Unusual sequences of two old, inactive human Alu repeats

Cis-acting influences on Alu RNA levels

The human short interspersed repeated element (SINE), Alu, amplifies through a poorly understood RNA-mediated mechanism, termed retroposition. There are over one million copies of Alu per haploid human genome. The copies show some internal variations in sequence and are very heterogeneous in chromosomal environment. However, very few Alu elements actively amplify. The amplification rate has decreased greatly in the last 40 million years. Factors influencing Alu transcription would directly affect an element's retroposition capability. Therefore, we evaluated several features that might influence expression from individual Alu elements. The influence of various internal sequence variations and 3' unique flanks on full-length Alu RNA steady-state levels was determined. Alu subfamily diagnostic mutations do not significantly alter the amount of Alu RNA observed. However, sequences containing random mutations throughout the right half of selected genomic Alu elements altered Alu RNA steady-state levels in cultured cells. In addition, sequence variations at the 3' unique end of the transcript also significantly altered the Alu RNA levels. In general, sequence mutations and 3' end sequences contribute to Alu RNA levels, suggesting that the master Alu element(s) have a multitude of individual differences that collectively gives them a selective advantage over other Alu elements.

Exon 2 of human cathepsin B derives from an Alu element

Transcripts for the cysteine protease cathepsin B are alternatively spliced in the untranslated regions (UTRs). We show that a cathepsin B probe containing 5'-UTR sequences hybridized to an RNA of approximately 300 nt in addition to the typical 2.2 and 4.0 kbp mRNAs. Within this 5'-UTR, exon 2 was found to be homologous to Alu repetitive elements. Specifically, exon 2 was part of an Alu element interspersed with the cathepsin B gene. The approximately 300 nt band that hybridized to our cathepsin B probe likely corresponds to Alu transcripts, which are known to accumulate in human cells. Indeed, a similarly migrating band was detected with an authentic Alu probe. Thus, we suggest that primary transcripts for cathepsin B contain Alu sequences which are preserved as exon 2 in some fully spliced mRNAs.

Monomeric scAlu and nascent dimeric Alu RNAs induced by adenovirus are assembled into SRP9/14-containing RNPs in HeLa cells

Nearly 1 000 000 copies of Alu interspersed elements comprise approximately 5% of human DNA. Alu elements cause gene disruptions by a process known as retrotransposition, in which dimeric Alu RNA is a presumed intermediate. Dimeric Alu transcripts are labile, giving rise to stable left monomeric scAlu RNAs whose levels are tightly regulated. Induction of Alu RNA by viral infection or cell stress leads to a dramatic increase in dimeric Alu transcripts, while scAlu RNA increases modestly. Each monomer of the dimeric Alu element shares sequence homology with the 7SL RNA component of the signal recognition particle (SRP). The SRP protein known as SRP9/14 is also found in a discrete complex with scAlu RNA, although whether dimeric Alu RNA is associated with SRP9/14 had been unknown. Here we show that antiserum to human SRP9 immunoprecipitates both scAlu RNA and dimeric Alu RNAs and that these RNPs accumulate after adenovirus infection, while levels of SRP9, SRP14, SRP54 and 7SL SRP RNA are unaffected. Dimeric Alu RNAs are also associated with the La protein, indicating that these are indeed nascent RNA polymerase III transcripts. This report documents that induced Alu transcripts are assembled into SRP9/14-containing RNPs in vivo while SRP levels are unchanged. Implications for Alu RNA metabolism and evolution are discussed.

Flanking sequences of an Alu source stimulate transcription in vitro by interacting with sequence-specific transcription factors

An Alu source gene, called the EPL Alu, was previously isolated by a phylogenetic strategy. Sequences flanking the EPL Alu family member stimulate its RNA polymerase III (Pol III) template activity in vitro. One cis-acting element maps within a 40-nucleotide region immediately upstream to the EPL Alu. This same region contains an Ap1 site which, when mutated, abolishes the transcriptional stimulation provided by this region. The flanking sequence, as assayed by gel mobility shift, forms sequence-specific complexes with several nuclear factors including Ap1. These results demonstrate that an an ancestral Alu source sequence fortuitously acquired positive transcriptional control elements by insertion into the EPL locus, thereby providing biochemical evidence for a model which explains the selective amplification of Alu subfamilies.

Rodent BC1 RNA gene as a master gene for ID element amplification

ID elements are short interspersed repetitive DNA elements (SINEs) which have amplified in rodent genomes via retroposition, a process involving an RNA intermediate. BC1, an abundant ID-related transcript, is transcribed from a conserved, single-copy gene in rodents. The gene encoding BC1 RNA represents one of the earliest and possibly the first ID-containing sequence. Comparison of consensus sequences of each rodent ID with its corresponding BC1 RNA gene showed that the variations of BC1 RNA within rodents corresponded to specific changes within the ID consensus sequence for each rodent species. This supports the hypothesis that the BC1 gene is a master gene responsible for the amplification and evolution of ID elements. The rat ID family consists of at least four subfamilies, with the oldest subfamily having been derived from the BC1 RNA. The other three subfamilies appear to have been derived from a new master gene(s), which has been responsible for the large increase in ID element copy number within the rat genome. We have found that the guinea pig genome contains two copies of the BC1 gene, apparently the result of a DNA-mediated duplication event. Both of these guinea pig BC1 genes have a conserved TATA-like element in the 5' flanking region and have contributed to guinea pig ID amplifications.

Alu transcripts: cytoplasmic localisation and regulation by DNA methylation

Full length Alu transcripts in HeLa cells are detected by primer extension using reverse transcriptase and are also analyzed as cloned cDNA sequences. The 5' end of these transcripts corresponds to the transcriptional start site for RNA polymerase III indicating that these RNAs are transcribed from their internal polymerase III promoters. The Alu transcripts found in cytoplasmic poly A+ RNAs appear to be organized into RNPs as assayed by sucrose gradient sedimentation. Present at about one hundred to one thousand copies per cell, the Alu transcripts are rare as compared to 7SL RNA. In agreement with previous reports that methylation inhibits Pol III-directed transcription of Alu in vitro, treatment of HeLa cells with 5-azacytidine results in Alu DNA hypomethylation and an increase in the abundance of the Alu transcript. Sequence analysis shows that many different Alu repeats including members of all subfamilies are transcribed by Pol III in vivo. cDNA sequences of the Pol III-directed transcripts exactly match the A box of the Pol III promoter element whereas in other Alu transcripts this element is not faithfully conserved.

Proposed roles for DNA methylation in Alu transcriptional repression and mutational inactivation

Methylation at CpG dinucleotides to produce 5 methyl cytosine (5me-C) has been proposed to regulate the transcriptional expression of human Alu repeats. Similarly, methylation has been proposed to indirectly favor the transpositional activity of young Alu repeats by transcriptionally inactivating older Alu's through the very rapid transition of 5me-C to T. Both hypotheses are examined here by RNA polymerase III (Pol III) in vitro transcription of Alu templates using HeLa cell extracts. A limiting factor represses the template activity of methylated Alu repeats. Competition by methylated prokaryotic vector DNA's relieves repression, showing that the factor is not sequence specific. This competitor has no effect on the activity of unmethylated templates showing that the repressor is highly specific toward methylated DNA. While methylation of a single pair of CpG dinucleotides in the A box of the Poll III promoter is sufficient to cause repression, methylation elsewhere within the template also causes repression. The repressor causing these effects on the Pol III directed transcription of Alu repeats is thought to be a previously reported, repressor for Pol II directed templates. Young Alu repeats are transcriptionally more active templates than a representative older Alu subfamily member. Also, younger Alu's form stable transcriptional complexes faster, potentially giving them an additional advantage. The mutation of three CpG's to CpA's within and near the A box drastically decreases both the template activity and rate of stable complex formation by a young Alu member. The sensitivity of Alu template activity to CpG transitions within the A box partially explains the selective transpositional advantage enjoyed by young Alu members.