Cauliflower mushroom (Sparassis latifolia), is widely distributed in Australia, North America, Europe, and East Asia (Bashir et al., 2020). It is known for its medicinal significance due to the availability of various pharmacological substances and their use in health supplements (Bashir et al., 2017). In recent years, with the development of artificial cultivation technology, S. latifolia has been industrialized in China, with an annual output value 50 million dollars. In March 2023, approximately 15% of S. latifolia showed obvious bacterial rot in mushroom hothouse (about 0.05 ha), located in Shuangliu county, Sichuan province, China (104°7'51"N, 30°25'2"E). The affected parts appear water-soaked, and become sunken and softened as the disease progresses. In the finally, all the fruiting body tissues turn into paste, with colors pale yellow, and have a foul smell. The pathogen was isolated from the margin of the lesions by dilution and streaking techniques onto Nutrient Agar, and incubated at 28℃ in the dark for 2-3 days. A single colony was re-streak for purification. Eight isolates were obtained from five samples collected randomly. The representative three isolates were selected for further characterization. For pathogenicity testing, ten health fruit bodies of S. latifolia were selected (for per isolate). Bacterial suspensions (1 × 107 CFU/ml) of the three isolates were applied to the fruiting body until wet, sterile water was used as controls. All the S. latifolia were maintained at 19±1℃, 85-100% relative humidity, and 18 h of light in the mushroom hothouse. Three days later, the inoculated fruiting bodies developed yellow color, and appear water-soaked, five days later, fruiting body gradually turn to soft and part turn to rot, seven days later, the fruiting body tissues completely turn into paste with a foul smell. The symptoms exhibited were similar to those of the original diseased fruiting bodies, while the control group remained healthy. The same bacterial were re-isolated from the infected fruiting bodies and subsequently identified by morphological characteristics and DNA sequenced. The pathogenicity test was conducted three times, each yielding similar results. The colonies of the pathogen are gram-negative rods, medium sized, convex, smooth, opaque, turning yellow after several days at a temperature 28℃. For molecular identification, the DNA of the representative three isolates was extracted using a Bacterial Genomic DNA Extraction Kit (Solarbio, Beijing). The 16S rRNA genes were amplified and sequenced with the primer 27F/1492R (Lane et al., 1985). Finally, the sequences were identical. The generated representative sequence was deposited in GenBank with accession number OR399122. BLASTn analysis showed 100% identity (1404/1404 bp) with previously deposited sequence (accession number CP068224) of S. multivorum FDAARGOS in GenBank. Based on the maximum likelihood method, phylogenetic analysis revealed 100% bootstrap support values with S. multivorum. Finally, the bacterium was identified as S. multivorum. This is the first report of S. multivorum causing bacterial rot of mushroom. The fruiting body of S. multivorum consists of multiple folded flat lobes, which are thin and have large surface area, may facilitate the infection of S. multivorum. Sphingobacterium sp. are named for their synthesize sphingolipids, which play an important role in bacterial infection (Kunz et al., 2019). These results will contribute to developing control strategies for this disease.
Keywords: Bacterial Rot; Cauliflower mushroom; Sparassis crispa; Sphingobacterium multivorum.