Ere, a Family of Short Interspersed Elements in the Genomes of Odd-Toed Ungulates (Perissodactyla).

Short Interspersed Elements (SINEs) are eukaryotic retrotransposons transcribed by RNA polymerase III (pol III). Many mammalian SINEs (T+ SINEs) contain a polyadenylation signal (AATAAA), a pol III transcription terminator, and an A-rich tail in their 3'-end. The RNAs of such SINEs have the capacity for AAUAAA-dependent polyadenylation, which is unique to pol III-generated transcripts. The structure, evolution, and polyadenylation of the Ere SINE of ungulates (horses, rhinos, and tapirs) were investigated in this study. A bioinformatics analysis revealed the presence of up to ~4 × 105 Ere copies in representatives of all three families. These copies can be classified into two large subfamilies, EreA and EreB, the former distinguished by an additional 60 bp sequence. The 3'-end of numerous EreA and all EreB copies exhibit a 50 bp sequence designated as a terminal domain (TD). The Ere family can be further subdivided into subfamilies EreA_0TD, EreA_1TD, EreB_1TD, and EreB_2TD, depending on the presence and number of terminal domains (TDs). Only EreA_0TD copies can be assigned to T+ SINEs as they contain the AATAAA signal and the TCTTT transcription terminator. The analysis of young Ere copies identified by comparison with related perissodactyl genomes revealed that EreA_0TD and, to a much lesser extent, EreB_2TD have retained retrotranspositional activity in the recent evolution of equids and rhinoceroses. The targeted mutagenesis and transfection of HeLa cells were used to identify sequences in equine EreA_0TD that are critical for the polyadenylation of its pol III transcripts. In addition to AATAAA and the transcription terminator, two sites in the 3' half of EreA, termed the ß and τ signals, were found to be essential for this process. The evolution of Ere, with a particular focus on the emergence of T+ SINEs, as well as the polyadenylation signals are discussed in comparison with other T+ SINEs.

SINEs as Potential Expression Cassettes: Impact of Deletions and Insertions on Polyadenylation and Lifetime of B2 and Ves SINE Transcripts Generated by RNA Polymerase III.

Short Interspersed Elements (SINEs) are common in the genomes of most multicellular organisms. They are transcribed by RNA polymerase III from an internal promoter comprising boxes A and B. As transcripts of certain SINEs from mammalian genomes can be polyadenylated, such transcripts should contain the AATAAA sequence as well as those called ß- and τ-signals. One of the goals of this work was to evaluate how autonomous and independent other SINE parts are ß- and τ-signals. Extended regions outside of ß- and τ-signals were deleted from SINEs B2 and Ves and the derived constructs were used to transfect HeLa cells in order to evaluate the relative levels of their transcripts as well as their polyadenylation efficiency. If the deleted regions affected boxes A and B, the 5'-flanking region of the U6 RNA gene with the external promoter was inserted upstream. Such substitution of the internal promoter in B2 completely restored its transcription. Almost all tested deletions/substitutions did not reduce the polyadenylation capacity of the transcripts, indicating a weak dependence of the function of ß- and τ-signals on the neighboring sequences. A similar analysis of B2 and Ves constructs containing a 55-bp foreign sequence inserted between ß- and τ-signals showed an equal polyadenylation efficiency of their transcripts compared to those of constructs without the insertion. The acquired poly(A)-tails significantly increased the lifetime and thus the cellular level of such transcripts. The data obtained highlight the potential of B2 and Ves SINEs as cassettes for the expression of relatively short sequences for various applications.

Nucleotide Context Can Modulate Promoter Strength in Genes Transcribed by RNA Polymerase III.

The small nuclear RNAs 4.5SH and 4.5SI were characterized only in mouse-like rodents; their genes originate from 7SL RNA and tRNA, respectively. Similar to many genes transcribed by RNA polymerase III (pol III), the genes of 4.5SH and 4.5SI RNAs include boxes A and B, forming an intergenic pol III-directed promoter. In addition, their 5'-flanking sequences have TATA-like boxes at position -31/-24, also required for efficient transcription. The patterns of the three boxes notably differ in the 4.5SH and 4.5SI RNA genes. The A, B, and TATA-like boxes were replaced in the 4.5SH RNA gene with the corresponding boxes in the 4.5SI RNA gene to evaluate their effect on the transcription of transfected constructs in HeLa cells. Simultaneous replacement of all three boxes decreased the transcription level by 40%, which indicates decreased promoter activity in a foreign gene. We developed a new approach to compare the promoter strength based on the competition of two co-transfected gene constructs when the proportion between the constructs modulates their relative activity. This method demonstrated that the promoter activity of 4.5SI is 12 times that of 4.5SH. Unexpectedly, the replacement of all three boxes of the weak 4.5SH promoter with those of the strong 4.5SI gene significantly reduced, rather than enhanced, the promoter activity. Thus, the strength of a pol III-directed promoter can depend on the nucleotide environment of the gene.

Tail Wags Dog's SINE: Retropositional Mechanisms of Can SINE Depend on Its A-Tail Structure.

SINEs, non-autonomous short retrotransposons, are widespread in mammalian genomes. Their transcripts are generated by RNA polymerase III (pol III). Transcripts of certain SINEs can be polyadenylated, which requires polyadenylation and pol III termination signals in their sequences. Our sequence analysis divided Can SINEs in canids into four subfamilies, older a1 and a2 and younger b1 and b2. Can_b2 and to a lesser extent Can_b1 remained retrotranspositionally active, while the amplification of Can_a1 and Can_a2 ceased long ago. An extraordinarily high Can amplification was revealed in different dog breeds. Functional polyadenylation signals were analyzed in Can subfamilies, particularly in fractions of recently amplified, i.e., active copies. The transcription of various Can constructs transfected into HeLa cells proposed AATAAA and (TC)n as functional polyadenylation signals. Our analysis indicates that older Can subfamilies (a1, a2, and b1) with an active transcription terminator were amplified by the T+ mechanism (with polyadenylation of pol III transcripts). In the currently active Can_b2 subfamily, the amplification mechanisms with (T+) and without the polyadenylation of pol III transcripts (T-) irregularly alternate. The active transcription terminator tends to shorten, which renders it nonfunctional and favors a switch to the T- retrotransposition. The activity of a truncated terminator is occasionally restored by its elongation, which rehabilitates the T+ retrotransposition for a particular SINE copy.

Analysis of SINE Families B2, Dip, and Ves with Special Reference to Polyadenylation Signals and Transcription Terminators.

Short Interspersed Elements (SINEs) are eukaryotic non-autonomous retrotransposons transcribed by RNA polymerase III (pol III). The 3'-terminus of many mammalian SINEs has a polyadenylation signal (AATAAA), pol III transcription terminator, and A-rich tail. The RNAs of such SINEs can be polyadenylated, which is unique for pol III transcripts. Here, B2 (mice and related rodents), Dip (jerboas), and Ves (vespertilionid bats) SINE families were thoroughly studied. They were divided into subfamilies reliably distinguished by relatively long indels. The age of SINE subfamilies can be estimated, which allows us to reconstruct their evolution. The youngest and most active variants of SINE subfamilies were given special attention. The shortest pol III transcription terminators are TCTTT (B2), TATTT (Ves and Dip), and the rarer TTTT. The last nucleotide of the terminator is often not transcribed; accordingly, the truncated terminator of its descendant becomes nonfunctional. The incidence of complete transcription of the TCTTT terminator is twice higher compared to TTTT and thus functional terminators are more likely preserved in daughter SINE copies. Young copies have long poly(A) tails; however, they gradually shorten in host generations. Unexpectedly, the tail shortening below A10 increases the incidence of terminator elongation by Ts thus restoring its efficiency. This process can be critical for the maintenance of SINE activity in the genome.

Identification of nucleotide sequences and some proteins involved in polyadenylation of RNA transcribed by Pol III from SINEs.

We have previously reported that not only transcripts of RNA polymerase II (pol II), but also one type of RNA transcribed by RNA polymerase III (pol III), undergo AAUAAA-dependent polyadenylation. Such an unusual feature is inherent in Short Interspersed Elements (SINEs) from genomes of certain mammals. For polyadenylation of its transcript, SINE should contain, besides an AATAAA hexamer and a transcription terminator, two specific regions: ß, located downstream of box B of a promoter, and τ, preceding AATAAA. Here, using nucleotide substitutions in SINEs B2 (mouse) and Ves (bat), we identified nucleotides of ß regions necessary for polyadenylation of their transcripts. These sequences (ß signals) are the following: ACCACATgg in B2 and GGGCATGT in Ves. Using this approach, we identified τ signal of SINE B2 (GCTACagTGTACTTACAT), where TGTA tetramer is most important for polyadenylation. In Ves, τ region is a long polypyrimidine motif which is able to interact with PTB protein in Ves transcripts. We demonstrated by knockdown that B2 and Ves transcript polyadenylation is performed by canonical poly(A) polymerase with the participation of proteins CSPF-160 and Fip1, the known factors of mRNA polyadenylation. We also showed that a factor CFIm partaking in polyadenylation of many mRNAs, is involved only in polyadenylation of B2 transcripts. CFIm seems to interact with τ signal of В2 RNA and thereby facilitates the recruiting of other proteins engaged in polyadenylation. Thus, SINEs utilize at least some proteins involved in polyadenylation of pol II transcripts to polyadenylate their pol III transcripts.

TATA-Like Boxes in RNA Polymerase III Promoters: Requirements for Nucleotide Sequences.

tRNA and some other non-coding RNA genes are transcribed by RNA polymerase III (pol III), due to the presence of intragenic promoter, consisting of boxes A and B spaced by 30-40 bp. Such pol III promoters, called type 2, are also intrinsic to Short Interspersed Elements (SINEs). The contribution of 5'-flanking sequences to the transcription efficiency of genes containing type 2 promoters is still studied insufficiently. Here, we studied this issue, focusing on the genes of two small non-coding RNAs (4.5SH and 4.5SI), as well as B1 and B2 SINEs from the mouse genome. We found that the regions from position -31 to -24 may significantly influence the transcription of genes and SINEs. We studied the influence of nucleotide substitutions in these sites, representing TATA-like boxes, on transcription of 4.5SH and 4.5SI RNA genes. As a rule, the substitutions of A and T to G or C reduced the transcription level, although the replacement of C with A also lowered it. In 4.5SH gene, five distal nucleotides of -31/-24 box (TTCAAGTA) appeared to be the most important, while in the box -31/-24 of 4.5SI gene (CTACATGA), all nucleotides, except for the first one, contributed significantly to the transcription efficiency. Random sequences occurring at positions -31/-24 upstream of SINE copies integrated into genome, promoted their transcription with different efficacy. In the 5'-flanking sequences of 4.5SH and 4.5SI RNA genes, the recognition sites of CREB, C/EBP, and Sp1 factors were found, and their deletion decreased the transcription.

Influence of 5'-flanking sequence on 4.5SI RNA gene transcription by RNA polymerase III.

Short nuclear 4.5SI RNA can be found in three related rodent families. Its function remains unknown. The genes of 4.5SI RNA contain an internal promoter of RNA polymerase III composed of the boxes A and B. Here, the effect of the sequence immediately upstream of the mouse 4.5SI RNA gene on its transcription was studied. The gene with deletions and substitutions in the 5'-flanking sequence was used to transfect HeLa cells and its transcriptional activity was evaluated from the cellular level of 4.5SI RNA. Single-nucleotide substitutions in the region adjacent to the transcription start site (positions -2 to -8) decreased the expression activity of the gene down to 40%-60% of the control. The substitution of the conserved pentanucleotide AGAAT (positions -14 to -18) could either decrease (43%-56%) or increase (134%) the gene expression. A TATA-like box (TACATGA) was found at positions -24 to -30 of the 4.5SI RNA gene. Its replacement with a polylinker fragment of the vector did not decrease the transcription level, while its replacement with a GC-rich sequence almost completely (down to 2%-5%) suppressed the transcription of the 4.5SI RNA gene. The effect of plasmid sequences bordering the gene on its transcription by RNA polymerase III is discussed.

Heat shock increases lifetime of a small RNA and induces its accumulation in cells.

4.5SH and 4.5SI RNA are two abundant small non-coding RNAs specific for several related rodent families including Muridae. These RNAs have a number of common characteristics such as the short length (about 100nt), transcription by RNA polymerase III, and origin from Short Interspersed Elements (SINEs). However, their stabilities in cells substantially differ: the half-life of 4.5SH RNA is about 20min, while that of 4.5SI RNA is 22h. Here we studied the influence of cell stress such as heat shock or viral infection on these two RNAs. We found that the level of 4.5SI RNA did not change in stressed cells; whereas heat shock increased the abundance of 4.5SH RNA 3.2-10.5 times in different cell lines; and viral infection, 5 times. Due to the significant difference in the turnover rates of these two RNAs, a similar activation of their transcription by heat shock increases the level of the short-lived 4.5SH RNA and has minor effect on the level of the long-lived 4.5SI RNA. In addition, the accumulation of 4.5SH RNA results not only from the induction of its transcription but also from a substantial retardation of its decay. To our knowledge, it is the first example of a short-lived non-coding RNA whose elongated lifetime contributes significantly to its accumulation in stressed cells.

Polyadenylation of RNA transcribed from mammalian SINEs by RNA polymerase III: Complex requirements for nucleotide sequences.

It is generally accepted that only transcripts synthesized by RNA polymerase II (e.g., mRNA) were subject to AAUAAA-dependent polyadenylation. However, we previously showed that RNA transcribed by RNA polymerase III (pol III) from mouse B2 SINE could be polyadenylated in an AAUAAA-dependent manner. Many species of mammalian SINEs end with the pol III transcriptional terminator (TTTTT) and contain hexamers AATAAA in their A-rich tail. Such SINEs were united into Class T(+), whereas SINEs lacking the terminator and AATAAA sequences were classified as T(-). Here we studied the structural features of SINE pol III transcripts that are necessary for their polyadenylation. Eight and six SINE families from classes T(+) and T(-), respectively, were analyzed. The replacement of AATAAA with AACAAA in T(+) SINEs abolished the RNA polyadenylation. Interestingly, insertion of the polyadenylation signal (AATAAA) and pol III transcription terminator in T(-) SINEs did not result in polyadenylation. The detailed analysis of three T(+) SINEs (B2, DIP, and VES) revealed areas important for the polyadenylation of their pol III transcripts: the polyadenylation signal and terminator in A-rich tail, ß region positioned immediately downstream of the box B of pol III promoter, and τ region located upstream of the tail. In DIP and VES (but not in B2), the τ region is a polypyrimidine motif which is also characteristic of many other T(+) SINEs. Most likely, SINEs of different mammals acquired these structural features independently as a result of parallel evolution.

A 5'-3' terminal stem in small non-coding RNAs extends their lifetime.

4.5SI and 4.5SH are two non-coding RNAs about 100nt long, synthesized by RNA polymerase III in cells of various rodents including mice, rats, and hamsters. The first RNA is long-lived whereas the half-life of the second is only 20min. We previously found that the 16bp double-stranded structure (stem), formed by 4.5SI RNA termini, contributes essentially to the long lifetime of this RNA (Koval et al., 2012). The rapid decay of 4.5SH RNA seems to be related to the lack of a similar structure in this RNA. The aim of this work was to verify whether the lifetime of any other short-lived non-coding RNA can be prolonged following creation of the double-stranded structure with its terminal regions. Here RNAs transcribed by RNA polymerase III from short interspersed elements (SINEs) B2 and Rhin-1 from the genomes of mouse and horseshoe bat, respectively, were used. Replacement of 16nt at the 3'-terminal region by the sequence complementary to the 5' end region of B2 and Rhin-1 RNA increased their half-life more than 4 fold. In addition, we demonstrated that shortening of the terminal stem from 16 to 8bp decreased only slightly the 4.5SI RNA lifetime. Finally, we showed that the disruption of an internal (non-terminal) stem in 4.5SI RNA did not accelerate its decay in cells. Possible mechanisms of the small non-coding RNA lifetime extension are discussed.

SINEBase: a database and tool for SINE analysis.

SINEBase (http://sines.eimb.ru) integrates the revisited body of knowledge about short interspersed elements (SINEs). A set of formal definitions concerning SINEs was introduced. All available sequence data were screened through these definitions and the genetic elements misidentified as SINEs were discarded. As a result, 175 SINE families have been recognized in animals, flowering plants and green algae. These families were classified by the modular structure of their nucleotide sequences and the frequencies of different patterns were evaluated. These data formed the basis for the database of SINEs. The SINEBase website can be used in two ways: first, to explore the database of SINE families, and second, to analyse candidate SINE sequences using specifically developed tools. This article presents an overview of the database and the process of SINE identification and analysis.

Complementarity of end regions increases the lifetime of small RNAs in mammalian cells.

Two RNAs (4.5SH and 4.5SI) with unknown functions share a number of features: short length (about 100 nt), transcription by RNA polymerase III, predominately nuclear localization, the presence in various tissues, and relatively narrow taxonomic distribution (4 and 3 rodent families, respectively). It was reported that 4.5SH RNA turns over rapidly, whereas 4.5SI RNA is stable in the cell, but their lifetimes remained unknown. We showed that 4.5SH is indeed short-lived (t(1/2)~18 min) and 4.5SI is long-lived (t(1/2)~22 h) in Krebs ascites carcinoma cells. The RNA structures specifying rapid or slow decay of different small cellular RNAs remain unstudied. We searched for RNA structural features that determine the short lifetime of 4.5SH in comparison with the long lifetime of 4.5SI RNA. The sequences of genes of 4.5SH and 4.5SI RNAs were altered and human cells (HeLa) were transfected with these genes. The decay rate of the original and altered RNAs was measured. The complementarity of 16-nt end regions of 4.5SI RNA proved to contribute to its stability in cells, whereas the lack of such complementarity in 4.5SH RNA caused its rapid decay. Possible mechanisms of the phenomenon are discussed.

SNOntology: Myriads of novel snoRNAs or just a mirage?

BACKGROUND: Small nucleolar RNAs (snoRNAs) are a large group of non-coding RNAs (ncRNAs) that mainly guide 2'-O-methylation (C/D RNAs) and pseudouridylation (H/ACA RNAs) of ribosomal RNAs. The pattern of rRNA modifications and the set of snoRNAs that guide these modifications are conserved in vertebrates. Nearly all snoRNA genes in vertebrates are localized in introns of other genes and are processed from pre-mRNAs. Thus, the same promoter is used for the transcription of snoRNAs and host genes. RESULTS: The series of studies by Dahai Zhu and coworkers on snoRNAs and their genes were critically considered. We present evidence that dozens of species-specific snoRNAs that they described in vertebrates are experimental artifacts resulting from the improper use of Northern hybridization. The snoRNA genes with putative intrinsic promoters that were supposed to be transcribed independently proved to contain numerous substitutions and are, most likely, pseudogenes. In some cases, they are localized within introns of overlooked host genes. Finally, an increased number of snoRNA genes in mammalian genomes described by Zhu and coworkers is also an artifact resulting from two mistakes. First, numerous mammalian snoRNA pseudogenes were considered as genes, whereas most of them are localized outside of host genes and contain substitutions that question their functionality. Second, Zhu and coworkers failed to identify many snoRNA genes in non-mammalian species. As an illustration, we present 1352 C/D snoRNA genes that we have identified and annotated in vertebrates. CONCLUSIONS: Our results demonstrate that conclusions based only on databases with automatically annotated ncRNAs can be erroneous. Special investigations aimed to distinguish true RNA genes from their pseudogenes should be done. Zhu and coworkers, as well as most other groups studying vertebrate snoRNAs, give new names to newly described homologs of human snoRNAs, which significantly complicates comparison between different species. It seems necessary to develop a uniform nomenclature for homologs of human snoRNAs in other vertebrates, e.g., human gene names prefixed with several-letter code denoting the vertebrate species.

SINEs.

Short interspersed elements (SINEs) are mobile genetic elements that invade the genomes of many eukaryotes. Since their discovery about 30 years ago, many gaps in our understanding of the biology and function of SINEs have been filled. This review summarizes the past and recent advances in the studies of SINEs. The structure and origin of SINEs as well as the processes involved in their amplification, transcription, RNA processing, reverse transcription, and integration of a SINE copy into the genome are considered. Then we focus on the significance of SINEs for the host genomes. While these genomic parasites can be deleterious to the cell, the long-term being in the genome has made SINEs a valuable source of genetic variation providing regulatory elements for gene expression, alternative splice sites, polyadenylation signals, and even functional RNA genes.

Additional box B of RNA polymerase III promoter in SINE B1 can be functional.

Many genes of small RNAs and short interspersed elements (SINEs) are transcribed by RNA polymerase III due to an internal promoter that is composed of two boxes (A and B) spaced by 30-45bp. Rodent SINE B1 originated from 7SL RNA, and a 29-bp tandem duplication took place in B1 at an early stage of its evolution. As a result of this duplication, an additional box B (named B') located at a distance of 79-82bp from box A arose in SINE B1. Here we have shown that despite the unusually large distance between boxes A and B', they can form an active promoter. In chinchillas, guinea pigs, and other rodents belonging to clade Ctenohystrica, structure of the B' box was well preserved and closely resembles the canonical B box. One may suggest therefore, that box B' can functionally replace box B in those copies of B1 where the latter has lost activity due to mutations.

Nucleotide sequences of B1 SINE and 4.5S(I) RNA support a close relationship of zokors to blind mole rats (Spalacinae) and bamboo rats (Rhizomyinae).

Until recently, zokors (Myospalacinae) were assigned to the Cricetidae family. However, analysis of mitochondrial and nuclear genes suggests a sister relationship between zokors and subterranean rodents of the Spalacidae family, namely blind mole rats (Spalacinae) and bamboo rats (Rhizomyinae). Here, we cloned and sequenced copies of the B1 short interspersed element (SINE) from the genome of zokor Myospalax psilurus. The consensus nucleotide sequence of zokor B1 was very similar to spalacids and rhizomyids, but not cricetids. Similar to spalacids (Spalax microphthalmus) and rhizomyids (Tachyoryctes splendens), zokor contained two variants of the 4.5S(I) small nuclear RNA. The longer variant (L-variant, 104 nucleotides) was found only in zokor, spalacids and rhizomyids. The short, or S-variant (98 nucleotides), had a wider distribution; however, analysis of the nucleotide sequences of S-variants of 4.5S(I) RNA confirmed that zokors are closely related to spalacids and rhizomyids, but not to cricetids. The evolution of the 4.5S(I) RNA genes and pseudogenes is discussed.

4.5SI RNA genes and the role of their 5'-flanking sequences in the gene transcription.

4.5S(I) RNA is a small nuclear RNA synthesized by RNA polymerase III and detected in rodents of only four families. Hundreds of copies of this RNA retropseudogenes are interspersed throughout the mouse (Mus musculus) and rat (Rattus norvegicus) genomes. We found a single locus containing 4.5S(I) RNA genes in the genomes of these rodents. The locus harbors three genes and occupies 80 kb on M. musculus chromosome 6 and 44 kb on R. norvegicus chromosome 4. Two long duplications seem to have taken place during evolution of this locus. Two mouse 4.5S(I) RNA genes were used for a study of the role of 5'-flanking sequences in transcription in vitro and ex vivo. We found that removal of these DNA sequences resulted in a dramatic reduction of transcription though an internal promoter for RNA polymerase III was preserved in 4.5S(I) RNA genes. Thus, 5'-flanking sequences (from -1 to -90) containing conserved regions are important for 4.5S(I) RNA gene expression.

5'-flanking sequences can dramatically influence 4.5SH RNA gene transcription by RNA-polymerase III.

4.5SH RNA is a 94 nt small nuclear RNA with an unknown function. Hundreds of its genes are present in the genomes of rodents of six families including Muridae. 4.5SH RNA genes contain an internal RNA-polymerase III promoter consisting of A and B boxes. Here we studied the influence of 5'-flanking sequences on the transcription of a mouse 4.5SH RNA gene. We found that replacement of the upstream sequence can dramatically change the 4.5SH RNA gene transcription efficiency. Various DNA fragments inserted immediately upstream from 4.5SH RNA gene completely inhibited its in vitro transcription, whereas others promoted it. The shortening of the native mouse 5'-flanking sequence of 4.5SH RNA gene to 42 bp resulted in the activation of an additional illegal transcription start site in upstream region. Transcription of the 4.5SH RNA gene with various upstream sequences in transfected HeLa cells revealed the differences between the tests performed in vivo and in vitro: in whole cells, only the construct with 5'-flanking native sequence could be transcribed. Apparently, at least some regions of the native 5'-flanking sequence of 4.5SH RNA genes have been selected during evolution for high transcription activity.

5S rRNA-derived and tRNA-derived SINEs in fruit bats.

Most short retroposons (SINEs) descend from cellular tRNA of 7SL RNA. Here, four new SINEs were found in megabats (Megachiroptera) but neither in microbats nor in other mammals. Two of them, MEG-RS and MEG-RL, descend from another cellular RNA, 5S rRNA; one (MEG-T2) is a tRNA-derived SINE; and MEG-TR is a hybrid tRNA/5S rRNA SINE. Insertion locus analysis suggests that these SINEs were active in the recent fruit bat evolution. Analysis of MEG-RS and MEG-RL in comparison with other few 5S rRNA-derived SINEs demonstrates that the internal RNA polymerase III promoter is their most invariant region, while the secondary structure is more variable. The mechanisms underlying the modular structure of these and other SINEs as well as their variation are discussed. The scenario of evolution of MEG SINEs is proposed.