Abstract

In Paramecium, the regeneration of a functional somatic genome at each sexual event relies on the elimination of thousands of germline DNA sequences, known as Internal Eliminated Sequences (IESs), from the zygotic nuclear DNA. Here, we provide evidence that IESs’ length and sub-terminal bases jointly modulate IES excision by affecting DNA conformation in P. tetraurelia. Our study reveals an excess of complementary base pairing between IESs’ sub-terminal and contiguous sites, suggesting that IESs may form DNA loops prior to cleavage. The degree of complementary base pairing between IESs’ sub-terminal sites (termed Cin-score) is positively associated with IES length and is shaped by natural selection. Moreover, it escalates abruptly when IES length exceeds 45 nucleotides (nt), indicating that only sufficiently large IESs may form loops. Finally, we find that IESs smaller than 46 nt are favored targets of the cellular surveillance systems, presumably because of their relatively inefficient excision. Our findings extend the repertoire of cis-acting determinants for IES recognition/excision and provide unprecedented insights into the distinct selective pressures that operate on IESs and somatic DNA regions. This information potentially moves current models of IES evolution and of mechanisms of IES recognition/excision forward.

Highlights

  • Single-celled ciliated protozoa are excellent systems for the study of programmed DNA elimination

  • What is the likelihood that P. tetraurelia Internal Eliminated Sequences (IESs) form loops? We addressed this issue by studying the extent to which the complementary base pairing between (i) intra-IES termini, and (ii) somatic DNA sequences abutting P. tetraurelia IESs deviates from what we would expect if pairing occurred at random

  • Excess of complementary base pairing between the termini of P. tetraurelia IESs

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Summary

Introduction

Single-celled ciliated protozoa are excellent systems for the study of programmed DNA elimination. These protozoa are the only eukaryotes with two nuclei in their cytoplasm: a micronucleus (MIC), which houses the germline genome, and a macronucleus (MAC) that contains the somatic genome. In ciliates, programmed DNA elimination takes place in the new zygotic MAC––as the old maternal. MAC degrades––and regulates the excision of up to tens of thousands of germline DNA sequences, known as Internal Eliminated Sequences (or IESs). Programmed DNA elimination ( referred to as DNA splicing hereinafter) in ciliates bears upon the generation of a functional somatic genome and the survival of sexual progeny. These IESs are short––more than 90% are shorter than 150 base pairs (bp)––and typically single-copy [3]

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