Your search keyword '"Perlman PS"' showing total 11 results

1. A DEAD-box protein alone promotes group II intron splicing and reverse splicing by acting as an RNA chaperone.

Author

Mohr S, Matsuura M, Perlman PS, and Lambowitz AM

Subjects

Adenosine Triphosphate metabolism, Base Sequence, Introns, Kinetics, Magnesium metabolism, Magnesium pharmacology, Molecular Chaperones genetics, Nucleic Acid Conformation, RNA Helicases genetics, RNA, Fungal chemistry, RNA, Fungal genetics, RNA-Directed DNA Polymerase genetics, RNA-Directed DNA Polymerase metabolism, Recombinant Proteins genetics, Recombinant Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Salts metabolism, Temperature, Molecular Chaperones metabolism, RNA Helicases metabolism, RNA Splicing, RNA, Fungal metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Group II intron RNAs self-splice in vitro but only at high salt and/or Mg2+ concentrations and have been thought to require proteins to stabilize their active structure for efficient splicing in vivo. Here, we show that a DEAD-box protein, CYT-19, can by itself promote the splicing and reverse splicing of the yeast aI5gamma and bI1 group II introns under near-physiological conditions by acting as an ATP-dependent RNA chaperone, whose continued presence is not required after RNA folding. Our results suggest that the folding of some group II introns may be limited by kinetic traps and that their active structures, once formed, do not require proteins or high Mg2+ concentrations for structural stabilization. Thus, during evolution, group II introns could have spliced and transposed by reverse splicing by using ubiquitous RNA chaperones before acquiring more specific protein partners to promote their splicing and mobility. More generally, our results provide additional evidence for the widespread role of RNA chaperones in folding cellular RNAs.

Published

2006

2. The splicing of yeast mitochondrial group I and group II introns requires a DEAD-box protein with RNA chaperone function.

Author

Huang HR, Rowe CE, Mohr S, Jiang Y, Lambowitz AM, and Perlman PS

Subjects

Amino Acid Motifs genetics, Amino Acid Motifs physiology, DEAD-box RNA Helicases, Introns physiology, Mitochondria metabolism, Mutation, Protein Biosynthesis physiology, RNA Helicases genetics, RNA Processing, Post-Transcriptional genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins, Introns genetics, Mitochondria genetics, Molecular Chaperones metabolism, RNA biosynthesis, RNA Helicases metabolism, RNA Processing, Post-Transcriptional physiology

Abstract

Group I and II introns self-splice in vitro, but require proteins for efficient splicing in vivo, to stabilize the catalytically active RNA structure. Recent studies showed that the splicing of some Neurospora crassa mitochondrial group I introns additionally requires a DEAD-box protein, CYT-19, which acts as an RNA chaperone to resolve nonnative structures formed during RNA folding. Here we show that, in Saccharomyces cerevisiae mitochondria, a related DEAD-box protein, Mss116p, is required for the efficient splicing of all group I and II introns, some RNA end-processing reactions, and translation of a subset of mRNAs, and that all these defects can be partially or completely suppressed by the expression of CYT-19. Results for the aI2 group II intron indicate that Mss116p is needed after binding the intron-encoded maturase, likely for the disruption of stable but inactive RNA structures. Our results suggest that both group I and II introns are prone to kinetic traps in RNA folding in vivo and that the splicing of both types of introns may require DEAD-box proteins that function as RNA chaperones.

Published

2005

3. Retrotransposition of a yeast group II intron occurs by reverse splicing directly into ectopic DNA sites.

Author

Dickson L, Huang HR, Liu L, Matsuura M, Lambowitz AM, and Perlman PS

Subjects

Base Sequence, DNA Primers, Mutation, Polymerase Chain Reaction, RNA, Fungal genetics, DNA, Fungal genetics, Introns, Retroelements, Saccharomyces cerevisiae genetics

Abstract

Group II introns, the presumed ancestors of nuclear pre-mRNA introns, are site-specific retroelements. In addition to "homing" to unoccupied sites in intronless alleles, group II introns transpose at low frequency to ectopic sites that resemble the normal homing site. Two general mechanisms have been proposed for group II intron transposition, one involving reverse splicing of the intron RNA directly into an ectopic DNA site, and the other involving reverse splicing into a site in RNA followed by reverse transcription and integration of the resulting cDNA by homologous recombination. Here, by using an "inverted-site" strategy, we show that the yeast mtDNA group II intron aI1 retrotransposes by reverse splicing directly into an ectopic DNA site. This same mechanism could account for other previously described ectopic transposition events in fungi and bacteria and may have contributed to the dispersal of group II introns into different genes.

Published

2001

4. In organello formaldehyde crosslinking of proteins to mtDNA: identification of bifunctional proteins.

Author

Kaufman BA, Newman SM, Hallberg RL, Slaughter CA, Perlman PS, and Butow RA

Subjects

Cell Fractionation, Chaperonin 60 genetics, Chaperonin 60 isolation & purification, Citric Acid Cycle, Cross-Linking Reagents, DNA Replication, DNA, Fungal, Formaldehyde, Ketoglutarate Dehydrogenase Complex isolation & purification, Mass Spectrometry, Point Mutation, Protein Binding, Replication Origin, Saccharomyces cerevisiae, DNA, Mitochondrial chemistry, DNA, Single-Stranded chemistry, DNA-Binding Proteins isolation & purification, Fungal Proteins isolation & purification, Mitochondria chemistry

Abstract

The segregating unit of mtDNA is a protein-DNA complex called the nucleoid. In an effort to understand how nucleoid proteins contribute to mtDNA organization and inheritance, we have developed an in organello formaldehyde crosslinking procedure to identify proteins associated with mtDNA. Using highly purified mitochondria, we observed a time-dependent crosslinking of protein to mtDNA as determined by sedimentation through isopycnic cesium chloride gradients. We detected approximately 20 proteins crosslinked to mtDNA and identified 11, mostly by mass spectrometry. Among them is Abf2p, an abundant, high-mobility group protein that is known to function in nucleoid morphology, and in mtDNA transactions. In addition to several other proteins with known DNA binding properties or that function in mtDNA maintenance, we identified other mtDNA-associated proteins that were not anticipated, such as the molecular chaperone Hsp60p and a Krebs cycle protein, Kgd2p. Genetic experiments indicate that hsp60-ts mutants have a petite-inducing phenotype at the permissive temperature and that a kgd2Delta mutation increases the petite-inducing phenotype of an abf2Delta mutation. Crosslinking and DNA gel shift experiments show that Hsp60p binds to single-stranded DNA with high specificity for the template strand of a putative origin of mtDNA replication. These data identify bifunctional proteins that participate in the stability of rho(+) mtDNA.

Published

2000

5. The high mobility group protein Abf2p influences the level of yeast mitochondrial DNA recombination intermediates in vivo.

Author

MacAlpine DM, Perlman PS, and Butow RA

Subjects

Fungal Proteins genetics, Gene Expression Regulation, Fungal, High Mobility Group Proteins genetics, Transfection, DNA, Fungal genetics, DNA, Mitochondrial genetics, DNA-Binding Proteins genetics, Recombination, Genetic, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins, Transcription Factors genetics

Abstract

Abf2p is a high mobility group (HMG) protein found in yeast mitochondria that is required for the maintenance of wild-type (rho+) mtDNA in cells grown on fermentable carbon sources, and for efficient recombination of mtDNA markers in crosses. Here, we show by two-dimensional gel electrophoresis that Abf2p promotes or stabilizes Holliday recombination junction intermediates in rho+ mtDNA in vivo but does not influence the high levels of recombination intermediates readily detected in the mtDNA of petite mutants (rho-). mtDNA recombination junctions are not observed in rho+ mtDNA of wild-type cells but are elevated to detectable levels in cells with a null allele of the MGT1 gene (Deltamgt1), which codes for a mitochondrial cruciform-cutting endonuclease. The level of recombination intermediates in rho+ mtDNA of Deltamgt1 cells is decreased about 10-fold if those cells contain a null allele of the ABF2 gene. Overproduction of Abf2p by >/= 10-fold in wild-type rho+ cells, which leads to mtDNA instability, results in a dramatic increase in mtDNA recombination intermediates. Specific mutations in the two Abf2p HMG boxes required for DNA binding diminishes these responses. We conclude that Abf2p functions in the recombination of rho+ mtDNA.

Published

1998

6. Catalytically critical nucleotide in domain 5 of a group II intron.

Author

Peebles CL, Zhang M, Perlman PS, and Franzen JS

Subjects

Base Composition, Base Sequence, Binding, Competitive, Catalysis, Conserved Sequence, DNA-Directed RNA Polymerases genetics, Genetic Variation, Kinetics, Molecular Sequence Data, Promoter Regions, Genetic, RNA metabolism, RNA Precursors chemistry, RNA Precursors metabolism, RNA Splicing, Regression Analysis, Templates, Genetic, Thermodynamics, Transcription, Genetic, Viral Proteins, Introns, Nucleic Acid Conformation, RNA chemistry

Abstract

Domain 5 (D5) is a small hairpin structure within group II introns. A bimolecular assay system depends on binding by D5 to an intron substrate for self-splicing activity. In this study, mutations in D5 identify two among six nearly invariant nucleotides as being critical for 5' splice junction hydrolysis but unimportant for binding. A mutation at another site in D5 blocks binding. Thus, mutations can distinguish two D5 functions: substrate binding and catalysis. The secondary structure of D5 may resemble helix I formed by the U2 and U6 small nuclear RNAs in the eukaryotic spliceosome. Our results support a revision of the previously proposed correspondence between D5 and helix I on the basis of the critical trinucleotide 5'-AGC-3' present in both. We suggest that this trinucleotide plays a similar role in promoting the chemical reactions for both splicing systems.

Published

1995

7. In vivo double-strand breaks occur at recombinogenic G + C-rich sequences in the yeast mitochondrial genome.

Author

Zinn AR, Pohlman JK, Perlman PS, and Butow RA

Subjects

Base Composition, Genes, Fungal, Polymorphism, Genetic, DNA, Fungal genetics, DNA, Mitochondrial genetics, Gene Conversion, Recombination, Genetic, Saccharomyces cerevisiae genetics

Abstract

An optional 46-base-pair G + C-rich element (GC cluster) in the coding region of the yeast mitochondrial var1 gene inserts preferentially in crosses into recipient alleles that lack the sequence. Unlike a similar gene conversion event involving the insertion of an optional 1143-base-pair intron, the mitochondrial 21S rRNA gene, which requires the action of a protein encoded by a gene within that intron, conversion of the var1 GC cluster does not require any protein product of the mitochondrial genome. We have detected double-strand breaks in the var1 gene in mitochondrial DNA isolated from unmated haploid rho+ and rho- strains at or near the boundaries of the optional GC cluster, as well as at a conserved copy of that sequence 160 base pairs upstream. No double-strand breaks were detected in the recipient var1 DNA molecules in the vicinity of the optional GC cluster target sequence. This contrasts with 21S rRNA-encoding DNA (rDNA) intron conversion where the recipient, but not the donor DNA, is cleaved at the element insertion site. These results suggest that although the 21S rDNA intron and the var1 GC cluster are preferentially inserted into their respective short alleles, these conversions probably occur by different mechanisms.

Published

1988

8. Secondary structure of the Tetrahymena ribosomal RNA intervening sequence: structural homology with fungal mitochondrial intervening sequences.

Author

Cech TR, Tanner NK, Tinoco I Jr, Weir BR, Zuker M, and Perlman PS

Subjects

Base Sequence, DNA Restriction Enzymes, Mitochondria analysis, Nucleic Acid Conformation, Species Specificity, Physarum genetics, RNA, Ribosomal genetics, Tetrahymena genetics

Abstract

Splicing of the ribosomal RNA precursor of Tetrahymena is an autocatalytic reaction, requiring no enzyme or other protein in vitro. The structure of the intervening sequence (IVS) appears to direct the cleavage/ligation reactions involved in pre-rRNA splicing and IVS cyclization. We have probed this structure by treating the linear excised IVS RNA under nondenaturing conditions with various single- and double-strand-specific nucleases and then mapping the cleavage sites by using sequencing gel electrophoresis. A computer program was then used to predict the lowest-free-energy secondary structure consistent with the nuclease cleavage data. The resulting structure is appealing in that the ends of the IVS are in proximity; thus, the IVS can help align the adjacent coding regions (exons) for ligation, and IVS cyclization can occur. The Tetrahymena IVS has several sequences in common with those of fungal mitochondrial mRNA and rRNA IVSs, sequences that by genetic analysis are known to be important cis-acting elements for splicing of the mitochondrial RNAs. In the predicted structure of the Tetrahymena IVS, these sequences interact in a pairwise manner similar to that postulated for the mitochondrial IVSs. These findings suggest a common origin of some nuclear and mitochondrial introns and common elements in the mechanism of their splicing.

Published

1983

9. Expandable var1 gene of yeast mitochondrial DNA: in-frame insertions can explain the strain-specific protein size polymorphisms.

Author

Hudspeth ME, Vincent RD, Perlman PS, Shumard DS, Treisman LO, and Grossman LI

Subjects

Alleles, Amino Acid Sequence, Base Sequence, DNA Restriction Enzymes, Mitochondrial Proteins, Mutation, Species Specificity, DNA, Mitochondrial genetics, Fungal Proteins genetics, Genes, Fungal, Membrane Proteins, Polymorphism, Genetic, Ribosomal Proteins genetics, Saccharomyces cerevisiae Proteins

Abstract

The var1 locus of yeast mitochondrial DNA encodes a protein of the small mitochondrial ribosome subunit, denoted var1 protein. The size of var1 protein was previously shown to exhibit a strain-dependent polymorphism, determined by various combinations of at least three genetic elements. We report here that the var1 gene is itself polymorphic and that the six forms of this gene examined here differ by various combinations of three in-frame insertions into the coding region of the smallest allele. These insertions, which appear to be the molecular basis for the genetic elements, could increase the size of var1 protein by 8, 10, 16, 24, or 26 amino acid residues, accounting for the observed protein polymorphisms. Furthermore, we have characterized three additional sources of sequence variation located outside of the coding region but within major transcripts of the var1 gene.

Published

1984

10. Regulatory interactions between mitochondrial genes: interactions between two mosaic genes.

Author

Dhawale S, Hanson DK, Alexander NJ, Perlman PS, and Mahler HR

Subjects

DNA Restriction Enzymes, Mutation, Phenotype, Protein Biosynthesis, Species Specificity, DNA, Mitochondrial genetics, Genes, Regulator, Saccharomyces cerevisiae genetics

Abstract

We have studied the mitochondrial DNA and the phenotypes of strains of Saccharomyces cerevisiae with specific intervening sequences in two mosaic genes: cob (the gene for apocytochrome b) and oxi3 (the gene for subunit I of cytochrome oxidase). The results suggest the following. (i) The presence of an intervening sequence downstream encompassing the intron box7 is sufficient for the regulation of oxi3 by cob (BOX phenotype); two sequences (containing intron loci box3 and box10) upstream in cob and two in oxi3 are dispensable. (ii) Strains without the two sequences upstream still contain the downstream sequence and the competence to specify a functional trans-acting element. Mutational lesions in this segment are phenotypically indistinguishable from box7 mutants, including the accumulation of polypeptides with homologous amino acid sequences. (iii) A catabolite-sensitive BOX phenotype, characteristic of mutants in the first exon, requires the simultaneous presence of an adjacent intervening sequence. A model is presented in which a hypothetical product specified by an intron (locus box7) of the cob gene controls the expression of a second mosaic gene (oxi3).

Published

1981

11. Mitochondrial genetics in Bakers' yeast: a molecular mechanism for recombinational polarity and suppressiveness.

Author

Perlman PS and Birky CW Jr

Subjects

Crosses, Genetic, Genotype, Suppression, Genetic, DNA, Mitochondrial metabolism, Extrachromosomal Inheritance, Models, Biological, Recombination, Genetic, Saccharomyces cerevisiae metabolism

Abstract

Recombinational polarity and suppressiveness are two well-known but puzzling cytoplasmic genetic phenomena in bakers' yeast, Saccharomyces cerevisiae. Little progress has been made in characterizing the underlying molecular mechanisms of these phenomena. In this paper we describe a molecular model for recombinational polarity that is compatible with the available genetic evidence. The model stresses the role of small deletions and excision/repair processes in otherwise canonical recombinational events. According to the model, both phenomena require recombination and may share mechanistic elements.

Published

1974