Physical mapping of sequences homologous to an endogenous retrovirus LTR on human chromosome 19

Nucleotide sequence and phylogenetic analysis of long terminal repeats of human endogenous retrovirus K family (HERV-K) on human chromosomes

It has been suggested that human endogenous retroviruses K family (HERV-K) has a role in disease, and solitary long terminal repeats (LTRs) of HERV-K have been potentially capable of affecting the expression of closely located genes. Using the human monochromosomes 8, 9, 17, and 18, with specific PCR primers, we identified thirty-four sequences of new HERV-K LTRs. Those LTR elements were analyzed phylogenetically with the human-specific HERV-K LTRs using neighbor-joining and maximum parsimony methods. Clones HKL8-5, HKL9-5, and HKL9-8 are related by more than 99% homology with the human-specific HERV-K LTRs. The HKL9-5 clone on chromosome 9 was 100% identical with the sequences of human-specific LTR, AC002400, on chromosome 16. The findings suggest that there has been recent proliferation, transposition, or chromosomal translocation of HERV-K LTR elements on human chromosomes.

Solitary HERV-K LTRs possess bi-directional promoter activity and contain a negative regulatory element in the U5 region

Reporter gene analysis of HERV-K solitary long terminal repeats (LTRs) showed that they retain detectable activity in human teratocarcinoma cells, and can direct the transcription in both orientations relative to the reporter gene. Deletion analysis demonstrated the possible existence of alternative promoters within the LTR as well as a silencer-like element in the U5 region. Our results indicate also that all-trans-retinoic acid is capable of modulating expression of the reporter gene directed by a HERV-K LTR in NT2/D1 cells.

Retroviruses and primate evolution

Human endogenous retroviruses (HERVs), probably representing footprints of ancient germ-cell retroviral infections, occupy about 1% of the human genome. HERVs can influence genome regulation through expression of retroviral genes, either via genomic rearrangements following HERV integrations or through the involvement of HERV LTRs in the regulation of gene expression. Some HERVs emerged in the genome over 30 MYr ago, while others have appeared rather recently, at about the time of hominid and ape lineages divergence. HERVs might have conferred antiviral resistance on early human ancestors, thus helping them to survive. Furthermore, newly integrated HERVs could have changed the pattern of gene expression and therefore played a significant role in the evolution and divergence of Hominoidea superfamily. Comparative analysis of HERVs, HERV LTRs, neighboring genes, and their regulatory interplay in the human and ape genomes will help us to understand the possible impact of HERVs on evolution and genome regulation in the primates. BioEssays 22:161-171, 2000.

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.

Perpetually mobile footprints of ancient infections in human genome

Up to 1% of the human genome is represented by human endogenous retroviruses (HERVs) and their fragments that are likely footprints of ancient primate germ-cell infections by retroviruses that occurred 10-60 million years ago. HERV solitary long terminal repeats (LTRs) can be often met in close vicinity to functional genes. The LTRs comprise a set of regulatory sequences like promoters, enhancers, hormone responsive elements and polyadenylation signals that might come out as new regulatory signals to resident genes and thus change their regulation in evolution. Moreover, the LTRs have a potential for chromatin remodeling that can also modulate gene expression. This review describes the integration specificity and distribution of the HERVs and LTRs in the human genome and discusses possible functional consequences of their integration in the vicinity of genes.

Long terminal repeats of human endogenous retrovirus K family (HERV-K) specifically bind host cell nuclear proteins

Solitary long terminal repeats (LTRs) of the human endogenous retroviruses, scattered in several thousand copies throughout the human genome, are potentially capable of affecting the expression of closely located genes. To assess their regulatory potential, the LTR sequences of one of the most abundant HERV families (HERV-K) were screened for the presence of binding sites for the host cell nuclear factors using mobility shift and UV-crosslinking assays. It was shown that the LTR sequences of two subfamilies harbor a specific binding site for a complex consisting of at least three proteins, ERF1, ERF2 and ERF3 of 98, 91 and 88 kDa apparent molecular mass, respectively. This binding site is located in the 5' region of the LTR U3 element. The preservation of the specific protein binding site in different HERV-K LTR sequences suggests their possible role in regulation of nearby located genes.

Positioning of 72 potentially full size LTRs of human endogenous retroviruses HERV-K on the human chromosome 19 map. Occurrences of the LTRs in human gene sites

Seventy-two near full size long terminal repeats (LTRs) of human endogenous retrovirus of K-family (HERV-K) have been precisely located on the metric map of human chromosome 19. The LTR-related sequences were identified and assigned to cosmids by hybridization with two independent chromosome 19 specific cDNA clones corresponding to different parts of U3 region of LTR of HERV-K. The presence of full-size LTR sequences in a cosmid was further verified by PCR assay with a pair of primers complementary to the termini of the LTR. Coincidences of the LTR and the known genes positions are discussed.

Distribution of human endogenous retroviral RTVL-H2 LTR sequences among human chromosomes

The human genome carries multiple copies of sequences related to endogenous retroviral DNA. We report here the distribution of a new multicopy long terminal repeat (LTR) sequence that has been a part of an endogenous retrovirus-like sequence RTVL-H2. Twenty-four human chromosomes were either separated by flow sorting or by using rodent cells carrying a single human chromosome, and the DNA was subjected to Southern analyses using the RTVL-H2 DNA as a probe. The RTVL-H2 LTRs were distributed among all the human chromosomes, but the density and the profile differed from chromosome to chromosome. The same chromosome obtained from different individuals showed essentially the same chromosome-specific patterns. The distribution of the RTVL-H2 LTRs among different chromosomes did not correlate with the distribution of LTRs from another endogenous retroviral DNA, HERV-A, strongly suggesting that there is no preferred chromosome or a region thereof, for the integration. The possibility of rearrangement or amplification after integration is discussed.

Comparative analyses of LTRs of the ERV-H family of primate-specific retrovirus-like elements isolated from marmoset, African green monkey, and man

We have isolated 8 different long terminal repeat (LTR) sequences of the ERV-H family of endogenous retrovirus-like elements from human chromosome 18, 9 from African green monkey, and 28 from marmoset. Human ERV-H LTRs have been divided into three types designated Type I, Type Ia, and Type II. Comparative analyses of the 45 isolated LTRs and 60 human ERV-H LTRs enabled a further subdivision into 13 subtypes. Type I elements were widely distributed in all three species. Their average evolutionary age (40 MYr), estimated by a consensus sequence approach, suggests that they first expanded in the genomes at the time New- and Old World monkeys diverged. The occurence of some very old Type I sequences indicate that ERV-H elements may have integrated even before prosimians and primates diverged. Type Ia and - II elements were found in both monkey species. Promoter active Type I and Type Ia LTRs were found while Type II LTRs were inactive. Promoter active Type I LTRs generally contained a functional GC/GT box immediately 3' to the TATA box, providing strong binding of Sp1 family proteins, while the highly promoter active Type Ia element H6 contained synergistically acting Sp1 binding sites located in the U3 enhancer region.

Factors affecting the priming efficiency of short contiguous oligonucleotide strings in the primer walking strategy of DNA sequencing

We use modified oligonucleotides with enhanced strength of complementary DNA binding for primer walking DNA sequencing with strings of short contiguous oligonucleotides as primers. Such an approach allows us to reduce the probability of primer failures due to unstable binding of oligos with templates. In this paper the factors affecting the priming efficiency of segmented primers (strings composed of several short oligonucleotides contiguously juxtaposed on the template) used for DNA sequencing were investigated. Modified oligonucleotides were used to discriminate the effects caused by intrinsic properties of the oligonucleotides and by template features. It was shown that the most crucial factor is the stability of the duplex formed by the template with the 3'-outermost oligonucleotide of a string. The data were obtained with a model M13 template and in the process of sequencing the region flanking a long terminal repeat of human endogenous retrovirus HERVK mapped on chromosome 19. The sequencing was done by primer walking with strings of contiguous modified hexanucleotides. The effects revealed should be taken into consideration when choosing oligonucleotide units of segmented primers and for construction of minimised libraries composed of short unit oligonucleotides.