Analysis of DNA of higher primates using inter-SINE PCR

Two types (MIR and Alu) of short interspersed repeated DNA sequences (SINEs) were used for analysis of genetic relationships among higher primates, and for detection of polymorphism in human genomic DNA. The DNA regions located between the neighboring copies of these SINEs were amplified in polymerase chain reaction with primers complementary to the MIR and Alu consensus sequences (inter-SINE PCR). Comparison of the sets of amplified DNA fragments for different species or individuals provides evaluation of the relationships among them. Using inter-MIR PCR technique, the relationships among the higher primates of the infraorder Catarrhini reported elsewhere were confirmed, pointing to the efficiency of the method for phylogenetic studies. No human DNA polymorphism was revealed with the help of inter-MIR PCR. This polymorphism was detected by means of inter-Alu PCR, which is probably associated with the continuing amplification of Alu elements in human genome.     

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.     

An alu-based phylogeny of lemurs (infraorder: lemuriformes)

LEMURS (INFRAORDER: Lemuriformes) are a radiation of strepsirrhine primates endemic to the island of Madagascar. As of 2012, 101 lemur species, divided among five families, have been described. Genetic and morphological evidence indicates all species are descended from a common ancestor that arrived in Madagascar ～55-60 million years ago (mya). Phylogenetic relationships in this species-rich infraorder have been the subject of debate. Here we use Alu elements, a family of primate-specific Short INterspersed Elements (SINEs), to construct a phylogeny of infraorder Lemuriformes. Alu elements are particularly useful SINEs for the purpose of phylogeny reconstruction because they are identical by descent and confounding events between loci are easily resolved by sequencing. The genome of the grey mouse lemur (Microcebus murinus) was computationally assayed for synapomorphic Alu elements. Those that were identified as Lemuriformes-specific were analyzed against other available primate genomes for orthologous sequence in which to design primers for PCR (polymerase chain reaction) verification. A primate phylogenetic panel of 24 species, including 22 lemur species from all five families, was examined for the presence/absence of 138 Alu elements via PCR to establish relationships among species. Of these, 111 were phylogenetically informative. A phylogenetic tree was generated based on the results of this analysis. We demonstrate strong support for the monophyly of Lemuriformes to the exclusion of other primates, with Daubentoniidae, the aye-aye, as the basal lineage within the infraorder. Our results also suggest Lepilemuridae as a sister lineage to Cheirogaleidae, and Indriidae as sister to Lemuridae. Among the Cheirogaleidae, we show strong support for Microcebus and Mirza as sister genera, with Cheirogaleus the sister lineage to both. Our results also support the monophyly of the Lemuridae. Within Lemuridae we place Lemur and Hapalemur together to the exclusion of Eulemur and Varecia, with Varecia the sister lineage to the other three genera.     

Clustering and subfamily relationships of the Alu family in the human genome

Thirteen and 10 sequences of the Alu family of repeated DNA elements found within the human thymidine kinase and beta-tubulin genes, respectively, were compared. These genes have approximately five times the expected density of Alu family members. The consensus sequence that could be drawn from these 23 Alu family members would differ slightly from others drawn from random Alu family sequences but only at very heterogeneous positions. The different Alu family members do show different pairwise percentage identities, with approximately 15% (7 of 48 Alu family members analyzed) of them clearly representing a separate subfamily of sequences. This analysis also confirms the species- specific differences between human and the prosimian Galago crassicaudatus Alu family members. These data are consistent with both the origin of these sequences in primates less than 65-70 Myr ago and amplification since that time to their present 500,000 copies. The data do not show any special relationships among densely clustered Alu family members.      

Molecular variability in the commom shrew Sorex araneus L. from European Russia and Siberia inferred from the length polymorphism of DNA regions flanked by short interspersed elements (Inter-SINE PCR) and the relationships between the Moscow and Seliger chromosome races

Genetic exchange among chromosomal races of the common shrew Sorex araneus and the problem of reproductive barriers have been extensively studied by means of such molecular markers as mtDNA, microsatellites, and allozymes. In the present study, the interpopulation and interracial polymorphism in the common shrew was derived, using fingerprints generated by amplified DNA regions flanked by short interspersed repeats (SINEs)-interSINE PCR (IS-PCR). We used primers, complementary to consensus sequences of two short retroposons: mammalian element MIR and the SOR element from the genome of Sorex araneus. Genetic differentiation among eleven populations of the common shrew from eight chromosome races was estimated. The NP and MJ analyses, as well as multidimensional scaling showed that all samples examined grouped into two main clusters, corresponding to European Russia and Siberia. The bootstrap support of the European Russia cluster in the NJ and MP analyses was respectively 76 and 61%. The bootstrap index for the Siberian cluster was 100% in both analyses; the Tomsk race, included into this cluster, was separated with the bootstrap support of NJ/MP 92/95%.     

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.     

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.     

Analysis of the human Alu Ya-lineage

The Alu Ya-lineage is a group of related, short interspersed elements (SINEs) found in primates. This lineage includes subfamilies Ya1-Ya5, Ya5a2 and others. Some of these subfamilies are still actively mobilizing in the human genome. We have analyzed 2482 elements that reside in the human genome draft sequence and focused our analyses on the 2318 human autosomal Ya Alu elements. A total of 1470 autosomal loci were subjected to polymerase chain reaction (PCR)-based assays that allow analysis of individual Ya-lineage Alu elements. About 22% (313/1452) of the Ya-lineage Alu elements were polymorphic for the insertion presence on human autosomes. Less than 0.01% (5/1452) of the Ya-lineage loci analyzed displayed insertions in orthologous loci in non-human primate genomes. DNA sequence analysis of the orthologous inserts showed that the orthologous loci contained older pre-existing Y, Sc or Sq Alu subfamily elements that were the result of parallel forward insertions or involved in gene conversion events in the human lineage. This study is the largest analysis of a group of "young", evolutionarily related human subfamilies. The size, evolutionary age and variable allele insertion frequencies of several of these subfamilies makes members of the Ya-lineage useful tools for human population studies and primate phylogenetics.     

A SINE in the genome of the cephalochordate amphioxus is an Alu element

Transposable elements of about 300 bp, termed "short interspersed nucleotide elements or SINEs are common in eukaryotes. However, Alu elements, SINEs containing restriction sites for the AluI enzyme, have been known only from primates. Here I report the first SINE found in the genome of the cephalochordate, amphioxus. It is an Alu element of 375 bp that does not share substantial identity with any genomic sequences in vertebrates. It was identified because it was located in the FoxD regulatory region in a cosmid derived from one individual, but absent from the two FoxD alleles of BACs from a second individual. However, searches of sequences of BACs and genomic traces from this second individual gave an estimate of 50-100 copies in the amphioxus genome. The finding of an Alu element in amphioxus raises the question of whether Alu elements in amphioxus and primates arose by convergent evolution or by inheritance from a common ancestor. Genome-wide analyses of transposable elements in amphioxus and other chordates such as tunicates, agnathans and cartilaginous fishes could well provide the answer.     

A young Alu subfamily amplified independently in human and African great apes lineages.

A variety of Alu subfamilies amplified in primate genomes at different evolutionary time periods. Alu Sb2 belongs to a group of young subfamilies with a characteristic two-nucleotide deletion at positions 65/66. It consists of repeats having a 7-nucleotide duplication of a sequence segment involving positions 246 through 252. The presence of Sb2 inserts was examined in five genomic loci in 120 human DNA samples as well as in DNAs of higher primates. The lack of the insertional polymorphism seen at four human loci and the absence of orthologous inserts in apes indicated that the examined repeats retroposed early in the human lineage, but following the divergence of great apes. On the other hand, similar analysis of the fifth locus (butyrylcholinesterase gene) suggested contemporary retropositional activity of this subfamily. By a semi-quantitative PCR, using a primer pair specific for Sb2 repeats, we estimated their copy number at about 1500 per human haploid genome; the corresponding numbers in chimpanzee and gorilla were two orders of magnitude lower, while in orangutan and gibbon the presence of Sb2 Alu was hardly detectable. Sequence analysis of PCR-amplified Sb2 repeats from human and African great apes is consistent with the model in which the founding of Sb2 subfamily variants occurred independently in chimpanzee, gorilla and human lineages.     

Molecular variability in the common shrew Sorex araneus L. from european russia and siberia inferred from the length polymorphism of DNA regions flanked by short interspersed elements (inter-SINE PCR) and the relationships between the moscow and seliger chromosome races

Genetic exchange among chromosomal races of the common shrew Sorex araneus and the problem of reproductive barriers have been extensively studied by means of such molecular markers as mtDNA, microsatellites, and allozymes. In the present study, the interpopulation and interracial polymorphism in the common shrew was derived, using fingerprints generated by amplified DNA regions flanked by short interspersed repeats (SINEs)—interSINE PCR (IS-PCR). We used primers, complementary to consensus sequences of two short retroposons: mammalian element MIR and the SOR element from the genome of Sorex araneus. Genetic differentiation among eleven populations of the common shrew from eight chromosome races was estimated. The NJ and MP analyses, as well as multidimensional scaling showed that all samples examined grouped into two main clusters, corresponding to European Russia and Siberia. The bootstrap support of the European Russia cluster in the NJ and MP analyses was respectively 76 and 61%. The bootstrap index for the Siberian cluster was 100% in both analyses; the Tomsk race, included into this cluster, was separated with the bootstrap support of NJ/MP 92/95%.     

Repetitive elements may comprise over two-thirds of the human genome

Transposable elements (TEs) are conventionally identified in eukaryotic genomes by alignment to consensus element sequences. Using this approach, about half of the human genome has been previously identified as TEs and low-complexity repeats. We recently developed a highly sensitive alternative de novo strategy, P-clouds, that instead searches for clusters of high-abundance oligonucleotides that are related in sequence space (oligo "clouds"). We show here that P-clouds predicts >840 Mbp of additional repetitive sequences in the human genome, thus suggesting that 66%-69% of the human genome is repetitive or repeat-derived. To investigate this remarkable difference, we conducted detailed analyses of the ability of both P-clouds and a commonly used conventional approach, RepeatMasker (RM), to detect different sized fragments of the highly abundant human Alu and MIR SINEs. RM can have surprisingly low sensitivity for even moderately long fragments, in contrast to P-clouds, which has good sensitivity down to small fragment sizes (～25 bp). Although short fragments have a high intrinsic probability of being false positives, we performed a probabilistic annotation that reflects this fact. We further developed "element-specific" P-clouds (ESPs) to identify novel Alu and MIR SINE elements, and using it we identified ～100 Mb of previously unannotated human elements. ESP estimates of new MIR sequences are in good agreement with RM-based predictions of the amount that RM missed. These results highlight the need for combined, probabilistic genome annotation approaches and suggest that the human genome consists of substantially more repetitive sequence than previously believed.     

Conserved nucleotide differences and subfamily structure of porcine short interspersed elements

Interspersed elements are ubiquitous in the genomes of higher eukaryotes and account for over a third of the genomic DNA (Smit 1996). In swine the short interspersed elements, SINEs or PREs (porcine repetitive elements), have been found in a number of introns and 3' untranslated regions of different genes. However, compared to human Alu repeats the number of available PRE DNA sequences is still limited. In this study we have compared 85 PREs selected from DNA sequence database entries. The PREs were aligned and for each nucleotide position the relative frequencies of the four bases were calculated. A consensus sequence was derived from the first base usage. Similar to studies of SINEs in other species, the analysis showed that most mutations in PREs occur at CpG dinucleotide hot spots. The position variability for the two most frequent bases shows a bimodal distribution. The analysis suggests that the porcine SINEs can be divided into three major subfamilies sharing conserved nucleotide similarities.     

Detection and Analysis of an Estrous－associated Oviductal Glycoprotein DNA Fragment from Primates by PCR

ＤｅｔｅｃｔｉｏｎａｎｄＡｎａｌｙｓｉｓｏｆａｎＥｓｔｒｏｕｓ－ａｓｓｏｃｉａｔｅｄＯｖｉｄｕｃｔａｌＧｌｙｃｏｐｒｏｔｅｉｎＤＮＡＦｒａｇｍｅｎｔｆｒｏｍＰｒｉｍａｔｅｓｂｙＰＣＲ￥ＣＨＥＮＱｉｎｇ－ｘｕａｎ（陈清轩）;ＣｌａｙｔｏｎＥ．Ｗａｌｔｏ...     

Characterization and population diversity of interspersed repeat sequence variants (IRS-morphs).

Inter-Alu PCR is increasingly useful in human genome mapping studies. One use is the generation of alumorphs, polymorphisms resulting from the presence or absence of inter-Alu PCR products. In this study, we have increased the proportion of the genome that can be analyzed by this technique with the use of long interspersed elements (LINEs). The set of polymorphisms detected by both Alu and LINE primers are referred to as interspersed repetitive sequence variants or IRS-morphs. Since a presence-absence variant may have been the result of a recent Alu or LINE insertion, we analyzed 7 isolated IRS-morphs that were generated, in part, with a primer derived from either a consensus LINE or a young Alu subfamily specific sequence, and observed by Southern blot analysis that these variants resulted from other types of genomic alterations. The use of these primers, however, reduces background from the numerous LINEs and Alu elements in the genome, providing sharp DNA fingerprint profiles. We have demonstrated the potential usefulness of these IRS-morph profiles in human population studies. We compared 12 IRS-morphs from a single amplification reaction from five distinct population groups (Caucasian (northern European descent), Hispanic (Mexican-American), Hindu-Indian, Papua New Guinean, and Greenland Eskimo) and observed that most have variable allelic frequencies among populations. The utilization of additional IRS-morph profiles will perpetuate this technique as a tool for DNA fingerprinting and for the analysis of human populations. Key words : Alu elements, DNA fingerprint, human populations, LINEs, SINEs.     

The evolution of a family of short interspersed repeats in primate DNA

Summary Human DNA contains 300 nucleotide interspersed repeated sequences which mostly belong to a single family of sequences called the Alu family. This work examines the evolution of this family of sequences in primates. Bonnet monkey (Macaque radiata) DNA contains a predominant family of 300 nucleotide repeats which has nearly the same restriction map as the human Alu family and which hybridizes to human Alu family repeats under Southern blotting conditions. Prosimian (Galago crassicaudatus pangeniesis) DNA also contains a prominent group of 300 nucleotide long repeated sequences which does not have the same restriction sites as the human Alu family but which does hybridize to the human Alu family under reduced stringency conditions.     

Molecular cladistic markers in New World monkey phylogeny (Platyrrhini,Primates)

Transpositions of primate-specific Alu elements were applied as molecular cladistic markers in a phylogenetic analysis of South American primates. Seventy-four human and platyrrhine loci containing intronic Alu elements were PCR screened in various New World monkeys and the human outgroup to detect the presence of orthologous retrotransposons informative of New World monkey phylogeny. Six loci revealed size polymorphism in the amplification pattern, indicating a shared derived character state due to the presence of orthologous Alu elements confirmed by subsequent sequencing. Three markers corroborate (1) New World monkey monophyly and one marker supports each of the following callitrichine relationships: (2) Callithrix and Cebuella are more closely related to each other than to any other callitrichine, (3) the callitrichines form a monophyletic clade including Callimico, and (4) the next living relatives to the callitrichines are Cebus, Saimiri, and Aotus.     

Alu DNA polymorphism in ACE gene is protective for age-related macular degeneration

Age-related macular degeneration (AMD) is the leading cause of blindness in the elderly. We report an association between an Alu polymorphism in the angiotensin-converting enzyme (ACE) gene with the dry/atrophic form of AMD. Using the polymerase chain reaction (PCR) on genomic DNA isolated from patients with AMD (n=173), and an age-matched control population (n=189), we amplified a region polymorphic for an Alu element insertion in the ACE gene. The Alu(+/+) genotype occurred 4.5 times more frequently in the control population than the dry/atrophic AMD patient population, (p=0.004). The predominance of the Alu(+/+) genotype within the unaffected control group represents a protective insertion with respect to the human ocular disease, dry/atrophic AMD. This is the first demonstration of an Alu element insertion exerting protective effects against a known human disease.