Molecular domestication – more than a sporadic episode in evolution

Transposable elements are short but complex pieces of DNA or RNA containing a streamlined minimal-genome with the capacity for its selfish replication in a foreign genomic environment. Cis-regulatory sections within the elements orchestrate tempo and mode of TE expression. Proteins encoded by TEs mainly direct their own propagation within the genome by recruitment of host-encoded factors. On the other hand, TE-encoded proteins harbor a very attractive repertoire of functional abilities for a cell. These proteins mediate excision, replication and integration of defined DNA fragments. Furthermore, some of these proteins are able to manipulate important host factors by altering their original function. Thus, if the host genome succeeds in domesticating such TE-encoded proteins by taming their ‘anarchistic behavior,’ such an event can be considered as an important evolutionary innovation for its own benefit. In fact, the domestication of TE-derived cis-regulatory modules and protein coding sections took place repeatedly in the course of genome evolution. We will present prominent cases that impressively demonstrate the beneficial impact of TEs on host biology over evolutionary time. Furthermore, we will propose that molecular domestication might be considered as a resumption of the same evolutionary process that drove the transition from ‘primitive genomes’ to ‘modern’ ones at the early dawn of life, that is, the adaptive integration of a short piece of autonomous DNA into a complex regulatory network. This revised version was published online in July 2006 with corrections to the Cover Date.     

Common evolutionary trends for SINE RNA structures

Short interspersed elements (SINEs) and long interspersed elements (LINEs) are transposable elements in eukaryotic genomes that mobilize through an RNA intermediate. Understanding their evolution is important because of their impact on the host genome. Most eukaryotic SINEs are ancestrally related to tRNA genes, although the typical tRNA cloverleaf structure is not apparent for most SINE consensus RNAs. Using a cladistic method where RNA structural components were coded as polarized and ordered multistate characters, we showed that related structural motifs are present in most SINE RNAs from mammals, fishes and plants, suggesting common selective constraints imposed at the SINE RNA structural level. Based on these results, we propose a general multistep model for the evolution of tRNA-related SINEs in eukaryotes.     

Molecular characterization,genomic distribution and evolutionary dynamics of Short INterspersed Elements in the termite genome

Short INterspersed Elements (SINEs) in invertebrates, and especially in animal inbred genomes such that of termites, are poorly known; in this paper we characterize three new SINE families (Talub, Taluc and Talud) through the analyses of 341 sequences, either isolated from the Reticulitermes lucifugus genome or drawn from EST Genbank collection. We further add new data to the only isopteran element known so far, Talua. These SINEs are tRNA-derived elements, with an average length ranging from 258 to 372 bp. The tails are made up by poly(A) or microsatellite motifs. Their copy number varies from 7.9 × 10³ to 10⁵ copies, well within the range observed for other metazoan genomes. Species distribution, age and target site duplication analysis indicate Talud as the oldest, possibly inactive SINE originated before the onset of Isoptera (~150 Myr ago). Taluc underwent to substantial sequence changes throughout the evolution of termites and data suggest it was silenced and then re-activated in the R. lucifugus lineage. Moreover, Taluc shares a conserved sequence block with other unrelated SINEs, as observed for some vertebrate and cephalopod elements. The study of genomic environment showed that insertions are mainly surrounded by microsatellites and other SINEs, indicating a biased accumulation within non-coding regions. The evolutionary dynamics of Talu~ elements is explained through selective mechanisms acting in an inbred genome; in this respect, the study of termites’ SINEs activity may provide an interesting framework to address the (co)evolution of mobile elements and the host genome.     

Sectorial mutagenesis by transposable elements

Transposable elements (TEs) generate insertions and cause other mutations in the genomic DNA. It is proposed that during co-evolution between TEs and eukaryotic genomes, an optimal path of the insertion mutagenesis is determined by the surviving TEs. These TEs can become semi-permanently established, chromatin-regulated ‘source’ or ‘mutator genes’, responsible for targeting insertion mutations to specific chromosomal regions. Such mutations can manifest themselves in non-random distribution patterns of interspersed repeats in eukaryotic chromosomes. In this paper we discuss specific models, examples and implications of optimized mutagenesis in eukaryotes. This revised version was published online in July 2006 with corrections to the Cover Date.     

SINEs: Short interspersed repeated elements of the eukaryotic genome

Much of the eukaryotic genome is composed of a variety of repetitive sequences. Amongst these, there are two kinds of retroposons (sequence elements derived from nonviral cellular RNA): SINEs (short interspersed elements) and LINEs (long interspersed elements). Amplification of SINEs occurs in a single germ cell, and the members of SINEs spread and become fixed in populations through genetic drift. SINEs can be regarded as phylogenetic landmarks: they are specific to one species, a few species, a genus or in some cases a family, indicating a specific time of amplification during evolution. Recent studies concerning the structure and origin of many SINEs revealed that retroposons are more widespread in animal genomes than was previously thought.     

The Au family, a novel short interspersed element (SINE) from Aegilops umbellulata

A novel plant short interspersed nuclear element (SINE) was identified in the second intron of the acetyl CoA carboxylase gene of Aegilops umbellulata which has been designated ”Au”, for the host species in which it was discovered. Au elements have a tRNA-related region, direct flanking repeats, and a short stretch of T at the 3′ end, which are features common to Au and previously characterized SINEs. Au elements are detected in the genomes of several monocots and dicots by DNA dot hybridization and are also found in the tobacco genome by database searching. Au elements are present at an especially high copy number (approximately 10⁴ copies per haploid genome) in wheat and Ae. umbellulata. This suggests a recent amplification of Au in the Triticum and Aegilops species. In situ hybridization revealed a dispersed distribution of Au elements on wheat chromosomes. Au elements were amplified by PCR from monocot and dicot species and the phylogenetic relationships among Au elements were inferred. This phylogenetic analysis suggests amplification of Au elements in a manner consistent with the retrotransposon model for SINE dispersion. The high copy number of Au elements and their dispersed distribution in wheat are desirable characteristics for a molecular marker system in this important species. Received: 15 April 2000 / Accepted: 24 August 2000     

Isolation and characterization of active LINE and SINEs from the eel

Long interspersed elements (LINEs) and short interspersed elements (SINEs) are retrotransposons. These elements can mobilize by the "copy-and-paste" mechanism, in which their own RNA is reverse-transcribed into complementary DNA (cDNA). LINEs and SINEs not only are components of eukaryotic genomes but also drivers of genomic evolution. Thus, studies of the amplification mechanism of LINEs and SINEs are important for understanding eukaryotic genome evolution. Here we report the characterization of one LINE family (UnaL2) and two SINE families (UnaSINE1 and UnaSINE2) from the eel (Anguilla japonica) genome. UnaL2 is approximately 3.6 kilobases (kb) and encodes only one open reading frame (ORF). UnaL2 belongs to the stringent type--thought to be a major group of LINEs--and can mobilize in HeLa cells. We also show that UnaL2 and the two UnaSINEs have similar 3' tails, and that both UnaSINE1 and UnaSINE2 can be mobilized by UnaL2 in HeLa cells. These elements are thus useful for delineating the amplification mechanism of stringent type LINEs as well as that of SINEs.     

植物基因组中的非LTR反转录转座子SINEs和LINEs

反转录转座子是基因组进化的推动者之一。分为LTR和非LTR两种类型。前者是真核基因组的主要组分,结构和转座方式与逆转录病毒类似。后者是最初发现于动物基因组新近发现在植物基因组中也广泛存在的新型重复序列,包括LINEs(long interspersed nuclear elements)和SINEs(short interspersed nuclear elements)两个亚型。它们大多因自身或受宿主基因组的调控而失去转座活性。其转座机理目前还不十分清楚,推测LINEs可以自主转座,SINEs依赖其他转座子被动转座。种系分析认为LINEs可能是最古老的反转录转座子,SINEs的起源未知。文章对以上内容进行了归纳和讨论。     

Tracking the ancestry of a deeply conserved eumetazoan SINE domain

Transposable elements (TEs), such as short interspersed elements (SINEs), evolve rapidly and are generally restricted to specific lineages. Here, we demonstrate that a central core of the previously described Deu-domain located within DeuSINEs (Nishihara et al. 2006) is widely distributed throughout the Metazoa. We characterize five new SINEs with this core sequence from the genomes of cnidarians, molluscs, annelids, and arthropods. Because this domain can be traced back to the cnidarian-bilaterian split >600 Ma, we propose naming it the "Nin" domain (the meaning of the Japanese character "Nin" is to endure and hide). Given that conserved noncoding DNA, such as that derived from the activity of SINEs, can be functionally relevant for the host genome (Sasaki et al. 2008), our findings highlight the need to understand these functions and the roles they may have played in supporting the evolution of multicellular genomes.     

Pstl repeat: a family of short interspersed nucleotide element (SINE)-like sequences in the genomes of cattle, goat, and buffalo.

The PstI family of elements are short, highly repetitive DNA sequences interspersed throughout the genome of the Bovidae. We have cloned and sequenced some members of the PstI family from cattle, goat, and buffalo. These elements are approximately 500 bp, have a copy number of 2 x 10(5) - 4 x 10(5), and comprise about 4% of the haploid genome. Studies of nucleotide sequence homology indicate that the buffalo and goat PstI repeats (type II) are similar types of short interspersed nucleotide element (SINE) sequences, but the cattle PstI repeat (type I) is considerably more divergent. Additionally, the goat PstI sequence showed significant sequence homology with bovine serine tRNA, and is therefore likely derived from serine tRNA. Interestingly, Southern hybridization suggests that both types of SINEs (I and II) are present in all the species of Bovidae. Dendrogram analysis indicates that cattle PstI SINE is similar to bovine Alu-like SINEs. Goat and buffalo SINEs formed a separate cluster, suggesting that these two types of SINEs evolved separately in the genome of the Bovidae.     

L1-mediated retrotransposition of murine B1 and B2 SINEs recapitulated in cultured cells

SINEs are short interspersed nucleotide elements with transpositional activity, present at a high copy number (up to a million) in mammalian genomes. They are 80-400 bp long, non-coding sequences which derive either from the 7SL RNA (e.g. human Alus, murine B1s) or tRNA (e.g. murine B2s) polymerase III-driven genes. We have previously demonstrated that Alus very efficiently divert the enzymatic machinery of the autonomous L1 LINE (long interspersed nucleotide element) retrotransposons to transpose at a high rate. Here we show, using an ex vivo assay for transposition, that both B1 and B2 SINEs can be mobilized by murine LINEs, with the hallmarks of a bona fide retrotransposition process, including target site duplications of varying lengths and integrations into A-rich sequences. Despite different phylogenetic origins, transposition of the tRNA-derived B2 sequences is as efficient as that of the human Alus, whereas that of B1s is 20-100-fold lower despite a similar high copy number of these elements in the mouse genome. We provide evidence, via an appropriate nucleotide substitution within the B1 sequence in a domain essential for its intracellular targeting, that the current B1 SINEs are not optimal for transposition, a feature most probably selected for the host sake in the course of evolution.     

CAN—a pan-carnivore SINE family

Short retroposons or short interspersed elements (SINEs) constituting 5–10% genome have been isolated from various organisms. CAN SINEs initially found in American mink were named after dogs (Canis), and the range of their distribution in the genomes of carnivores and mammals in general remained topical. Here we demonstrate CAN sequences in representatives of all carnivore families, but not beyond carnivores, on the basis of sequence bank search and genomic PCR. Analysis of their distribution supports division of carnivores into caniform (dogs, mustelids, raccoons, bears, and pinnipeds) and feliform (cats, civets, and hyenas) lineages. CAN structure is considered in the context of their function and evolution. Received: 13 July 2001 / Accepted: 18 September 2001     

Evolutionary modes of emergence of short interspersed nuclear element (SINE) families in grasses

Short interspersed nuclear elements (SINEs) are non‐autonomous transposable elements which are propagated by retrotransposition and constitute an inherent part of the genome of most eukaryotic species. Knowledge of heterogeneous and highly abundant SINEs is crucial for de novo (or improvement of) annotation of whole genome sequences. We scanned Poaceae genome sequences of six important cereals (Oryza sativa, Triticum aestivum, Hordeum vulgare, Panicum virgatum, Sorghum bicolor, Zea mays) and Brachypodium distachyon to examine the diversity and evolution of SINE populations. We comparatively analyzed the structural features, distribution, evolutionary relation and abundance of 32 SINE families and subfamilies within grasses, comprising 11 052 individual copies. The investigation of activity profiles within the Poaceae provides insights into their species‐specific diversification and amplification. We found that Poaceae SINEs (PoaS) fall into two length categories: simple SINEs of up to 180 bp and dimeric SINEs larger than 240 bp. Detailed analysis at the nucleotide level revealed that multimerization of related and unrelated SINE copies is an important evolutionary mechanism of SINE formation. We conclude that PoaS families diversify by massive reshuffling between SINE families, likely caused by insertion of truncated copies, and provide a model for this evolutionary scenario. Twenty‐eight of 32 PoaS families and subfamilies show significant conservation, in particular either in the 5′ or 3′ regions, across Poaceae species and share large sequence stretches with one or more other PoaS families.     

In vitro binding of cattle PstI SINE with a 33-kDa nuclear protein.

A PstI family of SINEs (short interspersed elements) has been identified in some of the members of the family Bovidae, for example, cattle, buffalo and goat. In vitro DNA-protein interactions were studied to provide a better understanding of the function of these SINEs in the genome. Use of one such cattle PstI interspersed repeat sequence, as a probe in gel retardation assays, has lead to the identification of a repeat DNA-binding factor PIRBP (PstI interspersed repeat binding protein) from cattle liver nuclear extract. Southwestern analysis with liver nuclear extracts from cattle, goat, and buffalo revealed the presence of a PIRBP-like nuclear factor in all three species belonging to the family Bovidae. Deletion analysis localized the PIRBP binding site to an 80-bp (337-417 bp) region within the cattle PstI sequence. UV crosslinking and Southwestern analyses clearly indicated that PIRBP is a singular, small polypeptide of 33-kDa molecular mass. Homology search of the nucleic acids database revealed that the cattle PstI sequence was associated with many different genes of the family Bovidae, either in the 5' flanking region, 5' locus activating region, 3' UTR or in intervening sequences. The binding of the cattle PstI SINE by PIRBP and its association with the regulatory regions of the genes suggests that it plays an important role in the bovine genome.     

Families of short interspersed elements in the genome of the oomycete plant pathogen, Phytophthora infestans

The first known families of tRNA-related short interspersed elements (SINEs) in the oomycetes were identified by exploiting the genomic DNA sequence resources for the potato late blight pathogen, Phytophthora infestans. Fifteen families of tRNA-related SINEs, as well as predicted tRNAs, and other possible RNA polymerase III-transcribed sequences were identified. The size of individual elements ranges from 101 to 392 bp, representing sequences present from low (1) to highly abundant (over 2000) copy number in the P. infestans genome, based on quantitative PCR analysis. Putative short direct repeat sequences (6-14 bp) flanking the elements were also identified for eight of the SINEs. Predicted SINEs were named in a series prefixed infSINE (for infestans-SINE). Two SINEs were apparently present as multimers of tRNA-related units; four copies of a related unit for infSINEr, and two unrelated units for infSINEz. Two SINEs, infSINEh and infSINEi, were typically located within 400 bp of each other. These were also the only two elements identified as being actively transcribed in the mycelial stage of P. infestans by RT-PCR. It is possible that infSINEh and infSINEi represent active retrotransposons in P. infestans. Based on the quantitative PCR estimates of copy number for all of the elements identified, tRNA-related SINEs were estimated to comprise 0.3% of the 250 Mb P. infestans genome. InfSINE-related sequences were found to occur in species throughout the genus Phytophthora. However, seven elements were shown to be exclusive to P. infestans.     

Characterization of an abundant short interspersed nuclear element (SINE) present in Canis familiaris

A short interspersed nuclear element (Can SINE) of ∼130–150 bp was cloned and characterized from Canis familiaris. We demonstrate that this element is interspersed, present approximately every 5–8.3 kbp, and many are sufficiently close to allow IRS (interspersed repetitive DNA sequences) PCR. Sequence analysis of >20 Can SINEs from the dog has identified a conserved region that was used to design oligonucleotides for IRS PCR. Since Can SINEs are not present in human or rodent genomes, IRS PCR using oligonucleotides directed to the conserved region of Can SINEs can be used to simplify analysis of canid DNA in somatic cell hybrids, as well as in large insert cloning vectors. We demonstrate that the canid IRS products are polymorphic and could be developed as genetic markers for filter-based genotyping in this organism. Received: 23 July 1997 / Accepted: 9 September 1997     

Evolutionary implications of multiple SINE insertions in an intronic region from diverse mammals

An analysis of the nuclear β-fibrinogen intron 7 locus from 30 taxa representing 12 placental orders of mammals reveals the enriched occurrences of short interspersed element (SINE) insertion events. Mammalian-wide interspersed repeats (MIRs) are present at orthologous sites of all examined species except those in the order Rodentia. The higher substitution rate in mouse and a rare MIR deletion from rat account for the absence of MIR in the rodents. A minimum of five lineage-specific SINE sequences are also found to have independently inserted into this intron in Carnivora, Artiodactyla and Lagomorpha. In the case of Carnivora, the unique amplification pattern of order-specific CAN SINE provides important evidence for the “pan-carnivore” hypothesis of this repeat element and reveals that the CAN SINE family may still be active today. Particularly interesting is the finding that all identified lineage-specific SINE elements show a strong tendency to insert within or in very close proximity to the preexisting MIRs for their efficient integrations, suggesting that the MIR element is a hot spot for successive insertions of other SINEs. The unexpected MIR excision as a result of a random deletion in the rat intron locus and the non-random site targeting detected by this study indicate that SINEs actually have a greater insertional flexibility and regional specificity than had previously been recognized. Implications for SINE sequence evolution upon and following integration, as well as the fascinating interactions between retroposons and the host genomes are discussed.