Project description:To study the mechanism of protective effect by White Button Mushroom (WBM) for Nonalcoholic Fatty Liver Disease (NAFLD) in ovariectomized mice (model for postmenopausal women).

Project description:Purpose: To evalute the antagonistic effects of White Button Mushroom/WBM extract on AR signaling in human prostate cance cells. Methods: LNCaP cells were treated with 1 nM DHT, with or without WBM extract (3 μL/mL), for 48h, in triplicates, and total RNA was isolated and sequenced. Results: We identified 155 up-regulated genes (Fold-change ≥ 2, p<0.05) versus 185 down-regulated genes (Fold-change ≤ 0.5, p<0.05). Conclusion: White Button Mushroom suppressed androgen respsonive genens and cell cycle division genes Collectively, these results suggest that WBM extract affects prostate cancer by interrupting AR-dependent cell cycle division and DNA replication.

Project description:To study the mechanism of protective effect by White Button Mushroom (WBM) for Nonalcoholic Fatty Liver Disease (NAFLD) in ovariectomized mice (model for postmenopausal women). The ovariectomized mice were fed WBM diet for 3 month, sacrificed to harvest liver. 4 mice for control diet and 4 mice for WBM diet.

Project description:The white button mushroom Agaricus bisporus is the most widely produced edible fungus with a great economical value. Its commercial cultivation process is often performed on wheat straw and animal manure based compost that mainly contains lignocellulosic material as a source of carbon and nutrients for the mushroom production. As a large portion of compost carbohydrates are left unused in the current mushroom cultivation process, the aim of this work was to study wild-type A. bisporus strains for their potential to convert the components that are poorly utilized by the commercial strain A15. Growth profiling suggested different abilities for several A. bisporus strains to use plant biomass derived polysaccharides, as well as to transport and metabolize the corresponding monomeric sugars. Six wild-type isolates with diverse growth profiles were compared for mushroom production to A15 strain in semi-commercial cultivation conditions. Transcriptome and proteome analyses of the three most interesting wild-type strains and A15 indicated that the unrelated A. bisporus strains degrade and convert plant biomass polymers in a highly similar manner. This was also supported by the chemical content of the compost during the mushroom production process. Our study therefore reveals a highly conserved physiology for unrelated strains of this species during growth in compost.

Project description:Microbiomes in commercial white button mushroom production

Project description:In prostate cancer patients following 3 months of white button mushroom consumption in freeze-dried tablet form, we observed the decline of circulating polymorphonuclear MDSCs (PMN-MDSCs), along with an increase of granzyme B positive CD8+ T cells and NK cells. Furthermore, single immune cell profiling of peripheral blood from WBM-treated patients revealed the transcriptional landscape of circulating immune cells. This methods showed a decrease in overall circulating PMN-MDSCs with suppression on the expression of STAT3/IRF1 and TGFβ signaling. Subclusters of PMN-MDSCs showed transcriptional profiles associated with "response to fungus", "neutrophil chemotaxis", "leukocyte aggregation", and "regulation of inflammatory response", which are associated with enhanced immune-modulated anti-tumor activity.

Project description:In prostate cancer patients following 3 months of white button mushroom consumption in freeze-dried tablet form, we observed the decline of circulating polymorphonuclear MDSCs (PMN-MDSCs), along with an increase of granzyme B positive CD8+ T cells and NK cells. Furthermore, single immune cell profiling of peripheral blood from WBM-treated patients revealed the transcriptional landscape of circulating immune cells. This methods showed a decrease in overall circulating PMN-MDSCs with suppression on the expression of STAT3/IRF1 and TGFβ signaling. Subclusters of PMN-MDSCs showed transcriptional profiles associated with "response to fungus", "neutrophil chemotaxis", "leukocyte aggregation", and "regulation of inflammatory response", which are associated with enhanced immune-modulated anti-tumor activity.

Project description:Liver protective effects of white button mushroom (Agaricus Bisporus)

Project description:The soft rot pathogen Janthinobacterium agaricidamnosum causes devastating damage to button mushrooms (Agaricus bisporus), one of the most cultivated and commercially relevant mushrooms. We previously discovered that this pathogen releases the membrane-disrupting lipopeptide jagaricin. This bacterial toxin, however, could not solely explain the rapid decay of mushroom fruiting bodies, indicating that J. agaricidamnosum implements a more sophisticated infection strategy. In this study, we show that secretion systems play a crucial role in soft rot disease. By mining the genome of J. agaricidamnosum, we identified gene clusters encoding a type I (T1SS), a type II (T2SS), a type III (T3SS), and two type VI secretion systems (T6SS). Through a combination of knockout studies and bioassays, we found that the T2SS and T3SS of J. agaricidamnosum are required for soft rot disease. Furthermore, comparative secretome analysis and activity-guided fractionation identified a number of secreted lytic enzymes responsible for mushroom damage. Our findings regarding the contribution of secretion systems to the disease process expand the current knowledge of bacterial soft rot pathogens and represent a significant stride towards identifying targets for their disarmament with secretion system inhibitors.

Project description:Agaricus bisporus is a soil-inhabiting fungus which is cultivated for production of white button mushrooms. A disease of A. bisporus has been previously described with a range of disease symptoms (yield loss, pinning delay, cap distortions and cap browning) which has been given collective name of “Mushroom Virus X” (MVX). The causes of this disease are not clear however prior to this research an association was found between the disease and double-stranded RNA molecules in the mushroom fruitbodies. The experiment was designed to examine causes and host responses of the disease causing the Brown Cap symptom in the cultivated mushroom A. bisporus. This microarray experiment was performed before the Agaricus bisporus genome was sequenced. The gene sequences used to design probes were from known and novel A. bisporus sequences and sequences of transcript fragments identified by Suppression Subtractive Hybridization of non-symptomatic and virus-diseased A. bisporus mushroom fruitbodies. The A. bisporus mushroom fruitbodies were grown on composted wheat straw using commercial cultivation procedures. The gene expression comparison was made of RNA isolated from 32 mushroom fruitbodies (Agaricus bisporus) samples: 20 samples from 5 separate virus-infected commercial mushroom farms with crops displaying the brown symptom (4 replicate samples per farm) and 12 samples from a non-infected crop grown at the University of Warwick. The precise composition of the viral load was the subject of this and future research/papers. Abstract of Manuscript submitted to Applied and Environmental Microbiology: Characterizing the viral agents causing brown cap mushroom disease of Agaricus bisporus by Daniel Eastwood, Julian Green, Helen Grogan, and Kerry Burton (Paper #AEM01093-15). The symptoms of viral infections of fungi range from cryptic to severe but there is little knowledge of the factors involved in this transition of fungal/viral interactions. Brown Cap Mushroom Disease of the cultivated Agaricus bisporus is economically important and represents a model system to describe this transition. Differentially expressed transcript fragments between mushrooms showing the symptoms of Brown Cap Mushroom Disease and control white non-infected mushrooms have been identified and sequenced. Ten of these RNA fragments have been found to be up-regulated over a thousand-fold between diseased and non-diseased tissue but are absent from the Agaricus bisporus genome sequence and hybridise to double-stranded RNA’s extracted from diseased tissue. We hypothesize these transcript fragments are viral and represent components of the disease-causing agent, a bipartite virus with similarities to the family Partitiviridae. The virus fragments were found at two distinct levels within infected mushrooms, at raised levels in infected, non-symptomatic, white coloured mushrooms and much greater levels (3,500-87,000 times greater) in infected mushrooms exhibiting brown colouration. In addition, differential screening revealed 9 up-regulated and 32 down-regulated host Agaricus bisporus transcripts. Chromametric analysis was able to distinguish colour differences between non-infected white mushrooms and white infected mushrooms at an early stage of mushroom growth. This method may be the basis for an ‘on-farm’ disease detection assay. A gene expression comparison was made between diseased mushroom displaying the brown cap symptom with characteristic double-strand RNA profiles (banding pattern on gels) and non-symptomatic virus-free mushrooms. In total RNA was isolated from 32 mushroom fruitbody (Agaricus bisporus) samples: 20 samples from 5 separate virus-infected commercial mushroom farms with crops displaying the brown symptom (4 replicate samples per farm) and 12 samples from a non-infected crop grown at the University of Warwick. Commercially-grown mushrooms are produced in “flushes” at approximately weekly intervals. The samples were collected from commercial farms when symptoms were reported to us but these were from different flushes: Farm1 from the 2nd flush; Farm 2 from the 1st flush; Farm 3 from the 3rd flush; Farm 4 from the 1st flush; and Farm 9 from the 1st flush. To allow for comparisons on the basis of Flush Number, the non-infected mushrooms grown at the University of Warwick were sampled from the first, second and third flushes, 4 mushrooms sampled from each flush.