Identification of the viridicatumtoxin and griseofulvin gene clusters from Penicillium aethiopicum
about
New penicillin-producing Penicillium species and an overview of section ChrysogenaBiosynthesis of oxygen and nitrogen-containing heterocycles in polyketidesAdvances in Aspergillus secondary metabolite research in the post-genomic eraNext-generation sequencing approach for connecting secondary metabolites to biosynthetic gene clusters in fungiEvolutionary relationships of microbial aromatic prenyltransferases.A genome-wide polyketide synthase deletion library uncovers novel genetic links to polyketides and meroterpenoids in Aspergillus nidulans.Classification, prediction, and verification of the regioselectivity of fungal polyketide synthase product template domains.Insights into radicicol biosynthesis via heterologous synthesis of intermediates and analogsFungal indole alkaloid biosynthesis: genetic and biochemical investigation of the tryptoquialanine pathway in Penicillium aethiopicumTotal synthesis and structural revision of viridicatumtoxin B.A genome-wide survey of the secondary metabolite biosynthesis genes in the wheat pathogen Parastagonospora nodorum.Total synthesis of viridicatumtoxin B and analogues thereof: strategy evolution, structural revision, and biological evaluation.A chemical ecogenomics approach to understand the roles of secondary metabolites in fungal cereal pathogens.Genomics-driven discovery of the pneumocandin biosynthetic gene cluster in the fungus Glarea lozoyensis.Genome-based deletion analysis reveals the prenyl xanthone biosynthesis pathway in Aspergillus nidulans.A genomics based discovery of secondary metabolite biosynthetic gene clusters in Aspergillus ustus.New insights into the formation of fungal aromatic polyketides.Bioinformatical analysis of the sequences, structures and functions of fungal polyketide synthase product template domains.Functional redundancy of necrotrophic effectors - consequences for exploitation for breeding.SnPKS19 Encodes the Polyketide Synthase for Alternariol Mycotoxin Biosynthesis in the Wheat Pathogen Parastagonospora nodorumGenome sequencing and secondary metabolism of the postharvest pathogen Penicillium griseofulvumIlluminating the diversity of aromatic polyketide synthases in Aspergillus nidulansBiosynthesis of Antibiotic Leucinostatins in Bio-control Fungus Purpureocillium lilacinum and Their Inhibition on Phytophthora Revealed by Genome Mining.Evolution of Chemical Diversity in a Group of Non-Reduced Polyketide Gene Clusters: Using Phylogenetics to Inform the Search for Novel Fungal Natural Products.Characterization of a silent azaphilone gene cluster from Aspergillus niger ATCC 1015 reveals a hydroxylation-mediated pyran-ring formation.Adaptive evolution of drug targets in producer and non-producer organisms.The polyketide synthase gene pks4 of Trichoderma reesei provides pigmentation and stress resistance.A cytochrome P450 serves as an unexpected terpene cyclase during fungal meroterpenoid biosynthesis.Discovery and characterization of a group of fungal polycyclic polyketide prenyltransferases.Impact of the Penicillium chrysogenum genome on industrial production of metabolites.Synthetic biological approaches to natural product biosynthesis.Discovering the secondary metabolite potential encoded within entomopathogenic fungi.Global analysis of biosynthetic gene clusters reveals vast potential of secondary metabolite production in Penicillium species.A Fivefold Parallelized Biosynthetic Process Secures Chlorination of Armillaria mellea (Honey Mushroom) Toxins.Prenyltransferases as key enzymes in primary and secondary metabolism.Impacts and perspectives of prenyltransferases of the DMATS superfamily for use in biotechnology.Comparative characterization of fungal anthracenone and naphthacenedione biosynthetic pathways reveals an α-hydroxylation-dependent Claisen-like cyclization catalyzed by a dimanganese thioesterase.Biosynthesis of fungal meroterpenoids.Co-culturing of Fungal Strains Against Botrytis cinerea as a Model for the Induction of Chemical Diversity and Therapeutic AgentsOxidative Cyclization in Natural Product Biosynthesis
P2860
Q24610902-3FED442E-FC6A-43DE-9BC3-81AC1D30FDE1Q26738945-93D6DFB6-7ED6-4258-B888-C60B7543849DQ26823169-51806612-CBDA-493E-8C66-656EB772D4D2Q28081722-80C6A864-0087-49C5-811D-525098751C23Q30155416-E8E6081B-0BFB-4413-8DA2-83DF52AD5A40Q33928023-E51AE791-2B03-478B-9F95-BBA40DA6D2A4Q34003788-0E916F5C-02E7-4F30-8E21-11F6885BD3D0Q34024374-586E2CA1-42F5-44A8-A67A-A39DE42C4D7BQ34163017-F235603F-03E3-4EFA-90D9-5CE2DD5802B9Q34360316-7B6C353E-4A28-44CA-AB7A-9FB5429573D7Q34385351-AB89CDDA-AB16-4D4F-A9BB-38934364D169Q34408147-597C9235-2614-43B8-A741-E6842A75F55EQ34541019-AC0AF8AF-AF5C-4CC0-9899-088053C3B10AQ34729062-91564B39-DA97-4BA8-BFBB-8D30AE50B23BQ35057853-01073EE9-395C-4137-B0B9-06FCA41C2413Q35112534-FA3D34FE-050D-43F3-89EB-0A7B0549B8C9Q35235074-FA1BF7AA-23AB-4619-8A70-C986185161B4Q35637445-FE2F886E-C29D-47D7-B59F-E9DABFF31E9DQ35829762-7EBD13CE-5E67-4CFF-8C38-0106FFDF5F49Q35876497-ADD3AE0C-EC36-427A-8E0A-E1AB627848C1Q35884691-1B3F556F-37F7-4F30-9183-E159C38C54E0Q35977059-A7F41FB0-4814-4ECD-9C78-2EC38219CAD0Q36077749-B420A445-0FFD-442E-B56E-4D75F5226E76Q36115211-733444E9-D9F5-48BA-A1EB-C9C04D55F66DQ36192706-6B7FFBF6-E35F-4864-A9EC-BC34D0454CCAQ36258978-83A77A9C-7031-49B3-A2D8-25AEA547E686Q37335926-F40A87DF-5A64-44E8-AE02-F161BC39D66BQ37412377-8423C688-8417-4F67-8FE3-2B8AC1C1E630Q37522818-F133CDE7-6768-4C1E-A503-8B2825BECD0AQ37909116-A13FD468-CDE9-4BF3-B1A0-965D7F62F48DQ37973514-9B6E28F7-B1CF-4F33-B953-A1555DACFD7DQ38242234-95694170-2939-4403-AC8A-E0076111734FQ38371710-E820CEDA-C889-4A1D-80D6-097A297BD1B4Q38386824-B4EC396F-C066-4BE5-A338-2CDEC0BECFDAQ38555536-577A86BD-7A16-4C89-A80D-0D3F6A68AF4FQ38557858-8E7B6989-B428-4935-8B17-8D6A208634CDQ38592486-A9D8F2D7-8567-45E1-8B81-7F42DF1FC51FQ38615304-A575F473-0C00-483E-A72E-A455CC3CC0A0Q38704964-4DFCCA0C-786D-450A-AE3F-9DC88B81673AQ39034361-A0AD3281-0941-4245-8132-EAB19CDFBA40
P2860
Identification of the viridicatumtoxin and griseofulvin gene clusters from Penicillium aethiopicum
description
2010 nî lūn-bûn
@nan
2010 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Identification of the viridica ...... s from Penicillium aethiopicum
@ast
Identification of the viridica ...... s from Penicillium aethiopicum
@en
Identification of the viridica ...... s from Penicillium aethiopicum
@en-gb
Identification of the viridica ...... s from Penicillium aethiopicum
@nl
type
label
Identification of the viridica ...... s from Penicillium aethiopicum
@ast
Identification of the viridica ...... s from Penicillium aethiopicum
@en
Identification of the viridica ...... s from Penicillium aethiopicum
@en-gb
Identification of the viridica ...... s from Penicillium aethiopicum
@nl
prefLabel
Identification of the viridica ...... s from Penicillium aethiopicum
@ast
Identification of the viridica ...... s from Penicillium aethiopicum
@en
Identification of the viridica ...... s from Penicillium aethiopicum
@en-gb
Identification of the viridica ...... s from Penicillium aethiopicum
@nl
P2860
P3181
P1476
Identification of the viridica ...... s from Penicillium aethiopicum
@en
P2093
P2860
P304
P3181
P356
10.1016/J.CHEMBIOL.2010.03.015
P407
P577
2010-05-28T00:00:00Z