Philip S. Perlman

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

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.

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

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.

Involvement of aminoacyl-tRNA synthetases and other proteins in group I and group II intron splicing

Group I and group II introns catalyse their own splicing, but depend on protein factors for efficient splicing in vivo. Some of these proteins, termed maturases, are encoded by the introns themselves and may also function in intron mobility. Other proteins are encoded by host chromosomal genes and include aminoacyl-tRNA synthetases and various proteins that function in protein synthesis. The splicing factors identified thus far appear to be idiosyncratic, even in closely related organisms. We suggest that some of these protein-assisted splicing reactions evolved relatively recently, possibly reflecting the recent dispersal of the introns themselves.

18 Group I and Group II Ribozymes as RNPs: Clues to the Past and Guides to the Future

Group I and group II introns are not only catalytic RNAs, but also mobile genetic elements. The success of these introns as mobile elements almost certainly relates to their innate self-splicing capability, which enables them to propagate by inserting into host genes while only minimally impairing gene expression. Nevertheless, both types of introns have become dependent on proteins for efficient splicing in vivo to help fold the intron RNA into the catalytically active structure. Although group I and group II introns have very different structures and splicing mechanisms (Chapter 13), there are striking parallels in the evolution of their protein-assisted splicing reactions. For example, the splicing factors for both types of introns include intron-encoded as well as cellular proteins, and the intron-encoded proteins, DNA endonucleases for group I introns and reverse transcriptases (RTs) for group II introns, also function in intron mobility. In addition, excised group I and group II intron RNAs remain associated with splicing factors in RNP particles, which can then cleave and insert into cellular RNA or DNA target sites by reverse splicing. The need to control this deleterious ribozyme activity may have been an evolutionary driving force favoring mutations that impaired self-splicing activity and resulted in dependence on protein factors (Nikolcheva and Woodson 1997). In this chapter, we review protein-assisted reactions of group I and group II introns. These studies illustrate how proteins facilitate RNA folding and catalysis and provide unique insights into how splicing mechanisms evolve. A recurring theme, first developed in a previous review...

A latent intron-encoded maturase is also an endonuclease needed for intron mobility.

Some yeast mitochondrial introns encode proteins that promote either splicing (maturases) or intron propagation via gene conversion (the fit1 endonuclease). We surveyed introns in the coxl gene for their ability to engage in gene conversion and found that the group I intron, al4 alpha, was efficiently transmitted to genes lacking it. An endonucleolytic cleavage is detectable in recipient DNA molecules near the site of intron insertion in vivo and in vitro. Conversion is dependent on an intact al4 alpha open reading frame. This intron product is a latent maturase, but these data show that it is also a potent endonuclease involved in recombination. Dual function proteins that cleave DNA and facilitate RNA splicing may have played a pivotal role in the propagation and tolerance of introns.

Derepression of mitochondria and their enzymes in yeast: Regulatory aspects☆

Abstract We have performed a detailed analysis of the properties of glucose-repressed cells of a commercial strain of Saccharomyces cerevisiae. They contain measurable amounts of the respiratory enzymes NADH oxidase, cytochrome c oxidase, succinate dehydrogenase, succinate:cytochrome c reductase and NADH:cytochrome c reductase (antimycin A-sensitive) as well as the dehydrogenases for l -malate, l -glutamate, and l 8-isocitrate. Cytochromes b, c1, and aa3 are present in amounts that may be in excess of those required for cytochrome-linked enzyme activities. Enzymes and cytochromes are localized in large, presumably mitochondrial organelles among which no compositional or functional heterogeneity could be detected. We have also analyzed the kinetics of synthesis of respiratory enzymes and cytochromes during the release from catabolite(glucose) repression. All activities assayed except for cytochrome c oxidase begin their derepression before the external glucose concentration falls below 0.4%; derepression of cytochrome oxidase occurs only after the glucose concentration falls below 0.1%. The earlier events comprise the “fermentative” phase of derepression while the later events comprise the “oxidative” phase. The two phases can be distinguished operationally by their sensitivity to antimycin A. Only the oxidative phase is blocked by the inhibitor. Respiratory enzymes and cytochromes appear to fall into two classes distinguishable by their increase during derepression. An apparently constitutive one consists of cytochrome c oxidase, ATPase, and cytochromes aa3, b, and c1; these entities increase in amount per cell but not in amount per unit of mitochondrial mass and are of the order of 5-fold or less. The second class consists of those activities that increase by more than 6-fold and may be considered derepressible in the strict sense. Thus, proliferation and differentiation of mitochondria both contribute to the cellular changes associated with derepression. The fermentative phase of derepression does not require mitochondrial function, mitochondrial protein, or RNA synthesis, or the gradual accumulation of regulatory elements for either its initiation or persistence. This phase of derepression also occurs in cytoplasmic petites. In contrast, the oxidative phase of derepression requires mitochondrial function. Mitochondrial gene expression is required for the biogenesis of fully functional mitochondria but, except for cytochrome c, it plays little or no role in regulating the expression of nuclear genes the products of which are localized in mitochondria.

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

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.

Mobility of Yeast Mitochondrial Group II Introns: Engineering a New Site Specificity and Retrohoming via Full Reverse Splicing

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.

AN ENZYME IN YEAST MITOCHONDRIA THAT CATALYZES A STEP IN BRANCHED-CHAIN AMINO ACID BIOSYNTHESIS ALSO FUNCTIONS IN MITOCHONDRIAL DNA STABILITY

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.

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

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.