The Endophytic Strain Trichoderma asperellum 6S-2: An Efficient Biocontrol Agent against Apple Replant Disease in China and a Potential Plant-Growth-Promoting Fungus

A study was conducted for endophytic antagonistic fungi obtained from the roots of healthy apple trees growing in nine replanted orchards in Shandong Province, China. The fungi were assessed for their ability to inhibit Fusarium proliferatum f. sp. malus domestica MR5, a fungal strain associated with apple replant disease (ARD). An effective endophyte, designated as strain 6S-2, was isolated and identified as Trichoderma asperellum. Strain 6S-2 demonstrated protease, amylase, cellulase, and laccase activities, which are important for the parasitic and antagonistic functions of pathogenic fungi. The inhibition rate of 6S-2 against Fusarium proliferatum f. sp. malus domestica MR5 was 52.41%. Strain 6S-2 also secreted iron carriers, auxin, ammonia and was able to solubilize phosphorus. Its fermentation extract and volatile substances inhibited the growth of MR5, causing its hyphae to twist, shrink, swell, and rupture. The antifungal activity of the 6S-2 fermentation extract increased with increasing concentrations. It promoted the production and elongation of Arabidopsis thaliana lateral roots, and the strongest effects were seen at a concentration of 50 mg/mL. A GC-MS analysis of the 6S-2 fermentation extract and volatile substances showed that they comprised mainly alkanes, alcohols, and furanones, as well as the specific volatile substance 6-PP. The application of 6S-2 spore suspension to replanted apple orchard soils reduced plant oxidative damage and promoted plant growth in a pot experiment. Therefore, the endophytic strain T. asperellum 6S-2 has the potential to serve as an effective biocontrol fungus for the prevention of ARD in China, and appears to promote plant growth.

Evaluation of Fungicides and Bioagents against Fusarium proliferatum under In vitro by Spore Germination Inhibition Technique

Background: Bottle gourd is a cucurbitaceous vegetable of culinary and medicinal importance cultivated in various tropical and sub-tropical regions of world. This crop is exposed to a wide variety of seed and soil mycoflora, out of which Fusarium proliferatum is utmost important as far as seed germination, viability and seedling vigour are concerned. Methods: Study was taken up to evaluate different fungicides and bioagents for their efficacy against the fungus Fusarium proliferatum under in vitro through spore germination inhibition technique. Result: Spore germination inhibition of 86.00%, 85.00% and 81.33% was recorded with hexaconazole (5% SC) @ 0.2% (C3), mancozeb (75% WP) @ 0.3% (C3) and Pseudomonas fluorescens (1% WP) @ 2% (C3), respectively. The inhibition in spore germination by mancozeb (75% WP) and Pseudomonas fluorescens (1% WP) was upto 77.33% and it was 61.78% and 67.33% in treatments involving carbendazim (50% WP) and Trichoderma harzianum (1% WP) that could be exploited to devise integrated approach for disease management.

First Report of Sea buckthorn Stem Wilt Caused by Fusarium proliferatum in Liaoning, China

Sea buckthorn（Hippophae rhamnoides L.） is a flowering shrub native to cold-temperate regions of Eurasia, which is also valuable for its berries and leaves containing various vitamins and flavonoids (Pundir et al. 2021). In late June 2020, high mortality (more than 70%) was observed in sea buckthorn in a 1.6-ha seedling nursery in Chaoyang City, Liaoning province, China, where 16 Chinese and Russian cultivars (cv.) had been planted since 2014 (cv. Shenqiuhong, eshi01 through eshi15). The mortality of two introduced sea buckthorn varieties (eshi02, eshi04) was 100% (125 trees died in total). The symptoms include massive drooping leaves and dried-up stems on 6-year-old infected trees. Pieces of tree roots and stems with brown discoloration in the xylem vessels were selected. Small tissue fragments (0.2-0.5 cm) were surface disinfested (3 min in 75% ethanol, rinsed with sterile distilled water), air-dried, and placed on potato dextrose agar (PDA) medium for 5 days at 25°C in the dark. A fungus was consistently isolated from both diseased roots and stems tissues, and a representative isolate (LC-1) was harvested. Genomic DNA was extracted for amplification and sequencing of the partial translation elongation factor-1α (EF1 and EF2 primers, accession Nos. MZ669853) (O’Donnell et al. 1998) and RNA polymerase II second largest subunit (RPB2) (7cf/11aR primers, accession Nos. MZ669854) (O’Donnell et al. 2007). The sequences were further analyzed at the Fusarium MLST (https://fusarium.mycobank.org/) for identity confirmation, and showed 99.8% (over 95.2% query coverage) and 96.4% (over 88.4% query coverage) similarity to Fusarium proliferatum (NRRL 13584, 13591). Isolates on Spezieller Nahrstoffarmer agar (SNA) produced abundant aerial white mycelia and yellow pigmentation. The 30 macroconidia measured ranged from 28.5 - 62.5 × 3.2 – 5.4 μm, were thin, slender, with 3-5 septa. The aseptate microconidia ranged from 4.7 – 13.6 × 2.2 – 4.3 μm (n = 30). Pathogenicity tests were performed on healthy, potted 1-year-old sea buckthorn seedlings (cv. eshi05) using two isolates in a greenhouse at 25 °C, 80% relative humidity, and 12-hour light/dark photoperiod. Ten potted seedlings were inoculated on the stems by placing a 5-mm-diameter mycelial plug (5-day-old PDA cultures for each isolate) into the surface of a wound created with a needle, and the inoculation sites were covered with Parafilm to maintain moisture. Ten seedlings were inoculated with PDA plugs as controls. Six to ten days after inoculation, color of the leaves in the middle of the stems was variegated, and then dark necrotic lesions on leaf margins were observed. Three weeks after inoculation, 80% of inoculated stems were wilted, while control plants remained asymptomatic. The pathogen was consistently re-isolated and the recovered isolates were identified as F. proliferatum by amplifying the EF-1α gene. The typical symptoms on inoculated plants were dark to brown necrotic lesions on chlorotic leaves initially, and black withered stems in the terminal stage, similar to those observed on sea buckthorn trees infected with Fusarium sporotrichioides in Gansu and Heilongjiang provinces (Song et al. 2010; Xia et al. 2021). To our knowledge, this is the first report of sea buckthorn stem wilt caused by F. proliferatum in Liaoning province, China, which will be beneficial for expanding knowledge of Fusarium disease in sea buckthorn and provide more information for sustainable disease management in sea buckthorn.

First Report of Crown Rot of Banana Caused by Fusarium porliferatum in Georgia, USA

Crown rot is one of the most damaging disease of banana fruit characterized by rot and necrosis of crown tissues. In severe cases, the disease can spread to the pedicel and banana pulp. Crown rot can be infected by several common fungi, including Lasiodiplodia theobromae, Musicillium theobromae, Colletotrichum musae, and a complex of Fusarium spp. and lead to softening and blackening of tissues (Lassois et al., 2010; Kamel et al., 2016; Triest et al., 2016; Snowdon, 1990). In November 2020, typical crown rot of banana fruits (cv. Pisang Awak, belonging to the tetraploid AABB genome) were observed from UGA Banana Research 12 Plots, Tifton, GA, with incidence rates of 15%. Initial symptoms appeared in the infected crown of green banana fruits. As the infection progressed, the crown tissues became blackened and softened, followed by an internal development of infection affecting the peduncle and the fruit, triggered early ripening of bananas. At last, the development of necrosis on the pedicels and fruits appeared and caused the fingers to fall off. To identify the pathogen, tissue pieces (~0.25 cm2) from the infected crown and pedicles were surface-sterilized in a 10% bleach solution for 1 min, followed by 30 s in 70% EtOH. The disinfected tissues were rinsed in sterile water 3 times and cultured on potato dextrose agar (PDA) amended with 50 µg/ml streptomycin at 25°C in the dark for 5–10 days. Isolates of the pathogen were purified using the single-spore isolation method (Leslie and Summerell 2006). Colonies on PDA produced fluffy aerial mycelium and developed an intense purple pigment when viewed from the underside. A range of colony pigmentation and growth rates were observed among the isolates. The microconidia were ovoid, hyaline, or ellipse in shape. The morphological features of the isolates were identified as Fusarium proliferatum (Leslie and Summerell, 2006). To further identify the isolates, genomic DNA was extracted from a representative isolate. And the internal transcribed spacer (ITS) region, the partial elongation factor (TEF1-α) gene and the β-tubulin gene (TUB2)were amplified and sequenced using the primers ITS1/ITS4 (Yin et al. 2012), EF-1 /EF-2 (O’Donnell et al. 1998) and B-tub1 /B-tub2 (O’Donnell and Cigelnik, 1997), respectively. The amplicons were sequenced and deposited in NCBI (accessions no. MZ292989, MZ293071 for ITS: MZ346602, MZ346603 for TEF1-α and MZ346600 and MZ346601 for B-tub). The ITS, TEF1-α, and B-tub sequences of the isolates showed 100% sequence similarity with Fusarium proliferatum isolates (accessions no. MT560212, LS42312, and LT575130, respectively) using BLASTn in Genbank. For pathogenicity testing, three whole bunched bananas sterilized with 10% bleach solutions and washed by sterilized water, were cut into 5 bananas per brunch. The cut surface of the banana crown was inoculated with conidial suspension (1.0 × 107 cfu/ml) of the pathogen with pipette tips. Equal number of bananas were treated with sterilized water in the same volume as a control. All bananas were sealed in a plastic bag and incubated at 25°C. After 7 days post inoculation, all inoculated bananas showed initial crown rot symptoms while no symptoms were observed on the control bananas. The fungus was re-isolated from the symptomatic tissues of infected bananas and confirmed to be genetically identical to F. proliferatum of the original inoculated strains according to morphological characteristics and molecular identification, fulfilling Koch’s postulates. To the best of our knowledge, this is the first report of F. proliferatum causing crown rot on bananas in Georgia, USA.

First Report of Fusarium proliferatum Causing Fruit Rot on Muskmelon (Cucumis melo L.) in China

Muskmelon is an economically important crop in the world, especially in China, the largest producer of muskmelon with an annual output up to 12.7 million tonnes (Gómez-García et al. 2020). Since 2018, fruit rot was observed on muskmelon in Malianzhuang Base, the main muskmelon producing area in Shandong Province, whose disease incidence was about 25-30%. Water-soaked dark brown spots were initially appeared on the side of the fruit near the ground, then gradually expanded and covered with white mold with time. To isolate the pathogens, ten muskmelon fruits with typical symptoms were collected from different greenhouses in the base. Small tissues taken from the edge of the diseased and healthy tissues were immersed in 1% NaClO for 2 min, then soaked in 75% ethanol for 30 s, and rinsed 3 times with sterile distilled water (SDW). The sterilized tissues were naturally dried and placed on potato dextrose agar (PDA) amended with streptomycin sulfate (50 mg/L) for 7 days at 28℃. The emerging fungal mycelia were transferred to fresh PDA using the hyphal tip technology. Ten colonies were purified by single spore method and cultured on PDA for 7 days at 28℃ in the dark for morphological and molecular analyses. All colonies were flocculent with abundant white to light purple aerial hyphae, and the undersides of the colonies were observed to be from white to purple over time. Microconidia produced on PDA were hyaline, fusiform, ovoid, single cell without septum, and 4.5 to 12.7 × 2.0 to 3.6 μm in size (n=50). Macroconidia produced on carboxymethylcellulose agar (CMC) were slightly curved at both ends with three to five septa, and 17.6 to 35.7 × 2.8 to 4.0 μm in size (n=30). According to the morphological characteristics, these isolates were preliminarily identified as Fusarium sp. (Leslie and Summerell 2006). To further identify these isolates, genomic DNA of five isolates was extracted by CTAB method (Wu et al. 2001). The internal transcribed spacer (ITS) region of ribosomal DNA, translation elongation factor 1-α (TEF1) region, and the RNA polymerase II second largest subunit (RPB2) were amplified by PCR amplification with primers ITS1/ITS4, EF-1/EF-2, and RPB2-5F2/fRPB2-7cR, respectively (White et al. 1990; O’Donnell et al. 2008; Liu et al. 1999). Sequences of the five isolates were identical. The ITS, EF1-α, and RPB2 gene sequences of isolate NEAU-Mf-10-2 were submitted to NCBI GenBank with accession numbers of MZ950914, MZ960928, and MZ960929, respectively, having 100% similarity to those of Fusarium proliferatum (MK372368, MK952799 and MN245721). Phylogenetic trees were constructed based on the concatenated sequences of EF1-α and RPB2 genes using neighbour-joining and maximum-likelihood algorithms with MEGA 7.0. Two similar tree topologies both showed isolate NEAU-Mf-10-2 clustered with F. proliferatum NRRL 43665. Therefore, isolate NEAU-Mf-10-2 was identified as F. proliferatum based on morphological characteristics and phylogenetic analysis. To fulfill Koch’s postulates, ten muskmelon fruits (var. Tianbao) were soaked in 2% NaClO for 2 min, and then washed three times with SDW. Muskmelon fruits were inoculated by injecting conidia suspension (200 μL, 1×106 spores/mL) with a sterile injector. Ten other surface sterilized muskmelon fruits inoculated with sterile water were used as control. The fruits were placed in a light incubator at 28℃ with 12h light cycles for 7 days. All inoculated fruits showed symptoms highly similar to those of infected muskmelon fruits observed in the field. No symptoms were observed on fruits used as control. The Fusarium isolates were successfully re-isolated from the symptomatic fruits, and identified based on above morphological and molecular biological methods. Previous studies have reported that F. proliferatum can infect Polygonatum cyrtonema, Salvia miltiorrhiza, Allium cepa, A. sativum, and so on. To our knowledge, this is the first report of F. proliferatum causing fruit rot on muskmelon in China, which will provide basic information for designing effective prevention and control strategies on this disease.