An Alu transposition model for the origin and expansion of human segmental duplications

Relative to genomes of other sequenced organisms, the human genome appears particularly enriched for large, highly homologous segmental duplications (> or =90% sequence identity and > or =10 kbp in length). The molecular basis for this enrichment is unknown. We sought to gain insight into the mechanism of origin, by systematically examining sequence features at the junctions of duplications. We analyzed 9,464 junctions within regions of high-quality finished sequence from a genomewide set of 2,366 duplication alignments. We observed a highly significant (P<.0001) enrichment of Alu short interspersed element (SINE) sequences near or within the junction. Twenty-seven percent of all segmental duplications terminated within an Alu repeat. The Alu junction enrichment was most pronounced for interspersed segmental duplications separated by > or =1 Mb of intervening sequence. Alu elements at the junctions showed higher levels of divergence, consistent with Alu-Alu-mediated recombination events. When we classified Alu elements into major subfamilies, younger elements (AluY and AluS) accounted for the enrichment, whereas the oldest primate family (AluJ) showed no enrichment. We propose that the primate-specific burst of Alu retroposition activity (which occurred 35-40 million years ago) sensitized the ancestral human genome for Alu-Alu-mediated recombination events, which, in turn, initiated the expansion of gene-rich segmental duplications and their subsequent role in nonallelic homologous recombination.     

Alu element mutation spectra: molecular clocks and the effect of DNA methylation

In primate genomes more than 40% of CpG islands are found within repetitive elements. With more than one million copies in the human genome, the Alu family of retrotransposons represents the most successful short interspersed element (SINE) in primates and CpG dinucleotides make up about 20% of Alu sequences. It is generally thought that CpG dinucleotides mutate approximately ten times faster than other dinucleotides due to cytosine methylation and the subsequent deamination and conversion of C-->T. However, the disparity of Alu subfamily age estimations based upon CpG or non-CpG substitution density indicates a more complex relationship between CpG and non-CpG substitutions within the Alu elements. Here we report an analysis of the mutation patterns for 5296 Alu elements comprising 20 subfamilies. Our results indicate a relatively constant CpG versus non-CpG substitution ratio of approximately 6 for the young (AluY) and intermediate (AluS) Alu subfamilies. However, a more complex non-linear relationship between CpG and non-CpG substitutions was observed when old (AluJ) subfamilies were included in the analysis. These patterns may be the result of the slowdown of the neutral mutation rate during primate evolution and/or an increase in the CpG mutation rate as the consequence of increased DNA methylation in response to a burst of retrotransposition activity approximately 35 million years ago.     

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.     

A novel approach for identifying candidate imprinted genes through sequence analysis of imprinted and control genes

Through the sequence analysis of 27 imprinted human genes and a set of 100 control genes we have developed a novel approach for identifying candidate imprinted genes based on the differences in sequence composition observed. The imprinted genes were found to be associated with significantly reduced numbers of short interspersed transposable element (SINE) Alus and mammalian-wide interspersed repeat (MIR) repeat elements, as previously reported. In addition, a significant association between imprinted genes and increased numbers of low-complexity repeats was also evident. Numbers of the Alu classes AluJ and AluS were found to be significantly depleted in some parts of the flanking regions of imprinted genes. A recent study has proposed that there is active selection against SINE elements in imprinted regions. Alternatively, there may be differences in the rates of insertion of Alu elements. Our study indicates that this difference extends both upstream and downstream of the coding region. This and other consistent differences between the sequence characteristics of imprinted and control genes has enabled us to develop discriminant analysis, which can be used to screen the genome for candidate imprinted genes. We have applied this function to a number of genes whose imprinting status is disputed or uncertain.     

Most recent AluY insertions in human gene introns reduce the content of the primary transcripts in a cell type specific manner

Being the most effectively transposed primate-specific SINEs, Alu elements are present in more than one million copies in the human genome and include most recently transposed subsets of AluY elements that are polymorphic in humans. Although Alu elements are commonly thought to play an essential role in shaping and functioning of primate genomes, the understanding of the impact of recent Alu insertions on human gene expression is far from being comprehensive. Here we compared hnRNA contents for allele pairs of genes heterozygous for AluY insertions in their introns in human cell lines of various origins. We demonstrated that some AluY insertions correlated with decreased content of the corresponding hnRNAs. The effect observed does not depend on sequences of Alu elements and their orientation but is likely to be cell type specific.     

Retroposons in modern human genome evolution

The ascertainment of the rates and driving forces of human genome evolution along with the genetic diversity of populations or separate population groups remains a topical problem of fundamental and applied genomics. According to the results of comparative analysis, the most numerous human genome structure peculiarities are connected with the distribution of mobile genetic retroelements—LTR, LINE1, SVA, and Alu repeats. Due to the wide distribution in different genome loci, conversed retropositional activity, and the retroelements’ regulatory potential, let us regard them as one of the significant evolutionary driving forces and the source of human genome variability. In the current review, we summarize published data and recent results of our research aimed at the analysis of the evolutionary impact of the young retroelements group on the function and variability of the human genome. We examine modern approaches of the polygenomic identification of polymorphic retroelements inserts. Using an original Internet resource, we analyze special features of the genomic polymorphic inserts of AluY repeats. We thoroughly characterize the strategy of large-scale functional analysis of polymorphic retroelement inserts. The presented results confirm the hypothesis of the roles of retroelements as active cis regulatory elements that are able to modulate surrounding genes.     

Active Alu elements are passed primarily through paternal germlines

Repetitive elements are distributed non-randomly in the human genome but, as reviewed in this paper, biological processes underlying the observed patterns appear to be complex and remain relatively obscure. Recent findings indicate that chromosomal distribution of Alu retroelements deposited in the past is different from the distribution of Alu elements that continue to be inserted in human population. These active elements from AluY sub(sub)families are the major focus of this paper. In particular, we analyzed chromosomal proportions of 19 AluY subfamilies, of which nine are reported for the first time in this paper. These 19 subfamilies contain over 80% of Alu elements that are polymorphic in the human genome. The chromosomal density of these most recent Alu insertions is around three times higher on chromosome Y than on chromosome X and over two times higher than the average density for all human autosomes. Based on this observation and other data we propose that active Alu elements are passed through paternal germlines. There is also some evidence that a small fraction of active Alu elements from less abundant subfamilies can be retroposed in female germlines or in the early embryos. Finally, we propose that the origin of Alu subfamilies in human populations may be related to evolution of chromosome Y.     

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.     

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.     

Developmental differences in methylation of human Alu repeats.

Alu repeats are especially rich in CpG dinucleotides, the principal target sites for DNA methylation in eukaryotes. The methylation state of Alus in different human tissues is investigated by simple, direct genomic blot analysis exploiting recent theoretical and practical advances concerning Alu sequence evolution. Whereas Alus are almost completely methylated in somatic tissues such as spleen, they are hypomethylated in the male germ line and tissues which depend on the differential expression of the paternal genome complement for development. In particular, we have identified a subset enriched in young Alus whose CpGs appear to be almost completely unmethylated in sperm DNA. The existence of this subset potentially explains the conservation of CpG dinucleotides in active Alu source genes. These profound, sequence-specific developmental changes in the methylation state of Alu repeats suggest a function for Alu sequences at the DNA level, such as a role in genomic imprinting.     

Changes in Gene Expression and DNA Methylation of Evolutionarily Young AluY Repeats during Apoptosis of Human K562 Erythro-Myeloblastic Leukemia Cells

Using a human K562 erythromyeloblastoid cell culture, we demonstrated changes in gene expression of Alu repeats, members of evolutionarily young AluY subfamilies (human mobile SINE elements), and in the DNA methylation level of AluYb8 during camptothecin (CAM)-induced apoptosis. The AluY-RNA level increased about 10 times 24 h and 20 times 48 h after exposure to CAM vs. proliferating cells. Using methylation-specific (MSP) PCR and high-resolution melting (HRM), we showed that the overall AluYb8-DNA methylation level remained intact throughout the apoptotic stages. Using DNA sequencing after bisulfite conversion, we established that at the CpG site, located in the A'-box of the AluYb8 gene promoter, the methylation level decreased significantly during different apoptotic stages. Apparently, it is reduced CpG methylation at the A'-box of the AluYb8 gene promoter, discovered in this work, that is one of the possible factors which account for increased expression of AluY repeats during K562 cell apoptosis. We assume that increased gene expression of evolutionarily young AluY repeats plays an important role in the implementation of the cellular apoptotic pathway.     

Analysis of repetitive element DNA methylation by MethyLight

Repetitive elements represent a large portion of the human genome and contain much of the CpG methylation found in normal human postnatal somatic tissues. Loss of DNA methylation in these sequences might account for most of the global hypomethylation that characterizes a large percentage of human cancers that have been studied. There is widespread interest in correlating the genomic 5-methylcytosine content with clinical outcome, dietary history, lifestyle, etc. However, a high-throughput, accurate and easily accessible technique that can be applied even to paraffin-embedded tissue DNA is not yet available. Here, we report the development of quantitative MethyLight assays to determine the levels of methylated and unmethylated repeats, namely, Alu and LINE-1 sequences and the centromeric satellite alpha (Satα) and juxtacentromeric satellite 2 (Sat2) DNA sequences. Methylation levels of Alu, Sat2 and LINE-1 repeats were significantly associated with global DNA methylation, as measured by high performance liquid chromatography, and the combined measurements of Alu and Sat2 methylation were highly correlative with global DNA methylation measurements. These MethyLight assays rely only on real-time PCR and provide surrogate markers for global DNA methylation analysis. We also describe a novel design strategy for the development of methylation-independent MethyLight control reactions based on Alu sequences depleted of CpG dinucleotides by evolutionary deamination on one strand. We show that one such Alu-based reaction provides a greatly improved detection of DNA for normalization in MethyLight applications and is less susceptible to normalization errors caused by cancer-associated aneuploidy and copy number changes.     

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.     

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.