging to VCG 1212 and CAV 786 belonging to VCG 0124) did not anastomose with the unique TR4 representative VCG 01213/16 isolates, further indicating reliability of the assay.
Molecular characterization of isolates by ap-PCR and specific PCR analyses
DNA from representative isolates of Fusarium oxysporum f. sp. cubense race TR4 and isolates associated with Fusarium wilt of banana in Israel, were amplified with species-specific TR4 primers. An F. o. f. sp. cubense TR4-specific amplicon of 1.4 kb was amplified from the representative and suspect Israeli isolates (Fig. 2). Genotyping of all 37 TR4 isolates was conducted using ap-PCR with four repeat-motif primers. Among the tested isolates, genetically distinct and identical banding patterns were displayed for all TR4 isolates, as shown with primer (GACA)4 (Fig. 3), and primers (CAG)5, (AGG)5 and (GACAC)3 (data not shown).
Thus, specific primer amplification and ap-PCR molecular analyses of all the recovered TR4 isolates from infected samples from Israel and representative isolates from abroad, confirmed the presence of TR4 in Israel (Figs. 2 and 3).
Two weeks after artificial inoculation with the three selected Israeli TR4 isolates, TR4-treated plants expressed typical external Fusarium wilt symptoms (Fig. 4). The disease progressed steadily and four weeks after inoculation, all TR4-treated plants were killed, while water controls remained healthy (Fig. 4). TR4 identification from symptomatic plants was reconfirmed by PCR (data not shown) and the inoculated FOC isolates were re-isolated from diseased plants verifying Koch postulate assays. TR4 was not isolated from asymptomatic water control plants.
Sequence analysis of Foc TR4 isolates
Whole genome sequencing of representative TR4 isolates from Israel and Jordan and other representative isolates from south East Asia were performed (our sequences have been uploaded to SRA under BioProject accession PRJNA563197), in order to study their genetic relatedness and determine the origin of Israeli isolates. The maximum-likelihood phylogeny of the genome sequences clearly confirmed that these isolates belong to the TR4 genetic lineage (Zheng et al.8). Single nucleotide polymorphisms (SNPs) of the TR4 isolates from Israel (FOC TR4-1 from Shfeya and FOC TR4-5 from Ein Gev), Jordan (JV14), the Philippines (S1B8), and Indonesia (II-5) were analyzed. These isolates were compared to ten additional isolates sequenced by Zheng et al.8 and García-Bastidas et al.16. Subsequent principal component analyses (PCA) and hierarchical clustering revealed three distinct geographical groups of the TR4 isolates: (i) a Middle Eastern clade containing isolates from Israel, Lebanon and Jordan; (ii) a South East Asian clade containing isolates from Laos, Myanmar, Pakistan, Philippines, and Vietnam, and (iii) a clade containing the representative Indonesian isolate and those from Colombia (Figs. 5 and 6). Likewise, five SIX-gene homologues (SIX1a, SIX1b, SIX1c, SIX4, and SIX9) of TR4 isolates based on the consensus sequence showed no differences in their sequences to those of our sequenced isolates (Fig. S1). The Jordanian and Israeli isolates showed a greater common SNP uniformity, as can be seen in the Venn diagram (Fig. 7).
In recent years, the occurrence and spread of Fusarium oxysporum f. sp. cubense race TR4 has created huge concern within the banana research, cultivation and industry communities. Examples are widespread, from a local incursion in the Northern Territory of Australia, the pathogen reached Northern Queensland where biosecurity officials were unfortunately unable to curb its initial establishment and consequent spread within the major banana cultivation area of the country24. Likewise, concern has surmounted due to continuous dissemination of TR4 within the greater Mekong sub-region and suspect origin of the pathogen associated with the involvement of Chinese entrepreneurs in this area8. Furthermore, the recent widespread detection of the pathogen in India, the largest banana producer worldwide15, and establishment of the pathogen in Africa7 and the Middle East18,19,20 has caused much alarm. Of utmost concern is the arrival of TR4 to the continent of America, where numerous reports have stated the presence of the pathogen in the most populous banana cultivation area of Colombia, specifically the northern coastal region of La Guajira16.
The first detection of F. o. f.sp. cubense isolate TR4 in Israel occurred in the summer of 2016 at two limited locations19. However, the pathogen has since been detected from at least five additional plots, located in the Jordan Valley, south of the original affected site20,21. This is the first comprehensive study pertaining to the identity, occurrence and spread of the pathogen in Israel. Detailed biological, pathological and molecular analyses were conducted in this study on the TR4 isolates from Israel to verify their identity and clonality. Vegetative compatibility groupings of TR4 has reliably allowed an accurate identity of the pathogen since only a single VCG (01213/16) for this race has been identified to date, indicating its uniformity24. VCG analyses conducted with 14 Israeli representative Foc TR4 isolates from four different geographic locations in Israel compared with four representative isolates from the Philippines, Jordan and Indonesia, confirmed and corroborated presence of the unique VCG (Table 1) in the Middle East.
Additional molecular methods confirmed the presence and spread of the pathogen within Israel (Figs. 2 and 3). Arbitrarily primed PCR, which has been used extensively for genetic diversity studies of fungal and other populations proved reliable for this cause. In past studies we have used ap-PCR to determine clonality within populations of Colletotrichum species affecting almond, anemone, avocado and other hosts30,31, including species of Fusarium causing mango malformation disease32. Thus, it was no surprise that genetic uniformity existed among ap-PCR amplified DNA products from the 37 tested Israeli TR4 isolates compared to amplified fragments of four representative isolates from Jordan, the Philippines and Indonesia (Fig. 3).
PCR-specific primer amplification techniques are paramount for initial detection, identification and verification purposes of the presence of TR4. Numerous primers and PCR techniques (lamp, qPCR and regular PCR) have been used for detection purposes, some more effective than others12,23,33,34. For example, the primer set used by Lin et al.34 was not accurate for TR4 detection and cross reacted with other Foc race 1 isolates33. Likewise, the commonly used assay using specific primers of Dita et al.23 has been extensively used, however in some cases a false-negative reaction was evident in some of our tests (data not shown). Therefore, in this study we repeatedly used the diagnostic primers published by O’Neill et al.24. These primers successfully verified the identity of the tested TR4 isolates from Israel and representative DNA of TR4 isolates from other areas worldwide (Fig. 3).
Detection of TR4 from the Middle East was first confirmed in 2013 from Jordan18 although it was assumed that the pathogen had existed in that country since 20053. At that time, no reports were available of TR4 infections from additional banana growing countries in the region. However, since the first report from Jordan, the pathogen has spread within that country3 (Freeman, personal comm.), has been detected from two locations in Lebanon17 and now is also well established in Israel20,21. The likelihood that the pathogen may be present in the Palestinian Authority (PA), within the territory where banana is cultivated in Jericho, should also be assessed, because extensive travel exists locally between the banana cultivation areas of the PA and Israel. Thus, it is imperative to determine the source or origin of the infections in Israel, in order to monitor and curb additional new introductions of the pathogen.
Recently, 251 single-nucleotide polymorphism (SNPs) were identified after sequencing 8 representative TR4 genomes allowing the clustering and subsequent phylogeographic relationship among isolates8. It was found that TR4 isolates from Vietnam, Laos, and Myanmar clustered with isolates from China (Yunnan province); isolates from Pakistan were closely related to those from the Philippines and those from Lebanon were genetically related to those from Jordan. Therefore, it can be postulated that the origins of related populations can be associated with that of the genetic relatedness using SNPs. In this study, we used SNP analyses of 5 representative TR4 isolates from the Philippines, Israel, Jordan and Indonesia, and compared them to those sequenced by Zheng et al.8 and by García-Bastidas et al.16. Isolates from Colombia clustered with the representative isolate from Indonesia, suggesting the source of incursion into South America. The Israeli isolates clustered with those from Jordan and Lebanon, indicating that the source of origin of the Israeli isolates is most likely from Jordan (Figs. 5 and 6), due to the fact that no overland transport exists between Israel and Lebanon. An additional asumption that the source of infection in Israel originated from Jordan, is due to the close proximity of infected plantations in Jordan to those in the Jordan Valley of Israel3,18, and possible movement of workers, soil, stray wild pigs and agricultural produce accross the borders. It is important to indicate that the SNP analyses did not indicate from where the initial infections of the Middle East originated, only the fact that the tested isolates within this geographical region were genetically similar.
In this report, we have updated our findings and data regarding the new incursions of Foc TR4 in the Middle East, specifically in Israel. This study further pronounces and stresses the gravity of the situation and the necessity to promote awareness campaigns in indicating the importance of TR4 within the banana industry community specifically, and the public in general. These efforts should also emphasize the priority of preventing local and international dissemination of TR4 isolates within the banana cultivation areas in Israel and from the cross-bordering infected plantation areas of Jordan.
Sample collection and fungal isolates
Commercial cultivar ‘Grande Naine’ Cavendish banana plants from Shfeya, Carmel coastal plain, and from Kibbutz Ein Gev, eastern shore of Lake Galilee, showing typical Fusarium wilt symptoms, accompanied by discoloration of the vasculature, mature leaf yellowing and dead leaves surrounding the pseudostem, were sampled during July and October 2016. Additional samples originated from a number of sites in close proximity to that of Ein Gev (Kibbutz Masada, Kibbutz Gesher and Kibbutz Deganya B), in the eastern/southern Lake Galilee area and Jordan Valley21 (Table 1).
The affected plant samples were processed for Foc TR4 isolation and characterization, as described19. Infected plant tissue was surface sterilized with 70% ethanol for 20 seconds, 1% sodium hypochlorite (NaOCl) for 3.5 minute, washed with sterile water and dried on sterilized tissue paper. The plant tissue was then placed aseptically on potato dextrose agar (PDA, Difco, USA) plates amended with 250 ppm chloramphenicol, and incubated at 25 °C. Cultures growing from affected tissue sections were further purified by the single spore method35. Representative Foc TR4 isolates from Israel and others used in this study, were kindly provided by R. Ploetz (Univ. of Florida, USA)19 and A. Viljoen (Stellenbosch Univ., South Africa)36 (Table 1). Subsequently, pathogenicity of representative TR4 isolates from Israel were verified, see below19.
VCG characterization of isolates
Vegetative compatibility groupings (VCG) of representative isolates (Table 1) were conducted, as described37. Puhalla’s minimal nitrate agar (MM), a sucrose-salt medium containing nitrate as the nitrogen source37,38, was used to identify nit mutants and for complementation (heterokaryon) tests. Chlorate media, based on MM or potato dextrose agar amended with KClO3 (15 g/L), were used to generate nit mutants36. Plates (9-cm diam.) of chlorate media were centrally inoculated with 4-mm3 mycelial plugs and incubated at 25 oC. Fast-growing sectors emerging from the restricted colonies were transferred to MM plates (5-cm diam.) and examined after a 4-day incubation period. Colonies with thin expansive mycelium were considered nit mutants. Complementation between nit mutants was tested on MM, as previously described31. Heterokaryons were usually evident within 10 to 15 days. When mutants formed a prototrophic heterokaryon, their parent isolates were assigned to the same VCG.
DNA extraction and molecular analyses of isolates
Monoconidial cultures of 40 F. o. f. sp. cubense isolates (Table 1) were grown at 25 °C in liquid broth of glucose minimal medium, per liter composition: 50 ml of 20 × salt solution (120 gm of NaNO3, 10.4 gm of KCl, 10.4 gm of MgSO4.7H2O, 30.4 gm of KH2PO4 dissolved in one liter of distilled water), 1 ml of Hunter’s trace elements solution (2.2 gm of ZnSO47H2O, 1.1 gm of H3BO3, 0.5 gm of MnCl24H2O, 0.5 gm of FeSO47H2O, 0.16 gm of CoCl25H2O, 0.16 gm of CuSO45H2O, 0.11 gm of (NH4)6Mo7O244H2, O.5 gm Na4EDTA dissolved in 100 ml of distilled water)35. Arbitrarily-primed (Ap)-PCR was performed on all the TR4 isolates using the following primers: (CAG)5, (GACA)4, (AGG)5 and (GACAC)3 30,31,32. PCR reactions were conducted in 20 µl volume, containing 1.5 µl of total genomic DNA (100 ng/µl concentration), 2 µl of 10x Taq Buffer, 1 µl of 10 µM primer, 2 µl of 25 mM MgCl2, 2 µl of 10 mM dNTPs, 0.2 µl of Taq Polymerase enzyme and 11.3 µl of sterile water. PCR reactions were carried out in a thermocycler (Biometra, Germany) with the following cycling parameters: initial denaturation at 95 °C for 5 min, followed by 29 cycles of denaturation at 95 °C for 30 sec, annealing for 30 sec (60 °C for CAG5 and AGG5; 48 °C for GACAC3 and GACA4), and extension at 72 °C for 1.5 min, and a final extension at 72 °C for 15 min. PCR primers (TR4-F2 5′CAG GCC AGA GTG AAG GGG GAA T3′ and TR4-R1 5′CGC CAG GAC TGC CTC GTG A3′) were used for specific diagnostic amplification of a DNA fragment of 1400 bp for TR4 isolate detection19,20,24. PCR cycling parameters included initial denaturation at 95 °C for 10 min, followed by 35 cycles of denaturation at 95 °C for 30 sec, 68 °C for 90 sec and a final extension at 72 °C for 3 min. PCR amplification and the reaction results were kept at 4 °C until further processed. PCR products were then separated in 1.8% agarose gel (15 × 10 cm, W × L) in Tris-Acetate-EDTA buffer, at 80 V, 400 mA for 2 hours and stained with ethidium bromide (0.5 µg/ml) to visualize the banding patterns using ENDURO GDS gel documenting system (Labnet, USA). All PCR reactions were conducted at least three times with identical results.
Three representative Israeli TR4 isolates (FOC TR4-1, FOC TR4-5 and FOC TR4-18 were used for plant (cv. ‘Grande Naine’) inoculation assays, as essentially described19,20. Conidia were produced from 1-week-old cultures grown in PDA dishes and plants with four true leaves were inoculated at a concentration of 106 conidia/ml in 400 ml sterile water. Inoculation was conducted by dipping unwounded rooted plants for 30 min in conidial suspensions of the above isolates and water control. Inoculated plants were then planted in a soil mix (Green90; Evenari.co.il) in 750 ml pots under 30 °C and 16/8-h light/darkness photoperiod conditions in a quarantine greenhouse. Ten replicate plants were inoculated each with the TR4 isolates and water control. Experiments were repeated twice with similar results.
Sequence analyses of Foc TR4 isolates
To determine the identity of the isolates and their relationship with other representatives, two TR4 isolates from Israel [FOC-TR4-1 (NRRL# 66915) from Shfeya and FOC TR4-5 (NRRL# 66916) from Ein Gev), one from Jordan (JV14), one from the Philippines (S1B8) and one from Indonesia (II-5) were arbitrarily selected for whole-genome sequencing at the Technion Genome Center, Haifa Israel, using Illumina technology (HiSeq. 2500), yielding ∼20 million cleaned reads (150 nt) (sequences were uploaded to SRA under BioProject accession PRJNA563197). An additional 8 representatives (JV11 from Jordan, Leb1.2 C from Lebanon, La-2 from Laos, My-1 from Myanmar, Vn-2 from Vietnam, Pak1-1A from Pakistan, Phi2-6C from the Philippines and II-5 from Indonesia), subsequently sequenced by Zheng et al.8, and 3 isolates (Col 2, Col 4 and Col 17 from Colombia) sequenced by García-Bastidas et al.16, were used for comparisons.
Single-nucleotide polymorphisms (SNPs) were identified using GATK version 3.4-039 by mapping short reads against the Foc TR4 II5 reference isolate, using BWA-mem40. Duplicate reads were marked using Picard tools version 1.78 (http://broadinstitute.github.io/picard/). Genomic variants were identified using GATK HaploTypeCaller, and a joint variant call set was generated using GATK Genotype GVCFs. Subsequently, SNP variants were selected and filtered to retain high quality SNPs (only homozygote SNPs were selected), and used to determine the relationships between Foc TR4 isolates by way of principle component analyses TASSEL software41.
All genome sequence and SNPs data have been submitted to GenBank (sequences have been uploaded to SRA under BioProject accession PRJNA563197) and will be readily available upon acceptance of this manuscript. Representative TR4 isolates from Israel have been deposited in the USDA-ARS, NRRL culture collection, Peoria IL.
Ploetz, R. C. Management of Fusarium wilt of banana: a review with special reference to tropical race 4. Crop Prot. 73, 7–15 (2015).
FAOSTAT, https://www.fao.org/faostat/en/#home (2019).
Ploetz, R. et al. Tropical race 4 of Panama disease in the Middle East. Phytoparasitica 43, 283–293, www.researchgate.net/publication/276424927_Tropical_race_4_of_Panama_disease_in_the_Middle_East/link/55ad39fa08ae98e661a4218f/download (2015).
Bancroft, J. Report of the board appointed to enquire into the cause of disease affecting livestock and plants. Votes Proc. 1877, 1011–1038 (1876).
Ploetz, R. C. Fusarium wilt of banana. Phytopathology 105, 1512–1521, https://apsjournals.apsnet.org/doi/10.1094/PHYTO-04-15-0101-RVW (2015).
Dita, M., Barquero, M, Heck, D., Mizubuti, E. S. G. & Staver, C. P. Fusarium wilt of banana: current knowledge on epidemiology and research needs toward sustainable disease management. Front. Plant Sci. 9, 1468, https://www.frontiersin.org/article/10.3389/fpls.2018.01468 (2018).
Butler, D. Fungus threatens top banana. Nature 504, 195–6, https://www.nature.com/news/fungus-threatens-top-banana-1.14336 (2013).
Zheng S. J. 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. 9, 457, https://www.frontiersin.org/articles/10.3389/fpls.2018.00457/full (2018).
Hwang, S. C. & Ko, W. H. Cavendish banana cultivars resistant to Fusarium wilt acquired through somaclonal variation. Plant Dis. 88, 580–588, https://doi.org/10.1094/PDIS.2004.88.6.580 (2004).
Su, H. J., Chuang, T. Y. & Kong, W. S. Physiological race of Fusarial wilt fungus attacking Cavendish banana of Taiwan. Taiwan Banana Res. Inst. Spec. Publ. 2, 1–21 (1977).
Buddenhagen, I. W. Understanding strain diversity in Fusarium oxysporum f.sp. cubense and history of introduction of ‘“Tropical Race 4”’ to better manage banana production. Acta Hortic. 828, 193–204 (2009).
Li, B. et al. 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. 135, 903–11 (2013).
Qi, Y. X. et al. Race 4 identification of Fusarium oxysporum f. sp. cubense from Cavendish cultivars in Hainan province, China. Australas. Plant Dis. Notes 3, 46–47, http://www.publish.csiro.au/dn/dn08018 (2008).
Su, H. J., Hwang, S. C. & Ko, W. H. Fusarial wilt of Cavendish bananas in Taiwan. Plant Dis. 70, 814–818, https://www.apsnet.org/publications/plantdisease/backissues/Documents/1986Articles/PlantDisease70n09_814.PDF (1986).
Thangavelu, R. et. al. First detection of Fusarium oxysporum f. sp. cubense tropical race 4 (TR4) on Cavendish banana in India. Eur. J. Plant Pathol. 154, 777-786, https://link.springer.com/article/10.1007%2Fs10658-019-01701-6 (2019).
García-Bastidas, F. A. et al. First report of Fusarium wilt Tropical Race 4 in Cavendish bananas caused by Fusarium odoratissimum in Colombia. Plant Dis. (in press), https://doi.org/10.1094/PDIS-09-19-1922-PDN (2019).
Ordonez, N. et al. First report of Fusarium oxysporum f. sp. cubense Tropical Race 4 causing Panama disease in Cavendish bananas in Pakistan and Lebanon. Plant Dis. 100, 209, https://doi.org/10.1094/PDIS-12-14-1356-PDN (2015).
García-Bastidas, F. et al. First report of Fusarium oxysporum f. sp. cubense Tropical Race 4 associated with Panama disease of banana outside Southeast Asia. Plant Dis. 98, 694–696, https://doi.org/10.1094/PDIS-09-13-0954-PDN (2014).
Maymon, M. et al. First report of Fusarium oxysporum f. sp. cubense tropical race 4 causing Fusarium wilt of Cavendish bananas in Israel. Plant Dis. 102, 2655 (2018).
Maymon, M. et al. First report of Fusarium oxysporum f. sp. cubense tropical race 4 causing Fusarium wilt of Cavendish bananas in Israel. Phytoparasitica 47, 241 (2019).
EPPO publication 2019/059. Update on the situation of Fusarium oxysporum f. sp. cubense tropical race 4 in Israel, https://biosecscanner.com/wp-content/uploads/2019/03/Rse-1903.pdf (2019).
Karangwa et al. Genetic diversity of Fusarium oxysporum f. sp. cubense in East and Central Africa. Plant Dis. 102, 552–560, https://doi.org/10.1094/PDIS-02-17-0282-RE (2018).
Dita, M. A., Waalwijk, C., Buddenhagen, I. W., Souza, M. T. Jr. & Kema, G. H. J. A. molecular diagnostic for tropical race 4 of the banana Fusarium wilt pathogen. Plant Pathol. 59, 348–357, https://doi.org/10.1111/j.1365-3059.2009.02221.x (2010).
O’Neill, W. T. et al. Detection of Fusarium oxysporum f. sp. cubense tropical race 4 strain in northern Queensland. Austral. Plant Dis. Notes, 11, 33, https://www.academia.edu/33596029/Detection_of_Fusarium_oxysporum_f._sp._cubense_tropical_race_4_strain_in_northern_Queensland (2016).
Guo, L. et al. Genome and transcriptome analysis of the fungal pathogen Fusarium oxysporum f. sp. cubense causing banana vascular wilt disease. PLoS ONE 9, e95543, https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0095543 (2014).
Dhont, A. et al. The banana (Musa acuminata) genome and the evolution of monocotyledonous plants. Nature 488, 213–217, https://www.nature.com/articles/nature11241 (2012).
FAO. Banana market review and banana statistics 2015-2016, http://www.fao.org/3/a-i7410e.pdf (2017).
Dale, J. et al. Transgenic Cavendish bananas with resistance to Fusarium wilt tropical race 4. Nat. Commun. 8, 1496, https://doi.org/10.1038/s41467-017-01670-6 (2017).
Ghag, S. B., Shekhawat, U. K. S. & Ganapathi, T. R. Host-induced osttranscriptional hairpin RNA-mediated gene silencing of vital fungal genes confers efficient resistance against Fusarium wilt in banana. Plant Biotechnol. J. 12, 541–553 (2014).
Freeman, S., Katan, T. & Shabi, E. Characterization of Colletotrichum species responsible for anthracnose diseases of various fruits. Plant Dis. 82, 596–605 (1998).
Freeman, S., Shabi, E. & Katan, T. Characterization of Colletotrichum acutatum causing anthracnose disease of anemone (Anemone coronaria L.). Appl. Environ. Microbiol. 66, 5267–5272 (2000).
Otero-Colina, G. et al. Identification and characterization of a novel etiological agent of mango malformation disease in México, Fusarium mexicanum sp. nov. Phytopathology 100, 1176–1184 (2010).
Aguayo J, 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 12, e0171767, https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0171767 (2017).
Lin, Y. H. et al. Development of a molecular marker for specific detection of Fusarium oxysporum f. sp. cubense race 4. Eur J. Plant Pathol. 123, 353–65 (2009).
Sharma, G., Maymon, M. & Freeman, S. Epidemiology, pathology and identification of Colletotrichum including a novel species associated with avocado (Persea americana) anthracnose in Israel. Sci. Rep. 7, 15839 (2017).
Fourie, G. Evolutionary biology of Fusarium oxysporum f. sp. cubense. Univ. of Pretoria, South Africa. MSc dissertation, https://repository.up.ac.za/bitstream/handle/2263/29586/dissertation.pdf;sequence=1 (2008).
Puhalla, J. E. Classification of strains of Fusarium oxysporum on the basis of vegetative compatibility. Can. J. Bot. 63, 79–183 (1985).
Correll, J. C., Klittich, C. J. R. & Leslie, J. F. Nitrate nonutilizing mutants of Fusarium oxysporum and their use in vegetative compatibility tests. Phytopathology 77, 1640–1646 (1987).
DePristo, M. A. et al. A framework for variation discovery and genotyping using next- generation DNA sequencing data. Nat. Genet. 43, 491–498, https://www.nature.com/articles/ng.806 (2011).
Li, H. & Durbin, R. Fast and accurate short read alignment with Burrows–Wheeler transform. Bioinformatics 25, 1754–1760 (2009).
Bradbury, P. J. et al. TASSEL: software for association mapping of complex traits in diverse samples. Bioinformatics 23, 2633–2635 (2007).
The authors thank the Chief Scientist of the Israeli Ministry of Agriculture and The Banana Growers Board, grant number 21-01-0029, for funding this research.
The authors declare no competing interests.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Maymon, M., Sela, N., Shpatz, U. et al. The origin and current situation of Fusarium oxysporum f. sp. cubense tropical race 4 in Israel and the Middle East. Sci Rep 10, 1590 (2020). https://doi.org/10.1038/s41598-020-58378-9
This article is cited by
Contemporary narratives about asymmetries in responsibility in global agri-food value chains: the case of the Ecuadorian stakeholders in the banana value chain
Agriculture and Human Values (2023)
Distribution and diversity of Fusarium oxysporum f.sp. cubense TR4 causing banana wilt in Sub-tropics of India and comparative analysis of TR4 specific molecular detection methods
Journal of Plant Biochemistry and Biotechnology (2023)
Triamcinolone Acetonide Produced by Bacillus velezensis YEBBR6 Exerts Antagonistic Activity Against Fusarium oxysporum f. sp. Cubense: A Computational Analysis
Molecular Biotechnology (2023)
Cultivar-specific markers, mutations, and chimerisim of Cavendish banana somaclonal variants resistant to Fusarium oxysporum f. sp. cubense tropical race 4
BMC Genomics (2022)
Analysis of TCP Transcription Factors Revealed Potential Roles in Plant Growth and Fusarium oxysporum f.sp. cubense Resistance in Banana (cv. Rasthali)
Applied Biochemistry and Biotechnology (2022)