Acquisition and Exaptation of Endogenous Retroviruses in Mammalian Placenta.

Endogenous retroviruses (ERVs) are retrovirus-like sequences that were previously integrated into the host genome. Although most ERVs are inactivated by mutations, deletions, or epigenetic regulation, some remain transcriptionally active and impact host physiology. Several ERV-encoded proteins, such as Syncytins and Suppressyn, contribute to placenta acquisition, a crucial adaptation in mammals that protects the fetus from external threats and other risks while enabling the maternal supply of oxygen, nutrients, and antibodies. In primates, Syncytin-1 and Syncytin-2 facilitate cell-cell fusion for placental formation. Suppressyn is the first ERV-derived protein that inhibits cell fusion by binding to ASCT2, the receptor for Syncytin-1. Furthermore, Syncytin-2 likely inserted into the genome of the common ancestor of Anthropoidea, whereas Syncytin-1 and Suppressyn likely inserted into the ancestor of catarrhines; however, they were inactivated in some lineages, suggesting that multiple exaptation events had occurred. This review discusses the role of ERV-encoded proteins, particularly Syncytins and Suppressyn, in placental development and function, focusing on the integration of ERVs into the host genome and their contribution to the genetic mechanisms underlying placentogenesis. This review provides valuable insights into the molecular and genetic aspects of placentation, potentially shedding light on broader evolutionary and physiological processes in mammals.

Establishment of CRFK cells for vaccine production by inactivating endogenous retrovirus with TALEN technology.

Endogenous retroviruses (ERVs) are retroviral sequences present in the host genomes. Although most ERVs are inactivated, some are produced as replication-competent viruses from host cells. We previously reported that several live-attenuated vaccines for companion animals prepared using the Crandell-Rees feline kidney (CRFK) cell line were contaminated with a replication-competent feline ERV termed RD-114 virus. We also found that the infectious RD-114 virus can be generated by recombination between multiple RD-114 virus-related proviruses (RDRSs) in CRFK cells. In this study, we knocked out RDRS env genes using the genome-editing tool TAL Effector Nuclease (TALEN) to reduce the risk of contamination by infectious ERVs in vaccine products. As a result, we succeeded in establishing RDRS knockout CRFK cells (RDKO_CRFK cells) that do not produce infectious RD-114 virus. The growth kinetics of feline herpesvirus type 1, calicivirus, and panleukopenia virus in RDKO_CRFK cells differed from those in parental cells, but all of them showed high titers exceeding 107 TCID50/mL. Infectious RD-114 virus was undetectable in the viral stocks propagated in RDKO_CRFK cells. This study suggested that RDRS env gene-knockout CRFK cells will be useful as a cell line for the manufacture of live-attenuated vaccines or biological substances with no risk of contamination with infectious ERV.

Characterization of DNA methylation and promoter activity of long terminal repeat elements of feline endogenous retrovirus RDRS C2a.

Endogenous retroviruses (ERVs) are genomic elements derived from retroviral infections in ancestral germ lines. Most ERVs are inactivated by genetic or epigenetic mechanisms, such as DNA methylation. RD-114-virus-related sequence (RDRS) C2a is a feline endogenous retrovirus present in all domestic cats; however, its expression and function are not clearly known. DNA methylation at CpG dinucleotides is a hallmark of silenced ERVs. This study aimed to investigate whether long terminal repeats (LTRs) of RDRS C2a function as a gene regulatory region. The DNA methylation status of RDRS C2a was examined by bisulfite sequencing, and CpG sites in 5' LTR of RDRS C2a were found hypomethylated, whereas those in 3' LTR were hypermethylated in feline cells. Several transcription factor-binding sites were identified in LTRs of RDRS C2a. Luciferase assay suggested that 5' LTR of RDRS C2a exhibited strong transcriptional activity, which was suppressed by in vitro DNA methylation. The study indicates that 5' LTR of RDRS C2a possibly functions as a promoter for itself or neighboring genes.

RD-114 virus story: from RNA rumor virus to a useful viral tool for elucidating the world cats' journey.

RD-114 virus is a feline endogenous retrovirus (ERV) isolated from human rhabdomyosarcoma in 1971 and classified as endogenous gammaretrovirus in domestic cats (Felis catus). Based on the previous reports in 70's, it has been considered that a horizontal, infectious event occurred to transfer the virus from ancient baboon species to ancient cat species, whereupon it became endogenous in the cat species about several million years ago in Mediterranean Basin. Although it has been believed that all domestic cats harbor infectious RD-114 provirus in their genome, we revealed that cats do not have infectious RD-114 viral loci, but infectious RD-114 virus is resurrected by recombination between uninfectious RD-114 virus-related ERVs [here we designated them as RD-114-related sequences (RDRSs)]. Further, we also revealed the RDRSs which would potentially be resurrected as RD-114 virus (here we refer to them as ''new'' RDRSs) had entered the genome of the domestic cat after domestication of the cat around 10 thousand years ago. The fractions and positions of RDRSs in the cat genome differed in Western and Eastern cat populations and cat breeds. Our study revealed that RDRS would be a useful tool for elucidating the world travel routes of domestic cats after domestication.

Susceptibility of domestic animals to a pseudotype virus bearing RD-114 virus envelope protein.

Retroviral vectors are used for gene transduction into cells and have been applied to gene therapy. Retroviral vectors using envelope protein (Env) of RD-114 virus, a feline endogenous retrovirus, have been used for gene transduction. In this study, we investigated the susceptibility to RD-114 Env-pseudotyped virus in twelve domestic animals including cattle, sheep, horse, pig, dog, cat, ferret, mink, rabbit, rat, mouse, and quail. Comparison of nucleotide sequences of ASCT2 (SLC1A5), a receptor of RD-114 virus, in 10 mammalian and 2 avian species revealed that insertion and deletion events at the region C of ASCT2 where RD-114 viral Env interacts occurred independently in the mouse and rat lineage and in the chicken and quail lineage. By the pseudotype virus infection assay, we found that RD-114 Env-pseudotyped virus could efficiently infect all cell lines except those from mouse and rat. Furthermore, we confirmed that bovine ASCT2 (bASCT2) functions as a receptor for RD-114 virus infection. We also investigated bASCT2 mRNA expression in cattle tissues and found that it is expressed in various tissues including lung, spleen and kidney. These results indicate that retrovirus vectors with RD-114 virus Env can be used for gene therapy in large domestic animals in addition to companion animals such as cat and dog.

Multiple invasions of an infectious retrovirus in cat genomes.

Endogenous retroviruses (ERVs) are remnants of ancient retroviral infections of host germ-line cells. While most ERVs are defective, some are active and express viral proteins. The RD-114 virus is a replication-competent feline ERV, and several feline cell lines produce infectious RD-114 viral particles. All domestic cats are considered to have an ERV locus encoding a replication-competent RD-114 virus in their genomes; however, the locus has not been identified. In this study, we investigated RD-114 virus-related proviral loci in genomes of domestic cats, and found that none were capable of producing infectious viruses. We also found that all domestic cats have an RD-114 virus-related sequence on chromosome C2, termed RDRS C2a, but populations of the other RDRSs are different depending on the regions where cats live or breed. Our results indicate that RDRS C2a, the oldest RD-114-related provirus, entered the host genome before an ancestor of domestic cats started diverging and the other new RDRSs might have integrated into migrating cats in Europe. We also show that infectious RD-114 virus can be resurrected by the recombination between two non-infectious RDRSs. From these data, we conclude that cats do not harbor infectious RD-114 viral loci in their genomes and RD-114-related viruses invaded cat genomes multiple times.

Heterogeneity of koala retrovirus isolates.

Koala retrovirus (KoRV) is a gammaretrovirus which may induce immune suppression, leukemia and lymphoma in koalas. Currently three KoRV subgroups (A, B, and J) have been reported. Our phylogenetic analysis suggests that KoRV-B and KoRV-J should be classified as the same subgroup. In long terminal repeat (LTR), a KoRV-B isolate has four 17 bp tandem repeats named direct repeat (DR)-1, while a KoRV-J isolate (strain OJ-4) has three 37 bp tandem repeats named DR-2. We also found that the promoter activity of the KoRV-J strain OJ-4 is stronger than that of original KoRV-A, suggesting that KoRV-J may replicate more efficiently than KoRV-A.

Contamination of live attenuated vaccines with an infectious feline endogenous retrovirus (RD-114 virus).

Retroviruses are classified as exogenous and endogenous retroviruses according to the mode of transmission. Endogenous retroviruses (ERVs) are retroviruses which have been integrated into germ-line cells and inherited from parents to offspring. Most ERVs are inactivated by deletions and mutations; however, certain ERVs maintain their infectivity and infect the same host and new hosts as exogenous retroviruses. All domestic cats have infectious ERVs, termed RD-114 virus. Several canine and feline attenuated vaccines are manufactured using RD-114 virus-producing cell lines such as Crandell-Rees feline kidney cells; therefore, it is possible that infectious RD-114 virus contaminates live attenuated vaccines. Recently, Japanese and UK research groups found that several feline and canine vaccines were indeed contaminated with infectious RD-114 virus. This was the first incidence of contamination of 'infectious' ERVs in live attenuated vaccines. RD-114 virus replicates efficiently in canine cell lines and primary cells. Therefore, it is possible that RD-114 virus infects dogs following inoculation with contaminated vaccines and induces proliferative diseases and immune suppression, if it adapts to grow efficiently in dogs. In this review, we summarize the incidence of contamination of RD-114 virus in live attenuated vaccines and potential risks of infection with RD-114 virus in dogs.

Identification of a novel subgroup of Koala retrovirus from Koalas in Japanese zoos.

We identified a new subgroup of koala retrovirus (KoRV), named KoRV-J, which utilizes thiamine transport protein 1 as a receptor instead of the Pit-1 receptor used by KoRV (KoRV-A). By subgroup-specific PCR, KoRV-J and KoRV-A were detected in 67.5 and 100% of koalas originating from koalas from northern Australia, respectively. Altogether, our results indicate that the invasion of the koala population by KoRV-J may have occurred more recently than invasion by KoRV-A.

Identification of cellular factors required for the budding of koala retrovirus.

Koala retrovirus (KoRV) is a unique gammaretrovirus that is currently endogenizing into its host and considered to be associated with leukemia, lymphoma and immunosuppression in koalas (Phascolactos cinereus). In this study, it was demonstrated that WWP2 or WWP2-like E3 ubiquitin ligases possessing the WW domain closely related to WWP2 and Vps4A/B are involved in KoRV budding. These data suggest that KoRV Gag recruits the cellular endosomal sorting complex required for transport machinery through interaction of the PPPY L-domain with the WW domain(s) of WWP2 and that progeny virions are released from cells by utilizing the multivesicular body sorting pathway.

Characterization of feline ASCT1 and ASCT2 as RD-114 virus receptor.

RD-114 virus is a replication-competent feline endogenous retrovirus (ERV). RD-114 virus had been thought to be xenotropic; however, recent findings indicate that RD-114 virus is polytropic and can infect and grow efficiently in feline cells. Receptor(s) for RD-114 virus has not been identified and characterized in cats. In this study, we confirmed that two feline sodium-dependent neutral amino acid transporters (ASCTs), fASCT1 and fASCT2, function as RD-114 virus receptors. By chimeric analyses of feline and murine ASCTs, we revealed that extracellular loop 2 of both fASCT1 and fASCT2 determines the susceptibility to RD-114 virus. Further, we revealed ubiquitous expression of these genes, consistent with the general metabolic role of the ASCT molecules. Our study indicates that RD-114 virus may reinfect tissues and cells in cats, once the virus is activated. Implications of the involvement of RD-114 virus in feline oncogenesis are also discussed.

Binding of transcription factor activating protein 2 γ on the 5'-proximal promoter region of human porcine endogenous retrovirus subgroup A receptor 2/GPR172B.

BACKGROUND: Xenotransplantation is one of the solutions for the shortage of organ donors, and pigs have been considered to be the most suitable animal donors. Specific pathogen-free pigs are utilized in the xenotransplantation; however, pigs have infectious gammaretroviruses, named porcine endogenous retroviruses (PERVs) in their genome. Of them, PERV-A and PERV-B can infect human cells in vitro and potentially induce diseases like other gammaretroviruses. The human cellular receptors for PERV-A were identified and named human PERV-A receptor (HuPAR)-1 and HuPAR-2 (also called as GPR172A and GPR172B, respectively). We have recently reported that HuPAR-2 expression was regulated by epigenetic modification and preferentially expressed in placenta. However, the detailed mechanisms of HuPAR-2 expression have not been fully characterized. In this study, we analyzed molecular mechanisms associated with HuPAR-2 transcription through the identification of transcription factors that bind to the promoter region of HuPAR-2. METHODS: In situ hybridization was performed to identify the cells expressing HuPAR-2 in placental tissues. Transcriptional activities were measured by dual-luciferase reporter assay using serial deletion mutants of HuPAR-2 5'-flanking region. To identify the transcription factors bound to the promoter region, in silico analysis, electrophoresis mobility shift assay, and chromatin immunoprecipitation assay were conducted. The effect of the transcription factor transcription factor activator protein (TFAP)-2γ on the promoter activities was investigated by overexpression of the factor. RESULTS: We identified that HuPAR-2 was specifically expressed in villous trophoblast cells. We also identified that a region spanning from -126 to -32 had proximal promoter activities and TFAP-2γ bound to a region spanning from -58 to -35 in vitro and in vivo. The overexpression of TFAP-2γ also augmented the proximal promoter activity. CONCLUSION: We demonstrated that TFAP-2γ is one of the transcription factors involved in the HuPAR-2 expression in human villous trophoblast cells. By studying transcriptional factors involved in the expression of HuPAR-2, we may find a clue to control the potential risks caused by PERV-A infection in xenotransplantation.

Sequence comparison of three infectious molecular clones of RD-114 virus.

RD-114 virus is a replication-competent feline endogenous retrovirus. RD-114 virus contaminates several feline and canine live attenuated vaccines and the issue of contamination of RD-114 virus in vaccines should be solved. To date, three infectious molecular clones (pSc3c, pCRT1, and pRD-UCL) have been reported. In this study, we sequenced the entire nucleotide sequence of pRD-UCL and compared the nucleotide sequences of the three infectious molecular clones. As a result, these three infectious clones were nearly identical with each other in gag-pol and env coding regions. These data support the notion that the active locus of infectious RD-114 virus is single in the feline genome. The length of long terminal repeat (LTR) of pCRT1 was 47 bp shorter than those of pSc3c and pRD-UCL. The 47-bp sequence named direct repeat A (DR-A) was duplicated in the U3 region in pSc3c and pRD-UCL. Although several potential enhancer binding sites are present in the DR-A, there was no significant difference in promoter activities between the LTRs of pRD-UCL and pCRT1 in two human cell lines. We also analyzed the splicing pattern of the RD-114 virus by reverse transcription-polymerase chain reaction and confirmed that RD-114 virus is a simple retrovirus. The data presented here will provide basic information about RD-114 virus to solve the contamination issue in live attenuated vaccines.

Identification and characterization of feline UBE1L gene.

Interferon-stimulated gene 15 (ISG15) is one of the type I interferon-inducible proteins. Addition of ISG15 known as ISGylation is an ubiquitin-like posttranslational modification. Coexpression of ISG15 and ubiquitin-activating enzyme E1-like protein (UBE1L) is required to induce ISGylation. Previously, we identified feline ISG15 gene and found that the capsid protein of feline immunodeficiency virus was ISGylated in vitro by treatment with feline interferon-ω. In this study, we cloned feline UBE1L (FeUBE1L) gene to further study the mechanism of the antiviral activities induced by ISGylation. Sequencing analysis revealed that active sites of FeUBE1L were highly conserved. These data suggest that FeUBE1L has an enzymatic activity. Further, expression of FeUBE1L was induced in feline cell lines by treatment with feline interferon-ω and ovine interferon-τ.