The pathway to detangle a scrambled gene.

BACKGROUND: Programmed DNA elimination and reorganization frequently occur during cellular differentiation. Development of the somatic macronucleus in some ciliates presents an extreme case, involving excision of internal eliminated sequences (IESs) that interrupt coding DNA segments (macronuclear destined sequences, MDSs), as well as removal of transposon-like elements and extensive genome fragmentation, leading to 98% genome reduction in Stylonychia lemnae. Approximately 20-30% of the genes are estimated to be scrambled in the germline micronucleus, with coding segment order permuted and present in either orientation on micronuclear chromosomes. Massive genome rearrangements are therefore critical for development. METHODOLOGY/PRINCIPAL FINDINGS: To understand the process of DNA deletion and reorganization during macronuclear development, we examined the population of DNA molecules during assembly of different scrambled genes in two related organisms in a developmental time-course by PCR. The data suggest that removal of conventional IESs usually occurs first, accompanied by a surprising level of error at this step. The complex events of inversion and translocation seem to occur after repair and excision of all conventional IESs and via multiple pathways. CONCLUSIONS/SIGNIFICANCE: This study reveals a temporal order of DNA rearrangements during the processing of a scrambled gene, with simpler events usually preceding more complex ones. The surprising observation of a hidden layer of errors, absent from the mature macronucleus but present during development, also underscores the need for repair or screening of incorrectly-assembled DNA molecules.

Interconversion of germline-limited and somatic DNA in a scrambled gene.

Ciliates have a somatic and a germline nucleus; after sexual conjugation a new somatic nucleus forms from the new zygotic germline nucleus. Formation of the somatic nucleus involves precise elimination of a large portion of DNA sequences from the germline. Here we compare the architecture of the germline and somatic versions of the actin I gene in two geographically isolated strains of Stylonychia lemnae. We show that the structure of the germline gene is surprisingly mercurial, with the distinction between germline-limited and somatic sequences variable over the course of evolution. This is, to our knowledge, the first example of evolutionary swapping of retained versus deleted sequences during ciliate development, with sequences deleted during development that are specifically retained in another strain.

Evolution of programmed ribosomal frameshifting in the TERT genes of Euplotes.

A number of recent studies indicate that programmed + 1 ribosomal frameshifting is frequently required for the expression of genes in species of the genus Euplotes. In E. crassus, three genes encoding the telomerase reverse transcriptase (TERT) subunit have been previously found to possess one or two + 1 frameshift sites. To examine the origin of frameshift sites within the Euplotes group, we have isolated segments of the TERT gene from five Euplotes species. Coupled with phylogenetic analysis, the results indicate that one frameshift site in the TERT gene arose late in the evolution of the group. In addition, a novel frameshift site was identified in the TERT gene of E. minuta, a species where frameshifting has not been previously reported. Coupled with other studies, the results indicate that frameshift sites have arisen during the diversification of the euplotids. The results also are discussed in regard to the mutations necessary to generate frameshift sites, and the specialization of TERT protein function that has apparently occurred in E. crassus.

The telomerase-associated protein p43 is involved in anchoring telomerase in the nucleus.

Telomere replication of eukaryotic chromosomes is achieved by a specialized enzyme, the telomerase. Although the biochemistry of end-replication is well understood, little is known about the organization of the end-replication machinery, its regulation throughout the cell cycle or the biological function of the telomerase-associated proteins. Here we investigate the function of the telomerase-associated protein p43 within the macronucleus of the ciliated protozoa Euplotes. It has been shown that p43 binds in vitro to the RNA subunit of telomerase and shares homology with the La autoantigen family. It therefore has been suggested that it is involved in the assembly and/or nuclear retention of telomerase. We show that the p43-telomerase complex is bound to a subnuclear structure in vivo and is resistant to electroelution. Upon inhibition of p43 or telomerase expression by RNAi, which in this study was used for the first time in spirotrichs, this complex is no longer retained in the nucleus. Further analysis revealed that the p43-telomerase complex is bound to the nuclear matrix in vivo and that after inhibition of p43 expression, telomerase is released from this structure, strongly suggesting that p43 is involved in anchoring of telomerase in the nucleus. This is the first in vivo demonstration of the biological function of this telomerase-associated component involved in telomere replication and allows us to propose a model for the organization of the end-replication machinery in the eukaryotic cell.

De novo telomere addition to spacer sequences prior to their developmental degradation in Euplotes crassus.

During sexual reproduction, Euplotes crassus precisely fragments its micronuclear chromosomes and synthesizes new telomeres onto the resulting DNA ends to generate functional macronuclear minichromosomes. In the micronuclear chromosomes, the macronuclear-destined sequences are typically separated from each other by spacer DNA segments, which are eliminated following chromosome fragmentation. Recently, in vivo chromosome fragmentation intermediates that had not yet undergone telomere addition have been characterized. The ends of both the macronuclear-destined and eliminated spacers were found to consist of six-base, 3' overhangs. As this terminal structure on the macronuclear-destined sequences serves as the substrate for de novo telomere addition, we sought to determine if the spacer DNAs might also undergo telomere addition prior to their elimination. Using a polymerase chain reaction approach, we found that at least some spacer DNAs undergo de novo telomere addition. In contrast to macronuclear-destined sequences, heterogeneity could be observed in the position of telomeric repeat addition. The observation of spacer DNAs with telomeric repeats makes it unlikely that differential telomere addition is responsible for differentiating between retained and eliminated DNA. The heterogeneity in telomere addition sites for spacer DNA also resembles the situation found for telomeric repeat addition to macronuclear-destined sequences in other ciliate species.