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Auricularia delicata (Mont.) Henn. 1893 is an edible and medicinal jelly mushroom popular in China. Here, we report the assembly and annotation of a complete A. delicata mitochondrial genome based on data sequenced using an Illumina NovaSeq 6000 platform. The length of the complete circular A. delicata mitochondrial genome is 189,696 bp, with a GC content of 34.1%. The A. delicata mitochondrial genome contains 60 genes, including 32 protein-coding genes, 26 tRNA genes, and two rRNA genes. Phylogenetic analysis indicated that A. delicata clustered with the Auricularia group, alongside A. auricula-judae and A. heimuer. Additionally, A. delicata was found to be genetically distant from other species of Polyporales, Russulales, and Agaricales. This genome will provide an invaluable reference for the continued study and utilization of A. delicata and other Auricularia species.
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Boosting the dissociation of excitons is essential to enhance the photocatalytic efficiency. However, the relationship between the structure of the catalyst and the exciton effect on the photocatalytic activity is still unclear as the main problem. Here, it is proposed that as a descriptive factor, an experimentally measurable dielectric constant (εr) is available to quantitatively describe its relationship with exciton binding energy (Eb) and photocatalytic activity. With tuning the linker of covalent organic frameworks (COFs), the "air gap" structure is oriented to shrink, leading to an increased εr of COFs and a lower Eb to facilitate exciton dissociation. Meanwhile, taking "water-/oxygen-fueled" photo-induced electron transfer reversible addition-fragmentation chain transfer (PET-RAFT) polymerization as a demonstration platform, it can be seen that COFs with a small "air gap" structure have relatively superior photocatalytic activity. This provides important implications for the evolution of efficient photocatalysts.
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Pleurotus giganteus (Berk.) Karunarathna & K.D. Hyde 2011 is one of the largest edible mushrooms integrating medicinal value and edible value. The complete mitochondrial genome of the edible fungus P. giganteus was published in this paper. It was determined using Pacbio and Illumina sequencing. The circular molecule is 102,950 bp in length, consisting of 30 protein-coding genes (PCGs), two ribosomal RNA (rRNA) genes, and 24 transfer RNA (tRNA) genes. The base composition of the whole mitogenome is A (37.3%), T (37.7%), G (12.2%), and C (12.8%). The phylogenetic tree shows P. giganteus was the basal taxon in Pleurotus and closely related to Pleurotus citrinopileatus Singer 1990.
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Passion fruit (Passiflora edulis) is an economically important fruit crop in many tropical and subtropical regions worldwide. In recent years, passion fruit was widely cultivated in Guangxi Province. In 2020, a rot disease occurred on immature fruit of passion fruit in several commercial orchards of Nanning, Guangxi, caused about 50% incidence. The first appeared as small, irregular, water-soaked, brown lesions on immature fruit. As the disease progressed, the lesions rapidly enlarged, causing fruit rot. A layer of sparse white mycelia appeared on the lesions at high humidity. The disease first developed in June, its peak periods from August to September. Five diseased fruits were collected from five different orchards. The edges of symptomatic fleshy mesocarp tissue were cut into pieces (5 mm × 5 mm), surface-sterilized in 75% ethanol solution for 60 s, rinsed three times with sterilized distilled water, and plated on potato dextrose agar (PDA). Plates were incubated at 25°C in the dark. After 5 days, similar white colonies with abundant aerial mycelia developed from all plated tissue samples. Five isolates were obtained, and they were identified as Phytophthora nicotianae based on morphological characteristics and DNA analysis. Spherical hyphal swellings were commonly produced. Numerous sporangia were formed in sterile soil extract. Sporangia were ovoid or obpyriform, papillate, and measured 25 to 58 µm (average 41 µm) × 21 to 45 µm (average 29 µm). Chlamydospores were spherical and 19 to 43 µm in diameter (average 30 µm) (Erwin and Ribeiro 1996). The genomic DNA of a representative isolate Seg2-5 was extracted from mycelia through modified CTAB method (Murray and Thompson 1980). The rDNA internal transcribed spacer (ITS) region, ypt1, and coxII were amplified and sequenced with primers ITS1/ITS4 (White et al., 1990), Yph1F/Yph2R (Schena et al. 2008), and FM75F/FM78R (Villa et al. 2006), respectively. BLAST searches of the ITS, ypt1, and coxII sequences (Accession No. MW470847, MW770870, and MW770871) showed 99 to 100% identity with sequences of P. nicotianae (Accession No. JF792540, MK058408, and MH551183). Based on morphological characteristics and phylogenetic analysis, isolate Seg2-5 was identified as P. nicotianae. To confirm pathogenicity, asymptomatic and immature fruits 'Mantianxing' of passion fruit were previously disinfested in 0.5% sodium hypochlorite. Mycelial plugs of isolate Seg2-5 were placed onto the surface of fruits by nonwounded and pin-prick inoculation. Blank plugs were used as negative controls. Each treatment had five replicates and the test was repeated twice. Fruits were maintained in plastic boxes at 28°C and the initial disease spots appeared at 3 dpi or 5 dpi with wounded or non-wounded inoculation. After 7 to 10 days, all inoculated fruits showed similar symptoms as observed initially in the field, whereas control fruits remained healthy. P. nicotianae was successfully reisolated and identified from the inoculated fruits based on morphological characters and ITS sequence, thus confirming Koch's postulates. P. nicotianae had been previously isolated from passion fruit in South Africa (Van and Huller 1970), Vietnam (Nguyen et al. 2015), and Fujian Province of China (Luo et al. 1993). To our knowledge, this is the first report of P. nicotianae infecting passion fruit in Guangxi Province, China.
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Pleurotus pulmonarius is a popular edible fungus and widely cultivated in many areas of China. In June 2018, yellow rot (more than 10% incidence) was found on the first crop of P. pulmonarius fruiting bodies in a mushroom factory in Nanning, Guangxi Province, China. At first, yellow water-soaked lesions appeared in the infected fruiting bodies. Lesions then spread and purulent tissues were formed. Severe rot induced production of deformed fruiting bodies and offensive odor. Internal sections of the diseased tissue (approximately 0.5 × 0.5 cm) were sterilized in 75% alcohol for 30 s, rinsed three times with sterilized and deionized water, crushed and suspended in sterilized and deionized water. The suspension was spread on the Luria-Bertani (LB) medium. After incubation at 30°C for 2 days, dominant bacterial colonies were oyster white, smooth, convex, and circular. Individual colonies were transferred two times to LB medium using the conventional streak plate techniques to obtain the pure cultures. The cells were gram-negative, short rods, motile, and no capsules or endospores were observed. Using a BoJian Gram-negative bacteria biochemical analysis kit (5 CARDS, Hopebio, Qingdao, China), data were obtained and analyzed, showing that the isolated strain belongs to the Cedecea genus (positive for ß-galactosidase, citric acid, arginine, sucrose, mannitol, sorbitol, D-glucose, gelatin hydrolysis and VP test but negative for H2S, urease, oxidase, indole, rhamnose, melibiose, amygdalin, lysine, ornithine, lactose, inositol and arabinose). Amplified 16S rDNA gene sequences (1,424 bp, GenBank accession No. MT925570) of the isolate using the universal primers 27f and 1492r (Lane 1991) exhibited 99.86% identity with Cedecea neteri M006 (CP009458.1). Based on its morphological characteristics, 16S rDNA sequences, and biochemical test results, the strain was identified as C. neteri. Pathogenicity tests for this strain were performed with bacterial suspensions (approximately 1 × 108 CFU/ml) after growing for 24 h in LB medium at 30°C. Mycelia of P. pulmonarius were cultivated for 60 days in plastic bags. Then young fruiting bodies were formed after induced with low temperature stimulation to serve as a host source. The prepared bacterial suspensions were directly sprayed onto the surface of three bags of fruiting bodies; another three bags were sprayed with sterilized and deionized water as negative control. All inoculated fruiting bodies were then incubated at 20°C with 90 to 95% relative humidity. All experiments were repeated three times. After 2 days, all the fruiting bodies inoculated with the bacterial suspensions showed yellow water-soaked lesions, and the normal growth of the fruiting bodies was inhibited. An offensive odor then developed along with a severe soft rot that was similar to the disease symptoms observed under natural conditions. The fruiting bodies of negative control were growing healthily with no symptoms. Koch's postulates were fulfilled by isolating bacteria from lesions on artificially inoculated fruiting bodies that were identical to the original isolates based on morphological characteristics, 16S rDNA sequences and biochemical test results. C. neteri was formally reported as a pathogen to humans that could cause bacteremia (Farmer et al. 1982). Recently, it has also been reported causing soft rot disease on mushrooms of Pholiota nameko (Yan et al. 2018) and yellow sticky disease on mushrooms of Flammulina velutipes (Yan et al. 2019). However, to the best of our knowledge, this is the first report of C. neteri-induced yellow rot disease of P. pulmonarius in China.
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A direct viable count procedure combined with fluorescence in situ hybridization (DVC-FISH) was developed for the specific detection and enumeration of viable Escherichia coli in cow manure. The DVC method was performed by trapping bacterial cells, extracted from cow manure samples, onto Nucleopore filters followed by incubation on a DVC medium containing yeast extract and four gyrase inhibitors. E. coli cells were identified by using the probe ES445. The DVC method efficiently promoted the elongation of E. coli cells and allowed for the recognition of individual cell division events, by observing microcolonies. Cell recovery by DVC-FISH together with bacterial extraction, was 53% with an inoculum of 10(7) to 10(10) cells g(-1) dry weight, when the manure samples were inoculated with a fresh culture of E. coli and determinations were made immediately. An examination of the survival of E. coli in a cow manure microcosm showed that an increasing fraction of E. coli became non-culturable but were still detectable by DVC-FISH. All these results suggest that DVC-FISH is useful for enumerating viable, even non-culturable, E. coli in cow manure.