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.     

The 10 kb Drosophila virilis 28S rDNA intervening sequence is flanked by a direct repeat of 14 base pairs of coding sequence

Most repeat units of rDNA in Drosophila virilis are interrupted in the 28S rRNA coding region by an intervening sequence about 10 kb in length; uninterrupted repeats have a length of about 11 kb. We have sequenced the coding/intervening sequence junctions and flanking regions in two independent clones of interrupted rDNA, and the corresponding 28S rRNA coding region in a clone of uninterrupted rDNA. The intervening sequence is terminated at both ends by a direct repeat of a fourteen nucleotide sequence that is present once in the corresponding region of an intact gene. This is a phenomenon associated with transposable elements in other eukaryotes and in prokaryotes, and the Drosophila rDNA intervening sequence is discussed in this context. We have compared more than 200 nucleotides of the D. virilis 28S rRNA gene with sequences of homologous regions of rDNA in Tetrahymena pigmentosa (Wild and Sommer, 1980) and Xenopus laevis (Gourse and Gerbi, 1980): There is 93% sequence homology among the diverse species, so that the rDNA region in question (about two-thirds of the way into the 28S rRNA coding sequence) has been very highly conserved in eukaryote evolution. The intervening sequence in T. pigmentosa is at a site 79 nucleotides upstream from the insertion site of the Drosophila intervening sequence.     

Conservation of sequences adjacent to the telomeric C4A2 repeats of ciliate macronuclear ribosomal RNA gene molecules.

We sequenced and compared the telomeric regions of linear rDNAs from vegetative macronuclei of several ciliates in the suborder Tetrahymenina. All telomeres consisted of tandemly repeated C4A2 sequences, including the 5' telomere of the 11 kb rDNA from developing macronuclei of Tetrahymena thermophila. Our sequence of the 11 kb 5' telomeric region shows that each one of a previously described pair of inverted repeats flanking the micronuclear rDNA (Yao et al., Mol. Cell. Biol. 5: 1260-1267, 1985) is 29 bp away from the positions to which telomeric C4A2 repeats are joined to the ends of excised 11 kb rDNA. In general we found that the macronuclear rDNA sequences adjacent to C4A2 repeats are not highly conserved. However, in the non-palindromic rDNA of Glaucoma, we identified a single copy of a conserved sequence, repeated in inverted orientation in Tetrahymena spp., which all form palindromic rDNAs. We propose that this sequence is required for a step in rDNA excision common to both Tetrahymena and Glaucoma.     

An unusual fibrillarin gene and protein: structure and functional implications.

The diploid germinal nucleus of the ciliated protozoan Tetrahymena thermophila is unusual among eukaryotes in that it encodes a single copy of the gene for rRNA allowing identification of cis-acting mutations in rDNA affecting rRNA structure, function, and processing. The generally conserved nucleolar protein fibrillarin has been characterized from a number of systems and is involved in pre-rRNA processing. We have demonstrated that Tetrahymena has fibrillarin and have analyzed the cDNA and the genomic DNA encoding this protein. The derived amino acid sequence of the N-terminal region of Tetrahymena fibrillarin shows little similarity with the generally highly conserved glycine/arginine-rich N-terminal domain of other eukaryotic fibrillarins. The remainder of the amino acid sequence of the molecule is more conserved. Polyclonal antibodies generated against the full-length Tetrahymena fibrillarin expressed in bacteria recognize a protein of M(r) approximately 32,000 in whole-cell or nucleolar preparations. Immunocytochemistry localizes fibrillarin to nucleoli in the somatic macronuclei of vegetative cells. Transformation experiments demonstrate that fibrillarin is an essential protein in Tetrahymena. The Tetrahymena fibrillarin is expressed but does not complement a NOP1 null mutation when transformed into the yeast Saccharomyces cerevisiae, indicating less functional conservation among fibrillarins than previously suggested.     

DNaseI-hypersensitive sites at promoter-like sequences in the spacer of Xenopus laevis and Xenopus borealis ribosomal DNA.

We have detected a DNAseI hypersensitive site in the ribosomal DNA spacer of Xenopus laevis and Xenopus borealis. The site is present in blood and embryonic nuclei of each species. In interspecies hybrids, however, the site is absent in unexpressed borealis rDNA, but is present normally in expressed laevis rDNA. Hypersensitive sites are located well upstream (over lkb) of the pre-ribosomal RNA promoter. Sequencing of the hypersensitive region in borealis rDNA, however, shows extensive homology with the promoter sequence, and with the hypersensitive region in X. laevis. Of two promoter-like duplications in each spacer, only the most upstream copy is associated with hypersensitivity to DNAaseI. Unlike DNAaseI, Endo R. MspI digests the rDNA of laevis blood nuclei at a domain extending downstream from the hypersensitive site to near the 40S promoter. Since the organisation of conserved sequence elements within this "proximal domain" is similar in three Xenopus species whose spacers have otherwise evolved rapidly, we conclude that this domain plays an important role in rDNA function.     

Introns and their flanking sequences of Bombyx mori rDNA.

We obtained two different clones (16 kb and 13 kb) of B. mori rDNA with intron sequence within the 28S-rRNA coding region. The sequence surrounding the intron was found to be highly conserved as indicated in several eukaryotes (Tetrahymena, Drosophila and Xenopus). The 28S rRNA-coding sequence of 16 kb and 13 kb clone was interrupted at precisely the same sites as those where the D. melanogaster rDNA interrupted by the type I and type II intron, respectively. The intron sequences of B. mori were different from those of D. melanogaster. In 16 kb clone, the intron was flanked by 14 bp duplication of the junction sequence, which was also present once within the 28S rRNA-coding region of rDNA without intron. This 14 bp sequence was identical with those surrounding the introns of Dipteran rDNAs.     

Sequence analysis of 28S ribosomal DNA from the amphibian Xenopus laevis.

We have determined the complete nucleotide sequence of Xenopus laevis 28S rDNA (4110 bp). In order to locate evolutionarily conserved regions within rDNA, we compared the Xenopus 28S sequence to homologous rDNA sequences from yeast, Physarum, and E. coli. Numerous regions of sequence homology are dispersed throughout the entire length of rDNA from all four organisms. These conserved regions have a higher A + T base composition than the remainder of the rDNA. The Xenopus 28S rDNA has nine major areas of sequence inserted when compared to E. coli 23S rDNA. The total base composition of these inserts in Xenopus is 83% G + C, and is generally responsible for the high (66%) G + C content of Xenopus 28S rDNA as a whole. Although the length of the inserted sequences varies, the inserts are found in the same relative positions in yeast 26S, Physarum 26S, and Xenopus 28S rDNAs. In one insert there are 25 bases completely conserved between the various eukaryotes, suggesting that this area is important for eukaryotic ribosomes. The other inserts differ in sequence between species and may or may not play a functional role.     

Microinjected Tetrahymena rDNA ends are not recognized as telomeres in Xenopus eggs

Telomeres are essential structures that stabilize the ends of eukaryotic chromosomes and allow complete replication of linear DNA molecules. We examined the structure and replication of telomeres by observing the fate of the linear extrachromosomal rDNA of Tetrahymena after injection into unfertilized Xenopus eggs. The rDNA replicated efficiently as a linear extrachromosomal molecule, increasing in mass 30-50-fold by 15-20 h after injection. In addition, the molecules increased in length by addition of up to several kilobases of DNA to their termini. Sequence analysis demonstrated that the added DNA bore no resemblance to known telomeres. The junction between the rDNA and added DNA was apparently random, indicating that the addition reaction did not involve a site-specific recombination or integration event. Surprisingly, Southern blot analysis showed that the added DNA did not derive from Xenopus DNA, but rather from co-purifying and therefore co-injected Tetrahymena DNA. The nonspecific ligation of random DNA fragments to the rDNA termini suggests that microinjected Tetrahymena rDNA ends are not recognized as telomeres in Xenopus eggs.     

Cloning yeast telomeres on linear plasmid vectors

We have constructed a linear yeast plasmid by joining fragments from the termini of Tetrahymena ribosomal DNA to a yeast vector. Structural features of the terminus region of the Tetrahymena rDNA plasmid maintained in the yeast linear plasmid include a set of specifically placed single-strand interruptions within the cluster of hexanucleotide (C4A2) repeat units. An artificially constructed hairpin terminus was unable to stabilize a linear plasmid in yeast. The fact that yeast can recognize and use DNA ends from the distantly related organism Tetrahymena suggests that the structural features required for telomere replication and resolution have been highly conserved in evolution. The linear plasmid was used as a vector to clone chromosomal telomeres from yeast. One Tetrahymena end was removed by restriction digestion, and yeast fragments that could function as an end on a linear plasmid were selected. Restriction mapping and hybridization analysis demonstrated that these fragments were yeast telomeres, and suggested that all yeast chromosomes might have a common telomere sequence. Yeast telomeres appear to be similar in structure to the rDNA of Tetrahymena, in which specific nicks or gaps are present within a simple repeated sequence near the terminus of the DNA.     

An rRNA variable region has an evolutionarily conserved essential role despite sequence divergence.

Regions extremely variable in size and sequence occur at conserved locations in eukaryotic rRNAs. The functional importance of one such region was determined by gene reconstruction and replacement in Tetrahymena thermophila. Deletion of the D8 region of the large-subunit rRNA inactivates T. thermophila rRNA genes (rDNA): transformants containing only this type of rDNA are unable to grow. Replacement with an unrelated sequence of similar size or a variable region from a different position in the rRNA also inactivated the rDNA. Mutant rRNAs resulting from such constructs were present only in precursor forms, suggesting that these rRNAs are deficient in either processing or stabilization of the mature form. Replacement with D8 regions from three other organisms restored function, even though the sequences are very different. Thus, these D8 regions share an essential functional feature that is not reflected in their primary sequences. Similar tertiary structures may be the quality these sequences share that allows them to function interchangeably.     

Evolutionary Conservation of Sequences Directing Chromosome Breakage and Rdna Palindrome Formation in Tetrahymenine Ciliates

Extensive, programmed chromosome breakage occurs during formation of the somatic macronucleus of ciliated protozoa. The cis-acting signal directing breakage has been most rigorously defined in Tetrahymena thermophila, where it consists of a 15-bp DNA sequence known as Cbs, for chromosome breakage sequence. We have identified sequences identical or nearly identical to the T. thermophila Cbs at sites of breakage flanking the germline micronuclear rDNA locus of six additional species of Tetrahymena as well as members of two related genera. Other general features of the breakage site are also conserved, but surprisingly, the orientation and number of copies of Cbs are not always conserved, suggesting the occurrence of germline rearrangement events over evolutionary time. At one end of the T. thermophila micronuclear rDNA locus, a pair of short inverted repeats adjacent to Cbs directs the formation of a giant palindromic molecule. We have examined the corresponding sequences from two other Tetrahymena species. We find the sequence to be partially conserved, as previously implied from analysis of macronuclear rDNA, but of variable length and organization.     

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.     

Two separate regions of the extrachromosomal ribosomal deoxyribonucleic acid of Tetrahymena thermophila enable autonomous replication of plasmids in Saccharomyces cerevisiae.

Plasmids containing the nontranscribed central and terminal, but not the coding, regions of the extrachromosomal ribosomal deoxyribonucleic acid (rDNA) of Tetrahymena thermophila are capable of autonomous replication in Saccharomyces cerevisiae. These plasmids transform S. cerevisiae at high frequency; transformants are unstable in the absence of selection, and plasmids identical to those used for transformation were isolated from the transformed yeast cells. One plasmid contains a 1.85-kilobase Tetrahymena DNA fragment which includes the origin of bidirectional replication of the extrachromosomal rDNA. The other region of Tetrahymena rDNA allowing autonomous replication of plasmids in S. cerevisiae is a 650-base pair, adenine plus thymine-rich segment from the rDNA terminus. Neither of these Tetrahymena fragments shares obvious sequence homology with the origin of replication of the S. cerevisiae 2-microns circle plasmid or with ars1, an S. cerevisiae chromosomal replicator.     

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.     

Amplification of tandemly repeated origin control sequences confers a replication advantage on rDNA replicons in Tetrahymena thermophila.

The macronuclear rRNA genes (rDNA) in the ciliate Tetrahymena thermophila are normally palindromic linear replicons, containing two copies of the replication origin region in inverted orientation. A circular plasmid containing a single Tetrahymena rRNA gene (one half palindrome) joined to a tandem repeat of a 1.9-kilobase (kb) rDNA segment encompassing the rDNA replication origin and known replication control elements was used to transform Tetrahymena macronuclei by microinjection. This plasmid was shown previously to have a replication advantage over the rDNA allele of the recipient cell strain (G.-L. Yu and E. H. Blackburn, Proc. Natl. Acad. Sci. USA 86:8487-8491, 1990). During vegetative cell divisions, the circular and palindromic rDNAs were rapidly replaced by novel, successively longer linear rDNAs that eventually contained up to 30 tandem 1.9-kb repeats, resulting from homologous but unequal crossovers between the 1.9-kb repeats. We present evidence to show that increasing the number of copies of the replication control regions increases the replicative advantage of the rDNA, the first such situation for a cellular nuclear replicon in a eucaryote.     

A single integrated gene for ribosomal RNA in a eucaryote, Tetrahymena pyriformis.

The macronucleus of the protozoan, Tetrahymena, is known to contain multiple rRNA genes which are not linked to the chromosomes. Here we present evidence that the germinal micronucleus of this organism contains a single gene for rRNA integrated into the chromosomal DNA. Unlike the extrachromosomal copies of the macronucleus, which are composed of a pair of reversely repeated sequences (a palindrome), the integrated copy of rDNA is nonrepetitive or half the size of the extrachromosomal rDNA. Furthermore, we have failed to detect such an integrated copy of rDNA in the macronucleus. The implications of these observations for the amplification and evolution of rDNA are discussed.     

High frequency vector-mediated transformation and gene replacement in Tetrahymena.

Recently, we developed a mass DNA-mediated transformation technique for the ciliated protozoan Tetrahymena thermophila that introduces transforming DNA by electroporation into conjugating cells. Other studies demonstrated that a neomycin resistance gene flanked by Tetrahymena H4-I gene regulatory sequences transformed Tetrahymena by homologous recombination within the H4-I locus when microinjected into the macronucleus. We describe the use of conjugant electrotransformation (CET) for gene replacement and for the development of new independently replicating vectors and a gene cassette that can be used as a selectable marker in gene knockout experiments. Using CET, the neomycin resistance gene flanked by H4-I sequences transformed Tetrahymena, resulting in the replacement of the H4-I gene or integrative recombination of the H4-I/neo/H4-I gene (but not vector sequences) in the 5' or 3' flanking region of the H4-I locus. Gene replacement was obtained with non-digested plasmid DNA but releasing the insert increased the frequency of replacement events about 6-fold. The efficiency of transformation by the H4-I/neo/H4-I selectable marker was unchanged when a single copy of the Tetrahymena rDNA replication origin was included on the transforming plasmid. However, the efficiency of transformation using CET increased greatly when a tandem repeat of the replication origin fragment was used. This high frequency of transformation enabled mapping of the region required for H4-I promoter function to within 333 bp upstream of the initiator ATG. Similarly approximately 300 bp of sequence downstream of the translation terminator TGA of the beta-tubulin 2 (BTU2) gene could substitute for the 3' region of the H4-I gene. This hybrid H4-I/neo/BTU2 gene did not transform Tetrahymena when subcloned on a plasmid lacking an origin of replication, but did transform at high frequency on a two origin plasmid. Thus, the H4-I/neo/BTU2 cassette is a selectable marker that can be used for gene knockout in Tetrahymena. As a first step toward constructing a vector suitable for cloning genes by complementation of mutations in Tetrahymena, we also demonstrated that the vector containing 2 origins and the H4-I/neo/BTU2 cassette can co-express a gene encoding a cycloheximide resistant ribosomal protein.     

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.