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.     

Evolution of Alu repeats. Imitation model

At present, nucleotide sequences of 100 different Alu repeats are known, i.e. 0.01% of the total number of Alu repeats in the genome. It is clear that one can not refer the evolutionary characteristics of Alu repeats obtained from the analysis of the available limited sample to all Alu repeats comprised in the genome, without additional statistical estimations. For supplementary investigation of such average evolutionary characteristics as the extent of intraspecific divergence, the rate of Alu repeats transposition (insertion, excision), we used the method of imitation simulation of the process of Alu repeats transposition in the genome. As a result of simulation, phylogenetic relations were obtained among all Alu repeats. It was shown that the evolutionary characteristics evaluated for different samples of repeats were similar. It was proved that the extent of divergence of Alu repeats in the model is twice as small as that evaluated, according to the real data (0.15, instead of 0.3). Possible reasons for such discrepancy have been discussed.     

Distribution of Alu repeats along the human genome: formation of clusters and features of insertion regions

The contextual analysis of nucleotide sequences of 22 Alu repeats arrangement regions in the human genome has been carried out and some of their peculiarities have been revealed. In particular, the occurrence of marked and statistical non-random homology between the repeats and the regions of their integration has been shown. A mechanism of choosing the Alu repeats insertion regions in the genome has been suggested taking into account these peculiarities. Using a sample of the 80 human Alu repeats sequences peculiarities of these repeats location within the genome has been investigated. A tendency to the formation of Alu repeats clusters in various regions of the genome was revealed. A range of possible mechanisms on such Alu clusters emergence is considered. On the basis of the data obtained an "attraction" mechanism, according to which integration of Alu repeats into the definite region of the genome increases the insertion probability of other Alu repeats into the same region, are proposed.     

Structural organization of the human genome: distribution of nucleotides, Alu-repeats and exons in chromosomes 21 and 22]

Analysis of DNA sequences of the human chromosomes 21 and 22 performed using a specially designed MegaGene software allowed us to obtain the following results. Purine and pyrimidine nucleotide residues are unevenly distributed along both chromosomes, displaying maxima and minima (Y waves phi) with a period of about 3 Mbp. Distribution of G + C along both chromosomes has no distinct maxima and minima, however, chromosome 21 contains considerably less G + C than chromosome 22. Both exons and Alu repeats are unevenly distributed along chromosome 21: they are scarce in its left part and abundant in the right part, while MIR elements are quite monotonously spread along this chromosome. The Alu repeats show a wave-like distribution pattern similar for both repeat orientations. The number of the Alu repeats of opposite orientations was equal for both studied chromosomes, and this may be considered a new property of the human genome. The positive correlation between the exon and Alu distribution patterns along the chromosome, the concurrent distribution of Alu repeats in both orientations along the chromosome, and the equal copy numbers for Alu in direct and inverted orientations within an individual chromosome point to their important role in the human genome, and do not fit the notion that Alu repeats belong to parasitic (junk) DNA.     

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     

Alu repeated DNAs are differentially methylated in primate germ cells.

A significant fraction of Alu repeats in human sperm DNA, previously found to be unmethylated, is nearly completely methylated in DNA from many somatic tissues. A similar fraction of unmethylated Alus is observed here in sperm DNA from rhesus monkey. However, Alus are almost completely methylated at the restriction sites tested in monkey follicular oocyte DNA. The Alu methylation patterns in mature male and female monkey germ cells are consistent with Alu methylation in human germ cell tumors. Alu sequences are hypomethylated in seminoma DNAs and more methylated in a human ovarian dysgerminoma. These results contrast with methylation patterns reported for germ cell single-copy, CpG island, satellite, and L1 sequences. The function of Alu repeats is not known, but differential methylation of Alu repeats in the male and female germ lines suggests that they may serve as markers for genomic imprinting or in maintaining differences in male and female meiosis.     

Phylogenetic roots of Alu-mediated rearrangements leading to cancer.

There are over a million Alu repetitive elements dispersed throughout the human genome, and a high level of Alu-sequence similarity ensures a strong propensity for unequal crossover events, some of which have lead to deleterious oncogenic rearrangements. Furthermore, Alu insertions introduce consensus 3' splice sites, which potentially facilitate alternative splicing. Not surprisingly, Alu-mediated defective splicing has also been associated with cancer. To investigate a possible correlation between the expansion of Alu repeats associated with primate divergence and predisposition to cancer, 4 Alu-mediated rearrangements--known to be the basis of cancer--were selected for phylogenetic analysis of the necessary genotype. In these 4 cases, it was determined that the different phylogenetic age of the oncogenic recombination-prone genotype reflected the evolutionary history of Alu repeats spreading to new genomic sites. Our data implies that the evolutionary expansion of Alu repeats to new genomic locations establishes new predispositions to cancer in various primate species.     

Structural analysis of the Alu-containing DNA fragment with disperse distribution in human chromosomes

Nucleotide sequencing of two terminal subfragments of a cloned human DNA fragment has been done. The fragment cloned hybridized dispersively along all chromosomes except for Y chromosome and C heterochromatic chromosome regions. Both subfragments sequenced contain Alu repeats, whose structures differ partially from those of accurately determined sequences of human Alu repeats. The results obtained are discussed in respect of possible usage of Alu repeats containing sequences for construction of special polymorphic molecular markers of human chromosomes.