Emergence of master sequences in families of retroposons derived from 7sl RNA

Rise and SINE: roles of transcription factors and retrotransposons in zygotic genome activation

In sexually reproducing organisms, life begins with the fusion of transcriptionally silent gametes, the oocyte and sperm. Although initiation of transcription in the embryo, known as zygotic genome activation (ZGA), is universally required for development, the transcription factors regulating this process are poorly conserved. In this Perspective, we discuss recent insights into the mechanisms of ZGA in totipotent mammalian embryos, namely ZGA regulation by several transcription factors, including by orphan nuclear receptors (OrphNRs) such as the pioneer transcription factor NR5A2, and by factors of the DUX, TPRX and OBOX families. We performed a meta-analysis and compiled a list of pan-ZGA genes, and found that most of these genes are indeed targets of the above transcription factors. Remarkably, more than a third of these ZGA genes appear to be regulated both by OrphNRs such as NR5A2 and by OBOX proteins, whose motifs co-occur in SINE B1 retrotransposable elements, which are enriched near ZGA genes. We propose that ZGA in mice is activated by recruitment of multiple transcription factors to SINE B1 elements that function as enhancers, and discuss a potential relevance of this mechanism to Alu retrotransposable elements in human ZGA.

The role of SRP9/SRP14 in regulating Alu RNA

SRP9/SRP14 is a protein heterodimer that plays a critical role in the signal recognition particle through its interaction with the scaffolding signal recognition particle RNA (7SL). SRP9/SRP14 binding to 7SL is mediated through a conserved structural motif that is shared with the primate-specific Alu RNA. Alu RNA are transcription products of Alu elements, a retroelement that comprises ~10% of the human genome. Alu RNA are involved in myriad biological processes and are dysregulated in several human disease states. This review focuses on the roles SRP9/SRP14 has in regulating Alu RNA diversification, maturation, and function. The diverse mechanisms through which SRP9/SRP14 regulates Alu RNA exemplify the breadth of protein-mediated regulation of non-coding RNA.

Repetitive elements in aging and neurodegeneration

Repetitive elements (REs), such as transposable elements (TEs) and satellites, comprise much of the genome. Here, we review how TEs and (peri)centromeric satellite DNA may contribute to aging and neurodegenerative disorders, including amyotrophic lateral sclerosis (ALS). Alterations in RE expression, retrotransposition, and chromatin microenvironment may shorten lifespan, elicit neurodegeneration, and impair memory and movement. REs may cause these phenotypes via DNA damage, protein sequestration, insertional mutagenesis, and inflammation. We discuss several TE families, including gypsy, HERV-K, and HERV-W, and how TEs interact with various factors, including transactive response (TAR) DNA-binding protein 43 kDa (TDP-43) and the siRNA and piwi-interacting (pi)RNA systems. Studies of TEs in neurodegeneration have focused on Drosophila and, thus, further examination in mammals is needed. We suggest that therapeutic silencing of REs could help mitigate neurodegenerative disorders.

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.

Alu RNA and their roles in human disease states

Alu RNA are implicated in the poor prognosis of several human disease states. These RNA are transcription products of primate specific transposable elements called Alu elements. These elements are extremely abundant, comprising over 10% of the human genome, and 100 to 1000 cytoplasmic copies of Alu RNA per cell. Alu RNA do not have a single universal functional role aside from selfish self-propagation. Despite this, Alu RNA have been found to operate in a diverse set of translational and transcriptional mechanisms. This review will focus on the current knowledge of Alu RNA involved in human disease states and known mechanisms of action. Examples of Alu RNA that are transcribed in a variety of contexts such as introns, mature mRNA, and non-coding transcripts will be discussed. Past and present challenges in studying Alu RNA, and the future directions of Alu RNA in basic and clinical research will also be examined.

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.

PUF60-activated exons uncover altered 3' splice-site selection by germline missense mutations in a single RRM

PUF60 is a splicing factor that binds uridine (U)-rich tracts and facilitates association of the U2 small nuclear ribonucleoprotein with primary transcripts. PUF60 deficiency (PD) causes a developmental delay coupled with intellectual disability and spinal, cardiac, ocular and renal defects, but PD pathogenesis is not understood. Using RNA-Seq, we identify human PUF60-regulated exons and show that PUF60 preferentially acts as their activator. PUF60-activated internal exons are enriched for Us upstream of their 3′ splice sites (3′ss), are preceded by longer AG dinucleotide exclusion zones and more distant branch sites, with a higher probability of unpaired interactions across a typical branch site location as compared to control exons. In contrast, PUF60-repressed exons show U-depletion with lower estimates of RNA single-strandedness. We also describe PUF60-regulated, alternatively spliced isoforms encoding other U-bound splicing factors, including PUF60 partners, suggesting that they are co-regulated in the cell, and identify PUF60-regulated exons derived from transposed elements. PD-associated amino-acid substitutions, even within a single RNA recognition motif (RRM), altered selection of competing 3′ss and branch points of a PUF60-dependent exon and the 3′ss choice was also influenced by alternative splicing of PUF60. Finally, we propose that differential distribution of RNA processing steps detected in cells lacking PUF60 and the PUF60-paralog RBM39 is due to the RBM39 RS domain interactions. Together, these results provide new insights into regulation of exon usage by the 3′ss organization and reveal that germline mutation heterogeneity in RRMs can enhance phenotypic variability at the level of splice-site and branch-site selection.

Alu RNA Modulates the Expression of Cell Cycle Genes in Human Fibroblasts

Alu retroelements, whose retrotransposition requires prior transcription by RNA polymerase III to generate Alu RNAs, represent the most numerous non-coding RNA (ncRNA) gene family in the human genome. Alu transcription is generally kept to extremely low levels by tight epigenetic silencing, but it has been reported to increase under different types of cell perturbation, such as viral infection and cancer. Alu RNAs, being able to act as gene expression modulators, may be directly involved in the mechanisms determining cellular behavior in such perturbed states. To directly address the regulatory potential of Alu RNAs, we generated IMR90 fibroblasts and HeLa cell lines stably overexpressing two slightly different Alu RNAs, and analyzed genome-wide the expression changes of protein-coding genes through RNA-sequencing. Among the genes that were upregulated or downregulated in response to Alu overexpression in IMR90, but not in HeLa cells, we found a highly significant enrichment of pathways involved in cell cycle progression and mitotic entry. Accordingly, Alu overexpression was found to promote transition from G1 to S phase, as revealed by flow cytometry. Therefore, increased Alu RNA may contribute to sustained cell proliferation, which is an important factor of cancer development and progression.

In vivo assembly of eukaryotic signal recognition particle: A still enigmatic process involving the SMN complex

The signal recognition particle (SRP) is a universally conserved non-coding ribonucleoprotein complex that is essential for targeting transmembrane and secretory proteins to the endoplasmic reticulum. Its composition and size varied during evolution. In mammals, SRP contains one RNA molecule, 7SL RNA, and six proteins: SRP9, 14, 19, 54, 68 and 72. Despite a very good understanding of the SRP structure and of the SRP assembly in vitro, how SRP is assembled in vivo remains largely enigmatic. Here we review current knowledge on how the 7SL RNA is assembled with core proteins to form functional RNP particles in cells. SRP biogenesis is believed to take place both in the nucleolus and in the cytoplasm and to rely on the survival of motor neuron complex, whose defect leads to spinal muscular atrophy.

Cardiac circRNAs arise mainly from constitutive exons rather than alternatively spliced exons

Circular RNAs (circRNAs) are a relatively new class of RNA molecules, and knowledge about their biogenesis and function is still in its infancy. It was recently shown that alternative splicing underlies the formation of circular RNAs (circRNA) arising from the Titin (TTN) gene. Since the main mechanism by which circRNAs are formed is still unclear, we hypothesized that alternative splicing, and in particular exon skipping, is a major driver of circRNA production. We performed RNA sequencing on human and mouse hearts, mapped alternative splicing events, and overlaid these with expressed circRNAs at exon-level resolution. In addition, we performed RNA sequencing on hearts of Rbm20 KO mice to address how important Rbm20-mediated alternative splicing is in the production of cardiac circRNAs. In human and mouse hearts, we show that cardiac circRNAs are mostly (∼90%) produced from constitutive exons and less (∼10%) from alternatively spliced exons. In Rbm20 KO hearts, we identified 38 differentially expressed circRNAs of which 12 were produced from the Ttn gene. Even though Ttn appeared the most prominent target of Rbm20 for circularization, we also detected Rbm20-dependent circRNAs arising from other genes including Fan1, Stk39, Xdh, Bcl2l13, and Sorbs1 Interestingly, only Ttn circRNAs seemed to arise from Rbm20-mediated skipped exons. In conclusion, cardiac circRNAs are mostly derived from constitutive exons, suggesting that these circRNAs are generated at the expense of their linear counterpart and that circRNA production impacts the accumulation of the linear mRNA.

Similar Evolutionary Trajectories for Retrotransposon Accumulation in Mammals

The factors guiding retrotransposon insertion site preference are not well understood. Different types of retrotransposons share common replication machinery and yet occupy distinct genomic domains. Autonomous long interspersed elements accumulate in gene-poor domains and their nonautonomous short interspersed elements accumulate in gene-rich domains. To determine genomic factors that contribute to this discrepancy we analyzed the distribution of retrotransposons within the framework of chromosomal domains and regulatory elements. Using comparative genomics, we identified large-scale conserved patterns of retrotransposon accumulation across several mammalian genomes. Importantly, retrotransposons that were active after our sample-species diverged accumulated in orthologous regions. This suggested a similar evolutionary interaction between retrotransposon activity and conserved genome architecture across our species. In addition, we found that retrotransposons accumulated at regulatory element boundaries in open chromatin, where accumulation of particular retrotransposon types depended on insertion size and local regulatory element density. From our results, we propose a model where density and distribution of genes and regulatory elements canalize retrotransposon accumulation. Through conservation of synteny, gene regulation and nuclear organization, mammalian genomes with dissimilar retrotransposons follow similar evolutionary trajectories.

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.

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.

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.

Alu and b1 repeats have been selectively retained in the upstream and intronic regions of genes of specific functional classes

Alu and B1 repeats are mobile elements that originated in an initial duplication of the 7SL RNA gene prior to the primate-rodent split about 80 million years ago and currently account for a substantial fraction of the human and mouse genome, respectively. Following the primate-rodent split, Alu and B1 elements spread independently in each of the two genomes in a seemingly random manner, and, according to the prevailing hypothesis, negative selection shaped their final distribution in each genome by forcing the selective loss of certain Alu and B1 copies. In this paper, contrary to the prevailing hypothesis, we present evidence that Alu and B1 elements have been selectively retained in the upstream and intronic regions of genes belonging to specific functional classes. At the same time, we found no evidence for selective loss of these elements in any functional class. A subset of the functional links we discovered corresponds to functions where Alu involvement has actually been experimentally validated, whereas the majority of the functional links we report are novel. Finally, the unexpected finding that Alu and B1 elements show similar biases in their distribution across functional classes, despite having spread independently in their respective genomes, further supports our claim that the extant instances of Alu and B1 elements are the result of positive selection.

Despite their fundamental role in cell regulation, genes account for less than 1% of the human genome. Recent studies have shown that non-genic regions of our DNA may also play an important functional role in human cells. In this paper, we study Alu and B elements, a specific class of such non-genic elements that account for ∼10% of the human genome and ∼7% of the mouse genome respectively. We show that, contrary to the prevailing hypothesis, Alu and B elements have been preferentially retained in the proximity of genes that perform specific functions in the cell. In contrast, we found no evidence for selective loss of these elements in any functional class. Several of the functional classes that we have linked to Alu and B elements are central to the proper working of the cell, and their disruption has previously been shown to lead to the onset of disease. Interestingly, the DNA sequences of Alu and B elements differ substantially between human and mouse, thus hinting at the existence of a potentially large number of non-conserved regulatory elements.

The pivotal roles of TIA proteins in 5' splice-site selection of alu exons and across evolution

More than 5% of alternatively spliced internal exons in the human genome are derived from Alu elements in a process termed exonization. Alus are comprised of two homologous arms separated by an internal polypyrimidine tract (PPT). In most exonizations, splice sites are selected from within the same arm. We hypothesized that the internal PPT may prevent selection of a splice site further downstream. Here, we demonstrate that this PPT enhanced the selection of an upstream 5′ splice site (5′ss), even in the presence of a stronger 5′ss downstream. Deletion of this PPT shifted selection to the stronger downstream 5′ss. This enhancing effect depended on the strength of the downstream 5′ss, on the efficiency of base-pairing to U1 snRNA, and on the length of the PPT. This effect of the PPT was mediated by the binding of TIA proteins and was dependent on the distance between the PPT and the upstream 5′ss. A wide-scale evolutionary analysis of introns across 22 eukaryotes revealed an enrichment in PPTs within ∼20 nt downstream of the 5′ss. For most metazoans, the strength of the 5′ss inversely correlated with the presence of a downstream PPT, indicative of the functional role of the PPT. Finally, we found that the proteins that mediate this effect, TIA and U1C, and in particular their functional domains, are highly conserved across evolution. Overall, these findings expand our understanding of the role of TIA1/TIAR proteins in enhancing recognition of exons, in general, and Alu exons, in particular.

Human genes are composed of functional regions, termed exons, separated by non-functional regions, termed introns. Intronic sequences may gradually accumulate mutations and subsequently become recognized by the splicing machinery as exons, a process termed exonization. Alu elements are prone to undergo exonization: more than 5% of alternatively spliced internal exons in the human genome originate from Alu elements. A typical Alu element is ∼300 nucleotides long, consisting of two arms separated by a polypyrimdine tract (PPT). Interestingly, in most cases, exonization occurs almost exclusively within either the right arm or the left, not both. Here we found that the PPT between the two arms serves as a binding site for TIA proteins and prevents the exon selection process from expanding into downstream regions. To obtain a wider overview of TIA function, we performed a cross-evolutionary analysis within 22 eukaryotes of this protein and of U1C, a protein known to interact with it, and found that functional regions of both these proteins were highly conserved. These findings highlight the pivotal role of TIA proteins in 5′ splice-site selection of Alu exons and exon recognition in general.

Characterization of a novel SINE superfamily from invertebrates: "Ceph-SINEs" from the genomes of squids and cuttlefish

Five tRNA-derived short interspersed repetitive elements (SINEs), named SepiaSINE, Sepioth-SINE1, Sepioth-SINE2A, Sepioth-SINE2B and OegopSINE, were isolated from the genomes of three decabrachian species [Sepia officinalis (order Sepiida), Sepiotheuthis lessoniana (suborder Myopsida), and Mastigoteuthis cordiformes (suborder Oegopsida)], by random sequencing and genome screening. In addition, two tRNA-derived SINEs, named IdioSINE1 and IdioSINE2, were further detected from EST (expressed sequence tag) data of Idiosepius paradoxus (order Idiosepiida), using a GenBank FASTA search with a conserved sequence of the SepiaSINE as the query. All the isolated SINEs had a common and unique highly conserved 149-bp sequence in their central structures (Sepioth-SINE2B and IdioSINEs, however, had a continuous 73-bp deletion in the conserved region.), and are therefore grouped as the fourth SINE superfamily "Ceph-SINEs", following the CORE-SINE, V-SINE, and DeuSINE superfamilies. Our analysis suggested that the central conserved region called the "Ceph-domain" might have originated before the diversification of cephalopods (505 myr ago). A sequence alignment of Sepioth-SINE1, Sepioth-SINE2A, and Sepioth-SINE2B demonstrated that Sepioth-SINE2A has a chimeric structure shared with two other SINEs. The above relationship suggests possible template switching in the central conserved domain during reverse transcription for the birth of Sepioth-SINE2A, providing the possibility that the presence of the conserved domain contributed to yield a variety of SINEs during evolution. Furthermore, the distributions of the isolated SINEs showed that order Sepiida, suborders Oegopsida and Myopsida, and order Idiosepiida have their own independent SINE(s), and suggest that order Sepiida can be largely separated into two groups, with clarification of the phylogenetic relatedness between subfamily Sepioteuthinae and the other loliginid squids.

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.

Alternative splicing of Alu exons--two arms are better than one

Alus, primate-specific retroelements, are the most abundant repetitive elements in the human genome. They are composed of two related but distinct monomers, left and right arms. Intronic Alu elements may acquire mutations that generate functional splice sites, a process called exonization. Most exonizations occur in right arms of antisense Alu elements, and are alternatively spliced. Here we show that without the left arm, exonization of the right arm shifts from alternative to constitutive splicing. This eliminates the evolutionary conserved isoform and may thus be selected against. We further show that insertion of the left arm downstream of a constitutively spliced non-Alu exon shifts splicing from constitutive to alternative. Although the two arms are highly similar, the left arm is characterized by weaker splicing signals and lower exonic splicing regulatory (ESR) densities. Mutations that improve these potential splice signals activate exonization and shift splicing from the right to the left arm. Collaboration between two or more putative splice signals renders the intronic left arm with a pseudo-exon function. Thus, the dimeric form of the Alu element fortuitously provides it with an evolutionary advantage, allowing enrichment of the primate transcriptome without compromising its original repertoire.

Bov-B-mobilized SINEs in vertebrate genomes

Two new short retroposon families (SINEs) have been found in the genome of springhare Pedetes capensis (Rodentia). One of them, Ped-1, originated from 5S rRNA, while the other one, Ped-2, originated from tRNA-derived SINE ID. In contrast to most currently active mammalian SINEs mobilized by L1 long retrotransposon (LINE), Ped-1 and Ped-2 are mobilized by Bov-B, a LINE family of the widely distributed RTE clade. The 3' part of these SINEs originates from two sequences in the 5' and 3' regions of Bov-B. Such bipartite structure of the LINE-derived part has been revealed in all Bov-B-mobilized SINEs known to date (AfroSINE, Bov-tA, Mar-1, and Ped-1/2), which distinguishes them from other SINEs with only a 3' LINE-derived part. Structural analysis and the distribution of Bov-B LINEs and partner SINEs supports the horizontal transfer of Bov-B, while the SINEs emerged independently in lineages with this LINE.

B1 SINEs in different rodent families

B1 SINEs were studied in 22 families covering all major rodent lineages. The number of B1 copies considerably varies, from 1 x 10(4) in Geomyidae to 1 x 10(6) in Myodonta. B1 sequences can be divided into three main structural variants: B1 with a 20-bp tandem duplication (found in Gliridae, Sciuridae, and Aplodontidae), B1 with a 29-bp duplication (found in other families), and proto-B1 without duplication (pB1). These variants can be further subdivided according to their characters, including specific 7-, 9-, or 10-bp deletions. Different B1 subfamilies predominate in different rodent families. The analysis of B1 variants allowed us to propose possible pathways for the evolution of this SINE in the context of rodent evolution.

DNA cleavage and Trp53 differentially affect SINE transcription

Among the cellular responses observed following treatment with DNA-damaging agents is the activation of Short Interspersed Elements (SINEs; retrotransposable genetic elements that comprise over 10% of the human genome). By placing a human SINE (the Alu element) into murine cells, we have previously shown that DNA-damaging agents such as etoposide can induce both upregulation of SINE transcript levels and SINE retrotransposition. A similarly cytotoxic (but not genotoxic) exposure to vincristine was not associated with SINE activation. Here we demonstrate that multiple other genotoxic exposures are associated with upregulation of SINE transcript levels. By comparing the effects of similarly cytotoxic doses of the topoisomerase II inhibitors etoposide and merbarone, we confirm that DNA strand breakage is specifically associated with SINE induction. By evaluating transcription rate and RNA stability, we demonstrate that SINE induction by genotoxic exposure is associated with transcriptional induction and not with transcript stabilization. Finally we demonstrate that SINE induction by genotoxic stress is mediated by a Trp53-independent pathway, and in fact that Trp53 plays an inhibitory role in attenuating the transcriptional induction of SINE elements following exposure to a genotoxic agent. Together these data support a model in which initial DNA damage can trigger genomic instability due to SINE activation, a response which may be amplified in cancer cells lacking functional TP53.

Local mutagenic impact of insertions of LTR retrotransposons on the mouse genome

Solitary LTR loci are the predominant form of LTR retrotransposons in most eukaryotic genomes. They originate from recombination between the two LTRs of an ancestral retrovirus and are therefore incapable of transposition. Despite this inactivity, they appear to have a substantial impact on the host genome. Here we use the murine RMER10 LTR family as an example to describe how such elements can reshape regions of the genome through multiple mutations on an evolutionary time scale. Specifically, we use phylogenetic analysis of multiple copies of RMER10 in rodent species, as well as comparisons of orthologous pairs in mouse and rat, to argue that insertions of members of this family have locally induced the emergence of tandem repeat loci as well as many indels. Analysis of structural aspects of these sequences (secondary structures and transcription factors signals) may explain why RMER10 can become endogenous "mutagenic" factors through induction of replication fork blockages and/or error-prone repair of aberrant DNA structures. This hypothesis is also consistent with features of other interspersed repeated elements.

Repetitive sequence environment distinguishes housekeeping genes

Housekeeping genes are expressed across a wide variety of tissues. Since repetitive sequences have been reported to influence the expression of individual genes, we employed a novel approach to determine whether housekeeping genes can be distinguished from tissue-specific genes by their repetitive sequence context. We show that Alu elements are more highly concentrated around housekeeping genes while various longer (>400-bp) repetitive sequences ("repeats"), including Long Interspersed Nuclear Element-1 (LINE-1) elements, are excluded from these regions. We further show that isochore membership does not distinguish housekeeping genes from tissue-specific genes and that repetitive sequence environment distinguishes housekeeping genes from tissue-specific genes in every isochore. The distinct repetitive sequence environment, in combination with other previously published sequence properties of housekeeping genes, was used to develop a method of predicting housekeeping genes on the basis of DNA sequence alone. Using expression across tissue types as a measure of success, we demonstrate that repetitive sequence environment is by far the most important sequence feature identified to date for distinguishing housekeeping genes.

ALU-ring elements in the primate genomes

Elucidation of complete nucleotide sequence of the human has revealed that coding sequences that store the information needed to synthesize functional proteins, occupy only 2% of the genomic region. The remaining 98%, barring few regulatory sequences, has been referred to as non-functional or junk DNA and consists of many kinds of repeat elements. In fact, human genome is the most repeat rich genome sequenced so far, in which more than half of the region is occupied by such sequences. Determination of significance of these repeats in the human genome has become the focus of many studies all over the world, especially after genome sequencing did not reveal any significant difference in coding regions between lower eukaryotes and human. In this article, we have focused on Alu repeats that are primate specific elements with many interesting biological properties. Moreover, these are the repeats with highest copy number in the human genome. We have highlighted different facets of their interaction with the genome and changing paradigms regarding their role in genome organization.

Evolutionary history of 4.5SH RNA

4.5SH RNA is a 94-nt small RNA with unknown function. This RNA is known to be present in the mouse, rat, and hamster cells; however, it is not found in human, rabbit, and chicken. In the mouse genome, the 4.5SH RNA gene is a part of a long (4.2 kb) tandem repeat ( approximately 800 copies) unit. Here, we found that 4.5SH RNA genes are present only in rodents of six families that comprise the Myodonta clade: Muridae, Cricetidae, Spalacidae, Rhizomyidae, Zapodidae, and Dipodidae. The analysis of complementary DNA derived from the rodents of these families showed general evolutionary conservation of 4.5SH RNA and some intraspecific heterogeneity of these RNA molecules. 4.5SH RNA genes in the Norway rat, mole rat, hamster and jerboa genomes are included in the repeated sequences. In the jerboa genome these repeats are 4.0-kb long and arranged tandemly, similar to the corresponding arrangements in the mouse and rat genomic DNA. Sequencing of the rat and jerboa DNA repeats containing 4.5SH RNA genes showed fast evolution of the gene-flanking sequences. The repeat sequences of the distantly related rodents (mouse and rat vs. jerboa) have no apparent similarity except for the 4.5SH RNA gene itself. Conservation of the 4.5SH RNA gene nucleotide sequence indicates that this RNA is likely to be under selection pressure and, thus, may have a function. The repeats from the different rodents have similar lengths and contain many simple short repeats. The data obtained suggest that long insertions, deletions, and simple sequence amplifications significantly contribute in the evolution of the repeats containing 4.5SH RNA genes. The 4.5SH RNA gene seems to have originated 50-85 MYA in a Myodonta ancestor from a copy of the B1 short interspersed element. The amplification of the gene with the flanking sequences could result from the supposed cellular requirement of the intensive synthesis of 4.5SH RNA. Further Myodonta evolution led to dramatic changes of the repeat sequences in every lineage with the conservation of the 4.5SH RNA genes only. This gene, like some other relatively recently originated genes, could be a useful model for studying generation and evolution of non-protein-coding genes.

B1 and related SINEs in mammalian genomes

Although B1 and Alu were the first discovered Short Interspersed Elements (SINEs), the studies of these genomic repeats were mostly limited to mice and humans and little data on their presence in other animals were available. Here we report the presence of these SINEs in a wide range of rodents (in all 15 tested families) as well as primates and tree-shrews and their absence in other mammals. Distribution pattern of these SINEs in mammals supports close relationship between rodents and primates as well as tree-shrews. Sequence analysis of these elements, apparently descending from cellular 7SL RNA indicates their rearrangements such as dimerization (Alu), quasi-dimerization (B1), acquiring a tRNA-related unit (B1-dID), extended deletions, etc., preceding their active expansion in the genomes. The revealed common pattern of microenvironment of some rearrangement hot spots in SINEs (internal duplications and deletions) suggests involvement of short direct repeats in the mechanism of such rearrangements. This hypothesis allows us to explain short rearrangements in these and other short retroposons.

Short interspersed transposable elements (SINEs) are excluded from imprinted regions in the human genome

To test whether regions undergoing genomic imprinting have unique genomic characteristics, imprinted and nonimprinted human loci were compared for nucleotide and retroelement composition. Maternally and paternally expressed subgroups of imprinted genes were found to differ in terms of guanine and cytosine, CpG, and retroelement content, indicating a segregation into distinct genomic compartments. Imprinted regions have been normally permissive to L1 long interspersed transposable element retroposition during mammalian evolution but universally and significantly lack short interspersed transposable elements (SINEs). The primate-specific Alu SINEs, as well as the more ancient mammalian-wide interspersed repeat SINEs, are found at significantly low densities in imprinted regions. The latter paleogenomic signature indicates that the sequence characteristics of currently imprinted regions existed before the mammalian radiation. Transitions from imprinted to nonimprinted genomic regions in cis are characterized by a sharp inflection in SINE content, demonstrating that this genomic characteristic can help predict the presence and extent of regions undergoing imprinting. During primate evolution, SINE accumulation in imprinted regions occurred at a decreased rate compared with control loci. The constraint on SINE accumulation in imprinted regions may be mediated by an active selection process. This selection could be because of SINEs attracting and spreading methylation, as has been found at other loci. Methylation-induced silencing could lead to deleterious consequences at imprinted loci, where inactivation of one allele is already established, and expression is often essential for embryonic growth and survival.

Differential expression of B1-containing transcripts in Leishmania-exposed macrophages

When the parasitic protozoan Leishmania infect host macrophage cells, establishment of the infection requires alteration in the expression of genes in both the parasite and the host cells. In the early phase of infection of macrophages in vitro, Leishmania exposure affects the expression of a group of mouse macrophage genes containing the repetitive transposable element designated B1 sequence. In Leishmania-exposed macrophages compared with unexposed macrophages, small (approximately 0.5 kilobase) B1-containing RNAs (small B1-RNAs) are down-regulated, and large (1-4 kilobases) B1-containing RNAs (large B1-RNA) are up-regulated. The down-regulation of small B1-RNAs precedes the up-regulation of large B1-RNAs in Leishmania-exposed macrophages. These differential B1-containing gene expressions in Leishmania-exposed macrophages were verified using individual small-B1-RNA and large B1-RNA. The differential expressions of the B1-containing RNAs at the early phase of Leishmania-macrophage interaction may associate the establishment of the leishmanial infection.

Does SINE evolution preclude Alu function?

The evolution, mobility and deleterious genetic effects of human Alus are fairly well understood. The complexity of regulated transcriptional expression of Alus is becoming apparent and insight into the mechanism of retrotransposition is emerging. Unresolved questions concern why mobile, highly repetitive short interspersed elements (SINEs) have been tolerated throughout evolution and why and how families of such sequences are periodically replaced. Either certain SINEs are more successful genomic parasites or positive selection drives their relative success and genomic maintenance. A complete understanding of the evolutionary dynamics and significance of SINEs requires determining whether or not they have a function(s). Recent evidence suggests two possibilities, one concerning DNA and the other RNA. Dispersed Alus exhibit remarkable tissue-specific differences in the level of their 5-methylcytosine content. Differences in Alu methylation in the male and female germlines suggest that Alu DNA may be involved in either the unique chromatin organization of sperm or signaling events in the early embryo. Alu RNA is increased by cellular insults and stimulates protein synthesis by inhibiting PKR, the eIF2 kinase that is regulated by double-stranded RNA. PKR serves other roles potentially linking Alu RNA to a variety of vital cell functions. Since Alus have appeared only recently within the primate lineage, this proposal provokes the challenging question of how Alu RNA could have possibly assumed a significant role in cell physiology.

Association of Puralpha with RNAs homologous to 7 SL determines its binding ability to the myelin basic protein promoter DNA sequence

Cell type and developmental stage expression of the myelin basic protein (MBP) gene in mouse brain is regulated at the transcriptional level. Earlier studies from our laboratory have led to the identification of a DNA binding protein from mouse brain, named Puralpha, which interacts with the MB1 regulatory motif of the MBP and stimulates its transcription in glial cells. In this report, we demonstrate that a cellular RNA, with significant homology to 7 SL RNA is associated with Puralpha. Results from band shift competition studies indicate that Puralpha-associated RNA (PU-RNA), inhibits the interaction of immunopurified Puralpha with the MB1 DNA sequence. Results from Northern blot studies indicated that PU-RNA is expressed during various stages of brain development. Of interest, this RNA was found in association with Puralpha that was produced in the mouse brain at the early stage of brain development. Results from Northwestern analysis using a PU-RNA probe identified the regions within Puralpha that are important for Puralpha/PU-RNA association. Production of Puralpha at the early stage of brain development and its association with PU-RNA at this stage, when Puralpha exhibits poor binding ability to the MB1 DNA sequence, suggests that PU-RNA may function as a co-factor that negatively regulates Puralpha interaction with the MBP promoter sequence.

Isolation of human promoter regions by Alu repeat consensus-based polymerase chain reaction

Knowledge of the promoter structure is critical for an understanding of the regulation of genes. We demonstrate by analysis of 405 human genes that human promoter regions are flanked by upstream Alu repeat elements, typically at a distance of 0.5-5 kb from their protein-coding areas. We identified common Alu repeat consensus sequences (ARC) among the different members of the Alu subfamilies that can be used as universal anchor sites for polymerase chain reaction (PCR) amplification. Utilizing ARC-specific primers and oligonucleotides specific for the 5' end of a selected target gene, we show that sequences spanning unknown human gene promoter regions can be directly amplified by PCR from genomic DNA. This novel technique, termed ARC-PCR, allowed us to characterize the proximal promoters of the human LTA4 hydrolase and SPARC genes, each within 1 day.

Alu sequences

Alu sequences are frequently encountered during study of human genomic nucleic acid and form a major component of repetitive DNA. This review describes the origin of Alu sequences and their subsequent amplification and evolution into distinct subfamilies. In recent years a number of different functional roles for Alu sequences have been described. The multiple influences of Alu sequences on RNA polymerase II-mediated gene expression and the presence of Alu sequences in RNA polymerase III-generated transcripts are discussed.

An evolution-based hypothesis on the origin and mechanisms of autoimmune disease

The pathogenesis of autoimmune disease remains an enigma. Here, the condition is analysed from an evolutionary standpoint, and the thesis developed that viruses, in particular retroviruses, are important to our evolution, and that their inappropriate re-expression by repetitive (? ischaemic) cell damage in individuals of appropriate major histocompatibility type, leads to autoimmune disease. Such a view requires a slight adjustment to traditional ways of seeing Darwinian evolution, but one which makes real sense of the MHC-restricted nature of the adaptive immune response.

The origin of interspersed repeats in the human genome

Over a third of the human genome consists of interspersed repetitive sequences which are primarily degenerate copies of transposable elements. In the past year, the identities of many of these transposable elements were revealed. The emerging concept is that only three mechanisms of amplification are responsible for the vast majority of interspersed repeats and that with each autonomous element a number of dependent non-autonomous sequences have co-amplified.

A BC200-derived element and Z-DNA as structural markers in annexin I genes: relevance to Alu evolution and annexin tetrad formation

We have identified two types of structural elements in genomic DNA for annexin I that provide physical evidence of genetic events leading to conserved changes in gene structure. The sequence upstream of the transcribed region in human annexin I contained a rare, Alu-like repetitive element with flanking direct repeats, probably derived from the active BC200 gene via germline retroposition. Nucleotide substitutions in this BC200 insert relative to the 7SL gene and its absence in rodent annexins I identified it as a recent primate pseudogene. Phylogenetic analysis showed that the BC200 gene represents a new clade of primate Alu evolution that branched near the time of appearance of the progenitor to the free left Alu monomer, FLAM-C. Separate analysis identified a Z-DNA motif in pigeon annexin I intron 7 that may represent the vestigial recombination site involved in primordial assembly of the annexin tetrad. These distinct structural features in annexin I genes provide insight into the evolution of Alu repeats and the mechanism of annexin tetrad formation.

The mammalian genome shaping activity of reverse transcriptase

Reverse transcriptase catalyses the conversion of RNA into DNA. This operation seems to have largely contributed to the evolution of complex genomes. More than 10% of a mammalian genome is composed of sequences with reverse transcribed origin, most of which consists of repeated sequences (SINEs, LINEs). In spite of their simplicity, these sequences can play a key role in evolution by favoring illegitimate recombination. In addition to this abundant material, retrotransposed sequences include retrotransposons, retroviruses and genes depleted from intervening sequences, known as pseudogenes. Some of these sequences can be functional or involved in the regulation of neighbouring genes. These hallmarks of reverse transcription activity indicate that it has largely contributed to the fluidity of modern genomes.