Tec2, a second transposon-like element demonstrating developmentally programmed excision in Euplotes crassus

New Insights into the Macronuclear Development in Ciliates

During macronuclear differentiation in ciliated protozoa, most amazing "DNA gymnastics" takes place, which includes DNA excision, DNA elimination, DNA reorganization, and DNA-specific amplification. Although the morphological events occurring during macronuclear development are well described, a detailed knowledge of the molecular mechanisms and the regulation of this differentiation process is still missing. However, recently several models have been proposed for the molecular regulation of macronuclear differentiation, but these models have yet to be verified experimentally. The scope of this review is to summarize recent discoveries in different ciliate species and to compare and discuss the different models proposed. Results obtained in these studies are not only relevant for our understanding of nuclear differentiation in ciliates, but also for cellular differentiation in eukaryotic organisms in general as well as for other disciplines such as bioinformatics and computational biology.

Identification of a novel "chromosome scaffold" protein that associates with Tec elements undergoing en masse elimination in Euplotes crassus

During macronuclear development in the ciliate Euplotes crassus, the highly repetitive, transposon-like Tec elements possess an unusual chromatin structure. We observed that the Tec element chromatin is highly resistant to salt extraction and behaves like a nuclear matrix/chromosome scaffold-associated structure. Standard matrix/scaffold extraction procedures identified two major proteins: 1) an ~140-kDa protein that seems to be topoisomerase II based on its reactivity with anti-topoisomerase II antibodies, and 2) an 85-kDa protein that we further purified by acid extraction and have shown to be a novel protein by sequence analysis of its gene. The 85-kDa protein (p85) is a developmental stage-specific protein and is located exclusively in the developing macronucleus. Immunolocalization studies of p85 show that it colocalizes with topoisomerase II in chromatin. In addition, in situ hybridization combined with immunofluorescence localization of the proteins indicates that 100% of the Tec elements colocalize with 70% of the p85, whereas no significant colocalization with a total macronuclear sequence-specific probe is observed. p85 is the first developmental stage-specific protein identified as being specifically associated with sequences undergoing elimination in E. crassus.

Genome remodeling in ciliated protozoa

The germline genomes of ciliated protozoa are dynamic structures, undergoing massive DNA rearrangement during the formation of a functional macronucleus. Macronuclear development involves chromosome fragmentation coupled with de novo telomere synthesis, numerous DNA splicing events that remove internal segments of DNA, and, in some ciliates, the reordering of scrambled gene segments. Despite the fact that all ciliates share similar forms of DNA rearrangement, there appears to be great diversity in both the nature of the rearranged DNA and the molecular mechanisms involved. Epigenetic effects on rearrangement have also been observed, and recent work suggests that chromatin differentiation plays a role in specifying DNA segments either for rearrangement or for elimination.

Differentiation of chromatin during DNA elimination in Euplotes crassus

In Euplotes crassus, most of the micronuclear genome is eliminated during formation of a transcriptionally active macronucleus. To understand how this is mediated throughout the genome, we have examined the chromatin structure of the macronucleus-destined sequences and Tec transposons, which are dispersed in 15,000 copies in the micronuclear genome and completely eliminated during formation of the macronuclear genome. Whereas the macronucleus-destined sequences show a typical pattern of nucleosomal repeats in micrococcal nuclease digests, the Tec element chromatin structure digests to a nucleosome-like repeat pattern that is not typical: the minimum digestion products are approximately 300-600 base pairs, or "subnucleosomal," in size. In addition, the excised, circular forms of the Tec elements are exceedingly resistant to nucleases. Nevertheless, an underlying nucleosomal structure of the Tec elements can be demonstrated from the size differences between repeats in partial micrococcal nuclease digests and by trypsin treatment of nuclei, which results in mononucleosome-sized products. Characterization of the most micrococcal nuclease-resistant DNA indicates that micronuclear telomeres are organized into a chromatin structure with digestion properties identical to those of the Tec elements in the developing macronucleus. Thus, these major repetitive sequence components of the micronuclear genome differ in their chromatin structure from the macronuclear-destined sequences during DNA elimination. The potential role of developmental stage-specific histone variants in this chromatin differentiation is discussed.

A mutation in the flanking 5'-TA-3' dinucleotide prevents excision of an internal eliminated sequence from the Paramecium tetraurelia genome

The germline chromosomes in Paramecium and other ciliated protozoa contain regions of DNA that are excised and eliminated during the development of a new macronuclear genome. Paramecium tetraurelia internal eliminated sequences (IESs) are invariably flanked by a 5'-TA-3' dinucleotide sequence that is part of a larger 8-bp terminal inverted-repeat consensus sequence. Both features, the absolutely conserved 5'-TA-3' and the remaining 6-bp terminal inverted repeat, are shared with the mariner/Tc1 class of transposons. In this article we describe a mutant cell line (AIM-2) defective in excision of a single IES from the coding region of the A51 surface antigen gene. Excision of the 370-bp IES6649 is prevented by a single A to G transition in the invariably conserved 5'-TA-3' dinucleotide. Failure to excise IES6649 also revealed a 29-bp IES located inside IES6649. Additional experiments with the previously isolated AIM-1 mutant, which also contains an internal IES, shows that alternate excision using the wild-type end of IES2591 with an end from the internal IES is extremely rare or nonexistent. These results indicate that IESs are discrete elements whose excision depends upon nucleotides located within the consensus sequence, but also suggest that additional information is required to match one end of an IES with its excision partner.

A mutation in Paramecium tetraurelia reveals functional and structural features of developmentally excised DNA elements

The excision of internal eliminated sequences (IESs) from the germline micronuclear DNA occurs during the differentiation of a new macronuclear genome in ciliated protozoa. In Paramecium, IESs are generally short (28-882 bp), AT rich DNA elements that show few conserved sequence features with the exception of an inverted-terminal-repeat consensus sequence that has similarity to the ends of mariner/Tcl transposons (KLOBUTCHER and HERRICK 1995). We have isolated and analyzed a mutant cell line that cannot excise a 370-bp IESs (IES2591) from the coding region of the 51A variable surface protein gene. A single micronuclear C to T transition within the consensus sequence prevents excision. The inability to excise IES259 I has revealed a 28-bp IES inside the larger IES, suggesting that reiterative integration of these elements can occur. Together, the consensus sequence mutation and the evidence for reiterative integration support the theory that Paramecium IESs evolved from transposable elements. Unlike a previously studied Paramecium IES, the presence of this IES in the macronucleus does not completely inhibit excision of its Mild-type micronuclear copy through multiple sexual generations.

Conjugation-specific genes in the ciliate Euplotes crassus: gene expression from the old macronucleus

Following mating or conjugation, the hypotrichous ciliate Euplotes crassus undergoes a massive genome reorganization process. While the nature of the rearrangement events has been well studied, little is known concerning proteins that carry out such processes. As a means of identifying such proteins, differential screening of a developmental cDNA library, as well as construction of a cDNA subtraction library, was used to isolate genes expressed only during sexual reproduction. Five different conjugation-specific genes have been identified that are maximally expressed early in conjugation, during the period of micronuclear meiosis, which is just prior to macronuclear development and the DNA rearrangement process. All five genes are retained in the mature macronucleus. Micronuclear, macronuclear, and cDNA clones of one gene (conZA7) have been sequenced, and the results indicate that the gene encodes a putative DNA binding protein. In addition, the presence of an internal eliminated sequence in the micronuclear copy of the conZA7 gene indicates that this conjugation-specific gene is transcribed from the old macronucleus.

Accumulation of telomerase RNA and telomere protein transcripts during telomere synthesis in Euplotes

In the ciliate Euplotes crassus a complex series of developmental events lead to formation of a new macronucleus. Millions of telomeres are synthesized during this process. We have shown that transcript levels are tightly regulated throughout Euplotes conjugation and macronuclear development. Thus, expression of gene products needed for macronuclear development and telomere synthesis appears to be controlled at the level of RNA abundance. To learn more about the role played by telomerase and the Euplotes telomere protein during telomere synthesis, we have correlated changes in the abundance of telomerase RNA and telomere protein mRNA transcript with specific developmental events. Telomerase RNA levels increase steadily during the early stages of macronuclear development and reach a peak just after telomere addition. The telomere protein transcript rises and falls twice during conjugation and then rises again at the time of telomere addition. The increases in transcript levels during conjugation parallel micronuclear division suggesting that the telomere protein is synthesized at this time and hence may have a micronuclear function.

Structures of the Euplotes crassus Tec1 and Tec2 elements: identification of putative transposase coding regions

The Tec1 and Tec2 transposon-like element families of Euplotes crassus are highly unusual in that all 30,000 copies of each family are excised from the genome during a discrete time period of macronuclear development. Complete nucleotide sequences were generated for the Tec1-1 and Tec2-1 elements, representing the Tec1 and Tec2 families. Open reading frames (ORFs) are conserved in position and sequence between the two elements, although sequences that comprise one ORF (ORF2) of Tec1-1 are split into two overlapping ORFs (ORFs 2A and 2B) in Tec2-1. ORF1 in Tec1-1, its homolog in Tec2-1 and one of the overlapping ORFs from Tec2-1 (ORF2B) contain TGA codons, which may be translated as Cys, as observed for two other Euplotid genes. Sequence analyses of ORFs from other members of each element family indicate that the families are distinct from each other and are highly conserved within each family. Computer searches of sequence databases have revealed sequence similarity between Tec ORF1s and the previously described Tc1-IS630 family of transposases which includes ORFs from bacterial, nematode and insect transposons.

Developmentally controlled genomic rearrangements in ciliated protozoa

The ciliated protozoa undergo an extensive genome reorganization during the course of forming a transcriptionally active macronucleus. The process includes numerous chromosome fragmentation and DNA breakage and rejoining events. Recent work indicates that transposable elements play a role in the process.