A trinucleotide repeat-associated increase in the level of Alu RNA-binding protein occurred during the same period as the major Alu amplification that accompanied anthropoid evolution.

Nearly 1 million Alu elements in human DNA were inserted by an RNA-mediated retroposition-amplification process that clearly decelerated about 30 million years ago. Since then, Alu sequences have proliferated at a lower rate, including within the human genome, in which Alu mobility continues to generate genetic variability. Initially derived from 7SL RNA of the signal recognition particle (SRP), Alu became a dominant retroposon while retaining secondary structures found in 7SL RNA. We previously identified a human Alu RNA-binding protein as a homolog of the 14-kDa Alu-specific protein of SRP and have shown that its expression is associated with accumulation of 3'-processed Alu RNA. Here, we show that in early anthropoids, the gene encoding SRP14 Alu RNA-binding protein was duplicated and that SRP14-homologous sequences currently reside on different human chromosomes. In anthropoids, the active SRP14 gene acquired a GCA trinucleotide repeat in its 3'-coding region that produces SRP14 polypeptides with extended C-terminal tails. A C-->G substitution in this region converted the mouse sequence CCA GCA to GCA GCA in prosimians, which presumably predisposed this locus to GCA expansion in anthropoids and provides a model for other triplet expansions. Moreover, the presence of the trinucleotide repeat in SRP14 DNA and the corresponding C-terminal tail in SRP14 are associated with a significant increase in SRP14 polypeptide and Alu RNA-binding activity. These genetic events occurred during the period in which an acceleration in Alu retroposition was followed by a sharp deceleration, suggesting that Alu repeats coevolved with C-terminal variants of SRP14 in higher primates.     

Exon skipping caused by an intronic insertion of a young Alu Yb9 element leads to severe hemophilia A

Short interspersed elements, such as Alu elements, have propagated to more than one million copies in the human genome. They affect the genome in several ways, caused by retrotransposition, recombination between elements, gene conversion, and alterations in gene expression. These events, including novel insertions into active genes, have been associated with a number of human disorders. Hemophilia A is an X-linked severe bleeding disorder and is caused by mutations in the Factor VIII gene. The spectrum of mutations includes point mutations, rearrangements, insertions, and deletions. Recently, an Alu retrotransposition event in a coding exon has been reported in a family with a severe form of hemophilia A. This was the first report of an Alu insertion in the Factor VIII gene. Here, we report a second Alu insertion event that lies in an intron of the same gene that causes exon skipping and the complete disruption of gene expression.     

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.     

Junctions between genes in the haptoglobin gene cluster of primates.

To investigate the nature of the recombination that generated the haptoglobin three-gene cluster in Old World primates, we sequenced the region between the second gene (HPR) and the third gene (HPP) in chimpanzees (15 kb), as well as the region 3' to the cluster in humans (14 kb). Comparison to the previously sequenced human haptoglobin (HP) and HPR genes showed that the junction point between HP and HPR in humans (junction 1) was not identical to the junction point between the HPR and HPP genes of the chimpanzee (junction 2). An Alu sequence was found at each junction, but both Alu sequences lacked short direct repeats of the flanking genomic DNA. The lack of direct repeats implies that both junction Alu sequences are the products of recombination between different Alu elements. In addition, other insertion and deletion events are clustered in the regions near the junction Alu sequences. The observation that Alu sequences define the junctions between genes in the haptoglobin gene cluster emphasizes the importance of Alu sequences in the evolution of multigene families.     

Large-scale analysis of the Alu Ya5 and Yb8 subfamilies and their contribution to human genomic diversity

We have utilized computational biology to screen GenBank for the presence of recently integrated Ya5 and Yb8 Alu family members. Our analysis identified 2640 Ya5 Alu family members and 1852 Yb8 Alu family members from the draft sequence of the human genome. We selected a set of 475 of these elements for detailed analyses. Analysis of the DNA sequences from the individual Alu elements revealed a low level of random mutations within both subfamilies consistent with the recent origin of these elements within the human genome. Polymerase chain reaction assays were used to determine the phylogenetic distribution and human genomic variation associated with each Alu repeat. Over 99 % of the Ya5 and Yb8 Alu family members were restricted to the human genome and absent from orthologous positions within the genomes of several non-human primates, confirming the recent origin of these Alu subfamilies in the human genome. Approximately 1 % of the analyzed Ya5 and Yb8 Alu family members had integrated into previously undefined repeated regions of the human genome. Analysis of mosaic Yb8 elements suggests gene conversion played an important role in generating sequence diversity among these elements. Of the 475 evaluated elements, a total of 106 of the Ya5 and Yb8 Alu family members were polymorphic for insertion presence/absence within the genomes of a diverse array of human populations. The newly identified Alu insertion polymorphisms will be useful tools for the study of human genomic diversity.     

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.     

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.     

Gene conversion as a secondary mechanism of short interspersed element (SINE) evolution.

The Alu repetitive family of short interspersed elements (SINEs) in primates can be subdivided into distinct subfamilies by specific diagnostic nucleotide changes. The older subfamilies are generally very abundant, while the younger subfamilies have fewer copies. Some of the youngest Alu elements are absent in the orthologous loci of nonhuman primates, indicative of recent retroposition events, the primary mode of SINE evolution. PCR analysis of one young Alu subfamily (Sb2) member found in the low-density lipoprotein receptor gene apparently revealed the presence of this element in the green monkey, orangutan, gorilla, and chimpanzee genomes, as well as the human genome. However, sequence analysis of these genomes revealed a highly mutated, older, primate-specific Alu element was present at this position in the nonhuman primates. Comparison of the flanking DNA sequences upstream of this Alu insertion corresponded to evolution expected for standard primate phylogeny, but comparison of the Alu repeat sequences revealed that the human element departed from this phylogeny. The change in the human sequence apparently occurred by a gene conversion event only within the Alu element itself, converting it from one of the oldest to one of the youngest Alu subfamilies. Although gene conversions of Alu elements are clearly very rare, this finding shows that such events can occur and contribute to specific cases of SINE subfamily evolution.     

Distinguishing humans from great apes with AluYb8 repeats

Humans and chimpanzees share some 99% of DNA and amino acid identity, yet they exhibit important biomedical, morphological, and cognitive differences, difficult to accommodate within the remaining 1% of sequence diversity. Other types of genetic variation must be responsible for the taxonomic differences. Here we trace the evolution of AluYb8 repeats from a single origin at the roots of higher primates to a large increase in their number in humans. We identify nine AluYb8 DNA repeats in the chimpanzee genome compared to over 2200 repeats in the human, which represents a 250-fold increase in the rate of change in the human lineage and far outweighs the 99% sequence similarity between the two species. It is estimated that the average age of the human Yb8Alus is about 3.3 million years (My); almost 10% of them are identical in sequence, and hence are of recent origin. Genomic variations of this magnitude, distinguishing humans from great apes have not been realized. This explosive Alu expansion must have had a profound effect on the organization of our genome and the architecture of our chromosomes, inferentially altering profiles of gene expression and chromosome choreography in cell division. Additionally, we conclude that this major evolutionary process of Alu proliferation is driven by internal forces, written in the chemistry of DNA, rather than by external selection.     

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.     

Non-traditional Alu evolution and primate genomic diversity

Alu elements belonging to the previously identified "young" subfamilies are thought to have inserted in the human genome after the divergence of humans from non-human primates and therefore should not be present in non-human primate genomes. Polymerase chain reaction (PCR) based screening of over 500 Alu insertion loci resulted in the recovery of a few "young" Alu elements that also resided at orthologous positions in non-human primate genomes. Sequence analysis demonstrated these "young" Alu insertions represented gene conversion events of pre-existing ancient Alu elements or independent parallel insertions of older Alu elements in the same genomic region. The level of gene conversion between Alu elements suggests that it may have a significant influence on the single nucleotide diversity within the genome. All the instances of multiple independent Alu insertions within the same small genomic regions were recovered from the owl monkey genome, indicating a higher Alu amplification rate in owl monkeys relative to many other primates. This study suggests that the majority of Alu insertions in primate genomes are the products of unique evolutionary events.     

Comprehensive analysis of two Alu Yd subfamilies

Alu elements have inserted in the human genome throughout primate evolution. A small number of Alu insertions have occurred after the divergence of humans from nonhuman primates and therefore should not be present in nonhuman primate genomes. Most of these recently integrated Alu elements are contained with a series of discrete Alu subfamilies that are related to each other based upon diagnostic nucleotide substitutions. We have extracted members of the Alu Yd subfamily that are derivatives of the Alu Y subfamily that share a common 12-bp deletion that defines the Yd lineage from the draft sequence of the human genome. Analysis of the Yd Alu elements resulted in the recovery of two new Alu subfamilies, Yd3 and Yd6, which contain a total of 295 members (198 Yd3 and 97 Yd6). DNA sequence analysis of each of the Alu Yd subfamilies yielded age estimates of 8.02 and 1.20 million years old for the Alu Yd3 and Yd6 subfamilies, respectively. Two hundred Alu Yd3 and Yd6 loci were screened using polymerase chain reaction (PCR) assays to determine their phylogenetic origin and associated levels of human genomic diversity. The Alu Yd3 subfamily appears to have started amplifying relatively early in primate evolution and continued propagating albeit at a low level as many of its members are found in a variety of hominoid (humans, greater and lesser ape) genomes. Only two of the elements are polymorphic in the human genome and absent from the genomes of nonhuman primates. By contrast all of the members of the Alu Yd6 subfamily are restricted to the human genome, with 12% of the elements representing insertion polymorphisms in human populations. A single Alu Yd6 locus contained an independent parallel forward insertion of a paralogous Alu Sq sequence in the owl monkey. These Alu subfamilies are a source of genomic fossil relics for the study of primate phylogenetics and human population genetics.     

Alu家族在人类基因组中的作用

Alu家族是灵长类动物特有的且是最重要的短散在元件(short interspersed elements,SINEs),经过6千5百万年的进化,Alu序列在基因组中约有120万份拷贝,占基因组的10%以上。Alu家族在基因组中有很多功能,如介导重组、基因插入和删除、甲基化和A-to-I的编辑作用、调控转录和翻译、选择性剪接等等。Alu家族的变异与疾病和进化存在密切关系。     

Alu repeats and human genomic diversity

During the past 65 million years, Alu elements have propagated to more than one million copies in primate genomes, which has resulted in the generation of a series of Alu subfamilies of different ages. Alu elements affect the genome in several ways, causing insertion mutations, recombination between elements, gene conversion and alterations in gene expression. Alu-insertion polymorphisms are a boon for the study of human population genetics and primate comparative genomics because they are neutral genetic markers of identical descent with known ancestral states.     

Alu repeats in the human genome

Highly repetitive DNA sequences account for more than 50% of the human genome. The L1 and Alu families harbor the most common mammalian long (LINEs) and short (SINEs) interspersed elements. Alu elements are each a dimer of similar, but not identical, fragments of total size about 300 bp, and originate from the 7SL RNA gene. Each element contains a bipartite promoter for RNA polymerase III, a poly(A) tract located between the monomers, a 3'-terminal poly(A) tract, and numerous CpG islands, and is flanked by short direct repeats. Alu repeats comprise more than 10% of the human genome and are capable of retroposition. Possibly, these elements played an important part in genome evolution. Insertion of an Alu element into a functionally important genome region or other Alu-dependent alterations of gene functions cause various hereditary disorders and are probably associated with carcinogenesis. In total, 14 Alu families differing in diagnostic mutations are known. Some of these, which are present in the human genome, are polymorphic and relatively recently inserted into new loci. Alu copies transposed during ethnic divergence of the human population are useful markers for evolutionary genetic studies.     

Alu insertion loci and platyrrhine primate phylogeny

Short INterspersed Elements (SINEs) make very useful phylogenetic markers because the integration of a particular element at a location in the genome is irreversible and of known polarity. These attributes make analysis of SINEs as phylogenetic characters an essentially homoplasy-free affair. Alu elements are primate-specific SINEs that make up a large portion of the human genome and are also widespread in other primates. Using a combination wet-bench and computational approach we recovered 190 Alu insertions, 183 of which are specific to the genomes of nine New World primates. We used these loci to investigate branching order and have produced a cladogram that supports a sister relationship between Atelidae (spider, woolly, and howler monkeys) and Cebidae (marmosets, tamarins, and owl monkeys) and then the joining of this two family clade to Pitheciidae (titi and saki monkeys). The data support these relationships with a homoplasy index of 0.00. In this study, we report one of the largest applications of SINE elements to phylogenetic analysis to date, and the results provide a robust molecular phylogeny for platyrrhine primates.