An additional class II intron with homology to reverse transcriptase in rapidly senescing Podospora anserina

Mitochondrial recombination increases with age in Podospora anserina

With uniparental inheritance of mitochondria, there seems little reason for homologous recombination in mitochondria, but the machinery for mitochondrial recombination is quite well-conserved in many eukaryote species. In fungi and yeasts heteroplasmons may be formed when strains fuse and transfer of organelles takes place, making it possible to study mitochondrial recombination when introduced mitochondria contain different markers. A survey of wild-type isolates from a local population of the filamentous fungus Podospora anserina for the presence of seven optional mitochondrial introns indicated that mitochondrial recombination does take place in nature. Moreover the recombination frequency appeared to be correlated with age: the more rapidly ageing fraction of the population had a significantly lower linkage disequilibrium indicating more recombination. Direct confrontation experiments with heterokaryon incompatible strains with different mitochondrial markers at different (relative) age confirmed that mitochondrial recombination increases with age. We propose that with increasing mitochondrial damage over time, mitochondrial recombination - even within a homoplasmic population of mitochondria - is a mechanism that may restore mitochondrial function.

Mitochondrial group II introns, cytochrome c oxidase, and senescence in Podospora anserina

Podospora anserina is a filamentous fungus with a limited life span. It expresses a degenerative syndrome called senescence, which is always associated with the accumulation of circular molecules (senDNAs) containing specific regions of the mitochondrial chromosome. A mobile group II intron (alpha) has been thought to play a prominent role in this syndrome. Intron alpha is the first intron of the cytochrome c oxidase subunit I gene (COX1). Mitochondrial mutants that escape the senescence process are missing this intron, as well as the first exon of the COX1 gene. We describe here the first mutant of P. anserina that has the alpha sequence precisely deleted and whose cytochrome c oxidase activity is identical to that of wild-type cells. The integration site of the intron is slightly modified, and this change prevents efficient homing of intron alpha. We show here that this mutant displays a senescence syndrome similar to that of the wild type and that its life span is increased about twofold. The introduction of a related group II intron into the mitochondrial genome of the mutant does not restore the wild-type life span. These data clearly demonstrate that intron alpha is not the specific senescence factor but rather an accelerator or amplifier of the senescence process. They emphasize the role that intron alpha plays in the instability of the mitochondrial chromosome and the link between this instability and longevity. Our results strongly support the idea that in Podospora, "immortality" can be acquired not by the absence of intron alpha but rather by the lack of active cytochrome c oxidase.

Evolutionary relationships among group II intron-encoded proteins and identification of a conserved domain that may be related to maturase function

Many group II introns encode reverse transcriptase-like proteins that potentially function in intron mobility and RNA splicing. We compared 34 intron-encoded open reading frames and four related open reading frames that are not encoded in introns. Many of these open reading frames have a reverse transcriptase-like domain, followed by an additional conserved domain X, and a Zn(2+)-finger-like region. Some open reading frames have lost conserved sequence blocks or key amino acids characteristic of functional reverse transcriptases, and some lack the Zn(2+)-finger-like region. The open reading frames encoded by the chloroplast tRNA(Lys) genes and the related Epifagus virginiana matK open reading frame lack a Zn(2+)-finger-like region and have only remnants of a reverse transcriptase-like domain, but retain a readily identifiable domain X. Several findings lead us to speculate that domain X may function in binding of the intron RNA during reverse transcription and RNA splicing. Overall, our findings are consistent with the hypothesis that all of the known group II intron open reading frames evolved from an ancestral open reading frame, which contained reverse transcriptase, X, and Zn(2+)-finger-like domains, and that the reverse transcriptase and Zn(2+)-finger-like domains were lost in some cases. The retention of domain X in most proteins may reflect an essential function in RNA splicing, which is independent of the reverse transcriptase activity of these proteins.

Nucleotide sequence of the COX1 gene in Kluyveromyces lactis mitochondrial DNA: evidence for recent horizontal transfer of a group II intron

The cytochrome oxidase subunit 1 gene (COX1) in K. lactis K8 mtDNA spans 8,826 bp and contains five exons (termed E1-E5) totalling 1,602 bp that show 88% nucleotide base matching and 91% amino acid homology to the equivalent gene in S. cerevisiae. The four introns (termed K1 cox1.1-1.4) contain open reading frames encoding proteins of 786, 333, 319 and 395 amino acids respectively that potentially encode maturase enzymes. The first intron belongs to group II whereas the remaining three are group I type B. Introns K1 cox1.1, 1.3, and 1.4 are found at identical locations to introns Sc cox1.2, 1.5 a, and 1.5 b respectively from S. cerevisiae. Horizontal transfer of an intron between recent progenitors of K. lactis and S. cerevisiae is suggested by the observation that K1 cox1.1 and Sc cox1.2 show 96% base matching. Sequence comparisons between K1 cox1.3/Sc cox1.5 a and K1 cox1.4/Sc cox1.5 b suggest that these introns are likely to have been present in the ancestral COX1 gene of these yeasts. Intron K1 cox1.2 is not found in S. cerevisiae and appears at an unique location in K. lactis. A feature of the DNA sequences of the group I introns K1 cox1.2, 1.3, and 1.4 is the presence of 11 GC-rich clusters inserted into both coding and noncoding regions. Immediately downstream of the COX1 gene is the ATPase subunit 8 gene (A8) that shows 82.6% base matching to its counterpart in S. cerevisiae mtDNA.

A site-specific deletion in mitochondrial DNA of Podospora is under the control of nuclear genes

In the filamentous fungus Podospora anserina, the association of two nuclear genes inevitably leads to a "premature death" phenotype consisting of an early end of vegetative growth a few days after ascospore germination. Mycelia showing this phenotype contain a mitochondrial chromosome that always bears the same deletion. One of the break points is exactly at the 5' splice site of a particular mitochondrial intron, suggesting that the deletion event could result from molecular mechanisms also involved in intron mobility. One of the nuclear genes involved in triggering this site-specific event belongs to the mating-type minus haplotype; the other is a mutant allele of a gene encoding a cytosolic ribosomal protein.

Detection of a protein encoded by a class II mitochondrial intron of Podospora anserina

In the filamentous fungus Podospora anserina, the amplification as circular DNA molecules of the first intron (intron alpha) of the CO1 mitochondrial gene, encoding the cytochrome oxidase subunit 1, is known to be strongly associated with aging of strains. In this study we have attempted to detect the protein potentially encoded by the open reading frame (ORF) contained in this intron. This was done by the Western blot technique using specific antisera raised against three polypeptides encoded by three non-overlapping fragments of this ORF adapted to the universal code and overexpressed in Escherichia coli. We examined about thirty independent subclones of Podospora derived from two different geographic races (A, s), using wild-type and mutant strains, young and senescent cultures. A 100 kDa polypeptide, encoded by the class II intron alpha, was detected in five senescent subclones which all showed strong amplification of the intronic alpha sequence (Sen DNA alpha).

The complete DNA sequence of the mitochondrial genome of Podospora anserina

The complete 94,192 bp sequence of the mitochondrial genome from race s of Podospora anserina is presented (1 kb = 10(3) base pairs). Three regions unique to race A are also presented bringing the size of this genome to 100,314 bp. Race s contains 31 group I introns (33 in race A) and 2 group II introns (3 in race A). Analysis shows that the group I introns can be categorized according to families both with regard to secondary structure and their open reading frames. All identified genes are transcribed from the same strand. Except for the lack of ATPase 9, the Podospora genome contains the same genes as its fungal counterparts, N. crassa and A. nidulans. About 20% of the genome has not yet been identified. DNA sequence studies of several excision-amplification plasmids demonstrate a common feature to be the presence of short repeated sequences at both termini with a prevalence of GGCGCAAGCTC.

DNA sequence analysis of the mitochondrial ND4L-ND5 gene complex from Podospora anserina. Duplication of the ND4L gene within its intron

A 15 kb region of the 100 kb mitochondrial genome of Podospora anserina has been mapped and sequenced (1 kb = 10(3) base-pairs). The genes for ND4L and ND5 are identified as contiguous genes with overlapping termination and initiation codons. In race A (101 kb) the gene for ND4L (4.3 kb) has a gene duplication within an intron including a second subgroup IC intron. Race s (95 kb) lacks this second gene complex. Each intron has the identical 5' exon boundary. Secondary structure analysis showed that the closest relative of the second intron is the first intron itself. The open reading frames of the two introns are also closely related to each other as well as to their counterpart in the ND4L gene of Neurospora crassa. The 9.9 kb ND5 gene starts immediately at the termination codon of ND4L and is split by two group IB introns, one group IC intron and one group II intron. The group II intron is closely related to other group II introns although its open reading frame sequence similarity with retroviral reverse transcriptase appears to be more divergent. The similarities in secondary structure and open reading frames for these six introns are discussed.

A sequence encoding a maturase-related protein in a group II intron of a plant mitochondrial nad1 gene

We have determined from nucleotide sequence analysis that the subterminal and terminal exons of a respiratory chain NADH dehydrogenase subunit I gene in broad bean mitochondrial DNA (mtDNA) are separated by a group II intron. Within this intron is a 687-codon open reading frame that, from considerations of similarity between amino acid sequences predicted from this open reading frame and maturase-coding sequences in group II introns of certain fungal mitochondrial genes, appears to encode a maturase-related protein. Transcripts complementary to this broad bean sequence (designated a mat-r gene) were detected among RNAs isolated from broad bean mitochondria. Data obtained from DNA-DNA hybridizations indicated that soybean and corn mtDNAs also contain a mat-r gene and suggested that only one copy of this gene occurs in each plant mtDNA. The putative protein specified by the broad bean mat-r gene contains amino acid sequences characteristic of reverse transcriptases. Because of this, consideration is given to the possibility that the maturase-related protein may be functional in the mechanisms by which plant mtDNA sequences are rearranged and foreign sequences are incorporated into plant mtDNAs.

DNA sequence analysis of the 24.5 kilobase pair cytochrome oxidase subunit I mitochondrial gene from Podospora anserina: a gene with sixteen introns

The DNA sequence of a 26.7 Kilobase pair (10(3) base pairs = 1 Kb) region of the mitochondrial genomes of races s and A from Podospora anserina was determined. Within this region, the 24.5 Kb cytochrome oxidase subunit I gene was located and its exon sequences determined by computer analysis comparisons with other fungal genes. The Podospora COI gene was interrupted by two group II introns (one in race s) and fourteen group I introns ranging in size from about 2.2 Kb to 404 bp. Earlier studies on secondary structure analysis, as well as comparison of their open reading frames (ORFs), showed that the two group II introns were closely related. The fourteen group I introns were representatives of three subgroupings (IB, C and a new category, subgroup ID). Two of these group I introns were separated by just a single exon codon. The analysis of all these introns is discussed in comparison with other fungal introns as well as with the known Podospora anserina introns.

DNA sequence analysis of the apocytochrome b gene of Podospora anserina: a new family of intronic open reading frame

The 5,969 bp (base pair) DNA sequence of the apocytochrome b mitochondrial (mt) gene of race A Podospora anserina was located in a 8.5 Kbp region. This gene contained a 2,499 bp subgroup IB and a 1,306 bp subgroup ID intron as well as a 990 bp subgroup IB intron which is present in race A but not race s. The large subgroup IB intron and the race A specific IB intron both contained potential alternate splice sites which brought their open reading frames into phase with their upstream exon sequences. All three introns were compared with regard to their secondary structures and open reading frames to the other 30 group I introns in Podospora anserina, as well as to other fungal introns. We detected a new family of intronic ORFs comprising seven P. anserina introns, several N. crassa introns, as well as the T4td bacteriophage intron. Sequence similarities to intron-encoded endonucleases were noteworthy. The DNA sequences reported here and in the accompanying paper complete the analysis of race s and race A mitochondrial DNA.

Comparative and functional anatomy of group II catalytic introns--a review

The 70 published sequences of group II introns from fungal and plant mitochondria and plant chloroplasts are analyzed for conservation of primary sequence, secondary structure and three-dimensional base pairings. Emphasis is put on structural elements with known or suspected functional significance with respect to self-splicing: the exon-binding and intron-binding sites, the bulging A residue involved in lariat formation, structural domain V and two isolated base pairs, one of them involving the last intron nucleotide and the other one, the first nt of the 3' exon. Separate sections are devoted to the 29 group II-like introns from Euglena chloroplasts and to the possible relationship of catalytic group II introns to nuclear premessenger introns. Alignments of all available sequences of group II introns are provided in the APPENDIX.

Structure-function relationships in a self-splicing group II intron: a large part of domain II of the mitochondrial intron aI5 is not essential for self-splicing

An oligonucleotide-directed deletion of 156 nucleotides has been introduced into the yeast mitochondrial group II intron al5 (887 nt). The deletion comprises almost all of domain II, which is one of the six phylogenetically conserved structural elements of group II introns. This mutant displays reduced self-splicing activity, but results of chemical probing with dimethylsulphate suggest that sequences at the site of the deletion interfere with the normal folding of the intron. This is supported by computer analyses, which predict a number of alternative structures involving conserved intron sequences. Splicing activity could be restored by insertion of a 10-nucleotide palindromic sequence into the unique Smal site of the deletion mutant, resulting in the formation of a small stable stem-loop element at the position of domain II. These results provide a direct correlation between folding of the RNA and its activity. We conclude that at least a large part of domain II of the group II intron al5 is not required for self-splicing activity. This deletion mutant with a length of 731 nucleotides represents the smallest self-splicing group II intron so far known.

Molecular genetics of group I introns: RNA structures and protein factors required for splicing--a review

In vivo and in vitro genetic techniques have been widely used to investigate the structure-function relationships and requirements for splicing of group-I introns. Analyses of group-I introns from extremely diverse genetic systems, including fungal mitochondria, protozoan nuclei, and bacteriophages, have yielded results which are complementary and highly consistent. In vivo genetic studies of fungal mitochondrial systems have served to identify cis-acting sequences within mitochondrial introns, and trans-acting protein products of mitochondrial and nuclear genes which are important for splicing, and to show that some mitochondrial introns are mobile genetic elements. In vitro genetic studies of the self-splicing intron within the Tetrahymena thermophila nuclear large ribosomal RNA precursor (Tetrahymena LSU intron) have been used to examine essential and nonessential RNA sequences and structures in RNA-catalyzed splicing. In vivo and in vitro genetic analysis of the intron within the bacteriophage T4 td gene has permitted the detailed examination of mutant phenotypes by analyzing splicing in vivo and self-splicing in vitro. The genetic studies combined with phylogenetic analysis of intron structure based on comparative nucleotide sequence data [Cech 73 (1988) 259-271] and with biochemical data obtained from in vitro splicing experiments have resulted in significant advances in understanding the biology and chemistry of group-I introns.

Sequence analysis of mitochondrial DNA from Podospora anserina. Pervasiveness of a class I intron in three separate genes

A 48 kb region of the 95 kb mitochondrial genome of Podospora anserina has been mapped and sequenced (1 kb = 10(3) base-pairs). The DNA sequence of the genes for ND2, 3, 4, ATPase 6 and URFC are presented here. As in Neurospora crassa, the ND2 and 3 genes consist of a unit separated by one TAA stop codon. ND3, 4 and ATPase 6 are interrupted by class I introns. All three introns are remarkably similar in the C-domain of their secondary structure, sufficient enough to designate them as new subgroup, class IC introns. The open reading frames of the ND3 and 4 introns bear a high sequence similarity to the open reading frame of the class IB introns of ATPase 6 from N. crassa and ND1 from Neurospora intermedia Varkud. We also show that the tRNA Met-2 gene is duplicated and is involved in a recombinational event. The 5' region of URFC is also duplicated but no involvement of this gene with recombination or formation of plasmids is known. The evolutionary significance of the similarities of intron secondary structures and open reading frames of the ND3, 4 and ATPase 6 genes is discussed, including the possible separate evolution of structural and coding sequences.

DNA sequence and organization of the mitochondrial ND1 gene from Podospora anserina: analysis of alternate splice sites

Earlier, we reported that the ND1 mitochondrial gene of Podospora anserina is mosaic, containing at least three class I introns. We have now completed the sequence of the ND1 gene and have determined that it contains four class I introns of 1,820, 2,631, 2,256 and 2,597 bp with the entire gene complex containing 10,505 bp, only 1,101 of which are exon sequences. Introns 1 and 3 appear to be related in that their open reading frames (ORFS) exhibit extensive amino acid sequence similarity and like the URFN sequence from Neurospora crassa have multiple sequence repetitions. Introns 2 and 4 are similar in that both appear to be mosaic introns. Where intron 2 has many short ORFS, intron 4 has two, 391 and 262 aa respectively. The first ORF has some patch work sequence similarity with one of the intron 2 ORFs but the second ORF is strikingly similar to the single intron ORF in the ND1 gene of N. crassa. Just upstream of the sequences necessary to form the central core of the P. anserina intron 4 secondary structure, there is a 17 bp sequence which is an exact replica of the exon sequence abutting the 5' flank of the 1,118 bp N. crassa ND1 intron. Secondary structure analysis suggests that the 2,597 bp intron 4 can fold as an entity but a similar structure can be constructed just from an 1,130 bp portion by utilizing the 17 bp element as an alternate splice site. Detailed structural analysis suggests that intron 4 (as well as the single ND1 intron from N. crassa) can utilize helical configurations which bring the downstream open reading frame into juxtaposition with the exon sequences.

A Podospora anserina longevity mutant with a temperature-sensitive phenotype for senescence

A Podospora anserina longevity mutant was identified with a temperature-sensitive phenotype for senescence. This mutant, termed TS1, grew for over 3 m at 27 degrees C, but when shifted to 34 degrees C, it underwent senescence between 10 and 18 cm. A previously described senescence-associated plasmid, alpha senDNA, derived from the mitochondrial genome, was not detected in TS1 at 27 degrees C but was present in senescent cultures at 34 degrees C. A similar result was observed in progeny strains obtained by crossing the TS1 mutant with a wild-type strain. Other mitochondrial excision-amplification DNAs in addition to alpha senDNA were also observed in the senescent cultures. Most were derived from a specific region of the mitochondrial genome. These results provide evidence that alpha senDNA is involved in TS1 senescence and suggest that this plasmid may play a role in the formation of other mitochondrial excision-amplification plasmids.

Excision-amplification of mitochondrial DNA during senescence in Podospora anserina. A potential role for an 11 base-pair consensus sequence in the excision process

Three novel mitochondrial excision-amplification plasmids of Podospora anserina were identified and the excision-junction sites on the mitochondrial genome determined. All three plasmids were at least partially derived from a common region of the mitochondrial genome termed EcoRI-7 (E7). The entire 5651 base-pair sequence of E7 is presented. Included within this sequence are the E7-specific excision-junction sites of these novel plasmids, the localizations of nine tRNA genes, and the localization of a class I intron of the large rRNA mitochondrial gene. The E7 region contains the 3' portion of this large rRNA gene. Formation of these three novel plasmids as well as other previously described mitochondrial plasmids was found to be associated with the presence of an 11 base-pair consensus sequence, GGCGCAAGCTC, or its complementary sequence. A possible role for this consensus sequence and its complement in plasmid formation and the senescence process of Podospora is discussed. A possible role for the tRNA genes in plasmid formation is considered.

A Podospora anserina longevity mutant with a temperature-sensitive phenotype for senescence

A Podospora anserina longevity mutant was identified with a temperature-sensitive phenotype for senescence. This mutant, termed TS1, grew for over 3 m at 27 degrees C, but when shifted to 34 degrees C, it underwent senescence between 10 and 18 cm. A previously described senescence-associated plasmid, alpha senDNA, derived from the mitochondrial genome, was not detected in TS1 at 27 degrees C but was present in senescent cultures at 34 degrees C. A similar result was observed in progeny strains obtained by crossing the TS1 mutant with a wild-type strain. Other mitochondrial excision-amplification DNAs in addition to alpha senDNA were also observed in the senescent cultures. Most were derived from a specific region of the mitochondrial genome. These results provide evidence that alpha senDNA is involved in TS1 senescence and suggest that this plasmid may play a role in the formation of other mitochondrial excision-amplification plasmids.

Multiple exon-binding sites in class II self-splicing introns

Partial deletion of the exon 5' to S. cerevisiae intron a5, a self-splicing mitochondrial class II intron, reveals the existence of several sites of intron-exon interaction. We have identified two of the corresponding exon-binding sites in intron a5 by comparative sequence analysis and RNAase H digestion of the intron complexed to a DNA version of its 5' exon. Introduction of mutations in either the intronic sites or the complementary exonic sequences affects splicing in vitro, whereas double mutants in which intron-exon pairings have been restored show normal activity. Some of the mutants accumulate a product that was shown to be the intron-3' exon lariat, a postulated splicing intermediate. The possible role of one of the intronic sites in aligning exons for the ligation step is discussed.