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[学术文献 ] Mitochondrial gene editing and allotopic expression unveil the role of orf125 in the induction of male fertility in some Solanum spp. hybrids and in the evolution of the common potato 进入全文
wiley
Genic-cytoplasmic male sterility (CMS) due to interactions between nuclear and cytoplasmic genomes is a well-known phenomenon in some Solanum spp. hybrids, but genes involved are not known. In this study, the chondriomes of two isonuclear male-fertile and sterile somatic hybrids (SH9A and SH9B, respectively) between the common potato (S. tuberosum Group Tuberosum, tbr) and the wild species S. commersonii were sequenced and compared to those of parental species to identify mitochondrial genes involved in the expression of male sterility. A putative novel gene (orf125) was found only in tbr and in male-sterile hybrids. Physical or functional deletion of orf125 by mtDNA editing in SH9B and its allotopic expression in SH9A clearly demonstrated that orf125 affects male fertility. Besides knockout mutants induced by mitoTALEN and DddA-derived cytosine base editing, specific orf125 missense mutations generated by the latter approach also induced reversion to male fertility in edited SH9B plants, prompting further studies on ORF125 structure–function relationship. The organization of the mitochondrial genome region implicated in CMS was found to be conserved across all common potato accessions, while an identical copy of tbr orf125 was detected in accessions belonging to the S. berthaultii species complex (ber). Such findings corroborate the hypothesis that ber accessions with T/β cytoplasm outcrossed as female with Andean potato, giving rise to the differentiation of the Chilean potato, and highlight the origin of mitochondrial factors contributing to genic-cytoplasmic male sterility in some tuber-bearing Solanum hybrids. Our results contribute to the development of innovative breeding approaches in potato.
[学术文献 ] A high-quality chromosome-level genome assembly for the agricultural pest Mythimna separata 进入全文
Scientific Data
The oriental armyworm, Mythimna separata, poses a persistent challenge to agricultural pest management due to its strong migratory abilities and polyphagous feeding behavior. In this study, we present a chromosome-level genome assembly using Illumina, PacBio HiFi, and Hi-C sequencing technologies. The final assembly spans 714.5 Mb with a scaffold N50 of 22.7 Mb and a GC content of 38.8%. A total of 32 chromosomes were successfully anchored, including the Z and W sex chromosomes. BUSCO analysis indicated a genome completeness of 98.6%, and 19,879 protein-coding genes were predicted. The W chromosome, measuring 30.55 Mb with a repeat content of 68.34%, harbors 824 protein-coding genes. Furthermore, a PCR-based method confirmed W-linked sequences for female-specific sex detection via the ZW system. This enhanced genome assembly provides a valuable resource for evolutionary research on M. separata and facilitates the development of sex-regulated pest control strategies.
[学术文献 ] De novo biosynthesis of plant lignans by synthetic yeast consortia 进入全文
Nature Chemical Biology
Reconstructing the biosynthesis of complex natural products such as lignans in yeast is challenging and can result in metabolic promiscuity, affecting the biosynthetic efficiency. Here we divide the lignan biosynthetic pathway across a synthetic yeast consortium with obligated mutualism and use ferulic acid as a metabolic bridge. This cooperative system successfully overcomes the metabolic promiscuity and synthesizes the common precursor, coniferyl alcohol. Furthermore, combined with systematic engineering strategies, we achieve the de novo synthesis of key lignan skeletons, pinoresinol and lariciresinol, and verify the scalability of the consortium by synthesizing complex lignans, including antiviral lariciresinol diglucoside. These results provide a starting engineering platform for the heterologous synthesis of lignans. In particular, the study illustrates that the yeast consortium with obligate mutualism is a promising strategy that mimics the metabolic division of labor among multiple plant cells, thereby improving the biosynthesis of long pathways and complex natural products.
[学术文献 ] Supra-second tracking and live-cell karyotyping reveal principles of mitotic chromosome dynamics 进入全文
Nature Cell Biology
Mitotic chromosome dynamics are essential for the three-dimensional organization of the genome during the cell cycle, but the spatiotemporal characteristics of this process remain unclear due to methodological challenges. While Hi-C methods capture interchromosomal contacts, they lack single-cell temporal dynamics, whereas microscopy struggles with bleaching and phototoxicity. Here, to overcome these limitations, we introduce Facilitated Segmentation and Tracking of Chromosomes in Mitosis Pipeline (FAST CHIMP), pairing time-lapse super-resolution microscopy with deep learning. FAST CHIMP tracked all human chromosomes with 8-s resolution from prophase to telophase, identified 15 out of 23 homologue pairs in single cells and compared chromosomal positioning between mother and daughter cells. It revealed a centrosome-motion-dependent flow that governs the mapping between chromosome locations at prophase and their metaphase plate position. In addition, FAST CHIMP measured supra-second dynamics of intra- and interchromosomal contacts. This tool adds a dynamic dimension to the study of chromatin behaviour in live cells, promising advances beyond the scope of existing methods.
[学术文献 ] The future of genome editing in plants 进入全文
nature plant
The future of genome editing in plants differs from how it is used today. For both research and product development, we need to think beyond the creation of simple single-nucleotide polymorphisms and short deletions in genes. We believe that the future of genome editing in plants involves mimicking the natural evolutionary processes that have shaped plant genomes and been the target of artificial selection during crop domestication and improvement. This includes programming large structural variations (insertions, duplications, deletions, inversions and translocations) and controlling plant recombination and endogenous transposable elements that naturally reshape plant genomes. The key is that genome editing will be used to reshape plant genomes in a manner that could have happened naturally, but now these changes can be directed rapidly in the laboratory.
[学术文献 ] CRISPR–Cas applications in agriculture and plant research 进入全文
Nature Reviews Molecular Cell Biology
Growing world population and deteriorating climate conditions necessitate the development of new crops with high yields and resilience. CRISPR–Cas-mediated genome engineering presents unparalleled opportunities to engineer crop varieties cheaper, easier and faster than ever. In this Review, we discuss how the CRISPR–Cas toolbox has rapidly expanded from Cas9 and Cas12 to include different Cas orthologues and engineered variants. We present various CRISPR–Cas-based methods, including base editing and prime editing, which are used for precise genome, epigenome and transcriptome engineering, and methods used to deliver the genome editors into plants, such as bacterial-mediated and viral-mediated transformation. We then discuss how promoter editing and chromosome engineering are used in crop breeding for trait engineering and fixation, and important applications of CRISPR–Cas in crop improvement, such as de novo domestication and enhancing tolerance to abiotic stresses. We conclude with discussing future prospects of plant genome engineering.
