Expansion and contraction of small RNA and methylation machinery throughout plant evolution
The revolution in sequencing has created a wealth of plant genomes that can be mined to understand the evolution of biological complexity. Complexity is often driven by gene duplication, which allows paralogs to specialize in an activity of the ancestral gene or acquire novel functions. Angiosperms...
Ausführliche Beschreibung
Autor*in: |
Chakraborty, Tania [verfasserIn] |
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Englisch |
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2022transfer abstract |
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Enthalten in: The effects of ball filling and ball diameter on kinetic breakage parameters of barite powder - 2012, London |
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volume:69 ; year:2022 ; pages:0 |
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10.1016/j.pbi.2022.102260 |
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10.1016/j.pbi.2022.102260 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000001951.pica (DE-627)ELV058985239 (ELSEVIER)S1369-5266(22)00089-9 DE-627 ger DE-627 rakwb eng 670 VZ 610 VZ 44.85 bkl Chakraborty, Tania verfasserin aut Expansion and contraction of small RNA and methylation machinery throughout plant evolution 2022transfer abstract nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier The revolution in sequencing has created a wealth of plant genomes that can be mined to understand the evolution of biological complexity. Complexity is often driven by gene duplication, which allows paralogs to specialize in an activity of the ancestral gene or acquire novel functions. Angiosperms encode a variety of gene silencing pathways that share related machinery for small RNA biosynthesis and function. Recent phylogenetic analysis of these gene families plots the expansion, specialization, and occasional contraction of this core machinery. This analysis reveals the ancient origin of RNA-directed DNA Methylation in early land plants, or possibly their algal ancestors, as well as ongoing duplications that evolve novel small RNA pathways. The revolution in sequencing has created a wealth of plant genomes that can be mined to understand the evolution of biological complexity. Complexity is often driven by gene duplication, which allows paralogs to specialize in an activity of the ancestral gene or acquire novel functions. Angiosperms encode a variety of gene silencing pathways that share related machinery for small RNA biosynthesis and function. Recent phylogenetic analysis of these gene families plots the expansion, specialization, and occasional contraction of this core machinery. This analysis reveals the ancient origin of RNA-directed DNA Methylation in early land plants, or possibly their algal ancestors, as well as ongoing duplications that evolve novel small RNA pathways. Small RNA Elsevier RNA-directed DNA Methylation Elsevier DNA methylation Elsevier Payne, Hayden oth Mosher, Rebecca A. oth Enthalten in Current Biology Ltd The effects of ball filling and ball diameter on kinetic breakage parameters of barite powder 2012 London (DE-627)ELV011200685 volume:69 year:2022 pages:0 https://doi.org/10.1016/j.pbi.2022.102260 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U 44.85 Kardiologie Angiologie VZ AR 69 2022 0 |
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The revolution in sequencing has created a wealth of plant genomes that can be mined to understand the evolution of biological complexity. Complexity is often driven by gene duplication, which allows paralogs to specialize in an activity of the ancestral gene or acquire novel functions. Angiosperms encode a variety of gene silencing pathways that share related machinery for small RNA biosynthesis and function. Recent phylogenetic analysis of these gene families plots the expansion, specialization, and occasional contraction of this core machinery. This analysis reveals the ancient origin of RNA-directed DNA Methylation in early land plants, or possibly their algal ancestors, as well as ongoing duplications that evolve novel small RNA pathways. |
abstractGer |
The revolution in sequencing has created a wealth of plant genomes that can be mined to understand the evolution of biological complexity. Complexity is often driven by gene duplication, which allows paralogs to specialize in an activity of the ancestral gene or acquire novel functions. Angiosperms encode a variety of gene silencing pathways that share related machinery for small RNA biosynthesis and function. Recent phylogenetic analysis of these gene families plots the expansion, specialization, and occasional contraction of this core machinery. This analysis reveals the ancient origin of RNA-directed DNA Methylation in early land plants, or possibly their algal ancestors, as well as ongoing duplications that evolve novel small RNA pathways. |
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The revolution in sequencing has created a wealth of plant genomes that can be mined to understand the evolution of biological complexity. Complexity is often driven by gene duplication, which allows paralogs to specialize in an activity of the ancestral gene or acquire novel functions. Angiosperms encode a variety of gene silencing pathways that share related machinery for small RNA biosynthesis and function. Recent phylogenetic analysis of these gene families plots the expansion, specialization, and occasional contraction of this core machinery. This analysis reveals the ancient origin of RNA-directed DNA Methylation in early land plants, or possibly their algal ancestors, as well as ongoing duplications that evolve novel small RNA pathways. |
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10.1016/j.pbi.2022.102260 |
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2024-07-06T20:38:13.157Z |
_version_ |
1803863503045394432 |
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