Search results for "Group II intron"

showing 8 items of 8 documents

Dynamic evolution of mitochondrial genomes in Trebouxiophyceae, including the first completely assembled mtDNA from a lichen-symbiont microalga (Treb…

2019

AbstractTrebouxiophyceae (Chlorophyta) is a species-rich class of green algae with a remarkable morphological and ecological diversity. Currently, there are a few completely sequenced mitochondrial genomes (mtDNA) from diverse Trebouxiophyceae but none from lichen symbionts. Here, we report the mitochondrial genome sequence of Trebouxia sp. TR9 as the first complete mtDNA sequence available for a lichen-symbiont microalga. A comparative study of the mitochondrial genome of Trebouxia sp. TR9 with other chlorophytes showed important organizational changes, even between closely related taxa. The most remarkable change is the enlargement of the genome in certain Trebouxiophyceae, which is princ…

0301 basic medicinePrasiolalesTrebouxiaMitochondrial DNALichensEvolutionlcsh:MedicineBiologyDNA MitochondrialGenomeArticleEvolution MolecularOpen Reading Frames03 medical and health sciences0302 clinical medicineIntergenic regionSpecies SpecificityChlorophytaPhylogeneticsMicroalgaelcsh:SciencePhylogenyMultidisciplinaryTrebouxiophyceaelcsh:RSequence Analysis DNAGroup II intronbiology.organism_classificationIntrons030104 developmental biologyTandem Repeat SequencesEvolutionary biologyGenome Mitochondriallcsh:QPlant sciences030217 neurology & neurosurgeryScientific Reports
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A variable intron distribution in globin genes of Chironomus: evidence for recent intron gain

1998

The intron positions found in globin genes of plants, protozoa and invertebrates have been interpreted as evidence for a three-intron-four-exon structure of the ancestral globin gene. In particular, the so-called 'central' introns, which are not found in vertebrate globin genes but are present in a variety of invertebrate and plant species, have been used as an argument for an ancestral gene structure featuring three introns. We have analyzed the presence or absence of central introns in the Gb genes 2beta, 9 and 7A of various European and Australasian species of the insect Chironomus. We find unrelated central introns at different positions in some of the species investigated, while other …

GeneticsBase SequencebiologyMolecular Sequence DataGene ConversionIntronVertebrateExonsGeneral MedicineGroup II intronbiology.organism_classificationChironomidaeIntronsGlobinsEvolution MolecularExonSpecies SpecificityMolecular evolutionSequence Homology Nucleic Acidbiology.animalGeneticsAnimalsChironomusGene conversionGeneGene
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A chimeric ribozyme in Clostridium difficile combines features of group I introns and insertion elements

2002

CdlSt1, a DNA insertion of 1975 bp, was identified within tcdA-C34, the enterotoxin gene of the Clostridium difficile isolate C34. Located in the catalytic domain A1-C34, Cd/St1 combines features of two genetic elements. Within the first 434 nt structures characteristic for group I introns were found; encoding the two transposase-like proteins tlpA and tlpB nucleotides 435-1975 represent the remainder of a IS605-like insertion element. We show that the entire CdlSt1 is accurately spliced from tcdA-C34 primary transcripts and that purified TcdA-C34 toxin is of regular size and catalytic activity. A search for CdlSt1-related sequences demonstrates that the element is widespread in toxinogenic…

GeneticsOpen reading framebiologyRNA splicingIntronRibozymebiology.proteinInterrupted geneGroup I catalytic intronGroup II intronORFSMolecular BiologyMicrobiologyMolecular Microbiology
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Demonstration that the Group II Intron from the Clostridial Conjugative Transposon Tn5397 Undergoes Splicing In Vivo

2001

Previous work has identified the conjugative transposon Tn5397 from Clostridium difficile. This element was shown to contain a group II intron. Tn5397 can be conjugatively transferred from C. difficile to Bacillus subtilis. In this work we show that the intron is spliced in both these hosts and that nonspliced RNA is also present. We constructed a mutation in the open reading frame within the intron, and this prevented splicing but did not prevent the formation of the circular form of the conjugative transposon (the likely transposition intermediate) or decrease the frequency of intergeneric transfer of Tn5397. Therefore, the intron is spliced, but splicing is not required for conjugation o…

GeneticsTransposable elementMutationClostridioides difficileRNA SplicingIntronRNAGroup II intronBiologymedicine.disease_causeMicrobiologyIntronsTransposition (music)Open reading frameRNA BacterialConjugation GeneticRNA splicingmedicineDNA Transposable ElementsRNA MessengerMolecular BiologyPlasmids and TransposonsBacillus subtilis
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Formation of new genes explains lower intron density in mammalian Rhodopsin G protein-coupled receptors

2007

Mammalian G protein-coupled receptor (GPCR) genes are characterised by a large proportion of intronless genes or a lower density of introns when compared with GPCRs of invertebrates. It is unclear which mechanisms have influenced intron density in this protein family, which is one of the largest in the mammalian genomes. We used a combination of Hidden Markov Models (HMM) and BLAST searches to establish the comprehensive repertoire of Rhodopsin GPCRs from seven species and performed overall alignments and phylogenetic analysis using the maximum parsimony method for over 1400 receptors in 12 subgroups. We identified 14 different Ancestral Receptor Groups (ARGs) that have members in both vert…

MammalsGeneticsRhodopsinProtein familyIntronComputational BiologySequence alignmentGroup II intronBiologyIntronsReceptors G-Protein-CoupledEvolution MolecularPhylogeneticsRhodopsinGeneticsbiology.proteinAnimalsHumansDatabases Nucleic AcidSequence AlignmentMolecular BiologyGenePhylogenyEcology Evolution Behavior and SystematicsG protein-coupled receptorMolecular Phylogenetics and Evolution
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The mitochondrial genome of fission yeast: inability of all introns to splice autocatalytically, and construction and characterization of an intronle…

1991

In this paper we report the inability of four group I introns in the gene encoding subunit I of cytochrome c oxidase (cox1) and the group II intron in the apocytochrome b gene (cob) to splice autocatalytically. Furthermore we present the characterization of the first cox1 intron in the mutator strain anar-14 and the construction and characterization of strains with intronless mitochondrial genomes. We provide evidence that removal of introns at the DNA level (termed DNA splicing) is dependent on an active RNA maturase. Finally we demonstrate that the absence of introns does not abolish homologous mitochondrial recombination.

Mitochondrial DNARNA MitochondrialRNA SplicingMolecular Sequence DataBiologyDNA MitochondrialGenomeElectron Transport Complex IVConsensus SequenceSchizosaccharomycesGeneticsGroup I catalytic intronAmino Acid SequenceCloning MolecularMolecular BiologyGeneGeneticsBase SequenceIntronRNAGroup II intronCytochromes bCytochrome b GroupIntronsMitochondriaRNA splicingNucleic Acid ConformationRNAApoproteinsMolecular and General Genetics MGG
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Evolutionary implications of intron-exon distribution and the properties and sequences of the RPL10A gene in eukaryotes.

2013

The RPL10A gene encodes the RPL10 protein, required for joining 40S and 60S subunits into a functional 80S ribosome. This highly conserved gene, ubiquitous across all eukaryotic super-groups, is characterized by a variable number of spliceosomal introns, present in most organisms. These properties facilitate the recognition of orthologs among distant taxa and thus comparative studies of sequences as well as the distribution and properties of introns in taxonomically distant groups of eukaryotes. The present study examined the multiple ways in which RPL10A conservation vs. sequence changes in the gene over the course of evolution, including in exons, introns, and the encoded proteins, can be…

Ribosomal ProteinsRibosomal Protein L10Molecular Sequence DataBiologyExon shufflingEvolution MolecularExonChlorophytaGeneticsMolecular BiologyGeneEcology Evolution Behavior and SystematicsConserved SequenceDNA PrimersGeneticsBase CompositionLikelihood FunctionsPhylogenetic treeBase SequenceModels GeneticIntronEukaryotaGenetic VariationBayes TheoremGroup II intronExonsSequence Analysis DNAIntronsEukaryotic RibosomeSequence AlignmentGC-contentMolecular phylogenetics and evolution
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Conservation of the positions of metazoan introns from sponges to humans

2002

Abstract Sponges (phylum Porifera) are the phylogenetic oldest Metazoa still extant. They can be considered as reference animals (Urmetazoa) for the understanding of the evolutionary processes resulting in the creation of Metazoa in general and also for the metazoan gene organization in particular. In the marine sponge Suberites domuncula , genes encoding p38 and JNK kinases contain nine and twelve introns, respectively. Eight introns in both genes share the same positions and the identical phases. One p38 intron slipped for six bases and the JNK gene has three more introns. However, the sequences of the introns are not conserved and the introns in JNK gene are generally much longer. Intron…

xMolecular Sequence Datap38 Mitogen-Activated Protein KinasesExonGene duplicationGeneticsAnimalsHumansCoding regionGroup I catalytic intronAmino Acid SequenceGeneConserved SequencePhylogenyCaenorhabditis elegansGeneticsBase SequenceSequence Homology Amino AcidbiologyCalcium-Binding ProteinsMicrofilament ProteinsJNK Mitogen-Activated Protein KinasesIntronDNASequence Analysis DNAGeneral MedicineGroup II intronbiology.organism_classificationIntronsPoriferaDNA-Binding ProteinsMitogen-Activated Protein KinasesSequence AlignmentGene
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