Alu element-mediated gene silencing

The Alu elements are conserved approximately 300-nucleotide-long repeat sequences that belong to the SINE family of retrotransposons found abundantly in primate genomes. Pairs of inverted Alu repeats in RNA can form duplex structures that lead to hyperediting by the ADAR enzymes, and at least 333 human genes contain such repeats in their 3'-UTRs. Here, we show that a pair of inverted Alus placed within the 3'-UTR of egfp reporter mRNA strongly represses EGFP expression, whereas a single Alu has little or no effect. Importantly, the observed silencing correlates with A-to-I RNA editing, nuclear retention of the mRNA and its association with the protein p54(nrb). Further, we show that inverted Alu elements can act in a similar fashion in their natural chromosomal context to silence the adjoining gene. For example, the Nicolin 1 gene expresses multiple mRNA isoforms differing in the 3'-UTR. One isoform that contains the inverted repeat is retained in the nucleus, whereas another lacking these sequences is exported to the cytoplasm. Taken together, these results support a novel role for Alu elements in human gene regulation.     

Gene regulation by SINES and inosines: biological consequences of A-to-I editing of Alu element inverted repeats

The Alu elements are conserved ~300 nucleotide long repeat sequences that belong to the SINE family of retrotransposons found abundantly in primate genomes. Although the vast majority of Alu elements appear to be genetically inert, it has been tempting to consider the great majority of them as â€?junk DNA. However, a growing line of evidence suggests that transcribed Alu RNAs are in fact functionally involved in a number of diverse biological processes. Pairs of inverted Alu repeats in RNA can form duplex structures that lead to A-to-I editing by the ADAR enzymes. In this review we discuss the possible biological effects of Alu editing, with particular focus on the regulation of gene expression by inverted Alu repeats in the 3a€?-UTR regions of mRNAs.     

Identification of widespread ultra-edited human RNAs

Adenosine-to-inosine modification of RNA molecules (A-to-I RNA editing) is an important mechanism that increases transciptome diversity. It occurs when a genomically encoded adenosine (A) is converted to an inosine (I) by ADAR proteins. Sequencing reactions read inosine as guanosine (G); therefore, current methods to detect A-to-I editing sites align RNA sequences to their corresponding DNA regions and identify A-to-G mismatches. However, such methods perform poorly on RNAs that underwent extensive editing ("ultra"-editing), as the large number of mismatches obscures the genomic origin of these RNAs. Therefore, only a few anecdotal ultra-edited RNAs have been discovered so far. Here we introduce and apply a novel computational method to identify ultra-edited RNAs. We detected 760 ESTs containing 15,646 editing sites (more than 20 sites per EST, on average), of which 13,668 are novel. Ultra-edited RNAs exhibit the known sequence motif of ADARs and tend to localize in sense strand Alu elements. Compared to sites of mild editing, ultra-editing occurs primarily in Alu-rich regions, where potential base pairing with neighboring, inverted Alus creates particularly long double-stranded RNA structures. Ultra-editing sites are underrepresented in old Alu subfamilies, tend to be non-conserved, and avoid exons, suggesting that ultra-editing is usually deleterious. A possible biological function of ultra-editing could be mediated by non-canonical splicing and cleavage of the RNA near the editing sites.     

Most human Alu and murine B1 repeats are unique

Alus and B1s are short interspersed repeat elements (SINEs) indirectly derived from the 7SL RNA gene. While most researchers recognize that there exists extensive variability between individual elements, the extent of this variability has never been systematically tested. We examined all Alu elements over 200 nucleotides and all B1 elements over 100 nucleotides in the human and mouse genomes, and analyzed the number of copies of each element at various stringencies from 22 nucleotides to full length. Over 98% of 923,277 Alus and 365,377 B1s examined were unique when queried at full length. When the criterion was reduced to half the length of the repeat, 97% of the Alus and 73% of the B1s were still found to be a single copy. All single and multi-copy sequences have been mapped and documented. Access to the data is possible using the AluPlus website http://www.ibr.hawaii.edu.     

Phylogenetic isolation of a human alu flounder gene: Drift to new subfamily identity

A severe bottleneck in the size of the PV Alu subfamily in the common ancestor of human and gorilla has been used to isolate an Alu source gene. The human PV Alu subfamily consists of about one thousand members which are absent in gorilla and chimpanzee DNA. Exhaustive library screening shows that there are as few as two PV Alus in the gorilla genome. One is gorilla-specific, i.e., absent in the orthologous loci in both human and chimpanzee, suggesting the independent retrotranspositional activity of the PV subfamily in the gorilla lineage. The second of these two gorilla PV Alus is present in both human and chimpanzee DNAs and is the single PV Alu known to precede the radiation of these three species. The orthologous Alu in gibbon DNA resembles the next older Alu subfamily. Thus, this Alu locus is originally templated by a non-PV source gene and acquired characteristic PV sequence variants by mutational drift in situ, consequently becoming the first member and presumptive founder of this PV subfamily. Correspondence to: C.W. Schmid     

The Role of Recombination in the Origin and Evolution of Alu Subfamilies

Alus are the most abundant and successful short interspersed nuclear elements found in primate genomes. In humans, they represent about 10% of the genome, although few are retrotransposition-competent and are clustered into subfamilies according to the source gene from which they evolved. Recombination between them can lead to genomic rearrangements of clinical and evolutionary significance. In this study, we have addressed the role of recombination in the origin of chimeric Alu source genes by the analysis of all known consensus sequences of human Alus. From the allelic diversity of Alu consensus sequences, validated in extant elements resulting from whole genome searches, distinct events of recombination were detected in the origin of particular subfamilies of AluS and AluY source genes. These results demonstrate that at least two subfamilies are likely to have emerged from ectopic Alu-Alu recombination, which stimulates further research regarding the potential of chimeric active Alus to punctuate the genome.     

Evolutionary evidence suggests that CpG island-associated Alus are frequently unmethylated in human germline

Most Alu elements are considered to belong to the methylated fraction of the genome that has undergone CpG depletion, whereas CpG islands are characteristically unmethylated. By analysing the CpG content of >12,000 autosomal CpG island-Alu Sx pairs we wanted to study what happens when an Alu is situated close to a CpG island. We have found that many Alus located close to CpG islands have retained a high proportion of CpG sites, which is consistent with these Alus being unmethylated in the human germline.     

Association of some potential hormone response elements in human genes with the Alu family repeats.

Short interspersed repeats of the Alu family located in promoters of some human genes contain high-affinity binding sites for thyroid hormone receptor, retinoic acid receptor and estrogen receptor. The standard binding sites for the receptors represent variants of duplicated AGGTCA motif with different spacing and orientation (direct, DR, or inverted, IR), and Alu sequences were found to have functional DR-4, DR-2 or variant IR-3/IR-17 elements. In this study we analyzed distribution and abundance of the elements in a set of human genomic sequences from GenBank and their association with Alu repeats. Our results indicate that a major fraction of potentially active DR-4, DR-2 and variant IR-3/IR-17 elements in the genes is located within Alu repeats. Alu-associated DR-2 elements are conserved in primate evolution. However, very few Alu have potential DR-3 glucocorticoid-response elements. Gel-shift experiments with the probe (AUB) corresponding to the consensus Alu sequence just upstream of the RNA polymerase III promoter B-box and containing duplicated AGGTCA motif indicate that the probe interacts in a sequence-specific manner with human nuclear proteins which bind to standard IR-0, DR-1, DR-4 or DR-5 elements. The AUB sequence was also able to promote thyroid hormone-dependent trans-activation of a reporter gene. The results support the view that Alu retroposons played an important role in evolution of regulation of the primate gene expression by nuclear hormone receptors.     

Germline methylation patterns inferred from local nucleotide frequency of repetitive sequences in the human genome

Given the genomic abundance and susceptibility to DNA methylation, interspersed repetitive sequences in the human genome can be exploited as valuable resources in genome-wide methylation studies. To learn about the relationships between DNA methylation and repeat sequences, we performed a global measurement of CpG dinucleotide frequencies for interspersed repetitive sequences and inferred germline methylation patterns in the human genome. Although extensive CpG depletion was observed for most repeat sequences, those in the proximity to CpG islands have been relatively removed from germline methylation being the potential source of germline activation. We also investigated the CpG depletion patterns of Alu pairs to see whether they might play an active role in germline methylation. Two kinds of Alu pairs, direct or inverted pairs classified according to the orientation, showed contrast CpG depletion patterns with respect to separating distance of Alus, i.e., as two Alu elements are more closely spaced in a pair, a higher extent of CpG depletion was observed in inverted orientation and vice versa for directly repetitive Alu pairs. This suggests that specific organization of repetitive sequences, such as inverted Alu pairs, might play a role in triggering DNA methylation consistent with a homology-dependent methylation hypothesis.