Frequent, phylogenetically local horizontal transfer of the cox1 group I Intron in flowering plant mitochondria.
about
Nothing in Evolution Makes Sense Except in the Light of Genomics: Read-Write Genome Evolution as an Active Biological ProcessMassive mitochondrial gene transfer in a parasitic flowering plant cladeHorizontal transfer of an adaptive chimeric photoreceptor from bryophytes to fernsThe "fossilized" mitochondrial genome of Liriodendron tulipifera: ancestral gene content and order, ancestral editing sites, and extraordinarily low mutation rateEvolution of a horizontally acquired legume gene, albumin 1, in the parasitic plant Phelipanche aegyptiaca and related species.Gorgeous mosaic of mitochondrial genes created by horizontal transfer and gene conversionComparative transcriptome analyses reveal core parasitism genes and suggest gene duplication and repurposing as sources of structural novelty.Extensive loss of translational genes in the structurally dynamic mitochondrial genome of the angiosperm Silene latifolia.Conservation of intron and intein insertion sites: implications for life histories of parasitic genetic elementsComplete sequences of organelle genomes from the medicinal plant Rhazya stricta (Apocynaceae) and contrasting patterns of mitochondrial genome evolution across asterids.The Agaricus bisporus cox1 gene: the longest mitochondrial gene and the largest reservoir of mitochondrial group i introns.Horizontal transfer and gene conversion as an important driving force in shaping the landscape of mitochondrial introns.Insights into the evolution of mitochondrial genome size from complete sequences of Citrullus lanatus and Cucurbita pepo (Cucurbitaceae).Building a model: developing genomic resources for common milkweed (Asclepias syriaca) with low coverage genome sequencing.Multiple recent horizontal transfers of the cox1 intron in Solanaceae and extended co-conversion of flanking exons.Origins and recombination of the bacterial-sized multichromosomal mitochondrial genome of cucumber.Intron RNA editing is essential for splicing in plant mitochondria.Horizontal transfer of entire genomes via mitochondrial fusion in the angiosperm Amborella.MitoCOGs: clusters of orthologous genes from mitochondria and implications for the evolution of eukaryotes.Rapid mitochondrial genome evolution through invasion of mobile elements in two closely related species of arbuscular mycorrhizal fungiThe complete sequence of the mitochondrial genome of Butomus umbellatus--a member of an early branching lineage of monocotyledonsThe chloroplast genome of Hyoscyamus niger and a phylogenetic study of the tribe Hyoscyameae (Solanaceae)Miniaturized mitogenome of the parasitic plant Viscum scurruloideum is extremely divergent and dynamic and has lost all nad genesGinkgo and Welwitschia Mitogenomes Reveal Extreme Contrasts in Gymnosperm Mitochondrial Evolution.Complete mitochondrial genome of the medicinal fungus Ophiocordyceps sinensis.Evolution of group I introns in Porifera: new evidence for intron mobility and implications for DNA barcoding.Limited mitogenomic degradation in response to a parasitic lifestyle in OrobanchaceaePhylogenetic analysis of LSU and SSU rDNA group I introns of lichen photobionts associated with the genera Xanthoria and Xanthomendoza (Teloschistaceae, lichenized Ascomycetes).Hoarding and horizontal transfer led to an expanded gene and intron repertoire in the plastid genome of the diatom, Toxarium undulatum (Bacillariophyta).Multiple origins of endosymbionts in Chlorellaceae with no reductive effects on the plastid or mitochondrial genomes.Dynamic evolution of Geranium mitochondrial genomes through multiple horizontal and intracellular gene transfers.A Dynamic Mobile DNA Family in the Yeast Mitochondrial Genome.The mitochondrial genome of the terrestrial carnivorous plant Utricularia reniformis (Lentibulariaceae): Structure, comparative analysis and evolutionary landmarksHorizontal transfer of a ß-1,6-glucanase gene from an ancestral species of fungal endophyte to a cool-season grass host.Foreign Plastid Sequences in Plant Mitochondria are Frequently Acquired Via Mitochondrion-to-Mitochondrion Horizontal Transfer.Loss of a Trans-Splicing nad1 Intron from Geraniaceae and Transfer of the Maturase Gene matR to the Nucleus in Pelargonium.Homologous recombination and retention of a single form of most genes shape the highly chimeric mitochondrial genome of a cybrid plant.Evolution of plant mitochondrial intron-encoded maturases: frequent lineage-specific loss and recurrent intracellular transfer to the nucleus.Linear Plasmids and the Rate of Sequence Evolution in Plant Mitochondrial Genomes.Origin and Spread of Spliceosomal Introns: Insights from the Fungal Clade Zymoseptoria.
P2860
Q26315280-A1745BD0-CF16-48C9-B4AE-7E2F658E9246Q28286603-CC92BA1D-D969-4866-9D10-B5EC2C2B0BE9Q28657358-A937B920-C772-4243-98B9-34A8F66EDD3FQ28705183-8D68B07E-1975-4465-89A5-65A6930F2B47Q28709653-88521250-4321-4C67-967D-B9C30DAD6979Q28744147-31EB8DFD-D4B8-4D1F-9600-8C269ED6E596Q30301080-6706A3EC-48BB-48F9-B7BD-8491E42B3336Q30434749-7F5AAEEE-8A2A-4346-840D-2ED1F0682CB9Q33521535-A997A9EE-79B4-4CAB-A4AC-6A0ADC1C5900Q33712741-62B2A0C3-CDD9-40E2-BCEF-0755C8EB739CQ33761350-7900168E-6478-47D0-8F80-1995EF18CBEFQ33761676-16F9F73A-5948-4705-95A9-0DF2EBED9247Q33883103-6636062E-5264-4152-9B9C-A2314861CD5EQ33890010-223E2F8E-D1D4-4D9B-931C-39D3F15717BAQ34029246-88CF7135-CC14-47F3-B585-D3F413CF2027Q34199225-197BC029-4087-4501-8287-608F41E1F2ADQ34298176-2908C3C7-E1AB-4DBB-8A62-402CD8587F33Q34393252-FD70C3B2-8C80-4A37-8B21-99E8A23FF621Q34636052-FC2D81C7-4195-4B78-BADF-CB8913F56DAEQ34700002-49D918B3-C591-49CE-BBBF-6DBF2647B885Q34700391-74C17DBF-371B-4D39-8C9F-B5F035792931Q35172421-A07916D1-AEF7-475C-B7B0-48C1F9C46EC5Q35845837-5B756468-1DDC-4EC5-AE82-5991BE735523Q35910694-CBF2D01A-8F92-4186-AC81-F3BAF7CDD073Q36060623-FAF577C5-A31B-4902-BD04-5145B40FD536Q36315237-44889C85-5909-4BAD-A56B-8327C029F7A0Q37390465-76742896-CEAA-4A20-B686-87BBCF99487BQ37451353-64B5A521-22F5-4EB3-B5A7-AB6F370D34CDQ39364988-6635FA18-8208-4AC3-BA96-2A8CB6C1993AQ40064188-135148A3-5859-413E-A11E-09EC827093A2Q40923600-4E35A7A6-88B4-4C6E-A175-23B03C62664CQ41035624-C6AB11F9-C167-4F47-B8FE-6CE09200B459Q41058559-5778EF6A-92FE-4343-9DF0-40F94B08711DQ41490729-5A162643-2128-4E18-AC31-9447D52ABCD5Q42318153-EDEB01A1-4BEF-440F-B401-0E6464A12B7EQ42345746-97A212A6-3A52-442B-A6C7-88415DF817FDQ42557005-42D10491-480D-440B-96E8-3046146B83F4Q42615568-67106005-02A4-465E-B090-1270792C07DAQ42647297-D34AFD42-F305-41DB-A1F8-BB9E2B164677Q42675449-9A61CF3C-55FA-40C6-9DF1-E42F1C7597BA
P2860
Frequent, phylogenetically local horizontal transfer of the cox1 group I Intron in flowering plant mitochondria.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 03 June 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Frequent, phylogenetically loc ...... flowering plant mitochondria.
@en
Frequent, phylogenetically loc ...... flowering plant mitochondria.
@nl
type
label
Frequent, phylogenetically loc ...... flowering plant mitochondria.
@en
Frequent, phylogenetically loc ...... flowering plant mitochondria.
@nl
prefLabel
Frequent, phylogenetically loc ...... flowering plant mitochondria.
@en
Frequent, phylogenetically loc ...... flowering plant mitochondria.
@nl
P2093
P2860
P356
P1476
Frequent, phylogenetically loc ...... n flowering plant mitochondria
@en
P2093
Jeffrey D Palmer
Jeffrey P Mower
Yangrae Cho
P2860
P304
P356
10.1093/MOLBEV/MSN129
P577
2008-06-03T00:00:00Z