Jean-Michel Savoie

Extracellular enzyme activities in six Lentinula edodes strains during cultivation in wheat straw

Lentinula edodes (Berk.) Pegler is found in nature on dead broadleaf trees, but it is commercially produced on different substrates. The question of adaptation to different lignocellulosic substrates was addressed by measuring enzyme activities produced by six strains that were cultivated on wheat straw and that were able to produce sporophores. Despite quantitative variations, each strain of L. edodes had similar patterns of enzyme secretion into the wheat straw log matrix. Two peaks of carbohydrase activities were observed, the first relating to the early mycelial growth during the first days after spawning and the second during sporophore extension. Laccase activity in the early stage of colonization was related to the degradation of soluble phenolic compounds present in wheat straw. Manganese peroxidase activity was associated with mycelia th. The strains with the earlier production and higher yield were able to hydrolyse and utilize straw cell wall components soon aft er inoculation, and developed high metabolic activities.

Extracellular laccase production during hyphal interactions between Trichoderma sp. and Shiitake, Lentinula edodes

Lentinula edodes (Berk.) Pegler was cultivated in liquid media containing malt and yeast extract. Extracellular laccase activity, measured in the culture fluids, was 5–18 times higher in cultures incubated for 29 days than in cultures incubated for 24 days. The addition of water-soluble lignin derivatives or Trichoderma sp. in cultures of L. edodes incubated for 11 days increased laccase activity 3- to 20 fold. The higher response was obtained with live mycelium of Trichoderma sp., but cell-free culture fluids of Trichoderma sp. in pure cultures were also effective. Trichoderma sp. induced changes in the laccase isoenzyme pattern as a result of the alteration of laccases secreted by L. edodes and not the induction of new isoforms.

Microbially induced diseases of Agaricus bisporus: biochemical mechanisms and impact on commercial mushroom production

The button mushroom, Agaricus bisporus (Lange) Imbach, the most common cultivated mushroom, is susceptible to a wide range of virus, bacterial, and fungal diseases. However, only some diseases were studied for the mechanisms involved in the host–microorganism interaction. This review deals with biochemical mechanisms related to cavity disease (Burkholderia gladioli) and to the interaction between A. bisporus and the causal agents responsible for the most severe diseases, namely the bacteria Pseudomonas tolaasii and Pseudomonas reactans and the fungi Trichoderma aggressivum and Lecanicillium fungicola.

Waste-reducing cultivation of Pleurotus ostreatus and Pleurotus pulmonarius on coffee pulp: changes in the production of some lignocellulolytic enzymes

Fruiting body production for one strain of Pleurotus ostreatus and three strains of P. pulmonarius was evaluated on coffee pulp pasteurized at 80 °C for 1 h. Based upon three harvests per strain, the single P. ostreatus line was found to display a 40-day culture cycle, whereas the three P. pulmonarius strains completed their cycles after more than 50 days of incubation. These time periods were notably shorter than those observed in previous studies using other growth substrates. Nevertheless, yields expressed as biological efficiencies were not significantly different among strains, fluctuating between 125 and 138%. Extracellular enzymatic activity was also monitored for P. ostreatus and P. pulmonarius (one strain only). To do this, samples of mycelium-bearing substrate were taken every 4 days throughout the incubation period. Care was taken to represent all developmental stages, including primordial and fruiting bodies. Samples were either lyophilized and then analysed or, in some cases, analysed immediately without lyophilization. Hydrolase activity (i.e. endoglucanase (CMC) and cellobiohydrolase (CBH)) was found to depend on developmental stage, showing peak production during fruiting body formation. On the other hand, oxidase activity-(i.e. laccase (LAC) and Mn-peroxidase (MnP)) was associated with phenol degradation. Nevertheless, in the case of oxidases developmental timing differences were also observed. Specifically, LAC activity was detected as early as 8 days after inoculation in non-lyophilized samples, whereas MnP appeared near the end of the incubation period. No LAC activity was observed in lyophilized samples. This study concludes that coffee pulp might be successfully employed in the cultivation of mushrooms, not only because important extracellular enzymes are produced by mushrooms when grown upon this substrate, but also because the abbreviated cultivation cycle associated with this medium favours commercial processes. Commercialization might be further improved if strains specifically adapted to this novel substrate are selected.

An expanded genetic linkage map of an intervarietal Agaricus bisporus var. bisporus × A. bisporus var. burnettii hybrid based on AFLP, SSR and CAPS markers sheds light on the recombination behaviour of the species

A genetic linkage map for the edible basidiomycete Agaricus bisporus was constructed from 118 haploid homokaryons derived from an intervarietal A. bisporus var. bisporus x A. bisporus var. burnettii hybrid. Two hundred and thirty-one AFLP, 21 SSR, 68 CAPS markers together with the MAT, BSN, PPC1 loci and one allozyme locus (ADH) were evenly spread over 13 linkage groups corresponding to the chromosomes of A. bisporus. The map covers 1156cM, with an average marker spacing of 3.9cM and encompasses nearly the whole genome. The average number of crossovers per chromosome per individual is 0.86. Normal recombination over the entire genome occurs in the heterothallic variety, burnettii, contrary to the homothallic variety, bisporus, which showed adaptive genome-wide suppressed recombination. This first comprehensive genetic linkage map for A. bisporus provides foundations for quantitative trait analyses and breeding programme monitoring, as well as genome organisation studies.

Interactions between the pathogen Trichoderma harzianum Th2 and Agaricus bisporus in mushroom compost

Trichoderma harzianum biotype Th2, re- sponsible for green mold disease, appeared in the North of France by the end of 1997. Cocultures of Agaricus bisporus with four French Th2 isolates and three less aggressive Trichoderma species were per- formed in conventional compost to further our un- derstanding of how Trichoderma Th2 establishes and competes with the button mushroom. Spore germi- nation of Th2 isolates was little affected by A. bisporus mycelium while that of other species was strongly in- hibited. Th2 mycelium flourished in compost unin- oculated or inoculated with A. bisporus, but myceli- um of the button mushroom is required for intensive sporulation. No fungistatic effect of the mycelium of Trichoderma on A. bisporus was observed in compost, but when Th2 produced spores, toxicity toward A. bisporus was detected. A simultaneous growth of A. bisporus and Th2 was observed before the mycelium of Agaricus stimulated the Th2 sporulation. As soon as sporulation occurred the mycelial growth of A. bis- porus was dramatically reduced and typical green

The medicinal Agaricus mushroom cultivated in Brazil: biology, cultivation and non-medicinal valorisation.

Sun mushroom is a cultivated mushroom extensively studied for its medicinal properties for several years and literature abounds on the topic. Besides, agronomical aspects were investigated in Brazil, the country the mushroom comes from, and some studies focus on the biology of the fungus. This review aimed to present an overview of the non-medicinal knowledge on the mushroom. Areas of commercial production and marketing trends are presented. Its specific fragrance, taste, nutritional value and potential use of extracts as food additives are compared to those of the most cultivated fungi and laboratory models. The interest of the mushroom for lignocellulosic enzyme production and source of biomolecules for the control of plant pathogens are shown. Investigation of genetic variability among cultivars is reported. Growing and storage of mycelium, as well as cultivation conditions (substrate and casing generally based on local products; indoor and outdoor cultivation; diseases and disorders) are described and compared to knowledge on Agaricus bisporus.

Production of edible mushrooms in forests: trends in development of a mycosilviculture

Developing the production of ectomycorrhizal (ECM) mushrooms in forest has become a challenge. Only a few ECM species are currently cultivable. Controlled mycorrhization practices offer promising advance to produce currently uncultivable ECM mushrooms. The persistence of the production of edible species, either cultivated or wild, depends on both the tree and the ecological environment (fungal communities, climate, soil, tree development). Developing adapted forest management practices appears to be means to improve production of edible ECM mushrooms. This review summarises current knowledge on the development of a science-based mycosilviculture for the production of edible ECM mushrooms.

Trichoderma harzianum metabolites pre-adapt mushrooms to Trichoderma aggressivum antagonism

Trichoderma spp. is the cause of green mold, a disorder that affects cultivated mushrooms. The aims of the study were to establish whether improvement of mushroom resistance to Trichoderma aggressivum could be obtained by inducing reaction mechanisms before contact with the pathogen and whether this ability was species or strain dependent. Twenty nine isolates of Agaricus bisporus, 29 isolates of Lentinula edodes and 18 isolates of Pleurotus spp. were studied. The effect of T. harzianum metabolites on mycelial growth of these isolates was evaluated on YMEA (yeast, malt extract and agar), supplemented or not with Lysing Enzymes from T. harzianum (Sigma®, L1412). Mycelial growth generally was affected by Lysing Enzymes, but some L. edodes and Pleurotus spp. adapted to Lysing Enzymes. When mycelium was taken from a first culture with Lysing Enzymes and placed on YMEA with Lysing Enzymes for a second culture, their growth rate was not different from those of the controls. In the case of A. bisporus, only partial adaptation was obtained with a few isolates. The effect of adaptation to Lysing Enzymes on resistance to T. aggressivum was assayed for one strain of each group. Trichoderma aggressivum was exposed to the margin of 5- to 9-day-old mushroom colonies. Agaricus bisporus produced brown droplets, and T. aggressivum overgrew its mycelium. Lentinula edodes and P. ostreatus produced brown lines blocking the progression of T. harzianum, both on YMEA and YMEA plus Lysing Enzymes. The line was visible after 3 d on YMEA and after only 2 d on YMEA plus Lysing Enzymes. Improvement in the resistance to antagonists by introduction of some of their metabolites to the culture medium is a method for mushroom protection.

Factors influencing the competitive saprophytic ability of Trichoderma harzianum Th2 in mushroom ( Agaricus bisporus ) compost

Green moulds caused by Trichoderma harzianum biotypes Th2 and Th4 are responsible for important economic losses on mushroom farms producing Agaricus bisporus , whereas other biotypes present in farms have only slight effects on the cultivated mushroom. Adaptation of Th2 and non-Th2 strains of Trichoderma to grow in compost prepared for mushroom cultivation was compared through extracellular enzyme activities and competition with bacteria isolated from compost. No specific differences between Th2 and non-Th2 strains were observed for the activities of the 17 secreted enzymes tested. Confrontations of 27 bacterial isolates with 4 Trichoderma strains revealed that the aggressive Th2 strains were affected by a lower number of bacterial isolates than the non-Th2 strains. Capacities of T. harzianum , biotype Th2, to colonise mushroom compost are not due to a specific ability to produce enzymes necessary for compost degradation but to their tolerance to the inhibitory effect of bacteria present in compost.