The
macroconidia are nearly straight, slender and thin-walled. They usually have three or four septa, a foot-shaped basal cell and a curved and tapered apical cell. They are generally produced from
phialides on
conidiophores by
basipetal division. They are important in secondary infection.[3]
The
microconidia are ellipsoidal and have either a single septum or none at all. They are formed from
phialides in false heads by basipetal division. They are important in secondary infection.[3]
The
chlamydospores are globose with thick walls. They are either formed from
hyphae or by the modification of hyphal cells. They endure in soils for long periods and act as
inocula in primary infection.[3]
The macroconidia and chlamydospores are normally only formed on dead or dying host plants. Chlamydospores are the most significant survival structures of this pathogen.[4]
The
teleomorph or sexual reproductive stage of F. oxysporum is unknown.[5]
Four races of this pathogen have been described which attack different
banana cultivars:
Race 1 attacks cultivars in the Musa (AAA group) 'Gros Michel'[1] and caused the 20th century epidemic.[6] It also attacks '
Ducasse',[1] '
Lady Finger',[1]Musa (AAB group) 'Pome'[citation needed] and its subgroups, Musa (AAB group) 'Silk'[1] and Musa (ABB group) 'Pisang Awak'.[citation needed] (See
§ Race 1.)
Splash by rainfall, movement of contaminated soil, and movement of contaminated
propagation materials are the major means of dispersal of Foc. Dispersal by wind alone remains unproven and while animals can test positive for Foc on their outer surfaces, it remains unproven whether they can be effective
vectors.[6] Although it is a soil-borne pathogen, it does not compete well against other soil microbes for growth on dead buried tissue. It is nonetheless able to produce infection in living Musa hosts after a complete absence of hosts for 20 years - despite a population decline of 97% within the first three years. This is thought to be due to durable
chlamydospores and due to persistence as an
asymptomatic infection.[11]
There is some debate as to whether Foc is sexual and this is investigated by studying its history of
recombination - or lack of it. One study of the
linkage disequilibrium of
gametes showed relatively high disequilibrium and another a high degree of correlation between independent genetic markers, both of which are diagnostic for a lack of recombination and thus a clonal population. Other post-sequencing data analysis performed by the disequilibrium study also failed to reject recombination however this could be consistent with
horizontal transfer. Horizontal transfer has been experimentally induced and appears to have been proven in Focs past and so seems the more likely explanation.[11] Both Fo mating types have been observed in Foc and
protoperithecia-like structures are produced, but not the sexual structures. This does not necessarily mean that the sexual process has degenerated however, instead this may be a defect of the experiment.[11]
Spores germinate at a higher rate in the presence of Musa root secondary metabolites from
susceptible cultivars than those from
resistant cultivars. This suggests that inhibition of germination is an important part of
host resistance.[11]
Tropical Race 3/TR3 is a pest of Heliconia ornamental flowers.[7][13] Formerly reported to be a lesser pest of Musa balbisiana seedlings and of
Gros Michel, but that is no longer thought to be true.[13][9] Now renamed Fusarium oxysporum f. sp. heliconiae.[14][13]
[16][17]Tropical Race 4/TR4 belongs to
vegetative compatibility group 01213/16. All
cultivars which are
susceptible to Race 1 and Race 2 are susceptible to TR4 (see
§ Race 1 and
§ Race 2).[18] Starting in 2019 some authorities are following Maryani et al., 2019 in regarding this strain as Fusarium odoratissimum.[15]
However, the validity of this taxonomic change has been challenged.[19]
Subtropical Race 4/STR4 is a subtropical race and does not become symptomatic on
Cavendish until the trees are stressed by cold.[20][1] Also found in Paspalum spp. and Amaranthus spp. in Australia.[16] These weeds may be acting as sources of inoculum.[6]
Research
Much research is being undertaken because of the urgency in formulating effective control methods for Panama disease and breeding resistant banana cultivars. Researchers at
University Sains Malaysia are examining variability in the genome of the pathogen and its genetic variability is being studied, as are the evolutionary relationships within
vegetative compatibility groups of the pathogen.[21]
Research into the
phylogenetic relationships among the different strains of F. oxysporum that cause wilt of banana has been undertaken to determine whether the strains that are specific to the banana have descended from a common ancestor or have developed independently. Results of this study show that it is not
monophyletic and appears to have multiple
evolutionary origins.[22] The largest lineages of F. oxysporum f. sp. cubense (
§ Race 1 and
§ Race 2) are genetically distinct from a lineage originating from East Africa (
§ Race 5) and developed pathogenicity for bananas independently from one another.[23]
Identification, differentiation, and usage of vegetative compatibility groups is useful and valid within Foc because there are relatively few VCGs.[24]
Management
Segura-Mena et al., 2021 finds that Foc§ R1 and
§ TR4 are highly sensitive to
pH.[25] They find that this is a potential
management method in this disease.[25]
^
abcCouteaudier, Y. and C. Alabouvette, 1990 Survival and inoculum potential of conidia and chlamydospores of Fusarium oxysporum f. sp. lini in soil. Can. J. Microbiol. 36:551-556
Lücking, Robert; Aime, M. Catherine; Robbertse, Barbara; Miller, Andrew N.; Aoki, Takayuki; Ariyawansa, Hiran A.; Cardinali, Gianluigi; Crous, Pedro W.; Druzhinina, Irina S.; Geiser, David M.; Hawksworth, David L.; Hyde, Kevin D.; Irinyi, Laszlo; Jeewon, Rajesh; Johnston, Peter R.; Kirk, Paul M.; Malosso, Elaine; May, Tom W.; Meyer, Wieland; Nilsson, Henrik R.; Öpik, Maarja; Robert, Vincent; Stadler, Marc; Thines, Marco; Vu, Duong; Yurkov, Andrey M.; Zhang, Ning; Schoch, Conrad L. (2021-04-26).
"Fungal taxonomy and sequence-based nomenclature". Nature Microbiology. 6 (5).
Nature Portfolio: 540–548.
doi:
10.1038/s41564-021-00888-x.
ISSN2058-5276.
PMC10116568.
PMID33903746.
S2CID233410673.
^
abPittaway, P. A.; Nasir, Nasril; Pegg, K. G. (1999). "Soil receptivity and host - pathogen dynamics in soils naturally infested with Fusarium oxysporum f. sp. cubense, the cause of Panama disease in bananas". Australian Journal of Agricultural Research. 50 (4).
CSIRO Publishing (Commonwealth Scientific and Industrial Research Organisation): 623.
doi:
10.1071/a98152.
ISSN0004-9409.
Regional strategy and action plan for the prevention, preparedness, response and recovery of Latin America and the Caribbean to Fusarium wilt of Musaceae tropical race 4. FAO (Food and Agriculture Organization of the United Nations). 2022.
doi:
10.4060/cb8674en.
ISBN978-92-5-136494-9.
S2CID252425659.