Your search keyword '"Fruiting Bodies, Fungal isolation & purification"' showing total 2 results

1. Mushroom Emergence Detected by Combining Spore Trapping with Molecular Techniques.

Author

Castaño C, Oliva J, Martínez de Aragón J, Alday JG, Parladé J, Pera J, and Bonet JA

Subjects

Agaricales classification, Agaricales genetics, Agaricales growth & development, Fruiting Bodies, Fungal classification, Fruiting Bodies, Fungal genetics, Fruiting Bodies, Fungal growth & development, Fruiting Bodies, Fungal isolation & purification, Mycological Typing Techniques instrumentation, Real-Time Polymerase Chain Reaction, Soil Microbiology, Spores, Fungal classification, Spores, Fungal genetics, Spores, Fungal growth & development, Agaricales isolation & purification, Mycological Typing Techniques methods, Spores, Fungal isolation & purification

Abstract

Obtaining reliable and representative mushroom production data requires time-consuming sampling schemes. In this paper, we assessed a simple methodology to detect mushroom emergence by trapping the fungal spores of the fruiting body community in plots where mushroom production was determined weekly. We compared the performance of filter paper traps with that of funnel traps and combined these spore trapping methods with species-specific quantitative real-time PCR and Illumina MiSeq to determine the spore abundance. Significantly more MiSeq proportional reads were generated for both ectomycorrhizal and saprotrophic fungal species using filter traps than were obtained using funnel traps. The spores of 37 fungal species that produced fruiting bodies in the study plots were identified. Spore community composition changed considerably over time due to the emergence of ephemeral fruiting bodies and rapid spore deposition (lasting from 1 to 2 weeks), which occurred in the absence of rainfall events. For many species, the emergence of epigeous fruiting bodies was followed by a peak in the relative abundance of their airborne spores. There were significant positive relationships between fruiting body yields and spore abundance in time for five of seven fungal species. There was no relationship between fruiting body yields and their spore abundance at plot level, indicating that some of the spores captured in each plot were arriving from the surrounding areas. Differences in fungal detection capacity by spore trapping may indicate different dispersal ability between fungal species. Further research can help to identify the spore rain patterns for most common fungal species. IMPORTANCE Mushroom monitoring represents a serious challenge in economic and logistical terms because sampling approaches demand extensive field work at both the spatial and temporal scales. In addition, the identification of fungal taxa depends on the expertise of experienced fungal taxonomists. Similarly, the study of fungal dispersal has been constrained by technological limitations, especially because the morphological identification of spores is a challenging and time-consuming task. Here, we demonstrate that spores from ectomycorrhizal and saprotrophic fungal species can be identified using simple spore traps together with either MiSeq fungus-specific amplicon sequencing or species-specific quantitative real-time PCR. In addition, the proposed methodology can be used to characterize the airborne fungal community and to detect mushroom emergence in forest ecosystems., (Copyright © 2017 American Society for Microbiology.)

Published

2017

2. Lentinula edodes Genome Survey and Postharvest Transcriptome Analysis.

Author

Sakamoto Y, Nakade K, Sato S, Yoshida K, Miyazaki K, Natsume S, and Konno N

Subjects

Fruiting Bodies, Fungal genetics, Fruiting Bodies, Fungal isolation & purification, Fruiting Bodies, Fungal metabolism, Fungal Proteins genetics, Fungal Proteins metabolism, Shiitake Mushrooms classification, Shiitake Mushrooms growth & development, Shiitake Mushrooms isolation & purification, Fruiting Bodies, Fungal growth & development, Gene Expression Profiling, Genome, Fungal, Shiitake Mushrooms genetics

Abstract

Lentinula edodes is a popular, cultivated edible and medicinal mushroom. Lentinula edodes is susceptible to postharvest problems, such as gill browning, fruiting body softening, and lentinan degradation. We constructed a de novo assembly draft genome sequence and performed gene prediction for Lentinula edodes De novo assembly was carried out using short reads from paired-end and mate-paired libraries and by using long reads by PacBio, resulting in a contig number of 1,951 and an N 50 of 1 Mb. Furthermore, we predicted genes by Augustus using transcriptome sequencing (RNA-seq) data from the whole life cycle of Lentinula edodes , resulting in 12,959 predicted genes. This analysis revealed that Lentinula edodes lacks lignin peroxidase. To reveal genes involved in the loss of quality of Lentinula edodes postharvest fruiting bodies, transcriptome analysis was carried out using serial analysis of gene expression (SuperSAGE). This analysis revealed that many cell wall-related enzymes are upregulated after harvest, such as β-1,3-1,6-glucan-degrading enzymes in glycoside hydrolase (GH) families GH5, GH16, GH30, GH55, and GH128, and thaumatin-like proteins. In addition, we found that several chitin-related genes are upregulated, such as putative chitinases in GH family 18, exochitinases in GH20, and a putative chitosanase in GH family 75. The results suggest that cell wall-degrading enzymes synergistically cooperate for rapid fruiting body autolysis. Many putative transcription factor genes were upregulated postharvest, such as genes containing high-mobility-group (HMG) domains and zinc finger domains. Several cell death-related proteins were also upregulated postharvest. IMPORTANCE Our data collectively suggest that there is a rapid fruiting body autolysis system in Lentinula edodes The genes for the loss of postharvest quality newly found in this research will be targets for the future breeding of strains that keep fresh longer than present strains. De novo Lentinula edodes genome assembly data will be used for the construction of a complete Lentinula edodes chromosome map for future breeding., (Copyright © 2017 American Society for Microbiology.)

Published

2017