Genomic profiling of carbohydrate metabolism in the ectomycorrhizal fungus <i>Tuber melanosporum</i>

Ceccaroli, Paola; Buffalini, Michele; Saltarelli, Roberta; Barbieri, Elena; Polidori, Emanuela; Ottonello, Simone; Kohler, Annegret; Tisserant, Émilie; Martin, Francis; Stocchi, Vilberto

doi:10.1111/j.1469-8137.2010.03520.x

Cited by 47 publications

(38 citation statements)

References 65 publications

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“…Fruiting body mutants are now available for many fungi other than P. anserina, including Sordaria macrospora [27], N. crassa [28], A. nidulans [29] and Coprinopsis cinerea (formely Coprinus cinereus) [30,31] and could be analyzed using similar methods. They are complementary to the now more widespread large scale analyses of transcriptomes during fruiting body development as performed in the ascomycetes Fusarium graminearum and Fusarium verticilloides [32][33][34], N. crassa [35,36], S. macrospora [37], Pyronema confluens [38], Tuber melanosporum [39][40][41], Cordyceps militaris [42] and Ophiocordyceps sinensis [43], as well as in the basidiomycetes C. cinerea [44], Moniliophthora perniciosa [45], Agrocybe aegerita [46], Lentinula edodes [47,48], Auricularia polytricha [49] and Ganoderma lucidum [50].…”

Section: Resultsmentioning

confidence: 99%

Simple Genetic Tools to Study Fruiting Body Development in Fungi

Silar¹

2014

TOMYCJ

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Unlike for animal and plant development, the molecular processes involved in shaping the multicellular fruiting bodies of fungi are almost unknown. Especially, the interplay between the mycelium, the maternal tissues and zygotic ones are seldom investigated. Here, I summarized simple genetic methods that permit to allocate site(s) of action for genes whose mutations block fruiting body development. These involve the formation of genetic mosaics and grafting, as used for many decades to study embryo development in animals and plants. They are easily implemented without the requirement of complex equipment. Yet, they provide useful information when one wants to order genes into pathways acting during fruiting body production. Examples taken from the study of the model ascomycete Podospora anserina illustrate how they can be interpreted.

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Section: Resultsmentioning

confidence: 99%

Simple Genetic Tools to Study Fruiting Body Development in Fungi

Silar¹

2014

TOMYCJ

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“…Interestingly, the presence of a gene coding for a secreted acid invertase has suggested that T. melanosporum is able to hydrolyze sucrose, unlike other ectomycorrhizal fungi, such as Laccaria bicolor (Martin et al 2008(Martin et al , 2010Ceccaroli et al 2011). In addition, transcripts of this gene have been reported to accumulate in the Hartig net compartment, i.e.…”

Section: The Black Truffle Genome Project and The Post-genomic Activimentioning

confidence: 98%

“…These data have improved the T. melanosporum genomic structural annotation and led to the identification of previously unidentified transcripts, exons, untranslated regions (UTRs) that extended in silico gene models and alternative splicing events. In addition, RNA-seq transcript profiling, which provides a global view on the transcriptome complexity, has been used for detailed analyses of specific gene groups (Balestrini et al 2012;Ceccaroli et al 2011;Montanini et al 2011;Rubini et al 2011a). More recently, the functional characterization of novel proteins has been obtained by Islam et al (2013).…”

Section: The Black Truffle Genome Project and The Post-genomic Activimentioning

confidence: 99%

“…The carbohydrate metabolism has been also investigated (Ceccaroli et al 2011), due to its special role related to nutrient exchange with the host plants and in metabolic support of fruiting body development. Interestingly, the presence of a gene coding for a secreted acid invertase has suggested that T. melanosporum is able to hydrolyze sucrose, unlike other ectomycorrhizal fungi, such as Laccaria bicolor (Martin et al 2008(Martin et al , 2010Ceccaroli et al 2011).…”

Section: The Black Truffle Genome Project and The Post-genomic Activimentioning

confidence: 99%

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Truffle Research in the Post-Genomics Era

Balestrini

Mello

2014

Food Anal. Methods

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The results originated in the frame of the genome sequencing project of the black truffle of Périgord (Tuber melanosporum) were published in 2010. Taking advantages from the sequencing project, which included automatic and manual annotation steps, specific studies were developed, in order to focus on specific gene categories (e.g. cell wallrelated genes, carbohydrate metabolism, environmental response genes, etc.) and, among them, specific gene families. This has allowed us to have, together with the transcriptomic data obtained during the sequencing phase, new knowledge on metabolic processes that may happen during the complex life cycle of a symbiotic fungus, such as Tuber. The aim of this review is (i) to highlight the work that has been done in postgenomics stage to better understand the molecular mechanisms occurring during the interaction of this fungus with the host plant, as well as those involved in the formation of precious truffles and (ii) to describe the results derived from projects mainly devoted to truffle identification in processed products and quality monitoring, as well as to the contribution of bacteria to truffle aroma.

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“…The genome sequence of the T. melanosporum black truffle fruiting body suggests that truffles possess all the genes needed to synthesize the key constituents of the truffle aroma (Martin et al 2010), and the Post-Genomics Era has been open to truffle research (Balestrini and Mello 2014;Kües and Martin 2011). Recently, the genomewide transcriptome studies have unraveled several developmental and metabolic pathways regulated by symbiosis and fruiting body formation, as well as environmental factors (Amicucci et al 2011;Bolchi et al 2011;Ceccaroli et al 2011;Montanini et al 2011;Zampieri et al 2011). However, the genes and enzymes involved in the biosynthesis of aroma active compounds, umami amino acids and 5′-nucleotides, and phytosterol are still unclear.…”

Section: Conclusion and Future Prospectsmentioning

confidence: 98%

Current progress on truffle submerged fermentation: a promising alternative to its fruiting bodies

Tang

Liu

2015

Appl Microbiol Biotechnol

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Truffle (Tuber spp.), also known as "underground gold," is popular in various cuisines because of its unique and characteristic aroma. Currently, truffle fruiting bodies are mostly obtained from nature and semi-artificial cultivation. However, the former source is scarce, and the latter is time-consuming, usually taking 4 to 12 years before harvest of the fruiting body. The truffle submerged fermentation process was first developed in Tang's lab as an alternative to its fruiting bodies. To the best of our knowledge, most reports of truffle submerged fermentation come from Tang's group. This review examines the current state of the truffle submerged fermentation process. First, the strategy to optimize the truffle submerged fermentation process is summarized; the final conditions yielded not only the highest reported truffle biomass but also the highest production of extracellular and intracellular polysaccharides. Second, the comparison of metabolites produced by truffle fermentation and fruiting bodies is presented, and the former were superior to the latter. Third, metabolites (i.e., volatile organic compounds, equivalent umami concentration, and sterol) derived from truffle fermentation could be regulated by fermentation process optimization. These findings indicated that submerged fermentation of truffles can be used for commercial production of biomass and metabolites as a promising alternative to generating its fruiting bodies in bioreactor.

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Genomic profiling of carbohydrate metabolism in the ectomycorrhizal fungus Tuber melanosporum

Cited by 47 publications

References 65 publications

Simple Genetic Tools to Study Fruiting Body Development in Fungi

Simple Genetic Tools to Study Fruiting Body Development in Fungi

Truffle Research in the Post-Genomics Era

Current progress on truffle submerged fermentation: a promising alternative to its fruiting bodies

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