Interstitial telomeres are hotspots for illegitimate recombination with DNA molecules injected into the macronucleus of Paramecium primaurelia.

DNA molecules injected into the macronucleus of Paramecium primaurelia replicate either as free linear telomerized or chromosome integrated molecules. In the present study we show that when a 1.77 kb BamHI DNA fragment harbouring the his3 gene of Saccharomyces cerevisiae was microinjected into the macronucleus, a fraction of the molecules are integrated into the chromosome via an illegitimate recombination process. The injected molecules were mostly inserted at their extremities at multiple points in the genome by replacing the Paramecium sequences. However, insertion sites were not totally at random. Roughly 30% of the molecules were integrated next to or in telomeric repeats. These telomeric repeats were not at the extremities of chromosomes but occupy an internal or interstitial position. We argue that such sites are hotspots for integration as the probability of random insertion near or in an interstitial telomeric site, of which there are 25-60 in a macronucleus is between 5 x 10(-4) and 3 x 10(-5).     

Telomeres inhibit end to end fusion and enhance maintenance of linear DNA molecules injected into the Paramecium primaurelia macronucleus.

Direct injection into the macronucleus of Paramecium tetraurelia of DNA molecules coding for the A-antigen leads to expression of the gene and autonomous replication. When injected into Paramecium primaurelia DNA from probably any origin, procaryote or eucaryote, can replicate as linear telomerized molecules and the number of copies maintained can be very high (up to 20000 copies). We present here evidence that if the injected linear DNA molecules harbour preexisting telomeres at both extremities they are protected from degradation, the number of DNA molecules maintained being 15- to 30-fold higher than if the molecules are injected without telomeres. Some of the injected molecules replicate as multimers, but, only when the fused ends are devoid of preexisting telomeric repeats.     

Variable telomeric repeat synthesis in Paramecium tetraurelia is consistent with misincorporation by telomerase.

Telomeric DNA at the ends of chromosomes consist of short, tandem repeat sequences. The telomeres of Paramecium tetraurelia are made up of variable repeats, whereas Paramecium caudatum telomeric repeats are largely invariant. To investigate variable repeat synthesis in P. tetraurelia, mutated telomerase RNA genes were expressed in vivo. We demonstrate that the P. caudatum telomerase RNA can participate in telomere synthesis when expressed in the P. tetraurelia macronucleus, despite 24% primary sequence divergence of the RNAs between the two species. De novo telomeric repeats from transformants indicate that P. tetraurelia telomerase fidelity is dramatically affected by template substitutions and that misincorporation at a single templating position is likely to account for the majority of P. tetraurelia telomeric DNA variability. Furthermore, we show that fidelity is not solely a function of the RNA moiety, as the P. caudatum telomerase RNA does not impart high fidelity to the chimeric enzyme.     

Microinjection of plasmid DNA encoding the A surface antigen of Paramecium tetraurelia restores the ability to regenerate a wild-type macronucleus.

Strain d48 of Paramecium tetraurelia contains the A i-antigen gene in the micronucleus, but the gene is lost when micronuclear products develop into the macronucleus. It has recently been shown that when injected into d48, macronucleoplasm from the wild type transforms d48 cells to wild type. It is shown here that wild-type cytoplasm can also bring about transformation, with a marked stage-specific sensitivity for both donor and recipient. It was also found that a plasmid containing the cloned A gene could transform d48 to wild type. Injection of nucleoplasm from animals in the vegetative stage of the cell cycle into the cytoplasm of recipients at various stages of autogamy caused high-frequency transformation of cells able to express the A serotype both before and after the next autogamy. Injection of nucleoplasm into vegetative macronuclei produced over 70% transformants able to express the A serotype after the next autogamy. The ability of nucleoplasm to transform was acquired at the second cell cycle after autogamy and was maintained throughout the vegetative stage. When cytoplasm was obtained from donors during autogamy and injected into the cytoplasm of recipients 1 to 2 h after the sensitive period, quite high frequencies of stable revertants were found when tested both before and after the next autogamy. Cells that were injected into the macronucleus with the cloned A plasmid expressed the A serotype after five fissions in over 20% of the lines and maintained this ability through successive fissions; all transformants except one stably expressed the A serotype even after the next autogamy.     

The Role of Macronuclear DNA Sequences in the Permanent Rescue of a Non-Mendelian Mutation in Paramecium Tetraurelia

The Paramecium tetraurelia mutant called d48 has a complete copy of the A surface protein gene in its micronuclei, but lacks the A gene in the macronucleus. Previous experiments have shown that microinjection of a plasmid containing the entire A gene or a large portion of the gene into the macronucleus of d48 rescued the cell line after formation of a new macronucleus (autogamy). Here we show that several different regions of the A gene can rescue d48, but 100% of the activity cannot be localized to a single, defined region. Inversion of a sequence contained within an A gene plasmid had no measurable effect on rescue efficiency and co-injection of two different plasmids results in enhancement of rescue activity despite the non-contiguous form of the DNA sequences. Both these results suggest that no specific product (RNA or protein) with defined end points is made from the rescuing fragment. A unique restriction site was created in the A gene and used to demonstrate that the injected DNA does not serve as a direct template for the synthesis of the new macronuclear DNA. Models to explain the action of the injected DNA are discussed.     

Macronuclear transformation with specific DNA fragments controls the content of the new macronuclear genome in Paramecium tetraurelia.

A previously isolated mutant cell line called d48 contains a complete copy of the A surface antigen gene in the micronuclear genome, but the gene is not incorporated into the macronucleus. Previous experiments have shown that a cytoplasmic factor made in the wild-type macronucleus can rescue the mutant. Recently, S. Koizumi and S. Kobayashi (Mol. Cell. Biol. 9:4398-4401, 1989) observed that injection of a plasmid containing the A gene into the d48 macronucleus rescued the cell line after autogamy. It is shown here that an 8.8-kb EcoRI fragment containing only a portion of the A gene coding region is sufficient for the rescue of d48. The inability of other A gene fragments to rescue the mutant shows that this effect is dependent upon specific Paramecium DNA sequences. Rescue results in restoration of the wild-type DNA restriction pattern in the macronucleus. These results are consistent with a model in which the macronuclear A locus normally makes an additional gene product that is required for correct processing of the micronuclear copy of the A gene.     

Bacteriophage lambda DNA fragments replicate in the Paramecium macronucleus: absence of active copy number control.

We show that bacteriophage lambda DNA fragments microinjected into the macronucleus of the ciliated protozoan Paramecium can replicate as unit-length linear molecules. These linear DNA molecules are substrates for the addition of Paramecium telomeres by an endogenous telomerase. The linear DNA pieces can exist at copy numbers much higher than that of typical endogenous macronuclear chromosomes. We show that the copy number of injected DNA many fissions after microinjection reflects that of the original input copy number, suggesting that active control of copy number does not occur. Instead, the results suggest that injected DNA is replicated once per cell division.     

In vivo linearization and autonomous replication of plasmids containing human telomeric DNA in Aspergillus nidulans

Plasmids containing two inverted 0.6-kb stretches of human telomeric repeats transform Aspergillus nidulans at frequencies characteristic of autonomously replicating vectors. Transformation frequency is not affected when the plasmids are linearized in vitro prior to transformation by cutting between the inverted repeats. Southern analysis reveals the presence of a homogeneous pool of linear plasmid molecules in mycelium of transformants. Addition of the AMA1 plasmid replicator to the telomere-containing plasmids has only a minor effect on transformation. The phenotypic stability of the transformants is low. However, unlike conventional replicative transformants containing AMA1-bearing plasmids, these transformants are prone to spontaneous stabilization which occurs predominantly by conversion of the mutant chromosomal allele of the marker gene to the plasmid-borne allele. The data strongly suggest that telomeric DNA can act as a plasmid replicator. An alternative interpretation is that autonomous replication of linear DNA fragments, in contrast to covalently closed supercoiled molecules, does not require any special replicator sequences.     

Telomeric site position heterogeneity in macronuclear DNA of Paramecium primaurelia.

In Paramecium primaurelia, the macronuclear gene encoding the G surface protein is located near a telomere. In this study, multiple copies of this telomere have been isolated and the subtelomeric and telomeric regions of some of them have been sequenced. The telomeric sequences consist of tandem repeats of the hexanucleotides C4A2 or C3A3. We show that the location where these repeats are added, which we call the telomeric site, is variable within a 0.6-0.8-kb region. These results are discussed in relation with the formation of macronuclear DNA.     

In VivoAddition of Telomeric Repeats to Foreign DNA Generates Extrachromosomal DNAs in the Taxol-Producing FungusPestalotiopsis microspora

Transformation of the taxol-producing filamentous fungusPestalotiopsis microsporawith a plasmid containing the bacterial hygromycin resistance gene fused toAspergillusregulatory sequences resulted in thein vivoformation of extrachromosomal DNAs with telomeric repeats in the majority of transformants. Repeats of the telomeric sequence 5′-TTAGGG-3′ were appended to nontelomeric transforming DNA termini. No fungal sequences other than telomeric repeats were detected in extrachromosomal DNAs. Transformants contained three to six different sizes or conformational forms of extrachromosomal DNAs. The DNAs showed no change in size or internal structure during 6 months of growth with selection, but were lost after 20 days of growth without selection. Transformation of wild-typeP. microsporawith a PCR-amplified extrachromosomal DNA having terminal telomeric repeats produced up to 50-fold more transformants than the original transformation vector. The addition of telomeric repeats to foreign DNA is unusual among fungi and may have important adaptive or developmental implications.     

In vivo linearization and autonomous replication of plasmids containing human telomeric DNA in Aspergillus nidulans

Plasmids containing two inverted 0.6-kb stretches of human telomeric repeats transform Aspergillus nidulans at frequencies characteristic of autonomously replicating vectors. Transformation frequency is not affected when the plasmids are linearized in vitro prior to transformation by cutting between the inverted repeats. Southern analysis reveals the presence of a homogeneous pool of linear plasmid molecules in mycelium of transformants. Addition of the AMA1 plasmid replicator to the telomere-containing plasmids has only a minor effect on transformation. The phenotypic stability of the transformants is low. However, unlike conventional replicative transformants containing AMA1-bearing plasmids, these transformants are prone to spontaneous stabilization which occurs predominantly by conversion of the mutant chromosomal allele of the marker gene to the plasmid-borne allele. The data strongly suggest that telomeric DNA can act as a plasmid replicator. An alternative interpretation is that autonomous replication of linear DNA fragments, in contrast to covalently closed supercoiled molecules, does not require any special replicator sequences. Received: 13 January 1998 / Accepted: 10 June 1998     

Conserved DNA sequences adjacent to chromosome fragmentation and telomere addition sites in Euplotes crassus.

During the formation of a new macronucleus in the ciliate Euplotes crassus, micronuclear chromosomes are reproducibly broken at approximately 10 000 sites. This chromosome fragmentation process is tightly coupled with de novo telomere synthesis by the telomerase ribonucleoprotein complex, generating short linear macronuclear DNA molecules. In this study, the sequences of 58 macronuclear DNA termini and eight regions of the micronuclear genome containing chromosome fragmentation/telomere addition sites were determined. Through a statistically based analysis of these data, along with previously published sequences, we have defined a 10 bp conserved sequence element (E-Cbs, 5'-HATTGAAaHH-3', H = A, C or T) near chromosome fragmentation sites. The E-Cbs typically resides within the DNA destined to form a macronuclear DNA molecule, but can also reside within flanking micronuclear DNA that is eliminated during macronuclear development. The location of the E-Cbs in macronuclear-destined versus flanking micronuclear DNA leads us to propose a model of chromosome fragmentation that involves a 6 bp staggered cut in the chromosome. The identification of adjacent macronuclear-destined sequences that overlap by 6 bp provides support for the model. Finally, our data provide evidence that telomerase is able to differentiate between newly generated ends that contain partial telomeric repeats and those that do not in vivo.     

In vivo generation of linear plasmids with addition of telomeric sequences by Histoplasma capsulatum

Histoplasma capsulatum is a dimorphic pathogenic fungus that is a major cause of respiratory and systemic mycosis. We previously developed a transformation system for Histoplasma and demonstrated chromosomal integration of transforming plasmid sequences. In this study, we describe another Histoplasma mechanism for maintaining transforming DNA i.e. the generation of modified, multicopy linear plasmids carrying DNA from the transforming Escherichia coli plasmid. Under selective conditions, these linear plasmids were stable and capable of retransforming Histoplasma without further modification. In vivo modification of the transforming DNA included duplication of plasmid sequence and telomeric addition at the termini of linear DNA. Apparently Histoplasma telomerase, like that of other organisms such as humans and Tetrahymena, is able to act on non-telomeric substrates. The terminus of a Histoplasma linear plasmid was cloned and shown to contain multiple repeats of GGGTTA, the telomeric repeat unit also found in vertebrates, trypanosomes, and slime moulds.     

Analysis of Paramecium Macronuclear DNA Using Pulsed Field Gel Electrophoresis

.We have analyzed the macronuclear DNA of Paramecium tetraurelia using orthogonal-field-altemation gel electrophoresis. The mean size of the linear macronuclear DNA molecules is approximately 450 kb. Less than 6% of the macronuclear DNA is larger than 800 kb. Using pulse times of 20, 40, 60 and 90 s we show that the macronuclear fragment containing the A type variable surface antigen gene migrates reproducibly as a 320-kb linear DNA. Over the same pulse times we describe the unusual migration of the ribosomal RNA gene (rDNA) of P. tetraurelia. At pulse times of 20 and 40 s the rDNA migrates at limit mobility (300 and 500 kb, respectively) whereas with 60- and 90-s pulse times, 2 components of rDNA are observed; 1 fraction independent of pulse time migrating at limit mobility, and a 2nd component migrating between 100-kb and 400-kb linear markers. Based upon previous electron micrographic studies of Paramecium rDNA as well as data presented here we conclude that the majority of Paramecium rDNA molecules are a circular DNA form.     

Developmentally regulated chromosome fragmentation linked to imprecise elimination of repeated sequences in paramecia

The chromosomes of ciliates are fragmented at reproducible sites during the development of the polyploid somatic macronucleus, but the mechanisms involved appear to be quite diverse in different species. In Paramecium aurelia, the process is imprecise and results in de novo telomere addition at locally heterogeneous positions. To search for possible determinants of chromosome fragmentation, we have studied an ~21-kb fragmentation region from the germ line genome of P. primaurelia. The mapping and sequencing of alternative macronuclear versions of the region show that two distinct multicopy elements, a minisatellite and a degenerate transposon copy, are eliminated by an imprecise mechanism leading either to chromosome fragmentation and the formation of new telomeres or to the rejoining of flanking sequences. Heterogeneous internal deletions occur between short direct repeats containing TA dinucleotides. The complex rearrangement patterns produced vary slightly among genetically identical cell lines, show non-Mendelian inheritance during sexual reproduction, and can be experimentally modified by transformation of the maternal macronucleus with homologous sequences. These results suggest that chromosome fragmentation in Paramecium is the consequence of imprecise DNA elimination events that are distinct from the precise excision of single-copy internal eliminated sequences and that target multicopy germ line sequences by homology-dependent epigenetic mechanisms.     

Isolation of telomeric DNA from the filamentous fungus Podospora anserina and construction of a self-replicating linear plasmid showing high transformation frequency.

It has been previously shown that linear plasmids bearing Tetrahymena telomeric sequences are able to replicate autonomously in the filamentous fungus Podospora anserina (1). However, autonomous replication occurs in only 50-70% of the transformants, suggesting a defect in the recognition of the Tetrahymena telomeric template by the putative P. anserina telomerase so that only a fraction of entering DNA is stabilized into linear extrachromosomal molecules. We have cloned DNA sequences added to the Tetrahymena (T2G4)n ends of the linear plasmid. Nucleotide sequencing showed that these sequences are exclusively composed of T2AG3 repeat units. Hybridization experiments of Bal31 treated DNA showed that T2AG3 repeats are confined within 200 bp in chromosomal P. anserina telomeres. A new plasmid has been constructed so that after linearization, the terminal sequences contain T2AG3 repeats. This linear molecule transforms P. anserina with a high frequency (up to 1.75 x 10(4) transformants/micrograms), autonomous replication occurs in 100% of the transformants and the plasmid copy number is about 2-3 per nucleus. These results underscore the importance of the telomeric repeat nucleotide sequence for efficient recognition as functional telomeric DNA in vivo and provide the first step toward the development of an artificial chromosome cloning system for filamentous fungi.     

Internal micronuclear DNA regions which include sequences homologous to macronuclear telomeres are deleted during development in Tetrahymena

C4A2 repeats are present in multiple clusters in both the macronucleus and micronucleus of Tetrahymena. Although the macronucleus is generated from the micronucleus after sexual conjugation, the repeats are telomeric sequences in the macronucleus but are internally located in the micronucleus (1). This study investigates the fate of the sequences adjacent to the micronuclear C4A2 repeats. Southern blot analyses of 21 C4A2-containing micronuclear clones show that extensive elimination of the adjacent sequences occurs during the formation of the macronucleus. Comparison of one C4A2-containing micronuclear clone with its derived macronuclear segment indicates that approximately 4.5 kb of DNA, which includes the C4A2 repeats and adjacent sequences on both sides is deleted from the macronucleus. The two regions adjoining the deletion are joined together to form a contiguous segment in the macronucleus. This excision of C4A2 repeats and surrounding sequences and the rejoining of the retained segments is probably the mechanism by which all or most of the other C4A2 adjacent sequences are eliminated.     

Cytidine Analogues and Stomatogenic Recovery in Amicronucleate Paramecium tetraurelia and Paramecium jenningsi

Removal of the micronuclei of Paramecium tetraurelia and Paramecium jenningsi by micropipetting generates amicronucleate cell lines. These cell lines go through a period of growth depression for several dozen fissions, but they gradually recover. Amicronucleate cells in the depression period characteristically exhibit abnormal oral development, particularly reduction in the length of the buccal cavity and an abnormal pattern of the oral membranelles. To test the notion that the macronucleus is involved in the recovery of amicronucleate cell lines, DNA demethylation drugs were administered to amicronucleates in the depression period. After at least 4 fissions, the treated amicronucleates were assessed for their progress in recovery by scoring the proportion of cells with normal oral membranelles. Cvtidine analogues which demethylate cytosine specifically at the 5 position, namely 5-azacytidine, 5-aza-2'- deoxycytidine and 5-fluoro-2'-deoxycytidine. promoted recovery of the amicronucleates. Cytidine, 6-azacytidine, 2'-fluoro-2'-deoxy-cytidine and cytosine-β-D-arabinofuranoside did not. These results suggest that (i) 5-methylcytosine is present in the macronucleus of these Paramecium species, probably in small amounts and (ii) recovery of amicronucleates involves demethylation of macronuclear DNA. This implies that in normal cells the micronuclei are involved in maintaining the macronuclear DNA in a methylated state and hence the inactivation of the macronuclear sequences that are to be employed for stomatogenic recovery. A general mechanism for the control of gene expression may therefore be employed for the regulation of specific sequences.