The human episome HALF1: Structure of its genomic counterpart

A human episomal sequence (HALF1) has been identified by its ability to restore expression of hepatic functions when used to transfect a rat dedifferentiated cell line. The genomic equivalent of this human episome (gHALF1) and its flanking sequences were analyzed. HALF1 itself does not present the characteristics of a transposable element but half of its sequence corresponds to retroposons, including Alu and L1 repeats and a processed pseudogene, known to transposevia RNA intermediates. The structural characteristics of these different kinds of retroposons and their origin and evolution were analyzed.     

A novel human nonviral retroposon derived from an endogenous retrovirus.

In a human genome, we found dispersed repetitive sequences homologous to part of a human endogenous retrovirus termed HERV-K which resembled mouse mammary tumor virus. For elucidation of their structure and organization, we cloned some of these sequences from a human gene library. The sequence common to the cloned DNA was ca. 630 base-pairs (bp) in length with an A-rich tail at the 3' end and was found to be a SINE (short interspersed repeated sequence) type nonviral retroposon. In this retroposon, the 5' end had multiple copies of a 40 bp direct repeat very rich in GC content and about the next 510 nucleotides were homologous to the 3' long terminal repeat and its upstream flanking region of the HERV-K genome. This retroposon was thus given the name, SINE-R element since most of it derived from a retrovirus. SINE-R elements were present at 4,000 to 5,000 copies per haploid human genome. The nucleotide sequence was ca. 90% homologous among the cloned elements.     

HERV-K(OLD): ancestor sequences of the human endogenous retrovirus family HERV-K(HML-2)

Sequences homologous to the human endogenous retrovirus (HERV) family HERV-K(HML-2) are present in all Old World primate species. A previous study showed that a central region of the HERV-K(HML-2) gag genes in Hominoidea species displays a 96-bp deletion compared to the gag genes in lower Old World primates. The more ancient HERV-K(HML-2) sequences present in lower Old World primates were apparently not conserved during hominoid evolution, as opposed to the deletion variants. To further clarify the evolutionary origin of the HERV-K(HML-2) family, we screened GenBank with the 96-bp gag-sequence characteristic of lower Old World primates and identified, to date, 10 human sequence entries harboring either full-length or partially deleted proviral structures, probably representing remnants of a more ancient HERV-K(HML-2) variant. The high degree of mutations demonstrates the long-time presence of these HERV-K(OLD) proviruses in the genome. Nevertheless, they still belong to the HML-2 family as deduced from dot matrix and phylogenetic analyses. We estimate, based on the family ages of integrated Alu elements and on long terminal repeat (LTR) divergence data, that the average age of HERV-K(OLD) proviruses is ca. 28 million years, supporting an integration time before the evolutionary split of Hominoidea from lower Old World primates. Analysis of HERV-K(OLD) LTR sequences led to the distinction of two subgroups, both of which cluster with LTRs belonging to an evolutionarily older cluster. Taken together, our data give further insight into the evolutionary history of the HERV-K(HML-2) family during primate evolution.     

Serial Alu sequence transposition interrupting a human B creatine kinase pseudogene.

We have isolated, sequenced, and characterized a single-copy B creatine kinase pseudogene. The chromosomal assignment of this gene is 16p13 and a unique sequence probe from this locus detects EcoRI restriction fragment length polymorphisms of 7.8 and 5.4 kb. In 26 unrelated individuals, the frequencies for the 7.8- and 5.4-kb B creatine kinase pseudogene alleles were calculated to be 17.3 and 82.7%, respectively. The B creatine kinase pseudogene is interrupted by a 904-bp DNA insertion composed of three Alu repeat sequences in tandem flanked by an 18-bp direct repeat, derived from the pseudogene sequence. Nucleotide sequence analysis of the Alu elements suggests that the Alu sequences were incorporated into this locus in three separate integration events. Several complex clustered Alu repeat sequences without defined integration borders have been previously identified at different genomic loci. This is the first evidence that complex tandem Alu elements can integrate in an apparently serial manner in the human genome and supports the contention that Alu repeats integrate nonrandomly into the human genome.     

Phylogeny of SINE-R retroposons in Asian apes.

The SINE-R retroposon family was derived from the long terminal repeats (LTRs) of human endogenous retrovirus K (HERV-K) that had been active during the hominoid evolution. The retroposons and HERV-K LTR elements have potential relevance to structural change and genetic variation of the hominoid genome. In our previous study, we found that the SINE-R retroposons were hominoid specific. Here we identified seventeen new SINE-R retroposons (14 from orangutan and 3 from gibbon) from Asian apes and phylogenetically analysed them in comparison with those of the humans and African great apes. None of the retroposons from Asian apes were closely related to SINE-R.C2 that is human specific, and originally identified in the gene for the C2 component of complement, whereas some retroposons (Ch-M10, Ch-M16, Gor-M, Gor-F1, Gor-M6, and Gor-F9) from African great apes showed very close relationship with that of the SINE-R.C2 retroposon. The phylogenetic tree based on the SINE-R retroposons revealed wide overlap of the retroposons across species, suggesting that the SINE-R retroposons have been evolved parallel pattern in the course of hominoid evolution.     

A human dihydrofolate reductase intronless pseudogene with an Alu repetitive sequence: multiple DNA insertions at a single chromosomal site

A dihydrofolate reductase (DHFR) pseudogene, hDHFR-psi 3 has been isolated from a human genomic DNA fragment library. Sequence analysis of this gene revealed a lack of introns and the presence of a tract of nine adenines, 90 bp downstream from the end of the coding sequence. These features suggest that hDHFR-psi 3 was derived from a processed RNA molecule that has been converted into DNA and inserted into a chromosome, analogous to the origin of three intronless human DHFR genes previously described. An interesting feature of hDHFR-psi 3 is the presence of a member of the Alu moderately repetitive DNA sequence family within the DHFR coding region. This Alu element is flanked by a 16 bp directly repeated DNA segment derived from DHFR coding sequences. The Alu element apparently has been inserted into the intronless DHFR pseudogene and thus, there have been two insertions at a single chromosomal locus. The hDHFR-psi 3 contains only the 3' half of the DHFR coding sequence. Immediately upstream from the directly repeated sequence before the Alu element is an adenine-rich tract. The DNA farther upstream is moderately repetitive and is related to neither DHFR nor Alu DNA sequence. Therefore, it seems possible that a third insertion has occurred at the same site further disrupting the hDHFR coding sequences.     

Phylogenetic analysis of a retroposon family as represented on the human X chromosome

SINE-R elements constitute a class of retroposons derived from the long terminal repeat (LTR) of the human endogenous retrovirus HERV-K family that are present in hominoid primates and active in the human genome. In an investigation of the X chromosome, we identified twenty-five SINE-R elements with between 89.6 and 97.7% homology with the SINE-R.C2 element that is human specific, originally identified in the gene for the C2 component of complement. SINE-R.C2 and a sequence HS307 that we previously identified in a region of Xq21.3 that has a recently created homology with a 4 Mb block in Yp11.2 are amongst the group of elements that have diverged furthest from the parent HERV-K10 sequence. The sequence on the X chromosome resemble those that we previously described on chromosomes 7 and 17 and the Y chromosome, with a similar range of variation. Phylogenetic analysis from the retroposon family including those of African great apes using the neighbor-joining method suggests that the SINE-R retroposon family have evolved independently during primate evolution. Further investigation of SINE-R elements on the sex chromosomes, particularly in recently created regions of X-Y homology, may cast light on the timing of the retroposition process and its possible relevance to recent evolutionary change.     

Phylogenetic screening of the human genome: identification of differentially hybridizing repetitive sequence families

The phi-screen, a method of phylogenetic screening, can be employed to detect repetitive sequence families that differentially hybridize between closely related species. Such differences may involve sequence divergence or variations in copy number, including total presence versus absence of a family of repeated DNA. We present the results of a phi-screen comparing the human genome to that of the prosimian, Galago crassicaudatus. Three human repetitive families that are divergent or not present in galago have been detected. One of these families is described in detail; it is similar among the anthropoids but is present in a lower copy number and/or divergent form in prosimians. The family is clearly related to the transposon-like human element (THE) described by Paulson et al. (1985). THEs have long terminal repeats reminiscent of retroviruses but are unique in that they have no sequence similarity to known mammalian retroviruses. The sequence of a solo long terminal repeat, found unassociated with THE internal sequence, is presented. This family member, THE p2, is bordered by a 5-bp target-site repeat and is interrupted by the insertion of an Alu element. A solo THE element sequenced by Wiginton et al. (1986) contains an insertion of Alu at precisely the same position as does THE p2.      

A transposon with an unusual LTR arrangement from Chlamydomonas reinhardtii contains an internal tandem array of 76 bp repeats.

TOC1, a transposable element from Chlamydomonas reinhardtii, is 5662 bases long. The 217 and 237 base long terminal repeat sequences of TOC1 are unusually arranged around the 4600 and 123 base unique regions: [217]-4600-[237] [217]-123-[237]. Although TOC1 contains long terminal repeats and most TOC1 elements are complete, features shared with virus-like retroposons, its unique 4600 base region is more similar to the structure of the L1 family of non-virus retroposons: first, 11 3/4 tandemly repeated copies of a 76 base repeat are found 813 bases from the left end of TOC1, and second using the universal genetic code large open reading frames were not found in TOC1. The relationship between TOC1, virus-like retroposons and the L1 family of non-virus retroposons is unclear and may be very distant since only poor similarity was found between the TOC1 encoded ORFs and retrovirus polypeptides. The length of the tandem array of 76 base repeat sequences was conserved in most TOC1 elements and solo 76 base repeat sequences were not found outside TOC1 elements in the C. reinhardtii genome. Nucleotide substitutions allow all copies of the 76 base repeat to be distinguished from one another.     

Presence and phylogenetic analysis of HERV-K LTR on human X and Y chromosomes: evidence for recent proliferation

The K group of human endogenous retroviruses (HERV-K) has been suggested to have a role in disease and has recently been shown to include long terminal repeat (LTR) elements that are human specific. Here we investigated the presence of HERV-K LTRs on the human X and Y chromosomes with the use of PCR on a monochromosomal somatic cell hybrid DNA panel. We report twelve such sequences on the X chromosome and ten sequences on the Y chromosome. Phylogenetic analysis reveals that clones X2, 4, 5, 6, 7, 11, 15 from the X chromosome and clones Y4, 5, 7, 10 from the Y chromosome are closely related to the human-specific members of Medstrand and Mager's cluster 9. The sequence of clone Y7 from the Y chromosome is identical with human-specific HERV-K LTR element (AC002350) from chromosome 12q24. The findings suggest recent proliferation and transposition of HERV-K LTR elements on these chromosomes. Such events may have contributed to structural change and genetic variation in the human genome. We draw attention to evolutionarily recent changes in homologies between X and Y chromosomes as a method of further investigating such transpositions.     

Base sequence studies of 300 nucleotide renatured repeated human DNA clones

A band of 300 nucleotide long duplex DNA is released by treating renatured repeated human DNA with the single strand-specific endonuclease S₁. Since many of the interspersed repeated sequences in human DNA are 300 nucleotides long, this band should be enriched in such repeats. We have determined the nucleotide sequences of 15 clones constructed from these 300 nucleotide S₁-resistant repeats. Ten of these cloned sequences are members of the Alu family of interspersed repeats. These ten sequences share a recognizable consensus sequence from which individual clones have an average divergence of 12.8%. The 300 nucleotide Alu family consensus sequence has a dimeric structure and was evidently formed from a head to tail duplication of an ancestral monomeric sequence. Three of the remaining clones are variations on a simple pentanucleotide sequence previously reported for human satellite III DNA. Two of the 15 clones have distinct and complex sequences and may represent other families of interspersed repeated sequences.     

Characterization of a human orphon 28 S ribosomal DNA

We have isolated clones in which two regions of the human genome are represented, each containing an orphon: a dispersed copy of 28S rDNA. Nucleotide (nt) sequence analysis established that one of these, H28S-O1, corresponds to nt 3627-4105 of human 28S rDNA, but in a mutated form. The orphon was flanked on one side by a portion of the L1Hs long interspersed repeat family of the human genome. Although H25S-O1 is not flanked by the terminal direct repeats characteristic of transposed DNA, it is possible that it is a processed pseudogene.     

Human endogenous retrovirus K106 (HERV-K106) was infectious after the emergence of anatomically modern humans

HERV-K113 and HERV-K115 have been considered to be among the youngest HERVs because they are the only known full-length proviruses that are insertionally polymorphic and maintain the open reading frames of their coding genes. However, recent data suggest that HERV-K113 is at least 800,000 years old, and HERV-K115 even older. A systematic study of HERV-K HML2 members to identify HERVs that may have infected the human genome in the more recent evolutionary past is lacking. Therefore, we sought to determine how recently HERVs were exogenous and infectious by examining sequence variation in the long terminal repeat (LTR) regions of all full-length HERV-K loci. We used the traditional method of inter-LTR comparison to analyze all full length HERV-Ks and determined that two insertions, HERV-K106 and HERV-K116 have no differences between their 5' and 3' LTR sequences, suggesting that these insertions were endogenized in the recent evolutionary past. Among these insertions with no sequence differences between their LTR regions, HERV-K106 had the most intact viral sequence structure. Coalescent analysis of HERV-K106 3' LTR sequences representing 51 ethnically diverse individuals suggests that HERV-K106 integrated into the human germ line approximately 150,000 years ago, after the emergence of anatomically modern humans.     

L1 repeat elements in the human epsilon-G gamma-globin gene intergenic region: sequence analysis and concerted evolution within this family

We have deduced the sequence of a composite long interspersed repeated DNA in primates and herein describe its relationship to a complex repeat element (L1Heg) located in the interval linking the human epsilon- and G gamma-globin genes. The main element of L1Heg is 3' truncated and interrupted by the insertion of the 3' end of a second L1 element. Transposition of L1Heg into this intergenic locus generated a 62-bp duplication of flanking sequences. In contrast, insertion of the second repeat may have been mediated by homology between donor and target sequences. The main repeat represents a novel class of abundant elements whose sequences have diverged from other rodent and primate LINES approximately 1.3 kb downstream from the 5' terminus of L1Heg. Comparison of L1Heg with the sequences of two other related L1 members revealed a complex set of rearrangements confined within a region that resembles the long terminal repeats of other types of retroposons. The boundaries of conversion-like events were defined on the basis of the clustering of nucleotide sequence variants common to two or more nonallelic 3' L1H elements. Several of these events are apparently initiated or resolved within a common 150-bp region that coincides with the 3' terminus of a pan-mammalian open reading frame. This analysis showed that concerted genetic interactions and random drift both contribute appreciably to sequence variation within this set of L1H members.     

Comparative study of the genomic organization of DNA repeats within the 5′-flanking region of the natural resistance-associated macrophage protein gene (NRAMP1) between humans and great apes

The human NRAMP1 gene located on Chromosome (Chr) region 2q35 is a candidate gene for increased risk of infection by several intracellular macrophage parasites, including M. tuberculosis and M. leprae. In search for a possible mutational hot spot, we have analyzed a 3.5-kb region 5′ to NRAMP1 that is highly enriched for DNA repeat sequences. The repeat sequences could be grouped into one Mer element and six Alu elements, representing five Alu subfamilies, that had integrated in the same DNA region during successive rounds of Alu retropositional activity. Comparative sequence analysis of the Alu cluster region in humans, chimpanzee (Pan paniscus), and gorilla (Gorilla gorilla) revealed only modest sequence variability and failed to detect any evidence for genomic instability of the highly repetitive DNA region. These results show that sequence length variants in the Alu-flanking regions as well as nucleotide substitutions are the most common genomic variations even in a region of extreme Alu-clustering. Moreover, the high degree of sequence conservation among three primate species argues against the Alu cluster being the site of frequent genomic rearrangements or other frequent genetic events that might influence NRAMP1 expression. Received: 20 September 1997 / Accepted: 23 January 1998     

Distribution of Alu and L1 repeats in human YAC recombinants

Evidence is accumulating that the two major families of interspersed repeated human DNA sequences, Alu and L1, are not randomly distributed. However, only limited information is available on their relative long-range distribution. We have analyzed a set of randomly selected, human Chromosome (Chr) 11-specific YAC recombinants constituting a total length of about 2 Mbp for the local and global distribution of Alu and L1 repeats: the data show a strong asymmetry in the distribution of these two repeat classes and give weight, at the long-range molecular level, to previous studies indicating their partition in the human genome; they also suggest a strong tendency for L1 repeats to cluster, with a higher proportion of full-length elements than expected.     

The Chinese hamster Alu-equivalent sequence: a conserved highly repetitious, interspersed deoxyribonucleic acid sequence in mammals has a structure suggestive of a transposable element.

A consensus sequence has been determined for a major interspersed deoxyribonucleic acid repeat in the genome of Chinese hamster ovary cells (CHO cells). This sequence is extensively homologous to (i) the human Alu sequence (P. L. Deininger et al., J. Mol. Biol., in press), (ii) the mouse B1 interspersed repetitious sequence (Krayev et al., Nucleic Acids Res. 8:1201-1215, 1980) (iii) an interspersed repetitious sequence from African green monkey deoxyribonucleic acid (Dhruva et al., Proc. Natl. Acad. Sci. U.S.A. 77:4514-4518, 1980) and (iv) the CHO and mouse 4.5S ribonucleic acid (this report; F. Harada and N. Kato, Nucleic Acids Res. 8:1273-1285, 1980). Because the CHO consensus sequence shows significant homology to the human Alu sequence it is termed the CHO Alu-equivalent sequence. A conserved structure surrounding CHO Alu-equivalent family members can be recognized. It is similar to that surrounding the human Alu and the mouse B1 sequences, and is represented as follows: direct repeat-CHO-Alu-A-rich sequence-direct repeat. A composite interspersed repetitious sequence has been identified. Its structure is represented as follows: direct repeat-residue 47 to 107 of CHO-Alu-non-Alu repetitious sequence-A-rich sequence-direct repeat. Because the Alu flanking sequences resemble those that flank known transposable elements, we think it likely that the Alu sequence dispersed throughout the mammalian genome by transposition.