Developmentally programmed excision of internal DNA sequences in Paramecium aurelia

The development of a new somatic nucleus (macronucleus) during sexual reproduction of the ciliate Paramecium aurelia involves reproducible chromosomal rearrangements that affect the entire germline genome. Macronuclear development can be induced experimentally, which makes P. aurelia an attractive model for the study of the mechanism and the regulation of DNA rearrangements. Two major types of rearrangements have been identified: the fragmentation of the germline chromosomes, followed by the formation of the new macronuclear chromosome ends in association with imprecise DNA elimination, and the precise excision of internal eliminated sequences (IESs). All IESs identified so far are short, A/T rich and non-coding elements. They are flanked by a direct repeat of a 5'-TA-3' dinucleotide, a single copy of which remains at the macronuclear junction after excision. The number of these single-copy sequences has been estimated to be around 60,000 per haploid genome. This review focuses on the current knowledge about the genetic and epigenetic determinants of IES elimination in P. aurelia, the analysis of excision products, and the tightly regulated timing of excision throughout macronuclear development. Several models for the molecular mechanism of IES excision will be discussed in relation to those proposed for DNA elimination in other ciliates.     

Developmentally programmed excision of internal DNA sequences in Paramecium aurelia

The development of a new somatic nucleus (macronucleus) during sexual reproduction of the ciliate Paramecium aurelia involves reproducible chromosomal rearrangements that affect the entire germline genome. Macronuclear development can be induced experimentally, which makes P. aurelia an attractive model for the study of the mechanism and the regulation of DNA rearrangements. Two major types of rearrangements have been identified: the fragmentation of the germline chromosomes, followed by the formation of the new macronuclear chromosome ends in association with imprecise DNA elimination, and the precise excision of internal eliminated sequences (IESs). All IESs identified so far are short, A/T rich and non-coding elements. They are flanked by a direct repeat of a 5’-TA-3’ dinucleotide, a single copy of which remains at the macronuclear junction after excision. The number of these single-copy sequences has been estimated to be around 60 000 per haploid genome. This review focuses on the current knowledge about the genetic and epigenetic determinants of IES elimination in P. aurelia, the analysis of excision products, and the tightly regulated timing of excision throughout macronuclear development. Several models for the molecular mechanism of IES excision will be discussed in relation to those proposed for DNA elimination in other ciliates.     

Cloning and sequence analysis of the micronuclear and macronuclear gene encoding Rab protein of Euplotes octocarinatus

The DNA in a micronucleus undergoes remarkable rearrangements when it develops into a macronucleus after cell mating in the hypotrichous ciliate. A Rab gene was isolated from the macronuclear plasmid mini-library of Euplotes octocarinatus. A micronuclear version of the Rab gene was amplified by polymerase chain reaction (PCR). The macronuclear DNA molecule carrying the Rab gene is 767 bp long and shows characteristics typical of macronuclear chromosomes of hypotrichous ciliates. Three of the five cysteines are encoded by the opal codon UGA. The deduced protein is a 207-amino acid (aa) with a molecular mass of 23 kDa. The protein shares 36% identity with Rab 1 protein of Plasmodium and yeast. Analysis of the sequences indicated that the micronuclear version of the Rab gene contains two internal eliminated sequences, internal eliminated sequence (IES)1 and IES2. IES1 is flanked by a pair of hepta-nucleotide 5'-AAATTTT-3' direct repeats, and IES2 is flanked by 5'-TA-3' direct repeats.     

Internal eliminated sequences are removed prior to chromosome fragmentation during development in Euplotes crassus.

The hypotrichous ciliated protozoa undergo a massive genome rearrangement process after their sexual cycle. One frequent type of rearrangement is the removal of DNA sequences (internal eliminated sequences; IESs) from internal regions of DNA molecules. In this study, we characterized the removal of IESs in Euplotes crassus. Southern hybridization analyses combined with cytological observations indicated that IES removal is an early event in macronuclear development, occurring during the polytene chromosome stage and prior to the chromosome fragmentation process. The results are consistent with IES removal occurring via an intramolecular DNA breakage and rejoining process.     

The processing of macronuclear-destined DNA sequences microinjected into the macronuclear anlagen of the hypotrichous ciliate Stylonchia lemnae.

We describe the construction of a vector carrying the micronuclear versions of two macronuclear DNA molecules, one of which was modified by the insertion of a polylinker sequence. This vector was injected into the polytene chromosomes of the developing macronucleus of Stylonychia and its processing during further macronuclear development and its fate in the mature macronucleus were analyzed. In up to 30% of injected cells the modified macronuclear DNA sequence could be detected. While the internal eliminated sequences (IES) present in the macronuclear precursor DNA sequence are still retained in the mature macronucleus, the modified macronuclear DNA sequence is correctly cut out from the vector, telomeres are added de novo and it is stably retained in the macronucleus during vegetative growth of the cells. This vector system represents an experimental system that allows the identification of DNA sequences involved in the processing of macronuclear DNA sequences during macronuclear development.     

Detection of circular forms of eliminated DNA during macronuclear development in E. crassus

Following their sexual cycle, hypotrichous ciliated protozoa transform a copy of a chromosomal micronucleus into a macronucleus containing small, linear DNA molecules. A frequent event during macronuclear development is the removal of short segments of DNA (internal eliminated sequences: IESs) by a process equivalent to DNA breakage and rejoining. In this study we used a polymerase chain reaction procedure to demonstrate that free circular forms of IESs are present in cells undergoing macronuclear development. Sequencing of the junctions of the free circular IESs suggests that they share 12 nucleotides with the macronuclear DNA molecules that are generated following IES removal. The results provide evidence that IESs are removed by an active DNA breakage and rejoining process, which may involve staggered cuts in the substrate DNA.     

Invention and Mystery in Hypotrich DNA1

ABSTRACT “The capacity to blunder slightly is the real marvel of DNA. Without this special attribute, we would still be anaerobic bacteria and there would be no music.” Lewis Thomas³ Hypotrichs have evolved extraordinary ways of organizing, manipulating, and replicating the DNA in their micronuclear and macronuclear genomes. Short macronuclear DNA molecules containing single genes are created by excision from chromosomes, accompanied by massive elimination of the germline DNA sequences between genes. Germline genes themselves are interrupted by multiple noncoding segments called internal eliminated segments, or IESs, that divide genes into multiple macronuclear-destined segments, or MDSs. The functional significance of this organization is unknown. Over evolutionary time IESs accumulate mutations rapidly are inserted into or excised from genes, and shift position along DNA molecules. MDSs are ligated to create functional genes when IESs are spliced out of micronuclear DNA during macronuclear development. MDSs in some germline genes are in scrambled disorder and become unscrambled in association with IES elimination. Replication of DNA in the macronucleus is accomplished by organization of replication enzymes and factors into a structure that sweeps through the macronucleus to replicate the many millions of gene-sized DNA molecules. The significance of many of the bizarre DNA phenomena in the evolutionary/functional success of hypotrichs is still unclear.     

Timing of developmentally programmed excision and circularization of Paramecium internal eliminated sequences

Paramecium internal eliminated sequences (IESs) are short AT-rich DNA elements that are precisely eliminated from the germ line genome during development of the somatic macronucleus. They are flanked by one 5'-TA-3' dinucleotide on each side, a single copy of which remains at the donor site after excision. The timing of their excision was examined in synchronized conjugating cells by quantitative PCR. Significant amplification of the germ line genome was observed prior to IES excision, which starts 12 to 14 h after initiation of conjugation and extends over a 2- to 4-h period. Following excision, two IESs were shown to form extrachromosomal circles that can be readily detected on Southern blots of genomic DNA from cells undergoing macronuclear development. On these circular molecules, covalently joined IES ends are separated by one copy of the flanking 5'-TA-3' repeat. The similar structures of the junctions formed on the excised and donor molecules point to a central role for this dinucleotide in IES excision.     

Analysis of micronuclear, macronuclear and cDNA sequences encoding the regulatory subunit of cAMP-dependent protein kinase of Euplotes octocarinatus: evidence for a ribosomal frameshift

We have isolated and characterized the micronuclear gene encoding the regulatory subunit of cAMP-dependent protein kinase of the ciliated protozoan Euplotes octocarinatus, as well as its macronuclear version and the corresponding cDNA. Analyses of the sequences revealed that the micronuclear gene contains one small 69-bp internal eliminated sequence (IES) that is removed during macronuclear development. The IES is located in the 5'-noncoding region of the micronuclear gene and is flanked by a pair of tetranucleotide 5'-TACA-3' direct repeats. The macronuclear DNA molecule carrying this gene is approximately 1400 bp long and is amplified to about 2000 copies per macronucleus. Sequence analysis suggests that the expression of this gene requires a +1 ribosomal frameshift. The deduced protein shares 31% identity with the cAMP-dependent protein kinase type I regulatory subunit of Homo sapiens, and 53% identity with the regulatory subunit R44 of one of the two cAMP-dependent protein kinases of Paramecium. In addition, it contains two highly conserved cAMP binding sites in the C-terminal domain. The putative autophosphorylation site ARTSV of the regulatory subunit of E. octocarinatus is similar to that of the regulatory subunit R44 of Paramecium but distinct from the consensus motif RRXSZ of other eukaryotic regulatory subunits of cAMP-dependent protein kinases.     

Macronuclear and micronuclear configurations of a gene encoding the protein synthesis elongation factor EF 1α in Stylonychia lemnae

The micronuclear and macronuclear configurations of a gene encoding the protein synthesis elongation factor EF 1 alpha in the hypotrich ciliate Stylonychia lemnae were compared. The two sequences are generally colinear. The coding sequence of the micronuclear gene is, however, interrupted by a 64 bp insert flanked by a 2 bp direct repeat in a gene region which is moderately conserved among EF 1 alpha genes of different organisms. The insertion site is distinct from known intron positions in eukaryotic EF 1 alpha genes. The insert sequence shows inverted repeats at its ends and thus exhibits typical features of an internal eliminated sequence (IES). Comparison with other such sequences in the related organism Oyxtricha nova shows that the IES falls into a new group of such elements. The macronuclear gene exhibits a strikingly limited codon usage, which cannot be simply explained by the overall base composition of the DNA but probably also relates to the very high copy number of the macronuclear gene and the putative high amount of the gene product.     

Processing of double-strand breaks is involved in the precise excision of paramecium internal eliminated sequences

In ciliates, the development of the somatic macronucleus involves the programmed excision of thousands of internal eliminated sequences (IES) scattered throughout the germ line genome. Previous work with Tetrahymena thermophila has suggested that excision is initiated by a staggered double-strand break (DSB) at one IES end. Nucleophilic attack of the other end by the 3'OH group carried by the firstly broken chromosome end leads to macronuclear junction closure. In this study, we mapped the 3'OH and 5'PO(4) groups that are developmentally released at Paramecium IES boundaries, which are marked by two conserved TA dinucleotides, one of which remains in the macronuclear genome after excision. We show that initiating DSBs at both ends generate 4-base 5' overhangs centered on the TA. Based on the observed processing of the 5'-terminal residue of each overhang, we present a new model for the precise closure of macronuclear chromosomes in Paramecium tetraurelia, different from that previously proposed for tetrahymena. In our model, macronucleus-destined broken ends are aligned through the partial pairing of their 5'-nTAn-3' extensions and joined after trimming of the 5' flaps.     

snRNA and heterochromatin formation are involved in DNA excision during macronuclear development in stichotrichous ciliates

Several models for specific excision of micronucleus-specific DNA sequences during macronuclear development in ciliates exist. While the template-guided recombination model suggests recombination events resulting in specific DNA excision and reordering of macronucleus-destined sequences (MDS) guided by a template, there is evidence that an RNA interference-related mechanism is involved in DNA elimination in holotrichous ciliates. We describe that in the stichotrichous ciliate Stylonychia, snRNAs homologous to micronucleus-specific sequences are synthesized during macronuclear differentiation. Western and in situ analyses demonstrate that histone H3 becomes methylated at K9 de novo during macronuclear differentiation, and chromatin immunoprecipitation revealed that micronucleus-specific sequences are associated with methylated H3. To link both observations, expression of a PIWI homolog, member of the RNA-induced silencing complex, was silenced. In these cells, the methylated micronucleus-specific histone H3 variant "X" is still present in macronuclear anlagen and no K9 methylation of histone H3 is observed. We suggest that snRNA recruits chromatin-modifying enzymes to sequences to be excised. Based on our and earlier observations, we believe that this mechanism is not sufficient for specific excision of sequences and reordering of MDS in the developing macronucleus and propose a model for internal eliminated sequence excision and MDS reordering in stichotrichous ciliates.     

Preferential cleavage of Paramecium DNA mediated by the C. elegans Tc1 transposase in vitro

In the ciliate Paramecium aurelia complex, thousands of internal eliminated sequences (IESs) are excised from the germline micronuclear DNA during macronuclear differentiation. Based on the resemblance of Paramecium IES end sequences to Tc1 transposon termini, it has been proposed that Paramecium IESs might have degenerately evolved from Tc1 family transposons, and still be removed by an enzyme homologous to a Tc1 transposase. In this study, we found that transposase preferentially cleaved (or nicked) 58 sites near the IESs in Paramecium DNA, at sequences consisting of TT or TCTA. Since one excision junction of the P. primaurelia W2 IES was included in such sites, this suggests that a Tc1-like transposase is involved in the IES excision process, although it is probably not a sole factor responsible for the precise cleavage. In addition, unmethylated substrate DNA appeared to decrease the cleavage specificity, suggesting an involvement of DNA methylation in the cleavage. Although these results do not directly address the transposon origin of Paramecium IESs, it is likely that the enzymatic machinery responsible for the initial cleavage is derived from a Tc1-like transposase. The mechanism necessary for precise excision is discussed, in relation to recent knowledge of IES excision obtained in Tetrahymena and Paramecium.     

Cis-acting requirements in flanking DNA for the programmed elimination of mse2.9: a common mechanism for deletion of internal eliminated sequences from the developing macronucleus of Tetrahymena thermophila

During macronuclear development in the ciliated protozoan Tetrahymena thermophila, extensive DNA deletions occur, eliminating thousands of internal eliminated sequences (IESs). Using an rDNA-based transformation assay we have analyzed the role during DNA deletion of DNA flanking mse2.9, an IES within the second intron of a gene encoding an as yet incompletely characterized protein. We establish that a cis-acting sequence for mse2.9 deletion acts at a distance to specify deletion boundaries. A complex sequence element necessary for efficient and accurate mse2.9 deletion is located in the region 47–81 bp from the right side of mse2.9. The ability of a variety of IES flanking sequences to rescue a processing deficient mse2.9 construct indicates that some cis-acting signal is shared among different IESs. In addition, the short intronic sequence that flanks mse2.9 is able to direct efficient and accurate processing. Despite no obvious sequence similarity between mse2.9 and other IESs, we suggest that a common mechanism is used to delete different families of IESs in Tetrahymena.     

Internal eliminated sequences interrupting the Oxytricha 81 locus: allelic divergence, conservation, conversions, and possible transposon origins

Internal eliminated sequences (IESs) often interrupt ciliate genes in the silent germline nucleus but are exactly excised and eliminated from the developing somatic nucleus from which genes are then expressed. Some long IESs are transposons, supporting the hypothesis that short IESs are ancient transposon relics. In light of that hypothesis and to explore the evolutionary history of a collection of IESs, we have compared various alleles of a particular locus (the 81 locus) of the ciliated protozoa Oxytricha trifallax and O. fallax. Three short IESs that interrupt two genes of the locus are found in alleles from both species, and thus must be relatively ancient, consistent with the hypothesis that short IESs are transposon relics. In contrast, TBE1 transposon interruptions of the locus are allele-specific and probably the results of recent transpositions. These IESs (and the TBE1s) are precisely excised from the DNA of the developing somatic macronucleus. Each IES interrupts a highly conserved sequence. A few nucleotides at the ends of each IES are also conserved, suggesting that they interact critically with IES excision machinery. However, most IES nucleotide positions have evolved at high rates, showing little or no selective constraint for function. Nonetheless, the length of each IES has been maintained (+/- 3 bp). While one IES is approximately 33 bp long, three other IESs have very similar sizes, approximately 70 bp long. Two IESs are surrounded by direct repeats of the sequence TTCTT. No other sequence similarities were found between any of the four IESs. However, the ends of one IES do match the inverted terminal repeat consensus sequence of the "TA" IESs of Paramecium. Three O. trifallax alleles appear to have been recipients in recent conversion events that could have been provoked by double-strand breaks associated with IES ends subsequent to IES transposition. Our findings support the hypothesis that short IESs evolved from ancient transposons that have lost most of their sequences, except those necessary for precise excision during macronuclear development.      

The micronuclear gene encoding a putative aminoacyl-tRNA synthetase cofactor of the ciliate Euplotes octocarinatus is interrupted by two sequences that are removed during macronuclear development.

The micronuclear gene of the ciliated protozoan Euplotes octocarinatus (Eo) syngen 1 encoding the putative aminoacyl-tRNA synthetase cofactor (ARCE), as well as its macronuclear version and the corresponding cDNA, were amplified and sequenced. Analyses of the sequences revealed that the micronuclear gene contains two sequences (430 and 625bp long) that are missing in the macronuclear version of this gene. These sequences are called 'internal eliminated sequences' (IESs) and appear to occur in all ciliates. The two IESs are located in the coding region of the micronuclear gene. One IES is flanked by a pair of dinucleotide 5'-TA-3' direct repeats and the other one by a pair of hepta-nucleotide 5'-TTACTGA-3' direct repeats. Inside the two IESs, several other sequence repeats were found. The macronuclear DNA molecule carrying this gene is 1517bp long and shows characteristics typical of macronuclear chromosomes of hypotrichous ciliates. Copy number determination revealed that the molecule is amplified to only about 750 copies per macronucleus. The deduced protein is a 441-amino-acid (aa) polypeptide with a molecular mass of 50kDa. It shares a conserved endothelial monocyte-activating polypeptide II (EMAP II)-like carboxyl-terminal domain and a hydrophilic central domain containing a KEKE-motif with a group of proteins associated with aminoacyl-tRNA synthetases and tRNAs.