Morphology, pathogenicity and molecular identification of Fusarium solani species complex (FSSC) associated with potato tubers

Potato (Solanum tuberosum L.) is among the top five crops growing worldwide following cereals, wheat, rice, corn and barley due to its high carbohydrate content and adaptability. Potatoes are particularly valued in developing countries as a rich source of starch, vitamins C and B6 and essential amino acids. Fusarium solani species complex (FSSC) is common pathogen of potato, causing dry rot in the Upper Egypt. In this study were isolated and identified FSSC from potato tubers based on the morphological and molecular characteristics. 187 isolates of Fusarium solani were obtained from potato tubers collected from different regions in the Upper Egypt. Based on the morphological characters, sequence data from β-tubulin and translation elongation factor (TEF-1α) genes, all of the selected FSSC isolates were divided into three major groups (F. keratoplasticum, F. falciforme and F. solani). All the tested FSSC were able to produce amylases. All of the isolates were evaluated for their pathogenicity on healthy potato tubers; which showed pathogenic effect, lesion sizes were quite variable. F. solani (SVUFs73) had a highly virulent effect.

First report of Fusarium solani Species Complex Causing Root Rot of Loquat (Eriobotrya japonica) in China

Loquat (Eriobotrya japonica), a native fruit tree to China, is a popular edible fruit with medicinal properties (Badenes et al. 2013). A 2016-2019 field survey of ~13,000 loquat trees in two orchards in Chongqing and Fujian provinces showed about 5 to 10% root rot disease incidence. The disease symptoms included leaf yellowing, wilting, rotting of main root, and cracking of lateral roots, eventually leading to defoliation and death. To determine the causative agent, diseased roots from six trees were collected, washed in tap water, cut into 2-3 mm pieces, and disinfected for 3 min in 75% (v/v) EtOH. After rinsing in sterilized water, the root pieces were soaked in 10% NaClO (w/v) for 5-10 min, rinsed thrice in sterile water, and plated on potato dextrose agar (PDA). After 7 days of incubation at 25°C, individual spores were collected from the fungal colonies and replated. Single spore cultures growing on PDA gave rise to woolly-cottony, cream-white colored aerial mycelium and a yellowish pigmented mycelium. The average colony growth rate was 8.6 mm day-1 (n=3). Microscopic observation of the mycelium revealed septate and hyaline hyphae and long cylindrical monophialides. Macroconidia were moderately curved, stout, 3-4 septate, measuring 20.79-48.70 μm × 4.16-10.14 μm (n=50). Microconidia produced from long phialides were kidney-shaped, 0-2 septate, and 5.72-17.28 μm × 2.29-6.51 μm (n=50) in size. The mycelial characteristics and reproductive structures of the isolates fit the morphological description of Fusarium sp. (Summerell et al. 2003). To confirm this identification, translation elongation factor (EF-1α) and RNA polymerase I beta subunit (RPB1) and RNA polymerase II beta subunit (RPB2) regions of the genome were PCR amplified from 3 separate isolates (R2, R4 and R5) using EF1/ EF2, RPB1-Fa/G2R, RPB2-5f2/7cR & RPB2-7cF/11aR primer pairs (O’Donnell et al. 2010) and sequenced. BLASTn comparison of the EF-1α (MT976167), RPB1 (MT967271) and RPB2 (MW233052) regions from isolate R4 showed 99% identity with the EF-1α (GU170620, 675/676 bp), RPB1 (KC808270, 1543/1545 bp) and RPB2 (MK4419902, 1637/1638 bp) sequences of Fusarium solani species complex (FSSC) in GenBank database. The same species level identification was also found using FUSARIUM-ID and FUSARIUM-MLDT databases. Two-year-old seedlings (n=3) of two different cultivars, ‘Hunanzaoshu’ and ‘Huabai No. 1’, growing in pots indoors at 25-27 °C were inoculated by drenching the soil with a conidial suspension of isolate R4 (40 mL, 106 conidia mL-1 obtained from 6-10 day old cultures). Control plants (n=3) were inoculated with sterilized water. At 20 days after inoculation (DAI) the leaves of inoculated plants became chlorotic and wilted, defoliated over time, and by 53 DAI 91.67% of plants died. The taproot and lateral roots of inoculated plants appeared brown to black in color and most lateral roots died and decomposed at 53 DAI, whereas the control plant roots remained healthy. All control plants remained symptomless. Based on morphological and molecular characters (TEF-1, RPB1 and RPB2), the re-isolated pathogen from diseased plants was identical to the R4 isolate used for inoculation and the disease assays were repeated thrice. FSSC was recently reported to cause fruit rot disease on loquat in Pakistan (Abbas et al. 2017). Identifying Fusarium solani species complex as a disease agent in Chinese loquat will assist in future development of improved germplasm for this important worldwide tree crop.

Pathogenicity and Distribution of Fusarium solani Isolates Associated with Erythrina Decline in Japan

Erythrina spp. trees have been declining since the 2000s worldwide, and fungi belonging to Fusarium solani species complex (FSSC) have been suggested to be a causal factor of decline and mortality of Erythrina variegata trees in Okinawa Island, Japan. In addition to the FSSC isolate grouped as “it-1” based on ITS sequence data (previously called strain A), we conducted an inoculation experiment with two isolates grouped as “it-2” (previously strain B), which is genetically close to it-1. Two it-2 isolates originating from two islands showed pathogenicity to E. variegata with the same symptoms as those caused by it-1 isolate. We also found the isolates of it-1 and it-2 were widely distributed, including on Ishigaki Island, ∼400 km south of Okinawa Island across the ocean. All isolates of it-1 and it-2 belong to the ambrosia Fusarium clade of the FSSC, a group of symbionts of ambrosia beetles, including the pathogens of Fusarium dieback in avocados and teas. The detection of ambrosia beetles Euwallacea spp. from our specimens provided information on the vectors of the pathogens. Our present results suggest the fungi of the FSSC could be responsible for the Erythrina decline in other areas with damage.

Efflux pump inhibition controls growth and enhances antifungal susceptibility of Fusarium solani species complex

Aim: To evaluate the inhibition of efflux pumps by using promethazine (PMZ) as a strategy to control Fusarium solani species complex (FSSC). Materials & methods: The susceptibility of FSSC strains to PMZ and the interaction between PMZ and antifungals were evaluated. The efflux pump activity was confirmed by flow cytometry with rhodamine 6G. Finally, PMZ was tested against FSSC biofilms. Results: PMZ inhibited FSSC planktonic growth and showed synergism with antifungals. PMZ reduced R6G efflux and inhibited cell adhesion, impaired the development of biofilms and disrupted mature biofilms. PMZ-challenged biofilms showed increased sensitivity to amphotericin B. Conclusion: The study provides indirect evidence of the occurrence of efflux pumps in FSSC and opens a perspective for this target in the control of fusariosis.

Genetic Diversity and Vegetative Compatibility of Fusarium solani Species Complex of Strawberry in Spain

Fusarium solani is a soilborne fungus that is a pathogen to >100 plant species. It is the causal agent of crown and root rot in strawberry. We collected 100 F. solani isolates from diseased plants and soils from two distinct geographic areas of strawberry production in Spain: plant nurseries located in the north-central region of the country and fruit production fields located in the southwestern region. The aims of this study were to accurately identify the isolates within the Fusarium solani species complex (FSSC) based on multilocus sequence typing, determine the genetic diversity and population structure of strawberry-associated FSSC based on phylogenetic analysis, and determine the vegetative compatibility among isolates in both strawberry production areas. Seven phylogenetic species, restricted to clade 3 of FSSC, were defined in the Spanish strawberry crops, showing a regional variation of species composition. Isolates from nurseries were composed of four phylogenetic species (i.e., FSSC 2, FSSC 5, FSSC 9, and an unknown FSSC species) that matched with five vegetative compatibility groups (VCGs). Isolates from fruit production fields included five phylogenetic species (i.e., FSSC 2, FSSC 3 + 4, FSSC 5, FSSC 6, and FSSC 11) distributed into 29 VCGs not correlated with phylogenetic groups. FSSC 5 and FSSC 2 were the most abundant species in nurseries and fruit production fields, respectively, and they were the only species present in both production areas. Of the 47 sequence-based haplotypes defined, no haplotypes were shared between nurseries and fruit production fields. Pathogenic isolates were present in all but FSSC 6 and FSSC 9 species, and FSSC 3 + 4 contained the higher percentage of pathogenic isolates. No relationship was observed between pathogenicity and the source of isolates (plant or soil). Generally, species present in fruit production fields showed higher genetic diversity than those present in nurseries. This work can contribute to understanding the diversity of this species complex in Spanish strawberry production areas, which will be useful for developing integrated disease management strategies.