Evolution of alu family repeats since the divergence of human and chimpanzee

Summary The DNA sequences of three members of the Alu family of repeated sequences located 5 to the chimpanzee 2 gene have been determined. The base sequences of the three corresponding human Alu family repeats have been previously determined, permitting the comparison of identical Alu family members in human and chimpanzee. Here we compare the sequences of seven pairs of chimpanzee and human Alu repeats. In each case, with the exception of minor sequence differences, the identical Alu repeat is located at identical sites in the human and chimpanzee genomes. The Alu repeats diverge at the rate expected for nonselected sequences. Sequence conversion has not replaced any of these 14 Alu family members since the divergence between chimpanzee and human.     

Association of hY4 pseudogenes with Alu repeats and abundance of hY RNA-like sequences in the human genome.

Three loci having homology with the small human cytoplasmic RNA, hY4, were isolated from human genomic DNA libraries and sequenced. Each sequence contains dispersed mismatches as compared with hY4 RNA, is followed by an A-rich or A + T-rich sequence, and is bordered by direct repeats. Each of these loci, therefore, appears to constitute a small RNA class-III pseudogene. Surprisingly, two of the three loci are associated with Alu repeats. In the hY4.B7 locus, the hY4 sequence has integrated into the tail of an Alu element and in the hY4.F2 locus, an Alu sequence has inserted into the hY4 tail, confirming that A-rich tracts are preferential targets for retroposition. In addition, Southern blots with probes for each of the four hY RNAs indicate that hY RNA-like sequences are abundant in the human genome.     

A high frequency of length polymorphisms in repeated sequences adjacent to Alu sequences

We describe a new class of DNA length polymorphism that is due to a variation in the number of tandem repeats associated with Alu sequences (Alu sequence-related polymorphisms). The polymerase chain reaction was used to selectively amplify a (TTA)n repeat identified in the 3-hydroxy-3-methylglutaryl coenzyme A (HMG CoA) reductase gene from genomic DNA of 41 human subjects, and the size of the amplified products was determined by gel electrophoresis. Seven alleles were found that differed in size by integrals of three nucleotides. The allele frequencies ranged from 1.5% to 52%, and the overall heterozygosity index was 62%. The polymorphic TTA repeat was located adjacent to a repetitive sequence of the Alu family. A homology search of human genomic DNA sequences for the trinucleotide TTA (at least five members in length) revealed tandem repeats in six other genes. Three of the six (TTA)n repeats were located adjacent to Alu sequences, and two of the three (in the genes for beta-tubulin and interleukin-1 alpha) were found to be polymorphic in length. Tandemly repetitive sequences found in association with Alu sequences may be frequent sites of length polymorphism that can be used as genetic markers for gene mapping or linkage analysis.     

Recently integrated human Alu repeats: finding needles in the haystack

Alu elements undergo amplification through retroposition and integration into new locations throughout primate genomes. Over 500,000 Alu elements reside in the human genome, making the identification of newly inserted Alu repeats the genomic equivalent of finding needles in the haystack. Here, we present two complementary methods for rapid detection of newly integrated Alu elements. In the first approach we employ computational biology to mine the human genomic DNA sequence databases in order to identify recently integrated Alu elements. The second method is based on an anchor-PCR technique which we term Allele-Specific Alu PCR (ASAP). In this approach, Alu elements are selectively amplified from anchored DNA generating a display or 'fingerprint' of recently integrated Alu elements. Alu insertion polymorphisms are then detected by comparison of the DNA fingerprints generated from different samples. Here, we explore the utility of these methods by applying them to the identification of members of the smallest previously identified subfamily of Alu repeats in the human genome termed Ya8. This subfamily of Alu repeats is composed of about 50 elements within the human genome. Approximately 50% of the Ya8 Alu family members have inserted in the human genome so recently that they are polymorphic, making them useful markers for the study of human evolution. This revised version was published online in July 2006 with corrections to the Cover Date.     

Mobility of short interspersed repeats within the chimpanzee lineage

The PV subfamily of Alu repeats in human DNA is largely composed of recently inserted members. Here we document additional members of the PV subfamily that are found in chimpanzee but not in the orthologous loci of human and gorilla, confirming the relatively recent and independent expansion of this Alu subfamily in the chimpanzee lineage. As further evidence for the youth of this Alu subfamily, one PV Alu repeat is specific to Pan troglodytes, whereas others are present in Pan paniscus as well. The A-rich tails of these Alu repeats have different lengths in Pan paniscus and Pan troglodytes. The dimorphisms caused by the presence and absence of PV Alu repeats and the length polymorphisms attributed to their A-rich tails should provide valuable genetic markers for molecular-based studies of chimpanzee relationships. The existence of lineage-specific Alu repeats is a major sequence difference between human and chimpanzee DNAs. Correspondence to: C.W. Schmid     

Revision of consensus sequence of human Alu repeats--a review

Nucleotide sequences of 50 human Alu repeats and their flanking regions are presented together with the consensus sequence based on the literature and our findings. The results indicate the need for some revisions of the Alu consensus sequence published by Deininger et al. (1981). Most nucleotide substitutions among the Alu members are transitions, rather than transversions. The Alu sequence seems to consist of 'conserved' regions and 'variable' regions. The conserved regions consist of a 25-bp region between nt positions 23 and 47 and a 16-bp region between nt positions 245 and 260. The 16-bp region corresponds to the region of 7SL RNA that is claimed to fold and become paired with the internal promoter sequence. Two A-rich regions, one located at the right end of the first monomer and the other at the right end of the second monomer, are variable. No defined property was found with direct repeats flanking the Alu repeats.     

AluElements: Repetitive DNA as Facilitators of Chromosomal Rearrangement

Alu repeats are the most common type of repetitive DNA sequences dispersed throughout the human genome. Technical advances in the field of cytogenetics and molecular biology have facilitated the analysis of epithelial tumors and hematologic malignancies which has led to the observation of Alu elements in and near sites often involved in chromosomal rearrangements. Repair mechanisms of double strand breaks (DSB) such as homol-ogous recombination (HR) may rely on the sequence homology of Alu repeats, potentially leading to chromosomal rearrange-ments. Databases have confirmed the strong association between Alu repeats, specifically the 26 bp consensus sequence and chro-mosomal regions involved in deletions and translocations. Although the Alu repetitive sequence is a potential "hotspot" during homologous recombination, there are other cellular mech-anisms that may play a more prominent role in the initiation of chromosomal rearrangements.     

An unusual Alu repeat sequence within the CAD gene

Summary There are several hundred thousand members of the Alu repeat family in the human genome. Those Alu elements sequenced to date appear to fit into subfamilies. A novel Alu has been found in an intron of the human CAD gene: it appears to be due to rearrangement between Alu repeats belonging to two different subfamilies. Further sequence data from this intron suggest that the Alu element may have rearranged prior to its entry into the CAD gene. Such findings indicate that, in addition to single nucleotide substitutions and deletions, DNA rearrangments may be a factor in generating the diversity of Alu repeats found in primate genomes.     

Identification and characterization of two polymorphic Ya5 Alu repeats

Two new polymorphic Alu elements (HS2.25 and HS4.14) belonging to the young (Ya5/8) subfamily of human-specific Alu repeats have been identified. DNA sequence analysis of both Alu repeats revealed that each Alu repeat had a long 3′-oligo-dA-rich tail (41 and 52 nucleotides in length) and a low level of random mutations. HS2.25 and HS4.14 were flanked by short precise direct repeats of 8 and 14 nucleotides in length, respectively. HS2.25 was located on human chromosome 13, and HS4.14 on chromosome 1. Both Alu elements were absent from the orthologous positions within the genomes of non-human primates, and were highly polymorphic in a survey of twelve geographically diverse human groups.     

Serial Alu sequence transposition interrupting a human B creatine kinase pseudogene.

We have isolated, sequenced, and characterized a single-copy B creatine kinase pseudogene. The chromosomal assignment of this gene is 16p13 and a unique sequence probe from this locus detects EcoRI restriction fragment length polymorphisms of 7.8 and 5.4 kb. In 26 unrelated individuals, the frequencies for the 7.8- and 5.4-kb B creatine kinase pseudogene alleles were calculated to be 17.3 and 82.7%, respectively. The B creatine kinase pseudogene is interrupted by a 904-bp DNA insertion composed of three Alu repeat sequences in tandem flanked by an 18-bp direct repeat, derived from the pseudogene sequence. Nucleotide sequence analysis of the Alu elements suggests that the Alu sequences were incorporated into this locus in three separate integration events. Several complex clustered Alu repeat sequences without defined integration borders have been previously identified at different genomic loci. This is the first evidence that complex tandem Alu elements can integrate in an apparently serial manner in the human genome and supports the contention that Alu repeats integrate nonrandomly into the human genome.     

Invasion of the human albumin-alpha-fetoprotein gene family by Alu, Kpn, and two novel repetitive DNA elements

The human albumin-alpha-fetoprotein genomic domain contains 13 repetitive DNA elements randomly distributed throughout the symmetrical structures of these genes. These repeated sequences are located at different sites within the two genes. The human albumin gene contains five Alu elements within four of its 14 intervening sequences. Two of these repeats are located in intron 2, and the remaining three are located in introns 7, 8, and 11. The human alpha-fetoprotein gene contains three of these Alu elements, one in intron 4 and the remaining two in the 3'-untranslated region. In addition, the human alpha-fetoprotein gene contains a Kpn repeat and two classes of novel repeats that are absent from the human albumin gene. Six of the Alu elements within the two genes are bound by short direct repeats that harbor five base substitutions in 120 possible positions (60 bp times 2 termini). The absence of Alu repeats from analogous positions in rodents indicates that these repeats invaded the albumin-alpha-fetoprotein domain less than 85 Myr ago (the time of mammalian radiation). Furthermore, considering the conservation of terminal repeats flanking the Alu sequences of the albumin-alpha-fetoprotein domain (0.042 changes per site), we submit that the average time of Alu insertion into this gene family could have been as recently as 15-30 Myr ago.     

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.     

Phylogenetic affinities of tarsier in the context of primate Alu repeats

Related genomes tend to be colonized by the same or similar repetitive sequence elements. Analysis of these elements provides useful taxonomic information. We have sequenced Alu repeats from tarsier and compared them with those from strepsirhine prosimians (lemurs, sifaka, and galago) and the human genome. Tarsier elements cluster with Alu subfamilies from the human lineage. The oldest subfamily in tarsier and the most abundant human subfamilies share an RNA secondary structure motif which is absent both in the earliest dimeric Alu Jo and in the strepsirhine elements. These findings are consistent with the view that tarsiers form a sister clade with anthropoides rather than with other prosimians. Alu repeats in tarsier genome are relatively old, which indicates a dramatic slowdown or even an arrest of these elements' amplification about 20 Myr ago.     

Base sequence studies of 300 nucleotide renatured repeated human DNA clones

A band of 300 nucleotide long duplex DNA is released by treating renatured repeated human DNA with the single strand-specific endonuclease S₁. Since many of the interspersed repeated sequences in human DNA are 300 nucleotides long, this band should be enriched in such repeats. We have determined the nucleotide sequences of 15 clones constructed from these 300 nucleotide S₁-resistant repeats. Ten of these cloned sequences are members of the Alu family of interspersed repeats. These ten sequences share a recognizable consensus sequence from which individual clones have an average divergence of 12.8%. The 300 nucleotide Alu family consensus sequence has a dimeric structure and was evidently formed from a head to tail duplication of an ancestral monomeric sequence. Three of the remaining clones are variations on a simple pentanucleotide sequence previously reported for human satellite III DNA. Two of the 15 clones have distinct and complex sequences and may represent other families of interspersed repeated sequences.     

Allelic dimorphism in the human tissue-type plasminogen activator (TPA) gene as a result of an Alu insertion/deletion event

Summary Polymerase chain reaction and direct sequencing were used to investigate an amplified DNA fragment containing the suspected polymorphic site of all known intragenic restriction fragment length polymorphisms (RFLPs) within the human tissue-type plasminogen activator (TPA) gene. Sequence data obtained showed that these RFLPs were all generated by the presence or absence of one of the two Alu sequences located in intron h of the human TPA gene. Furthermore, one of the direct repeats flanking this Alu sequence was absent in the minor allele. In addition to indicating the presence of an Alu insertion in an ancestral human TPA gene, these findings suggest a slip-replication mechanism for the deletion of this Alu repeat, once inserted into the gene. As both alleles have been observed in similar frequencies among different ethnic groups, the insertion or subsequent deletion of this Alu sequence in the human TPA gene must have occurred early in human evolution.     

Evolution of mouse B1 repeats: 7SL RNA folding pattern conserved

Summary In a recent report mouse B1 genomic repeats were divided into six families representing different waves of fixation of B1 variants, consistent with the retroposition model of human Alu elements. These data are used to examine the distribution of nucleotide substitutions in individual genomic repeats with respect to family consensus sequences and to compare the minimal energy structures of the corresponding B1 RNAs. By an enzymatic approach the predicted structure of B1 RNAs is experimentally confirmed using as a model sequence an RNA of a young B1 family member transcribed in vitro by T7 RNA polymerase. B1 RNA preserves folding domains of the Alu fragment of 7SL RNA, its progenitor molecule. Our results reveal similarities among 7SL-like retroposons, human Alu, and rodent B1 repeats, and relate the evolutionary conservation of B1 family consensus sequences to selection at the RNA level.