Linda Bonen scite author profile

For the first time a single experimental approach, 16 S ribosomal RNA sequence characterization, has been used to develop an overview of phylogenetic relationships in the bacterial world. The technique permits the tracing of relationships back to the common ancestor of all extant life. This first glimpse of bacterial phylogeny reveals a world whose roots appear to span more than 3 billion years. A deep phylogenetic split exists among the bacteria, which necessitates their division into two major lines of descent, the archaebacteria and the true bacteria (or eubacteria). It is a general finding that the most ancient bacterial phenotypes are anaerobic, and that aerobic phenotypes have arisen a number of times. Photosynthetic phenotypes are also extremely ancient. Many nonphotosynthetic groups appear to have arisen from photosynthetic ancestry, which is reason to question the generally held belief that the first bacteria were anaerobic heterotrophs. The two ultimate lines of bacterial descent are no more closely related to one another than either is to the cytoplasmic aspect of the eukaryotic cell. However, in that the eukaryotic cell is a phylogenetic chimera, it itself cannot be seen as a line of descent comparable to the two bacterial lines—although some of its individual parts can be so viewed. In this way, the chloroplast and perhaps the mitochondrion are each eubacterial, and at least one ribosomal protein is archaebacterial. A third line of descent that is neither eubacterial nor archaebacterial is represented in the 18 S ribosomal RNA.

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Shared Signatures of Parasitism and Phylogenomics Unite Cryptomycota and Microsporidia

James

et al. 2013

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Fungi grow within their food, externally digesting it and absorbing nutrients across a semirigid chitinous cell wall. Members of the new phylum Cryptomycota were proposed to represent intermediate fungal forms, lacking a chitinous cell wall during feeding and known almost exclusively from ubiquitous environmental ribosomal RNA sequences that cluster at the base of the fungal tree [1, 2]. Here, we sequence the first Cryptomycotan genome (the water mold endoparasite Rozella allomycis) and unite the Cryptomycota with another group of endoparasites, the microsporidia, based on phylogenomics and shared genomic traits. We propose that Cryptomycota and microsporidia share a common endoparasitic ancestor, with the clade unified by a chitinous cell wall used to develop turgor pressure in the infection process [3, 4]. Shared genomic elements include a nucleotide transporter that is used by microsporidia for stealing energy in the form of ATP from their hosts [5]. Rozella harbors a mitochondrion that contains a very rapidly evolving genome and lacks complex I of the respiratory chain. These degenerate features are offset by the presence of nuclear genes for alternative respiratory pathways. The Rozella proteome has not undergone major contraction like microsporidia; instead, several classes have undergone expansion, such as host-effector, signal-transduction, and folding proteins.

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The ins and outs of group II introns

2001

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Cis- and trans-splicing of group II introns in plant mitochondria

2008

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Excised group II introns in yeast mitochondria are lariats and can be formed by self-splicing in vitro

Veen

Arnberg

Horst

et al. 1986

Cell

323

135

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Conservation of primary structure in 16S ribosomal RNA

Woese

Fox

Zablen

et al. 1975

Nature

211

131

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Trans-splicing of pre-mRNA in plants, animals, and protists.

1993

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Messenger RNA maturation in eukaryotes typically involves the removal of introns from long precursor molecules. An unusual form of RNA splicing in which separate precursor transcripts contribute sequences to the mature mRNA through intermolecular reactions has now been documented in a number of diverse organisms. In this review, the phenomenon of pre-mRNA trans-splicing has been divided into two categories. The "spliced leader" type, found in protozoans such as trypanosomes and lower invertebrates such as nematodes, results in the addition of a short, capped 5' noncoding sequence to the mRNA. The "discontinuous group II intron" form of trans-splicing, found in plant/algal chloroplasts and plant mitochondria, involves the joining of independently transcribed coding sequences, presumably through interactions between "intronic" RNA pieces. Both categories of trans-splicing are mechanistically similar to conventional nuclear pre-mRNA cis-splicing; potential evolutionary relationships are discussed.

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The wheat mitochondrial gene for subunit I of the NADH dehydrogenase complex: A trans-splicing model for this gene-in-pieces

Chapdelaine

Bonen

1991

Cell

208

104

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Linda Bonen

The Phylogeny of Prokaryotes

Shared Signatures of Parasitism and Phylogenomics Unite Cryptomycota and Microsporidia

The ins and outs of group II introns

Cis- and trans-splicing of group II introns in plant mitochondria

Excised group II introns in yeast mitochondria are lariats and can be formed by self-splicing in vitro

Conservation of primary structure in 16S ribosomal RNA

Trans-splicing of pre-mRNA in plants, animals, and protists.

The wheat mitochondrial gene for subunit I of the NADH dehydrogenase complex: A trans-splicing model for this gene-in-pieces

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