Your search keyword '"Perlman PS"' showing total 113 results

1. A structural analysis of the group II intron active site and implications for the spliceosome.

Author

Keating KS, Toor N, Perlman PS, and Pyle AM

Subjects

Base Sequence, Crystallography, X-Ray, Eukaryotic Cells metabolism, Models, Biological, Models, Molecular, Molecular Sequence Data, RNA Splice Sites genetics, RNA, Catalytic chemistry, RNA, Catalytic genetics, Spliceosomes metabolism, Structure-Activity Relationship, Alternative Splicing genetics, Catalytic Domain genetics, Introns genetics, Nucleic Acid Conformation, Spliceosomes physiology

Abstract

Group II introns are self-splicing, mobile genetic elements that have fundamentally influenced the organization of terrestrial genomes. These large ribozymes remain important for gene expression in almost all forms of bacteria and eukaryotes and they are believed to share a common ancestry with the eukaryotic spliceosome that is required for processing all nuclear pre-mRNAs. The three-dimensional structure of a group IIC intron was recently determined by X-ray crystallography, making it possible to visualize the active site and the elaborate network of tertiary interactions that stabilize the molecule. Here we describe the molecular features of the active site in detail and evaluate their correspondence with prior biochemical, genetic, and phylogenetic analyses on group II introns. In addition, we evaluate the structural significance of RNA motifs within the intron core, such as the major-groove triple helix and the domain 5 bulge. Having combined what is known about the group II intron core, we then compare it with known structural features of U6 snRNA in the eukaryotic spliceosome. This analysis leads to a set of predictions for the molecular structure of the spliceosomal active site.

Published

2010

2. 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

3. 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

4. Abortive transposition by a group II intron in yeast mitochondria.

Author

Dickson L, Connell S, Huang HR, Henke RM, Liu L, and Perlman PS

Subjects

Crosses, Genetic, Cyclooxygenase 1, DNA, Complementary genetics, Introns genetics, Polymorphism, Restriction Fragment Length, Prostaglandin-Endoperoxide Synthases genetics, Ribonucleoproteins genetics, DNA Transposable Elements genetics, Gene Rearrangement genetics, Mitochondria genetics, Models, Genetic, Ribonucleoproteins metabolism, Yeasts genetics

Abstract

Group II intron homing in yeast mitochondria is initiated at active target sites by activities of intron-encoded ribonucleoprotein (RNP) particles, but is completed by competing recombination and repair mechanisms. Intron aI1 transposes in haploid cells at low frequency to target sites in mtDNA that resemble the exon 1-exon 2 (E1/E2) homing site. This study investigates a system in which aI1 can transpose in crosses (i.e., in trans). Surprisingly, replacing an inefficient transposition site with an active E1/E2 site supports <1% transposition of aI1. Instead, the ectopic site was mainly converted to the related sequence in donor mtDNA in a process we call "abortive transposition." Efficient abortive events depend on sequences in both E1 and E2, suggesting that most events result from cleavage of the target site by the intron RNP particles, gapping, and recombinational repair using homologous sequences in donor mtDNA. A donor strain that lacks RT activity carries out little abortive transposition, indicating that cDNA synthesis actually promotes abortive events. We also infer that some intermediates abort by ejecting the intron RNA from the DNA target by forward splicing. These experiments provide new insights to group II intron transposition and homing mechanisms in yeast mitochondria.

Published

2004

5. Molecular biology. Ring around the retroelement.

Author

Perlman PS and Boeke JD

Subjects

Cytoplasm metabolism, DNA Replication, DNA, Complementary biosynthesis, DNA, Complementary metabolism, Guanosine Diphosphate metabolism, Mutation, Nucleic Acid Conformation, RNA Caps, RNA Nucleotidyltransferases genetics, RNA Nucleotidyltransferases metabolism, RNA Splicing, RNA, Fungal genetics, RNA, Messenger chemistry, RNA, Messenger genetics, RNA, Messenger metabolism, RNA-Directed DNA Polymerase metabolism, Retroelements genetics, Saccharomyces cerevisiae metabolism, Terminal Repeat Sequences, Transcription, Genetic, RNA, Fungal chemistry, RNA, Fungal metabolism, Retroelements physiology, Saccharomyces cerevisiae genetics

Published

2004

6. The DIVa maturase binding site in the yeast group II intron aI2 is essential for intron homing but not for in vivo splicing.

Author

Huang HR, Chao MY, Armstrong B, Wang Y, Lambowitz AM, and Perlman PS

Subjects

Base Sequence, Binding Sites genetics, DNA, Fungal chemistry, DNA, Fungal genetics, DNA, Fungal metabolism, DNA, Mitochondrial chemistry, DNA, Mitochondrial genetics, DNA, Mitochondrial metabolism, Genetic Complementation Test, Molecular Sequence Data, Mutation, Nucleic Acid Conformation, Open Reading Frames, RNA chemistry, RNA genetics, RNA metabolism, RNA Splicing, RNA, Fungal chemistry, RNA, Fungal genetics, RNA, Fungal metabolism, RNA, Mitochondrial, Introns, RNA-Directed DNA Polymerase metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Splicing of the Saccharomyces cerevisiae mitochondrial DNA group II intron aI2 depends on the intron-encoded 62-kDa reverse transcriptase-maturase protein (p62). In wild-type strains, p62 remains associated with the excised intron lariat RNA in ribonucleoprotein (RNP) particles that are essential for intron homing. Studies of a bacterial group II intron showed that the DIVa substructure of intron domain IV is a high-affinity binding site for its maturase. Here we first present in vitro evidence extending that conclusion to aI2. Then, experiments with aI2 DIVa mutant strains show that the binding of p62 to DIVa is not essential for aI2 splicing in vivo but is essential for homing. Because aI2 splicing in the DIVa mutant strains remains maturase dependent, splicing must rely on other RNA-protein contacts. The p62 that accumulates in the mutant strains has reverse transcriptase activity, but fractionation experiments at high and low salt concentrations show that it associates more weakly than the wild-type protein with endogenous mitochondrial RNAs, and that phenotype probably explains the homing defect. Replacing the DIVa of aI2 with that of the closely related intron aI1 improves in vivo splicing but not homing, indicating that DIVa contributes to the specificity of the maturase-RNA interaction needed for homing.

Published

2003

7. A function for the mitochondrial chaperonin Hsp60 in the structure and transmission of mitochondrial DNA nucleoids in Saccharomyces cerevisiae.

Author

Kaufman BA, Kolesar JE, Perlman PS, and Butow RA

Subjects

Cell Division genetics, Chaperonin 60 genetics, DNA Replication genetics, Mitochondria genetics, Mutation genetics, Promoter Regions, Genetic genetics, Replication Origin genetics, Saccharomyces cerevisiae genetics, Transcription, Genetic genetics, Chaperonin 60 metabolism, DNA, Mitochondrial genetics, Mitochondria metabolism, Saccharomyces cerevisiae metabolism

Abstract

The yeast mitochondrial chaperonin Hsp60 has previously been implicated in mitochondrial DNA (mtDNA) transactions: it is found in mtDNA nucleoids associated with single-stranded DNA; it binds preferentially to the template strand of active mtDNA ori sequences in vitro; and wild-type (rho+) mtDNA is unstable in hsp60 temperature-sensitive (ts) mutants grown at the permissive temperature. Here we show that the mtDNA instability is caused by a defect in mtDNA transmission to daughter cells. Using high resolution, fluorescence deconvolution microscopy, we observe a striking alteration in the morphology of mtDNA nucleoids in rho+ cells of an hsp60-ts mutant that suggests a defect in nucleoid division. We show that rho- petite mtDNA consisting of active ori repeats is uniquely unstable in the hsp60-ts mutant. This instability of ori rho- mtDNA requires transcription from the canonical promoter within the ori element. Our data suggest that the nucleoid dynamics underlying mtDNA transmission are regulated by the interaction between Hsp60 and mtDNA ori sequences.

Published

2003

8. Reverse transcriptase and reverse splicing activities encoded by the mobile group II intron cobI1 of fission yeast mitochondrial DNA.

Author

Schäfer B, Gan L, and Perlman PS

Subjects

Blotting, Northern, Blotting, Southern, DNA, Fungal genetics, Endonucleases genetics, Endonucleases metabolism, Exons, RNA, Fungal genetics, RNA-Directed DNA Polymerase metabolism, Retroelements, Ribonucleoproteins metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Schizosaccharomyces genetics, Schizosaccharomyces metabolism, DNA, Mitochondrial genetics, Gene Expression Regulation, Fungal, Introns genetics, Mitochondria genetics, RNA Splicing, RNA, Fungal metabolism, RNA-Directed DNA Polymerase genetics, Schizosaccharomyces enzymology, Transcription, Genetic

Abstract

Mobile group II introns encode multidomain proteins with maturase activity involved in splicing and reverse transcriptase (RT) and (often) endonuclease activities involved in intron mobility. These activities are present in a ribonucleoprotein complex that contains the excised intron RNA and the intron-encoded protein. Here, we report biochemical studies of the protein encoded by the group IIA1 intron in the cob gene of fission yeast Schizosaccharomyces pombe mitochondria (cobI1). RNP particle fractions from the wild-type fission yeast strain with cobI1 in its mtDNA have RT activity even without adding an exogenous primer. Characterization of the cDNA products of such reactions showed a strong preference for excised intron RNA as template. Two main regions for initiation of cDNA synthesis were mapped within the intron, one near the DIVa putative high-affinity binding site for the intron-encoded protein and the other near domain VI. Adding exogenous primers complementary to cob exon 2 sequences near the intron/exon boundary stimulated RT activity but mainly for pre-mRNA rather than mRNA templates. Further in vitro experiments demonstrated that cobI1 RNA in RNP particle fractions can reverse splice into double-stranded DNA substrates containing the intron homing site. Target DNA primed reverse transcription was not detected unless a DNA target was used that was already nicked in the antisense strand of exon 2. This study shows that S.pombe cobI1 encodes RNP particles that have most of the biochemical activities needed for it to be a retroelement. Interestingly, it appears to lack an endonuclease activity, suggesting that the active homing exhibited by this intron in crosses may differ somewhat from that of the better-characterized introns.

Published

2003

9. Mitochondrial DNA instability mutants of the bifunctional protein Ilv5p have altered organization in mitochondria and are targeted for degradation by Hsp78 and the Pim1p protease.

Author

Bateman JM, Iacovino M, Perlman PS, and Butow RA

Subjects

ATP-Dependent Proteases, Alcohol Oxidoreductases chemistry, Blotting, Western, Cell Division, Chromatography, Glucose pharmacology, Microscopy, Fluorescence, Mitochondrial Proteins chemistry, Plasmids metabolism, Protein Binding, Saccharomyces cerevisiae metabolism, Time Factors, Alcohol Oxidoreductases genetics, DNA, Mitochondrial chemistry, DNA, Mitochondrial genetics, Fungal Proteins metabolism, Heat-Shock Proteins metabolism, Mitochondria metabolism, Mitochondrial Proteins genetics, Mutation, Saccharomyces cerevisiae Proteins, Serine Endopeptidases metabolism

Abstract

Ilv5p is a bifunctional mitochondrial protein in Saccharomyces cerevisiae required for branched-chain amino acid biosynthesis and for the stability of wild-type (rho(+)) mitochondrial DNA (mtDNA). Mutant forms of Ilv5p defective in mtDNA stability (a(+)D(-)) are present as 5-10 punctate structures in mitochondria, whereas mutants lacking enzymatic function (a(-)D(+)) show a reticular distribution, as does wild-type Ilv5p. a(+)D(-) ilv5 mutations are recessive, and the mutant protein is redistributed to a reticular form when co-expressed with wild-type Ilv5p. Ilv5p proteins that are punctate in vivo are also less soluble in detergent extracts of isolated mitochondria, suggesting that the punctate foci in a(+)D(-) Ilv5p mutants are aggregates of the protein. a(+)D(-) Ilv5p proteins are selectively degraded in cells lacking a functional mitochondrial genome, but only in cells grown under derepressing conditions. The targeted degradation of a(+)D(-) Ilv5p, which occurs even when co-expressed with wild-type Ilv5p, is mediated by the glucose-repressible chaperone, Hsp78, and by the ATP-dependent Pim1p protease, whose activity may be modulated by rho(+) mtDNA.

Published

2002

10. Bacterial group II introns in a deep-sea hydrothermal vent environment.

Author

Podar M, Mullineaux L, Huang HR, Perlman PS, and Sogin ML

Subjects

Amino Acid Sequence, Base Sequence, Cloning, Molecular, Molecular Sequence Data, Nucleic Acid Conformation, Open Reading Frames, RNA, Catalytic chemistry, Reverse Transcriptase Polymerase Chain Reaction, Bacteria genetics, DNA Transposable Elements genetics, Introns, RNA, Catalytic genetics, Water Microbiology

Abstract

Group II introns are catalytic RNAs and mobile retrotransposable elements known to be present in the genomes of some nonmarine bacteria and eukaryotic organelles. Here we report the discovery of group II introns in a bacterial mat sample collected from a deep-sea hydrothermal vent near 9 degrees N on the East Pacific Rise. One of the introns was shown to self-splice in vitro. This is the first example of marine bacterial introns from molecular population structure studies of microorganisms that live in the proximity of hydrothermal vents. These types of mobile genetic elements may prove useful in improving our understanding of bacterial genome evolution and may serve as valuable markers in comparative studies of bacterial communities.

Published

2002

11. Mutational bisection of the mitochondrial DNA stability and amino acid biosynthetic functions of ilv5p of budding yeast.

Author

Bateman JM, Perlman PS, and Butow RA

Subjects

Alcohol Oxidoreductases chemistry, Amino Acid Sequence, Base Sequence, DNA Mutational Analysis methods, DNA Primers, Fungal Proteins chemistry, Genetic Complementation Test, Genotype, Mitochondrial Proteins chemistry, Models, Molecular, Molecular Sequence Data, Protein Structure, Secondary, Schizosaccharomyces growth & development, Sequence Alignment, Sequence Homology, Amino Acid, Alcohol Oxidoreductases genetics, Amino Acids biosynthesis, DNA, Mitochondrial genetics, Fungal Proteins genetics, Mitochondrial Proteins genetics, Schizosaccharomyces genetics

Abstract

Ilv5p is a bifunctional yeast mitochondrial enzyme required for branched chain amino acid biosynthesis and for the stability of mitochondrial DNA (mtDNA) and its parsing into nucleoids. The latter occurs when the general amino acid control (GAC) pathway is activated. We have isolated ilv5 mutants that lack either the enzymatic (a(-)D(+)) or the mtDNA stability function (a(+)D(-)) of the protein. The affected residues in these two mutant classes cluster differently when mapped to the 3-D structure of the spinach ortholog of Ilv5p. a(-)D(+) mutations map to conserved internal domains known to be important for substrate and cofactor binding, whereas the a(+)D(-) mutations map to a C-terminal region on the surface of the protein. The a(+)D(-) mutants also have a temperature-sensitive phenotype when grown on a glycerol medium, which correlates with their degree of mtDNA instability. Analysis of an a(+)D(-) mutant with a strong mtDNA instability phenotype shows that it is also unable to parse mtDNA into nucleoids when activated by the GAC pathway. Finally, the wild-type Escherichia coli ortholog of Ilv5p behaves like a(+)D(-) mutants when expressed and targeted to mitochondria in ilv5Delta yeast cells, suggesting that yeast Ilv5p acquired its mtDNA function after the endosymbiotic event.

Published

2002

12. Crosslinking of proteins to mtDNA.

Author

Kaufman BA, Newman SM, Perlman PS, and Butow RA

Subjects

Cell Fractionation methods, Cross-Linking Reagents, DNA, Fungal metabolism, Indicators and Reagents, Mitochondria ultrastructure, Phosphorus Radioisotopes, Spheroplasts physiology, Ultraviolet Rays, DNA, Mitochondrial metabolism, DNA-Binding Proteins metabolism, Mitochondria genetics

Published

2002

13. Control of branch-site choice by a group II intron.

Author

Chu VT, Adamidi C, Liu Q, Perlman PS, and Pyle AM

Subjects

Base Sequence, Hydrolysis, Kinetics, Models, Biological, Molecular Sequence Data, Mutation, Phylogeny, Plasmids metabolism, RNA, Messenger metabolism, DNA Replication, Introns, Nucleic Acid Conformation, RNA Splicing, RNA, Catalytic chemistry, Spliceosomes chemistry

Abstract

The branch site of group II introns is typically a bulged adenosine near the 3'-end of intron domain 6. The branch site is chosen with extraordinarily high fidelity, even when the adenosine is mutated to other bases or if the typically bulged adenosine is paired. Given these facts, it has been difficult to discern the mechanism by which the proper branch site is chosen. In order to dissect the determinants for branch-point recognition, new mutations were introduced in the vicinity of the branch site and surrounding domains. Single mutations did not alter the high fidelity for proper branch-site selection. However, several combinations of mutations moved the branch site systematically to new positions along the domain 6 stem. Analysis of those mutants, together with a new alignment of domain 5 and domain 6 sequences, reveals a set of structural determinants that appear to govern branch-site selection by group II introns.

Published

2001

14. 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

15. Replication and preferential inheritance of hypersuppressive petite mitochondrial DNA.

Author

MacAlpine DM, Kolesar J, Okamoto K, Butow RA, and Perlman PS

Subjects

DNA, Circular, DNA, Single-Stranded, In Situ Hybridization, Fluorescence methods, Promoter Regions, Genetic, Replication Origin, Saccharomyces cerevisiae genetics, Transcription, Genetic, DNA Replication, DNA, Fungal biosynthesis, DNA, Mitochondrial biosynthesis

Abstract

Wild-type yeast mitochondrial DNA (mtDNA) is inherited biparentally, whereas mtDNA of hypersuppressive petite mutants is inherited uniparentally in crosses to strains with wild-type mtDNA. Genomes of hypersuppressive petites contain a conserved ori sequence that includes a promoter, but it is unclear whether the ori confers a segregation or replication advantage. Fluorescent in situ hybridization analysis of wild-type and petite mtDNAs in crosses reveals no preferential segregation of hypersuppressive petite mtDNA to first zygotic buds. We identify single-stranded DNA circles and RNA-primed DNA replication intermediates in hypersuppressive petite mtDNA that are absent from non-hypersuppressive petites. Mutating the promoter blocks hypersuppressiveness in crosses to wild-type strains and eliminates the distinctive replication intermediates. We propose that promoter-dependent RNA-primed replication accounts for the uniparental inheritance of hypersuppressive petite mtDNA.

Published

2001

16. Targeting of green fluorescent protein to mitochondria.

Author

Okamoto K, Perlman PS, and Butow RA

Subjects

Animals, Biomarkers, Genes, Reporter, Green Fluorescent Proteins, Indicators and Reagents metabolism, Luminescent Proteins genetics, Promoter Regions, Genetic, Protein Transport physiology, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Luminescent Proteins metabolism, Mitochondria metabolism

Published

2001

17. Multiple homing pathways used by yeast mitochondrial group II introns.

Author

Eskes R, Liu L, Ma H, Chao MY, Dickson L, Lambowitz AM, and Perlman PS

Subjects

Base Sequence, Crosses, Genetic, DNA Repair physiology, DNA, Complementary biosynthesis, Endonucleases genetics, Endonucleases metabolism, Exons, Molecular Sequence Data, Mutation, RNA-Directed DNA Polymerase genetics, RNA-Directed DNA Polymerase metabolism, Recombination, Genetic, Retroelements, Introns, Mitochondria genetics, Yeasts genetics

Abstract

The yeast mitochondrial DNA group II introns aI1 and aI2 are retroelements that insert site specifically into intronless alleles by a process called homing. Here, we used patterns of flanking marker coconversion in crosses with wild-type and mutant aI2 introns to distinguish three coexisting homing pathways: two that were reverse transcriptase (RT) dependent (retrohoming) and one that was RT independent. All three pathways are initiated by cleavage of the recipient DNA target site by the intron-encoded endonuclease, with the sense strand cleaved by partial or complete reverse splicing, and the antisense strand cleaved by the intron-encoded protein. The major retrohoming pathway in standard crosses leads to insertion of the intron with unidirectional coconversion of upstream exon sequences. This pattern of coconversion suggests that the major retrohoming pathway is initiated by target DNA-primed reverse transcription of the reverse-spliced intron RNA and completed by double-strand break repair (DSBR) recombination with the donor allele. The RT-independent pathway leads to insertion of the intron with bidirectional coconversion and presumably occurs by a conventional DSBR recombination mechanism initiated by cleavage of the recipient DNA target site by the intron-encoded endonuclease, as for group I intron homing. Finally, some mutant DNA target sites shift up to 43% of retrohoming to another pathway not previously detected for aI2 in which there is no coconversion of flanking exon sequences. This new pathway presumably involves synthesis of a full-length cDNA copy of the inserted intron RNA, with completion by a repair process independent of homologous recombination, as found for the Lactococcus lactis Ll.LtrB intron. Our results show that group II intron mobility can occur by multiple pathways, the ratios of which depend on the characteristics of both the intron and the DNA target site. This remarkable flexibility enables group II introns to use different recombination and repair enzymes in different host cells.

Published

2000

18. 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

19. Pentamidine inhibits mitochondrial intron splicing and translation in Saccharomyces cerevisiae.

Author

Zhang Y, Bell A, Perlman PS, and Leibowitz MJ

Subjects

Apoproteins genetics, Blotting, Western, Cell Nucleus genetics, Cycloheximide pharmacology, Cyclooxygenase 1, Cytochrome b Group genetics, Cytochromes b, DNA, Mitochondrial genetics, DNA, Mitochondrial metabolism, Dose-Response Relationship, Drug, Erythromycin pharmacology, Isoenzymes genetics, Prostaglandin-Endoperoxide Synthases genetics, Protein Synthesis Inhibitors pharmacology, RNA, Catalytic metabolism, Time Factors, Antifungal Agents pharmacology, DNA, Mitochondrial drug effects, Introns drug effects, Pentamidine pharmacology, Protein Biosynthesis drug effects, RNA Splicing drug effects, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism

Abstract

Pentamidine inhibits in vitro splicing of nuclear group I introns from rRNA genes of some pathogenic fungi and is known to inhibit mitochondrial function in yeast. Here we report that pentamidine inhibits the self-splicing of three group I and two group II introns of yeast mitochondria. Comparison of yeast strains with different configurations of mitochondrial introns (12, 5, 4, or 0 introns) revealed that strains with the most introns were the most sensitive to growth inhibition by pentamidine on glycerol medium. Analysis of blots of RNA from yeast strains grown in raffinose medium in the presence or absence of pentamidine revealed that the splicing of seven group I and two group II introns that have intron reading frames was inhibited by the drug to varying extents. Three introns without reading frames were unaffected by the drug in vivo, and two of these were inhibited in vitro, implying that the drug affects splicing by acting directly on RNA in vitro, but on another target in vivo. Because the most sensitive introns in vivo are the ones whose splicing depends on a maturase encoded by the intron reading frames, we tested pentamidine for effects on mitochondrial translation. We found that the drug inhibits mitochondrial but not cytoplasmic translation in cells at concentrations that inhibit mitochondrial intron splicing. Therefore, pentamidine is a potent and specific inhibitor of mitochondrial translation, and this effect explains most or all of its effects on respiratory growth and on in vivo splicing of mitochondrial introns.

Published

2000

20. The numbers of individual mitochondrial DNA molecules and mitochondrial DNA nucleoids in yeast are co-regulated by the general amino acid control pathway.

Author

MacAlpine DM, Perlman PS, and Butow RA

Subjects

DNA, Fungal genetics, DNA, Mitochondrial genetics, DNA-Binding Proteins metabolism, Endodeoxyribonucleases metabolism, Fungal Proteins genetics, Fungal Proteins metabolism, Gene Expression, Genes, Fungal, Holliday Junction Resolvases, Protein Kinases genetics, Protein Kinases metabolism, Recombination, Genetic, Saccharomyces cerevisiae genetics, Transcription Factors metabolism, Amino Acids metabolism, DNA, Fungal metabolism, DNA, Mitochondrial metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins

Abstract

Mitochondrial DNA (mtDNA) is inherited as a protein-DNA complex (the nucleoid). We show that activation of the general amino acid response pathway in rho(+) and rho(-) petite cells results in an increased number of nucleoids without an increase in mtDNA copy number. In rho(-) cells, activation of the general amino acid response pathway results in increased intramolecular recombination between tandemly repeated sequences of rho(-) mtDNA to produce small, circular oligomers that are packaged into individual nucleoids, resulting in an approximately 10-fold increase in nucleoid number. The parsing of mtDNA into nucleoids due to general amino acid control requires Ilv5p, a mitochondrial protein that also functions in branched chain amino acid biosynthesis, and one or more factors required for mtDNA recombination. Two additional proteins known to function in mtDNA recombination, Abf2p and Mgt1p, are also required for parsing mtDNA into a larger number of nucleoids, although expression of these proteins is not under general amino acid control. Increased nucleoid number leads to increased mtDNA transmission, suggesting a mechanism to enhance mtDNA inheritance under amino acid starvation conditions.

Published

2000

21. Group II intron reverse transcriptase in yeast mitochondria. Stabilization and regulation of reverse transcriptase activity by the intron RNA.

Author

Zimmerly S, Moran JV, Perlman PS, and Lambowitz AM

Subjects

Amino Acid Sequence, Conserved Sequence, DNA Primers, DNA, Complementary biosynthesis, Exons, Introns physiology, Mitochondria metabolism, Mutation, RNA Precursors metabolism, RNA Splicing, RNA, Fungal genetics, RNA-Directed DNA Polymerase isolation & purification, Ribonucleoproteins metabolism, Templates, Genetic, Transcription, Genetic, Yeasts genetics, Yeasts metabolism, Mitochondria genetics, RNA, Fungal metabolism, RNA-Directed DNA Polymerase genetics, RNA-Directed DNA Polymerase metabolism

Abstract

Group II introns encode reverse transcriptases that function in both intron mobility and RNA splicing. The proteins bind specifically to unspliced precursor RNA to promote splicing, and then remain associated with the excised intron to form a DNA endonuclease that mediates intron mobility by target DNA-primed reverse transcription. Here, immunoblotting and UV cross-linking experiments show that the reverse transcriptase activity encoded by the yeast mtDNA group II intron aI2 is associated with an intron-encoded protein of 62 kDa (p62). p62 is bound tightly to endogenous RNAs in mitochondrial ribonucleoprotein particles, and the reverse transcriptase activity is rapidly and irreversibly lost when the protein is released from the endogenous RNAs by RNase digestion. Non-denaturing gel electrophoresis and activity assays show that the aI2 reverse transcriptase is associated predominantly with the excised intron RNA, while a smaller amount is associated with unspliced precursor RNA, as expected from the role of the protein in RNA splicing. Although the reverse transcriptase in wild-type yeast strains is bound tightly to endogenous RNAs, it is regulated so that it does not copy these RNAs unless a suitable DNA oligonucleotide primer or DNA target site is provided. Certain mutations in the intron-encoded protein or RNA circumvent this regulation and activate reverse transcription of endogenous RNAs in the absence of added primer. Although p62 is bound to unspliced precursor RNA in position to initiate cDNA synthesis in the 3' exon, the major template for target DNA-primed reverse transcription in vitro is the reverse-spliced intron RNA, as found previously for aI1. Together, our results show that binding to intron-containing RNAs stabilizes and regulates the activity of p62., (Copyright 1999 Academic Press.)

Published

1999

22. Photocrosslinking of 4-thio uracil-containing RNAs supports a side-by-side arrangement of domains 5 and 6 of a group II intron.

Author

Podar M and Perlman PS

Subjects

Base Sequence, Molecular Sequence Data, Nucleic Acid Conformation, RNA chemistry, RNA, Fungal chemistry, RNA, Mitochondrial, Thiouracil metabolism, Ultraviolet Rays, Cross-Linking Reagents metabolism, Introns genetics, RNA genetics, RNA Splicing genetics, RNA, Fungal genetics, Thiouracil analogs & derivatives

Abstract

Previous studies suggested that domains 5 and 6 (D5 and D6) of group II introns act together in splicing and that the two helical structures probably do not interact by helix stacking. Here, we characterized the major Mg2+ ion- and salt-dependent, long-wave UV light-induced, intramolecular crosslinks formed in 4-thiouridine-containing D56 RNA from intron 5gamma (aI5gamma) of the COXI gene of yeast mtDNA. Four major crosslinks were mapped and found to result from covalent bonds between nucleotides separating D5 from D6 [called J(56)] and residues of D6 near and including the branch nucleotide. These findings are extended by results of similar experiments using 4-thioU containing D56 RNAs from a mutant allele of aI5gamma and from the group IIA intron, aI1. Trans-splicing experiments show that the crosslinked wild-type aI5gamma D56 RNAs are active for both splicing reactions, including some first-step branching. An RNA containing the 3-nt J(56) sequence and D6 of aI5gamma yields one main crosslink that is identical to the most minor of the crosslinks obtained with D56 RNA, but in this case in a cation-independent fashion. We conclude that the interaction between J(56) and D6 is influenced by charge repulsion between the D5 and D6 helix backbones and that high concentrations of cations allow the helices to approach closely under self-splicing conditions. The interaction between J(56) and D6 appears to be a significant factor establishing a side-by-side (i.e., not stacked) orientation of the helices of the two domains.

Published

1999

23. More than one way to splice an RNA: branching without a bulge and splicing without branching in group II introns.

Author

Chu VT, Liu Q, Podar M, Perlman PS, and Pyle AM

Subjects

Adenosine genetics, Base Sequence, Endoribonucleases, Kinetics, Models, Genetic, Point Mutation, RNA genetics, Sequence Analysis, RNA, Sequence Deletion, Introns, Nucleic Acid Conformation, RNA chemistry, RNA Splicing genetics

Abstract

Domain 6 (D6) of group II introns contains a bulged adenosine that serves as the branch-site during self-splicing. In addition to this adenosine, other structural features in D6 are likely to contribute to the efficiency of branching. To understand their role in promoting self-splicing, the branch-site and surrounding nucleotides were mutagenized. Detailed kinetic analysis on the self-splicing efficiency of the mutants revealed several interesting features. First, elimination of the branch-site does not preclude efficient splicing, which takes place instead through a hydrolytic first step. Second, pairing of the branch-site does not eliminate branching, particularly if the adenosine is involved in a mispair. Third, the G-U pairs that often surround group II intron branch-points contribute to the efficiency of branching. These results suggest that there is a strong driving force for promoting self-splicing by group II introns, which employ a versatile set of different mechanisms for ensuring that splicing is successful. In addition, the behavior of these mutants indicates that a bulged adenosine per se is not the important determinant for branch-site recognition in group II introns. Rather, the data suggest that the branch-site adenosine is recognized as a flipped base, a conformation that can be promoted by a variety of different substructures in RNA and DNA.

Published

1998

24. Group II intron mobility in yeast mitochondria: target DNA-primed reverse transcription activity of aI1 and reverse splicing into DNA transposition sites in vitro.

Author

Yang J, Mohr G, Perlman PS, and Lambowitz AM

Subjects

DNA, Fungal genetics, Deoxyribonuclease I genetics, Introns genetics, RNA Splicing, RNA-Directed DNA Polymerase genetics, Saccharomyces cerevisiae ultrastructure, DNA, Mitochondrial genetics, Gene Expression Regulation, Fungal, Mitochondria genetics, Saccharomyces cerevisiae genetics, Transcription, Genetic

Abstract

The retrohoming of the yeast mtDNA intron aI1 occurs by a target DNA-primed reverse transcription (TPRT) mechanism in which the intron RNA reverse splices directly into the recipient DNA and is then copied by the intron-encoded reverse transcriptase. Here, we carried out biochemical characterization of the intron-encoded reverse transcriptase and site-specific DNA endonuclease activities required for this process. We show that the aI1 reverse transcriptase has high TPRT activity in the presence of appropriate DNA target sites, but differs from the closely related reverse transcriptase encoded by the yeast aI2 intron in being unable to use artificial substrates efficiently. Characterization of TPRT products shows that the fully reverse spliced intron RNA is an efficient template for cDNA synthesis, while reverse transcription of partially reverse spliced intron RNA is impeded by the branch point. Novel features of the aI1 reaction include a prominent open-circular product in which cDNAs are incorporated at a nick at the antisense-strand cleavage site. The aI1 endonuclease activity, which catalyzes the DNA cleavage and reverse splicing reactions, is associated with ribonucleoprotein particles containing the intron-encoded protein and the excised intron RNA. As shown for the aI2 endonuclease, both the RNA and protein components are used for DNA target site recognition, but the aI1 protein has less stringent nucleotide sequence requirements for the reverse splicing reaction. Finally, perhaps reflecting this relaxed target specificity, in vitro experiments show that aI1 can reverse splice directly into ectopic mtDNA transposition sites, consistent with the previously suggested possibility that this mechanism is used for ectopic transposition of group II introns in vivo., (Copyright 1998 Academic Press.)

Published

1998

25. Mutant alleles of the MRS2 gene of yeast nuclear DNA suppress mutations in the catalytic core of a mitochondrial group II intron.

Author

Schmidt U, Maue I, Lehmann K, Belcher SM, Stahl U, and Perlman PS

Subjects

Alleles, Amino Acid Sequence, Genes, Suppressor, Introns genetics, Ion Channels, Mitochondrial Proteins, Molecular Sequence Data, Saccharomyces cerevisiae ultrastructure, DNA, Fungal genetics, DNA, Mitochondrial genetics, Gene Expression Regulation, Fungal, Genes, Fungal, Mutation, Nuclear Proteins genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins

Abstract

Previous studies show that some yeast strains carrying point mutations of domain 5 that block splicing of a mitochondrial group II intron yield spontaneous revertants in which splicing is partially restored by dominant mutations of nuclear genes. Here we cloned and sequenced the suppressor allele of one such gene, and found it to be a missense mutation of the MRS2 gene (MRS2-L232F). The MRS2 gene was first implicated in group II intron splicing by the finding that overexpression of the wild-type gene weakly suppresses the splicing defect of a mutation of another intron. Tetrad analysis showed that independently isolated suppressors of two other domain 5 mutations are also allelles of the MRS2 gene and DNA sequencing identified a new missense mutation in each strain (MRS2-T230I and MRS2-L213M). All three suppressor mutations cause a temperature-sensitive respiration defect that is dominant negative in heterozygous diploids, but those strains splice the mutant intron at the elevated temperature. The three mutations are in a domain of the protein that is likely to be a helix-turn-helix region, so that effects of the mutations on protein-protein interactions may contribute to these phenotypes. These mutations suppress the splicing defect of many, but not all, of the available splicing defective mutations of aI5gamma, including mutations of several intron domains. Protein and RNA blot experiments show that the level of the protein encoded by the MRS2 gene, but not the mRNA, is elevated by these mutations. Interestingly, overexpression of the wild-type protein restores much lower levels of splicing than were obtained with similar elevated levels of the mutated Mrs2 proteins. The splicing phenotypes of these strains suggest a direct role for Mrs2 protein on group II intron splicing, but an indirect effect is not yet ruled out., (Copyright 1998 Academic Press.)

Published

1998

26. The sorting of mitochondrial DNA and mitochondrial proteins in zygotes: preferential transmission of mitochondrial DNA to the medial bud.

Author

Okamoto K, Perlman PS, and Butow RA

Subjects

Crosses, Genetic, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Fluorescent Antibody Technique, Green Fluorescent Proteins, Indicators and Reagents, Luminescent Proteins, Membrane Proteins metabolism, Transcription Factors genetics, Transcription Factors metabolism, DNA, Mitochondrial metabolism, Mitochondria metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins

Abstract

Green fluorescent protein (GFP) was used to tag proteins of the mitochondrial matrix, inner, and outer membranes to examine their sorting patterns relative to mtDNA in zygotes of synchronously mated yeast cells in rho+ x rho0 crosses. When transiently expressed in one of the haploid parents, each of the marker proteins distributes throughout the fused mitochondrial reticulum of the zygote before equilibration of mtDNA, although the membrane markers equilibrate slower than the matrix marker. A GFP-tagged form of Abf2p, a mtDNA binding protein required for faithful transmission of rho+ mtDNA in vegetatively growing cells, colocalizes with mtDNA in situ. In zygotes of a rho+ x rho+ cross, in which there is little mixing of parental mtDNAs, Abf2p-GFP prelabeled in one parent rapidly equilibrates to most or all of the mtDNA, showing that the mtDNA compartment is accessible to exchange of proteins. In rho+ x rho0 crosses, mtDNA is preferentially transmitted to the medial diploid bud, whereas mitochondrial GFP marker proteins distribute throughout the zygote and the bud. In zygotes lacking Abf2p, mtDNA sorting is delayed and preferential sorting is reduced. These findings argue for the existence of a segregation apparatus that directs mtDNA to the emerging bud.

Published

1998

27. The two steps of group II intron self-splicing are mechanistically distinguishable.

Author

Podar M, Perlman PS, and Padgett RA

Subjects

Binding Sites, Manganese pharmacology, Models, Chemical, Nucleic Acid Conformation, Oligodeoxyribonucleotides metabolism, Oligoribonucleotides metabolism, RNA metabolism, Stereoisomerism, Thionucleotides metabolism, Introns, RNA Splicing

Abstract

The two transesterification reactions catalyzed by self-splicing group II introns take place in either two active sites or two conformations of a single active site involving rearrangements of the positions of the reacting groups. We have investigated the effects on the rates of the chemical steps of the two reactions due to sulfur substitution of nonbridging oxygens at both the 5' and 3' splice sites as well as the deoxyribose substitution of the ribose 2' hydroxyl group at the 5' splice site. The data suggest that the two active sites differ in their interactions with several of these groups. Specifically, sulfur substitution of the pro-Sp nonbridging oxygen at the 5' splice site reduces the chemical rate of the step one branching reaction by at least 250-fold, whereas substitution of the pro-Sp oxygen at the 3' splice site has only a 4.5-fold effect on the chemical rate of step two. Previous work demonstrated that the Rp phosphorothioate substitutions at both the 5' and 3' splice sites reduced the rate of both steps of splicing to an undetectable level. These results suggest that either two distinct active sites catalyze the two steps or that more significant alterations must be made in a single bifunctional active site to accommodate the two different reactions.

Published

1998

28. 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

29. Functions of the high mobility group protein, Abf2p, in mitochondrial DNA segregation, recombination and copy number in Saccharomyces cerevisiae.

Author

Zelenaya-Troitskaya O, Newman SM, Okamoto K, Perlman PS, and Butow RA

Subjects

Binding Sites, Crossing Over, Genetic, DNA-Binding Proteins genetics, Fungal Proteins genetics, Gene Dosage, High Mobility Group Proteins genetics, Recombination, Genetic, Transcription Factors genetics, DNA, Mitochondrial, DNA-Binding Proteins physiology, Fungal Proteins physiology, High Mobility Group Proteins physiology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae physiology, Saccharomyces cerevisiae Proteins, Transcription Factors physiology

Abstract

Previous studies have established that the mitochondrial high mobility group (HMG) protein, Abf2p, of Saccharomyces cerevisiae influences the stability of wild-type (rho+) mitochondrial DNA (mtDNA) and plays an important role in mtDNA organization. Here we report new functions for Abf2p in mtDNA transactions. We find that in homozygous deltaabf2 crosses, the pattern of sorting of mtDNA and mitochondrial matrix protein is altered, and mtDNA recombination is suppressed relative to homozygous ABF2 crosses. Although Abf2p is known to be required for the maintenance of mtDNA in rho+ cells growing on rich dextrose medium, we find that it is not required for the maintenance of mtDNA in p cells grown on the same medium. The content of both rho+ and rho- mtDNAs is increased in cells by 50-150% by moderate (two- to threefold) increases in the ABF2 copy number, suggesting that Abf2p plays a role in mtDNA copy control. Overproduction of Abf2p by > or = 10-fold from an ABF2 gene placed under control of the GAL1 promoter, however, leads to a rapid loss of rho+ mtDNA and a quantitative conversion of rho+ cells to petites within two to four generations after a shift of the culture from glucose to galactose medium. Overexpression of Abf2p in rho- cells also leads to a loss of mtDNA, but at a slower rate than was observed for rho+ cells. The mtDNA instability phenotype is related to the DNA-binding properties of Abf2p because a mutant Abf2p that contains mutations in residues of both HMG box domains known to affect DNA binding in vitro, and that binds poorly to mtDNA in vivo, complements deltaabf2 cells only weakly and greatly lessens the effect of overproduction on mtDNA instability. In vivo binding was assessed by colocalization to mtDNA of fusions between mutant or wild-type Abf2p and green fluorescent protein. These findings are discussed in the context of a model relating mtDNA copy number control and stability to mtDNA recombination.

Published

1998

30. Group II intron splicing in vivo by first-step hydrolysis.

Author

Podar M, Chu VT, Pyle AM, and Perlman PS

Subjects

Esterification, Genes, Fungal, Hydrolysis, Mitochondria metabolism, Mutagenesis, Site-Directed, RNA, Fungal metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Introns, RNA Splicing

Abstract

Group I, group II and spliceosomal introns splice by two sequential transesterification reactions. For both spliceosomal and group II introns, the first-step reaction occurs by nucleophilic attack on the 5' splice junction by the 2' hydroxyl of an internal adenosine, forming a 2'-5' phosphodiester branch in the intron. The second reaction joins the two exons with a 3'-5' phosphodiester bond and releases intron lariat. In vitro, group II introns can self-splice by an efficient alternative pathway in which the first-step reaction occurs by hydrolysis. The resulting linear splicing intermediate participates in normal second-step reactions, forming spliced exon and linear intron RNAs. Here we show that the group II intron first-step hydrolysis reaction occurs in vivo in place of transesterification in the mitochondria of yeast strains containing branch-site mutations. As expected, the mutations block branching, but surprisingly still allow accurate splicing. This hydrolysis pathway may have been a step in the evolution of splicing mechanisms.

Published

1998

31. Domain 5 binds near a highly conserved dinucleotide in the joiner linking domains 2 and 3 of a group II intron.

Author

Podar M, Zhuo J, Zhang M, Franzen JS, Perlman PS, and Peebles CL

Subjects

Base Sequence, Binding Sites genetics, Conserved Sequence, Cross-Linking Reagents, DNA, Fungal chemistry, DNA, Fungal genetics, DNA, Fungal metabolism, Genetic Variation, Molecular Sequence Data, Nucleic Acid Conformation, Photochemistry, RNA Splicing, RNA, Catalytic genetics, Introns, RNA, Catalytic chemistry, RNA, Catalytic metabolism

Abstract

Photocrosslinking has identified the joiner between domains 2 and 3 [J(23)] as folding near domain 5 (D5), a highly conserved helical substructure of group II introns required for both splicing reactions. D5 RNAs labeled with the photocrosslinker 4-thiouridine (4sU) reacted with highly conserved nucleotides G588 and A589 in J(23) of various intron acceptor transcripts. These conjugates retained some ribozyme function with the lower helix of D5 crosslinked to J(23), so they represent active complexes. One partner of the gamma x gamma' tertiary interaction (A587 x U887) is also in J(23); even though gamma x gamma' is involved in step 2 of the splicing reaction, D5 has not previously been found to approach gamma x gamma'. Similar crosslinking patterns between D5 and J(23) were detected both before and after step 1 of the reaction, indicating that the lower helix of D5 is positioned similarly in both conformations of the active center. Our results suggest that the purine-rich J(23) strand is antiparallel to the D5 strand containing U32 and U33. Possibly, the interaction with J(23) helps position D5 correctly in the ribozyme active site; alternatively, J(23) itself might participate in the catalytic center.

Published

1998

32. Group II intron endonucleases use both RNA and protein subunits for recognition of specific sequences in double-stranded DNA.

Author

Guo H, Zimmerly S, Perlman PS, and Lambowitz AM

Subjects

Base Sequence, Electron Transport Complex IV genetics, Mitochondria genetics, Models, Genetic, Molecular Sequence Data, Nucleic Acid Conformation, RNA Splicing, Saccharomyces cerevisiae genetics, Substrate Specificity, Zinc metabolism, DNA, Fungal metabolism, Endodeoxyribonucleases metabolism, Introns, RNA, Catalytic metabolism, RNA-Directed DNA Polymerase metabolism, Ribonucleoproteins metabolism, Saccharomyces cerevisiae Proteins

Abstract

Group II introns use intron-encoded reverse transcriptase, maturase and DNA endonuclease activities for site-specific insertion into DNA. Remarkably, the endonucleases are ribonucleoprotein complexes in which the excised intron RNA cleaves the sense strand of the recipient DNA by reverse splicing, while the intron-encoded protein cleaves the antisense strand. Here, studies with the yeast group II intron aI2 indicate that both the RNA and protein components of the endonuclease contribute to recognition of an approximately 30 bp DNA target site. Our results lead to a model in which the protein component first recognizes specific nucleotides in the most distal 5' exon region of the DNA target site (E2-21 to -11). Binding of the protein then leads to DNA unwinding, enabling the intron RNA to base pair to a 13 nucleotide DNA sequence (E2-12 to E3+1) for reverse splicing. Antisense-strand cleavage requires additional interactions of the protein with the 3' exon DNA (E3+1 to +10). Our results show how enzymes can use RNA and protein subunits cooperatively to recognize specific sequences in double-stranded DNA.

Published

1997

33. Mobility of yeast mitochondrial group II introns: engineering a new site specificity and retrohoming via full reverse splicing.

Author

Eskes R, Yang J, Lambowitz AM, and Perlman PS

Subjects

Base Sequence, DNA, Complementary analysis, DNA, Complementary chemical synthesis, DNA, Fungal analysis, Endonucleases genetics, Gene Expression Regulation, Enzymologic genetics, Gene Expression Regulation, Fungal genetics, Mutagenesis, Site-Directed genetics, Plasmids, RNA Splicing genetics, Recombination, Genetic, Yeasts enzymology, DNA, Mitochondrial physiology, Introns genetics, Yeasts genetics

Abstract

The mobile group II introns aI1 and aI2 of yeast mtDNA encode endonuclease activities that cleave intronless DNA target sites to initiate mobility by target DNA-primed reverse transcription. For aI2, sense-strand cleavage occurs mainly by a partial reverse splicing reaction, whereas for aI1, complete reverse splicing occurs, leading to insertion of the linear intron RNA into double-stranded DNA. Here, we show that aI1 homing and reverse splicing depend on the EBS1 (RNA)/IBS1(DNA) pairing and that target specificity can be changed by compensatory changes in the target site and the donor intron. Using well-marked strains to follow coconversion of flanking DNA, we show that homing occurs by both RT-dependent and -independent pathways. Remarkably, in most RT-dependent events, the reverse spliced intron is the initial template for first-strand cDNA synthesis.

Published

1997

34. Mutations of the two-nucleotide bulge of D5 of a group II intron block splicing in vitro and in vivo: phenotypes and suppressor mutations.

Author

Schmidt U, Podar M, Stahl U, and Perlman PS

Subjects

Base Sequence, DNA, Fungal genetics, DNA, Mitochondrial genetics, Genes, Fungal, Mutation, Nucleic Acid Conformation, Phenotype, RNA, Fungal chemistry, RNA, Fungal genetics, RNA, Fungal metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Suppression, Genetic, Introns, RNA Splicing genetics

Abstract

Domain 5 (D5) is a highly conserved substructure of group II introns that is essential for catalysis of both steps of the splicing pathway. Here we studied the effects of mutations of the conserved 2-nt bulge in the binding and catalytic functions of D5 of intron aI5gamma of yeast mitochondrial DNA. Sequence variants of the 2-nt bulge reduced the rate of self-splicing somewhat. Deletion of one or both bulge nucleotides inhibited splicing more than 10(4)-fold, whereas mutants with a 3-nt bulge were much less debilitated. A novel allele with a symmetrical internal loop in place of the bulge self-splices nearly as actively as the control. Trans-splicing assays of D5 function showed some mutations primarily affect the catalytic function of D5, whereas others chiefly affect its binding function. Representative alleles were transformed into mtDNA and each inhibited splicing and respiratory growth. Pseudo-revertants included suppressor mutations nearby in D5 and one mutant yielded a dominant nuclear suppressor. These experiments provide new evidence that the D5 bulge is crucial for D5 binding and catalysis. It is possible that the bulge bends the D5 helix and that the extent of bending is especially important for D5 binding. The presence and exact nature of the bulge is also likely to have local structural consequences (besides bending) that influence the participation of specific backbone groups in binding and catalysis.

Published

1996

35. Length changes in the joining segment between domains 5 and 6 of a group II intron inhibit self-splicing and alter 3' splice site selection.

Author

Boulanger SC, Faix PH, Yang H, Zhuo J, Franzen JS, Peebles CL, and Perlman PS

Subjects

Base Sequence, DNA, Fungal chemistry, DNA, Fungal metabolism, Genetic Variation, Molecular Sequence Data, Nucleic Acid Conformation, Nucleic Acid Denaturation, Oxygen Consumption, Plasmids, RNA, Catalytic metabolism, RNA, Fungal chemistry, Saccharomyces cerevisiae genetics, Transcription, Genetic, DNA, Mitochondrial chemistry, DNA, Mitochondrial metabolism, Introns, Mitochondria metabolism, RNA Splicing, RNA, Fungal biosynthesis, Saccharomyces cerevisiae metabolism

Abstract

Domain 5 (D5) and domain 6 (D6) are adjacent folded hairpin substructures of self-splicing group II introns that appear to interact within the active ribozyme. Here we describe the effects of changing the length of the 3-nucleotide segment joining D5 to D6 [called J(56)3] on the splicing reactions of intron 5 gamma of the COXI gene of yeast mitochondrial DNA. Shortened variants J(56)0 and J(56)1 were defective in vitro for branching, and the second splicing step was performed inefficiently and inaccurately. The lengthened variant J(56)5 had a milder defect-splicing occurred at a reduced rate but with correct branching and a mostly accurate 3' splice junction choice. Yeast mitochondria were transformed with the J(56)5 allele, and the resulting yeast strain was respiration deficient because of ineffective aI5 gamma splicing. Respiration-competent revertants were recovered, and in one type a single joiner nucleotide was deleted while in the other type a nucleotide of D6 was deleted. Although these revertants still showed partial splicing blocks in vivo and in vitro, including a substantial defect in the second step of splicing, both spliced accurately in vivo. These results establish that a 3-nucleotide J(56) is optimal for this intron, especially for the accuracy of 3' splice junction selection, and indicate that D5 and D6 are probably not coaxially stacked.

Published

1996

36. Efficient integration of an intron RNA into double-stranded DNA by reverse splicing.

Author

Yang J, Zimmerly S, Perlman PS, and Lambowitz AM

Subjects

Base Sequence, DNA, Fungal genetics, Molecular Sequence Data, Ribonucleoproteins metabolism, Saccharomyces cerevisiae genetics, DNA genetics, Introns, RNA Splicing, RNA, Fungal genetics, RNA-Directed DNA Polymerase genetics, Recombination, Genetic

Abstract

Some group II introns are mobile elements as well as catalytic RNAs. Introns aI1 and aI2 found in the gene COX1 in yeast mitochondria encode reverse transcriptases which promote site-specific insertion of the intron into intronless alleles ('homing'). For aI2 this predominantly occurs by reverse transcription of unspliced precursor RNA at a break in double-strand DNA made by an endonuclease encoded by the intron. The aI2 endonuclease involves both the excised intron RNA, which cleaves the DNA's sense strand by partial reverse splicing; and the intron-encoded reverse transcriptase which cleaves the anti-sense strand. Here we show that aI1 encodes an analogous endonuclease specific for a different target site compatible with the different exon-binding sequences of the intron RNA. Over half of aI1 undergoes complete reverse splicing in vitro, thus integrating linear intron RNA directly into the DNA. This unprecedented reaction has implications for both intron mobility and evolution, and potential genetic engineering applications.

Published

1996

37. Analysis of mitochondrial DNA nucleoids in wild-type and a mutant strain of Saccharomyces cerevisiae that lacks the mitochondrial HMG box protein Abf2p.

Author

Newman SM, Zelenaya-Troitskaya O, Perlman PS, and Butow RA

Subjects

DNA, Fungal analysis, DNA-Binding Proteins analysis, Deoxyribonuclease I, Electron Transport Complex IV genetics, Fluorescent Dyes, Fungal Proteins analysis, Fungal Proteins genetics, Indoles, Mitochondrial Proteins, Permeability, Replication Origin genetics, Ribosomal Proteins genetics, DNA, Mitochondrial analysis, DNA-Binding Proteins physiology, Fungal Proteins physiology, Membrane Proteins, Mitochondria chemistry, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae Proteins, Transcription Factors physiology

Abstract

DNA-protein complexes (nucleoids) are believed to be the segregating unit of mitochondrial DNA (mtDNA) in Saccharomyces cerevisiae. A mitochondrial HMG box protein, Abf2p, is needed for maintenance of mtDNA in cells grown on rich dextrose medium, but is dispensible in glycerol grown cells. As visualized by 4',6'-diamino-2-phenylindole staining, mtDNA nucleoids in mutant cells lacking Abf2p ( delta abf2) are diffuse compared with those in wild-type cells. We have isolated mtDNA nucleoids and characterized two mtDNA-protein complexes, termed NCLDp-2 and NCLDs-2, containing distinct but overlapping sets of polypeptides. This protocol yields similar nucleoid complexes from the delta abf2 mutant, although several proteins appear lacking from NCLDs-2. Segments of mtDNA detected with probes to COXII, VAR1 and ori5 sequences are equally sensitive to DNase I digestion in NCLDs-2 and NCLDp-2 from wild-type cells and from the delta abf2 mutant. However, COXII and VAR1 sequences are 4-to 5-fold more sensitive to DNase I digestion of mtDNA in toluene-permeabilized mitochondria from the delta abf2 mutant than from wild-type cells, but no difference in DNase I sensitivity was detected with the ori5 probe. These results provide a first indication that Abf2p influences differential organization of mtDNA sequences.

Published

1996

38. Transformation of Saccharomyces cerevisiae mitochondria using the biolistic gun.

Author

Butow RA, Henke RM, Moran JV, Belcher SM, and Perlman PS

Subjects

Biolistics instrumentation, DNA administration & dosage, DNA, Mitochondrial metabolism, Electron Transport Complex II, Gene Expression, Genes, Fungal, Multienzyme Complexes biosynthesis, NAD(P)H Dehydrogenase (Quinone) biosynthesis, Oxidoreductases biosynthesis, Succinate Dehydrogenase biosynthesis, Transformation, Genetic, Mitochondria metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism

Published

1996

39. Reactions catalyzed by group II introns in vitro.

Author

Perlman PS and Podar M

Subjects

Base Sequence, Catalysis, DNA, Fungal chemistry, DNA, Fungal metabolism, Exons, Molecular Sequence Data, Nucleic Acid Conformation, Polymerase Chain Reaction methods, Promoter Regions, Genetic, RNA, Catalytic metabolism, DNA, Bacterial chemistry, DNA, Bacterial metabolism, DNA, Mitochondrial chemistry, DNA, Mitochondrial metabolism, Introns, RNA Precursors metabolism, RNA Splicing, Transcription, Genetic

Published

1996

40. Mechanisms of intron mobility.

Author

Belfort M and Perlman PS

Subjects

Amino Acid Sequence, Conserved Sequence, DNA genetics, Endodeoxyribonucleases genetics, Models, Genetic, Molecular Sequence Data, Nucleic Acid Conformation, Open Reading Frames, RNA metabolism, RNA-Directed DNA Polymerase genetics, Sequence Homology, Amino Acid, Zinc Fingers, DNA metabolism, Endodeoxyribonucleases biosynthesis, Introns, RNA-Directed DNA Polymerase biosynthesis

Published

1995

41. A group II intron RNA is a catalytic component of a DNA endonuclease involved in intron mobility.

Author

Zimmerly S, Guo H, Eskes R, Yang J, Perlman PS, and Lambowitz AM

Subjects

Base Sequence, DNA metabolism, DNA ultrastructure, DNA, Antisense metabolism, Molecular Sequence Data, RNA Splicing genetics, RNA-Directed DNA Polymerase physiology, Substrate Specificity, Yeasts genetics, Zinc metabolism, Deoxyribonuclease I metabolism, Introns physiology, RNA metabolism, Saccharomyces cerevisiae Proteins

Abstract

The mobility (homing) of the yeast mitochondrial DNA group II intron al2 occurs via target DNA-primed reverse transcription at a double-strand break in the recipient DNA. Here, we show that the site-specific DNA endonuclease that makes the double-strand break is a ribonucleoprotein complex containing the al2-encoded reverse transcriptase protein and excised al2 RNA. Remarkably, the al2 RNA catalyzes cleavage of the sense strand of the recipient DNA, while the al2 protein appears to cleave the antisense strand. The RNA-catalyzed sense strand cleavage occurs via a partial reverse splicing reaction in which the protein component stabilizes the active intron structure and appears to confer preference for DNA substrates. Our results demonstrate a biologically relevant ribozyme reaction with a substrate other than RNA.

Published

1995

42. Maturase and endonuclease functions depend on separate conserved domains of the bifunctional protein encoded by the group I intron aI4 alpha of yeast mitochondrial DNA.

Author

Henke RM, Butow RA, and Perlman PS

Subjects

Amino Acid Sequence, Conserved Sequence, DNA Transposable Elements, Electron Transport Complex IV genetics, Mitochondria enzymology, Molecular Sequence Data, Multigene Family, Mutagenesis, Site-Directed, Open Reading Frames genetics, RNA Splicing, Recombination, Genetic, Saccharomyces cerevisiae Proteins, DNA, Mitochondrial genetics, Deoxyribonucleases, Type II Site-Specific, Endodeoxyribonucleases genetics, Introns genetics, Saccharomyces cerevisiae genetics

Abstract

Intron 4 alpha (aI4 alpha) of the yeast mitochondrial COXI gene is a mobile group I intron that contains a reading frame encoding both the homing endonuclease I-SceII and a latent maturase capable of splicing both aI4 alpha and the fourth intron of the cytochrome b (COB) gene (bI4). The aI4 alpha reading frame is a member of a large gene family recognized by the presence of related dodecapeptide sequence motifs called P1 and P2. In this study, missense mutations of P1 and P2 were placed in mitochondrial DNA by biolistic transformation. The effects of the mutations on intron mobility, endonuclease I-SceII activity and maturase function were tested. The mutations of P1 strongly affected mobility and endonuclease I-SceII activity, but had little or no effect on maturase function; mutations of P2 affected splicing but not mobility or endonuclease I-SceII activity. Surprisingly, the conditional (temperature-sensitive) mutations at P1 and P2 block one or the other function of the protein but not both. This study indicates that the two functions depend on separate domains of the intron-encoded protein.

Published

1995

43. A UV-induced, Mg(2+)-dependent crosslink traps an active form of domain 3 of a self-splicing group II intron.

Author

Podar M, Dib-Hajj S, and Perlman PS

Subjects

Base Sequence, Cross-Linking Reagents, Kinetics, Molecular Sequence Data, Nucleic Acid Conformation, Pyrimidines chemistry, Pyrimidines radiation effects, RNA metabolism, RNA, Messenger, Ribonuclease H genetics, Ribonuclease H metabolism, Transcription, Genetic, DNA-Binding Proteins genetics, Introns, Magnesium pharmacology, RNA chemistry, RNA Splicing drug effects, RNA Splicing radiation effects, Ultraviolet Rays, Viral Proteins genetics

Abstract

In vitro irradiation of a15 gamma group II intron RNA with low doses of 254 nm UV light induces a single major crosslink. This crosslink was mapped within the domain 3 substructure of this RNA and one of the participating nucleotides was identified. When an RNA containing only the domain 3 substructure is irradiated under the same conditions, an intramolecular crosslink forms between two specific pyrimidines, one of them identical to the nucleotide crosslinked in the full-length intron RNA. In both RNAs, the crosslink is magnesium ion-dependent and photoreversible. A trans assay for domain 3 function was developed and used to find that the crosslinked domain 3 RNA remains highly reactive. This suggests that crosslinking has trapped a functional, Mg(2+)-induced folded state of this group II intron substructure and that this folding is probably independent of the other domains of the intron.

Published

1995

44. Group II intron mobility occurs by target DNA-primed reverse transcription.

Author

Zimmerly S, Guo H, Perlman PS, and Lambowitz AM

Subjects

Base Sequence, DNA Primers genetics, DNA, Complementary biosynthesis, DNA, Complementary genetics, DNA, Mitochondrial genetics, Endonucleases genetics, Molecular Sequence Data, Plasmids genetics, Restriction Mapping, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Transcription, Genetic, DNA, Fungal genetics, Introns

Abstract

Mobile group II introns encode reverse transcriptases and insert site specifically into intronless alleles (homing). Here, in vitro experiments show that homing of the yeast mtDNA group II intron aI2 occurs by reverse transcription at a double-strand break in the recipient DNA. A site-specific endonuclease cleaves the antisense strand of recipient DNA at position +10 of exon 3 and the sense strand at the intron insertion site. Reverse transcription of aI2-containing pre-mRNA is primed by the antisense strand cleaved in exon 3 and results in cotransfer of the intron and flanking exon sequences. Remarkably, the DNA endonuclease that initiates homing requires both the aI2 reverse transcriptase protein and aI2 RNA. Parallels in their reverse transcription mechanisms raise the possibility that mobile group II introns were ancestors of nuclear non-long terminal repeat retrotransposons and telomerases.

Published

1995

45. Stereochemical selectivity of group II intron splicing, reverse splicing, and hydrolysis reactions.

Author

Podar M, Perlman PS, and Padgett RA

Subjects

Exons genetics, Hydrolysis, Molecular Conformation, RNA metabolism, Recombination, Genetic, Stereoisomerism, Substrate Specificity, Thionucleotides metabolism, Introns genetics, Mitochondria genetics, RNA Splicing, Saccharomyces cerevisiae genetics

Abstract

We have previously shown, using phosphorothioate substitutions at splice site, that both transesterification steps of group II intron self-splicing proceed, by stereochemical inversion, with an Sp but not an Rp phosphorothioate. Under alternative reaction conditions or with various intron fragments, group II introns can splice following hydrolysis at the 5' splice site and can also hydrolyze the bond between spliced exons (the spliced-exon reopening reaction). In this study, we have determined the stereochemical specificities of all of the major model hydrolytic reactions carried out by the aI5 gamma intron from Saccharomyces cerevisiae mitochondria. For all substrates containing exon 1 and most of the intron, the stereospecificity of hydrolysis is the same as for the step 1 transesterification reaction. In contrast, the spliced-exon reopening reaction proceeds with an Rp but not an Sp phosphorothioate at the scissile bond, as does true reverse splicing. Thus, by stereochemistry, this reaction appears to be related to the reverse of step 2 of self-splicing. Finally, a substrate RNA that contains the first exon and nine nucleotides of the intron, when reacted with the intron ribozyme, releases the first exon regardless of the configuration of the phosphorothioate at the 5' splice site, suggesting that this substrate can be cleaved by either the step 1 or the step 2 reaction site. Our findings clarify the relationships of these model reactions to the transesterification reactions of the intact self-splicing system and permit new studies to be interpreted more rigorously.

Published

1995

46. Studies of point mutants define three essential paired nucleotides in the domain 5 substructure of a group II intron.

Author

Boulanger SC, Belcher SM, Schmidt U, Dib-Hajj SD, Schmidt T, and Perlman PS

Subjects

Base Composition, Base Sequence, Conserved Sequence, DNA Mutational Analysis, Molecular Sequence Data, Phenotype, Point Mutation, Structure-Activity Relationship, Suppression, Genetic, Electron Transport Complex IV genetics, Introns genetics, RNA Splicing, RNA, Catalytic genetics, Saccharomyces cerevisiae genetics

Abstract

Domain 5 (D5) is a highly conserved, largely helical substructure of group II introns that is essential for self-splicing. Only three of the 14 base pairs present in most D5 structures (A2.U33, G3.U32, and C4.G31) are nearly invariant. We have studied effects of point mutations of those six nucleotides on self-splicing and in vivo splicing of aI5 gamma, an intron of the COXI gene of Saccharomyces cerevisiae mitochondria. Though none of the point mutations blocked self-splicing under one commonly used in vitro reaction condition, the most debilitating mutations were at G3 and G4. Following mitochondrial Biolistic transformation, it was found that mutations at A2, G3, and C4 blocked respiratory growth and splicing while mutations at the other sites had little effect on either phenotype. Intra-D5 second-site suppressors showed that pairing between nucleotides at positions 2 and 33 and 4 and 31 is especially important for D5 function. At the G3.U32 wobble pair, the mutant A.U pair blocks splicing, but a revertant of that mutant that can form an A+.C base pair regains some splicing. A dominant nuclear suppressor restores some splicing to the G3A mutant but not the G3U mutant, suggesting that a purine is required at position 3. These findings are discussed in terms of the hypothesis of Madhani and Guthrie (H. D. Madhani and C. Guthrie, Cell 71:803-817, 1992) that helix 1 formed between yeast U2 and U6 small nuclear RNAs may be the spliceosomal cognate of D5.

Published

1995

47. An enzyme in yeast mitochondria that catalyzes a step in branched-chain amino acid biosynthesis also functions in mitochondrial DNA stability.

Author

Zelenaya-Troitskaya O, Perlman PS, and Butow RA

Subjects

2-Acetolactate Mutase biosynthesis, 2-Acetolactate Mutase genetics, Alleles, Base Sequence, Chromosome Mapping, DNA-Binding Proteins biosynthesis, DNA-Binding Proteins genetics, Enzyme Activation, Fungal Proteins biosynthesis, Fungal Proteins genetics, Gene Expression Regulation, Fungal, Genes, Fungal, Genes, Regulator, Molecular Sequence Data, Mutation, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae growth & development, Suppression, Genetic, Transcription Factors biosynthesis, Transcription Factors genetics, Amino Acids, Branched-Chain biosynthesis, DNA, Fungal metabolism, DNA, Mitochondrial chemistry, Mitochondria enzymology, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins

Abstract

The yeast mitochondrial high mobility group protein Abf2p is required, under certain growth conditions, for the maintenance of wild-type (rho+) mitochondrial DNA (mtDNA). We have identified a multicopy suppressor of the mtDNA instability phenotype of cells with a null allele of the ABF2 gene (delta abf2). The suppressor is a known gene, ILV5, encoding the mitochondrial protein, acetohydroxy acid reductoisomerase, which catalyzes a step in branched-chain amino acid biosynthesis. Efficient suppression occurs with just a 2- to 3-fold increase in ILV5 copy number. Moreover, in delta abf2 cells with a single copy of ILV5, changes in mtDNA stability correlate directly with changes in conditions that are known to affect ILV5 expression. Wild-type mtDNA is unstable in cells with an ILV5 null mutation (delta ilv5), leading to the production of mostly rho- petite mutants. The instability of rho+ mtDNA in delta ilv5 cells is not simply a consequence of a block in branched-chain amino acid biosynthesis, since mtDNA is stable in cells with a null allele of the ILV2 gene, which encodes another enzyme of that pathway. The most severe instability of rho+ mtDNA is observed in cells with null alleles of both ABF2 and ILV5. We suggest that ILV5 encodes a bifunctional protein required for branched-chain amino acid biosynthesis and for the maintenance of rho+ mtDNA.

Published

1995

48. The mobile group I intron 3 alpha of the yeast mitochondrial COXI gene encodes a 35-kDa processed protein that is an endonuclease but not a maturase.

Author

Guo WW, Moran JV, Hoffman PW, Henke RM, Butow RA, and Perlman PS

Subjects

Base Sequence, DNA, Fungal chemistry, Introns, Molecular Sequence Data, Mutation, RNA Splicing, DNA, Mitochondrial genetics, Endonucleases genetics, Endoribonucleases genetics, Fungal Proteins genetics, Genes, Fungal, Nucleotidyltransferases genetics, Saccharomyces cerevisiae genetics

Abstract

Three mitochondrial mutants were characterized that block the splicing of aI3 alpha, a mobile group I intron of the COXI gene of yeast mtDNA. Mutant C1085 alters helical structures known to be important for splicing of group I introns. M44 and C1072 are point mutants in exon 3 that block correct splicing but allow some splicing at cryptic 5'-splice sites. M44 alters the P1 helix needed for 5'-splice site definition, while the mutation in C1072 is a new kind of mutation because it is located upstream of the exon sequence involved in the P1 helix. All three mutants accumulate novel proteins of 35 and 44 kDa (p35 and p44, respectively) detected both by labeling of mitochondrial translation products and by Western blotting. Partial protease digestions indicate that p44 and p35 are closely related, probably as precursor and processed protein. The level of the intron-encoded endonuclease activity, I-SceIII, is elevated approximately 10-fold in the mutants. Partial purification of I-SceIII from the mutants showed that most, if not all, of the activity is associated with p35. Finally, because aI3 alpha splices accurately in a petite mutant, we conclude that aI3 alpha splicing does not depend on a mtDNA-encoded maturase.

Published

1995

49. 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

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

Author

Moran JV, Zimmerly S, Eskes R, Kennell JC, Lambowitz AM, Butow RA, and Perlman PS

Subjects

Amino Acid Sequence, Base Sequence, Crosses, Genetic, Genes, Fungal, Genetic Markers, Introns, Molecular Sequence Data, Mutagenesis, Site-Directed, RNA-Directed DNA Polymerase genetics, Saccharomyces cerevisiae enzymology, DNA, Fungal genetics, DNA, Mitochondrial genetics, Retroelements, Saccharomyces cerevisiae genetics

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 nearby flanking 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 Zn2+ 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. A cis-dominant splicing-defective mutant of aI2 continues to synthesize cDNAs containing the introns but is completely defective in both 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.

Published

1995