Many human endogenous retrovirus K (HERV-K) proviruses are unique to humans.

BACKGROUND: Endogenous retroviruses contribute to the evolution of the host genome and can be associated with disease. Human endogenous retrovirus K (HERV-K) is related to the mouse mammary tumor virus and is present in the genomes of humans, apes and cercopithecoids (Old World monkeys). It is unknown how long ago in primate evolution the full-length HERV-K proviruses that are in the human genome today were formed. RESULTS: Ten full-length HERV-K proviruses were cloned from the human genome. Using provirus-specific probes, eight of the ten were found to be present in a genetically diverse set of humans but not in other extant hominoids. Intact preintegration sites for each of these eight proviruses were present in the apes. A ninth provirus was detected in the human, chimpanzee, bonobo and gorilla genomes, but not in the orang-utan genome. The tenth was found only in humans, chimpanzees and bonobos. Complete sequencing of six of the human-specific proviruses showed that full-length open reading frames for the retroviral protein precursors Gag-Pro-Pol or Env were each present in multiple proviruses. CONCLUSIONS: At least eight full-length HERV-K genomes that are in the human germline today integrated after humans diverged from chimpanzees. All of the viral open reading frames and cis-acting sequences necessary for HERV-K replication must have been intact during the recent time when these proviruses formed. Multiple full-length open reading frames for all HERV-K proteins are present in the human genome today.     

A HERV-K provirus in chimpanzees, bonobos and gorillas, but not humans

Evidence from DNA sequencing studies strongly indicated that humans and chimpanzees are more closely related to each other than either is to gorillas [1-4]. However, precise details of the nature of the evolutionary separation of the lineage leading to humans from those leading to the African great apes have remained uncertain. The unique insertion sites of endogenous retroviruses, like those of other transposable genetic elements, should be useful for resolving phylogenetic relationships among closely related species. We identified a human endogenous retrovirus K (HERV-K) provirus that is present at the orthologous position in the gorilla and chimpanzee genomes, but not in the human genome. Humans contain an intact preintegration site at this locus. These observations provide very strong evidence that, for some fraction of the genome, chimpanzees, bonobos, and gorillas are more closely related to each other than they are to humans. They also show that HERV-K replicated as a virus and reinfected the germline of the common ancestor of the four modern species during the period of time when the lineages were separating and demonstrate the utility of using HERV-K to trace human evolution.     

A Single Amino Acid Substitution in a Segment of the CA Protein within Gag That Has Similarity to Human Immunodeficiency Virus Type 1 Blocks Infectivity of a Human Endogenous Retrovirus K Provirus in the Human Genome

Human endogenous retrovirus K (HERV-K) is the most intact retrovirus in the human genome. However, no single HERV-K provirus in the human genome today appears to be infectious. Since the Gag protein is the central component for the production of retrovirus particles, we investigated the abilities of Gag from two HERV-K proviruses to support production of virus-like particles and viral infectivity. HERV-K113 has full-length open reading frames for all viral proteins, while HERV-K101 has a full-length gag open reading frame and is expressed in human male germ cell tumors. The Gag of HERV-K101 allowed production of viral particles and infectivity, although at lower levels than observed with a consensus sequence Gag. Thus, including HERV-K109, at least two HERV-K proviruses in human genome today have functional Gag proteins. In contrast, HERV-K113 Gag supported only very low levels of particle production, and no infectivity was detectable due to a single amino acid substitution (I516M) near the extreme C terminus of the CA protein within Gag. The sequence of this portion of HERV-K CA showed similarities to that of human immunodeficiency virus type 1 and other primate immunodeficiency viruses. The extreme C terminus of CA may be a general determinant of retrovirus particle production. In addition, precise mapping of the defects in HERV-K proviruses as was done here identifies the key polymorphisms that need to be analyzed to assess the possible existence of infectious HERV-K alleles within the human population.Approximately 8% of the human genome comprises endogenous retroviruses (ERVs) (33, 59). These viruses infect germ lineage cells and thereby enter the genome of the host species. Thus, endogenous proviruses (the integrated form of retroviral DNA) are transmitted from parents to offspring in genomic DNA. If ERV genomes are intact, viral particles may be generated that can reinfect the germ line and form proviruses at new positions in the host genome. However, ERVs are subject to the same mutagenic processes over evolutionary time as any cellular gene. In the absence of selective pressure on the host to maintain intact viral genomes, endogenous retroviral proviruses accrue mutations over evolutionary time that inactivate viral infectivity. Most of the ERVs in the human genome have converted to solo long terminal repeats (solo LTRs), which are the product of homologous recombination between LTRs at the ends of the complete viral genome. Other types of mutations, such as nucleotide substitutions, insertions, and deletions, can also affect ERV proviruses, and many of the retroviral proviruses in the human genome have been inactivated by such mutations, which created premature stop codons or frameshifts in viral open reading frames (ORFs). The vast majority of the ERVs present in humans today (and perhaps all of them) have incurred mutations that inactivated viral infectivity.One provirus that exists in the genome of approximately 20% of humans, human ERV K113 (HERV-K113, referred to here as K113), has full-length ORFs for all viral proteins (8, 63). However, this provirus does not appear to be infectious, as the pol and env genes of K113 do not support infectivity (9, 19, 20). K113 belongs to a subset of HERV-K called HML-2 (43). Since the human and chimpanzee lineages diverged about 6 million years ago (52), the only proviruses that entered the genome of the human lineage belong to this subgroup, although other members of this subgroup entered the germ line prior to the divergence of the human and chimpanzee lineages (8, 27, 44, 63). The human-specific proviruses of this subgroup are the most intact retroviruses in the human genome. Infectious HERV-K particles have been generated using two different approaches based on their DNA sequences. HERV-KCON (K-CON) was constructed based on the consensus sequence of human-specific HERV-K proviruses (34). Infectious HERV-K particles were also generated by combining pieces from three separate proviruses, HERV-K109 (K109) gag-pro, HERV-K115 pol, and HERV-K108 (K108) env (20). Thus, it may be that no single provirus is infectious, but recombination and/or genetic complementation among multiple genomic proviruses may be required to produce infectious HERV-K particles. This raises the questions of whether multiple functional HERV-K components exist in the human genome today and how close these components are to being able to form a functional viral genome that might be capable of reinfecting human cells.To begin addressing these issues, we examined two of the full-length HERV-K gag genes that exist in the human genome today. Like all retroviruses, HERV-K contains the four genes necessary for viral replication: gag, pro, pol, and env. The human-specific HERV-K proviruses exist in two forms, type I and type II (38, 39). The type II proviruses contain gag, pro, pol, and env plus an accessory gene, rec, that encodes a protein (Rec) that functions in nuclear export of unspliced viral RNA in a manner analogous to that of human immunodeficiency virus type 1 (HIV-1) Rev (12, 40, 41, 65, 66). In type I proviruses, the pol and env genes are fused in frame by a 292-bp deletion that includes the first coding exon of rec, and the viruses encode an additional protein called Np9 (5, 48). The gag genes are relevant to whether HERV-K components in the human genome today might form an infectious virus, as the Gag protein is sufficient to produce virus-like particles (VLPs) in the absence of other viral proteins (4). Formation of such particles is an essential step for subsequent viral replication. Therefore, we decided to investigate whether Gag proteins from K113 and a second provirus, HERV-K101 (K101), are active in functional assays.     

Hypermutation of an ancient human retrovirus by APOBEC3G

Human endogenous retroviruses (HERVs) comprise approximately 8% of the human genome, but all are remnants of ancient retroviral infections and harbor inactivating mutations that render them replication defective. Nevertheless, as viral “fossils,” HERVs may provide insights into ancient retrovirus-host interactions and their evolution. Indeed, one endogenous retrovirus [HERV-K(HML-2)], which has replicated in humans for the past few million years but is now thought to be extinct, was recently reconstituted in a functional form, and infection assays based on it have been established. Here, we show that several human APOBEC3 proteins are intrinsically capable of mutating and inhibiting infection by HERV-K(HML-2) in cell culture. We also present striking evidence that two HERV-K(HML-2) proviruses that are fixed in the modern human genome (HERV-K60 and HERV-KI) were subjected to hypermutation by a cytidine deaminase. Inspection of the spectrum of mutations that are found in HERV-K proviruses in the human genome and HERV-K DNA generated during in vitro replication in the presence of each of the human APOBEC3 proteins unequivocally identifies APOBEC3G as the cytidine deaminase responsible for hypermutation of HERV-K60 and HERV-KI. This is a rare example of the antiretroviral effects of APOBEC3G in the setting of natural human infection, whose consequences have been fossilized in human DNA, and a striking example of inactivation of ancient retroviruses in humans through enzymatic cytidine deamination.     

Nucleotide sequence of human endogenous retrovirus genome related to the mouse mammary tumor virus genome.

We determined the complete nucleotide sequence of the human endogenous retrovirus genome HERV-K10 isolated as the sequence homologous to the Syrian hamster intracisternal A-particle (type A retrovirus) genome. HERV-K10 is 9,179 base pairs long with long terminal repeats of 968 base pairs at both ends; a sequence 290 base pairs long, however, was found to be deleted. It was concluded that a composite genome having the 290-base-pair fragment is the prototype HERV-K provirus gag (666 codons), protease (334 codons), pol (937 codons), and env (618 codons) genes. The size of the protease gene product of HERV-K is essentially the same as that of A- and D-type oncoviruses but nearly twice that of other retroviruses. A comparison of the deduced amino acid sequences encoded by the pol region showed HERV-K to be closely related to types A and D retroviruses and even more so to type B retrovirus. It was noted that the env gene product of HERV-K structurally resembles the mouse mammary tumor virus (type B retrovirus) env protein, and the possible expression of the HERV-K env gene in human breast cancer cells is discussed.     

Presence of dUTPase in the Various Human Endogenous Retrovirus K (HERV-K) Families

Various retroviruses have been shown to encode dUTPase. The overall phylogeny of dUTPase is unclear, though. The human genome contains a significant amount of human endogenous retroviruses (HERV) representing fossilized sequences of ancient exogenous retroviruses. A few HERV families have been reported to harbor dUTPase domains. We surveyed the various HERV families for the presence of dUTPase and found that ancestors of all HERV-K families but one encoded dUTPase. With two exceptions phylogenetic analysis shows a monophyletic origin of dUTPase for the different HERV-K dUTPases. Sequences of consensus dUTPase domains suggest that the various exogenous ancestors of HERV-K once encoded active enzymes. Our analysis provides informations on dUTPase phylogeny and further shows that endogenous retroviruses provide important informations regarding retrovirus evolution.     

The distribution of the endogenous retroviruses HERV-K113 and HERV-K115 in health and disease

The human endogenous retroviruses HERV-K113 and HERV-K115 are full-length proviruses but unusual in being found in only a proportion of the population. Here, we study the geographic distribution of these HERVs and their prevalence in autoimmune disease. The frequency of HERV-K113 and HERV-K115 in 174 individuals from Africa was 21.8 and 34.1%, respectively, compared to 4.16 and 1% in 96 people in the United Kingdom (p < 0.001). Prevalence in Yemen (n = 56) was 8 and 7.14% and in Papua New Guinea (n = 54) 0% for both. In the United Kingdom, HERV-K113 was found in 15.6% of 96 Sj?gren's syndrome patients (p < 0.01) and 11.9% of 109 multiple sclerosis patients (p < 0.05). No increase in prevalence in either disease was seen with HERV-K115. These data suggest that both viruses are recently integrated and/or under positive evolutionary selection pressure. HERV-K113 may be a genetic risk factor for some types of autoimmunity.     

Identification, characterization, and comparative genomic distribution of the HERV-K (HML-2) group of human endogenous retroviruses

Background

Integration of retroviral DNA into a germ cell may lead to a provirus that is transmitted vertically to that host's offspring as an endogenous retrovirus (ERV). In humans, ERVs (HERVs) comprise about 8% of the genome, the vast majority of which are truncated and/or highly mutated and no longer encode functional genes. The most recently active retroviruses that integrated into the human germ line are members of the Betaretrovirus-like HERV-K (HML-2) group, many of which contain intact open reading frames (ORFs) in some or all genes, sometimes encoding functional proteins that are expressed in various tissues. Interestingly, this expression is upregulated in many tumors ranging from breast and ovarian tissues to lymphomas and melanomas, as well as schizophrenia, rheumatoid arthritis, and other disorders.

Results

No study to date has characterized all HML-2 elements in the genome, an essential step towards determining a possible functional role of HML-2 expression in disease. We present here the most comprehensive and accurate catalog of all full-length and partial HML-2 proviruses, as well as solo LTR elements, within the published human genome to date. Furthermore, we provide evidence for preferential maintenance of proviruses and solo LTR elements on gene-rich chromosomes of the human genome and in proximity to gene regions.

Conclusions

Our analysis has found and corrected several errors in the annotation of HML-2 elements in the human genome, including mislabeling of a newly identified group called HML-11. HML-elements have been implicated in a wide array of diseases, and characterization of these elements will play a fundamental role to understand the relationship between endogenous retrovirus expression and disease.     

Frequency of Human Endogenous Retroviral Sequences (HERV) K113 and K115 in the Polish Population,and Their Effect on HIV Infection

Background

The human genome contains about 8% of endogenous retroviral sequences originated from germ cell infections by exogenous retroviruses during evolution. Most of those sequences are inactive because of accumulation of mutations but some of them are still capable to be transcribed and translated. The latter are insertionally polymorphic HERV-K113 and HERV-K115. It has been suggested that their presence and expression was connected with several human diseases. It is also believed that they could interfere with the replication cycle of exogenous retroviruses, including HIV.

Results

Prevalence of endogenous retroviral sequences HERV-K113 and HERV-K115 was determined in the Polish population. The frequencies were found as 11.8% for HERV-K113 and 7.92% for HERV-K115. To verify the hypothesis that the presence of these HERVs sequences could affect susceptibility to HIV infection, comparison of a control group (HIV-negative, not exposed to HIV; n = 303) with HIV-positive patients (n = 470) and exposed but uninfected (EU) individuals (n = 121) was performed. Prevalence of HERV-K113 and HERV-K115 in the EU group was 8.26% and 5.71%, respectively. In the HIV(+) group we detected HERV-K113 sequences in 12.98% of the individuals and HERV-K115 sequences in 7.23% of the individuals. There were no statistically significant differences between groups studied.

Conclusion

The frequency of HERV-K113 and HERV-K115 sequences in Poland were found to be higher than usually shown for European populations. No relation between presence of the HERVs and HIV infection was detected.     

Evolutionary dynamics of the human endogenous retrovirus family HERV-K inferred from full-length proviral genomes

Several distinct families of endogenous retroviruses exist in the genomes of primates. Most of them are remnants of ancient germ-line infections. The human endogenous retrovirus family HERV-K represents the unique known case of endogenous retrovirus that amplified in the human genome after the divergence of human and chimpanzee lineages. There are two types of HERV-K proviral genomes differing by the presence or absence of 292 bp in the pol-env boundary. Human-specific insertions exist for both types. The analyses shown in the present work reveal that several lineages of type 1 and type 2 HERV-K proviruses remained transpositionally active after the human/chimpanzee split. The data also reflect the important role of mosaic evolution (either by recombination or gene conversion) during the evolutionary history of HERV-K. Received: 5 February 2001 / Accepted: 22 March 2001     

Inhibition of human endogenous retrovirus-K10 protease in cell-free and cell-based assays

A full-length and C-terminally truncated version of human endogenous retrovirus (HERV)-K10 protease were expressed in Escherichia coli and purified to homogeneity. Both versions of the protease efficiently processed HERV-K10 Gag polyprotein substrate. HERV-K10 Gag was also cleaved by human immunodeficiency virus, type 1 (HIV-1) protease, although at different sites. To identify compounds that could inhibit protein processing dependent on the HERV-K10 protease, a series of cyclic ureas that had previously been shown to inhibit HIV-1 protease was tested. Several symmetric bisamides acted as very potent inhibitors of both the truncated and full-length form of HERV-K10 protease, in subnanomolar or nanomolar range, respectively. One of the cyclic ureas, SD146, can inhibit the processing of in vitro translated HERV-K10 Gag polyprotein substrate by HERV-K10 protease. In addition, in virus-like particles isolated from the teratocarcinoma cell line NCCIT, there is significant accumulation of Gag and Gag-Pol precursors upon treatment with SD146, suggesting the compound efficiently blocks HERV-K Gag processing in cells. This is the first report of an inhibitor able to block cell-associated processing of Gag polypeptides of an endogenous retrovirus.     

Haplotype Analysis of the Human Endogenous Retrovirus Locus HERV-K(HML-2.HOM) and Its Evolutionary Implications

We and others recently identified an almost-intact human endogenous retrovirus (HERV), termed HERV-K(HML-2.HOM), that is usually organized as a tandem provirus. Studies on HERV proviral loci commonly rely on the analysis of single alleles being taken as representative for a locus. We investigated the frequency of HERV-K(HML-2.HOM) single and tandem alleles in various human populations. Our analysis revealed that another HERV-K(HML-2) locus, the so-called HERV-K(II) provirus, is also present as a tandem provirus allele in the human population. Proviral tandem formations were identified in various nonhuman primate species. We furthermore examined single nucleotide polymorphisms (SNPs) within the HERV-K(HML-2.HOM) proviral gag, prt, and pol genes, which all result in nonsense mutations. We identified four proviral haplotypes displaying different combinations of gag, prt, and pol SNPs. Haplotypes harboring completely intact proviral genes were not found. For the left provirus of the tandem arrangement a haplotype displaying intact gag and prt genes and a mutated pol was found in about two-thirds of individuals from different ethnogeographic origins. The same haplotype was always found in the right provirus. The various haplotypes point toward multiple recombination events between HERV-K(HML-2.HOM) proviruses. Based on these findings we derive a model for the evolution of the proviral locus since germ line integration. [Reviewing Editor : Dr. Martin Kreitman]     

Novel Denisovan and Neanderthal Retroviruses

Following the recent availability of high-coverage genomes for Denisovan and Neanderthal hominids, we conducted a screen for endogenized retroviruses, identifying six novel, previously unreported HERV-K(HML2) elements (HERV-K is human endogenous retrovirus K). These elements are absent from the human genome (hg38) and appear to be unique to archaic hominids. These findings provide further evidence supporting the recent activity of the HERV-K(HML2) group, which has been implicated in human disease. They will also provide insights into the evolution of archaic hominids.     

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.