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DNA virus

DNA viruses are a diverse group of viruses that utilize deoxyribonucleic acid (DNA) as their genetic material, in contrast to RNA viruses, and are characterized by their obligate intracellular parasitic nature, requiring host cell machinery for replication. Their genomes can be double-stranded (dsDNA) or single-stranded (ssDNA), linear or circular, and are typically enclosed within a protein capsid, with some possessing an outer lipid envelope derived from the host cell membrane. DNA viruses infect a broad range of hosts, including humans, animals, plants, and bacteria, and are responsible for numerous diseases, from acute infections like the common cold to chronic conditions such as herpes and certain cancers. In the system, DNA viruses are categorized into Group I (dsDNA viruses, whose mRNA is synthesized by transcription of the double-stranded using , with genome replication via DNA-dependent ) and Group II (ssDNA viruses, which first convert their genome to dsDNA before transcription), providing a framework based on type and mRNA synthesis strategy. This system, developed in 1971, underscores the evolutionary diversity among DNA viruses while highlighting their shared reliance on host nuclear processes for most replication, except for poxviruses which replicate in the using their own enzymes. Notable families include (causing respiratory and gastrointestinal illnesses), (responsible for , varicella-zoster infections like and ), (linked to and human papillomavirus-associated cancers such as ), (associated with rare tumors like ), (causing and aplastic crises in humans), and (including the eradicated virus). Many DNA viruses establish latent or persistent infections, evading host immunity and potentially reactivating later, as seen in herpesviruses, while others like adenoviruses typically cause self-limiting acute infections. Their medical significance extends to vaccine development (e.g., against human papillomavirus and varicella-zoster virus) and ongoing research into antiviral therapies targeting viral DNA polymerases.

Overview

Definition

DNA viruses are viruses whose genomes are composed of deoxyribonucleic acid (DNA), serving as the primary hereditary material that encodes instructions for viral protein synthesis and replication within infected host cells. These viruses are obligate intracellular parasites, requiring the host's cellular machinery to produce new viral particles, with the DNA genome typically enclosed in a protective protein coat known as a capsid. Unlike RNA viruses, which use ribonucleic acid (RNA) as their genetic material, DNA viruses employ DNA, resulting in generally lower mutation rates and distinct evolutionary trajectories influenced by the stability of DNA polymerases compared to error-prone RNA-dependent polymerases. This genomic distinction fundamentally shapes their life cycles, as DNA viruses often integrate or replicate their DNA using host nuclear processes, whereas RNA viruses typically operate in the cytoplasm. In the Baltimore classification system, DNA viruses are categorized into Group I (double-stranded DNA viruses) and Group II (single-stranded DNA viruses). DNA viruses demonstrate remarkable prevalence, infecting a diverse array of hosts spanning , , protists, , fungi, , and vertebrates including humans, and they are ubiquitous in global ecosystems, particularly where they constitute a significant portion of the viral abundance and influence microbial . The identification of viruses began in the late 19th and early 20th centuries, with the (TMV) isolated in 1892 and initially presumed to carry DNA as its genetic material akin to cellular life forms, only to be reclassified as an following experiments in 1957 that demonstrated RNA's infectious capability. Confirmation that DNA serves as the genetic material in certain viruses came from the landmark Hershey-Chase experiment in 1952, which used radiolabeled T2 to show that only its DNA enters cells to orchestrate viral replication, solidifying DNA's role in viral heredity.

Key characteristics

DNA viruses are characterized by genomes composed of deoxyribonucleic acid (DNA), which typically range in size from 5 to 250 kilobases (kb), allowing for more genetic information than the smaller genomes of most RNA viruses, owing to the greater chemical stability of DNA that permits larger, more complex structures without frequent degradation. This size variation accommodates diverse viral strategies, with single-stranded DNA (ssDNA) viruses generally having smaller genomes (around 5 kb) and double-stranded DNA (dsDNA) viruses reaching up to 2,500 kb or more (e.g., in giant viruses), with families like Herpesviridae and Poxviridae having genomes of 150–200 kb. Structurally, DNA viruses feature protein s that protect the , which can be either enveloped—surrounded by a derived from membranes—or non-enveloped, with the capsid directly exposed; common capsid symmetries include icosahedral forms in many families, while others exhibit complex morphologies such as the tailed structures in bacteriophages. Genomes may be linear or circular, influencing packaging and replication mechanisms, and the overall architecture supports across a broad spectrum, including prokaryotes like (exemplified by tailed bacteriophages in the order ) and eukaryotes such as and (e.g., herpesviruses in mammals). Many DNA viruses employ lytic cycles that destroy s upon replication or latent or persistent s where the viral may integrate into or persist in the , enabling long-term persistence. The stability of DNA genomes confers resistance to mutations compared to RNA, resulting from the double-helix structure and associated during replication, which yields mutation rates orders of magnitude lower (typically 10^{-6} to 10^{-8} per per replication cycle) than those of RNA viruses (10^{-4} to 10^{-6}), thereby promoting slower evolutionary rates and greater genetic conservation over time. For transcription, most DNA viruses, particularly those infecting eukaryotes, rely on the host's to synthesize viral (mRNA) from their DNA templates, contrasting with RNA viruses that often encode their own polymerases; this dependence integrates viral into the host's transcriptional machinery, typically occurring in the .

Classification

Baltimore classification

The Baltimore classification system, proposed by virologist in 1971, organizes viruses into seven groups based on the type of in their and the mechanism by which they synthesize (mRNA) from that . This framework highlights the central role of mRNA in and , providing a functional that transcends host specificity or morphological traits. DNA viruses are assigned to two of these groups: Group I, comprising double-stranded DNA (dsDNA) viruses, and Group II, consisting of single-stranded DNA (ssDNA) viruses. Group I viruses possess dsDNA genomes that function directly as positive-sense templates for transcription into mRNA, utilizing host or viral polymerases. Most replicate within the host , leveraging cellular machinery for DNA replication and transcription, although exceptions like poxviruses carry out these processes in the using their own enzymes. Representative families include , which cause infections such as , and , associated with respiratory illnesses. This group encompasses a wide range of viruses infecting animals, , and , unified by their reliance on dsDNA as the genetic material. Group II viruses contain ssDNA genomes, typically positive-sense, which are first converted into a dsDNA intermediate upon entry into the host cell; this replicative form then serves as the template for transcription and further genome production. Replication generally occurs in the , dependent on host DNA polymerases. Key examples include , small viruses causing diseases like in humans, and , plant pathogens transmitted by insects that lead to crop losses. These viruses are smaller and more limited in host range compared to Group I but share the core strategy of using a dsDNA intermediate for . One key advantage of the Baltimore system is its emphasis on replication strategies and mRNA synthesis pathways, offering a simple, mechanistic view of viral diversity that remains relevant for understanding infection processes, independent of evolutionary phylogeny. It contrasts with the International Committee on Taxonomy of Viruses (ICTV) approach, which employs realm-based classification like for dsDNA viruses and for ssDNA viruses to reflect phylogenetic relationships. However, a limitation is that it predates modern genomic insights, such as the polyphyletic origins of ssDNA viruses, which derive from diverse plasmid-like ancestors rather than a single lineage, complicating strict grouping.

ICTV classification

The International Committee on Taxonomy of Viruses (ICTV) utilizes a hierarchical taxonomic system for viruses, with established as the highest rank in 2018 to reflect evolutionary relationships based on shared protein folds and morphogenetic modules. DNA viruses exhibit , spanning three distinct realms—, , and —due to their divergent architectures and replication strategies, rather than a monophyletic grouping by type alone. This structure contrasts with functional systems like the (Groups I for dsDNA and II for ssDNA viruses). The realm Duplodnaviria, established in 2020, comprises viruses with linear double-stranded DNA (dsDNA) genomes and major capsid proteins (MCPs) featuring a double jelly-roll fold, a hallmark morphogenetic module conserved across archaeal, bacterial, and eukaryotic hosts. It includes the kingdom Heunggongvirae, which encompasses both prokaryotic viruses (phylum Uroviricota, class Caudoviricetes, including tailed bacteriophages) and eukaryotic viruses (phylum Peploviricota, class Herviviricetes, such as Herpesviridae causing infections in vertebrates and invertebrates). The realm , introduced in 2019, primarily includes single-stranded DNA (ssDNA) viruses that utilize a rolling-circle replication mechanism, along with some dsDNA viruses sharing this module. It comprises four kingdoms: Loebvirae, Sangervirae, and Trapavirae (primarily prokaryotic ssDNA viruses); and Shotokuvirae (eukaryotic ssDNA and related circular dsDNA viruses). Under Shotokuvirae, phylum Cressdnaviricota includes circular ssDNA viruses such as (plant pathogens) and Circoviridae (animal pathogens like circoviruses); phylum Cossaviricota includes circular dsDNA viruses like (causing and cancers) and (associated with tumors). Under Loebvirae, phylum Hofneiviricota covers linear ssDNA viruses, such as (e.g., parvoviruses causing disease in mammals). This realm underscores the evolutionary linkage among small, non-enveloped DNA viruses infecting , , and prokaryotes. The realm Varidnaviria, created in 2020, groups dsDNA viruses with MCPs containing a single vertical jelly-roll fold, emphasizing vertical transmission in capsid assembly. Its kingdoms include Bamfordvirae, with phylum Nucleocytoviricota for nucleocytoplasmic large DNA viruses (NCLDVs), such as Poxviridae (e.g., vaccinia virus), Mimiviridae (giant viruses infecting amoebae), Iridoviridae, and Phycodnaviridae (algal viruses); and phylum Preplasmiviricota (class Polintoviricetes) for some bacteriophages and viruses like Adenoviridae (causing respiratory illnesses) and families Tectiviridae and Corticoviridae. Additional kingdoms, such as Abadenavirae, cover other prokaryotic dsDNA viruses. This realm captures the structural unity among large, complex dsDNA viruses across eukaryotic and prokaryotic hosts. As of the 2025 ICTV release (version 2, ratified February 2025), updates have integrated metagenomic discoveries from viromes and other environments, refining boundaries by adding new families and genera—such as expansions in Mimiviridae for giant viruses and novel NCLDV lineages—while maintaining the polyphyletic framework for DNA viruses based on enhanced phylogenetic analyses.

Genome and structure

Double-stranded DNA viruses

Double-stranded DNA (dsDNA) viruses, classified under Baltimore group I, possess genomes consisting of two strands, enabling stable storage of genetic information and facilitating replication through host or viral polymerases. These genomes are typically linear, though some families feature circular forms, and range in size from approximately 5 to over 2 Mb, with most falling between 10 and 300 to support diverse coding capacities. Many linear dsDNA genomes include inverted terminal repeats (ITRs) at their ends, which serve as origins for replication initiation and protein priming, as seen in adenoviruses where ITRs flank the 26–45 genome. This structural organization allows for efficient packaging and uncoating during infection. Adenoviruses exemplify non-enveloped dsDNA viruses with linear genomes packaged in , measuring about 90 nm in diameter, which protect the DNA during extracellular transmission. In contrast, herpesviruses feature linear dsDNA genomes of 125–240 kb, enclosed in enveloped approximately 125 nm across, with an additional tegument layer that aids in early and establishment. Poxviruses represent a distinct group with large linear dsDNA genomes of 130–300 kb, assembled into complex, brick-shaped virions up to 360 × 270 × 250 nm, featuring multiple protein layers rather than a simple . These variations highlight the architectural diversity among dsDNA viruses, adapting to different replication environments. The coding capacity of dsDNA viruses scales with genome size, typically encoding 50–300 proteins, including essential enzymes for DNA metabolism; for instance, herpesviruses encode a dedicated B-family for replication. Packaging occurs via portal vertices in icosahedral capsids or through specialized motors in complex structures, ensuring dense coiling of the genome within the virion. Most dsDNA viruses, such as adenoviruses and herpesviruses, replicate in the host , briefly referencing this site for . dsDNA viruses maintain genomic stability through mechanisms in their s, achieving rates of 10^{-8} to 10^{-6} substitutions per per replication cycle, far lower than RNA viruses due to 3'–5' activity in host or viral enzymes like the herpesvirus . This fidelity, supported by either cellular pathways or virus-encoded factors, minimizes errors across large genomes and supports long-term persistence in hosts.

Single-stranded DNA viruses

Single-stranded DNA (ssDNA) viruses possess genomes that are notably compact, typically ranging from 1 to 8 kilobases (kb) in length, and exist as either linear or circular molecules. These genomes are single-stranded and can be of positive-sense or negative-sense , with many requiring host-mediated conversion to a double-stranded DNA replicative form (RF) to initiate transcription and replication. Unlike the larger genomes of double-stranded DNA viruses, which often exceed 100 kb, ssDNA viral genomes prioritize efficiency due to their small size. Representative examples include parvoviruses, which feature linear ssDNA of approximately 5 kb packaged in non-enveloped icosahedral capsids, and circoviruses, which have circular ssDNA around 2 kb also enclosed in small icosahedral structures. The replication process in these viruses generates double-stranded , such as the covalently closed circular RF in circoviruses or hairpin-containing RF in parvoviruses, which serve as templates for both transcription and further genome amplification. This intermediate stage is essential, as the initial ssDNA genome alone cannot directly support protein synthesis. Structurally, ssDNA viruses package their genomes tightly coiled within small icosahedral capsids, often 17-26 nm in diameter, to accommodate the nucleic acid's flexibility and density. This packaging is facilitated by numerous capsid-genome interactions, enabling cooperative assembly similar to that in single-stranded RNA viruses, though the ssDNA must be condensed without the rigidity of double-stranded forms. High gene density is a hallmark, with overlapping reading frames allowing a limited genome to encode essential proteins like the capsid protein and replication-associated protein (Rep), maximizing coding capacity in these minimalistic blueprints. Mutability in ssDNA viruses is elevated during the exposed ssDNA phase, where and other chemical instabilities can introduce errors more readily than in double-stranded forms, contributing to evolutionary adaptability. However, their overall mutation rates, ranging from 10^{-8} to 10^{-6} substitutions per per , remain lower than those of viruses (10^{-6} to 10^{-4}), reflecting by host enzymes during RF synthesis. These viruses exhibit strong dependence on host DNA s for second-strand synthesis and RF maintenance, often persisting as extrachromosomal episomes in the without integrating into the host . Such interactions highlight their reliance on cellular machinery for , particularly in non-dividing cells where polymerase availability is limited.

Replication

General process

The replication cycle of DNA viruses follows a series of conserved steps that enable the production of progeny virions, typically spanning 4 to 48 hours depending on the virus and host cell conditions. This process begins with attachment and culminates in release, relying heavily on host cellular machinery while the virus directs key enzymatic activities. Although variations exist based on genome type—such as double-stranded (dsDNA) or single-stranded (ssDNA)—most DNA viruses share these fundamental phases, with replication often occurring in the nucleus except for exceptions like poxviruses. Attachment initiates the cycle, where viral surface or proteins specifically bind to host cell receptors, such as proteoglycans, , or residues, facilitating initial contact and determining host . This step is highly specific and energy-independent, mediated by electrostatic and hydrophobic interactions between the virion and the plasma membrane. For example, () uses C to bind on target cells. Following attachment, entry occurs through mechanisms like , direct membrane , or, rarely, injection, allowing the viral to penetrate the cell. In endocytosis, the virion is engulfed in a vesicle that acidifies, triggering uncoating; involves viral proteins merging the envelope with the host membrane. Uncoating then releases the viral , often transporting it to the via and complexes for dsDNA viruses. Once inside, and replication proceed in temporal phases. The viral , uncoated in the , is transcribed by host into mRNA, starting with immediate-early genes that encode regulatory proteins to hijack host transcription machinery. This is followed by early genes producing enzymes for , such as and , enabling the synthesis of multiple copies using host and factors. Late genes are then expressed, coding for structural proteins like capsids and envelope components. For ssDNA viruses, the is first converted to dsDNA by host before replication. Assembly occurs concurrently, with newly synthesized genomes packaged into procapsids in the or , often requiring viral scaffolding proteins for maturation; enveloped DNA viruses acquire their during this phase. Finally, release happens via , which bursts the host membrane to liberate non-enveloped virions, or , where enveloped particles egress by wrapping in host-derived membranes without immediate , ensuring virion infectivity.

Specific replication strategies

DNA viruses exhibit a variety of replication strategies adapted to their genome structures and host cellular machinery, ensuring efficient genome amplification within infected cells. These mechanisms include bidirectional theta replication for many double-stranded DNA (dsDNA) viruses, rolling circle replication prevalent in both single-stranded DNA (ssDNA) and some dsDNA viruses, strand displacement in adenoviruses, replicative transposition in certain tailed bacteriophages, and conversion of ssDNA to dsDNA intermediates. Overall, these processes maintain high replication fidelity, with error rates typically ranging from $10^{-6} to $10^{-8} errors per base, attributed to the proofreading exonuclease activity of DNA polymerases involved. Poxviruses replicate their linear dsDNA genomes in the cytoplasm using virally encoded enzymes, including a multi-subunit DNA polymerase, helicase-primase, and others. Replication initiates via a self-priming mechanism at the hairpin termini, producing long concatemers that are resolved into unit-length genomes by viral recombination and resolution enzymes like a Holliday junction endonuclease. This occurs within cytoplasmic viral factories. In dsDNA viruses with circular , such as herpesviruses and papillomaviruses, replication often proceeds bidirectionally from a specific in a mode, forming a theta-shaped intermediate as the replication progress. This origin-initiated process recruits and proteins to unwind the DNA and synthesize leading and lagging strands simultaneously, allowing for rapid duplication of the . The of the replication , which determines the rate of incorporation, is given by the equation v = \frac{dN}{dt}, where v is the fork speed, N is the number of added, and t is time; in eukaryotic viruses, this speed typically ranges from 10 to 100 per second. Rolling circle replication, employed by ssDNA viruses like parvoviruses and some dsDNA viruses such as herpesviruses during later stages, generates long linear concatemers of the to facilitate high-yield production. The process begins with a viral endonuclease nicking one strand at the (ori), creating a 3' hydroxyl end that serves as a primer for . As synthesis proceeds, the non-template strand is displaced, resulting in a single-stranded tail that extends into a concatemer with multiple units; this displaced strand is later converted to dsDNA by or viral polymerases. Adenoviruses utilize a specialized strand for their linear dsDNA , where the DNA extends the new strand without fully unwinding the parental duplex, thereby displacing the non-template strand. Initiation occurs at the ends via a protein-primed involving a pre-terminal protein covalently linked to the 5' end, followed by polymerase progression that releases single-stranded DNA intermediates. These displaced strands are then replicated into duplex forms using host factors, enabling efficient amplification in the . Single-stranded DNA-binding proteins stabilize the displaced strands during this . Tailed bacteriophages like employ replicative to integrate and replicate their dsDNA within the host chromosome. This involves where the phage (MuA) recognizes the phage ends and inserts the genome at random or semi-random target sites, simultaneously replicating the inserted copy through a cointegrate intermediate. The process generates direct repeats at the integration junctions and allows multiple rounds of during lytic growth, amplifying the without relying on host origins. For ssDNA viruses, such as parvoviruses and geminiviruses, the initial replication step involves conversion of the incoming single-stranded genome to a double-stranded replicative form by host , which synthesizes the complementary strand using the viral ssDNA as a template. This occurs in the , where the ssDNA is uncoated and serves directly as a primer-template for host polymerase δ or ε, often with assistance from viral proteins like Rep that initiate nicking for subsequent rolling circle amplification. The resulting dsDNA intermediate then supports transcription and further replication cycles.

Diseases and hosts

Human pathogens

DNA viruses from several families are significant human pathogens, causing a range of acute and chronic diseases, including respiratory infections, skin lesions, neurological disorders, and cancers. These viruses often establish lifelong infections, with latency or persistence in host cells contributing to recurrent symptoms or long-term health risks. Key families include , , , , , and , each associated with distinct clinical manifestations primarily in humans. The family encompasses eight human-specific herpesviruses, with types 1 and 2 (HSV-1 and HSV-2) causing oral and genital sores, respectively, through blistering lesions that recur due to viral in sensory neurons. Varicella-zoster virus (VZV) leads to in primary and shingles upon reactivation, characterized by painful vesicular rashes along dermatomes. Epstein-Barr virus (EBV) is linked to , presenting with fever, , and , and contributes to malignancies such as and via oncogenic transformation in B cells. is a hallmark of these viruses, allowing lifelong persistence and reactivation under stress or . Papillomaviridae viruses, particularly human papillomavirus (HPV) types 16 and 18, cause benign and are responsible for nearly all cancers through integration into host DNA and disruption of control. Low-risk types like HPV-6 and -11 lead to , while high-risk types promote anogenital and oropharyngeal cancers. The vaccine, introduced in 2006, targets these major oncogenic types and has significantly reduced incidence in vaccinated populations. Adenoviridae viruses commonly cause respiratory infections, such as , , and , as well as (pink eye), with outbreaks frequent in children and settings. Over 50 serotypes exist, but types 3, 4, 7, and 14 are most associated with severe illness in vulnerable groups. These infections are typically self-limiting but can lead to complications like in young children. Polyomaviridae includes the JC virus (human polyomavirus 2), which infects 50–80% of individuals asymptomatically early in life but reactivates in immunocompromised hosts to cause (PML), a demyelinating brain disease with , cognitive decline, and motor deficits. PML primarily affects those with or on immunosuppressive therapy, with no specific antiviral treatment available. Additionally, (MCPyV) is associated with , a rare but aggressive , through viral integration and T-antigen expression promoting oncogenesis. Parvoviridae viruses, particularly , cause erythema infectiosum (), characterized by a distinctive "slapped cheek" rash in children, along with mild flu-like symptoms. In adults, it can lead to joint pain and swelling. The virus also triggers transient aplastic crisis in individuals with underlying hemolytic anemias, such as , by suppressing production, and in pregnant women if infection occurs in the first or second trimester. Cases of increased notably in 2024, particularly in the United States. Poxviridae human pathogens include variola virus, which caused smallpox—a disfiguring, often fatal disease eradicated globally in 1980 through —and , responsible for benign, pearly skin papules that spread through contact and resolve spontaneously but can persist in immunocompromised individuals. featured high fever, rash progressing to pustules, and a 30% , while is more common in children and sexually active adults. Epidemiologically, DNA viruses infect billions worldwide, with HSV-1 alone affecting approximately 3.8 billion people under age 50 (64% prevalence, as of 2025), establishing lifelong infections. Certain DNA viruses, such as HPV and EBV, contribute to about 15% of global cancer cases, underscoring their impact through oncogenic mechanisms.

Pathogens in other organisms

DNA viruses infect a wide array of non-human organisms, playing significant roles in animal health, plant agriculture, microbial ecology, and global biogeochemical cycles. In animals, the (ASFV), a member of the Asfarviridae family with a double-stranded DNA genome, causes a highly lethal hemorrhagic disease in domestic pigs, characterized by mortality rates approaching 100% and substantial economic impacts on the swine industry. Similarly, iridoviruses, large double-stranded DNA viruses from the Iridoviridae family, infect , amphibians, and reptiles, leading to systemic diseases such as lymphocystis in and ranaviral hemorrhagic conditions in amphibians, which can decimate wild and farmed populations. These animal pathogens highlight the zoonotic potential and parallels to human viral infections through shared viral families like , though their primary impacts are veterinary. In plants, DNA viruses from the Caulimoviridae family, which possess double-stranded DNA genomes replicated via reverse transcription, cause notable crop diseases; for instance, cauliflower mosaic virus (CaMV) induces mosaic symptoms and stunting in brassica crops like and , resulting in yield reductions of up to 50% in infected fields, particularly in temperate regions. Complementing these, geminiviruses, single-stranded DNA viruses transmitted by insect vectors such as and leafhoppers, affect a broad range of crops including tomatoes, , and , leading to leaf curling, , and severe yield losses worldwide. These DNA viruses collectively contribute to annual global agricultural losses estimated at tens of billions of dollars, underscoring their economic significance in . Bacteriophages, or phages, represent another critical category of DNA viruses targeting prokaryotes; T4-like myoviruses, with their double-stranded DNA genomes, infect bacteria such as through lytic cycles that cause host cell , thereby regulating bacterial populations and facilitating via , which influences microbial and diversity. Beyond bacteria, giant viruses from the Mimiviridae family, including mimiviruses with large double-stranded DNA genomes, primarily infect amoebae in aquatic environments and play a pivotal ecological role by lysing hosts, thereby influencing marine microbial food webs and contributing to carbon cycling through the release of that supports bacterial remineralization. Economically, veterinary interventions against animal DNA viruses are vital; for example, vaccines targeting virus (a double-stranded DNA alphaherpesvirus affecting pigs) have effectively controlled outbreaks in swine herds, reducing mortality from respiratory and neurological symptoms through attenuated live or inactivated formulations. Overall, these non-human DNA virus infections drive ecological dynamics, such as biodiversity regulation in aquatic systems, while imposing substantial costs on and .

Evolution

Origins

DNA viruses are thought to have multiple independent origins, emerging from cellular genetic elements such as plasmids and transposons during the early of life on , around 3 to 4 billion years ago. This hypothesis posits that DNA viruses arose after RNA-based systems, as part of a broader "ancient virus world" that predated the (LUCA) of modern cells, evolving within precellular compartments like hydrothermal vents. of viral hallmark genes, including the jelly-roll protein and superfamily 3 —absent in cellular genomes but shared across diverse es—supports this precellular derivation, indicating viruses as ancient replicators that later became obligate intracellular parasites. Key evidence for these ancient origins comes from endogenous viral elements (EVEs), viral sequences integrated into host genomes that serve as genomic fossils. In eukaryotes, EVEs from ssDNA viruses, such as geminivirus-like sequences resembling retrotransposons, have been identified in fungal genomes like that of Tuber melanosporum, suggesting viral contributions to host transposon evolution. Similarly, dsDNA virus EVEs, including polinton-like viruses (PLVs), are widespread in protist and animal genomes, with purifying selection in vertebrates indicating functional roles in host adaptation. These integrations, some dating to 40–50 million years ago for circoviruses and parvoviruses in animal hosts, reveal a history of repeated endogenization events that trace viral lineages deep into eukaryotic evolution. Double-stranded DNA (dsDNA) viruses likely originated from primordial plasmids or escaped fragments of cellular DNA, with bacteriophages representing an early prokaryotic form that predates eukaryotes. Genomic analyses show eukaryotic dsDNA viruses, such as those in the Nucleocytoviricota phylum, evolved through recombination with bacteriophage ancestors during eukaryogenesis, acquiring genes from both bacterial and archaeal sources. Single-stranded DNA (ssDNA) viruses, unified in the realm Monodnaviria, trace their roots to bacterial and archaeal rolling-circle replicating plasmids, evolving via fusion with capsid genes from positive-sense RNA viruses. This modular assembly underscores multiple emergence events in prokaryotic environments, long before eukaryotic hosts. Through co-evolution, DNA viruses have profoundly influenced host immunity, driving the diversification of adaptive immune components. For instance, long-term interactions between herpesviruses and vertebrates have fueled an , promoting the of ( alleles like HLA-B to enhance recognition and immune evasion countermeasures. Such dynamics, evidenced by phylogenetic congruence between viral and host immune genes, highlight viruses as key architects of host defense systems across billions of years.

Phylogenetic diversity

DNA viruses exhibit polyphyletic origins, as they do not form a single monophyletic group but are distributed across multiple distinct lineages within the International Committee on Taxonomy of Viruses (ICTV) classification system. Specifically, DNA viruses are partitioned into at least three major realms—, , and —reflecting independent evolutionary histories based on conserved genomic and structural features rather than a shared common ancestor for all DNA viruses. This is evident in the disparate architectures of their replication and modules, which have evolved convergently in response to similar selective pressures across viral lineages. Within the realm Duplodnaviria, viruses share a conserved morphogenetic characterized by a major protein (MCP) with the HK97 fold, alongside for a genome-packaging and terminase, enabling tailed structures observed in bacteriophages, herpesviruses, and related viruses across bacterial, archaeal, and eukaryotic hosts. This realm encompasses a broad phylogenetic diversity, with gene homologs distributed across kingdoms, underscoring ancient divergences and adaptations to diverse cellular environments. In contrast, the realm Varidnaviria includes viruses with MCPs featuring double β-jelly roll folds, such as adenoviruses, polyomaviruses, and giant viruses like mimiviruses, which can encode over 1,000 , far exceeding typical viral sizes and incorporating complex metabolic functions. These phylogenies highlight the realm's expansive diversity, from small icosahedral viruses to massive nucleocytoviruses that rival small eukaryotic in complexity. Horizontal gene transfer (HGT) plays a pivotal role in shaping the phylogenetic diversity of DNA viruses, facilitating the exchange of genetic material between viruses and their hosts, as well as among viral lineages. For instance, polinton-like viruses (PLVs), which are integrative dsDNA elements akin to selfish genetic mobiles, exhibit evidence of HGT with poxviruses, including shared genes for proteins and polymerases that suggest polintons as evolutionary precursors to certain large DNA viruses. Such transfers are widespread, contributing to mosaic genomes that enhance viral adaptability, such as acquiring host-like metabolic genes to manipulate cellular processes during infection. Recent metagenomic advances since 2020 have unveiled substantial uncultured diversity in marine DNA viruses, particularly single-stranded DNA (ssDNA) forms, with long-read sequencing revealing novel lineages in oligotrophic environments that dominate microbial and nutrient . In parallel, studies from 2023 to 2025 on giant viruses within have identified expanded auxiliary metabolic s (AMGs) in viromes, including those modulating carbon, , and pathways, which enhance host metabolic reprogramming and reveal previously undetected functional roles in global biogeochemical cycles. These discoveries, derived from genome-resolved , have expanded the known Nucleocytoviricota by recovering hundreds of new genomes with alternative genetic codes and novel gene cassettes. Global estimates suggest the virosphere comprises over 10^8 distinct viral species, a figure derived from metagenomic surveys extrapolating from sampled diversity in oceans, soils, and host-associated microbiomes, though this represents only a fraction of the total virosphere.

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