Extrachromosomal ribosomal RNA genes in Tetrahymena: structure and evolution

Identifying and distinguishing sibling species in the Tetrahymena pyriformis complex (Ciliophora, Oligohymenophorea) using PCR/RFLP analysis of nuclear ribosomal DNA

We describe a riboprinting strategy for identifying and distinguishing among sibling species in the Tetrahymena pyriformis complex. It involves use of the polymerase chain reaction to amplify a large segment of the nuclear ribosomal DNA and internal transcribed spacers, and digestion of this DNA with restriction enzymes. Unique restriction fragment length patterns or haplotypes were then used to distinguish species into: (1) six taxa that were identifiable to the species level, (2) eight taxa that were separated into four pairs, and (3) a group of eight taxa that were identical to each other. The latter result indicates that a more variable molecule is needed to distinguish the most closely related species in the complex. There was no intraspecific variation between two strains from one species (Tetrahymena thermophila) nor among multiple isolates from another species (Tetrahymena empidokyrea). This approach provides an alternative to traditional techniques for identifying T. pyriformis species that require living reference specimens and/or that reveal high levels of intraspecific variation.

The DNA of ciliated protozoa

Ciliates contain two types of nuclei: a micronucleus and a macronucleus. The micronucleus serves as the germ line nucleus but does not express its genes. The macronucleus provides the nuclear RNA for vegetative growth. Mating cells exchange haploid micronuclei, and a new macronucleus develops from a new diploid micronucleus. The old macronucleus is destroyed. This conversion consists of amplification, elimination, fragmentation, and splicing of DNA sequences on a massive scale. Fragmentation produces subchromosomal molecules in Tetrahymena and Paramecium cells and much smaller, gene-sized molecules in hypotrichous ciliates to which telomere sequences are added. These molecules are then amplified, some to higher copy numbers than others. rDNA is differentially amplified to thousands of copies per macronucleus. Eliminated sequences include transposonlike elements and sequences called internal eliminated sequences that interrupt gene coding regions in the micronuclear genome. Some, perhaps all, of these are excised as circular molecules and destroyed. In at least some hypotrichs, segments of some micronuclear genes are scrambled in a nonfunctional order and are recorded during macronuclear development. Vegetatively growing ciliates appear to possess a mechanism for adjusting copy numbers of individual genes, which corrects gene imbalances resulting from random distribution of DNA molecules during amitosis of the macronucleus. Other distinctive features of ciliate DNA include an altered use of the conventional stop codons.

Self-splicing of the Tetrahymena pre-rRNA is decreased by misfolding during transcription

RNA processing depends in part on the ability of nascent transcripts to fold into the desired conformation. Self-splicing of the group I intron from Tetrahymena was used to assess the folded state of preribosomal RNA transcripts when synthesized in vitro. A simple method for isolating nondenatured RNA from a T7 RNA polymerase reaction was tested. The intron alone is fully active when transcribed at 30 degrees C, suggesting that the active structure is both kinetically and thermodynamically favored. Longer precursor RNAs, however, were less than completely active in self-splicing. Full activity, as judged by both the initial rate and the extent of product formation, was restored by brief incubation at 95 degrees C and rapid cooling in the presence of magnesium ion. This result did not depend on the length of the precursor RNA in any simple way, but correlated loosely with the presence of intact exon domains. When transcribed in the absence of cellular proteins, a significant portion of the pre-RNA appears to be trapped in a conformation that does not readily undergo the first step of splicing.

Inheritance of the group I rDNA intron in Tetrahymena pigmentosa

We have previously argued from phylogenetic sequence data that the group I intron in the rRNA genes of Tetrahymena was acquired by different Tetrahymena species at different times during evolution. We have now approached the question of intron mobility experimentally by crossing intron+ and intron- strains looking for a strong polarity in the inheritance of the intron (intron homing). Based on the genetic analysis we find that the intron in T. pigmentosa is inherited as a neutral character and that intron+ and intron- alleles segregate in a Mendelian fashion with no sign of intron homing. In an analysis of vegetatively growing cells containing intron+ and intron- rDNA, initially in the same macronucleus, we similarly find no evidence of intron homing. During the course of this work, we observed to our surprise that progeny clones from some crosses contained three types of rDNA. One possible explanation is that T. pigmentosa has two rdn loci in contrast to the single locus found in T. thermophila. Some of the progeny clones from the genetic analysis were expanded for several hundred generations, and allelic assortment of the rDNA was demonstrated by subcloning analysis.

DNA elimination and its relation to quantities in the macronucleus of Tetrahymena

The macronucleus of Tetrahymena contains a large number of DNA molecules of subchromosomal size. They belong to about 270 species each one occurring at an average number of 45 copies. Macronuclei divide unequally and nothing is known of segregation control. This and the elimination and degradation of DNA during macronuclear amitosis make the clonal stability of macronuclei a problem of qualitative and quantitative control on a subchromosomal level. We studied the contribution of DNA elimination to the quantitative composition of the macronucleus cytophotometrically in single cells of different strains. This was done under standard conditions and under conditions known to influence the amount of macronuclear DNA. The following results were found: Elimination of DNA occurs at almost every division. The size of the elimination body is highly variable but still positively correlated with the macronuclear DNA content. In T. thermophila the amount of eliminated DNA is 2.5% of the G2 content and is not dependent on the growth state. It varies with species, amounting to as much as 8% in T. pigmentosa. During conditions which increase the macronuclear DNA content, very little DNA is eliminated. On the other hand, large amounts are eliminated under other conditions causing the macronuclear DNA content to decrease. DNA to be eliminated at division is synthesized at the same time as bulk DNA. We developed a computer program which helps us study the effects of DNA elimination and unequal divisions upon the copy numbers of subchromosomal DNA classes.(ABSTRACT TRUNCATED AT 250 WORDS)

Short inverted repeats at a free end signal large palindromic DNA formation in Tetrahymena

Large palindromic DNAs are formed in many cell types, but their molecular mechanism is unknown. During nuclear differentiation in Tetrahymena, the ribosomal RNA genes (rDNA) are converted from a single integrated copy to an extrachromosomal head-to-head palindrome. Using in vitro mutagenesis and Tetrahymena transformation, we show that two properties of the rDNA are necessary and sufficient for palindrome formation. The first is a pair of 42 bp inverted repeats found at the rDNA's 5' end. Its inverted symmetry, but not specific sequence, is important. The second is a free end next to the repeats. It is normally created by chromosome breakage in vivo, but can also be provided by restriction endonuclease cutting before transformation. We also demonstrate that the ability to form palindromes is not restricted to developing nuclei, but is present in vegetative cells as well. This process may represent a general mechanism for palindrome formation in eukaryotes.

Complete sequence of the extrachromosomal rDNA molecule from the ciliate Tetrahymena thermophila strain B1868VII

The recent development of rDNA vectors for transformation of Tetrahymena combined with improved microinjection technology should lead to a renewed interest in this organism. In particular, the rDNA itself constitutes an attractive system for biochemical studies. The rDNA is amplified to a level of 2% of the total DNA and exists as extrachromosomal molecules. Furthermore, the rDNA is homogeneous in sequence because it is derived from a single gene during sexual reorganization. In order to facilitate studies of this molecule, we report here a compilation of previously published sequence information together with new sequence data that completes the entire sequence of the 21 kb rDNA molecule.

The controlling sequence for site-specific chromosome breakage in Tetrahymena

Site-specific chromosome breakage occurs in many ciliated protozoa during nuclear differentiation. We have determined the cis-acting sequence that controls this process in Tetrahymena thermophila. The Tetrahymena ribosomal RNA gene is bounded by two breakage sites. Injection of this gene into developing macronuclei leads to breakage at these sites. Deletion analysis has localized the sequences essential for breakage to a 28 bp region that includes a 15 bp sequence (Cbs) known to be present in other breakage sites. Insertions of Cbs allow breakage to occur at new sites, which is accompanied by elimination of surrounding DNAs and formation of telomeric sequences, as it is at natural sites. Thus, Cbs is the necessary and sufficient sequence signal for chromosome breakage in Tetrahymena.

The replication advantage of a free linear rRNA gene is restored by somatic recombination in Tetrahymena thermophila

The autonomously replicating rRNA genes (rDNA) in the somatic nucleus of Tetrahymena thermophila are maintained at a copy number of approximately 10(4) per nucleus. A mutant in which the replication properties of this molecule were altered was isolated and characterized. This mutation of inbred strain C3, named rmm4, was shown to have the same effect on rDNA replication and to be associated with the same 1-base-pair (bp) deletion as the previously reported, independently derived rmm1 mutation (D. L. Larson, E. H. Blackburn, P. C. Yaeger, and E. Orias, Cell 47:229-240, 1986). The rDNA of inbred strain B, which is at a replicational disadvantage compared with wild-type C3 rDNA, has a 42-bp deletion. This deletion is separated by 25 bp from the 1-bp deletion of rmm4 or rmm1. Southern blot analysis and DNA sequencing revealed that during prolonged vegetative divisions of C3-rmm4/B-rmm heterozygotes, somatic recombination produced rDNAs lacking both the rmm4-associated deletion and the 42-bp deletion. In somatic nuclei in which this rare recombinational event had occurred, all 10(4) copies of nonrecombinant rDNA were eventually replaced by the recombinant rDNA. The results prove that each of the two deletions is the genetic determinant of the observed replication disadvantage. We propose that the analysis of somatically recombinant rDNAs can be used as a general method in locating other mutations which affect rDNA propagation in T. thermophilia.

A mobile group I intron in the nuclear rDNA of Physarum polycephalum

We have shown that a strain-specific group I intron (intron 3) in the nuclear extrachromosomal rDNA or Physarum polycephalum is a mobile element. Shortly after mating of amoebae from intron-lacking and intron-containing strains, intron 3 transposes in a site-specific manner into all available recipient molecules. The transposition appears to occur by gene conversion, as evidence by the co-conversion of adjacent sequences and by double strand breakage observed in some of the recipient rDNA molecules. We infer that the double strand break is induced by an endonuclease encoded by intron 3, since in vitro transcription and translation of the cloned intron leads to the synthesis of an enzymatically active, site-specific nuclease. This is the first demonstration of the transposition of a nuclear intron in an experimental setting, and provides a rare example of a protein encoded by an RNA polymerase I transcript.

Recombination occurs during telomere formation in yeast

Short stretches of cloned telomeric sequences are necessary and sufficient for telomere formation in yeast as long as the sequences are present in the same orientation as they are found in vivo. During telomere formation, DNA termini usually undergo RAD52-independent recombination with other DNA termini as would be predicted by models of recombination-mediated telomere replication.

The replication advantage of a free linear rRNA gene is restored by somatic recombination in Tetrahymena thermophila

The autonomously replicating rRNA genes (rDNA) in the somatic nucleus of Tetrahymena thermophila are maintained at a copy number of approximately 10(4) per nucleus. A mutant in which the replication properties of this molecule were altered was isolated and characterized. This mutation of inbred strain C3, named rmm4, was shown to have the same effect on rDNA replication and to be associated with the same 1-base-pair (bp) deletion as the previously reported, independently derived rmm1 mutation (D. L. Larson, E. H. Blackburn, P. C. Yaeger, and E. Orias, Cell 47:229-240, 1986). The rDNA of inbred strain B, which is at a replicational disadvantage compared with wild-type C3 rDNA, has a 42-bp deletion. This deletion is separated by 25 bp from the 1-bp deletion of rmm4 or rmm1. Southern blot analysis and DNA sequencing revealed that during prolonged vegetative divisions of C3-rmm4/B-rmm heterozygotes, somatic recombination produced rDNAs lacking both the rmm4-associated deletion and the 42-bp deletion. In somatic nuclei in which this rare recombinational event had occurred, all 10(4) copies of nonrecombinant rDNA were eventually replaced by the recombinant rDNA. The results prove that each of the two deletions is the genetic determinant of the observed replication disadvantage. We propose that the analysis of somatically recombinant rDNAs can be used as a general method in locating other mutations which affect rDNA propagation in T. thermophilia.

Comparison of ribosomal and isozymic phylogenies of tetrahymenine ciliates

A recent analysis of sequence variations in ribosomal RNA's from 31 species of tetrahymenine ciliates groups them into 9 sets referred to as "ribosets." These species associations are not well correlated with the distributions of distinctive morphological characteristics. The phylogenetic structure suggests that modern "pyriform" tetrahymenines may be paraphyletic survivors of primitive design and that the morphologically distinctive forms may include examples of convergent evolution of derived forms. Alternatively, the common ancestor may have been a polymorphic species that has lost its plasticity in some derived lineages. In an attempt to test the ribosomal phylogeny, we here compare it with a phylogeny based on isozymic variation. The main features of the ribosomal and isozymic phylogenies are similar. The carnivorous (macrostome-forming) species are widely scattered in both, as are the bacteriophagous pyriform species. Isozymic and ribosomal analyses are optimally useful, however, in different contexts. Isozymic variations can distinguish species that are ribosomally identical. Ribosomal variations provide more secure evaluations of distant relationships.

Transformation of Tetrahymena thermophila with hypermethylated rRNA genes

The extrachromosomal rRNA genes (rDNA) of Tetrahymena thermophila contain 0.4% N6-methyladenine. C3 strain rDNA was isolated, hypermethylated in vitro, and microinjected into B strain host cells. Clonal cell lines were established, and transformants were selected on the basis of resistance to paromomycin, conferred by the injected rDNA. The effects of methylation by three enzymes which methylate the sequence 5'-NAT-3', the dam, EcoRI, and ClaI methylases, were tested. Hypermethylation of the injected rDNA had no effect on transformation efficiency relative to mock-methylated controls. The injected C3 strain rDNA efficiently replaced host rDNA as the major constituent of the population of rDNA molecules. Hypermethylation of the injected DNA was not maintained through 20 to 25 cell generations.

Transformation of Tetrahymena thermophila with hypermethylated rRNA genes

The extrachromosomal rRNA genes (rDNA) of Tetrahymena thermophila contain 0.4% N6-methyladenine. C3 strain rDNA was isolated, hypermethylated in vitro, and microinjected into B strain host cells. Clonal cell lines were established, and transformants were selected on the basis of resistance to paromomycin, conferred by the injected rDNA. The effects of methylation by three enzymes which methylate the sequence 5'-NAT-3', the dam, EcoRI, and ClaI methylases, were tested. Hypermethylation of the injected rDNA had no effect on transformation efficiency relative to mock-methylated controls. The injected C3 strain rDNA efficiently replaced host rDNA as the major constituent of the population of rDNA molecules. Hypermethylation of the injected DNA was not maintained through 20 to 25 cell generations.

rRNA genes of Naegleria gruberi are carried exclusively on a 14-kilobase-pair plasmid

An extrachromosomal DNA was discovered in Naegleria gruberi. The 3,000 to 5,000 copies per cell of this 14-kilobase-pair circular plasmid carry all the 18S, 28S, and 5.8S rRNA genes. The presence of the ribosomal DNA of an organism exclusively on a circular extrachromosomal element is without precedent, and Naegleria is only the third eucaryotic genus in which a nuclear plasmid DNA has been found.

rRNA genes of Naegleria gruberi are carried exclusively on a 14-kilobase-pair plasmid

An extrachromosomal DNA was discovered in Naegleria gruberi. The 3,000 to 5,000 copies per cell of this 14-kilobase-pair circular plasmid carry all the 18S, 28S, and 5.8S rRNA genes. The presence of the ribosomal DNA of an organism exclusively on a circular extrachromosomal element is without precedent, and Naegleria is only the third eucaryotic genus in which a nuclear plasmid DNA has been found.

Phylogenetic evidence for the acquisition of ribosomal RNA introns subsequent to the divergence of some of the major Tetrahymena groups

Previous work has demonstrated the presence of a self-splicing intron in the large subunit ribosomal RNA coding region in some strains of the ciliate protozoan Tetrahymena. Sequence comparisons of the intron regions from six Tetrahymena species showed these to fall into three homology groups. In an attempt to evaluate the evolutionary origins of the intervening sequences, we have now determined complete small subunit ribosomal RNA gene sequences from 13 species of Tetrahymena and the absolute number of nucleotide differences between the sequences was used to construct a phylogenetic tree. This phylogeny was consistent with the groupings suggested by comparisons of other biochemical characters including cytoskeletal proteins, isozyme analyses, and restriction maps of complete rRNA transcription units. The homology groupings that were based upon the intron sequence data do not agree with the relationships inferred from the small subunit rRNA sequence data. These observations are taken to indicate that the intron character has been acquired independently in different species at a stage later than the branching out of the species.

Control of rDNA replication in Tetrahymena involves a cis-acting upstream repeat of a promoter element

A novel genetic scheme was used to isolate mutants altered in the formation or maintenance of amplified rDNA in the Tetrahymena macronucleus. One such mutant had a cis-acting rDNA mutation that affected the ability of mutant rDNA molecules to replicate in macronuclei in the presence of a wild-type (B strain) rDNA. The mutant rDNA was lost from these heterozygous macronuclei during vegetative cell divisions, although it was maintained normally in the homozygous or hemizygous state. In contrast, wild-type macronuclear rDNA of the C3 strain used to obtain the mutant outreplicated B strain rDNA in B/C3 heterozygote macronuclei. Sequence differences were found between wild-type B and C3 and mutant C3 rDNAs in the replication origin region, changing an upstream repeat of a highly conserved rRNA promoter element. We propose that the various rDNA alleles differentially compete for limiting amounts of trans-acting factors that bind to these enhancer-like repeats and positively regulate rDNA replication.

Transformation of Tetrahymena thermophila by microinjection of ribosomal RNA genes

The ribosomal RNA genes (rDNA) of Tetrahymena thermophila macronucleus exist as free linear 21-kilobase molecules that contain replication origins and telomeres. A mutation in this gene confers resistance to the antibiotic paromomycin. We have isolated rDNA from such a mutant (strain p2f), microinjected it into the macronucleus of a sensitive strain, and obtained drug-resistant cells at a frequency of 1-3%. The transformed cells have a distinct and stable phenotype. The rDNA of the transformants contains the expected sequences of the mutant rDNA as determined by oligonucleotide hybridization. rDNA from a different inbred line (C3-368), which contains heteromorphic restriction sites, has also been used for injection, and the results confirm the fact that the injected rDNA is indeed present in the transformants. Injection of rDNA from the C3 strains also increases the transformation frequency 5- to 10-fold and leads to the total replacement of the resident rDNA of the B-inbred strains. This is presumably due to the replication dominance of rDNA from the C3 strains over that of the B strains. Using this method, we have also been able to transform developing cells, at similar frequencies, by microinjecting into the macronuclear anlagen.

The 5S and 5.8S ribosomal RNA sequences of Tetrahymena thermophila and T. pyriformis

The nucleotide sequences of the 5S rRNAs of Tetrahymena thermophila and two strains of T. pyriformis have been determined to be identical. The 5.8S rRNA sequences have also been determined; these sequences correct several errors in an earlier report. The 5.8S rRNAs of the two species differ at a single position. The sequencing results indicate that the species are of recent common ancestry. Molecular evidence that has been interpreted in the past as suggestive of an ancient divergence has been reviewed and found to be consistent with a T. pyriformis complex radiation beginning approximately 30-40 million years ago.

Sequence comparison of the rDNA introns from six different species of Tetrahymena

We have studied the sequence variation of the rDNA intron among six species of Tetrahymena. From these data, the intron appears to be relatively well conserved in evolution. We have evaluated the sequence variations among the most distant of these species in relation to the secondary structure model for the intron RNA of Cech et al. (Proc. Natl. Acad. Sci. U.S.A. 80, 3903 (83)). Most of the sequence variation in the four new sequences reported here is found in single stranded loops in the model. However, in four cases we found nucleotide substitutions in duplex stem regions, two of them involving compensating base pair changes. Interestingly, one of these is found in a region that is known to be dispensable in the in vitro splicing reaction suggesting differences between the in vivo and in vitro reactions. One of the single nucleotide deletions is found in the so-called "internal guide sequence" which has been implicated in the alignment process during splicing. In conclusion, none of the observed natural sequence variations are in disfavor of the proposed secondary structure model.

Updating rDNA restriction enzyme maps of Tetrahymena reveals four new intron-containing species

The extrachromosomal rDNA molecules from a number of Tetrahymena strains were characterized by restriction enzyme mapping using three different restriction enzymes combined with gel blotting and hybridization analysis. Strains from four out of six recently described species were found to contain an intron in the 26s rRNA coding region. The evolutionary relationship among the species of the T. pyriformis complex was examined on the basis of the rDNA maps with emphasis on similarities between two of the new species and the widely studied T. thermophila and T. pigmentosa. Examination of a large number of T. pigmentosa strains showed this species to exhibit an unusual polymorphism with respect to its rDNA. It is suggested that recombinational cross-over events play a role in the formation of new rDNA alleles in this species.

Functional intron+ and intron- rDNA in the same macronucleus of the ciliate Tetrahymena pigmentosa

Diallelic clones of Tetrahymena pigmentosa containing equal amounts of intron+ and intron- rDNA in the macronucleus were constructed. The macronucleus of the resulting strains divides amitotically during vegetative growth and the diallelic genotype is therefore unstable. The coexistence of the two alleles was followed in the total culture and in single cells during their vegetative segregation and it was observed that replication was non-preferential with respect to the two alleles. The diallelic clones were also used to demonstrate that intron-containing rDNA was transcribed and the transcript processed in the presence of corresponding intron- rDNA. The results are discussed in the light of the 'non-function' idea for ribosomal RNA introns.

Conserved arrangements of repeated DNA sequences in nontranscribed spacers of ciliate ribosomal RNA genes: evidence for molecular coevolution

We have analyzed the nucleotide sequences of the nontranscribed spacer (NTS) and transcription initiation and termination regions of the extrachromosomal rDNAs of the ciliated protozoans Tetrahymena thermophila and Glaucoma chattoni. The sequences surrounding the sites of transcription initiation and termination are highly conserved. The only extensive homologies of the NTS regions occur in five sets of dispersed repetitive sequences. Type I, II and III repeats in the 5' NTS are strongly conserved in sequence between Tetrahymena and Glaucoma in the case of the type I and III repeats, and in location relative to the transcription initiation site in the case of type I and II repeats. We identify two new repeat types, designated IV and V, in the 3' NTS. The sequence of type IV repeats, and the location relative to the transcription termination site of type IV and V repeats, are conserved. All five types of repeats are interspersed with nonconserved DNA sequences. These results suggest that the five repeat types in the 5' and 3' NTSs are important in rRNA gene function; the sequence organization, and the differing rates of divergence between species of the repeat types, provide strong evidence for their functional selection through the process of molecular coevolution.

DNA sequences of telomeres maintained in yeast

Telomeres, the ends of eukaryotic chromosomes, have long been recognized as specialized structures. Their stability compared with broken ends of chromosomes suggested that they have properties which protect them from fusion, degradation or recombination. Furthermore, a linear DNA molecule such as that of a eukaryotic chromosome must have a structure at its ends which allows its complete replication, as no known DNA polymerase can initiate synthesis without a primer. At the ends of the relatively short, multi-copy linear DNA molecules found naturally in the nuclei of several lower eukaryotes, there are simple tandemly repeated sequences with, in the cases analysed, a specific array of single-strand breaks, on both DNA strands, in the distal portion of the block of repeats. In general, however, direct analysis of chromosomal termini presents problems because of their very low abundance in nuclei. To circumvent this problem, we have previously cloned a chromosomal telomere of the yeast Saccharomyces cerevisiae on a linear DNA vector molecule. Here we show that yeast chromosomal telomeres terminate in a DNA sequence consisting of tandem irregular repeats of the general form C1-3A. The same repeat units are added to the ends of Tetrahymena telomeres, in an apparently non-template-directed manner, during their replication on linear plasmids in yeast. Such DNA addition may have a fundamental role in telomere replication.

Structural organization of the two main rDNA size classes of Ascaris lumbricoides

The two main rDNA size classes in the genome of Ascaris lumbricoides consist of 8.8 kb and 8.4 kb long repeating units present in a quantitative ratio of roughly 10:1. They both contain the genes coding for 18 , 5.8S and 26S ribosomal RNAs. The length heterogeneity is due to a 450 bp long spacer region localized in the longer repeating unit which begins 870 bp upstream of the 5'-end 18S gene. A few additional microheterogeneities in base sequence occur at the 5'-end of the 26S gene. The 18S, 5.8S and 26S coding regions have been mapped on both the 8.8 kb and 8.4 kb repeating units and the localization of the 5'- and 3'-ends of the 18S and 26S genes has been performed by S1 protection. No intervening sequences are present in either coding region of the two main rDNA size classes.

Strong sequence conservation of a 38 bp region near the center of the extrachromosomal rDNA palindrome in different Tetrahymena species

The restriction-endonuclease map and the nucleotide sequence of the central region in the extrachromosomal rDNA palindrome of two micronuclear and one a-micronucleate species of Tetrahymena has been determined. The sequence data show that the different species investigated have a 24 or 26 nucleotide sequence region at the very center of the rDNA molecule which is non-palindromic. Comparison of the present sequence data with the published data of another micronucleate species reveal that a segment of 38 base pairs just outside the non-palindromic center is highly conserved in all the different species, while the rest of the central region show little sequence homology. The relevance of this conserved region to the amplification process of the rDNA molecule is discussed.

Complex endonucleolytic cleavage pattern during early events in the processing of pre-rRNA in the lower eukaryote, Tetrahymena thermophila

We have analysed nuclear RNA from T. thermophila by RNA transfer hybridization using cloned rDNA fragments. A very high number of in vivo intermediates and by-products of rRNA processing were identified. These include putative intermediates of the splicing process and alternative products resulting from temporal variability in various endonucleolytic cleavages. In addition, four small RNA species including only transcribed spacer sequences were detected. These are (1) the IVS RNA (approximately 400 bases), the by-product of the splicing process, (2) a fragment from the internal transcribed spacer (approximately 360 bases), possibly resulting from 3'-end processing of pre-17S rRNA, (3) a fragment comprising most or all of the external transcribed spacer (approximately 600 bases) obviously representing the major by-product of 5'-end processing, and, in addition, (4) a small fragment from the initiation region (approximately 230 bases) which might be a product of premature transcription termination.

Autocatalytic cyclization of an excised intervening sequence RNA is a cleavage-ligation reaction

The intervening sequence (IVS) of the Tetrahymena ribosomal RNA precursor is excised as a linear RNA molecule which subsequently cyclizes itself in a protein-independent reaction. Cyclization involves cleavage of the linear IVS RNA 15 nucleotides from its 5' end and formation of a phosphodiester bond between the new 5' phosphate and the original 3'-hydroxyl terminus of the IVS. This recombination mechanism is analogous to that by which splicing of the precursor RNA is achieved. The circular molecules appear to have no direct function in RNA splicing, and we propose the cyclization serves to prevent unwanted RNA from driving the splicing reactions backwards.

Self-splicing RNA: autoexcision and autocyclization of the ribosomal RNA intervening sequence of Tetrahymena

In the macronuclear rRNA genes of Tetrahymena thermophila, a 413 bp intervening sequence (IVS) interrupts the 26S rRNA-coding region. A restriction fragment of the rDNA containing the IVS and portions of the adjacent rRNA sequences (exons) was inserted downstream from the lac UV5 promoter in a recombinant plasmid. Transcription of this template by purified Escherichia coli RNA polymerase in vitro produced a shortened version of the pre-rRNA, which was then deproteinized. When incubated with monovalent and divalent cations and a guanosine factor, this RNA underwent splicing. The reactions that were characterized included the precise excision of the IVS, attachment of guanosine to the 5' end of the IVS, covalent cyclization of the IVS and ligation of the exons. We conclude that splicing activity is intrinsic to the structure of the RNA, and that enzymes, small nuclear RNAs and folding of the pre-rRNA into an RNP are unnecessary for these reactions. We propose that the IVS portion of the RNA has several enzyme-like properties that enable it to break and reform phosphodiester bonds. The finding of autocatalytic rearrangements of RNA molecules has implications for the mechanism and the evolution of other reactions that involve RNA.

The intervening sequence of the ribosomal RNA gene is highly conserved between two Tetrahymena species

The entire intervening sequence of Tetrahymena thermophila ribosomal DNA has been determined. It is 413 nucleotides long and has the same splice junctions as those in T. pigmentosa. There is 93% homology between the intervening sequences in the two species, and 100% homology between their adjacent 26S RNA coding regions.

The nucleotide sequence at the transcription termination site of the ribosomal RNA gene in Tetrahymena thermophila

The sequence of 415 nucleotides surrounding the transcription termination site for ribosomal RNA in Tetrahymena thermophila has been determined. The positions of the 3'-ends of mature 26S rRNA, pre-26S rRNA and 35S pre-rRNA were localized within this sequence by hybridization of the purified RNA species to be selected DNA fragments, followed by S1 nuclease treatment of the hybrid and a precise sizing of the RNA-protected DNA fragments on sequencing gels. The 35S pre-rRNA population contained molecules with two distinct 3'-ends, one of which is identical to the end of pre-26S and 26S rRNA, while the other corresponds to a position 15 nucleotides further downstream, which is assumed to be the transcription termination site. The non-coding DNA strand contains a cluster of T's at the putative termination site, and several other T clusters are found further downstream. A short inverted repeat sequence is located near the putative termination site within the transcribed region. The possible role of these structures for transcription termination is discussed.

Nucleotide sequence of the ribosomal RNA gene of Physarum polycephalum: intron 2 and its flanking regions of the 26S rRNA gene

The 26S ribosomal RNA gene of Physarum polycephalum is interrupted by two introns, and we have previously determined the sequence of one of them (intron 1) (Nomiyama et al. Proc.Natl.Acad.Sci.USA 78, 1376-1380, 1981). In this study we sequenced the second intron (intron 2) of about 0.5 kb length and its flanking regions, and found that one nucleotide at each junction is identical in intron 1 and intron 2, though the junction regions share no other sequence homology. Comparison of the flanking exon sequences to E. coli 23S rRNA sequences shows that conserved sequences are interspersed with tracts having little homology. In particular, the region encompassing the intron 2 interruption site is highly conserved. The E. coli ribosomal protein L1 binding region is also conserved.

An electron microscopic analysis of transcription of nucleolar chromatin isolated from Tetrahymena pyriformis

Transcriptionally active nucleoli and solubilized nucleolar chromatin were visualized by electron microscopy. The palindromic structure of the chromatin was demonstrated by spreading the chromatin on glow-discharged grids. In the presence of single-strand binding EcoHDP protein the preribosomal RNA transcripts are seen attached to the RNA-polymerase molecules in the electron micrographs. Each palindrome contains two preribosomal RNA genes. THe strict termination properties of the transcription are indicated by the absence of transcriptional complexes in the distal parts of the molecules. - Investigation of the process of transcription in nucleolar chromatin being depleted of a termination protein by ammonium sulfate-treatment showed in agreement with biochemical studies that only some of the RNA polymerases terminate properly while other transcribe into the distal spacer region. The elongation rate is estimated to be slightly lower than in the gene region. The results are discussed in relation to biochemical studies of the transcriptional properties of the chromatin.

Two distinct intervening sequences in different ribosomal DNA repeat units of Sciara coprophila

We have prepared a partial gene library of sheared DNA from the fungus fly, Sciara coprophila, by dA-T tailing and insertion into pBR322. Two ribosomal DNA clones which differ from the usual ribosomal DNA organization in this organism were studied in detail. Clone pBc 1L-1 has an intervening sequence of 1.4 kb, and clone pBc 6D-6 has an intervening sequence of 0.9 kb. These intervening sequences occur in about the same position in 28S rDNA, but do not appear to share sequence homology with one another. Previously we found that 90% of Sciara ribosomal DNA is homogenous and lacks an intervening sequence, and our present data explains the size heterogeneity found in most of the remaining 10%. We have found no evidence of size heterogeneity in the nontranscribed spacer.

Replication of the extrachromosomal ribosomal RNA genes of Tetrahymena thermophilia

Cultures of Tetrahymena thermophila were deprived of nutrients and later refed with enriched medium to obtain partial synchrony of DNA replication. Preferential replication of the extrachromosomal, macronuclear ribosomal RNA genes (rDNA) was found to occur at 40-80 min after refeeding. The rDNA accounted for one half of the label incorporated into cellular DNA during this period. Electron microscopy of the purified rDNA showed 1% replicative intermediates. Their structure was that expected for bidirectional replication of the linear rDNA from an origin or origins located in the central nontranscribed region of the palindromic molecule. Similar forms had previously been observed for the rDNA of a related species, Tetrahymena pyriformis. The electron microscopic data was consistent with an origin of replication located approximatley 600 base pairs from the center of the rDNA of T. thermophila, in contrast to a more central location in the rDNA of T. pyriformis. One implication of an off-center origin of replication is that there are two such sequences per palindromic molecule.

Nuclease-sensitive regions on the extrachromosomal r-chromatin from Tetrahymena pyriformis

The extrachromosomal DNA coding for the ribosomal precursor in Tetrahymena contains a transcribed region with a size of 6 x 10(3) base pairs plus non-transcribed central and distal spacers. In the present study the chromatin structure of the transcribed region and the terminal spacer have been compared. Micrococcal nuclease and DNase I were used to investigate the nucleosomal and the higher order structures. The specific DNA fragments were visualized by gel electrophoresis, Southern blotting onto nitrocellulose sheets and hybridization with specific 32P-labelled RNA probes. Investigations of the cleavage patterns demonstrate the presence of a defined nucleosomal structure in the non-transcribed region, while there is no indication of a nucleosomal pattern in the transcribed region. Specific regions on the r-chromatin are hypersensitive to DNase I. The first cleavage occurs in the non-transcribed central spacer region, while the second cleavage takes place in a region near the 3' end. The hypersensitivity of the central part of r-chromatin is also found by autodigestion in isolated nucleoli.

Extrachromosomal rDNA of Tetrahymena thermophila is not a perfect palindrome

We have determined the restriction-endonuclease-cleavage map and the nucleotide sequence of the central 1.4 kb fragment of the macronuclear extrachromosomal rDNA of Tetrahymena thermophila. These data demonstrate that this molecule is not a perfect palindrome, having a 29 bp AT-rich non-palindromic sequence at its center. This observation is important in determining the mechanism by which a single chromosomally integrated rRNA gene in the micronucleus is rearranged and amplified during sexual development to yield multiple copies of extrachromosomal rDNA in the macronucleus.