LAUSR

Ear rot is one of the most prevalent and destructive diseases on maize. During field surveys in recent years, it was found that a Penicillium ear rot broke out in some areas of Shanxi, Shaanxi, Hebei and Tianjin in China, with an incidence of 3%-90%. A Penicillium sp. was isolated from diseased kernels covered with greyish green mold, and three isolates were identified by morphological and molecular characteristics. The pathogenicity of isolate ZBS205 to maize ears was further determined by artificial inoculation in a field. Furthermore, the sensitivity of isolate ZBS205 against six commonly-used fungicides was also evaluated. According to macro- and micro-morphological characteristics, isolate ZBS205 was generally identical to Talaromyces funiculosus (teleomorph of P. funiculosum). The partial gene sequences of the nuclear ribosomal ITS1-5.8S-ITS2 (ITS) region, β-Tubulin, putative ribosome biogenesis protein (Tsr1) and the second largest subunit of the RNA polymerase II (RPB2) from isolates ZBS205, D49-1 and S73-1 showed the highest nucleotide identity to T. funiculosus strain X33, and the phylogenetic analysis conducted by neighbor-joining method with the combined data of the four genes demonstrated that these three isolates clustered with T. funiculosus strain X33. These results suggested that the fungus isolated from diseased maize kernels was T. funiculosus. Pathogenicity testing showed that the T. funiculosus isolate ZBS205 was pathogenic to maize ears, which showed symptoms of rotted cob and deteriorated kernels. This is the first report of T. funiculosus as the definitive pathogen causing maize ear rot. The result of fungal sensitivity against fungicides showed that pyraclostrobin exhibited the highest toxicity to mycelial growth and could be used as a candidate agent for the prevention and control of T. funiculosus ear rot. Results of the present study provide a basis for understanding ear rot caused by T. funiculosus, and should play an important role in disease management.