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[学术文献 ] Chromosome-level genome assembly of cultivated strawberry ‘Seolhyang’ (Fragaria × ananassa) 进入全文
Scientific Data
Cultivated strawberry (Fragaria × ananassa) belongs to the family Rosaceae and is an allo-octoploid species (2n = 8× = 56). Using PacBio Revio long reads of ‘Seolhyang’, we completed telomere-to-telomere phased genome assemblies with a size of 797 Mb with a contig N50 of 27.04 Mb. Benchmarking of the universal single-copy orthologs (BUSCO) analysis detected 99.1% conserved genes in the assembly. In addition, the average long terminal repeat assembly index (LAI) was 17.28, with high genome continuity. In this study, we identified 50 of the possible 56 telomeres across 28 chromosomes. The ‘Seolhyang’ genome was annotated using RNA-Seq data representing various F. × ananassa tissues from the NCBI sequence read archive, which resulted in 129,184 genes.
[学术文献 ] Sucrose-driven carbon redox rebalancing eliminates the Crabtree effect and boosts energy metabolism in yeast 进入全文
Nature Communications
Saccharomyces cerevisiae primarily generates energy through glycolysis and respiration. However, the manifestation of the Crabtree effect results in substantial carbon loss and energy inefficiency, which significantly diminishes product yield and escalates substrate costs in microbial cell factories. To address this challenge, we introduce the sucrose phosphorolysis pathway and delete the phosphoglucose isomerase gene PGI1, effectively decoupling glycolysis from respiration and facilitating the metabolic transition of yeast to a Crabtree-negative state. Additionally, a synthetic energy system is engineered to regulate the NADH/NAD ratio, ensuring sufficient ATP supply and maintaining redox balance for optimal growth. The reprogrammed yeast strain exhibits significantly higher yields of various non-ethanol compounds, with lactic acid and 3-hydroxypropionic acid production increasing by 8- to 11-fold comparing to the conventional Crabtree-positive strain. This study describes an approach for overcoming the Crabtree effect in yeast, substantially improving energy metabolism, carbon recovery, and product yields.
[学术文献 ] Ipecac alkaloid biosynthesis in two evolutionarily distant plants 进入全文
Nature Chemical Biology
Ipecac alkaloids are medicinal monoterpenoid-derived tetrahydroisoquinoline alkaloids found in two distantly related plants: Carapichea ipecacuanha (Gentianales) and Alangium salviifolium (Cornales). Here we provide evidence suggesting that both plants initiate ipecac alkaloid biosynthesis through a nonenzymatic Pictet–Spengler reaction and we elucidate the biosynthetic fate of both the 1R and 1S stereoisomers that are produced in this nonstereoselective reaction. Although the biosynthesis of the 1S-derived protoemetine proceeds according to the same chemical logic in both species, each plant uses a distinct monoterpene precursor. Phylogenetic analyses show examples of independent pathway evolution through parallel and convergently evolved enzymes. This work provides insight into how nature can capitalize on highly reactive starting substrates and the manner in which multistep pathways can arise and lays the foundation for metabolic engineering of these important medicinal compounds.
[学术文献 ] Utilizing plant synthetic biology to accelerate plant-microbe interactions research 进入全文
BioDesign Research
Plant-microbe interactions are critical to ecosystem resilience and substantially influence crop production. From the perspective of plant science, two important focus areas concerning plant-microbe interactions include: 1) understanding plant molecular mechanisms involved in plant-microbe interfaces and 2) engineering plants for increasing plant disease resistance or enhancing beneficial interactions with microbes to increase their resilience to biotic and abiotic stress conditions. Molecular biology and genetics approaches have been used to investigate the molecular mechanisms underlying plant responses to various beneficial and pathogenic microbes. While these approaches are valuable for elucidating the functions of individual genes and pathways, they fall short of unraveling the complex cross-talk across pathways or systems that plants employ to respond and adapt to environmental stresses. Also, genetic engineering of plants to increase disease resistance or enhance symbiosis with microbes has mainly been attempted or conducted through targeted manipulation of single genes/pathways of plants. Recent advancements in synthetic biology tool development are paving the way for multi-gene characterization and engineering in plants in relation to plant-microbe interactions. Here, we briefly summarize the current understanding of plant molecular pathways involved in plant interactions with beneficial and pathogenic microorganisms. Then, we highlight the progress in applying plant synthetic biology to elucidate the molecular basis of plant responses to microbes, enhance plant disease resistance, engineer synthetic symbiosis, and conduct in situ microbiome engineering. Lastly, we discuss the challenges, opportunities, and future directions for advancing plant-microbe interactions research using the capabilities of plant synthetic biology.
[学术文献 ] Chromosome-scale genome assembly of the fire blight resistant Malus fusca accession MAL0045, donor of FB_Mfu10 进入全文
Scientific Data
The wild apple, Malus fusca accession MAL0045, is highly resistant to fire blight disease, caused by the bacterial pathogen, Erwinia amylovora. A major resistance locus, FB_Mfu10 was identified on chromosome 10 of MAL0045 including other contributory loci on chromosomes 16, 4, and 15. Here, we report a chromosome-scale genome assembly of MAL0045 to facilitate the studies of its fire blight resistance. PacBio sequencing and Illumina sequencing for Hi-C contig anchorage were employed to obtain the genome. A total of 669.46 Mb sequences were anchored onto 17 chromosomes, taking up 99.75% of total contig length. Contigs anchored onto chromosomes were further ordered and orientated, where a total of 637.67 Mb sequences were anchored onto chromosomes in proper order and orientation, resulting in a final anchoring ratio of 95.25%. The BUSCO score of this assembly is 97.46%. Further, a total of 47,388 genes were predicted via ab initio, homology-based, and RNAseq methodologies. The availability of this genome will facilitate functional and comparative genomics studies, especially about the donors of fire blight resistance in Malus.
[学术文献 ] Identification of a gene conferring broad-spectrum orthotospovirus resistance in Solanaceae 进入全文
science
"Linkage drag can hinder the integration of resistance genes from wild crop relatives into breeding programs. We used a chromosome-scale Nicotiana alata genome assembly and a segregating population exceeding 160,000 plants to dissect the complex genetic architecture and overcome the tight linkage between resistance and deleterious loci to produce plants free from linkage drag. We cloned N. alata RTSW, encoding an immune receptor that confers broad-spectrum resistance to orthotospoviruses through the interaction of its carboxyl-terminal domain with an orthotospovirus-encoded protein. Notably, despite recognizing the same avirulen ce factor, RTSW genes from N. alata and Sw-5b from Solanum peruvianum have evolved independently of adjacent nonorthologous ancestral loci. Our work illustrates the potential of wild relative genomes as resources from which to precisely introduce disease resistance into cultivated crops."
