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     

Phylogenetic isolation of a human alu flounder gene: Drift to new subfamily identity

A severe bottleneck in the size of the PV Alu subfamily in the common ancestor of human and gorilla has been used to isolate an Alu source gene. The human PV Alu subfamily consists of about one thousand members which are absent in gorilla and chimpanzee DNA. Exhaustive library screening shows that there are as few as two PV Alus in the gorilla genome. One is gorilla-specific, i.e., absent in the orthologous loci in both human and chimpanzee, suggesting the independent retrotranspositional activity of the PV subfamily in the gorilla lineage. The second of these two gorilla PV Alus is present in both human and chimpanzee DNAs and is the single PV Alu known to precede the radiation of these three species. The orthologous Alu in gibbon DNA resembles the next older Alu subfamily. Thus, this Alu locus is originally templated by a non-PV source gene and acquired characteristic PV sequence variants by mutational drift in situ, consequently becoming the first member and presumptive founder of this PV subfamily. Correspondence to: C.W. Schmid     

Unusual class of Alu sequences containing a potential Z-DNA segment.

A potential Z-DNA sequence, (dA-dC)9, has been found to replace the customary A-rich region in the middle of an Alu family member in the African green monkey genome. This Alu, bounded by imperfect direct repeats, also contains an unusual 3' end and may be a member of a large subfamily of such sequences.     

Structure and variability of recently inserted Alu family members.

The HS subfamily of Alu sequences is comprised of a group of nearly identical members. Individual subfamily members share 97.7% nucleotide identity with each other and 98.9% nucleotide identity with the HS consensus sequence. Individual subfamily members are on the average 2.8 million years old, and were probably derived from a single source 'master' gene sometime after the human/great ape divergence. The recent Alu family member insertions provide a better image of the structure of Alu retroposons before they have had the opportunity to change significantly. All of the HS subfamily members are flanked by perfect direct repeats as a result of insertion at staggered nicks. The 'master' gene from which the HS subfamily members were derived had an oligo-dA rich tail at least 40 bases long. The 'master' gene is very rich in CpG dinucleotides, but nucleotide substitutions within subfamily members accumulated in a random manner typical for Alu sequence with CpG substitutions occurring 9.2 fold faster than non-CpG substitutions.     

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.     

Subfamily relationships and clustering of rabbit C repeats

C repeats constitute the predominant family of short interspersed repeats (SINEs) in the rabbit genome. Determination of the nucleotide sequence 5' to rabbit zeta-globin genes reveals clusters of C repeats, and analysis of these and other sequenced regions of rabbit chromosomes shows that the C repeats have a strong tendency to insert within or in close proximity to other C repeats. An alignment of 44 members of the C repeat family shows that they are composites of different sequences, including a tRNA-like sequence, a conserved central core, a stretch of repeating CT dinucleotides, and an A-rich tract. Cladograms generated by both parsimony and cluster analysis subdivide the C repeats into at least three distinct subfamilies. Nucleotides at sites diagnostic for subfamilies appear to have changed in a punctuated and progressive manner during evolution, indicating that a limited number of progenitors have given rise to new repeats in waves of dispersion. C repeats that insert into preexisting C repeats belong to subfamilies that are proposed to have been propagated more recently; hence, these data support the model of dispersion in successive waves. The divergence among the oldest group of C repeats is greater than that observed for the analogous Alu repeats in humans, indicating that rabbit C repeats have been propagating longer than human Alu repeats. The improved consensus sequence for these repeats is similar to that of the predominant artiodactyl SINE in both the tRNA-like region and a central region. Because members of different subfamilies cross-hybridize very poorly, hybridization data with representatives of each subfamily provide a new minimal estimate, 234,000, for the copy number of C repeats in the rabbit haploid genome, although it is likely that the actual value is closer to 1 million.     

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.     

Unusual sequences of two old, inactive human Alu repeats.

Two human Alu repeats terminating in an oligo(T) run rather than the usual A-rich 3' tail were isolated by library screening. Base sequence comparisons reveal that these unusual Alus are also exceptionally divergent from other Alu family members implying that they are evolutionarily old. Unlike other members of the family, they are not transcribed in vitro by RNA polymerase III (Pol III) suggesting a partial explanation for how Alu source genes might become inactive with age.     

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 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.     

The role and amplification of the HS Alu subfamily founder gene

A recently identified Alu element (Leeflang et al. J. Mol. Evol. 1993, 37:559–565), referred to as the putative founder of the HS (PV) subfamily, was found to be present at orthologous loci in the human, chimpanzee, gorilla, and gibbon lineages. The evolution of this Alu suggested that it is a source gene in the evolution of Alu family repeats for one of the most recent subfamilies, HS. We have determined that this putative founder of the HS subfamily was not present at the orthologous loci in older primates, including old world and new world monkeys. Thus, this particular Alu locus has only been responsible for the establishment of a very small subfamily of Alu sequences. We have further demonstrated that this putative founder Alu was not responsible for the de novo Alu insertion into the neurofibromatosis-1 gene of an individual causing neurofibromatosis. Our data demonstrate that although the putative founder of the HS subfamily found by Leeflang et al. (1993) probably gave rise to one of the most recent subfamilies of Alu sequences, it has not been very active in retroposition. Correspondence to: T.H. Shaikh     

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.      

Genetic variation of recent Alu insertions in human populations

The Alu family of intersperesed repeats is comprised of ovr 500,000 members which may be divided into discrete subfamilies based upon mutations held in common between members. Distinct subfamilies of Alu sequences have amplified within the human genome in recent evolutionary history. Several individual Alu family members have amplified so recently in human evolution that they are variable as to presence and absence at specific loci within different human populations. Here, we report on the distribution of six polymorphic Alu insetions in a survey of 563 individuals from 14 human population groups across several continents. Our results indicate that these polymorphic Alu insertions probably have an African origin and that there is a much smaller amount of genetic variation between European populations than that found between other populations groups. Present address: Department of Pathology, Stanley S. Scott Cancer Center, Louisiana State University Medical Center, 1901 Perdido St., New Orleans, LA 70112 Correspondence to: M.A. Batzer     

Alu Evolution in Human Populations: Using the Coalescent to Estimate Effective Population Size

There are estimated to be ~1000 members of the Ya5 Alu subfamily of retroposons in humans. This subfamily has a distribution restricted to humans, with a few copies in gorillas and chimpanzees. Fifty-seven Ya5 elements were previously cloned from a HeLa-derived randomly sheared total genomic library, sequenced, and screened for polymorphism in a panel of 120 unrelated humans. Forty-four of the 57 cloned Alu repeats were monomorphic in the sample and 13 Alu repeats were dimorphic for insertion presence/absence. The observed distribution of sample frequencies of the 13 dimorphic elements is consistent with the theoretical expectation for elements ascertained in a single diploid cell line. Coalescence theory is used to compute expected total pedigree branch lengths for monomorphic and dimorphic elements, leading to an estimate of human effective population size of ~18,000 during the last one to two million years.     

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.     

Evolution of the master Alu gene(s)

Summary A comparison of Alu sequences that comprise more recently amplified Alu subfamilies was made. There are 18 individual diagnostic mutations associated with the different subfamilies. This analysis confirmed that the formation of each subfamily can be explained by the sequential accumulation of mutations relative to the previous subfamily. Polymerase chain reaction amplification of orthologous loci in several primate species allowed us to determine the time of insertion of Alu sequences in individual loci. These data suggest that the vast majority of Alu elements amplified at any given time comprised a single Alu subfamily. We find that, although the individual divergence relative to a consensus sequence correlate reasonably well with sequence age, the diagnostic mutations are a more accurate measure of the age of any individual Alu family member. Our data are consistent with a model in which all Alu family members have been made from a single master gene or from a series of sequential master genes. This master gene(s) accumulated diagnostic base changes, resulting in the amplification of different subfamilies from the master gene at different times in primate evolution. The changes in the master gene(s) probably occurred individually, but their appearance is clearly punctuated. Ten of them have occurred within an 15-million-year time span, 40–25 million years ago, and 8 changes have occurred within the last 5 million years. Surprisingly, no changes appeared in the 20 milion years separating these periods.     

A human-specific subfamily of Alu sequences.

Of a total of 500,000 Alu family members, approximately 500 are present as a human-specific (HS) subfamily. Each of the HS subfamily members shares a high degree of nucleotide identity and is not present at orthologous positions in other primate genomes, suggesting that HS subfamily members have recently inserted within the human genome. This confirms the hypothesis that the majority of Alu family members are amplified copies of a "master" gene(s). This master gene appears to be amplifying at a rate much slower than that seen earlier in primate evolution. Some of the HS Alu subfamily members have amplified so recently that they are dimorphic in the human population, making them a potentially powerful tool for studies of human populations.