Differential replication and DNA elimination in the polytene chromosomes of Euplotes crassus.

The transposon-like Tec elements of Euplotes crassus are precisely excised during formation of polytene chromosomes in the developing macronucleus. To determine whether all Tec elements exhibit identical developmental timing of excision, we used polymerase chain reaction to visualize amplification and diminution at numerous randomly selected Tec insertion sites. Two classes of sites are evident. Early replicating sites show one or more rounds of amplification and diminution (corresponding to excision) and frequently occur within macronuclear-destined sequences. Late replicating sites do not undergo diminution until chromosome fragmentation and are predominantly associated with eliminated sequences. We conclude that the previously described clustering of macro-nuclear-destined sequences in the micronuclear genome allows for their differential replication at the polytene stage and results in targeting of these sequences for transcriptional activation and highly specific deletion and chromosome fragmentation processes.

DNA rearrangements in Euplotes crassus coincide with discrete periods of DNA replication during the polytene chromosome stage of macronuclear development.

Macronuclear development in Euplotes crassus begins with polytenization of micronuclear chromosomes and is accompanied by highly precise excision of DNA sequences known as internal eliminated sequences and transposon-like elements (Tecs). Quantitation of radiolabeled-precursor incorporation into DNA indicates that DNA synthesis during formation of polytene chromosomes is not continuous and occurs during two distinct periods. We demonstrate that the timing of Tec excision coincides with these replication periods and that excision can occur during both periods even at a single locus. We also show that Tec and internal eliminated sequence excisions are coincident in the second replication period, thus providing further evidence for similarity in their excision mechanism. Inhibition of DNA synthesis with hydroxyurea diminishes Tec element excision, indicating that replication is an important aspect of the excision process.

Developmentally regulated, low abundance Tec element transcripts in Euplotes crassus--implications for DNA elimination and transposition.

During macromolecular development in the ciliated protozoan, Euplotes crassus, > 105 Tec elements are precisely eliminated from the genome in a 2-4 h time interval, generating extrachromosomal circular forms of the elements. Various models have proposed a transposition-based mechanism for this excision. We have tested this hypothesis by determining the abundance of transcripts of Tec element open reading frames (ORFs) and the timing of their appearance. Transcripts are very low in abundance and are only detected by PCR amplification techniques. Thus, the low levels of transcripts argue against the participation of element-encoded functions in the Tec element elimination process. The element transcripts are only detected in RNA samples from mated cells, indicating that the micronucleus and/or developing macronucleus are transcriptionally active during the sexual phase of the life cycle. The transcription detected could allow a low level of germline-specific transposition for these elements.

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.