Your search keyword '"John C. Kennell"' showing total 4 results

1. A mitochondrial retroplasmid integrates into mitochondrial DNA by a novel mechanism involving the synthesis of a hybrid cDNA and homologous recombination

Author

Chia Chien Chiang, John C. Kennell, Alan M. Lambowitz, and Leslie A. Wanner

Subjects

Mitochondrial DNA, DNA, Complementary, Molecular Sequence Data, DNA, Recombinant, Biology, DNA, Mitochondrial, Polymerase Chain Reaction, Plasmid, Complementary DNA, Molecular Biology, Gene, Recombination, Genetic, Genetics, Base Sequence, Models, Genetic, RNA, Sequence Analysis, DNA, Cell Biology, Ribosomal RNA, Neurospora, RNA, Ribosomal, Transfer RNA, Nucleic Acid Conformation, DNA, Circular, Homologous recombination, Research Article

Abstract

The Mauriceville and Varkud mitochondrial plasmids of Neurospora spp. are closely related, small circular DNAs that propagate via an RNA intermediate and reverse transcription. Although the plasmids ordinarily replicate autonomously, they can also integrate into mitochondrial DNA (mtDNA), yielding defective mtDNAs that in some cases cause senescence. To investigate the integration mechanism, we analyzed four cases in which the Varkud plasmid integrated into the mitochondrial small rRNA gene, three in wild-type subcultures and one in a senescent mutant. Our analysis suggests that the integrations occurred by the plasmid reverse transcriptase template switching between the plasmid transcript and internal sequences in the mitochondrial small rRNA to yield hybrid cDNAs that circularized and recombined homologously with the mtDNA. The integrated plasmid sequences are transcribed, presumably from the mitochondrial small rRNA promoters, resulting in hybrid RNAs containing the 5' segment of the mitochondrial small rRNA linked head-to-tail to the full-length plasmid transcript. Analysis of additional senescent mutants revealed three cases in which the plasmid used the same mechanism to integrate at other locations in the mtDNA. In these cases, circular variant plasmids that had incorporated a mitochondrial tRNA or tRNA-like sequence by template switching integrated by homologous recombination at the site of the corresponding tRNA or tRNA-like sequence in mtDNA. This simple integration mechanism involving template switching to generate a hybrid cDNA that integrates homologously could have been used by primitive retroelements prior to the acquisition of a specialized integration machinery.

Published

1994

2. The Mauriceville plasmid of Neurospora spp. uses novel mechanisms for initiating reverse transcription in vivo

Author

Alan M. Lambowitz, Huating Wang, and John C. Kennell

Subjects

Plasmid, biology, Rapid amplification of cDNA ends, Transcription (biology), Complementary DNA, biology.protein, RNA, Cell Biology, Primer (molecular biology), Molecular Biology, Molecular biology, Polymerase, Reverse transcriptase

Abstract

The Mauriceville plasmid and the closely related Varkud plasmid of Neurospora spp. are retroelements that propagate in mitochondria. Replication appears to occur by a novel mechanism in which a monomer-length plasmid transcript having a 3' tRNA-like structure ending in CCA is reverse transcribed to give a full-length minus-strand cDNA beginning at or near the 3' end of the RNA. Here, we show that the plasmids are transcribed in vitro by the Neurospora mitochondrial RNA polymerase, with the major in vitro transcription start site approximately 260 bp upstream of the 5' end of the plasmid transcript. The location of the transcription start site suggests that the monomer-length transcripts are generated by transcription around the plasmid combined with a site-specific RNA cleavage after the 3'-CCA sequence. The 5' ends of minus-strand cDNAs in ribonucleoprotein particles were analyzed to obtain insight into the mechanism of initiation of reverse transcription in vivo. A major class of minus-strand cDNAs begins opposite C2 of the 3'-CCA sequence, the same site used for de novo initiation of cDNA synthesis by the plasmid reverse transcriptase in vitro. A second class of minus-strand cDNAs begins with putative primer sequences that correspond to cDNA copies of the plasmid or mitochondrial transcripts. These findings are consistent with the possibility that the plasmid reverse transcriptase initiates minus-strand cDNA synthesis in vivo both by de novo initiation and by a novel template-switching mechanism in which the 3' OH of a previously synthesized cDNA is used to prime the synthesis of a new minus-strand cDNA directly at the 3' end of the plasmid transcript.

Published

1994

3. Mobile group II introns of yeast mitochondrial DNA are novel site-specific retroelements

Author

John V. Moran, John C. Kennell, Steven Zimmerly, Ronald A. Butow, Philip S. Perlman, Alan M. Lambowitz, and Robert Eskes

Subjects

Genetic Markers, Retroelements, Genes, Fungal, Molecular Sequence Data, Saccharomyces cerevisiae, Biology, DNA, Mitochondrial, Exon, Group I catalytic intron, Amino Acid Sequence, DNA, Fungal, Molecular Biology, Gene, Crosses, Genetic, Genetics, Base Sequence, Intron, RNA, RNA-Directed DNA Polymerase, Cell Biology, Group II intron, Introns, RNA splicing, Mutagenesis, Site-Directed, Mobile genetic elements, Research Article

Abstract

Group II introns aI1 and aI2 of the yeast mitochondrial COXI gene are mobile elements that encode an intron-specific reverse transcriptase (RT) activity. We show here that the introns of Saccharomyces cerevisiae ID41-6/161 insert site specifically into intronless alleles. The mobility is accompanied by efficient, but highly asymmetric, coconversion of nearbyflanking exon sequences. Analysis of mutants shows that the aI2 protein is required for the mobility of both aI1 and aI2. Efficient mobility is dependent on both the RT activity of the aI2-encoded protein and a separate function, a putative DNA endonuclease, that is associated with the Zn 21 finger-like region of the intron reading frame. Surprisingly, there appear to be two mobility modes: the major one involves cDNAs reverse transcribed from unspliced precursor RNA; the minor one, observed in two mutants lacking detectable RT activity, appears to involve DNA level recombination. Acis-dominant splicingdefectivemutantofaI2continuestosynthesizecDNAscontainingtheintronsbutiscompletelydefectiveinboth mobility modes, indicating that the splicing or the structure of the intron is required. Our results demonstrate that the yeast group II intron aI2 is a retroelement that uses novel mobility mechanisms. Some group I and group II introns are mobile genetic elements. Mobile group I introns are widespread, being found in organelle, bacteriophage, and nuclear genomes (reviewed in reference25).ThebasicmechanismofgroupIintronmobility, or homing, appears to be the same in all cases examined. Each mobile group I intron encodes a site-specific DNA endonuclease that cleaves intronless alleles, initiating intron movement by a double-strand DNA break gap repair process (47, 53). As a consequence of this process, there is extensive coconversion of markers flanking the mobile intron, often extending up to 500 bp on either side of the intron insertion site (25). Neither splicing nor the structure of the intron plays a role in group I intron mobility (4).

Published

1995

4. Development of an In Vitro Transcription System for Neurospora crassa Mitochondrial DNA and Identification of Transcription Initiation Sites

Author

Alan M. Lambowitz and John C. Kennell

Subjects

Mitochondrial DNA, Transcription, Genetic, Genes, Fungal, Molecular Sequence Data, Response element, Biology, DNA, Mitochondrial, Neurospora crassa, Transcription (biology), Consensus sequence, DNA, Fungal, Promoter Regions, Genetic, Gene, Molecular Biology, Genetics, Base Sequence, RNA, Fungal, Promoter, Cell Biology, Ribosomal RNA, biology.organism_classification, Molecular biology, Neurospora, RNA, Ribosomal, Mutation, Research Article

Abstract

We have developed an in vitro transcription system for Neurospora crassa mitochondrial DNA (mtDNA) and used it to identify transcription initiation sites at the 5' ends of the genes encoding the mitochondrial small and large rRNA and cytochrome b (cob). The in vitro transcription start sites correspond to previously mapped 5' ends of major in vivo transcripts of these genes. Sequences around the three transcription initiation sites define a 15-nucleotide consensus sequence, 5'-TTAGARA(T/G)G(T/G)ARTRR-3', all or part of which appears to be an element of an N. crassa mtDNA promoter. A somewhat looser 11-nucleotide consensus sequence, 5'-TTAGARR(T/G)R(T/G)A-3', was derived by including two additional promoters identified recently. Group I extranuclear mutants, such as [poky] and [SG-3], have a 4-base-pair (bp) deletion in the consensus sequence at the 5' end of the mitochondrial small rRNA and are grossly deficient in mitochondrial small rRNA (R. A. Akins and A. M. Lambowitz, Proc. Natl. Acad. Sci. USA 81:3791-3795, 1984). We show here that the 4-bp deletion in the consensus sequence decreases in vitro transcription from this site by more than 99%. N. crassa mtDNA is similar to Saccharomyces cerevisiae mtDNA in having multiple promoters, including separate promoters for the genes encoding the mitochondrial small and large rRNAs. Our results suggest that the primary effect of the 4-bp deletion in group I extranuclear mutants is to inhibit transcription of the mitochondrial small rRNA, leading to severe deficiency of mitochondrial small rRNA and small ribosomal subunits.

Published

1989