Heterokaryotic transmission of senescence plasmid DNA in Neurospora

Summary Heterokaryotic transmission is one of the major techniques for the study of cytoplasmic inheritance and here we have applied it to the senescence-determining plasmids kalilo (Hawaiian) and maranhar (Indian). We have shown that kalilo-based senescence is effectively transmitted by cytoplasmic contact, both in N. crassa and in N. intermedia. In the first place, the heterokaryons themselves are senescent, confirming the suppressivity of the senescence phenotype in mixtures of normal and senescent cytoplasms. Second, senescence is found in new nuclear associations, as shown by analysis of conidial isolates and meiocytes stemming from the heterokaryons. In addition, the free plasmid AR-kalDNA, and its form that is inserted into mtDNA, (mtIS-kalDNA), are both transmitted to new nuclear associations. In a transient fusion between senescent N. intermedia and nonsenescent N. crassa cells, AR-kalDNA was transmitted to N. crassa and mtIS-kalDNA was transmitted to N. crassa mtDNA. A cryptic mitochondrial plasmid, not associated with senescence, was also transmitted very efficiently to N. crassa mitochondria. In mixed kalilo/maranhar fusions, both plasmids coexisted, approximately equally, in the heterokaryons themselves, and in conidial isolates. However, in sexual derivatives, AR-marDNA was in an excess and AR-kalDNA was sometimes absent. The efficient heterokaryotic transmission of these elements suggests that this is one of their natural modes of spread in populations.     

Genetic organization and structural features of maranhar,a senescence-inducing linear mitochondrial plasmid of Neurospora crassa

Summary The nucleotide sequence of maranhar, a senescence-inducing linear mitochondrial plasmid of Neurospora crassa, was determined. The termini of the 7-kb plasmid are 349-bp inverted repeats (TIRs). Each DNA strand contains a long open reading frame (ORF) which begins within the TIR and extends toward the centre of the plasmid. ORF-1 codes for a single-subunit RNA polymerase that is not closely related to that encoded by another Neurospora plasmid, kalilo. The ORF-2 product may be a B-type DNA polymerase resembling those encoded by terminal protein-linked linear genetic elements, including linear mitochondrial plasmids and linear bacteriophages. A separate coding sequence for the terminal protein could not be identified; however, the DNA polymerase of maranhar has an amino-terminal extension with features that are also present in the terminal proteins of linear bacteriophages. The N-terminal extensions of the DNA polymerases of other linear mitochondrial plasmids contain similar features, suggesting that the terminal proteins of linear plasmids may be comprised, at least in part, of these cryptic domains. The terminal protein-DNA bond of maranhar is resistant to mild alkaline hydrolysis, indicating that it might involve a tyrosine or a lysine residue. Although maranhar and the senescence-inducing kalilo plasmid of N. intermedia are structurally similar, and integrate into mitochondrial DNA by a mechanism thus far unique to these two plasmids, they are not closely related to each other and they do not have any nucleotide sequence features, or ORFs, that distinguish them clearly from mitochondrial plasmids which are not associated with senescence and most of which are apparently non-integrative.     

R-type plasmids in mitochondria from a single source of Zea luxurians teosinte

Two linear DNA plasmids resembling the R1 and R2 plasmids that are present in the mitochondria of several South American strains of maize were found in mitochondria from a single source of Zea luxurians collected by L. Mazoti. The Mazoti mtDNA is closely related to mtDNAs of other Z. luxurians, but mitochondria derived from the other Z. luxurians sources lack the plasmids. The larger plasmid from Mazoti mitochondria, M1, was cloned and large portions of it were sequenced. Restriction mapping and sequence comparisons showed that approximately 4.9 kb is similar to the S1 plasmid of maize and an additional 2.6 kb is related to R1 sequences integrated into the main mitochondrial genome of N cytoplasm. Therefore, the M1 plasmid appears to be very similar to the R1 plasmid. The inverted repeats at the ends of the M1 plasmid are not identitical. The left end IR is similar to the S-TIRs found at the termini of the S plasmids. The right end IR more closely resembles the integrated R1 sequences, including the variant region of the TIR. Whereas the variant region contains 13 bp in the S-TIRs and 15 bp in an integrated version of R1, it is 16 bp long in M1. The region of M1 that has no homology to the S1 plasmid is expressed at very low levels in Mazoti and RU cytoplasms, but at much higher levels in CMS-S mitochondria, where part of it is present in the main mitochondrial genome.     

The kalilo linear senescence-inducing plasmid of Neurospora is an invertron and encodes DNA and RNA polymerases

Summary The nucleotide sequence of kalilo, a linear plasmid that induces senescence in Neurospora by intergrating into the mitochondrial chromosome, reveals structural and genetic features germane to the unique properties of this element. Prominent features include: (1) very long perfect terminal inverted repeats of nucleotide sequences which are devoid of obvious genetic functions, but are unusually GC-rich near both ends of the linear DNA; (2) small imperfect palindromes that are situated at the termini of the plasmid and are cognate with the active sites for plasmid integration into mtDNA; (3) two large, non-overlapping open-reading frames, ORF-1 and ORF-2, which are located on opposite strands of the plasmid and potentially encode RNA and DNA polymerases, respectively, and (4) a set of imperfect palindromes that coincide with similar structures that have been detected at more or less identical locations in the nucleotide sequences of other linear mitochondrial plasmids. The nucleotide sequence does not reveal a distinct gene that codes for the protein that is attached to the ends of the plasmid. However, a 335-amino acid, cryptic, N-terminal domain of the putative DNA polymersse might function as the terminal protein. Although the plasmid has been co-purifed with nuclei and mitochondria, its nucleotide composition and codon usage indicate that it is a mitochondrial genetic element.     

Mitochondrial DNA rearrangements associated with mF plasmid integration and plasmodial longevity in Physarum polycephalum

Plasmodial cultures of Physarum polycephalum have defined life spans and undergo a reproducible decline (senescence) before losing the ability to be subcultured. Studies of the mtDNA of a long-lived Physarum strain, which does not undergo senescence, revealed a 7.9-kb insertion in its mtDNA. This insertion is derived from a mitochondrial plasmid which enhances mitochondrial fusion and mtDNA recombination. Four different recombination events are required to convert the parental mtDNA to the form found in the long-lived strain. An additional recombination event, which deletes a 2.4-kb region of the insert from the long-lived strain, has been identified in the mtDNA of a normally senescing strain. These observations imply a mitochondrial involvement in the process of plasmodial senescence and implicate a region of the DNA derived from the mitochondrial plasmid as being necessary for plasmodial longevity. Received: 11 August / 18 November 1997     

Polymorphism of the mitochondrial L-RNA gene of the basidiomycete Coprinus cinereus

Summary Two unexpectedly small mitochondrial (mt) genomes of Coprinus cinereus, P and S, were compared with the H and J genomes we have described previously. H and J are 42 kb in size and differ in having alternative 1.23 kb insertions in or adjacent to the co-1 gene. P and S DNAs lacked both insertions and had an identical 4.4 kb deletion between the co-1 and L-RNA gene. P DNA contained a 700 by insertion and S DNA a 300 by deletion within a sequence coding the L-RNA gene. This was shown by Southern blot analysis using probes containing the 5 or the 3 exon sequences of the L-RNA gene of Neurospora crassa. These hybridisations showed also that the L-RNA gene and co-1 gene in the C. cinereus mt genome are oppositely orientated and must be transcribed from different DNA strands. No DNA homology was detected using probes containing intron sequences from the L-RNA genes of Saccharomyces cerevisiae or N. crassa. There was no evidence of respiratory deficiency in P and S strains and transfer of nuclei by dikaryon formation made it possible to recombine H nuclei with P and S mitochondria, S nuclei with H and P mitochondria and P nuclei with H mitochondria with no apparent detrimental effect on growth. We conclude that P and S mtDNAs represent naturally occurring variants of the C. cinereus mt genome.     

Association between variant plasmid formation and senescence in retroplasmid-containing strains of Neurospora spp.

Serial transfer of Neurospora strains harboring the Mauriceville and Varkud mitochondrial retroplasmids frequently displays erratic growth and senescence. Growth impairment is associated with the formation of variant forms of the retroplasmids that can integrate into the mitochondrial genome, resulting in mtDNA rearrangements and eventual loss of respiratory function. Here, we evaluate the rate at which variant plasmids arise in subcultures of the Mauriceville strain of N. crassa and their association with the senescent phenotype. Although variant plasmid formation preceded senescence, subcultures were found to tolerate variant plasmids for variable lengths of time and no correlation could be made between the specific sequence inserted in the plasmids and the rate or frequency of senescence. In addition, many cultures were found to contain more than one variant plasmid. The lack of concordance between the timing of variant plasmid formation and growth cessation distinguishes these two events, and provides additional insight into the etiology of senescence. We also detected differences in the frequency of senescence between retroplasmid-containing strains of N. crassa and N. intermedia and report the isolation of a strain in which senescence occurs in the absence of variant plasmid formation or detectable alterations in mtDNA. Our findings indicate there are multiple pathways that lead to senescence and suggest there are host-specific mechanisms that suppress the deleterious effects of the variant plasmids. Received: 8 August 2000 / Accepted: 17 November 2000     

Inversions and recombinations in mitochondrial DNA of the (SG-1) cytoplasmic mutant in two Neurospora species

Summary The mitochondrial DNAs of [SG-1] cytoplasmically-mutant and wild-type strains of Neurospora crassa and Neurospora sitophila were examined by comparative restriction endonuclease analyses. The mtDNA of N. sitophila wild type of Whitehouse differs from type II mtDNA of N. crassa by insertions of 3.3 kb in EcoRI-9, and 1.2 kb in EcoRI-3, and a deletion of 1.1 kb in EcoRI-5. These DNA heteromorphisms provided convenient markers for tracing N. crassa [SG-1] mtDNA during and after its transfer into N. sitophila. The [SG-1] cytoplasmic mutant in both N. crassa and N. sitophila has a distinctive inversion that connects the fragment EcoRI-4 with HindIII-10a. The [SG-1] mtDNA from N. crassa remained essentially intact after it was transferred by crosses into N. sitophila. In each species, a unique second inversion occured in the [SG-1] mtDNA after the transfer was made. In N. sitophila, polar recombination in heteroplasmons between [SG-1] and wild-type preferentially yields strains with mtDNAs that contain the maximum possible number of insertions in the cob and co-1 loci of the EcoRI-3 region of the mitochondrial chromosome.     

The organization of repeating units in mitochondrial DNA from yeast petite mutants

Summary We have reinvestigated the linkage orientation of repeating units in mtDNAs of yeast ^– petite mutants containing an inverted duplication. All five petite mtDNAs studied contain a continuous segment of wild-type mtDNA, part of which is duplicated and present in inverted form in the repeat. We show by restriction enzyme analysis that the non-duplicated segments between the inverted duplications are present in random orientation in all five petite mtDNAs. There is no segregation of sub-types with unique orientation. We attribute this to the high rate of intramolecular recombination between the inverted duplications. The results provide additional evidence for the high rate of recombination of yeast mtDNA even in haploid ^– petite cells.We conclude that only two types of stable sequence organization exist in petite mtDNA: petites without an inverted duplication have repeats linked in straight head-to-tail arrangement (abcabc); petites with an inverted duplication have repeats in which the non-duplicated segments are present in random orientation.     

Location,identity, amount and serial entry of chloroplast DNA sequences in crucifer mitochondrial DNAs

Southern blot hybridization techniques were used to examine the chloroplast DNA (cpDNA) sequences present in the mitochondrial DNAs (mtDNAs) of two Brassica species (B. campestris and B. hirta), two closely related species belonging to the same tribe as Brassica (Raphanus sativa, Crambe abyssinica), and two more distantly related species of crucifers (Arabidopsis thaliana, Capsella bursa-pastoris). The two Brassica species and R. sativa contain roughly equal amounts (12–14 kb) of cpDNA sequences integrated within their 208–242 kb mtDNAs. Furthermore, the 11 identified regions of transferred DNA, which include the 5 end of the chloroplast psaA gene and the central segment of rpoB, have the same mtDNA locations in these three species. Crambe abyssinica mtDNA has the same complement of cpDNA sequences, plus an additional major region of cpDNA sequence similarity which includes the 16S rRNA gene. Therefore, except for the more recently arrived 16S rRNA gene, all of these cpDNA sequences appear to have entered the mitochondrial genome in the common ancestor of these three genera. The mitochondrial genomes of A. thaliana and Capsella bursa-pastoris contain significantly less cpDNA (5–7 kb) than the four other mtDNAs. However, certain cpDNA sequences, including the central portion of the rbcL gene and the 3 end of the psaA gene, are shared by all six crucifer mtDNAs and appear to have been transferred in a common ancestor of the crucifer family over 30 million years ago. 1n conclusion, DNA has been transferred sequentially from the chloroplast to the mitochondrion during crucifer evolution and these cpDNA sequences can persist in the mitochondrial genome over long periods of evolutionary time.     

Mitochondrial DNA of the filamentous ascomycete Cochliobolus heterostrophus

Summary The mitochondrial chromosome of Cochliobolus heterostrophus is a circle approximately 115 kb in circumference, among the largest known from fungi. A physical map of C. heterostrophus mtDNA was constructed using the restriction enzymes BamHI, EcoRI, and PvulI by DNA-DNA hybridizations with cloned or purified mtDNA BamHI fragments. The following sequences were located on the mtDNA map: (1) the large and small mitochondrial ribosomal RNA genes (identified by heterologous hybridization to cloned Neurospora crassa rRNA genes); (2) the sequence homologous to a mitochondrial plasmid present in one field isolate of C. heterostrophus; and (3) a 1.05 kb EcoRI fragment that functions as an autonomously replicating sequence in Saccharomyces cerevisiae. An examination of mtDNA from 23 isolates of C. heterostrophus collected worldwide revealed polymorphisms in restriction enzyme sites. One such polymorphism, coupled with data on a polymorphism in nuclear rDNA, suggests that there are two genetically distinct but geographically overlapping mating populations of C. heterostrophus in the world.     

The linear mitochondrial plasmid pAL2-1 of a long-lived Podospora anserina mutant is an invertron encoding a DNA and RNA polymerase

The molecular characterization of an additional DNA species (pAL2-1) which was identified previously in a long-lived extrachromosomal mutant (AL2) of Podospora anserina revealed that this element is a mitochondrial linear plasmid. pAL2-1 is absent from the corresponding wild-type strain, has a size of 8395 bp and contains perfect long terminal inverted repeats (TIRs) of 975 bp. Exonuclease digestion experiments indicated that proteins are covalently bound at the 5 termini of the plasmid. Two long, non-overlapping open reading frames, ORF1 (3,594 bp) and ORF2 (2847 bp), have been identified, which are located on opposite strands and potentially encode a DNA and an RNA polymerase, respectively. The ORF1-encoded polypeptide contains three conserved regions which may be responsible for a 3–5 exonuclease activity and the typical consensus sequences for DNA polymerases of the D type. In addition, an amino-acid sequence motif (YSRLRT), recently shown to be conserved in terminal proteins from various bacteriophages, has been identified in the amino-terminal part of the putative protein. According to these properties, this first linear plasmid identified in P. anserina shares all characteristics with invertrons, a group of linear mobile genetic elements.     

Characterization of the termini of linear plasmids from Nectria haematococca and their use in construction of an autonomously replicating transformation vector

Summary The mitochondria of isolate FS37 from Nectria haematococca mating population I (Fusarium solani f. sp. cucurbitae) contain two linear plasmids, pFSCI and pFSC2, of 9.2 and 8.3 kbp, respectively. Evidence for a protein blocking the 5 termini of these plasmids was obtained from exonuclease digestion experiments. A single protein band with an apparent M_r of 80 K was labeled when the DNA-protein complex of either plasmid was reacted with [¹²⁵I] Bolton-Hunter reagent and then digested with DNase I. DNA sequence analysis of the termini of both plasmids revealed long inverted repeats of 1,211 by (pFSC1) and 1,027bp (pFSC2). No sequence similarity was found between the terminal inverted repeats (TIRs) of pFSC1 and pFSC2, nor was any similarity identified between the TIRs of the these plasmids and sequences of TIRs from other linear DNAs. A restriction fragment containing the TIR of pFSCI conferred autonomous replication when incorporated into an integrative transformation vector of Ustilago maydis.     

The mitochondrial plasmid of Podospora anserina: A mobile intron of a mitochondrial gene

Summary In the ascomycete Podospora anserina strain ageing (senescence) is caused by a mitochondrial plasmid. In juvenile mycelia it is an integral part of the mtDNA and becomes liberated during ageing. The nucleotide sequence of this plasmid and of its flanking regions was determined. It consists of 2,539 by and contains an un identified reading frame (URF) originating in the adjacent mtDNA upstream of excision point 1. Within the URF a putative 48 by autonomously replicating sequence (ars) was identified. At both excision sites of the plasmid there are two short nonidentical interrupted palindromes and a few base pairs apart from these palindromes, both upstream and downstream, two short inverted repeats are localised. The experimental data make it evident that the mt plasmid is an intron of the cytochrome c oxidase gene (subunit I) which may be excised at the DNA level and thus become the mobile infective agent causing senescence. The concept of this mobile intron and current hypotheses concerning the relationship between introns and transposons are stressed.     

Transfer of Neurospora kalilo plasmids among species and strains by introgression

There are four different variants of the kalilo “family” of linear mitochondrial plasmids. This family is found in several heterothallic species and one pseudohomothallic species of Neurospora, as well as in one homothallic species of Gelasinospora. The mode of dispersal of these plasmids is not known. Horizontal transmission has proved difficult to demonstrate. Another possibility is transfer by introgression, and this is modelled in the present paper. We have used introgression and subsequent heterokaryosis to successfully transfer the LA-kalilo plasmid from a Haitian strain of Neurospora crassa to the standard Oak Ridge N. crassa background, the LA-kalilo plasmid from the pseudohomothallic Neurospora tetrasperma to N. crassa, and the kalilo plasmid from N. crassa to N. tetrasperma. Thus, introgression is shown to be a possible avenue of dispersal between species. The recipient strains were all senescent but the mechanism of this senescence is not known. It could be caused by the plasmids, but if so the mechanism is novel since plasmid/mtDNA junction fragments of the type found in the standard mode of mtDNA insertion could not be detected. However, mtDNA changes were observed in the senescent recipients. Received: 15 February / 24 June 1999     

Characterization and prevalence of a circular mitochondrial plasmid in senescence-prone isolates of Neurospora intermedia

Genetic and molecular analyses of the phenomenon of senescence—i.e., irreversible loss of growth and reproductive potential upon subculturing—in Neurospora intermedia strain M1991-60A, collected from Maddur in southern India, showed the presence of plasmid pMaddur1, which is homologous to the senescence-inducing circular mitochondrial plasmid, pVarkud. Maternal inheritance of senescence in M1991-60A correlated to the formation of variant pMaddur1, its subsequent insertion into mitochondrial (mt)DNA and the accumulation of defective mtDNA with the pMaddur1insert. PCR-based analyses for similar plasmids in 147 natural isolates of Neurospora from Maddur showed that nearly 40% of the strains had pMaddur1 or pMaddur2 that shared 97–98% sequence homology with pVarkud and pMauriceville. Nearly 50% of the strains that harbored either pMaddur1 or pMaddur2, also contained a circular Varkud satellite plasmid (pVS). Size polymorphism maps to the cluster of PstI sites in the non-coding region. Whereas senescence of nearly 40% of N. intermedia strains may be due to pMaddur, the presence in seven strains of pVS but not pMaddur and the absence of either of these two plasmids in other senescence-prone isolates suggests yet undiscovered mechanisms of senescence in the Maddur strains.     

Plasmids of mitochondrial origin in senescent mycelia of Podospora curvicolla

Summary Podospora curvicolla displays symptoms of senescence similar but not quite identical to those reported for Podospora anserina. In Podospora curvicolla single hyphae may escape from death leading to a new growth front and consequently to a mode of growth characterized by alternating phases of growth and non-growth. Restriction analyses and hybridization experiments have revealed that the Podospora curvicolla type of senescence is correlated with plasmids originating from amplification of a single distinct region of the mitochondrial DNA containing the IrRNA gene. In the yeast transformation system sequences of this region may function as autonomously replicating sequences (ARS). Plasmids (pl1, pl2 and pl3) isolated from different, independently aged mycelia are largely homologous to each other but differ in their excision/junction sites and have different sizes: 10.85 kb (pl1), 9.01 kb (p12) and 10.50 kb (pl3). The sequence of the most frequently occurring plasmid in ageing strains of Podospora anserina is absent in Podospora curvicolla either as free plasmid DNA or as an integrated part of the mtDNA. Possibly there is a correlation between the absence of this particular sequence in Podospora curvicolla and the type of senescence displayed in this organism.     

Involvement of a large inverted repeated sequence

Summary Southern hybridization of the total DNA of Agrocybe aegerita with cloned mitochondrial (mt) probes revealed a sequence homology between two distant mitochondrial restriction fragments. From the mtDNA restriction map and the distribution of restriction sites on the cross-hybridizing mitochondrial fragments, two copies of a large inverted repeated sequence (IR) of 3 kbp were located on the mitochondrial genome. These IR sequences divided the 80 kbp mtDNA into two singlecopy regions of 24 kbp (SSC) and 50 kbp (LSC). For the first time in higher fungi, this IR sequence has been shown to be involved in an intramolecular homologous recombinational event. Such a rearrangement led to an inversion of the orientation of the two unique-copy regions, without any change in mtDNA complexity. The location of the recombinational event was compared with previously reported plant and fungal mitochondrial rearrangements and the potential role of the IR sequence was discussed.     

A truncated recombination repeat in the mitochondrial genome of a Petunia CMS line

Repeated sequences known as recombination repeats are present in the majority of plant mitochondrial genomes. Two recombination repeat sequences from Petunia have been analyzed. The two repeats are virtually identical over 1.42 kb. One of the repeats is truncated and is likely to have arisen from a rare recombination event in the full-length repeat. Two sequence-blocks within the Petunia repeat are highly similar to sequences in the 5 flank of several plant mitochondrial genes. No sequence motifs are shared by the Petunia repeat and other sequenced plant mitochondrial recombination repeats, suggesting that the recombination occurs by an homologous, rather than a site-specific, mechanism.     

Kalilo plasmids are a family of four distinct members with individual global distributions across species

Kalilo is a linear 9-kb plasmid, isolated originally from Hawaiian strains of the heterothallic fungus Neurospora intermedia. Its properties include terminal inverted repeats, two ORFs coding for a presumptive DNA and an RNA polymerase, and the ability to cause senescence in its original host and in the closely related species Neurospora crassa. We have examined natural isolates alleged to contain plasmids homologous to kalilo. Most of these isolates do in fact contain plasmids with so close an identity to kalilo as to be certain relatives. We found a new case of kalilo in Neurospora tetrasperma from Moorea-Tahiti, and a new case of LA-kalilo (previously found only in N. tetrasperma) in N. crassa from Haiti. A previously unreported, substantially shorter, kalilo variant has been found in three geographically separate isolates of the heterothallic species Neurospora discreta. Therefore, if the previously reported kalilo variant from the genus Gelasinospora is included, in all there are four members of the kalilo plasmid family. The main differences between these plasmids are in the terminal inverted repeats (TIRs). The phylogeny of the TIR sequences is largely congruent with that of nuclear DNA in the species in which they are found, suggesting that the plasmids are related by vertical descent throughout the evolution of these species. However, there are two cases of a plasmid found in a heterothallic and a pseudohomothallic species in the same global area; these cases might have arisen from more recent horizontal transmission or introgression. Received: 14 July / 17 September 1999