Complexity of fungal polyketide biosynthesis and function.

Where does one draw the line between primary and secondary metabolism? The answer depends on the perspective. Microbial secondary metabolites (SMs) were at first believed not to be very important for the producers because they are dispensable for growth under laboratory conditions. However, such compounds become important in natural niches of the organisms, and some are of prime importance for humanity. Polyketides are an important group of SMs with aflatoxin as a well-known and well-characterized example. In Aspergillus spp., all 34 afl genes encoding the enzymes for aflatoxin biosynthesis are located in close vicinity on chromosome III in a so-called gene cluster. This led to the assumption that most genes required for polyketide biosynthesis are organized in gene clusters. Recent research, however, revealed an enormous complexity of the biosynthesis of different polyketides, ranging from individual polyketide synthases to a gene cluster producing several compounds, or to several clusters with additional genes scattered in the genome for the production of one compound. Research of the last decade furthermore revealed a huge potential for SM biosynthesis hidden in fungal genomes, and methods were developed to wake up such sleeping genes. The analysis of organismic interactions starts to reveal some of the ecological functions of polyketides for the producing fungi.

Transcriptomic analysis unveils alterations in the genetic expression profile of tree peony (Paeonia suffruticosa Andrews) infected by Alternaria alternata.

BACKGROUND: Black spot disease in tree peony caused by the fungal necrotroph A. alternata, is a primary limiting factor in the production of the tree peony. The intricate molecular mechanisms underlying the tree peony resistance to A. alternata have not been thoroughly investigated. RESULTS: The present study utilized high-throughput RNA sequencing (RNA-seq) technology to conduct global expression profiling, revealing an intricate network of genes implicated in the interaction between tree peony and A. alternata. RNA-Seq libraries were constructed from leaf samples and high-throughput sequenced using the BGISEQ-500 sequencing platform. Six distinct libraries were characterized. M1, M2 and M3 were derived from leaves that had undergone mock inoculation, while I1, I2 and I3 originated from leaves that had been inoculated with the pathogen. A range of 10.22-11.80 gigabases (Gb) of clean bases were generated, comprising 68,131,232 - 78,633,602 clean bases and 56,677 - 68,996 Unigenes. A grand total of 99,721 Unigenes were acquired, boasting a mean length of 1,266 base pairs. All these 99,721 Unigenes were annotated in various databases, including NR (Non-Redundant, 61.99%), NT (Nucleotide, 45.50%), SwissProt (46.32%), KEGG (Kyoto Encyclopedia of Genes and Genomes, 49.33%), KOG (clusters of euKaryotic Orthologous Groups, 50.18%), Pfam (Protein family, 47.16%), and GO (Gene Ontology, 34.86%). In total, 66,641 (66.83%) Unigenes had matches in at least one database. By conducting a comparative transcriptome analysis of the mock- and A. alternata-infected sample libraries, we found differentially expressed genes (DEGs) that are related to phytohormone signalling, pathogen recognition, active oxygen generation, and circadian rhythm regulation. Furthermore, multiple different kinds of transcription factors were identified. The expression levels of 10 selected genes were validated employing qRT-PCR (quantitative real-time PCR) to confirm RNA-Seq data. CONCLUSIONS: A multitude of transcriptome sequences have been generated, thus offering a valuable genetic repository for further scholarly exploration on the immune mechanisms underlying the tree peony infected by A. alternata. While the expression of most DEGs increased, a few DEGs showed decreased expression.

Biocontrol potential and growth-promoting effect of endophytic fungus Talaromyces muroii SD1-4 against potato leaf spot disease caused by Alternaria alternata.

BACKGROUND: Alternaria alternata is the primary pathogen of potato leaf spot disease, resulting in significant potato yield losses globally. Endophytic microorganism-based biological control, especially using microorganisms from host plants, has emerged as a promising and eco-friendly approach for managing plant diseases. Therefore, this study aimed to isolate, identify and characterize the endophytic fungi from healthy potato leaves which had great antifungal activity to the potato leaf spot pathogen of A. alternata in vitro and in vivo. RESULTS: An endophytic fungal strain SD1-4 was isolated from healthy potato leaves and was identified as Talaromyces muroii through morphological and sequencing analysis. The strain SD1-4 exhibited potent antifungal activity against the potato leaf spot pathogen A. alternata Lill, with a hyphal inhibition rate of 69.19%. Microscopic and scanning electron microscope observations revealed that the strain SD1-4 grew parallel to, coiled around, shrunk and deformed the mycelia of A. alternata Lill. Additionally, the enzyme activities of chitinase and ß-1, 3-glucanase significantly increased in the hyphae of A. alternata Lill when co-cultured with the strain SD1-4, indicating severe impairment of the cell wall function of A. alternata Lill. Furthermore, the mycelial growth and conidial germination of A. alternata Lill were significantly suppressed by the aseptic filtrate of the strain SD1-4, with inhibition rates of 79.00% and 80.67%, respectively. Decrease of leaf spot disease index from 78.36 to 37.03 was also observed in potato plants treated with the strain SD1-4, along with the significantly increased plant growth characters including plant height, root length, fresh weight, dry weight, chlorophyll content and photosynthetic rate of potato seedlings. CONCLUSION: The endophyte fungus of T. muroii SD1-4 isolated from healthy potato leaves in the present study showed high biocontrol potential against potato leaf spot disease caused by A. alternata via direct parasitism or antifungal metabolites, and had positive roles in promoting potato plant growth.

The SET-Domain-Containing Protein MdSDG26 Negatively Regulates Alternaria alternata Resistance in Apple.

Apple leaf spot is one of the most devastating diseases in the apple industry, caused by Alternaria alternata f. sp mali (A. alternata). SET-domain group (SDG) proteins function as the histone methyltransferases and participate in plant development and stress responses. However, whether SDG proteins are associated with A. alternata resistance is largely unclear. Here, we describe the pathogen-inducible MdSDG26 gene in apple (Malus × domestica). MdSDG26 has two transcript variants that function similarly in catalyzing histone methylation and A. alternata resistance. Transient overexpression of MdSDG26 increased the global levels of H3K4me3 and H3K36me3, whereas knockdown of MdSDG26 only reduced the H3K36me3 level. Transcriptome analysis revealed that MdSDG26 affected the genome-wide transcriptome changes in response to A. alternata infection. ChIP-qPCR analysis demonstrated that MdSDG26 modulates the levels of H3K36me3 and H3K4me3 at both the promoter and exon regions of MdNTL9. As a negative regulator of A. alternata resistance in apples, MdNTL9 plays a pivotal role in MdSDG26-mediated resistance to A. alternata. Therefore, our findings provide compelling evidence for the regulatory function of MdSDG26 in histone methylation and its molecular role in conferring resistance to A. alternata.

Mould allergen Alt a 1 spiked with the micronutrient retinoic acid reduces Th2 response and ameliorates Alternaria allergy in BALB/c mice.

BACKGROUND: We investigated the biological function of the mould allergen Alt a 1 as a carrier of micronutrients, such as the vitamin A metabolite retinoic acid (RA) and the influence of RA binding on its allergenicity in vitro and in vivo. METHODS: Alt a 1-RA complex formation was analyzed in silico and in vitro. PBMCs from Alternaria-allergic donors were stimulated with Alt a 1 complexed with RA (holo-Alt a 1) or empty apo-Alt a 1 and analyzed for cytokine production and CD marker expression. Serum IgE-binding and crosslinking assays to apo- and holo-protein were correlated to B-cell epitope analysis. Female BALB/c mice already sensitized to Alt a 1 were intranasally treated with apo-Alt a 1, holo-Alt a 1 or RA alone before measuring anaphylactic response, serum antibody levels, splenic cytokines and CD marker expression. RESULTS: In silico docking calculations and in vitro assays showed that the extent of RA binding depended on the higher quaternary state of Alt a 1. Holo-Alt a 1 loaded with RA reduced IL-13 released from PBMCs and CD3+CD4+CRTh2 cells. Complexing Alt a 1 to RA masked its IgE B-cell epitopes and reduced its IgE-binding capacity. In a therapeutic mouse model of Alternaria allergy nasal application of holo-Alt a 1, but not of apo-Alt a 1, significantly impeded the anaphylactic response, impaired splenic antigen-presenting cells and induced IL-10 production. CONCLUSION: Holo-Alt a 1 binding to RA was able to alleviate Th2 immunity in vitro, modulate an ongoing Th2 response and prevent anaphylactic symptoms in vivo, presenting a novel option for improving allergen-specific immunotherapy in Alternaria allergy.

The G-protein alpha subunit AaGA1 positively regulates vegetative growth, appressorium-like formation, and pathogenicity in Alternaria alternata.

AIMS: The Gα subunit is a major component of heterotrimeric G proteins, which play a crucial role in the development and pathogenicity of several model fungi. However, its detailed function in the causal agent of pear black spot (Alternaria alternata) is unclear. Our aim was to understand the characteristics and functions of AaGA1 in A. alternata. METHODS AND RESULTS: AaGA1 was cloned from A. alternata in this study, which encodes 353 amino acids and has a "G-alpha" domain. Mutant ΔAaGA1 resulted in reduced vegetative growth, conidiation, and spore germination. Especially, mutant ΔAaGA1 produced only fewer conidia on the V8A medium, and spore formation-related genes AbaA, BrlA, and WetA were significantly downregulated. More tolerance against cell wall-inhibiting agents was observed after the deletion of AaGA1. Moreover, AaGA1 deletion led to a significant reduction in melanin and toxin production. Interestingly, deletion of AaGA1 resulted in defective appressorium-like formations, complete loss of the ability to penetrate cellophane, and decreased infection on non-wound inoculated tobacco leaves. Cell wall-degrading enzyme-related genes PME, CL, Cut2, and LC were significantly downregulated in mutant ΔAaGA1 mutant, significantly reducing virulence on wound-inoculated pear fruits. CONCLUSIONS: The G protein alpha subunit AaGA1 is indispensable for fungal development, appressorium-like formations, and pathogenicity in A. alternata.

Fermentation of waste water from agar processing with Bacillus subtilis by metabolomic analysis.

Fungal infection has become a major threat to crop loss and affects food safety. The waste water from agar processing industries extraction has a number of active substances, which could be further transformed by microorganisms to synthesize antifungal active substances. In this study, Bacillus subtilis was used to ferment the waste water from agar processing industries extraction to analyze the antifungal activity of the fermentation broth on Alternaria alternata and Alternaria spp. Results showed that 25% of the fermentation broth was the most effective in inhibited A. alternata and Alternaria spp., with fungal inhibition rates of 99.9% and 96.1%, respectively, and a minimum inhibitory concentration (MIC) was 0.156 µg/mL. Metabolomic analysis showed that flavonoid polyphenols such as coniferyl aldehyde, glycycoumarin, glycitin, and procyanidin A1 may enhance the inhibitory activity against the two pathogenic fungal strains. Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis showed that polyphenols involved in the biosynthesis pathways of isoflavonoid and phenylpropanoid were upregulated after fermentation. The laser confocal microscopy analyses and cell conductivity showed that the cytoplasm of fungi treated with fermentation broth was destroyed. This study provides a research basis for the development of new natural antifungal agents and rational use of seaweed agar waste. KEY POINTS: • Bacillus subtilis fermented waste water has antifungal activity • Bacillus subtilis could transform active substances in waste water • Waste water is a potential raw material for producing antifungal agents.

Molecular Insights into the Defense of Dioscorea opposita Cultivar Tiegun Callus Against Pathogenic and Endophytic Fungal Infection Through Transcriptome Analysis.

Dioscorea opposita cultivar Tiegun is an economically important crop with high nutritional and medicinal value. Plants can activate complex and diverse defense mechanisms after infection by pathogenic fungi. Moreover, endophytic fungi can also trigger the plant immune system to resist pathogen invasion. However, the study of the effects of endophytic fungi on plant infection lags far behind that of pathogenic fungi, and the underlying mechanism is not fully understood. Here, the black spot pathogen Alternaria alternata and the endophytic fungus Penicillium halotolerans of Tiegun were identified and used to infect calli. The results showed that A. alternata could cause more severe membrane lipid peroxidation, whereas P. halotolerans could rapidly increase the activity of the plant antioxidant enzymes superoxide dismutase, peroxidase, and catalase; thus, the degree of damage to the callus caused by P. halotolerans was weaker than that caused by A. alternata. RNA sequencing analysis revealed that various plant defense pathways, such as phenylpropanoid biosynthesis, flavonoid biosynthesis, plant hormone signal transduction, and the mitogen-activated protein kinase signaling pathway, play important roles in triggering the plant immune response during fungal infection. Furthermore, the tryptophan metabolism, betalain biosynthesis, fatty acid degradation, flavonoid biosynthesis, tyrosine metabolism, and isoquinoline alkaloid biosynthesis pathways may accelerate the infection of pathogenic fungi, and the ribosome biogenesis pathway in eukaryotes may retard the damage caused by endophytic fungi. This study lays a foundation for exploring the infection mechanism of yam pathogens and endophytic fungi and provides insight for effective fungal disease control in agriculture.

Biocontrol activity of an endophytic Alternaria alternata Aa-Lcht against apple Valsa canker.

Apple Valsa canker (AVC), caused by Valsa mali, is the most serious branch disease for apples in East Asia. Biocontrol constitutes a desirable alternative strategy to alleviate the problems of orchard environment pollution and pathogen resistance risk. It is particularly important to explore efficient biocontrol microorganism resources to develop new biocontrol technologies and products. In this study, an endophytic fungus, which results in the specific inhibition of the growth of V. mali, was isolated from the twig tissue of Malus micromalus with a good tolerance to AVC. The fungus was identified as Alternaria alternata, based on morphological observations and phylogenetic analysis, and was named Aa-Lcht. Aa-Lcht showed a strong preventive effect against AVC, as determined with an in vitro twig evaluation method. When V. mali was inhibited by Aa-Lcht, according to morphological and cytological observations, the hyphae was deformed and it had more branches, a degradation in protoplasm, breakages in cell walls, and then finally died completely due to mycelium cells. Transcriptome analysis indicated that Aa-Lcht could suppress the growth of V. mali by inhibiting the activity of various hydrolases, destroying carbohydrate metabolic processes, and damaging the pathogen membrane system. It was further demonstrated that Aa-Lcht could colonize apple twig tissues without damaging the tissue's integrity. More importantly, Aa-Lcht could also stimulate the up-regulated expression of defense-related genes in apples together with the accumulation of reactive oxygen species and callose deposition in apple leaf cells. Summarizing the above, one endophytic biocontrol resource was isolated, and it can colonize apple twig tissue and play a biocontrol role through both pathogen inhibition and resistance inducement.

First Report of Fruit Scab Caused by Alternaria alternata on Actinidia chinensis in Korea.

Kiwi (Actinidia chinesis) is an economically important fruit in Korea, with 1,300 ha cultivated and a production of approximately 25,000 tons per year (Kim and Koh, 2018; Kim and Choi, 2023). In late June 2020, fruit scab symptoms were observed on A. chinensis var. rufopulpa in an orchard in Suncheon, Korea. The incidence of scab symptoms among 20-year-old trees was over 75%, primarily superficial, but rendered the fruit less marketable. In the initial stages of the disease, small, light-brown, circular, and oval spots were formed. As the superficial spots expanded, they became cracked scabs measuring 1 to 7 cm with light edges at the later stages. To isolate the causal pathogen, two lesions were cut from two sections of symptomatic tissue, from each of seven fruits from seven trees. Lesions were surface-sterilized with 70% ethanol for 1 min and washed three times with sterilized distilled water (SDW). The sterilized pieces were placed on potato dextrose agar (PDA) and incubated in the dark at 25°C for one week. After subculturing on PDA, single-spore isolation produced 14 isolates: SYP-410 to 423). All 14 colonies appeared greyish-green and cottony on PDA after 7 d. Conidia were pale brown, ellipsoid to obclavate, with ornamented walls, 1 to 6 transverse and 0 to 3 vertical septa, and length × width of 21.5 to 53.4 × 7.3 to 19.2 µm (avg. 33.0 × 12.0 µm, n = 100). Their morphological characteristics were consistent with Alternaria spp. (van der Waals et al. 2011; Woudenberg et al. 2015). We randomly selected three isolates from the morphologically similar cultures and named them SYP-412 to 414 for further investigation. The ITS (GenBank accession nos.: OR901850 to 52), gapdh (OR924309 to 11), tef1 (OR924312 to 14), rpb2 (OR924315 to 17), Alt a1 (OR924318 to 20), endoPG (OR924321 to 23), and OPA10-2 (OR924324 to 26) sequences from SYP-412 to 414 had a 100% (515 bp/515 bp), 100% (578/578), 100% (240/240), 100% (724/724), 95.55% (451/472), 99.33% (445/448), and 100% (634/634) identity with that of type strain A. alternata CBS 918.96 (AF347032, AY278809, KC584693, KC584435, AY563302, KP124026, and KP124633), respectively. Results from the maximum likelihood phylogenetic analysis, based on the seven concatenated gene sequences, placed the representative isolates in a clade with A. alternata. Pathogenicity of SYP-412 was tested using 12 surface-sterilized two-month-old kiwifruits on a 20-year-old trees. Six kiwifruits were spray-inoculated with 5 mL of a conidial suspension (1 × 106 conidia/ml) generated after culturing in PDA medium for 7 d, with or without wounding. Another six control fruits were inoculated with SDW with and without wounding. The inoculated kiwifruits were enclosed in plastic bags to maintain high humidity for one day. Scab symptoms were observed in both wounded and unwounded fruits six weeks after inoculation, but not in the control. The pathogenicity test was performed on a total of three separate trees twice. To satisfy Koch's postulates, A. alternata was re-isolated from all the symptomatic tissues and confirmed by analyzing the ITS and rpb2 genes. Although scab disease caused by A. tenuissima (now A. alternata) has been previously reported in kiwifruit of A. chinensis var. rufopulpa in China (Woudenberg et al. 2015; Ma et al., 2019), this is the first report of its occurrence on kiwifruit in Korea and will help in future detection and control.

First Report of Polygonatum kingianum Leaf Spot Caused by Alternaria alternata in Kunming, China.

Polygonatum kingianum Coll. et Hemsl., a Polygonatum species in the Asparagaceae family, plays an important role in Chinese herbal medicine (Zhao et al. 2018). P. kingianum is widely planted in the Southwestern China. In September 2023, we observed a leaf spot of P. kingianum with disease incidence of 100%, and disease index reached 60 in commercial plantings in Kunming, Yunnan province, China (24.3610°N, 102.3740°E). In the initial stage of infection, symptoms manifested as a small circular brown spot. As the spots gradually expanded, they formed oval to irregular shaped lesions with grayish-white or dark-brown borders. Progressively the entire leaf withered and died. For identification of the causal agent of the leaf spot, leaf sections (5×5 mm2) were cut from the margin of the lesion and soaked in 75% ethanol for 10 s, 1% sodium hypochlorite for 3 min, washed with sterile distilled water, dried on sterilized tissue paper and placed on potato dextrose agar (PDA). The Petri dishes were then incubated at 28℃ for 3 days with a 12-h photoperiod. A predominant fungus was isolated from 95% of the samples. Three monosporic isolates were screened using a single-spore isolation method. After 4 days of incubation the colonies were white, after 7 days turned yellow-white. Conidia were black-brown, oblong or fusiform, with 3-7 transverse septa and 0-3 longitudinal septa, with dimensions of 19.5 to 49.5 × 8.7 to 17.6 µm (n = 30). Total genomic DNA of these three isolates was extracted from mycelia by the cetyltrimethylammonium bromide (CTAB) protocol. The nucleotide sequences of the elongation factor 1-alpha (EF1α), nuclear ribosomal internal transcribed spacer (ITS), 28S nuclear ribosomal large subunit rRNA gene (LSU), 18S nuclear ribosomal small subunit rRNA gene (SSU), and the second largest subunit of nuclear DNA-directed RNA polymerase II (RPB2) gene regions were amplified using the primer pairs EF1-728F/EF1-986R (Carbone and Kohn 1999), ITS1/ITS4 (White et al. 1990), LR0R/LR5 (Schoch et al. 2012), NS1/NS4 (Schoch et al. 2012), and fRPB2-5F/fRPB2-7Cr (Liu et al. 1999), respectively. Amplicons were cloned in a pMDTM19-T vector (code no. 6013, Takara, Kusatsu, Japan) and bidirectionally sequenced. All three isolates had identical nucleotide sequences. Sequences from one isolate (PkF03) were deposited in GenBank. BLASTn analyses showed that sequences of EF1α (GenBank accession no. PP695240), ITS (PP694046), LSU (PP683406), SSU (PP683407), and RPB2 (PP695241) of isolate PkF03 were 99.6 (KP125134), 100 (KP124358), 100 (KP124510), 99.9 (KP124980), and 100% (KP124826), respectively, identical with Alternaria alternata (Fr.) Keissl. strain CBS 118815. Based on the nucleotide sequences of EF1α, ITS, LSU, SSU, and RPB2, a maximum likelihood phylogenetic tree was constructed using MEGAX with Tamura-Nei model. Isolate PkF03 was grouped in the same clade as A. alternata. According to the morphology and sequence analyses isolate PkF03 was identified as A. alternata (Woudenberg et al. 2013). To determine pathogenicity of isolate PkF03, a spore suspension (106 spores/mL) was sprayed on 1-year-old healthy leaves of P. kingianum. The control leaves were sprayed with sterile water. All plants were incubated at 28℃, 70% relative humidity, and a 12-h photoperiod. The pathogenicity tests were repeated three times with six plants in each treatment. Fifteen days post-inoculation, the inoculated leaves showed brown-yellow lesions, whereas the control leaves remained symptomless. A. alternata was reisolated from infected leaves. To our knowledge, this is the first report of A. alternata causing leaf spot on P. kingianum in Kunming, China. The results provide a scientific basis for prevention and control of the disease.

Occurrence of Leaf Spot on Elaeocarpus decipiens Caused by Alternaria alternata, a new disease in China.

Elaeocarpus decipiens is widely cultivated as an ornamental tree of commercial importance in southern China. During March 2018 to March 2021, leaf spot disease was observed in about 40% of E. decipiens on the campus of Jiangnan University in Wuxi, Jiangsu, China (31.48°N, 120.46°E). Leaf symptoms began as small, light brown lesions that enlarged, turned olive brown in color and then became necrotic. Ten symptomatic leaves were collected from five different trees on the Jiangnan University campus and surface sterilized with 75% ethanol for 30 seconds, followed by 1% sodium hypochlorite for 1 minute, and rinsed three times with sterile distilled water before being cultured onto potato dextrose agar and incubated in the dark at 25°C for 5 days. Five purified fungal isolates were obtained by the single spore isolation method. Emergent fungal colonies were olive-green in color with 1 to 3 mm white margins and abundant aerial hyphae. Conidia were borne in chains or singly and were obclavate or obpyriform and measured 6.5 to 17.4 × 21.3 to 32.8 µm (n=50) with one to seven transverse septa and zero to three longitudinal septa. Based on morphological characteristics, the pathogen was identified as Alternaria spp.(Simmons 2007). Three representative isolates, At1, At2 and At3, were selected for molecular identification, total genomic DNA of the fungus isolates were extracted with Plant/Fungi DNA Isolation Kit (Sigma-Aldrich, Ontario, Canada). Plasma membrane ATPase (ATP) gene, chitin synthase (CHS) gene and translation elongation factor 1-alpha (EF1) gene were amplified with primers ATPDF1/ATPDR1, CHS-79F/CHS-345R (Lawrence et al. 2013) and EF1-728F/EF1-986R (Carbone and Kohn 1999). The amplification results of the three isolate genes were consistent, and we deposited the results of the ATP (MN046377), CHS (MN046378) and EF1 (MN046379) sequences of At1 in the NCBI GeneBank. The ATPase gene from the representative isolate At1 shared 99.83% similarity to A. alternata causing leaf Spot of Codonopsis pilosula in China (OM362504, Shi et al. 2022), the CHS gene shared 100% similarity to A. alternata causing brown leaf spot on Paris polyphylla var. chinensis in China (MK391053, Fu et al. 2019), and the EF1 gene shared 100% similarity to A. alternata CBS 916.96 ex-type on Arachis hypogaea in India (KC584634). A phylogenetic tree constructed with the EF1 gene using the neighbor-joining algorithm in MEGA 11 software with 1,000 bootstrap replicates revealed that the examined isolate, At1, belongs to the fungus A. alternata. For pathogenicity tests, 10 leaves of five healthy plants were sprayed with spore suspensions (1 × 107 conidia/ml) of the 10-day-old isolates (At1, At2 and At3, respectively). As a control, five plants were sprayed with sterile distilled water. After inoculation, use the bags to moisturize for 48 hours. Pathogenicity tests were conducted three times. Fourteen days after inoculation, olive brown necrotic lesions developed on inoculated leaves while control leaves remained symptomless. The pathogen was reisolated from infected leaves and confirmed as A. alternata based on morphological characteristics and molecular markers. To date, A. alternata has been reported to cause leaf spot disease on many plants inculuding Ficus religiosa (Du et al. 2022), Tilia miqueliana (Yue et al. 2023), Ligustrum japonicum (Fang et al. 2023) and so on. To our knowledge, this is the first report of the occurrence of A. alternata causing leaf spot on E. decipiens in China. The increasing area of E. decipiens cultivation and global climate change have led to an increase in the incidence of E. decipiens diseases, which should be taken into account by forest conservationists.

First Report of Alternaria Leaf Spot Caused by Alternaria alternata on Ulmus parvifolia in Jiangsu, China.

Ulmus parvifolia Jacq. is an important tree with ornamental value, which is widely planted in Hebei and southern regions of China. In September 2022, a leaf spot symptom was observed on about approximately 20% U. parvifolia seedlings growing a tree farm (20000 m2) of Jiangsu Academy of Forestry (118°45'57.30″E, 31°51'27. 94″N). Gray to black spots appeared on leaves of seedlings. Five diseased leaves were collected from five different seedlings. The pieces were excised from the margins between healthy and diseased tissues, surface sterilized in 75% ethanol for 30 s and then in 1.5% NaClO for 90 s, rinsed three times in sterilized distilled water, plated on potato dextrose agar (PDA) and incubated at 25℃ in the darkness. Pure cultures were obtained by monosporic isolation. Six isolates with identical morphological features and the internal transcribed spacer (ITS) sequences were obtained (the isolate rate of 67%), and identified as Alternaria sp. A representative isolate, LY-1-1 was used for the further study. The colony of LY-1-1, growing on PDA was cotton-like and brown in color with gray-white aerial hyphae on their surfaces, and its reverse was dark grey. The conidia were ovate to pear-shaped, brown in color, with 1 to 4 transverse septa and 0 to 1 longitudinal septa, parietal cells extending into the beak, and measured 7.1 to 12.5×3.8 to 7.1 µm (n=35). These characteristics were consistent with the description of Alternaria sp. (Simmons 2007). The regions of ITS, large subunit ribosomal RNA (LSU), small subunit ribosomal RNA (SSU), anonymous region OPA10-2 genomic sequence (OPA10-2), Alternaria 1 major allergen (Alta1), glyceraldehyde 3-phosphate dehydrogenase (GAPDH) and translation elongation factor 1-alpha (TEF1) genes (GenBank Accession No. OR047916, OR051904, OR047919, OR061065, OR061063, OR061064, and OR061062, respectively) were amplified (White et al. 1990; Woudenberg et al. 2015) and sequenced. These obtained sequences showed 99.86-100% similarity to the ITS (514/515 bp) of A. alternata isolate SPM-2 (OR378581), LSU (801/801 bp) of isolate B9 (OR366492), SSU (1019/1020 bp) of strain LSU0766 (MT000349), OPA10-2 (632/633 bp) of strain 19-1 (MN185000), Alta1 (470/470 bp) of strain CMML21-73 (OQ831518), GAPDH (177/177 bp) of isolate CS36-3 (KY814638), and TEF1 (240/240 bp) of isolate SY-6 (OP980553). A neighbor-joining phylogenetic tree was generated by combining all sequenced loci in MEGA7. The isolate LY-1-1 clustered in the A. alternata clade with 98% bootstrap support. Three 3-month-old U. parvifolia seedlings were wounded with a sterile needle and inoculated with 20 µL conidia suspension (1×106 spores/mL) on the left sides of leaves. Inoculation on the right side with 20 µL of sterile water was treated as a control. All inoculated plants were incubated in a greenhouse at 25℃, 80% relative humidity, and a 12-h light/dark cycle. The experiment was repeated three times. After 5 days of inoculation, typical gray to black spots were found on the left sides of all inoculated leaves, and the control did not have any leaf spot symptoms. Subsequently, the same fungus was reisolated and identified based on morphological and molecular traits, fulfilling Koch's postulates. The A. alternata has been reported to cause leaf spot on pecan (Wu et al. 2020), fruit spot on olive (Alam et al. 2019) and fruit rot on lychee (Alam et al. 2017). However, there are no other reports of A. alternata on U. parvifolia in the world. Thus, this study provides an important reference for the biology, epidemiology of A. alternata.

First Report of Alternaria alternata Causing Leaf Spot on Coffea arabica in China.

Yunnan Province is the major region for coffee (Coffea arabica) cultivation in China, contributing to over 98% of the national yield and total production value (Ma et al. 2022). In May 2023, brown spot symptoms were observed only on the leaves of coffee plants in a field located in Baoshan City (98°52'37.988400"E, 24°58'17.673600"N), Yunnan Province. Notably, brown and irregularly shaped spots initially started on the leaf bases. The spots enlarged and developed concentric rings with dark brown margins, which are often surrounded by yellow halos. Finally, the necrotic spots spread across the entire leaf and caused the leaf to curl and fall off. The incidence of the disease was approximately 3% of the coffee plants (n = 600). The symptomatic leaves collected from 10 plants were sectioned (5 × 5 mm), subjected to surface sterilization with 70% ethanol for 40 s, rinsed with sterile distilled water, air-dried, and transferred to potato dextrose agar (PDA). Fungi with grayish-white, cotton-like aerial mycelia grew after 7 days at 28°C. The older mycelia of these isolates displayed dark gray pigmentation. Single conidia were cultivated on PDA, and 15 morphologically similar monosporic isolates were ultimately obtained. Microscopic observation revealed that these isolates produced branched, septate, transparent and amber mycelium. Brown, elliptical or pear-shaped conidia with 2 to 4 transversal septa and 0 to 3 longitudinal septa, measuring 9.6 to 33.3 long × 6.0 to 15.0 µm wide (n = 30), were observed on potato carrot agar (PCA). Molecular identification of multiple genes, such as ITS (Schoch et al. 2012), RPB2 (O'Donnell et al. 2010) and GAPDH (Berbee et al. 1999), indicated consistent 100% identity among these isolates. Sequences of the representative isolates CFSY1-CFSY5 were deposited in GenBank (acc. nos.: OR351112, PP188577, PP188578, PP294863, PP294864, OR509742, PP215341-PP215344, OR509740 and PP239378-PP239381), revealing 98.35% - 100% homology with distinct Alternaria alternata strains previously deposited in GenBank (acc. nos.: PP110780, MN649031 and OR485338). The multigene phylogenetic analysis positioned isolates CFSY1-CFSY5 within a distinct cluster, alongside diverse A. alternata isolates. Based on morphological and molecular characterizations, the pathogen was identified as A. alternata. To verify its pathogenicity, a conidial suspension (1×106 conidia/mL) of isolate CFSY1 was sprayed on six leaves of three healthy one-year-old C. arabica seedlings. Subsequently, the inoculated seedlings were covered with plastic bags and placed in a growth chamber under controlled conditions (a 14 h daylight period and a 10 h dark period at 28°C). The experiment was repeated three times. After 20 days, typical brown spot symptoms analogous to those originally observed in the field appeared on the leaves in all inoculated plants. Reisolation, morphology identification and DNA sequencing substantiated Koch's postulates. In contrast, control plants treated with sterilized water remained asymptomatic, and no pathogen was reisolated from them. Significantly, A. alternata has been previously reported as the causal agent for leaf spot disease in a diverse variety of woody plant species in China, including Prunus avium (Ahmad et al. 2020), Magnolia grandiflora (Liu et al. 2019) and citrus (Wang et al. 2010). This study represents the first report of brown leaf spot caused by A. alternata specifically on C. arabica in China, enriching the contents of fungal pathogens under Chinese coffee cultivation conditions.

First Report of Leaf Spot on Eriobotrya japonica Caused by Alternaria alternata in Southwest Korea.

Loquat (Eriobotrya japonica) is a crop cultivated in Southwest Korea, covering an area of 101 ha and yielding 120 tons at harvest (KASS, 2024). Due to its high-income potential, the cultivation area is gradually expanding. In May 2023, 30% of leaf brown spots were observed on all three trees in the Suncheonman National Garden, Suncheon (3488'57.97" N, 12750'92.83" E). As the disease progressed, the brown spot gradually enlarged, turning greyish-ivory inside and forming concentric circles. Three leaf lesions from each tree were cut into 5 x 5 mm pieces, surface-sterilized with 70% ethanol for 1 min, and washed in sterile water three times to isolate the pathogen potentially responsible for these symptoms. The samples obtained were subsequently cultured on 1.5% water agar and then incubated in the dark at 25℃. A total of nine isolates were obtained, with three isolates from each of the three trees through single-spore isolation, namely SYP-1202-1 to 3, SYP-1202-4 to 6, and SYP-1202-7 to 9. The colonies reached 90 mm in diameter after 10 days on potato dextrose agar (PDA), initially dark green, and turned sooty gray after 2 weeks. The hyphae grown on a 0.6% KCl medium for 3 days produced long chains containing three to twelve conidia. The conidia were ellipsoidal or obpyriform in shape and light brown. The conidiophores were straight or curved, measuring 12.1-75.3 x 1.6-4.8 µm (n = 100). The primary and secondary conidia measured length × width of 19.1-60.6 × 6.1-14.4 µm and 8.4-27.8 × 3.5-9.5 µm (n = 100), respectively. The conidia had 1 to 7 transverse and 0 to 3 vertical septa. The morphology of the nine isolates was identical and consistent with Alternaria species (van der Waals et al., 2011; Woudenberg et al., 2015). For molecular identification, ITS (OR844500 to OR844508), GAPDH (OR866383 to OR866391), TEF1 (OR866392 to OR866400), RPB2 (OR866401 to OR866409), Alt a1 (OR866410 to OR866418), endoPG (OR866419 to OR866427), and OPA10-2 (OR866428 to OR866436) sequences from SYP-1202-1 to 9 showed a 100% (515 bp/515 bp), 100% (579/579), 100% (240/240), 100% (753/753), 95.1% (449/472), 100% (448/448), and 100% (634/634) identity with that of type strain A. alternata CBS 115152 (KP124348, KP124202, KP125124, KP124816, KP123896, KP124049, and KP124658, respectively). A pathogenicity test was conducted on three 5-year-old E. japonica cultivar Daebang trees in pots. The surface of the five leaves per tree was sterilized with 70% ethanol for 1 min. Before inoculation, the leaves were wounded with sterile needles and sprayed with the conidial suspension (1×106 conidia/ml) produced from a 1-week-old culture grown on PDA. In contrast, control leaves were sprayed with sterile distilled water. The inoculated leaves were wrapped with black plastic bags and kept at 100% relative humidity for two days. At seven days post-inoculation, symptoms were observed on the wounded leaves, whereas the nonwounded and control leaves did not exhibit any symptoms. The experiment was performed three times in the greenhouse. For each experiment, pathogens were reisolated from the two symptomatic leaves per plant. The identity of the reisolated pathogens was then confirmed via analysis of ITS and RPB2 genes, thereby confirming adherence to Koch's postulates. To the best of our knowledge, this is the first report of E. japonica being infected by A. alternata in Korea. This report provides important information to support effective disease control strategies for E. japonica in orchards in southern Korea.

First Report of Alternaria alternata Causing Postharvest Fruit Rot of Indian Jujube (Ziziphus mauritiana) in China.

Ziziphus mauritiana Lam., commonly known as Indian jujube or ber, is a popular fruit crops grown in tropical and sub-tropical regions of China. It is commonly stored at 4℃, relative humidity of about 90%, combined with waxing or sealing with film bag. In January 2023, a postharvest fruit rot was observed on Indian jujube in three markets located in Nanchang city of Jiangxi province, China, with a disease incidence of 4 to 10%. Initially, brown spots appeared on the surface or base of the fruit, which gradually expanded into irregular brown lesions. Gray-white hyphae developed in the center of the lesions, and ultimately the fruit rotted. To isolate the pathogen, small pieces (5 × 5 mm) of ten infected fruits were surface-sterilized in 75% ethanol for 15 s and then 1% sodium hypochlorite for 30 s, rinsed three times in sterile water, plated onto potato dextrose agar (PDA), and incubated at 25°C for 3 days. Eight strains with similar morphological characteristics were isolated, and one representative isolate (JXAA-1) was used for morphological and molecular characterization. The colonies on PDA were initially olive green with white margins, and later turned dark olive or black with profuse sporulation. Conidia were borne singly or in a chain, brown, with 1 to 5 transverse septa and 0 to 3 longitudinal septa, obclavate to obpyriform, and measured 12.9 to 33.7 × 7.5 to 12.9 µm (n = 30). On the basis of morphological characteristics, the isolates were tentatively identified as Alternaria spp. (Simmons 2007). To confirm the identification, genomic DNA was extracted from the isolate JXAA-1 with the Fungi Genomic DNA Extraction Kit (Solarbio Biotech, China). The 18S nrDNA (SSU), 28S nrDNA (LSU), internal transcribed spacer of the rDNA (ITS), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), elongation factor 1-alpha (TEF1), Alternaria major allergen gene (Alt a 1), endopolygalacturonase (EndoPG) and an anonymous gene regions (OPA 10-2) were amplified and sequenced using primers NS1/NS4, LR7/LR0R, ITS5/ITS4, gpd1/gpd2, EF1-728F/EF1-986R, Alt-for/Alt-rev, PG3/PG2b, OPA10-2L/OPA10-2R, respectively (Woudenberg et al. 2015). The obtained DNA sequences (SSU: PP190241; LSU: PP190242; ITS: PP189927; GAPDH: PP196557; TEF1: PP196558; Alt a 1: PP196559; EndoPG: PP196560; and OPA 10-2: PP196561) showed 100% homology with those of A. alternata (GenBank accession nos. MT000349 [1020/1020 bp]; KP940477 [1312/1312 bp]; MK972909 [583/583 bp]; MN615421 [593/593 bp]; MN046379 [280/280 bp]; MN304714 [490/490 bp]; MN698284 [458/458 bp] and MH975214 [701/701 bp]). A maximum likelihood phylogenetic tree was constructed by combining all sequenced loci in IQTREE web servers. The isolate JXAA-1 clustered with Alternaria alternata (CBS 121336). The fungus associated with postharvest fruit rot on Z. mauritiana was thus identified as A. alternata. To evaluate the pathogenicity, six surface sterilized fruits were wounded by a sterile scalpel and inoculated with a 10 µl drop of spore suspension (1 × 105 conidia/ml) of isolate JXAA-1. Another six fruits were inoculated with sterilized ddH2O as control and the experiment was repeated three times. All fruits were incubated at 25°C and 80% relative humidity. After 5 days, all the wounded fruit inoculated with A. alternata showed similar symptoms to those observed previously, while the control fruits remained healthy. A. alternata was consistently reisolated from infected fruit and confirmed by morphological and molecular data, fulfilling Koch's postulates. A. alternata has previously been reported causing leaf spot and fruit rot on Chinese jujube (Ziziphus jujuba) in China (Bai et al. 2015; Li et al. 2021). But to our knowledge, this is the first report of A. alternata causing postharvest fruit rot on Indian jujube (Z. mauritiana) in China. Therefore, managers should pay more attention to postharvest fruit rot of jujube caused by A. alternata, the foam bag is put on after the membrane bag is sealed, the broken or infected fruit is picked out in time to reduce the spread of pathogenic fungus.

First report of Alternaria alternata causing leaf spot on Polygonatum kingianum in China.

Polygonatum kingianum is a Chinese herbal medicine that belongs to the genus Polygonatum of the family Liliaceae. In June 2023, Polygonatum kingianum Coll. et Hemsl. in nurseries in Qujing, Yunnan Province, China, showed irregular brown spots on the leaves, whole leaf necrosis, and plant death in serious cases, with an incidence of 10-20% (Fig. S1). To identify the pathogens of P. kingianum, six diseased samples were collected from nurseries with 0.6 acre. These diseased sample leaves were soaked in 0.1% HgCl2 for 1 min and 75% ethanol for 2 min and then rinsed thrice with sterile water. Treated leaves were cut into small pieces (5×5 mm) and cultured on potato dextrose agar (PDA) for five days at 28°C. Total thirteen fungal strains were isolated from PDA medium. The nuclear ribosomal internal transcribed spacer of ribosomal DNA (ITS rDNA) region of these 13 strains was amplified by polymerase chain reaction (PCR) using universal primers ITSI/ITS4 (White et al. 1990). Sequencing and BLAST of the ITS region on NCBI showed that 11 out of 13 fungal strains belonged to the genus Alternaria, with an identity ≥99%. We selected one of the Alternaria strains, HJ-A1, for further study. The HJ-A1 colony appeared grayish brown white-to-gray with a flocculent texture on the front side and a dark gray underside on the PDA medium (Fig. S1). The conidiophores appeared brown, either single or branched, and produced numerous short conidial chains. The conidia were obclavate to obpyriform or ellipsoid in shape and contained 1-4 transverse septa and 0-2 oblique septa. The conidial diameter was 27.30µm in length and 12.27µm in width. (Fig. S1). To further determine the species of HJA1, the genomic DNA of HJ-A1 was extracted using the Lysis Buffer for PCR (AG, Hunan, China). Four Alternaria genomic DNA regions including the ITS, translation elongation factor 1-α gene (TEF1-α), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), and Alternaria major allergen gene (Alt a1) were amplified by PCR using the primers as previously reported (Woudenberg et al. 2013, Hong et al. 2005). Sequence analysis revealed that the ITS (484bp) of HJ-A1 (NCBI No. PP082633), TEF1-α (267bp) of HJ-A1 (NCBI No. PP419893), GAPDH (582bp) of HJ-A1 (NCBI No. PP419892), and Alt a1 (522bp) of HJ-A1 (NCBI No. PP228046) shared the highest identity with A. alternata respectively (99≥%). A maximum likelihood phylogenetic tree was constructed with the combined sequence data sets of ITS, GAPDH, TEF, and Alt a1 using MEGA 7. The results showed that HJ-A1 strain clustered with A. alternate (Fig. S2). The pathogenicity of HJ-A1 was tested according to Koch's postulates by inoculating HJ-A1 conidia suspension (2×105 conidia/mL) into leaves of 1-year-old P. kingianum, with sterile water as a control. Each treatment group included 3 plants with 3 replicates. The tested plants were planted in a phytotron at 28℃ and 90% humidity. Three days after inoculation, symptoms similar to those under natural conditions were observed in the HJ-A1-inoculated plants, whereas no symptoms were observed in the control plants (Fig. S1). The same fungal strains were re-isolated from inoculated leaves and identified by morphologically and sequence of ITS. Previous studies showed that Alternaria alternata funji cause many plant diseases, such as fig fruit rot (Latinovic N et al. 2014)，daylily leaf spot (Huang D et al. 2022), fruit blight on sesame (Cheng H et al. 2021)，leaf spot of Cynanchum atratum Bunge (Sun H et al. 2021) and so on. To our knowledge, this is the first report of A. alternata causing P. kingianum leaf spot in China. The discovery of this pathogen will help to guide the protection and control of P. kingianum disease.

Baseline sensitivity and toxicity mechanisms of prochloraz to Alternaria alternata strains associated with maize leaf blight in Heilongjiang province in China.

Alternaria species are fungal pathogens that can infect maize, causing leaf blight disease and significant economic losses. This study aimed to determine the baseline sensitivity to prochloraz of A. alternata isolates obtained from diseased maize leaves collected from Heilongjiang province by assessing the half-maximal effective concentration (EC50) values. The EC50 values of prochloraz ranged from 0.0550 µg/mL to 2.3258 µg/mL, with an average of 0.9995 ± 0.5192 µg/mL. At EC50 (1.2495 µg/mL) and 2EC50 (2.4990 µg/mL), prochloraz increased the number of mycelial offshoots, disrupted the cell membrane integrity of conidia and mycelia, and resulted in a reduced ergosterol content in the mycelia. Prochloraz significantly affected the mycelial cell membrane permeability and increased the malondialdehyde (MDA) content and superoxide dismutase (SOD) activity. No cross-resistance was detected between prochloraz and other fungicides. These data demonstrate that prochloraz is a promising fungicide for managing maize leaf blight caused by A. alternata and provide novel insights into understanding the mechanism of prochloraz toxicity against A. alternata isolates.

First Report of Leaf Spot Caused by Alternaria alternata on Chard (Beta vulgaris var. cicla L.) in China.

Chard (Beta vulgaris var. cicla L.) is popular vegetable in China. In June 2023, a leaf spot disease was observed on Chard plants in Hunan Province (27°46'10.99″N, 112°05'52.80″E), China. The disease incidence was 30% in a surveyed of about 500 plants. Symptoms began as many light brown round- to polygon-shaped spots on chard leaves, then developed and enlarged into grayish-white lesions, with the edge of the spots brown to dark brown. A total of 10 symptomatic samples were randomly collected. To identify the pathogen, symptomatic tissues (0.5 × 0.5 cm) from the lesion margin surface were sterilized with 75% ethanol for 30 s and 2% NaClO for 1 min, rinsed 3 times with sterile water, air dried. The sterile pieces were placed on potato dextrose agar (PDA) and incubated at 25°C. A total of nine isolates were obtained. Fungal colonies cultured on potato carrot agar (PCA) were almost the same as each other, and two representative isolates (TC0, TC10) were used for further identification. On PCA, the fungal hyphae were initially white and finally gray-brown with flocculent aerial mycelia. Conidia were solitary or in chains, with various shapes, mostly subglobose, the size was 13.2 to 28.0 µm long and 5.8 to 13.0 µm wide (n = 30). The cultural and morphological characteristics of isolates were similar to those of Alternaria sp (Simmons et al. 2007). For molecular identification, four loci, ITS (White et al. 1990), RPB2 (O'Donnell, 2022), H3 (Zheng et al. 2015), and GAPDH (Berbee et al. 1999), were sequenced from two representative isolates (TC0, TC10). Compared with a reference isolate, Alternaria alternata strain CBS 107.27, GenBank accession nos. KP124300.1 (ITS), KP124768.1 (RPB2), KP124157.1 (GAPDH). The ITS, RPB2, and GAPDH sequences of TC0 and TC10 showed 99% (502 of 504 bp ), 100% (753 of 753 bp), and 99% (560 of 561 bp) similarity, respectively. Compared with a reference isolate, A. alternata isolate 21-5, GenBank accession no. MN840996.1 (H3), H3 sequences of TC0 and TC10 showed 99% (399 of 401 bp) similarity. The sequences of two isolates (TC0, TC10) were deposited in GenBank with accession numbers PP837733.1, PP565404.1(ITS), PP839298.1, PP573905.1(RPB2), PP839299.1, PP573904.1 (GAPDH), and PP839297.1, PP573903.1(H3). Phylogenetic trees were constructed using the sequences and showed that isolates (TC0, TC10) were in the same clade with A. alternata strains. TC0 and TC10 were identified as A. alternata based on the morphological characteristics and molecular phylogeny. Pathogenicity testing was conducted on six-month-old healthy plants, (cv. Green Stalk), three plants were inoculated by spraying spore solution (1 × 106 conidia/mL), and three plants were sprayed with sterile water as a control. The pathogenicity test was performed 3 times. Plants were maintained at 28°C and >80% RH. Plants showed symptoms after 30 days, symptoms were observed similar to those of the original infected plants, control plants were asymptomatic. The fungus was reisolated, confirmed as A. alternata based on conidial characteristics, no pathogenic fungus was isolated from the control plants. A. alternata has previously been reported on beet (also Beta vulgaris) in China (Tai, F. L. 1979; Zhuang, W. Y. 2005). To our knowledge, this is the first report of leaf spot caused by A. alternata on chard in China. This result may expand the etiological study of A. alternata and the control strategy of Chard leaf spot.

First Report on Apothecium Deformity of Morchella importuna Caused by Alternaria alternata in China.

Morel mushrooms (Morchella spp.) are highly regarded globally for their distinctive texture and savory flavor. In 2022, the cultivation area for morel mushrooms in China reached nearly 20,000 hectares, with predominant cultivars including M. sextelata, M. importuna and M. exima (Bian et al., 2024). In March 2022, however, deformities of friting bodies were observed in M. importna at morel mushroom farms in Huaihua city (28.43°N, 110.47°), China, with an incidence rate ranging from 5% to 10%. The disease symptoms begin with the invasion of the hymenium of morel mushroom by white cotton-like mycelia, ultimately resulting in halted fruiting body growth and the manifestation of anomalous fruiting body morphology. Infected samples were collected from the morel growers. Following sterilization with 75% ethanol of the surrounding tissue of infected samples, the white hyphae from the morel lesions were picked out using a dissecting needle, and incubated onto potato saccharose agar medium supplemented with 60 mg/L streptomycin at 25°C. Studies showed that seven out of nine fungal isolates exhibiting identical morphological features rapidly grew on the same culture medium described above, reaching a length of 75 mm in 4 to 5 days at 25°C. The white and thick hyphal colonies of these isolates gradually filled with brown spore powder. Generally, the conidia of the hyphal colonies were polyblastic with protrusions at the tips, measuring 75 to 165 × 36 to 50 µm (n = 30) in width and length, displaying colors varying from light reddish brown to grayish brown, and possessing one or five septa. To confirm the identity of the pathogen, the region of the internal transcribed spacer region (ITS), 28S nuclear ribosomal large subunit (LSU), and RNA polymerase II second largest subunit (rpb2) genes of the representative isolate H2 were amplified by PCR (Taguiam, et al. 2021). The generated ITS (OR338304), rpb2 (OR452112) and LSU (OR338334) from the isolate H2 had 98-100% similarity to the Alternaria alternata strains ATCC 6663 and CBS 880.95 in BLASTn analysis. ITS, rpb2 and LSU sequences were assembled using Sequence Matrix, and their homogeneity was assessed with PAUP (Vaidya et al., 2011). Bayesian (MrBayes-3.2.7a) and maximum-likelihood (RAxML1.3.1) methods, utilizing the best fit GTR+G+I model obtained from MrModeltest 2.3, were employed for phylogenetic analysis (Aveskamp et al. 2010). Based on morphological characteristics and phylogenetic analysis, the isolate H2 was identified as A. alternata. In the second year post-disease, disease-free morels, with a height of 3 cm, were cultivated in field greenhouses and used for test. A 15 ml suspension (1 × 106 conidia/ml) was applied to 15 young fruiting bodies and their corresponding substrate soil. The results showed that the reappearance of white cotton-like mycelia and deformed M. importuna fruiting bodies within 7 days post-inoculation with the spore suspension, as opposed to the controls. The isolates (H2-1, H2-2 and H2-3) were reisolated from the infected tissues and identified as A. alternata based on its morphological features and phylogenetic analyses. In this study, a similar investigation was previously conducted on cultivated quinoa (Chenopodium quinoa) in Eastern Denmark (Colque-Little et al., 2023). This study marks the first documentation of A. alternata causing deformities in M. importuna fruiting bodies. These deformities occur under conditions of high-temperature (>22°C) and high humidity (>88%). Our findings provide crucial insights for managing A. alternata in M. importuna cultivation in China.