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Endogenous retrovirus

March 13, 2024

"HERV" redirects here. For other uses, see Herv (disambiguation).

Endogenous retroviruses (ERVs) are endogenous viral elements in the genome that closely resemble and can be derived from retroviruses. They are abundant in the genomes of jawed vertebrates, and they comprise up to 5–8% of the human genome (lower estimates of ~1%).[1][2]

Dendrogram of various classes of endogenous retroviruses

ERVs are a vertically inherited proviral sequence and a subclass of a type of gene called a transposon, which can normally be packaged and moved within the genome to serve a vital role in gene expression and in regulation.[3][4] ERVs however lack most transposon functions, are typically not infectious and are often defective genomic remnants of the retroviral replication cycle.[5][6] They are distinguished as germline provirus retroelements due to their integration and reverse-transcription into the nuclear genome of the host cell.

Researchers have suggested that retroviruses evolved from a type of transposon called a retrotransposon, a Class I element;[7] these genes can mutate and instead of moving to another location in the genome they can become exogenous or pathogenic. This means that not all ERVs may have originated as an insertion by a retrovirus but that some may have been the source for the genetic information in the retroviruses they resemble.[8] When integration of viral DNA occurs in the germ-line, it can give rise to an ERV, which can later become fixed in the gene pool of the host population.[1][9]

Formation edit

The replication cycle of a retrovirus entails the insertion ("integration") of a DNA copy of the viral genome into the nuclear genome of the host cell. Most retroviruses infect somatic cells, but occasional infection of germline cells (cells that produce eggs and sperm) can also occur. Rarely, retroviral integration may occur in a germline cell that goes on to develop into a viable organism. This organism will carry the inserted retroviral genome as an integral part of its own genome—an "endogenous" retrovirus (ERV) that may be inherited by its offspring as a novel allele. Many ERVs have persisted in the genome of their hosts for millions of years. However, most of these have acquired inactivating mutations during host DNA replication and are no longer capable of producing the virus. ERVs can also be partially excised from the genome by a process known as recombinational deletion, in which recombination between the identical sequences that flank newly integrated retroviruses results in deletion of the internal, protein-coding regions of the viral genome.

The general retrovirus genome consists of three genes vital for the invasion, replication, escape, and spreading of its viral genome. These three genes are gag (encodes for structural proteins for the viral core), pol (encodes for reverse transcriptase, integrase, and protease), and env (encodes for coat proteins for the virus's exterior). These viral proteins are encoded as polyproteins. In order to carry out their life cycle, the retrovirus relies heavily on the host cell's machinery. Protease degrades peptide bonds of the viral polyproteins, making the separate proteins functional. Reverse transcriptase functions to synthesize viral DNA from the viral RNA in the host cell's cytoplasm before it enters the nucleus. Integrase guides the integration of viral DNA into the host genome.[9][10]

Over time, the genome of ERVs not only acquire point mutations, but also shuffle and recombine with other ERVs.[11] ERVs with a decayed sequence for the env become more likely to propagate.[12]

Role in genomic evolution edit

 
Diagram displaying the integration of viral DNA into a host genome

Endogenous retroviruses can play an active role in shaping genomes. Most studies in this area have focused on the genomes of humans and higher primates, but other vertebrates, such as mice and sheep, have also been studied in depth.[13][14][15][16] The long terminal repeat (LTR) sequences that flank ERV genomes frequently act as alternate promoters and enhancers, often contributing to the transcriptome by producing tissue-specific variants. In addition, the retroviral proteins themselves have been co-opted to serve novel host functions, particularly in reproduction and development. Recombination between homologous retroviral sequences has also contributed to gene shuffling and the generation of genetic variation. Furthermore, in the instance of potentially antagonistic effects of retroviral sequences, repressor genes have co-evolved to combat them.

About 90% of endogenous retroviruses are solo LTRs, lacking all open reading frames (ORFs). Solo LTRs and LTRs associated with complete retroviral sequences have been shown to act as transcriptional elements on host genes. Their range of action is mainly by insertion into the 5' UTRs of protein coding genes; however, they have been known to act upon genes up to 70–100 kb away.[13][17][18][19] The majority of these elements are inserted in the sense direction to their corresponding genes, but there has been evidence[20] of LTRs acting in the antisense direction and as a bidirectional promoter for neighboring genes.[21][22] In a few cases, the LTR functions as the major promoter for the gene.

For example, in humans AMY1C has a complete ERV sequence in its promoter region; the associated LTR confers salivary specific expression of the digestive enzyme amylase.[23] Also, the primary promoter for bile acid-CoA:amino acid N-acyltransferase (BAAT), which codes for an enzyme that is integral in bile metabolism, is of LTR origin.[18][24]

The insertion of a solo ERV-9 LTR may have produced a functional open reading frame, causing the rebirth of the human immunity related GTPase gene (IRGM).[25] ERV insertions have also been shown to generate alternative splice sites either by direct integration into the gene, as with the human leptin hormone receptor, or driven by the expression of an upstream LTR, as with the phospholipase A-2 like protein.[26]

Most of the time, however, the LTR functions as one of many alternate promoters, often conferring tissue-specific expression related to reproduction and development. In fact, 64% of known LTR-promoted transcription variants are expressed in reproductive tissues.[27] For example, the gene CYP19 codes for aromatase P450, an important enzyme for estrogen synthesis, that is normally expressed in the brain and reproductive organs of most mammals.[18] However, in primates, an LTR-promoted transcriptional variant confers expression to the placenta and is responsible for controlling estrogen levels during pregnancy.[18] Furthermore, the neuronal apoptosis inhibitory protein (NAIP), normally widespread, has an LTR of the HERV-P family acting as a promoter that confers expression to the testis and prostate.[28] Other proteins, such as nitric oxide synthase 3 (NOS3), interleukin-2 receptor B (IL2RB), and another mediator of estrogen synthesis, HSD17B1, are also alternatively regulated by LTRs that confer placental expression, but their specific functions are not yet known.[24][29] The high degree of reproductive expression is thought to be an after effect of the method by which they were endogenized; however, this also may be due to a lack of DNA methylation in germ-line tissues.[24]

The best-characterized instance of placental protein expression comes not from an alternatively promoted host gene but from a complete co-option of a retroviral protein. Retroviral fusogenic env proteins, which play a role in the entry of the virion into the host cell, have had an important impact on the development of the mammalian placenta. In mammals, intact env proteins called syncytins are responsible for the formation and function of syncytiotrophoblasts.[15] These multinucleated cells are mainly responsible for maintaining nutrient exchange and separating the fetus from the mother's immune system.[15] It has been suggested that the selection and fixation of these proteins for this function have played a critical role in the evolution of viviparity.[30]

In addition, the insertion of ERVs and their respective LTRs have the potential to induce chromosomal rearrangement due to recombination between viral sequences at inter-chromosomal loci. These rearrangements have been shown to induce gene duplications and deletions that largely contribute to genome plasticity and dramatically change the dynamic of gene function.[31] Furthermore, retroelements in general are largely prevalent in rapidly evolving, mammal-specific gene families whose function is largely related to the response to stress and external stimuli.[18] In particular, both human class I and class II MHC genes have a high density of HERV elements as compared to other multi-locus-gene families.[26] It has been shown that HERVs have contributed to the formation of extensively duplicated duplicon blocks that make up the HLA class 1 family of genes.[32] More specifically, HERVs primarily occupy regions within and between the break points between these blocks, suggesting that considerable duplication and deletions events, typically associated with unequal crossover, facilitated their formation.[33] The generation of these blocks, inherited as immunohaplotypes, act as a protective polymorphism against a wide range of antigens that may have imbued humans with an advantage over other primates.[32]

The characteristic of placentas being very evolutionary distinct organs between different species has been suggested to result from the co-option of ERV enhancers. Regulatory mutations, instead of mutations in genes that encode for hormones and growth factors, support the known evolution of placental morphology, especially since the majority of hormone and growth factor genes are expressed in response to pregnancy, not during placental development. Researchers studied the regulatory landscape of placental development between the rat and mouse, two closely related species. This was done by mapping all regulatory elements of the rat trophoblast stem cells (TSCs) and comparing them to their orthologs in mouse TSCs. TSCs were observed because they reflect the initial cells that develop in the fetal placenta. Regardless of their tangible similarities, enhancer and repressed regions were mostly species-specific. However, most promoter sequences were conserved between mouse and rat. In conclusion to their study, researchers proposed that ERVs influenced species-specific placental evolution through mediation of placental growth, immunosuppression, and cell fusion.[34]

Another example of ERV exploiting cellular mechanisms is p53, a tumor suppressor gene (TSG). DNA damage and cellular stress induces the p53 pathway, which results in cell apoptosis. Using chromatin immunoprecipitation with sequencing, thirty-percent of all p53-binding sites were located within copies of a few primate-specific ERV families. A study suggested that this benefits retroviruses because p53's mechanism provides a rapid induction of transcription, which leads to the exit of viral RNA from the host cell.[7]

Finally, the insertion of ERVs or ERV elements into genic regions of host DNA, or overexpression of their transcriptional variants, has a much higher potential to produce deleterious effects than positive ones. Their appearance into the genome has created a coevolutionary dynamic that proliferated the duplication and expansion of repressor genes. The most clear-cut example of this involves the rapid duplication and proliferation of tandem zinc-finger genes in mammal genomes. Zinc-finger genes, particularly those that include a KRAB domain, exist in high copy number in vertebrate genomes, and their range of functions are limited to transcriptional roles.[35] It has been shown in mammals, however, that the diversification of these genes was due to multiple duplication and fixation events in response to new retroviral sequences or their endogenous copies to repress their transcription.[19]

Role in disease edit

The majority of ERVs that occur in vertebrate genomes are ancient, inactivated by mutation, and have reached genetic fixation in their host species. For these reasons, they are extremely unlikely to have negative effects on their hosts except under unusual circumstances. Nevertheless, it is clear from studies in birds and non-human mammal species including mice, cats and koalas, that younger (i.e., more recently integrated) ERVs can be associated with disease.[36] The number of active ERVs in the genome of mammals is negatively related to their body size, suggesting a contribution to Peto's paradox through cancer pathogenesis.[37] This has led researchers to propose a role for ERVs in several forms of human cancer and autoimmune disease, although conclusive evidence is lacking.[38][39][40][41]

Neurological disorders edit

In humans, ERVs have been proposed to be involved in multiple sclerosis (MS). A specific association between MS and the ERVWE1, or "syncytin", gene, which is derived from an ERV insertion, has been reported, along with the presence of an "MS-associated retrovirus" (MSRV), in patients with the disease.[42][43] Human ERVs (HERVs) have also been implicated in ALS[44] and addiction.[45][46][47]

In 2004 it was reported that antibodies to HERVs were found in greater frequency in the sera of people with schizophrenia. Additionally, the cerebrospinal fluid of people with recent onset schizophrenia contained levels of a retroviral marker, reverse transcriptase, four times higher than control subjects.[48] Researchers continue to look at a possible link between HERVs and schizophrenia, with the additional possibility of a triggering infection inducing schizophrenia.[49]

Immunity edit

ERVs have been found to be associated to disease not only through disease-causing relations, but also through immunity. The frequency of ERVs in long terminal repeats (LTRs) likely correlates to viral adaptations to take advantage of immunity signaling pathways that promote viral transcription and replication. A study done in 2016 investigated the benefit of ancient viral DNA integrated into a host through gene regulation networks induced by interferons, a branch of innate immunity.[50] These cytokines are first to respond to viral infection and are also important in immunosurveillance for malignant cells.[51] ERVs are predicted to act as cis-regulatory elements, but much of the adaptive consequences of this for certain physiological functions is still unknown. There is data that supports the general role of ERVs in the regulation of human interferon response, specifically to interferon-gamma (IFNG). For example, interferon-stimulated genes were found to be greatly enriched with ERVs bound by signal transducer and activator of transcription 1 (STAT1) and/or Interferon regulatory factor (IRF1) in CD14+ macrophages.[1]

HERVs also play various roles shaping the human innate immunity response, with some sequences activating the system and others suppressing it. They may also protect from exogenous retroviral infections: the virus-like transcripts can activate pattern recognition receptors, and the proteins can interfere with active retroviruses. A gag protein from HERV-K(HML2) is shown to mix with HIV Gag, impairing HIV capsid formation as a result.[52]

Gene regulation edit

Another idea proposed was that ERVs from the same family played a role in recruiting multiple genes into the same network of regulation. It was found that MER41 elements provided addition redundant regulatory enhancement to the genes located near STAT1 binding sites.[1]

Role in medicine edit

Porcine endogenous retrovirus edit

See also: Xenotransplantation § Porcine endogenous retroviruses

For humans, porcine endogenous retroviruses (PERVs) pose a concern when using porcine tissues and organs in xenotransplantion, the transplanting of living cells, tissues, and organs from an organism of one species to an organism of different species. Although pigs are generally the most suitable donors to treat human organ diseases due to practical, financial, safety, and ethical reasons,[50] PERVs previously could not be removed from pigs, due to their viral ability to integrate into the host genome and to be passed into offspring, until the year 2017, when one lab, using CRISPR-Cas9, removed all 62 retroviruses from the pig genome.[53] The consequences of cross-species transmission remain unexplored and have dangerous potential.[54]

Researchers have indicated that infection of human tissues by PERVs is very possible, especially in immunosuppressed individuals. An immunosuppressed condition could potentially permit a more rapid and tenacious replication of viral DNA, and would later have less difficulty adapting to human-to-human transmission. Although known infectious pathogens present in the donor organ/tissue can be eliminated by breeding pathogen-free herds, unknown retroviruses can be present in the donor. These retroviruses are often latent and asymptomatic in the donor, but can become active in the recipient. Some examples of endogenous viruses that can infect and multiply in human cells are from baboons (BaEV), cats (RD114), and mice.[50]

There are three different classes of PERVs, PERV-A, PERV-B, and PERV-C. PERV-A and PERV-B are polytropic and can infect human cells in vitro, while PERV-C is ecotropic and does not replicate on human cells. The major differences between the classes is in the receptor binding domain of the env protein and the long terminal repeats (LTRs) that influence the replication of each class. PERV-A and PERV-B display LTRs that have repeats in the U3 region. However, PERV-A and PERV-C show repeatless LTRs. Researchers found that PERVs in culture actively adapted to the repeat structure of their LTR in order to match the best replication performance a host cell could perform. At the end of their study, researchers concluded that repeatless PERV LTR evolved from the repeat-harboring LTR. This was likely to have occurred from insertional mutation and was proven through use of data on LTR and env/Env. It is thought that the generation of repeatless LTRs could be reflective of an adaptation process of the virus, changing from an exogenous to an endogenous lifestyle.[55]

A clinical trial study performed in 1999 sampled 160 patients who were treated with different living pig tissues and observed no evidence of a persistent PERV infection in 97% of the patients for whom a sufficient amount of DNA was available to PCR for amplification of PERV sequences. This study stated that retrospective studies are limited to find the true incidence of infection or associated clinical symptoms, however. It suggested using closely monitored prospective trials, which would provide a more complete and detailed evaluation of the possible cross-species PERV transmission and a comparison of the PERV.[56]

Human endogenous retroviruses edit

"HERV" redirects here. For other uses, see Herv (disambiguation).

Human endogenous retroviruses (HERV) comprise a significant part of the human genome, with approximately 98,000 ERV elements and fragments making up 5–8%.[1] According to a study published in 2005, no HERVs capable of replication had been identified; all appeared to be defective, containing major deletions or nonsense mutations (not true for HERV-K). This is because most HERVs are merely traces of original viruses, having first integrated millions of years ago. An analysis of HERV integrations is ongoing as part of the 100,000 Genomes Project.[57]

A 2023 study found HERV can become awakened from dormant states and contribute to aging which could be blocked by neutralizing antibodies.[58][59]

Human endogenous retroviruses were originally discovered when human genomic libraries were screened under low-stringency conditions using either probes from animal retroviruses or by using oligonucleotides with similarity to virus sequences.[1]

Classification edit

HERVs are classified based on their homologies to animal retroviruses. Families belonging to Class I are similar in sequence to mammalian Gammaretroviruses (type C) and Epsilonretroviruses (Type E). Families belonging to Class II show homology to mammalian Betaretroviruses (Type B) and Deltaretroviruses (Type D). Families belonging to Class III are similar to foamy viruses. For all classes, if homologies appear well conserved in the gag, pol, and env gene, they are grouped into a superfamily. There are more Class I families known to exist.[1][11] The families themselves are named in a less uniform manner, with a mixture of naming based on an exogenous retrovirus, the priming tRNA (HERV-W, HERV-K), or some neighboring gene (HERV-ADP), clone number (HERV-S71), or some amino acid motif (HERV-FRD). A proposed nomenclature aims to clean up the sometimes paraphyletic standards.[6]

Origin edit

Sometime during human evolution, exogenous progenitors of HERV inserted themselves into germ line cells and then replicated along with the host's genes using and exploiting the host's cellular mechanisms. Because of their distinct genomic structure, HERVs were subjected to many rounds of amplification and transposition, which lead to a more widespread distribution of retroviral DNA.[1]

Nevertheless, one family of viruses has been active since the divergence of humans and chimpanzees. This family, termed HERV-K (HML2), makes up less than 1% of HERV elements but is one of the most studied. There are indications it has even been active in the past few hundred thousand years, e.g., some human individuals carry more copies of HML2 than others.[60] Traditionally, age estimates of HERVs are performed by comparing the 5' and 3' LTR of a HERV; however, this method is only relevant for full-length HERVs. A recent method, called cross-sectional dating,[61] uses variations within a single LTR to estimate the ages of HERV insertions. This method is more precise in estimating HERV ages and can be used for any HERV insertions. Cross-sectional dating has been used to suggest that two members of HERV-K (HML2), HERV-K106 and HERV-K116, were active in the last 800,000 years and that HERV-K106 may have infected modern humans 150,000 years ago.[62] However, the absence of known infectious members of the HERV-K (HML2) family, and the lack of elements with a full coding potential within the published human genome sequence, suggests to some that the family is less likely to be active at present. In 2006 and 2007, researchers working independently in France and the US recreated functional versions of HERV-K (HML2).[63][64]

Expression of HERV proteins edit

The expression of HERV-K, a biologically active family of HERV, produces proteins found in placenta. Furthermore, the expression of the envelope genes of HERV-W (ERVW-1 2013-09-19 at the Wayback Machine) and HERV-FRD (ERVFRD-1 2012-10-26 at the Wayback Machine) produces syncytins which are important for the generation of the syncytiotrophoblast cell layer during placentogenesis by inducing cell-cell fusion.[65] The HUGO Gene Nomenclature Committee (HGNC) approves gene symbols for transcribed human ERVs.[66]

Functional impact edit

MER41.AIM2 is an HERV that regulates the transcription of AIM2 (Absent in Melanoma 2) which encodes for a sensor of foreign cytosolic DNA. This acts as a binding site for AIM2, meaning that it is necessary for the transcription of AIM2. Researchers had shown this by deleting MER41.AIM2 in HeLa cells using CRISPR/Cas9, leading to an undetectable transcript level of AIM2 in modified HeLa cells. The control cells, which still contained the MER41.AIM2 ERV, were observed with normal amounts of AIM2 transcript. In terms of immunity, researchers concluded that MER41.AIM2 is necessary for an inflammatory response to infection.[67]

Activation by exogenous viruses edit

Considerable evidence indicate that HERVs can be reactivated by viral infections, such as:

1) retroviruses – human immunodeficiency virus type-1 (HIV-1), human T-lymphotropic virus 1 (HTLV-1);

2) RNA viruses – influenza A virus, hepatitis C virus (HCV), severe acute respiratory syndrome coronavirus-2 (SARSCoV-2);

3) DNA viruses – herpes simplex virus type-1 (HSV-1), Epstein-Barr virus (EBV), human cytomegalovirus (CMV), Kaposi’s sarcoma-associated herpesvirus (KSHV) [68]

Several studies have shown that EBV is able to transactivate the expression of the normally inactive HERV-K18 Env protein, e.g., interacting with resting B cells via CD21 receptor. Further studies revealed that the mechanism of transactivation depends on the expression of the major EBV late gene transactivator, EBNA-2. In-depth analysis completed the picture identifying the EBV latent membrane protein LMP-2A as a strong candidate for the HERV-K18 transactivation. HERV-K18 has also been reported to have superantigen activity (i.e. polyclonal T and B cell activation regardless of the specificity of their antigen receptor).[69]

It has also been shown that in vitro binding of the EBV gp350 protein caused activation of MSRVenv and syncytin-1 in B-cells, monocytes, macrophages and in astrocytes - cells that are involved in pathogenesis of multiple sclerosis.[70] Monocytes, especially after their differentiation into macrophages, appeared to be the most responsive to EBVgp350, expressing even higher levels of HERV-Wenv than B cells.This finding is concordant with another study, which demonstrated that during infectious mononucleosis EBV promoted the strongest activation of HERV-W/MSRV expression in monocytes compared to other blood cell types.[71]

Immune response to HERVs edit

Despite having been integrated into genomes of vertebrates for millions of years, ERVs represent an intermediate stage between exogenous viruses and the host genome; it is suggested that immunological tolerance to HERV-derived proteins and peptides is imperfect due to the epigenetic silencing of HERV in the thymus and bone marrow, which prevents deletion of all HERV-specific T and B cells.[72] As evidence of this, immunization of non-human primates with ERV-derived antigens mounted robust polyfunctional cytotoxic T cell response as well as high antibody titers. According to phylogenetic studies, among 30 HERV families existing in the human genome, HERV-K (HML-2) elements which integrated most recently are the most intact and biologically active forms.[69] HERV-K env and HERV-H env, considered to be a new class of tumor-associated antigens, have been found to promote strong cytotoxic T-cell responses in patients with various types of cancers.[72][73][74]

On a level of the innate immune sensing of nucleic acids, single-stranded RNA (ssRNA) and double-stranded RNA (dsRNA) derived from endogenous retroviruses are recognized by pattern recognition receptors (PRRs).

SsRNAs can be sensed by Toll-like receptors TLR-7 and TLR-8, resulting in secretion of IFN-α by stimulated dendritic cells (DCs) and macrophages, which was observed for ssRNAs derived from HIV-1.[75]

DsRNAs might be one of the most immunogenic nucleic acid pathogen-associated molecular patterns (PAMPs), since they are not found in cells in a normal state. HERV-derived dsRNA can be recognized by TLR-3, RIG-I and MDA5; RIG-I and MDA5 are known to induce a type I IFN response.[75][76]

When retrotranscribed into DNA, retroviruses can be sensed by cyclic GMP-AMP synthase-stimulator of interferon genes (cGAS-STING) pathway, leading to the activation of nuclear factor-kappa B (NF-kB) and IFN regulatory factor 3 (IRF3), which in turn trigger a type I IFN response. DsDNA could also be sensed by DNA-dependent activator of IFN-regulatory factors (DAI); DNA:RNA hybrids could be recognized by TLR-9[75]

The recognition of nucleic acids through PRRs provides a very efficient strategy to fight against viral infections, at the same time imposing the host to a risk due to the possibility of recognizing self-nucleic acids and promotion of autoimmunity.[75] Not surprisingly, HERVs have been found to be associated with different autoimmune and inflammatory diseases, such as multiple sclerosis, amyotrophic lateral sclerosis (ALS), systemic lupus erythematosus (SLE), rheumathoid arthritis (RA), Sjögren syndrome (SS).[69]

On a protein level, a direct interaction between TLRs and certain HERV proteins has been shown. For example, the surface unit of HERV-W Env (also known as Multiple sclerosis-associated retroviral element (MSRV) env) was found to bind to TLR4 and CD14, stimulating the production of pro-inflammatory cytokines including IL-1β, IL-6, and TNFα. HERV-W Env can trigger a maturation process in human dendritic cells, endowing them with the capacity to support a Th1-like type of Th cell differentiation.[77]

Immunological studies have shown some evidence for T cell immune responses against HERVs in HIV-infected individuals.[78] The hypothesis that HIV induces HERV expression in HIV-infected cells led to the proposal that a vaccine targeting HERV antigens could specifically eliminate HIV-infected cells. The potential advantage of this novel approach is that, by using HERV antigens as surrogate markers of HIV-infected cells, it could circumvent the difficulty inherent in directly targeting notoriously diverse and fast-mutating HIV antigens.[78]

Techniques for characterizing ERVs edit

Whole genome sequencing edit

Example: A porcine ERV (PERV) Chinese-born minipig isolate, PERV-A-BM, was sequenced completely and along with different breeds and cell lines in order to understand its genetic variation and evolution. The observed number of nucleotide substitutions and among the different genome sequences helped researchers determine an estimate age that PERV-A-BM was integrated into its host genome, which was found to be of an evolutionary age earlier than the European-born pigs isolates.[54]

Chromatin immunoprecipitation with sequencing (ChIP-seq) edit

This technique is used to find histone marks indicative of promoters and enhancers, which are binding sites for DNA proteins, and repressed regions and trimethylation.[34] DNA methylation has been shown to be vital to maintain silencing of ERVs in mouse somatic cells, while histone marks are vital for the same purpose in embryonic stem cells (ESCs) and early embryogenesis.[7]

Applications edit

Constructing phylogenies edit

Because most HERVs have no function, are selectively neutral, and are very abundant in primate genomes, they easily serve as phylogenetic markers for linkage analysis. They can be exploited by comparing the integration site polymorphisms or the evolving, proviral, nucleotide sequences of orthologs. To estimate when integration occurred, researchers used distances from each phylogenetic tree to find the rate of molecular evolution at each particular locus. It is also useful that ERVs are rich in many species genomes (i.e. plants, insects, mollusks, fish, rodents, domestic pets, and livestock) because its application can be used to answer a variety of phylogenetic questions.[9]

Designating the age of provirus and the time points of species separation events edit

This is accomplished by comparing the different HERV from different evolutionary periods. For example, this study was done for different hominoids, which ranged from humans to apes and to monkeys. This is difficult to do with PERV because of the large diversity present.[55]

Further research edit

Epigenetic variability edit

Researchers could analyze individual epigenomes and transcriptomes to study the reactivation of dormant transposable elements through epigenetic release and their potential associations with human disease and exploring the specifics of gene regulatory networks.[7]

Immunological problems of xenotransplantation edit

Little is known about an effective way to overcoming hyperacute rejection (HAR), which follows the activation of complement initiated by xenoreactive antibodies recognizing galactosyl-alpha1-3galatosyl (alpha-Gal) antigens on the donor epithelium.[50]

Risk factors of HERVs in gene therapy edit

Because retroviruses are able to recombine with each other and with other endogenous DNA sequences, it would be beneficial for gene therapy to explore the potential risks HERVs can cause, if any. Also, this ability of HERVs to recombine can be manipulated for site-directed integration by including HERV sequences in retroviral vectors.[1]

HERV gene expression edit

Researchers believe that RNA and proteins encoded for by HERV genes should continue to be explored for putative function in cell physiology and in pathological conditions. This would make sense to examine in order to more deeply define the biological significance of the proteins synthesized.[1]

See also edit

References edit

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Further reading edit

  • Löwer R, Löwer J, Kurth R (May 1996). "The viruses in all of us: characteristics and biological significance of human endogenous retrovirus sequences". Proceedings of the National Academy of Sciences of the United States of America. 93 (11): 5177–5184. Bibcode:1996PNAS...93.5177L. doi:10.1073/pnas.93.11.5177. PMC 39218. PMID 8643549.
  • Molès JP, Tesniere A, Guilhou JJ (July 2005). "A new endogenous retroviral sequence is expressed in skin of patients with psoriasis". The British Journal of Dermatology. 153 (1): 83–89. doi:10.1111/j.1365-2133.2005.06555.x. PMID 16029331. S2CID 6642536.
  • Seifarth W, Frank O, Zeilfelder U, Spiess B, Greenwood AD, Hehlmann R, Leib-Mösch C (January 2005). "Comprehensive analysis of human endogenous retrovirus transcriptional activity in human tissues with a retrovirus-specific microarray". Journal of Virology. 79 (1): 341–352. doi:10.1128/JVI.79.1.341-352.2005. PMC 538696. PMID 15596828.
  • Knerr I, Beinder E, Rascher W (February 2002). "Syncytin, a novel human endogenous retroviral gene in human placenta: evidence for its dysregulation in preeclampsia and HELLP syndrome". American Journal of Obstetrics and Gynecology. 186 (2): 210–213. doi:10.1067/mob.2002.119636. PMID 11854637.
  • Gifford R, Tristem M (May 2003). (PDF). Virus Genes. 26 (3): 291–315. doi:10.1023/A:1024455415443. PMID 12876457. S2CID 34639116. Archived from the original (PDF) on 2013-02-15. Retrieved 2008-01-16.

External links edit

  • Endogenous+Retroviruses at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
  • HERVd – human endogenous retrovirus database

March 13, 2024
endogenous, retrovirus, herv, redirects, here, other, uses, herv, disambiguation, this, article, require, cleanup, meet, wikipedia, quality, standards, specific, problem, some, links, missing, also, check, overlink, please, help, improve, this, article, februa. HERV redirects here For other uses see Herv disambiguation This article may require cleanup to meet Wikipedia s quality standards The specific problem is Some links missing also check for overlink Please help improve this article if you can February 2023 Learn how and when to remove this template message Endogenous retroviruses ERVs are endogenous viral elements in the genome that closely resemble and can be derived from retroviruses They are abundant in the genomes of jawed vertebrates and they comprise up to 5 8 of the human genome lower estimates of 1 1 2 Dendrogram of various classes of endogenous retrovirusesERVs are a vertically inherited proviral sequence and a subclass of a type of gene called a transposon which can normally be packaged and moved within the genome to serve a vital role in gene expression and in regulation 3 4 ERVs however lack most transposon functions are typically not infectious and are often defective genomic remnants of the retroviral replication cycle 5 6 They are distinguished as germline provirus retroelements due to their integration and reverse transcription into the nuclear genome of the host cell Researchers have suggested that retroviruses evolved from a type of transposon called a retrotransposon a Class I element 7 these genes can mutate and instead of moving to another location in the genome they can become exogenous or pathogenic This means that not all ERVs may have originated as an insertion by a retrovirus but that some may have been the source for the genetic information in the retroviruses they resemble 8 When integration of viral DNA occurs in the germ line it can give rise to an ERV which can later become fixed in the gene pool of the host population 1 9 Contents 1 Formation 2 Role in genomic evolution 3 Role in disease 3 1 Neurological disorders 3 2 Immunity 3 3 Gene regulation 4 Role in medicine 4 1 Porcine endogenous retrovirus 5 Human endogenous retroviruses 5 1 Classification 5 2 Origin 5 3 Expression of HERV proteins 5 4 Functional impact 5 5 Activation by exogenous viruses 5 6 Immune response to HERVs 6 Techniques for characterizing ERVs 6 1 Whole genome sequencing 6 2 Chromatin immunoprecipitation with sequencing ChIP seq 7 Applications 7 1 Constructing phylogenies 7 2 Designating the age of provirus and the time points of species separation events 8 Further research 8 1 Epigenetic variability 8 2 Immunological problems of xenotransplantation 8 3 Risk factors of HERVs in gene therapy 8 4 HERV gene expression 9 See also 10 References 11 Further reading 12 External linksFormation editThe replication cycle of a retrovirus entails the insertion integration of a DNA copy of the viral genome into the nuclear genome of the host cell Most retroviruses infect somatic cells but occasional infection of germline cells cells that produce eggs and sperm can also occur Rarely retroviral integration may occur in a germline cell that goes on to develop into a viable organism This organism will carry the inserted retroviral genome as an integral part of its own genome an endogenous retrovirus ERV that may be inherited by its offspring as a novel allele Many ERVs have persisted in the genome of their hosts for millions of years However most of these have acquired inactivating mutations during host DNA replication and are no longer capable of producing the virus ERVs can also be partially excised from the genome by a process known as recombinational deletion in which recombination between the identical sequences that flank newly integrated retroviruses results in deletion of the internal protein coding regions of the viral genome The general retrovirus genome consists of three genes vital for the invasion replication escape and spreading of its viral genome These three genes are gag encodes for structural proteins for the viral core pol encodes for reverse transcriptase integrase and protease and env encodes for coat proteins for the virus s exterior These viral proteins are encoded as polyproteins In order to carry out their life cycle the retrovirus relies heavily on the host cell s machinery Protease degrades peptide bonds of the viral polyproteins making the separate proteins functional Reverse transcriptase functions to synthesize viral DNA from the viral RNA in the host cell s cytoplasm before it enters the nucleus Integrase guides the integration of viral DNA into the host genome 9 10 Over time the genome of ERVs not only acquire point mutations but also shuffle and recombine with other ERVs 11 ERVs with a decayed sequence for the env become more likely to propagate 12 Role in genomic evolution edit nbsp Diagram displaying the integration of viral DNA into a host genomeEndogenous retroviruses can play an active role in shaping genomes Most studies in this area have focused on the genomes of humans and higher primates but other vertebrates such as mice and sheep have also been studied in depth 13 14 15 16 The long terminal repeat LTR sequences that flank ERV genomes frequently act as alternate promoters and enhancers often contributing to the transcriptome by producing tissue specific variants In addition the retroviral proteins themselves have been co opted to serve novel host functions particularly in reproduction and development Recombination between homologous retroviral sequences has also contributed to gene shuffling and the generation of genetic variation Furthermore in the instance of potentially antagonistic effects of retroviral sequences repressor genes have co evolved to combat them About 90 of endogenous retroviruses are solo LTRs lacking all open reading frames ORFs Solo LTRs and LTRs associated with complete retroviral sequences have been shown to act as transcriptional elements on host genes Their range of action is mainly by insertion into the 5 UTRs of protein coding genes however they have been known to act upon genes up to 70 100 kb away 13 17 18 19 The majority of these elements are inserted in the sense direction to their corresponding genes but there has been evidence 20 of LTRs acting in the antisense direction and as a bidirectional promoter for neighboring genes 21 22 In a few cases the LTR functions as the major promoter for the gene For example in humans AMY1C has a complete ERV sequence in its promoter region the associated LTR confers salivary specific expression of the digestive enzyme amylase 23 Also the primary promoter for bile acid CoA amino acid N acyltransferase BAAT which codes for an enzyme that is integral in bile metabolism is of LTR origin 18 24 The insertion of a solo ERV 9 LTR may have produced a functional open reading frame causing the rebirth of the human immunity related GTPase gene IRGM 25 ERV insertions have also been shown to generate alternative splice sites either by direct integration into the gene as with the human leptin hormone receptor or driven by the expression of an upstream LTR as with the phospholipase A 2 like protein 26 Most of the time however the LTR functions as one of many alternate promoters often conferring tissue specific expression related to reproduction and development In fact 64 of known LTR promoted transcription variants are expressed in reproductive tissues 27 For example the gene CYP19 codes for aromatase P450 an important enzyme for estrogen synthesis that is normally expressed in the brain and reproductive organs of most mammals 18 However in primates an LTR promoted transcriptional variant confers expression to the placenta and is responsible for controlling estrogen levels during pregnancy 18 Furthermore the neuronal apoptosis inhibitory protein NAIP normally widespread has an LTR of the HERV P family acting as a promoter that confers expression to the testis and prostate 28 Other proteins such as nitric oxide synthase 3 NOS3 interleukin 2 receptor B IL2RB and another mediator of estrogen synthesis HSD17B1 are also alternatively regulated by LTRs that confer placental expression but their specific functions are not yet known 24 29 The high degree of reproductive expression is thought to be an after effect of the method by which they were endogenized however this also may be due to a lack of DNA methylation in germ line tissues 24 The best characterized instance of placental protein expression comes not from an alternatively promoted host gene but from a complete co option of a retroviral protein Retroviral fusogenic env proteins which play a role in the entry of the virion into the host cell have had an important impact on the development of the mammalian placenta In mammals intact env proteins called syncytins are responsible for the formation and function of syncytiotrophoblasts 15 These multinucleated cells are mainly responsible for maintaining nutrient exchange and separating the fetus from the mother s immune system 15 It has been suggested that the selection and fixation of these proteins for this function have played a critical role in the evolution of viviparity 30 In addition the insertion of ERVs and their respective LTRs have the potential to induce chromosomal rearrangement due to recombination between viral sequences at inter chromosomal loci These rearrangements have been shown to induce gene duplications and deletions that largely contribute to genome plasticity and dramatically change the dynamic of gene function 31 Furthermore retroelements in general are largely prevalent in rapidly evolving mammal specific gene families whose function is largely related to the response to stress and external stimuli 18 In particular both human class I and class II MHC genes have a high density of HERV elements as compared to other multi locus gene families 26 It has been shown that HERVs have contributed to the formation of extensively duplicated duplicon blocks that make up the HLA class 1 family of genes 32 More specifically HERVs primarily occupy regions within and between the break points between these blocks suggesting that considerable duplication and deletions events typically associated with unequal crossover facilitated their formation 33 The generation of these blocks inherited as immunohaplotypes act as a protective polymorphism against a wide range of antigens that may have imbued humans with an advantage over other primates 32 The characteristic of placentas being very evolutionary distinct organs between different species has been suggested to result from the co option of ERV enhancers Regulatory mutations instead of mutations in genes that encode for hormones and growth factors support the known evolution of placental morphology especially since the majority of hormone and growth factor genes are expressed in response to pregnancy not during placental development Researchers studied the regulatory landscape of placental development between the rat and mouse two closely related species This was done by mapping all regulatory elements of the rat trophoblast stem cells TSCs and comparing them to their orthologs in mouse TSCs TSCs were observed because they reflect the initial cells that develop in the fetal placenta Regardless of their tangible similarities enhancer and repressed regions were mostly species specific However most promoter sequences were conserved between mouse and rat In conclusion to their study researchers proposed that ERVs influenced species specific placental evolution through mediation of placental growth immunosuppression and cell fusion 34 Another example of ERV exploiting cellular mechanisms is p53 a tumor suppressor gene TSG DNA damage and cellular stress induces the p53 pathway which results in cell apoptosis Using chromatin immunoprecipitation with sequencing thirty percent of all p53 binding sites were located within copies of a few primate specific ERV families A study suggested that this benefits retroviruses because p53 s mechanism provides a rapid induction of transcription which leads to the exit of viral RNA from the host cell 7 Finally the insertion of ERVs or ERV elements into genic regions of host DNA or overexpression of their transcriptional variants has a much higher potential to produce deleterious effects than positive ones Their appearance into the genome has created a coevolutionary dynamic that proliferated the duplication and expansion of repressor genes The most clear cut example of this involves the rapid duplication and proliferation of tandem zinc finger genes in mammal genomes Zinc finger genes particularly those that include a KRAB domain exist in high copy number in vertebrate genomes and their range of functions are limited to transcriptional roles 35 It has been shown in mammals however that the diversification of these genes was due to multiple duplication and fixation events in response to new retroviral sequences or their endogenous copies to repress their transcription 19 Role in disease editThe majority of ERVs that occur in vertebrate genomes are ancient inactivated by mutation and have reached genetic fixation in their host species For these reasons they are extremely unlikely to have negative effects on their hosts except under unusual circumstances Nevertheless it is clear from studies in birds and non human mammal species including mice cats and koalas that younger i e more recently integrated ERVs can be associated with disease 36 The number of active ERVs in the genome of mammals is negatively related to their body size suggesting a contribution to Peto s paradox through cancer pathogenesis 37 This has led researchers to propose a role for ERVs in several forms of human cancer and autoimmune disease although conclusive evidence is lacking 38 39 40 41 Neurological disorders edit In humans ERVs have been proposed to be involved in multiple sclerosis MS A specific association between MS and the ERVWE1 or syncytin gene which is derived from an ERV insertion has been reported along with the presence of an MS associated retrovirus MSRV in patients with the disease 42 43 Human ERVs HERVs have also been implicated in ALS 44 and addiction 45 46 47 In 2004 it was reported that antibodies to HERVs were found in greater frequency in the sera of people with schizophrenia Additionally the cerebrospinal fluid of people with recent onset schizophrenia contained levels of a retroviral marker reverse transcriptase four times higher than control subjects 48 Researchers continue to look at a possible link between HERVs and schizophrenia with the additional possibility of a triggering infection inducing schizophrenia 49 Immunity edit ERVs have been found to be associated to disease not only through disease causing relations but also through immunity The frequency of ERVs in long terminal repeats LTRs likely correlates to viral adaptations to take advantage of immunity signaling pathways that promote viral transcription and replication A study done in 2016 investigated the benefit of ancient viral DNA integrated into a host through gene regulation networks induced by interferons a branch of innate immunity 50 These cytokines are first to respond to viral infection and are also important in immunosurveillance for malignant cells 51 ERVs are predicted to act as cis regulatory elements but much of the adaptive consequences of this for certain physiological functions is still unknown There is data that supports the general role of ERVs in the regulation of human interferon response specifically to interferon gamma IFNG For example interferon stimulated genes were found to be greatly enriched with ERVs bound by signal transducer and activator of transcription 1 STAT1 and or Interferon regulatory factor IRF1 in CD14 macrophages 1 HERVs also play various roles shaping the human innate immunity response with some sequences activating the system and others suppressing it They may also protect from exogenous retroviral infections the virus like transcripts can activate pattern recognition receptors and the proteins can interfere with active retroviruses A gag protein from HERV K HML2 is shown to mix with HIV Gag impairing HIV capsid formation as a result 52 Gene regulation edit Another idea proposed was that ERVs from the same family played a role in recruiting multiple genes into the same network of regulation It was found that MER41 elements provided addition redundant regulatory enhancement to the genes located near STAT1 binding sites 1 Role in medicine editPorcine endogenous retrovirus edit See also Xenotransplantation Porcine endogenous retroviruses For humans porcine endogenous retroviruses PERVs pose a concern when using porcine tissues and organs in xenotransplantion the transplanting of living cells tissues and organs from an organism of one species to an organism of different species Although pigs are generally the most suitable donors to treat human organ diseases due to practical financial safety and ethical reasons 50 PERVs previously could not be removed from pigs due to their viral ability to integrate into the host genome and to be passed into offspring until the year 2017 when one lab using CRISPR Cas9 removed all 62 retroviruses from the pig genome 53 The consequences of cross species transmission remain unexplored and have dangerous potential 54 Researchers have indicated that infection of human tissues by PERVs is very possible especially in immunosuppressed individuals An immunosuppressed condition could potentially permit a more rapid and tenacious replication of viral DNA and would later have less difficulty adapting to human to human transmission Although known infectious pathogens present in the donor organ tissue can be eliminated by breeding pathogen free herds unknown retroviruses can be present in the donor These retroviruses are often latent and asymptomatic in the donor but can become active in the recipient Some examples of endogenous viruses that can infect and multiply in human cells are from baboons BaEV cats RD114 and mice 50 There are three different classes of PERVs PERV A PERV B and PERV C PERV A and PERV B are polytropic and can infect human cells in vitro while PERV C is ecotropic and does not replicate on human cells The major differences between the classes is in the receptor binding domain of the env protein and the long terminal repeats LTRs that influence the replication of each class PERV A and PERV B display LTRs that have repeats in the U3 region However PERV A and PERV C show repeatless LTRs Researchers found that PERVs in culture actively adapted to the repeat structure of their LTR in order to match the best replication performance a host cell could perform At the end of their study researchers concluded that repeatless PERV LTR evolved from the repeat harboring LTR This was likely to have occurred from insertional mutation and was proven through use of data on LTR and env Env It is thought that the generation of repeatless LTRs could be reflective of an adaptation process of the virus changing from an exogenous to an endogenous lifestyle 55 A clinical trial study performed in 1999 sampled 160 patients who were treated with different living pig tissues and observed no evidence of a persistent PERV infection in 97 of the patients for whom a sufficient amount of DNA was available to PCR for amplification of PERV sequences This study stated that retrospective studies are limited to find the true incidence of infection or associated clinical symptoms however It suggested using closely monitored prospective trials which would provide a more complete and detailed evaluation of the possible cross species PERV transmission and a comparison of the PERV 56 Human endogenous retroviruses edit HERV redirects here For other uses see Herv disambiguation Human endogenous retroviruses HERV comprise a significant part of the human genome with approximately 98 000 ERV elements and fragments making up 5 8 1 According to a study published in 2005 no HERVs capable of replication had been identified all appeared to be defective containing major deletions or nonsense mutations not true for HERV K This is because most HERVs are merely traces of original viruses having first integrated millions of years ago An analysis of HERV integrations is ongoing as part of the 100 000 Genomes Project 57 A 2023 study found HERV can become awakened from dormant states and contribute to aging which could be blocked by neutralizing antibodies 58 59 Human endogenous retroviruses were originally discovered when human genomic libraries were screened under low stringency conditions using either probes from animal retroviruses or by using oligonucleotides with similarity to virus sequences 1 Classification edit HERVs are classified based on their homologies to animal retroviruses Families belonging to Class I are similar in sequence to mammalian Gammaretroviruses type C and Epsilonretroviruses Type E Families belonging to Class II show homology to mammalian Betaretroviruses Type B and Deltaretroviruses Type D Families belonging to Class III are similar to foamy viruses For all classes if homologies appear well conserved in the gag pol and env gene they are grouped into a superfamily There are more Class I families known to exist 1 11 The families themselves are named in a less uniform manner with a mixture of naming based on an exogenous retrovirus the priming tRNA HERV W HERV K or some neighboring gene HERV ADP clone number HERV S71 or some amino acid motif HERV FRD A proposed nomenclature aims to clean up the sometimes paraphyletic standards 6 Origin edit Sometime during human evolution exogenous progenitors of HERV inserted themselves into germ line cells and then replicated along with the host s genes using and exploiting the host s cellular mechanisms Because of their distinct genomic structure HERVs were subjected to many rounds of amplification and transposition which lead to a more widespread distribution of retroviral DNA 1 Nevertheless one family of viruses has been active since the divergence of humans and chimpanzees This family termed HERV K HML2 makes up less than 1 of HERV elements but is one of the most studied There are indications it has even been active in the past few hundred thousand years e g some human individuals carry more copies of HML2 than others 60 Traditionally age estimates of HERVs are performed by comparing the 5 and 3 LTR of a HERV however this method is only relevant for full length HERVs A recent method called cross sectional dating 61 uses variations within a single LTR to estimate the ages of HERV insertions This method is more precise in estimating HERV ages and can be used for any HERV insertions Cross sectional dating has been used to suggest that two members of HERV K HML2 HERV K106 and HERV K116 were active in the last 800 000 years and that HERV K106 may have infected modern humans 150 000 years ago 62 However the absence of known infectious members of the HERV K HML2 family and the lack of elements with a full coding potential within the published human genome sequence suggests to some that the family is less likely to be active at present In 2006 and 2007 researchers working independently in France and the US recreated functional versions of HERV K HML2 63 64 Expression of HERV proteins edit The expression of HERV K a biologically active family of HERV produces proteins found in placenta Furthermore the expression of the envelope genes of HERV W ERVW 1 Archived 2013 09 19 at the Wayback Machine and HERV FRD ERVFRD 1 Archived 2012 10 26 at the Wayback Machine produces syncytins which are important for the generation of the syncytiotrophoblast cell layer during placentogenesis by inducing cell cell fusion 65 The HUGO Gene Nomenclature Committee HGNC approves gene symbols for transcribed human ERVs 66 Functional impact edit MER41 AIM2 is an HERV that regulates the transcription of AIM2 Absent in Melanoma 2 which encodes for a sensor of foreign cytosolic DNA This acts as a binding site for AIM2 meaning that it is necessary for the transcription of AIM2 Researchers had shown this by deleting MER41 AIM2 in HeLa cells using CRISPR Cas9 leading to an undetectable transcript level of AIM2 in modified HeLa cells The control cells which still contained the MER41 AIM2 ERV were observed with normal amounts of AIM2 transcript In terms of immunity researchers concluded that MER41 AIM2 is necessary for an inflammatory response to infection 67 Activation by exogenous viruses edit Considerable evidence indicate that HERVs can be reactivated by viral infections such as 1 retroviruses human immunodeficiency virus type 1 HIV 1 human T lymphotropic virus 1 HTLV 1 2 RNA viruses influenza A virus hepatitis C virus HCV severe acute respiratory syndrome coronavirus 2 SARSCoV 2 3 DNA viruses herpes simplex virus type 1 HSV 1 Epstein Barr virus EBV human cytomegalovirus CMV Kaposi s sarcoma associated herpesvirus KSHV 68 Several studies have shown that EBV is able to transactivate the expression of the normally inactive HERV K18 Env protein e g interacting with resting B cells via CD21 receptor Further studies revealed that the mechanism of transactivation depends on the expression of the major EBV late gene transactivator EBNA 2 In depth analysis completed the picture identifying the EBV latent membrane protein LMP 2A as a strong candidate for the HERV K18 transactivation HERV K18 has also been reported to have superantigen activity i e polyclonal T and B cell activation regardless of the specificity of their antigen receptor 69 It has also been shown that in vitro binding of the EBV gp350 protein caused activation of MSRVenv and syncytin 1 in B cells monocytes macrophages and in astrocytes cells that are involved in pathogenesis of multiple sclerosis 70 Monocytes especially after their differentiation into macrophages appeared to be the most responsive to EBVgp350 expressing even higher levels of HERV Wenv than B cells This finding is concordant with another study which demonstrated that during infectious mononucleosis EBV promoted the strongest activation of HERV W MSRV expression in monocytes compared to other blood cell types 71 Immune response to HERVs edit Despite having been integrated into genomes of vertebrates for millions of years ERVs represent an intermediate stage between exogenous viruses and the host genome it is suggested that immunological tolerance to HERV derived proteins and peptides is imperfect due to the epigenetic silencing of HERV in the thymus and bone marrow which prevents deletion of all HERV specific T and B cells 72 As evidence of this immunization of non human primates with ERV derived antigens mounted robust polyfunctional cytotoxic T cell response as well as high antibody titers According to phylogenetic studies among 30 HERV families existing in the human genome HERV K HML 2 elements which integrated most recently are the most intact and biologically active forms 69 HERV K env and HERV H env considered to be a new class of tumor associated antigens have been found to promote strong cytotoxic T cell responses in patients with various types of cancers 72 73 74 On a level of the innate immune sensing of nucleic acids single stranded RNA ssRNA and double stranded RNA dsRNA derived from endogenous retroviruses are recognized by pattern recognition receptors PRRs SsRNAs can be sensed by Toll like receptors TLR 7 and TLR 8 resulting in secretion of IFN a by stimulated dendritic cells DCs and macrophages which was observed for ssRNAs derived from HIV 1 75 DsRNAs might be one of the most immunogenic nucleic acid pathogen associated molecular patterns PAMPs since they are not found in cells in a normal state HERV derived dsRNA can be recognized by TLR 3 RIG I and MDA5 RIG I and MDA5 are known to induce a type I IFN response 75 76 When retrotranscribed into DNA retroviruses can be sensed by cyclic GMP AMP synthase stimulator of interferon genes cGAS STING pathway leading to the activation of nuclear factor kappa B NF kB and IFN regulatory factor 3 IRF3 which in turn trigger a type I IFN response DsDNA could also be sensed by DNA dependent activator of IFN regulatory factors DAI DNA RNA hybrids could be recognized by TLR 9 75 The recognition of nucleic acids through PRRs provides a very efficient strategy to fight against viral infections at the same time imposing the host to a risk due to the possibility of recognizing self nucleic acids and promotion of autoimmunity 75 Not surprisingly HERVs have been found to be associated with different autoimmune and inflammatory diseases such as multiple sclerosis amyotrophic lateral sclerosis ALS systemic lupus erythematosus SLE rheumathoid arthritis RA Sjogren syndrome SS 69 On a protein level a direct interaction between TLRs and certain HERV proteins has been shown For example the surface unit of HERV W Env also known as Multiple sclerosis associated retroviral element MSRV env was found to bind to TLR4 and CD14 stimulating the production of pro inflammatory cytokines including IL 1b IL 6 and TNFa HERV W Env can trigger a maturation process in human dendritic cells endowing them with the capacity to support a Th1 like type of Th cell differentiation 77 Immunological studies have shown some evidence for T cell immune responses against HERVs in HIV infected individuals 78 The hypothesis that HIV induces HERV expression in HIV infected cells led to the proposal that a vaccine targeting HERV antigens could specifically eliminate HIV infected cells The potential advantage of this novel approach is that by using HERV antigens as surrogate markers of HIV infected cells it could circumvent the difficulty inherent in directly targeting notoriously diverse and fast mutating HIV antigens 78 Techniques for characterizing ERVs editWhole genome sequencing edit Example A porcine ERV PERV Chinese born minipig isolate PERV A BM was sequenced completely and along with different breeds and cell lines in order to understand its genetic variation and evolution The observed number of nucleotide substitutions and among the different genome sequences helped researchers determine an estimate age that PERV A BM was integrated into its host genome which was found to be of an evolutionary age earlier than the European born pigs isolates 54 Chromatin immunoprecipitation with sequencing ChIP seq edit This technique is used to find histone marks indicative of promoters and enhancers which are binding sites for DNA proteins and repressed regions and trimethylation 34 DNA methylation has been shown to be vital to maintain silencing of ERVs in mouse somatic cells while histone marks are vital for the same purpose in embryonic stem cells ESCs and early embryogenesis 7 Applications editConstructing phylogenies edit Because most HERVs have no function are selectively neutral and are very abundant in primate genomes they easily serve as phylogenetic markers for linkage analysis They can be exploited by comparing the integration site polymorphisms or the evolving proviral nucleotide sequences of orthologs To estimate when integration occurred researchers used distances from each phylogenetic tree to find the rate of molecular evolution at each particular locus It is also useful that ERVs are rich in many species genomes i e plants insects mollusks fish rodents domestic pets and livestock because its application can be used to answer a variety of phylogenetic questions 9 Designating the age of provirus and the time points of species separation events edit This is accomplished by comparing the different HERV from different evolutionary periods For example this study was done for different hominoids which ranged from humans to apes and to monkeys This is difficult to do with PERV because of the large diversity present 55 Further research editEpigenetic variability edit Researchers could analyze individual epigenomes and transcriptomes to study the reactivation of dormant transposable elements through epigenetic release and their potential associations with human disease and exploring the specifics of gene regulatory networks 7 Immunological problems of xenotransplantation edit Little is known about an effective way to overcoming hyperacute rejection HAR which follows the activation of complement initiated by xenoreactive antibodies recognizing galactosyl alpha1 3galatosyl alpha Gal antigens on the donor epithelium 50 Risk factors of HERVs in gene therapy edit Because retroviruses are able to recombine with each other and with other endogenous DNA sequences it would be beneficial for gene therapy to explore the potential risks HERVs can cause if any Also this ability of HERVs to recombine can be manipulated for site directed integration by including HERV sequences in retroviral vectors 1 HERV gene expression edit Researchers believe that RNA and proteins encoded for by HERV genes should continue to be explored for putative function in cell physiology and in pathological conditions This would make sense to examine in order to more deeply define the biological significance of the proteins synthesized 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L Delogu LG et al 2013 11 13 Activation of MSRV type endogenous retroviruses during infectious mononucleosis and Epstein Barr virus latency the missing link with multiple sclerosis PLOS ONE 8 11 e78474 Bibcode 2013PLoSO 878474M doi 10 1371 journal pone 0078474 PMC 3827255 PMID 24236019 a b Bannert N Hofmann H Block A Hohn O 2018 02 13 HERVs New Role in Cancer From Accused Perpetrators to Cheerful Protectors Frontiers in Microbiology 9 178 doi 10 3389 fmicb 2018 00178 PMC 5816757 PMID 29487579 Rycaj K Plummer JB Yin B Li M Garza J Radvanyi L et al January 2015 Cytotoxicity of human endogenous retrovirus K specific T cells toward autologous ovarian cancer cells Clinical Cancer Research 21 2 471 483 doi 10 1158 1078 0432 CCR 14 0388 PMID 25370465 S2CID 2651471 Mullins CS Linnebacher M July 2012 Endogenous retrovirus sequences as a novel class of tumor specific antigens an example of HERV H env encoding strong CTL epitopes Cancer Immunology Immunotherapy 61 7 1093 1100 doi 10 1007 s00262 011 1183 3 PMID 22187063 S2CID 28485656 a b c d Alcazer V Bonaventura P Depil S March 2020 Human Endogenous Retroviruses HERVs Shaping the Innate Immune Response in Cancers Cancers 12 3 610 doi 10 3390 cancers12030610 PMC 7139688 PMID 32155827 Hurst TP Magiorkinis G June 2015 Activation of the innate immune response by endogenous retroviruses The Journal of General Virology 96 Pt 6 1207 1218 doi 10 1099 jgv 0 000017 PMID 26068187 Rolland A Jouvin Marche E Viret C Faure M Perron H Marche PN June 2006 The envelope protein of a human endogenous retrovirus W family activates innate immunity through CD14 TLR4 and promotes Th1 like responses Journal of Immunology 176 12 7636 7644 doi 10 4049 jimmunol 176 12 7636 PMID 16751411 S2CID 24492010 a b Garrison KE Jones RB Meiklejohn DA Anwar N Ndhlovu LC Chapman JM et al November 2007 T cell responses to human endogenous retroviruses in HIV 1 infection PLOS Pathogens 3 11 e165 doi 10 1371 journal ppat 0030165 PMC 2065876 PMID 17997601 Further reading editLower R Lower J Kurth R May 1996 The viruses in all of us characteristics and biological significance of human endogenous retrovirus sequences Proceedings of the National Academy of Sciences of the United States of America 93 11 5177 5184 Bibcode 1996PNAS 93 5177L doi 10 1073 pnas 93 11 5177 PMC 39218 PMID 8643549 Moles JP Tesniere A Guilhou JJ July 2005 A new endogenous retroviral sequence is expressed in skin of patients with psoriasis The British Journal of Dermatology 153 1 83 89 doi 10 1111 j 1365 2133 2005 06555 x PMID 16029331 S2CID 6642536 Seifarth W Frank O Zeilfelder U Spiess B Greenwood AD Hehlmann R Leib Mosch C January 2005 Comprehensive analysis of human endogenous retrovirus transcriptional activity in human tissues with a retrovirus specific microarray Journal of Virology 79 1 341 352 doi 10 1128 JVI 79 1 341 352 2005 PMC 538696 PMID 15596828 Knerr I Beinder E Rascher W February 2002 Syncytin a novel human endogenous retroviral gene in human placenta evidence for its dysregulation in preeclampsia and HELLP syndrome American Journal of Obstetrics and Gynecology 186 2 210 213 doi 10 1067 mob 2002 119636 PMID 11854637 Gifford R Tristem M May 2003 The evolution distribution and diversity of endogenous retroviruses PDF Virus Genes 26 3 291 315 doi 10 1023 A 1024455415443 PMID 12876457 S2CID 34639116 Archived from the original PDF on 2013 02 15 Retrieved 2008 01 16 External links editEndogenous Retroviruses at the U S National Library of Medicine Medical Subject Headings MeSH HERVd human endogenous retrovirus database Retrieved from https en wikipedia org w index php title Endogenous retrovirus amp oldid 1212650847 Porcine endogenous retrovirus, wikipedia, wiki, book, books, library,

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