Evolution of internal eliminated segments and scrambling in the micronuclear gene encoding DNA polymerase alpha in two Oxytricha species.

To learn about the evolution of internal eliminated segments (IESs) and gene scrambling in hypotrichous ciliates we determined the structure of the micronuclear (germline) gene encoding DNA polymerasealpha(DNA polalpha) in Oxytricha trifallax and compared it to the previously published structure of the germline DNA polalphagene in Oxytricha nova . The DNA polalphagene of O.trifallax contains 51 macronuclear-destined segments (MDSs) separated by 50 IESs, compared to 45 MDSs and 44 IESs in the O.nova gene. This means that IESs and MDSs have been gained and/or lost during evolutionary divergence of the two species. Most of the MDSs are highly scrambled in a similar non-random pattern in the two species. We present a model to explain how IESs, non-scrambled MDSs and scrambled MDSs may be added and/or eliminated during evolution. Corresponding IESs in the two species differ totally in sequence, and junctions between MDSs and IESs are shifted by 1-18 bp in O.trifallax compared to the O.nova gene. In both species a short region of the gene is distantly separated from the main part of the gene. Comparison of the gene in the two species shows that IESs and scrambling are highly malleable over evolutionary time.     

尖毛虫属Actin Ⅰ、α-TBP和DNA pol α乱序基因的模式研究

研究旨在对尖毛虫属内现有物种的3种乱序小核基因结构进行比较,探讨其乱序模式。于湛江湖光红树林水域中采集到一个尖毛虫属物种Oxytricha sp.（ZJ）,成功扩增了其肌动蛋白Ⅰ（ActinⅠ）、端粒结合蛋白（α-TBP）、DNA聚合酶α（DNA pol α）3个乱序基因的完整大核基因序列和完整/部分小核基因序列,并结合已有资料对比研究了尖毛虫属这3个乱序基因的进化。结果表明:（1）Oxytricha sp.（ZJ）与O.nova的小核Actin Ⅰ基因具有相同的乱序模式,区别于其余的尖毛虫属物种;在增加尖毛虫属物种的基础上,对前人推测提出了质疑,我们认为MDS-IES接合处移动现象在乱序MDSs之间并非比非乱序MDSs之间更保守。（2）Oxytricha sp.（ZJ）与O.nova的小核α-TBP基因具有相同乱序模式和相似长度的IESs。（3）Oxytricha sp.（ZJ）的小核DNA pol α基因乱序模式,区别于任一已报道物种,与属内O. trifallax最为相近。基于序列分析,在DNA pol α基因中发现了一例IES转换为MDS的痕迹,以及由此导致原先MDS的丢失。研究发现在编码区内IES向MDS的转变,使得本应删除的序列成为基因组永久保留的一部分。     

The germline gene encoding DNA polymerase alpha in the hypotrichous ciliate Oxytricha nova is extremely scrambled.

We report the structure of the micronuclear (germline) gene encoding the large catalytic subunit of DNA polymerase alpha (DNA pol alpha) in the ciliate Oxytricha nova. It contains 44 internal eliminated segments (IESs) that divide the gene into 45 macronuclear-destined segments (MDSs) that are in a non-randomly scrambled order with an inversion near the gene center. Odd numbered MDSs 29-43, containing 230 bp out of a total of 4938 bp of macronuclear sequence, are missing from the 14 kb cloned gene. The missing MDSs have not been located but are at least several kilobases from the main body of the gene. The remarkably scrambled DNA pol alpha gene must be extensively cut, re-ordered and spliced and an inversion must occur to produce an unscrambled, functional version of the gene during development of a new macronucleus. Unscrambling is hypothesized to occur by a homologous recombination mechanism guided by repeat sequences at MDS ends.     

Internal Eliminated Segments (IESs) of Oxytrichidae1

ABSTRACT Internal eliminated segments (IESs) are sequences that interrupt coding and noncoding regions of germline (micronuclear) genes of ciliated protozoa. IESs are flanked by short, unique repeat sequences, which are presumably required for precise IES excision during macronuclear development. Coding and noncoding segments of genes separated by IESs are called macronuclear-destined segments, or MDSs. We have compiled the characteristics of 89 individual IESs in 12 micronuclear genes in the Oxytricha and Stylonychia genera to define the IES phenomenon precisely, a first step in determining the origin, function and significance of IESs. Although all 89 IESs among the 12 different genes are AT-rich, they show no other similarity in sequence, length, position or number. Two main types of IESs are present. IESs that separate scrambled MDSs are significantly shorter and more frequent and have longer flanking repeat sequences than IESs that intervene between nonscrambled MDSs. A comparison of the nonscrambled gene encoding β-telomere binding protein in three species of hypotrichs shows that even in the same gene IESs are not conserved in sequence, length, position, or number from species to species. A comparison of IESs in the scrambled gene encoding actin I in the three species shows that the evolutionary behavior of IESs in a scrambled gene may be more constrained. However, IESs in the scrambled actin I gene have shifted along the DNA molecule during evolution. In total, the various studies show that IESs are hypermutable in sequence and length. They insert, excise, and shift along DNA molecules more or less randomly during evolution, with no discernible function or consequences.     

Evolution of the Germline Actin Gene in Hypotrichous Ciliates: Multiple Nonscrambled IESs at Extremely Conserved Locations in Two Urostylids

In hypotrichous ciliates, macronuclear chromosomes are gene‐sized, and micronuclear genes contain short, noncoding internal eliminated segments (IESs) as well as macronuclear‐destined segments (MDSs). In the present study, we characterized the complete macronuclear gene and two to three types of micronuclear actin genes of two urostylid species, i.e. Pseudokeronopsis rubra and Uroleptopsis citrina. Our results show that (1) the gain/loss of IES happens frequently in the subclass Hypotrichia (formerly Stichotrichia), and high fragmentation of germline genes does not imply for gene scrambling; and (2) the micronuclear actin gene is scrambled in the order Sporadotrichida but nonscrambled in the orders Urostylida and Stichotrichida, indicating the independent evolution of MIC‐actin gene patterns in different orders of hypotrichs; (3) locations of MDS–IES junctions of micronuclear actin gene in coding regions are conserved among closely related species.     

Volatility of internal eliminated segments in germ line genes of hypotrichous ciliates.

Germ line micronuclear genes in ciliated protozoa contain two types of interrupting sequences. Some genes contain introns, but internal eliminated segments (IESs) are much more prevalent. IESs are AT-rich DNA segments that separate macronucleus-destined segments (MDSs) in micronuclear genes. All IESs are excised and destroyed when a micronucleus develops into a macronucleus after each cell mating. IESs have no discernible function. Therefore, an investigation of the behavior of IESs in evolution has been undertaken to assess their possible significance. The IESs in the micronuclear gene encoding the beta-subunit of the telomere-binding protein (beta-TP) are not conserved in number, position, sequence, or length during the evolution of four oxytrichid ciliates. In contrast, the scrambled pattern of MDSs and IESs of the micronuclear actin I gene has been conserved during evolution; however, the precise positions, sequences, and lengths of the IESs differ among species, and in some organisms the actin I gene contains an additional IES and MDS. Corresponding IESs in the actin I genes among the different organisms have shifted positions by 1 to 14 bp, presumably by a mutation-shifting mechanism, creating differences in the repeat sequences flanking IESs. Thus, conservation of a particular repeat sequence among species is not required for IES excision. The changes in IES number and position in the beta-TP genes among ciliates are in sharp contrast to the stability of the intron position. Therefore, IESs are volatile, hypermutable elements that are inserted, removed, shifted, and modified continuously in the germ line through evolutionary time.     

Invention and Mystery in Hypotrich DNA1

ABSTRACT “The capacity to blunder slightly is the real marvel of DNA. Without this special attribute, we would still be anaerobic bacteria and there would be no music.” Lewis Thomas³ Hypotrichs have evolved extraordinary ways of organizing, manipulating, and replicating the DNA in their micronuclear and macronuclear genomes. Short macronuclear DNA molecules containing single genes are created by excision from chromosomes, accompanied by massive elimination of the germline DNA sequences between genes. Germline genes themselves are interrupted by multiple noncoding segments called internal eliminated segments, or IESs, that divide genes into multiple macronuclear-destined segments, or MDSs. The functional significance of this organization is unknown. Over evolutionary time IESs accumulate mutations rapidly are inserted into or excised from genes, and shift position along DNA molecules. MDSs are ligated to create functional genes when IESs are spliced out of micronuclear DNA during macronuclear development. MDSs in some germline genes are in scrambled disorder and become unscrambled in association with IES elimination. Replication of DNA in the macronucleus is accomplished by organization of replication enzymes and factors into a structure that sweeps through the macronucleus to replicate the many millions of gene-sized DNA molecules. The significance of many of the bizarre DNA phenomena in the evolutionary/functional success of hypotrichs is still unclear.     

Evolution of the scrambled germline gene encoding α-telomere binding protein in three hypotrichous ciliates

The micronuclear genes encoding α-telomere-binding protein (αTP) in Oxytricha trifallax and Stylonychia mytilus contain multiple internal eliminated segments, or IESs, that divide the gene into multiple parts called macronuclear destined segments, or MDSs. The MDSs have become disordered, or scrambled, during evolution. The scrambled structures of the αTP genes in Oxytricha trifallax and S. mytilus have been compared with the previously published scrambled structure of the αTP gene in O. nova. The scrambled patterns of the αTP gene in the three species are similar but show significant differences. The micronuclear genes in O. nova and S. mytilus consist of 13 IESs and 14 MDSs, but the gene in O. trifallax is divided into three additional MDSs by the presence of three additional IESs, believed to have been inserted into the O. trifallaxαTP gene after divergence of O. trifallax from the other two species. Corresponding IESs among the three species have shifted along the DNA during evolution, presumably by a mutational mechanism that changes the short repeat sequences that flank IESs. The IESs also have changed markedly in length by insertion and/or deletion of nucleotides. Comparison of the putative αTP amino acid sequences in the three species reveals three conserved and three nonconserved domains. The 5′ nontranslated regions of the gene-sized molecules encoding αTP contain several conserved segments, and the 3′ nontranscribed trailer contains one conserved segment. Received: 29 May 1998; in revised form: 3 August 1998 / Accepted: 18 August 1998     

The scrambled Actin I gene in<Emphasis Type="Italic"> Uroleptus pisces</Emphasis>

The micronuclear gene encoding actin I in Uroleptus pisces occurs in two segments. Segment I contains 638 bp divided into six macronuclear destined subsegments, or MDSs, by five internal eliminated segments, or IESs. The MDSs in segment 1 are in the scrambled disorder, 1-2-4-8-6-15, with MDSs 8 and 6 inverted. Segment II contains 2452 bp divided into ten MDSs by nine IESs in the scrambled disorder, 3-5-7-10-13-12-9-14-16-11, with MDSs 12, 9, and 11 inverted. Extensive attempts by polymerase chain reaction to connect the two segments failed. We conclude that the two segments are separated by a very long IES or are in different loci. The pattern of the 16 scrambled MDSs is entirely different from the scrambled pattern observed for the actin I gene in six other stichotrichs. We conclude that the actin I gene became scrambled on two separate occasions during stichotrich evolution: once in the lineage leading to the group of six stichotrichs, which includes, among others, Sterkiella species and Stylonychia lemnae, and once in the lineage leading to Uroleptus pisces. Repeated sequence pairs (pointers) of three to 14 bases at the ends of MDSs appear to be essential for correct splicing of MDSs during macronuclear development. However, the micronuclear actin gene also contains 40 matches of eight or more bases between IESs and MDSs that do not function as pointers. To prevent these ectopic repeats from causing improper processing of the micronuclear gene appears to demand a template of DNA or RNA from the old macronucleus to guide splicing of MDSs in the orthodox order.Communicated by A. SpradlingAccession numbers: AY373659, AY382825, AY382826     

Template-guided recombination for IES elimination and unscrambling of genes in stichotrichous ciliates

The micronuclear versions of genes in stichotrichous ciliates are interrupted by multiple, short, non-coding DNA segments called internal eliminated segments, or IESs. IESs divide a gene into macronuclear destined segments, or MDSs. In some micronuclear genes MDSs are in a scrambled disorder. During development of a micronucleus into a macronucleus after cell mating the IESs are excised from micronuclear genes and the MDSs are spliced in the sequentially correct order. Pairs of short repeat sequences in the ends of MDSs undergo homologous recombination to excise IESs and splice MDSs. However, the repeat sequences are too short to guide unambiguously their own alignment in preparation for recombination. Based on experiments by others on the distantly related ciliate, Paramecium, we propose a molecular model of template-guided recombination to explain the excision of the 100,000-150,000 IESs and splicing of MDSs, including unscrambling, in the genome of stichotrichous ciliates. The model solves the problem of correct pairing of pointers, precisely identifies MDS-IES junctions, and provides for irreversible recombination.     

A model for the origin of internal eliminated segments (IESs) and gene rearrangement in stichotrichous ciliates

A characteristic feature of ciliates (ciliated protozoans) is their nuclear dimorphism: the presence of two kinds of functionally different nuclei in the same cell--a micronucleus (MIC) and the macronucleus (MAC). In the stichotrichous group of ciliates the organization of DNA in the MIC is dramatically different from that in the MAC. Genes in the MIC consist of the sequence of segments, called MDSs, which are separated by short noncoding pieces of DNA, called IESs. Moreover, the order of MDSs in the MIC may be scrambled compared to their order in the MAC, and also some MDSs may be inverted with respect to each other. In this paper, we consider the evolutionary origin of this bizarre form of MIC genes, and in particular we postulate that the insertion of IESs as well as possible scramblings/inversions have resulted from a repair of one or more breaks in a DNA molecule. We propose a specific repair scheme, and postulate that this repair scheme applied to a coiled structure of a DNA molecule that has undergone multiple breaks can produce IES insertions and/or scrambled/inverted MIC gene patterns. All experimentally demonstrated as well as theoretical MIC gene patterns can be produced in this way.     

Origin, evolution, and excision of internal eliminated segments in germline genes of ciliates

Three hypotheses on the evolutionary/molecular origin of internal eliminated segments (IESs) in the germline of hypotrichous ciliates are discussed in the context of the high rate of mutation accumulation in IESs, shifting of IESs during speciation, and evolutionary scrambling of segments within some hypotrich germline genes. Developmental excision of IESs from the germline in Paramecium suggests that the parental macronucleus may provide nucleic acid sequence information to guide excision of IESs and splicing of macronuclear-destined sequences. In ciliates of the oxytrichid/stylonychid group, such a mechanism could explain the precision of excision of IESs and gene unscrambling. Recently initiated molecular/genetic studies may eventually clarify the role of the parental macronucleus in IES excision and gene unscrambling as well as the molecular mechanisms of these events.     

Internal eliminated sequences interrupting the Oxytricha 81 locus: allelic divergence, conservation, conversions, and possible transposon origins

Internal eliminated sequences (IESs) often interrupt ciliate genes in the silent germline nucleus but are exactly excised and eliminated from the developing somatic nucleus from which genes are then expressed. Some long IESs are transposons, supporting the hypothesis that short IESs are ancient transposon relics. In light of that hypothesis and to explore the evolutionary history of a collection of IESs, we have compared various alleles of a particular locus (the 81 locus) of the ciliated protozoa Oxytricha trifallax and O. fallax. Three short IESs that interrupt two genes of the locus are found in alleles from both species, and thus must be relatively ancient, consistent with the hypothesis that short IESs are transposon relics. In contrast, TBE1 transposon interruptions of the locus are allele-specific and probably the results of recent transpositions. These IESs (and the TBE1s) are precisely excised from the DNA of the developing somatic macronucleus. Each IES interrupts a highly conserved sequence. A few nucleotides at the ends of each IES are also conserved, suggesting that they interact critically with IES excision machinery. However, most IES nucleotide positions have evolved at high rates, showing little or no selective constraint for function. Nonetheless, the length of each IES has been maintained (+/- 3 bp). While one IES is approximately 33 bp long, three other IESs have very similar sizes, approximately 70 bp long. Two IESs are surrounded by direct repeats of the sequence TTCTT. No other sequence similarities were found between any of the four IESs. However, the ends of one IES do match the inverted terminal repeat consensus sequence of the "TA" IESs of Paramecium. Three O. trifallax alleles appear to have been recipients in recent conversion events that could have been provoked by double-strand breaks associated with IES ends subsequent to IES transposition. Our findings support the hypothesis that short IESs evolved from ancient transposons that have lost most of their sequences, except those necessary for precise excision during macronuclear development.      

The Micronuclear Gene Encoding β-Telomere Binding Protein in Oxytricha nova

ABSTRACT The micronuclear version of the gene encoding β-telomere binding protein (β-TBP) in Oxytricha nova has been sequenced and compared to the macronuclear β-TBP gene, previously described. The micronuclear gene contains three AT-rich internal eliminated sequences (IES) of 37, 40, and 43 bp and four macronuclear destined sequences (MDS). The IES interrupt the gene once near the 5′ end of the coding region and twice in the 3′ trailer downstream from the TGA stop codon. The sequences of the micronuclear and macronuclear genes are colinear. Thus, the micronuclear β-TBP gene is not scrambled, which contrasts with the highly scrambled state among the 14 MDS in the micronuclear α;-TBP gene.     

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.     

The Paramecium Germline Genome Provides a Niche for Intragenic Parasitic DNA: Evolutionary Dynamics of Internal Eliminated Sequences

Insertions of parasitic DNA within coding sequences are usually deleterious and are generally counter-selected during evolution. Thanks to nuclear dimorphism, ciliates provide unique models to study the fate of such insertions. Their germline genome undergoes extensive rearrangements during development of a new somatic macronucleus from the germline micronucleus following sexual events. In Paramecium, these rearrangements include precise excision of unique-copy Internal Eliminated Sequences (IES) from the somatic DNA, requiring the activity of a domesticated piggyBac transposase, PiggyMac. We have sequenced Paramecium tetraurelia germline DNA, establishing a genome-wide catalogue of ∼45,000 IESs, in order to gain insight into their evolutionary origin and excision mechanism. We obtained direct evidence that PiggyMac is required for excision of all IESs. Homology with known P. tetraurelia Tc1/mariner transposons, described here, indicates that at least a fraction of IESs derive from these elements. Most IES insertions occurred before a recent whole-genome duplication that preceded diversification of the P. aurelia species complex, but IES invasion of the Paramecium genome appears to be an ongoing process. Once inserted, IESs decay rapidly by accumulation of deletions and point substitutions. Over 90% of the IESs are shorter than 150 bp and present a remarkable size distribution with a ∼10 bp periodicity, corresponding to the helical repeat of double-stranded DNA and suggesting DNA loop formation during assembly of a transpososome-like excision complex. IESs are equally frequent within and between coding sequences; however, excision is not 100% efficient and there is selective pressure against IES insertions, in particular within highly expressed genes. We discuss the possibility that ancient domestication of a piggyBac transposase favored subsequent propagation of transposons throughout the germline by allowing insertions in coding sequences, a fraction of the genome in which parasitic DNA is not usually tolerated.     

Scrambled actin I gene in the micronucleus of Oxytricha nova.

In the hypotrichous ciliate Oxytricha nova the cloned precursor gene from the micronuclear genome that encodes actin I is composed of highly disordered blocks of deoxynucleotide sequences. We present and illustrate in detail a recombination model that explains how the actin I gene may be unscrambled during macronuclear development after cell mating. The model was described in a previous publication (Greslin et al.: Proc Natl Acad Sci USA 86:6264-6268, 1989). Here we show the data, described in the earlier publication, that support the model. The data show that scrambling is not an artifact of cloning. They rule against the presence of an unscrambled copy of the actin I gene in the micronucleus, which means that unscrambling must be a part of macronuclear development. Finally, the data prove that the actin I gene in O. trifallax is scrambled in a pattern that resembles the pattern in O. nova.     

Preferential cleavage of Paramecium DNA mediated by the C. elegans Tc1 transposase in vitro

In the ciliate Paramecium aurelia complex, thousands of internal eliminated sequences (IESs) are excised from the germline micronuclear DNA during macronuclear differentiation. Based on the resemblance of Paramecium IES end sequences to Tc1 transposon termini, it has been proposed that Paramecium IESs might have degenerately evolved from Tc1 family transposons, and still be removed by an enzyme homologous to a Tc1 transposase. In this study, we found that transposase preferentially cleaved (or nicked) 58 sites near the IESs in Paramecium DNA, at sequences consisting of TT or TCTA. Since one excision junction of the P. primaurelia W2 IES was included in such sites, this suggests that a Tc1-like transposase is involved in the IES excision process, although it is probably not a sole factor responsible for the precise cleavage. In addition, unmethylated substrate DNA appeared to decrease the cleavage specificity, suggesting an involvement of DNA methylation in the cleavage. Although these results do not directly address the transposon origin of Paramecium IESs, it is likely that the enzymatic machinery responsible for the initial cleavage is derived from a Tc1-like transposase. The mechanism necessary for precise excision is discussed, in relation to recent knowledge of IES excision obtained in Tetrahymena and Paramecium.