Fungicide Sensitivity of Fusarium oxysporum f. sp. lentis and Fusarium acuminatum Affecting Lentil in the Northern Great Plains.

Fusarium oxysporum f. sp. lentis and F. acuminatum cause wilting and root rot in pulse crops including lentil. Fungicide seed treatments are widely used, but information about Fusarium spp. sensitivity in lentils is limited. Here, 30 F. oxysporum f. sp. lentis and 30 F. acuminatum isolates from Montana, southern Canada, North Dakota, and Washington were identified, tested for pathogenicity, and assayed for in vitro sensitivity to pyraclostrobin, prothioconazole, ipconazole, and thiophanate-methyl. F. oxysporum f. sp. lentis and F. acuminatum differed in their sensitivity to all fungicides. No resistant isolates were identified, but F. oxysporum f. sp. lentis had lower EC50 values in pyraclostrobin (averaging 0.47 µg a.i./ml) than F. acuminatum (averaging 0.89 µg a.i./ml) for mycelia assays. Both species had lower EC50 values in prothioconazole, averaging EC50 0.23 in F. oxysporum f. sp. lentis and 0.53 µg a.i./ml in F. acuminatum. F. oxysporum f. sp. lentis isolates had the lowest EC50 values on ipconazole compared to F. acuminatum (0.78 and 1.49 µg a.i./ml). The pathogens were least sensitive to thiophanate-methyl (1.74 µg a.i./ml for F. oxysporum f. sp. lentis and 1.91 µg a.i./ml for F. acuminatum). Overall sensitivity to the fungicides was higher in F. oxysporum f. sp. lentis than F. acuminatum. This study provides reference EC50 values while pointing to the possibility of differential fungicide efficacies on Fusarium spp. This will be helpful to monitor shifts in sensitivity of Fusarium spp. and devise robust root rot/wilt management approaches.

Identification of Crucial Genes and Regulatory Pathways in Alfalfa against Fusarium Root Rot.

Fusarium root rot, caused by Fusarium spp. in alfalfa (Medicago sativa L.), adversely impacts alfalfa by diminishing plant quality and yield, resulting in substantial losses within the industry. The most effective strategy for controlling alfalfa Fusarium root rot is planting disease-resistant varieties. Therefore, gaining a comprehensive understanding of the mechanisms underlying alfalfa's resistance to Fusarium root rot is imperative. In this study, we observed the infection process on alfalfa seedling roots infected by Fusarium acuminatum strain HM29-05, which is labeled with green fluorescent protein (GFP). Two alfalfa varieties, namely, the resistant 'Kangsai' and the susceptible 'Zhongmu No. 1', were examined to assess various physiological and biochemical activities at 0, 2, and 3 days post inoculation (dpi). Transcriptome sequencing of the inoculated resistant and susceptible alfalfa varieties were conducted, and the potential functions and signaling pathways of differentially expressed genes (DEGs) were analyzed through gene ontology (GO) classification and Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analysis. Meanwhile, a DEG co-expression network was constructed though the weighted gene correlation network analysis (WGCNA) algorithm. Our results revealed significant alterations in soluble sugar, soluble protein, and malondialdehyde (MDA) contents in both the 'Kangsai' and 'Zhongmu No. 1' varieties following the inoculation of F. acuminatum. WGCNA analysis showed the involvement of various enzyme and transcription factor families related to plant growth and disease resistance, including cytochrome P450, MYB, ERF, NAC, and bZIP. These findings not only provided valuable data for further verification of gene functions but also served as a reference for the deeper explorations between plants and pathogens.

First Report of Fusarium acuminatum Causing Leaf Spot on Schisandra chinensis in China.

Schisandra chinensis (Turcz.) Baill. is a popular and widely cultivated medicinal herb in China, which has rich nutritional value and medicinal effect. In August 2022, leaves with oval and irregularly circular light brown spots from 2 to 10 mm wide with white centers were found on Schisandra chinensis growing in Fusong district (127°28'E, 42°33'N) of Jilin, China. The symptoms were observed in 20% of the plants of a 2 ha-1 field of Schisandra chinensis. About 50% of the leaf areas were affected. As the disease developed, the lesions grew larger and developed necrotic centers. Leaves with light brown spot symptoms from five plants were collected from the field. Five leaf pieces (3 to 5 mm2) were excised from lesion margins, surface sterilized based on Ju et al. (Ju et al. 2021), and incubated on potato dextrose agar (PDA) at 25°C. Six single spores were isolated from five independently infected isolates for pure culture using the single spore isolation technique (Zhang. 2003). Representative single spore isolate (ZWWZH) was selected from pure cultures for further culture. After 5 days, fluffy white aerial mycelium with pink pigmentation on the underside of the colony were observed on PDA. Mycelia became pinkish-brown as the culture aged. Microscopic observations showed the presence of elongated or pointed, and thick-walled macroconidia (n = 50), predominantly three septate, 3.40 to 7.50 × 40.34 to 61.29 µm were observed. Chlamydospores formed in chains within or on top of the mycelium. The primers ITS1/ITS4 (White et al. 1990) and Bt-2a/Bt-2b (Robideau et al., 2011) were used to amplify the internal transcribed spacer (ITS) rDNA and ß-tubulin (TUB2) region, respectively. The obtained sequences were submitted to GenBank under accession numbers for OQ629789 (ITS) and OQ803521(TUB2). BLASTn analysis of both ITS sequence and TUB2 sequence, revealed 100% and 99.92% sequence identity with F. acuminatum MT566456, MT560377 and KJ396328, respectively. The pathogen was identified as F. acuminatum based on morphological and molecular data. Pathogenicity tests were carried out in the greenhouse. Select five healthy Schisandra chinensis seedlings, each with each healthy leaf surfaces inoculated a 1 × 106 spores/mL solution, 3 wells on one side, 10 µL per well. Sterile ddH2O was used in the control experiment. The inoculated seedlings were incubated at 25°C with a relative humidity of 65 to 70% in a greenhouse. Four days after inoculation, all inoculated leaves exhibited the same symptoms as observed in the field, while the controls showed no symptoms. The experiment was repeated three more times with similar results. The re-isolated fungi from the inoculated plants had the same morphology and DNA sequences as the original isolate (ZWWZH) obtained from the field samples, completing Koch's postulates. To our knowledge, this is the first report of F. acuminatum causing leaf spot on Schisandra chinensis in China. F. acuminatum has seriously affected the quality of Schisandra chinensis production. The identification of leaf spot caused by F. acuminatum will enable farmers to identify practices to minimize disease on this important crop.

First report of peanut root rot caused by Fusarium acuminatum in Shandong Province, China.

Peanut (Arachis hypogaea L.) is one of the most economically important crops as a major source of edible oil and protein. In July 2021, a root rot disease was observed on peanut in Laiwu (36º22' N, 117º67' E), Shandong Province, China. Disease incidence was approximately 35%. Disease symptoms included root rot, vessels with a brown to dark brown discoloration, plus progressive yellowing and wilting of leaves from the base leading to whole plant death. To determine the causal agent, symptomatic roots with typical lesions were cut into small pieces, surface sterilized in 75% ethanol for 30 s, and 2% NaClO for 5 min, rinsed three times in sterile water and placed on potato dextrose agar (PDA) at 25℃ (Leslie and Summerell 2006). After 3 days of incubation, whitish-pink to red colonies growing from the roots were observed. Eight single-spore isolates had identical morphological traits that were similar to those of Fusarium spp. A representative isolate (LW-5) was used for morphological characterization, molecular analysis, and pathogenicity test. On PDA, the isolate formed dense aerial mycelia, which were initially white, then became deep pink with age and formed red pigments in the medium. On carnation leaf agar (CLA), macroconidia with 3 to 5 septa were abundant, relatively slender, curved to lunate, that measured 23.7 to 52.2 × 3.6 to 5.4 µm (n=50). Microconidia were oval, 0 to 1 septa. Chlamydospores were globose with a smooth outer wall in chains or single. Following DNA extraction of isolate LW-5, primers EF1-728F/EF1-986R (Carbone et al., 1999), RPB1U/RPB1R, and RPB2U/RPB2R (Ponts et al., 2020) were used to amplify the partial translation elongation factor 1 alpha (TEF1-α), RNA polymerase II largest subunit (RPB1), and RNA polymerase II second largest subunit (RPB2) regions for DNA sequencing, respectively. BLASTn analysis of TEF1-α (GenBank accession No. OP838084), RPB1 (OP838085), and RPB2 (OP838086) sequences, revealed 99.66, 99.87, and 99.09% identity with those of F. acuminatum (OL772800, OL772952 and OL773104), respectively. Isolate LW-5 was identified as F. acuminatum based on morphology and molecular analysis. Twenty Huayu36 peanut seeds were each planted in a 500-ml sterile pot containing 300 g of autoclaved potting medium (nutritive soil: vermiculite=2:1 in volume). Two weeks after seedling emergence, 1 cm depth of the potting medium was dug around the plants to expose the taproot. Two 5-mm wounds per taproot were scratched with a sterile syringe needle. Potting medium in each pot of 10 inoculated plants was mixed with 5 ml of conidial suspension (106 conidia per ml). The other 10 plants were used as non-inoculated controls and treated with sterile water in the same manner. The seedlings were placed in a plant growth chamber maintained at 25°C, RH >70%, 16-h light per day, and irrigated with sterile water. After 4 weeks, inoculated plants exhibited yellowing and wilting symptoms that were similar to those observed in the field, while non-inoculated control plants had no symptoms. F. acuminatum was re-isolated from diseased roots and confirmed using morphological features and DNA sequence analysis of TEF1-α, RPB1 and RPB2. F. acuminatum was reported to cause root rot on Ophiopogon japonicus (Linn. f.) (Tang et al., 2020), Polygonatum odoratum (Li et al., 2021), and Schisandra chinensis (Shen et al., 2022) in China. To our knowledge, this is the first report of root rot on peanut caused by F. acuminatum in Shandong Province, China. Our report will provide crucial information for studying the epidemiology and management of this disease.

Characterization of a Plant Growth-Promoting Endohyphal Bacillus subtilis in Fusarium acuminatum from Spiranthes sinensis.

Successful seed germination and seedling growth in orchids require an association with mycorrhizal fungi. An endophytic Fusarium fungal strain YZU 172038 exhibiting plant growth-promoting (PGP) ability was isolated from the roots of Spiranthes sinensis (Orchidaceae). The harboring endohyphal bacteria were detected in the hypha by SYTO-9 fluorescent nucleic acid staining, fluorescence in situ hybridization (FISH), and PCR amplification of the 16S rDNA gene's region. Consequently, one endohyphal bacterium (EHB) - a strain YZSR384 was isolated and identified as Bacillus subtilis based on morphology, phylogenetic analysis, and genomic information. The results indicated that the strain YZSR384 could significantly promote the growth of rice roots and shoots similar to its host fungus. Its indole acetic acid (IAA) production reached a maximum of 23.361 µg/ml on the sixth day after inoculation. The genome annotation revealed several genes involved in PGP traits, including the clusters of genes encoding the IAA (trpABCDEFS), the siderophores (entABCE), and the dissolving phosphate (pstABCS and phoABDHPR). As an EHB, B. subtilis was first isolated from endophytic Fusarium acuminatum from S. sinensis.

First report of Atractylodes lancea leaf spot caused by Fusarium acuminatum in China.

Atractylodes lancea Thunb. DC (cangzhu) is a traditional Chinese medicinal plant (Cai et al., 2020). In June 2020, leaf spots were observed in A. lancea plants at the Chongqing Institute of Medicinal Plant Cultivation located in Nanchuan District, Chongqing, China (29°8'26.46″ N, 107°13'23'21″ E). Approximately 75% of the plants displayed leaf spot, partial leaf wilting, and stunted growth, and some plants died. To determine the cause of this disease, five typical leaf spots were cut into small pieces. The pieces were successively surface-disinfected with 0.5% NaClO for 1 min and 75% ethanol for 30 s, washed thrice with sterile water, and placed on potato dextrose agar (PDA) to incubate at 25 ℃. These isolates initially formed abundant white aerial mycelium, then gradually developed a rose pigmentation with a brownish color in the center and grayish rose at the periphery of the colony (Li et al. 2019). Mycelial tips were picked and placed on carnation leaf agar (CLA) and inoculated for 7 days. The macroconidia of the isolates were slender, distinctively curved in the bottom half of the apical cell, and sickle-shaped, with 3-4 septa. They ranged in size from 16.68-26.49 × 1.48-2.34 µm (n=50). The microconidia were fusiform with or without one septum. Their size ranged from 6.19-11.02 × 1.25-1.43 µm (n=50) (Li et al. 2019). The morphological characteristics of the isolates were consistent with those of Fusarium spp. PCR amplification and DNA sequencing of the internal transcribed spacer (ITS) region and ß-tubulin (TUB2) gene were performed using the primers ITS1/ITS4 (White et al. 1990) and Bt-2a/Bt-2b (Robideau et al. 2011), respectively. BLASTn analysis revealed that the ITS sequences of the isolates were 100% identical to those of the F. acuminatum isolates from the Fusarium MLST database (http://isolate.fusariumdb.org/guide.php). Further analysis revealed that the TUB2 sequences were 99.14% identical to those of the F. acuminatum strain S16 isolates (MF662644) from the GeneBank database of the NCBI server. Based on the morphology and sequence analyses, the isolates were identified as F. acuminatum. Pathogenicity tests were conducted on 1.5-year-old A. lancea plants by inoculating spore suspensions under greenhouse conditions (25°C). For this, wound were made on leaves by piercing with sterilized toothpicks. 30 µl of spore suspension containing 2 × 106 conidia/ml was placed on each wound. Wounds on the leaves of control plants were inoculated with 10 µl of sterile distilled water. There were three plants for each treatment. After incubation at 25 °C for 5 days in a greenhouse, the leaves of the treated plants all showed partial wilting, consistent with the field observations. No symptoms were observed in controlled plants. The fungi were again isolated from the symptomatic tissues and were identical to the original isolate. The experiment was repeated twice with similar results. Pathogenicity symptoms were similar to what was first observed in the field and the isolated fungi were verified based on morphological characteristics, thus fulfilling Koch's postulate. To the best of our knowledge, this is the first time that A. lancea leaf spot caused by F. acuminatum has been discovered in China. The leaf spot caused by F. acuminatum on A. lancea has serious yield loss, and proper control measures should be applied.

[Identification and biological characteristics of a pathogen causing leaf blight of Rehmannia glutinosa].

Leaf blight outbroke in Rehmannia glutinosa plantation in Wenxian county, Henan province in 2019. R. glutinosa plants with diseased leaves were collected from the plantation, and three strains were isolated from the diseased leaf samples. Pathogenicity test, morphological observation, and phylogenetic analysis of ITS, EF1-α, and Tub suggested that they were respectively Fusarium proliferatum, F. oxysporum, and F.acuminatum. Among them, F. acuminatum, as a pathogen of R. glutinosa leaf disease, had never been reported. To clarify the biological characteristics of F. acuminatum, this study tested the influence of light, pH, temperature, medium, carbon source, and nitrogen source on the mycelial growth rate of the pathogen during a 5-day culture period, and explored the lethal temperature. The results showed that the mycelia grew well under the photoperiod of 12 h light/12 h darkness, at 5-40 ℃(optimal temperature: 25 ℃), at pH 4-11(optimal pH: 7.0), on a variety of media(optimal medium: oatmeal agar), and in the presence of diverse carbon and nitrogen sources(optimal carbon source: soluble starch; optimal nitrogen source: sodium nitrate). The lethal temperature was verified to be 51 ℃(10 min). The conclusion is expected to lay a scientific basis for diagnosis and control of R. glutinosa leaf diseases caused by F. acuminatum.

Genetic Diversity and Potential Inoculum Sources of Fusarium Species Causing Cankers in Bareroot-Propagated Almond Trees in California Nurseries.

Previous research determined that Fusarium acuminatum and F. avenaceum are important causal agents of a canker disease in bareroot-propagated fruit and nut trees in California that emerges during cold storage or after transplanting. The disease largely disappeared after 2001, but it reemerged in 2011 in almond trees in at least one nursery. This motivated further study of the etiology and epidemiology of the disease by undertaking studies to determine distribution of the pathogens throughout almond nursery propagation systems and trace possible sources of inoculum. Research initiated in 2013 detected pathogenic Fusarium spp. throughout the almond propagation system, including in healthy trees, in soils, on wheat rotation crops, on equipment, and in the cold-storage facility air. In addition to the two Fusarium spp. implicated previously, F. brachygibbosum and a new Fusarium species, F. californicum, were found to be pathogenic on almond trees. Multilocus sequence typing and somatic compatibility testing confirmed that isolates within a species collected from different materials in the nursery were all highly genetically similar and likely of one clonal lineage. These findings affirm that equipment surfaces, wheat rotation crops, soil, cold-storage facility air, and asymptomatic almond tree materials (i.e., rootstock cuttings, budwood, and scions) can potentially contribute inoculum to increase disease prevalence and severity.

Identification and biological characteristics of a pathogen causing leaf blight of Rehmannia glutinosa / 中国中药杂志

Leaf blight outbroke in Rehmannia glutinosa plantation in Wenxian county, Henan province in 2019. R. glutinosa plants with diseased leaves were collected from the plantation, and three strains were isolated from the diseased leaf samples. Pathogenicity test, morphological observation, and phylogenetic analysis of ITS, EF1-α, and Tub suggested that they were respectively Fusarium proliferatum, F. oxysporum, and F.acuminatum. Among them, F. acuminatum, as a pathogen of R. glutinosa leaf disease, had never been reported. To clarify the biological characteristics of F. acuminatum, this study tested the influence of light, pH, temperature, medium, carbon source, and nitrogen source on the mycelial growth rate of the pathogen during a 5-day culture period, and explored the lethal temperature. The results showed that the mycelia grew well under the photoperiod of 12 h light/12 h darkness, at 5-40 ℃(optimal temperature: 25 ℃), at pH 4-11(optimal pH: 7.0), on a variety of media(optimal medium: oatmeal agar), and in the presence of diverse carbon and nitrogen sources(optimal carbon source: soluble starch; optimal nitrogen source: sodium nitrate). The lethal temperature was verified to be 51 ℃(10 min). The conclusion is expected to lay a scientific basis for diagnosis and control of R. glutinosa leaf diseases caused by F. acuminatum.

First report of root rot of Polygonatum odoratum caused by Fusarium acuminatum in China.

Polygonatum odoratum (Mill.) Druce is used in traditional Chinese medicine and also consumed as a vegetable. In July of 2020, a root rot was observed on P. odoratum in a commercial field located in Benxi city (41º23'32" N, 124º04'27" E), Liaoning province of China. About 35% diseased plants in the field exhibited poor vigor, were stunted, and had yellow or brown leaves. Affected plants wilted and died. Roots of the plants were poorly developed, had brown lesions, and later rotted. To determine the causal agent, symptomatic roots with typical lesions were cut into small pieces, surface sterilized in 2% sodium hypochlorite (NaOCl) for 3 min, rinsed three times in sterile water, and plated onto PDA medium. After 5 days of incubation at 26°C, whitish-pink to red colonies growing from the root samples were observed and transferred to carnation leaf agar (CLA). Ten single conidia isolates obtained from the colonies on CLA were incubated at 26°C for 10 days. Abundant macroconidia were formed in sporodochia on CLA. Macroconidia were falcate, slender, distinctively curved in the bottom half of the apical cell, had 3 to 5 septa, and 33.1 - 46.3 × 5.0 - 7.2 µm (n=50). Chlamydospores formed in chains or single, measuring 13.8 to 14.5 µm in diameter. Microconidia were not observed on CLA. Morphologically, the isolates were identified as Fusarium acuminatum (Leslie and Summerell, 2006). To confirm the species identity, the partial translation elongation factor 1 alpha (TEF1-α) gene and rDNA internal transcribed spacer (ITS) region of isolate YZ5-2 were amplified and sequenced (O'Donnell et al. 2015; White et al.1990). BLASTn analysis of both TEF sequence (MW423623) and ITS sequence (MW423626), revealed 100% (696/692 bp) and 99.64% (563/602 bp) sequence identity with F. acuminatum LC546967 and MF509746, respectively. Pathogenicity tests were carried out in the greenhouse. A conidial suspension (2 × 106 conidia per ml) of the isolate YZ5-2 was prepared from 7-day-old cultures grown in potato dextrose broth (PDB) o n a shaker (140 rpm) at 26±1°C. Five 12-liter pots were filled with sterilized field soil and each pot was drenched with 300ml of conidial suspension. Five control pots with sterilized field soil and 300 ml PDB were also included. Roots of 20 healthy P. odoratum plants were surface disinfected in 2% NaOCl for 3 min, and rinsed with sterilized water. Prior to planting, 2-3 pinholes (1.5× 1.0 mm) were made using a toothpick on the root surface of each plant, and they were then planted in each pot (2 plants per pot). All ten pots were maintained in a greenhouse at 22-26°C for 40 days. Plants grown in the pots inoculated with the conidial suspension were stunted, had yellowed leaves and were wilted. The roots of the affected plants were rotted. Disease symptoms were similar to those observed in field. Non-inoculated control plants had no symptoms. F. acuminatum was reisolated from inoculated plants and was identical to the original isolate. The experiment was repeated twice with similar results. To our knowledge, this is the first report of root rot of P. odoratum caused by F. acuminatum in China. The disease has since been observed on P. odoratum in fields in Liaoyang and Qingyuan city in Liaoning Province of China, and it has become an important threat to P. odoratum production in China.

Host susceptibility factors render ripe tomato fruit vulnerable to fungal disease despite active immune responses.

The increased susceptibility of ripe fruit to fungal pathogens poses a substantial threat to crop production and marketability. Here, we coupled transcriptomic analyses with mutant studies to uncover critical processes associated with defense and susceptibility in tomato (Solanum lycopersicum) fruit. Using unripe and ripe fruit inoculated with three fungal pathogens, we identified common pathogen responses reliant on chitinases, WRKY transcription factors, and reactive oxygen species detoxification. We established that the magnitude and diversity of defense responses do not significantly impact the interaction outcome, as susceptible ripe fruit mounted a strong immune response to pathogen infection. Then, to distinguish features of ripening that may be responsible for susceptibility, we utilized non-ripening tomato mutants that displayed different susceptibility patterns to fungal infection. Based on transcriptional and hormone profiling, susceptible tomato genotypes had losses in the maintenance of cellular redox homeostasis, while jasmonic acid accumulation and signaling coincided with defense activation in resistant fruit. We identified and validated a susceptibility factor, pectate lyase (PL). CRISPR-based knockouts of PL, but not polygalacturonase (PG2a), reduced susceptibility of ripe fruit by >50%. This study suggests that targeting specific genes that promote susceptibility is a viable strategy to improve the resistance of tomato fruit against fungal disease.

Seasonal Variation in Host Susceptibility to Fusarium Canker in Young Almond Trees.

Loss of water that reduces the relative water content (RWC) of bark can occur during processing, cold storage, and planting of bare-root stone fruit trees. In California nurseries and newly planted orchards, this stress can predispose young almond trees (Prunus dulcis) to a canker disease caused primarily by Fusarium species. While reduced bark RWC contributes to disease development, anecdotal observations suggest a seasonal effect on host physiology may also influence disease severity. We evaluated the effect of season and the impact of drying and reduced RWC on susceptibility of almond branch segments excised from orchard trees (cv. Nonpareil) to Fusarium acuminatum, Fusarium avenaceum, Fusarium brachygibbosum, and Fusarium californicum sp. nov. With lesion size as the criterion, excised inoculated branch segments were most susceptible in spring, of intermediate susceptibility during winter dormancy, and least susceptible during summer and fall. Consistent with an earlier study, branches with RWC between 80 and 85% yielded lesions that were significantly larger than lesions from branches with bark that was above or below that range. However, the effect of reduced bark moisture on lesion size was only apparent in the spring. These results affirm the importance of avoiding conditions that diminish moisture status in bare-root almond trees in Fusarium canker disease management, especially during transport and planting operations in the spring, a period of high physiological vulnerability. California nurseries apply fungicides to bare-root trees prior to cold storage to reduce "mold" growth. Of eight fungicides currently registered for use on almond trees, fludioxonil (Scholar), fluopyram/trifloxystrobin (Luna Sensation), and fluxapyroxad/pyraclostrobin (Merivon) were most inhibitory to in vitro mycelial growth of F. acuminatum, F. avenaceum, and F. brachygibbosum. However, our almond branch disease assay did not demonstrate preventive or curative fungicide action against infections by F. acuminatum or F. avenaceum.

Effect of wheat infection timing on Fusarium head blight causal agents and secondary metabolites in grain.

Fusarium head blight (FHB) results in yield loss and damaging contamination of cereal grains and can be caused by several Fusarium species. The objective of the present study was to determine, in a greenhouse experiment on winter wheat, how FHB was affected by timing of infection (0, 3, 6 or 9 days after anthesis, daa) by the aggressive species Fusarium graminearum compared to the relatively weak species Fusarium avenaceum, Fusarium poae and Fusarium acuminatum. Measures of FHB development were: symptoms in spikes (visually assessed), fungal biomass (quantified by real time quantitative PCR) and accumulation of fungal secondary metabolites (quantified by liquid chromatography-tandem mass spectrometry) in kernels. With regard to symptoms, F. graminearum was unaffected by inoculation timing, while the weaker pathogens caused greater disease severity at later timings. In contrast, the accumulation of F. graminearum biomass was strongly affected by inoculation timing (3 daa ≥ 6 daa ≥ 0 daa = 9 daa), while colonization by the weaker pathogens was less influenced. Similarly, F. graminearum secondary metabolite accumulation was affected by inoculation timing (3 daa ≥ 6 daa ≥ 0 daa = 9 daa), while that of the weaker species was less affected. However, secondary metabolites produced by these weaker species tended to be higher from intermediate-late inoculations (6 daa). Overall, infection timing appeared to play a role particularly in F. graminearum colonization and secondary metabolite accumulation. However, secondary metabolites of weaker Fusarium species may be relatively more abundant when environmental conditions promote spore dispersal later in anthesis, while secondary metabolites produced by F. graminearum are relatively favored by earlier conducive conditions.

Investigation of Some Parameters Affecting Methyl OrangeRemoval by Fusarium acuminatum

ABSTRACT Dye stuff released to the ecosystem from textile industries cause a serious contamination and become a major environmental problem over the last few decades. As biological decolorization of textile wastewater is an important issue, Fusarium . acuminatum was used to removal of a frequently used textile dye, methyl orange. Live pellet of Fusarium acuminatum was used and decolorization studies performed in various temperatures and pH conditions with different dye concentrations. The highest decolorization rate was observed at 35ᴼC. 60 mg/L was found as the optimum initial dye concentration. In the pH range of 3-4, decolorization rate was approximately 70%. It was seen that Fusarium acuminatum have the great ability of the methyl orange removal. To our knowledge, it took place for the first time in the literature.