Deciphering the code for retroviral integration target site selection

Upon cell invasion, retroviruses generate a DNA copy of their RNA genome and integrate retroviral cDNA within host chromosomal DNA. Integration occurs throughout the host cell genome, but target site selection is not random. Each subgroup of retrovirus is distinguished from the others by attraction to particular features on chromosomes. Despite extensive efforts to identify host factors that interact with retrovirion components or chromosome features predictive of integration, little is known about how integration sites are selected. We attempted to identify markers predictive of retroviral integration by exploiting Precision-Recall methods for extracting information from highly skewed datasets to derive robust and discriminating measures of association. ChIPSeq datasets for more than 60 factors were compared with 14 retroviral integration datasets. When compared with MLV, PERV or XMRV integration sites, strong association was observed with STAT1, acetylation of H3 and H4 at several positions, and methylation of H2AZ, H3K4, and K9. By combining peaks from ChIPSeq datasets, a supermarker was identified that localized within 2 kB of 75% of MLV proviruses and detected differences in integration preferences among different cell types. The supermarker predicted the likelihood of integration within specific chromosomal regions in a cell-type specific manner, yielding probabilities for integration into proto-oncogene LMO2 identical to experimentally determined values. The supermarker thus identifies chromosomal features highly favored for retroviral integration, provides clues to the mechanism by which retrovirus integration sites are selected, and offers a tool for predicting cell-type specific proto-oncogene activation by retroviruses.     

Nucleotide sequence analysis of avian retroviruses: structural similarities with transposable elements

Integrated retroviral genomes are flanked by direct repeats of sequences derived from the termini of the viral RNA genome. These sequences are designated long terminal repeats (LTRs). We have determined and analyzed the nucleotide sequence of the LTRs from several exogenous and endogenous avian retroviruses. These LTRs possess several structural similarities with eukaryotic and prokaryotic transposable elements: 1) inverted complementary repeats at the termini, 2) deletions of sequences adjacent to the LTR, 3) small duplications of host sequences flanking the integrated provirus, and 4) sequence homologies with transposable and other genetic elements. These observations suggest that LTRs function in the integration and perhaps transposition of retrovirus genomes. Evidence exists for the presence of a strong promoter sequence within the LTR. The retroviral LTR also contains a "Hogness box" up-stream of the capping site and a poly(A) signal. These features suggest an additional role for the LTR in the regulation of gene expression.     

Retroviral infection of hES cells produces random-like integration patterns

Retroviral integration provides us with a powerful tool to realize prolonged gene expressions that are often critical to gene therapy. However, the perturbation of gene regulations in host cells by viral genome integration can lead to detrimental effects, yielding cancer. The oncogenic potential of retroviruses is linked to the preference of retroviruses to integrate into genomic regions that are enriched in gene regulatory elements. To better navigate the double-edged sword of retroviral integration we need to understand how retroviruses select their favored genomic loci during infections. In this study I showed that in addition to host proteins that tether retroviral pre-integration complexes to specific genomic regions, the epigenetic architecture of host genome might strongly affect retroviral integration patterns. Specifically, retroviruses showed their characteristic integration preference in differentiated somatic cells. In contrast, retroviral infections of hES cells, which are known to display decondensed chromatin, produced random-like integration patterns lacking of strong preference for regulatory-element-rich genomic regions. Better identification of the cellular and viral factors that determine retroviral integration patterns will facilitate the design of retroviral vectors for safer use in gene therapy.     

Full-sized HERV-K (HML-2) human endogenous retroviral LTR sequences on human chromosome 21: map locations and evolutionary history

One of the evolutionary mechanisms for acquisition of novel functional sequences can be domestication of exogenous retroviruses that have been integrated into the germ line. The whole genome mapping of such elements in various species could reveal differences in positions of the retroviral integration and suggest possible roles of these differences in speciation. Here, we describe the number, locations and sequence features of the human endogenous retrovirus HERV-K (HML-2) long terminal repeat (LTR) sequences on human chromosome 21. We show that their distribution along the chromosome is not only non-random but also roughly correlated with the gene density. Amplification of orthologous LTR sites from a number of primate genomes produced patterns of presence and absence for each LTR sequence and allowed determination of the phylogenetic ages and evolutionary order of appearance of individual LTRs. The identity level and phylogenetic age of the LTRs did not correlate with their map locations. Thus, despite the non-random distribution of LTRs, they have apparently been inserted randomly into the chromosome relative to each other. As evidenced in previous studies of chromosomes 19 and 22, this is a characteristic of HERV-K integration.     

Fusion proteins consisting of human immunodeficiency virus type 1 integrase and the designed polydactyl zinc finger protein E2C direct integration of viral DNA into specific sites

In order to establish a productive infection, a retrovirus must integrate the cDNA of its RNA genome into the host cell chromosome. While this critical process makes retroviruses an attractive vector for gene delivery, the nonspecific nature of integration presents inherent hazards and variations in gene expression. One approach to alleviating the problem involves fusing retroviral integrase to a sequence-specific DNA-binding protein that targets a defined chromosomal site. We prepared proteins consisting of wild-type or truncated human immunodeficiency virus type 1 (HIV-1) integrase fused to the synthetic polydactyl zinc finger protein E2C. The purified fusion proteins bound specifically to the 18-bp E2C recognition sequence as analyzed by DNase I footprinting. The fusion proteins were catalytically active and biased integration of retroviral DNA near the E2C-binding site in vitro. The distribution was asymmetric, and the major integration hot spots were localized within a 20-bp region upstream of the C-rich strand of the E2C recognition sequence. Integration bias was not observed with target plasmids bearing a mutated E2C-binding site or when HIV-1 integrase and E2C were added to the reaction as separate proteins. The results demonstrate that the integrase-E2C fusion proteins offer an efficient approach and a versatile framework for directing the integration of retroviral DNA into a predetermined DNA site.     

Studies of endogenous retroviruses reveal a continuing evolutionary saga

Retroviral replication involves the formation of a DNA provirus integrated into the host genome. Through this process, retroviruses can colonize the germ line to form endogenous retroviruses (ERVs). ERV inheritance can have multiple adverse consequences for the host, some resembling those resulting from exogenous retrovirus infection but others arising by mechanisms unique to ERVs. Inherited retroviruses can also confer benefits on the host. To meet the different threats posed by endogenous and exogenous retroviruses, various host defences have arisen during evolution, acting at various stages on the retrovirus life cycle. In this Review, I describe our current understanding of the distribution and architecture of ERVs, the consequences of their acquisition for the host and the emerging details of the intimate evolutionary relationship between virus and vertebrate host.     

Presence of a retroviral encapsidation sequence in nonretroviral RNA increases the efficiency of formation of cDNA genes.

We showed previously that retrovirus vector particles can encapsidate RNAs without retroviral cis-acting sequences, that such RNAs are reverse transcribed in infected target cells, and that the cDNA copies are inserted into the host genome resulting in cDNA genes (R. Dornburg and H. M. Temin, Mol. Cell. Biol. 8:2328-2334, 1988). To provide further evidence that this retrovirus-mediated gene transfer occurred through an RNA intermediate, we constructed retroviral vectors containing an intron from a cellular gene. This intron was lost in a cDNA gene formed after infection with retroviral particles, establishing that an RNA intermediate had existed. Retroviral vectors with additional encapsidation sequences were constructed. The presence of a murine leukemia virus encapsidation sequence in an mRNA transcribed from the hygromycin B phosphotransferase gene increased the efficiency of encapsidation into spleen necrosis virus vector particles and the formation of cDNA genes by approximately 2 orders of magnitude.     

Transforming DNA integrates into the host chromosome

A series of rat liver cotransformed cell lines have been constructed containing from 5 to 100 copies of a variant human growth hormone gene. We have used hybridization in situ to demonstrate that most, if not all, cotransformed sequences reside in a chromosome of the host cell. In each of four cell lines examined, hybridization was restricted to a single chromosomal site with no extrachromosomal sites apparent. The site was invariant within each line; however, each line revealed a different site of integration for transforming sequences. In two of the four lines, transforming DNA resided at or near the site of gross chromosomal rearrangements, in one line near an rDNA site, and in one line in the middle of an apparently normal chromosome. Thus, insertion is not restricted to a unique chromosome or chromosomal region.     

Quasispecies in retrotransposons: a role for sequence variability in Tnt1 evolution

Retroviral replication is a very error-prone process. Replication of retroviruses gives rise to populations of closely related but different genomes referred to as ‘quasispecies’. This huge swarm of different sequences constitutes a reservoir of potentially useful genomes in case of an environmental change, endowing retroviruses with extreme adaptability. Retrotransposons are mobile genetic elements closely related to retroviruses, and retrotransposition is as error prone as retroviral replication. The Tnt1 retrotransposon is present in hundreds of copies in the genome of tobacco that show a high level of sequence heterogeneity. When Tnt1 is expressed, its RNA is not a single sequence but a population of sequences displaying a quasispecies-like structure. This population structure gives to Tnt1, as in the case of retroviruses, a high sequence plasticity and an adaptive capacity. We propose this adaptivity as the major reason for Tnt1 maintenance in Nicotiana genomes and we discuss in this paper the importance of sequence variability for Tnt1 evolution. This revised version was published online in August 2006 with corrections to the Cover Date.     

Retroviral DNA integration: HIV and the role of LEDGF/p75

To replicate, a retrovirus must integrate a DNA copy of its RNA genome into a chromosome of the host cell. Integration is not random in the host genome but favors particular regions, and preferences differ among retroviruses. Several mechanisms might play a part in this favored integration targeting: (i) open chromatin might be preferentially accessible for viral DNA integration; (ii) DNA replication during cell division might facilitate access of integration complexes to favored sites; and (iii) cellular proteins bound to the host chromosome might tether integration complexes to favored regions. This review summarizes recent advances in understanding the mechanisms of retroviral integration, focusing on LEDGF/p75--the first cellular protein shown to have a role in directing HIV DNA integration. Studies on LEDGF/p75 indicate that it directs HIV integration site selection by a tethering interaction, whereas the chromatin accessibility or cell cycle models are less well supported. Understanding viral integration will help improve the safety of retrovirus-based vectors used in gene therapy.     

Analysis of the virogenes related to the rhesus monkey endogenous type C retrovirus in monkeys and apes.

Molecular hybridization studies were carried out by using a [3H]complementary DNA (cDNA) probe to compare the endogenous type C retrovirus of rhesus monkeys (MMC-1) with other known retroviruses and related sequences in various primate DNAs. The genomic RNA of the endogenous type C retrovirus of stumptail monkeys (MAC-1) was found to be highly related to the MMC-1 cDNA probe, whereas the other retroviral RNAs tested showed no homology. Related sequences were found in Old World monkey DNAs and to a lesser extent in gorilla dn chimpanzee DNAs. No homology was detected between MMC-1 cDNA and DNA of gibbon, orangutan, or human origin. Restriction endonuclease analysis of genomic DNA indicated that many of the several hundred sequences related to MMC-1 in rhesus monkey DNA differed from that integrated into DNA of infected canine cells. Gorilla and chimpanzee DNAs contained a specific restriction endonuclease fragment of the MMC-1 genome.     

Crystal structure of a pivotal domain of human syncytin-2, a 40 million years old endogenous retrovirus fusogenic envelope gene captured by primates

HERV-FRD is a human endogenous retrovirus that entered the human genome 40 million years ago. Its envelope gene, syncytin-2, was diverted by an ancestral host most probably because of its fusogenic property, for a role in placenta morphogenesis. It was maintained in a functional state in all primate branches as a bona fide cellular gene, submitted to a very low mutation rate as compared to infectious retrovirus genomes. The structure of the syncytin-2 protein thus provides a good insight into that of the oldest mammalian retroviral envelope. Here, we report the crystal structure of a central fragment of its "fossil" ectodomain, allowing a remarkable superposition with the structures of the corresponding domains of present-day infectious retroviruses, in spite of a more than 60% divergent sequence. These results suggest the existence of a unique structural solution selected by these proteins for their fusogenic function.     

Banding profiles of LTR of human endogenous retrovirus HERV-A in 24 chromosomes in somatic cell hybrids.

The human genome carries multiple copies of sequences related to endogenous retroviral genomes. We investigated the distribution of one of these sequences, HERV-A, in 24 human chromosomes by Southern analyses using DNAs from flow-sorted chromosomes or rodent cells carrying a single human chromosome. The results showed that HERV-A is distributed among all human chromosomes and that each chromosome has a specific Southern blot profile. The chromosome-specific pattern did not show significant polymorphism, except in a few cases, when the same chromosome obtained from different individuals was compared. These chromosome-specific Southern hybridization profiles may be useful for chromosome karyotyping. This would allow the integrity of human chromosomes in human-rodent somatic cell hybrids to be monitored without using conventional cytogenetic methods.     

Fidelity of Target Site Duplication and Sequence Preference during Integration of Xenotropic Murine Leukemia Virus-Related Virus

Xenotropic murine leukemia virus (MLV)-related virus (XMRV) is a new human retrovirus associated with prostate cancer and chronic fatigue syndrome. The causal relationship of XMRV infection to human disease and the mechanism of pathogenicity have not been established. During retrovirus replication, integration of the cDNA copy of the viral RNA genome into the host cell chromosome is an essential step and involves coordinated joining of the two ends of the linear viral DNA into staggered sites on target DNA. Correct integration produces proviruses that are flanked by a short direct repeat, which varies from 4 to 6 bp among the retroviruses but is invariant for each particular retrovirus. Uncoordinated joining of the two viral DNA ends into target DNA can cause insertions, deletions, or other genomic alterations at the integration site. To determine the fidelity of XMRV integration, cells infected with XMRV were clonally expanded and DNA sequences at the viral-host DNA junctions were determined and analyzed. We found that a majority of the provirus ends were correctly processed and flanked by a 4-bp direct repeat of host DNA. A weak consensus sequence was also detected at the XMRV integration sites. We conclude that integration of XMRV DNA involves a coordinated joining of two viral DNA ends that are spaced 4 bp apart on the target DNA and proceeds with high fidelity.     

Weak palindromic consensus sequences are a common feature found at the integration target sites of many retroviruses

Integration into the host genome is one of the hallmarks of the retroviral life cycle and is catalyzed by virus-encoded integrases. While integrase has strict sequence requirements for the viral DNA ends, target site sequences have been shown to be very diverse. We carefully examined a large number of integration target site sequences from several retroviruses, including human immunodeficiency virus type 1, simian immunodeficiency virus, murine leukemia virus, and avian sarcoma-leukosis virus, and found that a statistical palindromic consensus, centered on the virus-specific duplicated target site sequence, was a common feature at integration target sites for these retroviruses.     

Approaches to site-directed DNA integration based on transposases and retroviral integrases

The ability of retroviruses and transposons to insert their genome into the host cell makes them attractive objects for constructing gene therapy vectors. However, enzymes that insert genetic material do not possess any selectivity relative to target nucleotide sequences, which results in almost random DNA insertion into the recipient cell genome. This leads to mutations that in turn may cause certain undesirable consequences and sometimes neoplastic cell transformation. For successful functioning, it is a primary necessity to modify a retrovirus and transposon based genetic therapy systems in such a way that the directed vector integration into a target sequence in the human genome can be achieved. In this review, the approaches to date that have been developed for highly specific modification of the genome using fusion protein construction based on retroviral integrases and transposases are discussed, as well as cellular factors interacting with these enzymes.