Internal Eliminated Sequences Research Articles

Analysis of a scrambled gene: the gene encoding alpha-telomere-binding protein in Oxytricha nova.

Following cell mating in ciliates, a copy of the micronuclear genome is processed into a new macronucleus through massive cutting, reordering, splicing, elimination, and amplification of the DNA. DNA processing includes the deletion of short interrupting elements called internal eliminated sequences (IESs), followed by the splicing of the remaining segments, known as macronuclear destined sequences (MDSs). The MDSs in some micronuclear genes, such as actin I, are scrambled and must be reordered during IES removal and MDS splicing to yield a functional gene. Here, we describe the cloning, sequencing, and characterization of a different scrambling pattern for the gene that encodes the alpha subunit of the telomere-binding protein of Oxytricha nova. The micronuclear gene is made up of 14 MDSs in the scrambled order 1-3-5-7-9-11-2-4-6-8-10-12-13-14. Only the scrambled version is present in the micronucleus, and only the unscrambled version is present in the macronucleus. We propose that unscrambling occurs by homologous recombination guided by pairs of direct repeats at MDS-IES junctions. The patterned array of scrambling may be a clue to the origin of scrambling in this gene.

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.

High fidelity developmental excision of Ted transposons and internal eliminated sequences inEuplotes crassus

Following the sexual phase of its life cycle, the hypotrichous ciliate Euplotes crassus transforms a copy of its chromosomal micronucleus into a transcriptionally active macronucleus containing short, linear, gene-sized DNA molecules. Tens of thousands of DNA breakage and joining, or splicing, events occur during macronuclear development. The DNA removed by such events includes transposon-like elements, referred to as Tec1 elements, as well as segments of unique sequence DNA, termed internal eliminated sequences (IESs). Both types of elements are bounded by short direct repeats. In the current study, a polymerase chain reaction (PCR) and DNA sequencing strategy has been used to examine the fidelity of excision of two Tec1 elements and three IESs. In all cases, the vast majority of excision events were found to be precise, with one copy of the terminal direct repeats retained at the empty site in the macronuclear DNA molecule. These results, in combination with previous studies that have characterized the excised DNA elements, indicate that the two products of excision (the free element and the macronuclear DNA molecule) share DNA sequences. This suggests that excision events are initiated by staggered cuts in the chromosomal DNA.

Precise excision of telomere-bearing transposons during Oxytricha fallax macronuclear development.

In ciliated protozoa, development of the macronucleus from a copy of the germ line micronucleus involves elimination of a large number of sequences by DNA splicing akin to precise excision of transposons. The known examples of such internal eliminated sequences (IESs) are not repetitive. The telomere-bearing elements (TBE1s) of Oxytricha fallax are a family of transposons. We show that two particular TBE1s are also IESs. TBE1-1 and TBE1-2 disrupt a micronuclear region that codes for macronuclear DNA. A variety of tests indicates that each TBE1 and one copy of the flanking target repeat is absent from most, if not all, molecules of the macronuclear DNA, as if the TBE1s were precisely excised during macronuclear development. Three alternative explanations for the absence of TBE1-1 and TBE1-2 from the macronuclear DNA were tested. First, because two other highly homologous versions of that DNA are also found in the macronucleus, recombination between versions during or after macronuclear development could have bypassed the elements. Recombination in the regions flanking the elements was not detected. Second, micronuclear DNA blots show no evidence of a micronuclear counterpart of the macronuclear region that lacks TBE1-1. Third, TBE1-2 was demonstrated in two sexually independent cell lines. This shows that it pre-existed in the germ line, as opposed to having transposed into the micronuclear DNA subsequent to the generation of the macronucleus of the vegetative line that is usually studied. We conclude that TBE1-1 and TBE1-2, and possibly many of the other approximately 1900 micronucleus-limited TBE1s are excised as IESs during macronuclear development. These transposons appear to enjoy the luxury of relaxed constraints on family expansion, because they are removed from the genome before it is expressed. We discuss the possibility that all IESs are transposon-derived, that all are excised by transposition machinery, and that linear excision products are early intermediates in transposition.

Nucleic acid splicing events occur frequently during macronuclear development in the protozoan Oxytricha nova and involve the elimination of unique DNA.

During its life cycle, the hypotrichous ciliated protozoan Oxytricha nova transforms a copy of its chromosomal micronucleus into a transcriptionally active macronucleus which contains exclusively linear, gene-sized DNA molecules with an average size of about 2.2 kilobase pairs (kbp). The micronuclear precursors of two macronuclear DNA molecules have been examined. Each was found to contain at least five blocks of DNA sequences that are absent in the mature macronuclear DNA molecule. These blocks of sequences, referred to as internal eliminated sequences (IESs), must be removed by a nucleic acid breakage and joining process during development. The data obtained to date indicate that IESs are common and suggest that greater than 60,000 IES removal events occur during macronuclear development. Additional analyses indicate that IESs represent a portion of the unique micronuclear DNA sequences known to be eliminated during development. Comparisons of the sequences of IESs revealed common organizational features and some limited primary sequence homologies that suggest models for their developmental excision.