Thesis, which is known to be triggered by various environmental cues

September 8, 2017

Thesis, which is known to be triggered by various environmental cues in G. lucidum. We are currently creating the genetic mutants of G. lucidum that are deficient in Hog-1 to clarify the gene’s role in controlling GA biosynthesis in G. lucidum. In addition, the network controlling the various signaling pathways that regulate GA biosynthesis and apoptosis are under investigating by our group using both pharmacological and genetic approaches.Figure 7. Reactive oxygen species production in Ganoderma lucidum incubated with aspirin. Fungal mycelium was pre-loaded with 29,79-dichlorofluorescin diacetate and then incubated with 2?8 mM aspirin for 4 hr. doi:10.1371/journal.pone.0053616.gFigure 8. Phosphorylation of Hog-1 MAP kinases of Ganoderma lucidum in response to aspirin. (A) Fungal mycelium was incubated with 2 mM aspirin for 2?0 min. (B) Fungal mycelium was incubated with 1? mM aspirin for 5 min. Amount of actin detected by mouse anti-beta actin monoclonal antibody was used as the loading controls. doi:10.1371/journal.pone.0053616.gEnhanced GA Production by Apoptosis in G. lucidumConclusionsProduction and the biosynthetic regulation of secondary metabolites are important for the application of medicinal fungi and plants. Our results are the first findings to indicate that aspirin induces cell apoptosis in G. lucidum and that the induction of apoptosis coincides with GA biosynthesis. 26001275 The findings presented here Pentagastrin chemical information provided a novel and powerful approach to enhancing fungal secondary metabolite production, and potentially could be applied to other medicinal fungi and plants. Furthermore, our results indicate that ROS production and Hog-1 phosphorylation areinduced by aspirin. This provides insights into the regulation of triterpenoid biosynthesis and the fungal apoptosis signaling cascade.Author ContributionsParticipated in critical discussions and provided valuable suggestions: MHL. Conceived and designed the experiments: BJY NT MSL HZL. Performed the experiments: HCH LHT YLC. Analyzed the data: NT HCH LHT YLC. Wrote the paper: BJY MHL HZL.
Hepatitis C virus (HCV) is the major etiological agent of non-A, non-B hepatitis that infects almost 200 million people worldwide [1]. HCV is a major cause of post transfusion and communityacquired hepatitis. Approximately 70?0 of HCV patients develop chronic hepatitis of which 20?0 leads to liver disease, cirrhosis and hepatocellular carcinoma [2]. Treatment options for chronic HCV infection are limited, and a vaccine to prevent HCV infection is not available. The Met-Enkephalin web virion contains a positive-sense single stranded RNA genome of approximately 9.6 kb that consists of a highly conserved 59 non coding region followed by a long open reading frame of 9,030 to 9,099 nucleotides (nts). It is translated into a single polyprotein of 3,010 to 3030 amino acids [3,4]. A combination of host and viral proteases are involved in the polyprotein processing to generate ten different proteins. The structural proteins of HCV are comprised of the core protein (,21 kDa) and two envelope glycoproteins E1 (,31 kDa) and E2 (,70 kDa) [3?]. E1 and E2 are transmembrane proteins consisting of a large N-terminal ectodomain and a C-terminal hydrophobic anchor. E1 and E2 undergo post translationalmodifications by extensive N-linked glycosylation and are responsible for cell binding and entry [6?5]. Due to the error-prone nature of HCV RNA-dependent RNA polymerase and its high replicative rate in vivo, it shows a high degree of genetic var.Thesis, which is known to be triggered by various environmental cues in G. lucidum. We are currently creating the genetic mutants of G. lucidum that are deficient in Hog-1 to clarify the gene’s role in controlling GA biosynthesis in G. lucidum. In addition, the network controlling the various signaling pathways that regulate GA biosynthesis and apoptosis are under investigating by our group using both pharmacological and genetic approaches.Figure 7. Reactive oxygen species production in Ganoderma lucidum incubated with aspirin. Fungal mycelium was pre-loaded with 29,79-dichlorofluorescin diacetate and then incubated with 2?8 mM aspirin for 4 hr. doi:10.1371/journal.pone.0053616.gFigure 8. Phosphorylation of Hog-1 MAP kinases of Ganoderma lucidum in response to aspirin. (A) Fungal mycelium was incubated with 2 mM aspirin for 2?0 min. (B) Fungal mycelium was incubated with 1? mM aspirin for 5 min. Amount of actin detected by mouse anti-beta actin monoclonal antibody was used as the loading controls. doi:10.1371/journal.pone.0053616.gEnhanced GA Production by Apoptosis in G. lucidumConclusionsProduction and the biosynthetic regulation of secondary metabolites are important for the application of medicinal fungi and plants. Our results are the first findings to indicate that aspirin induces cell apoptosis in G. lucidum and that the induction of apoptosis coincides with GA biosynthesis. 26001275 The findings presented here provided a novel and powerful approach to enhancing fungal secondary metabolite production, and potentially could be applied to other medicinal fungi and plants. Furthermore, our results indicate that ROS production and Hog-1 phosphorylation areinduced by aspirin. This provides insights into the regulation of triterpenoid biosynthesis and the fungal apoptosis signaling cascade.Author ContributionsParticipated in critical discussions and provided valuable suggestions: MHL. Conceived and designed the experiments: BJY NT MSL HZL. Performed the experiments: HCH LHT YLC. Analyzed the data: NT HCH LHT YLC. Wrote the paper: BJY MHL HZL.
Hepatitis C virus (HCV) is the major etiological agent of non-A, non-B hepatitis that infects almost 200 million people worldwide [1]. HCV is a major cause of post transfusion and communityacquired hepatitis. Approximately 70?0 of HCV patients develop chronic hepatitis of which 20?0 leads to liver disease, cirrhosis and hepatocellular carcinoma [2]. Treatment options for chronic HCV infection are limited, and a vaccine to prevent HCV infection is not available. The virion contains a positive-sense single stranded RNA genome of approximately 9.6 kb that consists of a highly conserved 59 non coding region followed by a long open reading frame of 9,030 to 9,099 nucleotides (nts). It is translated into a single polyprotein of 3,010 to 3030 amino acids [3,4]. A combination of host and viral proteases are involved in the polyprotein processing to generate ten different proteins. The structural proteins of HCV are comprised of the core protein (,21 kDa) and two envelope glycoproteins E1 (,31 kDa) and E2 (,70 kDa) [3?]. E1 and E2 are transmembrane proteins consisting of a large N-terminal ectodomain and a C-terminal hydrophobic anchor. E1 and E2 undergo post translationalmodifications by extensive N-linked glycosylation and are responsible for cell binding and entry [6?5]. Due to the error-prone nature of HCV RNA-dependent RNA polymerase and its high replicative rate in vivo, it shows a high degree of genetic var.