The Hypoxylaceae(Xylariales,Ascomycota)is a diverse family of mainly saprotrophic fungi,which commonly occur in angiosperm-dominated forests around the world.Despite their importance in forest and plant ecology as wel...The Hypoxylaceae(Xylariales,Ascomycota)is a diverse family of mainly saprotrophic fungi,which commonly occur in angiosperm-dominated forests around the world.Despite their importance in forest and plant ecology as well as a prolific source of secondary metabolites and enzymes,genome sequences of related taxa are scarce and usually derived from envi-ronmental isolates.To address this lack of knowledge thirteen taxonomically well-defined representatives of the family and one member of the closely related Xylariaceae were genome sequenced using combinations of Illumina and Oxford nanopore technologies or PacBio sequencing.The workflow leads to high quality draft genome sequences with an average N50 of 3.0 Mbp.A backbone phylogenomic tree was calculated based on the amino acid sequences of 4912 core genes reflecting the current accepted taxonomic concept of the Hypoxylaceae.A Percentage of Conserved Proteins(POCP)analysis revealed that 70%of the proteins are conserved within the family,a value with potential application for the definition of family boundaries within the order Xylariales.Also,Hypomontagnella spongiphila is proposed as a new marine derived lineage of Hypom.monticulosa based on in-depth genomic comparison and morphological differences of the cultures.The results showed that both species share 95%of their genes corresponding to more than 700 strain-specific proteins.This difference is not reflected by standard taxonomic assessments(morphology of sexual and asexual morph,chemotaxonomy,phylogeny),preventing species delimitation based on traditional concepts.Genetic changes are likely to be the result of environmental adaptations and selective pressure,the driving force of speciation.These data provide an important starting point for the establishment of a stable phylogeny of the Xylariales;they enable studies on evolution,ecological behavior and biosynthesis of natural products;and they significantly advance the taxonomy of fungi.展开更多
The unicellular green alga Chlamydomonas reinhardtii is capable of using organic and inorganic carbon sources simultaneously, which requires the adjustment of photosynthetic activity to the prevailing mode of carbon a...The unicellular green alga Chlamydomonas reinhardtii is capable of using organic and inorganic carbon sources simultaneously, which requires the adjustment of photosynthetic activity to the prevailing mode of carbon assimilation. We obtained novel insights into the regulation of light-harvesting at photosystem II (PSII) following altered carbon source avail- ability. In C. reinhardtii, synthesis of PSll-associated light-harvesting proteins (LHCBMs) is controlled by the cytosolic RNA- binding protein NAB1, which represses translation of particular LHCBM isoform transcripts. This mechanism is fine-tuned via regulation of the nuclear NAB1 promoter, which is activated when linear photosynthetic electron flow is restricted by CO2- limitation in a photoheterotrophic context. In the wild-type, accumulation of NAB1 reduces the functional PSII antenna size, thus preventing a harmful overexcited state of PSII, as observed in a NABl-less mutant. We further demonstrate that trans- lation control as a newly identified long-term response to prolonged CO2-1imitation replaces LHCII state transitions as a fast response to PSII over-excitation. Intriguingly, activation of the long-term response is perturbed in state transition mutant stt7, suggesting a regulatory link between the long- and short-term response. We depict a regulatory circuit operating on distinct timescales and in different cellular compartments to fine-tune light-harvesting in photoheterotrophic eukaryotes.展开更多
基金the DFG(Deutsche Forschungsgemeinschaft)priority program“Taxon-Omics:New Approaches for Discovering and Naming Biodiversity”(SPP 1991)The bioinformatics support of the BMBF-funded project‘Bielefeld-Gießen Center for Microbial Bioin-formaticsBiGi(Grant Number 031A533)’within the German Network for Bioinformatics Infrastructure(de.NBI)is gratefully acknowledged.
文摘The Hypoxylaceae(Xylariales,Ascomycota)is a diverse family of mainly saprotrophic fungi,which commonly occur in angiosperm-dominated forests around the world.Despite their importance in forest and plant ecology as well as a prolific source of secondary metabolites and enzymes,genome sequences of related taxa are scarce and usually derived from envi-ronmental isolates.To address this lack of knowledge thirteen taxonomically well-defined representatives of the family and one member of the closely related Xylariaceae were genome sequenced using combinations of Illumina and Oxford nanopore technologies or PacBio sequencing.The workflow leads to high quality draft genome sequences with an average N50 of 3.0 Mbp.A backbone phylogenomic tree was calculated based on the amino acid sequences of 4912 core genes reflecting the current accepted taxonomic concept of the Hypoxylaceae.A Percentage of Conserved Proteins(POCP)analysis revealed that 70%of the proteins are conserved within the family,a value with potential application for the definition of family boundaries within the order Xylariales.Also,Hypomontagnella spongiphila is proposed as a new marine derived lineage of Hypom.monticulosa based on in-depth genomic comparison and morphological differences of the cultures.The results showed that both species share 95%of their genes corresponding to more than 700 strain-specific proteins.This difference is not reflected by standard taxonomic assessments(morphology of sexual and asexual morph,chemotaxonomy,phylogeny),preventing species delimitation based on traditional concepts.Genetic changes are likely to be the result of environmental adaptations and selective pressure,the driving force of speciation.These data provide an important starting point for the establishment of a stable phylogeny of the Xylariales;they enable studies on evolution,ecological behavior and biosynthesis of natural products;and they significantly advance the taxonomy of fungi.
文摘The unicellular green alga Chlamydomonas reinhardtii is capable of using organic and inorganic carbon sources simultaneously, which requires the adjustment of photosynthetic activity to the prevailing mode of carbon assimilation. We obtained novel insights into the regulation of light-harvesting at photosystem II (PSII) following altered carbon source avail- ability. In C. reinhardtii, synthesis of PSll-associated light-harvesting proteins (LHCBMs) is controlled by the cytosolic RNA- binding protein NAB1, which represses translation of particular LHCBM isoform transcripts. This mechanism is fine-tuned via regulation of the nuclear NAB1 promoter, which is activated when linear photosynthetic electron flow is restricted by CO2- limitation in a photoheterotrophic context. In the wild-type, accumulation of NAB1 reduces the functional PSII antenna size, thus preventing a harmful overexcited state of PSII, as observed in a NABl-less mutant. We further demonstrate that trans- lation control as a newly identified long-term response to prolonged CO2-1imitation replaces LHCII state transitions as a fast response to PSII over-excitation. Intriguingly, activation of the long-term response is perturbed in state transition mutant stt7, suggesting a regulatory link between the long- and short-term response. We depict a regulatory circuit operating on distinct timescales and in different cellular compartments to fine-tune light-harvesting in photoheterotrophic eukaryotes.
