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Negative-strand RNA virus

Negative-strand RNA viruses, also known as negative-sense RNA viruses, are a diverse group of enveloped viruses characterized by single-stranded genomes with negative polarity, meaning the genomic RNA is antisense to (mRNA) and cannot be directly translated by host cellular machinery. These viruses belong to group V and require a virion-packaged (RdRp) to initiate by transcribing the genomic RNA into positive-sense mRNA upon entry into the host . Their genomes are typically linear and may be non-segmented or segmented into 2 to 8 pieces, encapsidated with nucleoproteins to form helical or circular ribonucleoprotein complexes essential for replication. These viruses are classified into several orders and families based on genome organization, morphology, and host range, with the majority infecting animals, humans, or plants. The order Mononegavirales comprises non-segmented negative-strand RNA viruses, including the families Rhabdoviridae (e.g., ), Paramyxoviridae (e.g., and viruses), Filoviridae (e.g., and viruses), and Bornaviridae. Segmented negative-strand RNA viruses include the family Orthomyxoviridae (influenza viruses, with 6–8 genome segments), the order Bunyavirales (encompassing families such as Peribunyaviridae (e.g., La Crosse virus) and Phenuiviridae (e.g., virus)), and the family Arenaviridae (e.g., Lassa virus, some with ambisense segments). Additional families like Pneumoviridae (e.g., ) fall under Mononegavirales. Replication of negative-strand RNA viruses predominantly occurs in the host cytoplasm, where the RdRp complex, along with accessory proteins, transcribes genomic into subgenomic mRNAs for protein and full-length antigenomic as a template for new genomic strands. Exceptions include orthomyxoviruses, which replicate in the . These viruses exhibit high rates due to error-prone RdRp activity, facilitating antigenic drift and shift, which contribute to their potential and challenges in development. Notable for causing acute respiratory illnesses, hemorrhagic fevers, and neurological diseases, they represent significant threats worldwide.

Overview and Definition

Etymology

The term "negative-strand RNA virus" derives from the polarity of the genome relative to (mRNA), where the genome is in the antisense —complementary to the mRNA that encodes proteins—necessitating initial transcription by a virus-encoded before can occur. This contrasts with positive-strand RNA viruses, whose genomes have the same sense as mRNA and can be directly translated by host ribosomes upon infection. The was formalized in 1971 by in his seminal classification system for viruses, which grouped them based on their type and mode of mRNA synthesis, placing negative-strand RNA viruses in Group V. This system emerged amid growing discoveries of RNA viruses in the 1960s, such as and vesicular stomatitis viruses, whose genomes were found to require de novo transcription, distinguishing them from the more common positive-strand types like . The term gained widespread adoption through the efforts of the International Committee on Taxonomy of Viruses (ICTV), established in 1971, which integrated Baltimore's framework into its hierarchical during the to standardize classification amid rapid virological advances. Related terminology includes "negative-sense RNA," often used interchangeably, though some viruses within negative-strand groups, such as certain arenaviruses, feature ambisense segments where portions of the genome are positive-sense and others negative-sense, highlighting nuances in organization while maintaining the overall negative-strand designation.

General Characteristics

Negative-strand RNA viruses, also known as negative-sense single-stranded RNA (nsRNA) viruses, possess a genome composed of single-stranded RNA that is complementary to messenger RNA (mRNA), rendering it non-infectious when extracted from virions. This negative-sense orientation distinguishes them from positive-strand RNA viruses, whose genomes can directly serve as mRNA for translation upon entry into host cells. Instead, nsRNA viruses require a primary transcription step mediated by their virally encoded (RdRp) to generate positive-sense mRNAs, as their genomic RNA lacks both a 5' cap and a 3' poly(A) tail essential for host ribosomal recognition. These viruses are broadly divided into two major groups based on genome organization: non-segmented genomes, exemplified by the order Mononegavirales (including families such as , e.g., , and , e.g., measles virus), and segmented genomes, represented by families like (e.g., viruses) with 6–8 RNA segments. Most nsRNA viruses are enveloped, acquiring a from host cell membranes during , which facilitates attachment and entry via surface glycoproteins. Their virions typically contain helical or spherical nucleocapsids, where the genomic is tightly encapsidated by nucleoproteins (N or NP) to form stable ribonucleoprotein complexes that serve as templates for replication and protect the from host nucleases. A hallmark of nsRNA viruses is their reliance on cellular machinery for , as mRNAs—produced by the RdRp—are translated by ribosomes in the . Replication predominantly occurs in the , often within specialized that concentrate components, though exceptions exist, such as viruses (), which replicate in the and employ cap-snatching from pre-mRNAs for mRNA priming. This cytoplasmic or nuclear localization, combined with the need for concurrent encapsidation of nascent by nucleoproteins during replication, underscores their dependence on a multifunctional polymerase complex (typically comprising the large L protein and cofactors like phosphoprotein P) to switch between transcription and replication modes. In contrast to positive-strand RNA viruses, which can initiate by direct genomic to produce RdRp and other proteins, nsRNA viruses must deliver their and nucleoproteins within the virion to enable the initial transcription event, as naked negative-sense is inert in host cells. This fundamental difference imposes unique evolutionary pressures, leading to conserved structural motifs in their polymerases for de novo initiation and processive synthesis on nucleocapsid templates.

Genome and Virion Structure

Genome Organization

Negative-strand RNA viruses possess linear, single-stranded RNA genomes of negative polarity, which serve as templates for transcription by the viral RNA-dependent RNA polymerase (RdRp). In non-segmented viruses, such as those in the order Mononegavirales, the genome is a continuous molecule typically ranging from 10 to 15 kilobases (kb) in length, though some like Ebola virus extend to about 19 kb. These genomes begin with a 3' leader sequence followed by open reading frames (ORFs) encoding essential proteins in a conserved order, such as nucleoprotein (N), phosphoprotein (P), matrix (M), glycoprotein (G), and large polymerase (L) for rhabdoviruses like vesicular stomatitis virus. The genomic RNA lacks a 5' cap and 3' poly-A tail, necessitating viral enzymes for mRNA modification during transcription. Segmented negative-strand viruses, including those in the orders and Orthomyxovirales as well as the family Arenaviridae, feature divided into 2 to 8 discrete RNA segments, with exemplifying 8 segments totaling around 13.5 kb and arenaviruses having 2 segments totaling about 10.5 kb. Each segment contains one or two ORFs, encoding proteins like the polymerase complex subunits on the largest segment and surface glycoproteins on others, without a universal order across the . Terminal sequences include 3' and 5' untranslated regions (UTRs) with partial complementarity that forms panhandle structures, serving as packaging signals for genome assembly. Like their non-segmented counterparts, these lack 5' caps and 3' poly-A tails, relying on viral polymerases for subsequent mRNA processing. Certain segmented viruses exhibit ambisense coding strategies, particularly in genera like Phlebovirus within and in the small segment of arenaviruses within Arenaviridae, where portions of segments such as the small (S) and medium (M) RNAs are transcribed in positive while others remain negative . This dual-polarity arrangement allows efficient expression of nonstructural proteins alongside structural ones, optimizing genome utilization in compact segments.

Virion Morphology

Negative-strand RNA viruses are characterized by enveloped virions, with the lipid bilayer derived from the host cell membrane during budding. This envelope is typically studded with surface glycoproteins that project outward, forming spikes essential for viral interaction with host cells. The envelope surrounds an internal matrix layer and the nucleocapsid core, providing structural integrity and protection to the viral genome. The nucleocapsid core consists of the genomic tightly encapsidated by (N or NP), forming a ribonucleoprotein complex (RNP) that serves as the functional unit for transcription and replication. In most families, such as and , the nucleocapsid exhibits helical symmetry, with the N protein oligomerizing along the RNA in a rod-like or coiled structure; for example, in vesicular stomatitis virus (VSV, a rhabdovirus), the helical nucleocapsid measures approximately 180 nm in length and 15-20 nm in diameter. Orthomyxoviruses like feature multiple short helical RNP segments rather than a single continuous . A matrix protein (M or equivalent, such as VP40 in ) lies beneath the envelope, bridging the RNP to the and contributing to virion stability and shape. Surface glycoproteins vary by family: rhabdoviruses and filoviruses have a single type (e.g., in and GP in Ebola virus), paramyxoviruses typically have two (F for fusion and HN/H for hemagglutinin-neuraminidase, as in measles virus), and orthomyxoviruses have HA () and NA (neuraminidase). Virion sizes exhibit considerable variation across families, generally ranging from 80 to 200 nm in diameter, though shapes differ markedly. Rhabdoviruses often adopt a bullet-shaped or rod-like (100-430 nm long by 45-100 nm wide), paramyxoviruses are pleomorphic and spherical to filamentous (150-300 nm in diameter), and orthomyxoviruses form spherical (80-120 nm) or filamentous (up to 200 nm long) particles. Filoviruses represent an extreme, with elongated, filamentous forms up to 1-14 μm in length but only ~80 nm in diameter, as seen in Ebola virus. All known negative-strand RNA virus families produce enveloped virions, with no confirmed non-enveloped exceptions in major taxa.

Replication Cycle

Transcription and Gene Expression

Upon entry into the host cell, negative-strand RNA viruses initiate primary transcription using their (RdRp) complex, which transcribes the negative-sense genome into positive-sense mRNAs. In non-segmented negative-strand RNA viruses, such as those in the order (e.g., vesicular virus), the RdRp consists of the large (L) protein, which catalyzes RNA synthesis and processing, and the (P) as a cofactor that tethers the complex to the nucleocapsid. The L protein contains domains for methyltransferase, polyribonucleotidyltransferase (PRNTase), and RNA-dependent RNA polymerase activities, enabling initiation at the 3' leader promoter (e.g., UGC in vesicular stomatitis virus). In segmented viruses, like (), the RdRp comprises three subunits—PB1 (polymerase core), PB2 (cap-binding), and PA (endonuclease)—which bind to the 5' and 3' ends of each genome segment to initiate transcription. Viral mRNAs are processed to resemble transcripts for efficient . In non-segmented viruses, capping occurs via an unconventional PRNTase mechanism in the L protein, where a covalently linked pRNA intermediate is transferred to GDP to form GpppA, followed by to m^7GpppAm. Polyadenylation results from stuttering at gene-end poly-U tracts (typically 3'-AUACUUUUUUU), adding ~200 residues through reiterative copying. Segmented viruses employ cap-snatching, where the PB2 subunit binds and PA endonuclease cleaves 5' s from nascent pre-mRNAs (10–13 nucleotides upstream of the cap), priming viral transcription and providing a short non-templated leader sequence. Gene junctions in non-segmented viruses feature conserved intergenic motifs, such as gene-start (3'-UUGUCDNUAG) and gene-end sequences, which signal termination and reinitiation, with poly-U/UG tracts enabling stuttering for poly(A) addition and precise spacing between open reading frames. Gene expression exhibits a hierarchical gradient, with higher transcription levels for genes proximal to the 3' end due to polymerase processivity and attenuation at junctions. In non-segmented viruses, reinitiation efficiency is ~70%, leading to abundant nucleoprotein (N) and P transcripts decreasing toward the 3'-distal polymerase (L) gene, ensuring early production of replication factors. Segmented viruses transcribe each segment independently, but overall expression follows a similar 3' to 5' bias within segments, regulated by polymerase stalling and termination signals. Viral mRNAs, capped and polyadenylated, are exported to the cytoplasm and translated by host ribosomes; in some paramyxoviruses (e.g., measles virus), the P gene undergoes co-transcriptional editing via polymerase stuttering at a template U-run, inserting or deleting G residues to produce accessory proteins like V and W from the primary P mRNA. The switch from transcription to replication is triggered by accumulation of the N protein, which favors of full-length antigenomic RNA over subgenomic mRNAs. In non-segmented viruses, nascent antigenome RNA is encapsidated by soluble N₀-P complexes, preventing recognition of transcription termination signals and promoting read-through by the RdRp. This N-dependent shift ensures balanced early in , transitioning to genome amplification as N levels rise.

Genome Replication and Assembly

Genome replication in negative-strand RNA viruses begins with the synthesis of a full-length positive-sense antigenome from the incoming negative-sense RNA template, a process mediated by the (RdRp) complex. This antigenome serves as the template for producing new negative-sense genomic RNAs. To prevent degradation by host nucleases, the nascent RNA strands are immediately encapsidated by the (N or NP), forming ribonucleoprotein (RNP) complexes that protect the genome and facilitate further replication. The RdRp switches from a transcription mode, which produces subgenomic mRNAs, to a replication mode upon accumulation of soluble protein, enabling the polymerase to ignore transcription stop signals and synthesize full-length copies. In non-segmented negative-strand RNA viruses, such as those in the Mononegavirales order, replication involves iterative synthesis starting from leader and trailer sequences at the genome ends, producing multiple antigenome and genome copies sequentially. In contrast, segmented viruses like perform segment-specific replication, where each genomic segment is independently transcribed and replicated within the . During assembly, the replicated RNPs associate with the matrix (M) protein, which condenses the nucleocapsids and directs them to the plasma where glycoproteins such as are embedded. This interaction drives virion envelopment as the RNPs bud through lipid rafts enriched in viral glycoproteins, with M protein bridging the RNP and envelope components. Virion release occurs primarily through at the plasma , often recruiting host endosomal sorting complexes required for transport () machinery via late-domain motifs in the M protein to mediate membrane scission and final particle detachment. Many negative-strand RNA viruses, including filoviruses via VP40 late domains and some paramyxoviruses, recruit ESCRT machinery through matrix protein motifs for membrane scission; viruses, however, use an ESCRT-independent pathway involving the M2 protein. Post-budding maturation in involves neuraminidase activity to cleave residues, preventing virion aggregation and facilitating release. Replication by the error-prone RdRp, lacking proofreading mechanisms, results in high mutation rates of approximately 10^{-4} to 10^{-5} substitutions per nucleotide per replication cycle, contributing to genetic diversity.

Taxonomy and Phylogeny

Classification into Families

Negative-strand RNA viruses belong to the realm Riboviria and kingdom Orthornavirae, encompassed within the phylum Negarnaviricota, which distinguishes them from positive-sense and double-stranded RNA viruses based on their non-capped, negative-sense single-stranded RNA genomes that require RNA-dependent RNA polymerase for initial transcription. This phylum is further subdivided into classes, orders, and families primarily according to genome segmentation, virion morphology, host range, and conserved replication strategies, as defined by the International Committee on Taxonomy of Viruses (ICTV). The major order Mononegavirales comprises non-segmented, linear genomes typically 10–19 kb in length, infecting vertebrate and invertebrate hosts, with enveloped virions featuring helical nucleocapsids; key families include (e.g., genus containing , bullet-shaped virions), (e.g., genus containing , spherical or pleomorphic enveloped particles), (e.g., genus containing Ebola virus, filamentous morphology), (e.g., genus containing ), and (e.g., genus Bornavirus containing Borna disease virus 1). Additional families in this order, such as and Mypoviridae, primarily infect arthropods or fungi, reflecting host-specific adaptations in envelope glycoproteins and polymerase complexes. Segmented negative-strand RNA viruses, with genomes of 3–10 segments totaling 10–21 kb, are classified in orders like Bunyavirales (promoted from family to order in 2017 and expanded thereafter), which includes ambisense coding in some segments and targets a broad host range from mammals to plants and arthropods; prominent families are Hantaviridae (e.g., genus Orthohantavirus, rodent-borne spherical virions), Peribunyaviridae (e.g., genus Orthobunyavirus, tri-segmented enveloped particles), Nairoviridae (e.g., genus Orthonairovirus, tick-transmitted), Phenuiviridae (e.g., genus Phlebovirus, sandfly- or mosquito-vectored), and Arenaviridae (e.g., genus Mammarenavirus, ambisense segments in rodent-borne viruses like Lassa virus). The order Orthomyxovirales features enveloped viruses with 6–8 segments and helical nucleocapsids, exemplified by the family Orthomyxoviridae (e.g., genus Influenzavirus A containing influenza A virus, pleomorphic spherical or filamentous forms). Plant-infecting negative-strand RNA viruses are grouped in the Articulavirales, with the Fimoviridae (e.g., genus Emaravirus, quadripartite or multipartite genomes in enveloped bacilliform virions transmitted by eriophyid mites). Fungal hosts are represented in orders such as Jingchuvirales and Muvirales, including like Amnoonviridae and the newly established Mymonaviridae (e.g., genera Auricularimonavirus and Botrytimonavirus, non-enveloped or enveloped particles with unsegmented genomes). Arthropod-specific highlight vector roles in . As of 2025, the ICTV's Animal dsRNA and ssRNA(-) Viruses Subcommittee ratified expansions within Negarnaviricota, adding eight new genera and 88 species across existing families in orders like Mononegavirales, , and Jingchuvirales, without major restructuring of higher taxa but emphasizing metagenomic discoveries of novel fungal and invertebrate viruses. Classification criteria continue to prioritize molecular features like nucleoprotein-polymerase interactions alongside morphological and ecological traits to delineate families.

Phylogenetic Relationships

The (RdRp) gene serves as the primary phylogenetic marker for negative-strand RNA viruses due to its high conservation across the group, enabling robust inference of evolutionary relationships even at deep timescales. This conservation is evident in key structural motifs, such as the GDN triad in the of the polymerase palm domain, which facilitates binding and is shared among diverse lineages, allowing alignment-based phylogenies to resolve ancient divergences. Negative-strand RNA viruses form a monophyletic within the , encompassing all viruses that replicate via , with the Negarnaviricota specifically uniting these viruses under a shared evolutionary origin. Phylogenetic analyses of RdRp sequences reveal a basal divergence within Negarnaviricota into non-segmented genomes, which represent the deep-rooted core (e.g., order Mononegavirales), and segmented genomes, which form derived (e.g., orders and Articulavirales). This split reflects early adaptations in genome organization, with non-segmented viruses maintaining a single linear and segmented ones evolving multiple independent segments for packaging efficiency. Homologous recombination is rare in negative-strand RNA viruses, with most reported instances limited to sporadic events in specific genera like hantaviruses, often detectable only through careful sequence alignments that rule out artifacts such as laboratory contamination. In contrast, reassortment is prevalent among segmented lineages, where co-infection allows segment exchange, as evidenced by sequence alignments showing mosaic genomes in influenza A viruses responsible for pandemics like the 1957 Asian flu and 1968 . These reassortment events, confirmed by phylogenetic incongruence across segments, drive rapid antigenic shifts and highlight the role of genetic mixing in segmented clades. Phylogenetic trees of negative-strand RNA viruses exhibit host-specific clades, with distinct branches for vertebrate-infecting lineages (e.g., filoviruses and paramyxoviruses) versus invertebrate-associated ones (e.g., rhabdoviruses in ), reflecting long-term co-evolution with host groups. Cross-kingdom jumps are documented, particularly in the family Tospoviridae (order ), where plant-infecting viruses share RdRp ancestry with arthropod and vertebrate bunyaviruses, suggesting historical host shifts facilitated by insect vectors like . Such transitions underscore the dynamic host range expansions within the phylum, often inferred from sequence similarities bridging animal and plant clades. Molecular clock analyses, calibrated using host fossil records and substitution rates from RdRp alignments, suggest ancient origins for core lineages of Negarnaviricota, aligning with the emergence of multicellular eukaryotes and indicating an origin for the group's foundational . These estimates are challenged by high rates and provide context for the phylum's basal position in phylogenies and its adaptation to early eukaryotic .

Evolution

Origins and Ancient History

Negative-strand RNA viruses are proposed to have evolved from double-stranded RNA (dsRNA) viruses, based on phylogenetic analyses of (RdRp) sequences that reveal monophyly within a broader clade of viruses. Structural homologies in the RdRp core domains, including conserved motifs in the palm subdomain, further support this descent, indicating that negative-strand viruses adapted dsRNA replication mechanisms to produce single-stranded negative-sense genomes. This evolutionary transition likely occurred through and divergence events, with the RdRp of negative-strand viruses showing similarity to those of cystoviruses (a dsRNA virus group) and certain positive-strand viruses. The ancient origins of negative-strand RNA viruses are estimated to predate the radiation of eukaryotic supergroups around 1.5–2 billion years ago, aligning with the emergence of cellular life and the RNA virosphere. Indirect evidence from the comes from metagenomic surveys of environmental samples, which uncover highly divergent negative-strand-like sequences in the virosphere, suggesting persistent ancient lineages associated with early eukaryotes such as protists and . These findings indicate that negative-strand viruses diversified alongside the expansion of eukaryotic hosts, with contributing to their global distribution before the metazoan explosion ~600 million years ago. Co-speciation with hosts provides further insight into their long-term evolutionary history, as phylogenetic patterns show negative-strand viruses mirroring host divergences over hundreds of millions of years. For instance, rhabdoviruses exhibit ancient associations with , predating the split between bony and cartilaginous fishes more than 300 million years ago, reflecting basal diversification in vertebrates. Endogenization events, where viral sequences integrate into host genomes, offer molecular "fossils" of these interactions; bornavirus-like nucleoprotein elements (EBLNs) in mammalian genomes, including and , integrated over 40 million years ago, demonstrating persistent infections and potential host adaptation in mammals. Although speculative, the RdRp enzymes of negative-strand RNA viruses are considered highly diverged relics from the ancient , where self-replicating RNA molecules may have given rise to the first viral polymerases before the advent of DNA-based life. This posits that negative-strand viruses represent an early branch in , bridging primordial RNA replication strategies to modern eukaryotic pathogens.

Mechanisms of Evolution

Negative-strand RNA viruses exhibit exceptionally high mutation rates, primarily due to the error-prone nature of their -dependent polymerases (RdRps), which lack mechanisms, leading to substitution rates typically ranging from 10^{-6} to 10^{-4} substitutions per per cell infection (s/n/c). This intrinsic mutability results in the formation of quasispecies—diverse, dynamic populations of closely related viral variants within a single host—enabling rapid adaptation to selective pressures such as antiviral drugs or host immune responses. For instance, in viruses like influenza A, these quasispecies facilitate the of variants with enhanced fitness, contributing to ongoing across populations. In segmented negative-strand RNA viruses, such as those in the and Bunyaviridae families, reassortment serves as a major mechanism of , where of a host by two distinct strains allows the mixing of genome segments to produce novel progeny viruses. This process can lead to significant genetic shifts, altering viral properties like host range or transmissibility; a prominent example is the 2009 H1N1 pandemic virus, which arose from reassortment of swine, avian, and human influenza segments in pigs, combining the (HA) and neuraminidase (NA) from a North American swine virus with internal genes from Eurasian swine lineages. Such reassortants often exhibit hybrid phenotypes, underscoring reassortment's role in generating evolutionary novelty beyond point mutations. Host jumps in negative-strand RNA viruses frequently involve adaptive evolution of surface glycoproteins, which mediate receptor binding and entry into new host cells, allowing viruses to exploit novel receptors and expand their host range. In (), phylogenetic and selection analyses reveal positive selection pressures on the attachment (), driving mutations that enhance binding to ephrin-B2/B3 receptors in diverse mammals, facilitating bat-to-human transmission and adaptation during outbreaks in . Similarly, for Ebola virus (), mutations in the (), such as A82V, increase in cells by modulating fusion efficiency and immune evasion, as observed in variants dominating the 2013–2016 West African , highlighting glycoprotein evolution's key role in cross-species adaptation. Antigenic drift and shift further drive evolution in negative-strand RNA viruses like influenza A, where incremental HA mutations (drift) accumulate in immunodominant epitopes, enabling immune escape and gradual antigenic change, while major shifts occur via reassortment of HA/NA segments, rapidly altering surface antigens to evade population immunity. These HA mutations, often in the receptor-binding site or globular head, reduce antibody recognition without compromising receptor , sustaining seasonal epidemics; for example, substitutions like those at positions 156 and 164 in H3N2 HA clusters have been linked to annual mismatches. Drift predominates in stable host populations, whereas shifts, exemplified by the 2009 H1N1 event, can precipitate pandemics by introducing novel antigens. Metagenomic surveys have uncovered novel lineages of negative-strand RNA viruses in uncultured environmental samples, revealing hidden that expands our understanding of their evolutionary potential. For instance, deep sequencing of transcriptomes has identified over 100 previously unknown negative-sense viruses, including mononegaviral-like elements in and crustaceans, suggesting ancient divergences and untapped reservoirs that could fuel future host jumps or adaptations. These discoveries, often from or microbiomes, highlight how uncultured niches harbor with unique genomic architectures, driving broader phylogenetic innovation. As of 2025, ongoing metagenomic surveys have continued to identify novel negative-strand viruses in diverse hosts, including and , underscoring the expanding evolutionary landscape.

Clinical and Biological Significance

Associated Diseases

Negative-strand RNA viruses are responsible for a wide array of diseases affecting humans, animals, and plants, often leading to significant morbidity and mortality worldwide. In humans, these viruses cause both endemic and epidemic illnesses, with notable examples including influenza viruses from the family Orthomyxoviridae, which trigger seasonal respiratory infections and periodic pandemics. The 1918 influenza pandemic, caused by an H1N1 strain, resulted in an estimated 50 million deaths globally. Rabies virus, a member of the Rhabdoviridae family, induces fatal encephalitis following bites from infected animals, with nearly 100% mortality once clinical symptoms appear. Measles virus, from the Paramyxoviridae family, leads to acute respiratory illness and prolonged immunosuppression, contributing to secondary infections in affected individuals. Ebola virus, classified in the Filoviridae family, causes severe hemorrhagic fever with case fatality rates often exceeding 50%. The 2014–2016 West Africa outbreak of Ebola virus disease infected over 28,600 people and resulted in 11,325 deaths. Lassa virus, from the Arenaviridae family, causes Lassa fever, an acute viral hemorrhagic illness endemic to West Africa with approximately 100,000–300,000 cases and 5,000 deaths annually as of recent estimates. Respiratory syncytial virus (RSV), in the Pneumoviridae family, primarily affects infants, causing bronchiolitis and pneumonia that can lead to hospitalization in vulnerable populations; however, as of 2025, vaccines such as Arexvy and Abrysvo are recommended for adults aged 60 and older, and maternal immunization or monoclonal antibodies for infants, reducing severe disease incidence. In animals, negative-strand RNA viruses cause economically devastating diseases, such as canine distemper virus from the Paramyxoviridae family, which affects dogs and other carnivores, leading to multisystemic illness with high mortality rates in unvaccinated populations. Newcastle disease virus, also in the Paramyxoviridae family, infects birds, particularly poultry, resulting in respiratory and neurological symptoms that cause significant losses in the avian industry. Plant diseases from these viruses impact agriculture, exemplified by tomato spotted wilt virus in the Tospoviridae family, which infects over 1,000 plant species, causing , , and substantial crop yield reductions in tomatoes and other solanaceous plants. Many negative-strand RNA viruses exhibit zoonotic potential, with henipaviruses such as from the family emerging from bat reservoirs to cause in humans, often through intermediate hosts like pigs or direct contact with contaminated fruit.

Host Interactions and Pathogenesis

Negative-strand RNA viruses initiate infection through specific receptor-binding interactions that facilitate attachment to host cells, followed by entry via or direct membrane fusion. For instance, binds to terminal residues on host cell surface glycans, enabling and subsequent low-pH-induced fusion in endosomes. Similarly, interacts with nicotinic receptors (nAChR), particularly the α1 subunit, to promote clathrin-mediated and pH-dependent fusion, allowing axonal entry into neurons. These mechanisms underscore the diversity in entry pathways among negative-strand viruses, where surface glycoproteins dictate host cell specificity and . To establish productive infection, these viruses employ sophisticated strategies to evade the host innate immune response, particularly by antagonizing interferon signaling and inhibiting apoptosis. In paramyxoviruses, the V protein plays a central role in immune evasion by binding to STAT1 and MDA5, thereby blocking JAK-STAT pathway activation and preventing type I interferon production. Many negative-strand RNA viruses also inhibit host cell apoptosis to prolong viral replication; for example, influenza A virus NS1 protein suppresses caspase activation and pro-apoptotic signaling, while Ebola virus VP24 sequesters karyopherin α to disrupt interferon-induced gene expression and delay cell death. These evasion tactics allow viruses to replicate unchecked in the early phases of infection, minimizing immune detection. Pathogenesis arises from a combination of direct cytopathic effects and indirect immune-mediated damage. Cytopathic effects often manifest as leading to formation, as seen in virus, where the (F) and (H) proteins induce membrane between infected and neighboring cells, amplifying viral spread and contributing to tissue destruction. In contrast, immune-mediated pathogenesis, such as the in virus infection, results from excessive proinflammatory cytokine release (e.g., TNF-α, IL-6) triggered by viral interactions with immune cells, leading to vascular leakage and without widespread direct . This duality highlights how negative-strand viruses balance direct cellular disruption with host immune dysregulation to drive progression. Tissue tropism is governed by receptor distribution and viral glycoprotein affinities, directing infection to specific anatomical sites. Respiratory syncytial virus (RSV) preferentially targets ciliated epithelial cells in the airway via the G protein binding to heparan sulfate or integrins, causing mucosal inflammation and impaired clearance. Rabies virus exhibits strong neuronal tropism, entering via nAChR at neuromuscular junctions and retrogradely transporting along axons to the central nervous system, evading immune surveillance in neural tissue. Filoviruses like Ebola demonstrate vascular tropism, with glycoprotein binding to endothelial cells via DC-SIGN or integrins, disrupting barrier integrity and promoting hemorrhage. Some negative-strand viruses establish or persistent infections, integrating into nuclear processes without immediate . Borna disease virus (BDV), for example, persists lifelong in the nuclei of infected neurons, maintaining a non-cytolytic state through regulated transcription and evasion of antiviral responses, leading to chronic neurological alterations over acute disease. This persistent lifecycle contrasts with lytic replication in many family members, enabling long-term and potential reactivation.

History of Research

Early Discoveries

The of in the late marked one of the earliest scientific recognitions of a negative-strand , though its molecular nature remained unknown for decades. In 1885, and colleagues developed the first effective by passaging the virus through rabbits, confirming its transmissible, filterable agent status and enabling controlled studies of the disease. The viral etiology had been suspected since ancient times, but Pasteur's work provided the foundational experimental framework for . The composition of was not established until 1963, when biochemical analyses identified it as a single-stranded agent within the family. Advancements in the 1930s revolutionized virus propagation and identification, particularly for , later identified as the first recognized segmented negative-strand RNA virus. In 1931, pathologist Ernest Goodpasture introduced a method for cultivating uncontaminated viruses in the chorioallantoic membranes of fertile eggs, overcoming limitations of models and enabling large-scale production. This technique facilitated the 1933 isolation of human virus by Wilson Smith, Christopher Andrewes, and Patrick using ferrets, with subsequent adaptation to egg-based systems that became standard for research and development. Indirectly, Peyton Rous's 1911 discovery of the —an RNA tumor-inducing agent in s—highlighted the oncogenic potential of viruses, spurring broader interest in despite its retroviral classification. The 1950s brought morphological insights through electron microscopy, revealing the distinctive bullet-shaped virions of rhabdoviruses, a hallmark of non-segmented . Vesicular stomatitis virus, isolated in from infected horses, was among the first extensively studied due to its propagation in cell cultures, but its enveloped, rod-like structure with helical nucleocapsids was visualized in the mid-1950s. A 1958 electron microscopy study of rabies-infected mouse brain cells confirmed similar rod-shaped particles approximately 180 nm long and 75 nm wide, cross-striated due to ribonucleoprotein packaging, distinguishing these viruses from earlier rod-like plant pathogens like , which was later confirmed as positive-sense in 1956. The 1957 Asian highlighted antigenic shift, later understood to result from reassortment of the segmented genome of orthomyxoviruses, consisting of eight negative-sense segments. By the 1960s and 1970s, molecular characterizations solidified the negative-sense polarity of these viruses. The RNA nature of was biochemically verified in 1963, aligning it with emerging data on other rhabdoviruses. In 1971, proposed a seminal system for viruses based on mRNA synthesis pathways, designating negative-strand RNA viruses (including rhabdoviruses and orthomyxoviruses) as Group V due to their non-infectious, antisense genomes requiring viral for transcription. This was supported by hybridization experiments in the 1970s, such as those using vesicular stomatitis virus, where genomic RNA formed hybrids with newly synthesized positive-sense mRNA, confirming the complementary negative polarity and distinguishing it from positive-strand counterparts. The International Committee on Taxonomy of Viruses (ICTV) formalized this grouping in 1991 by establishing the order Mononegavirales for non-segmented negative-strand RNA viruses, encompassing families like and . In the 1970s, polyacrylamide gel electrophoresis confirmed the eight-segmented genome of viruses.

Key Developments and Current Research

In the 1980s and 1990s, significant advances in enabled the and manipulation of negative-strand RNA virus genomes, overcoming challenges posed by their non-infectious RNA templates. A pivotal development was the establishment of systems, which allow the generation of infectious viruses from cDNA. The first such system for a negative-strand RNA virus was achieved for vesicular stomatitis virus (VSV) in 1995, using a plasmid-based approach with T7 to transcribe full-length antigenome , co-expressed with viral , , and . This breakthrough facilitated studies on and . Similarly, in 1994, a system for was developed, enabling the recovery of recombinant viruses and paving the way for design and studies. The 2000s saw rapid progress in genomic sequencing and outbreak responses for emerging negative-strand RNA viruses. Full genome sequencing of Ebola virus, initially isolated in 1976, was completed in the early 1990s, but high-throughput sequencing technologies in the 2000s enabled detailed phylogenetic analyses and identification of variants during outbreaks, such as the 2000-2001 Uganda epidemic. The 1998-1999 Nipah virus outbreak in Malaysia highlighted the zoonotic potential of paramyxoviruses, leading to its identification as a novel through electron microscopy and sequencing within months, informing subsequent surveillance in bat reservoirs. These events spurred international collaborations, including the Henipavirus Ecology Research Group to study spillover risks. Vaccine and antiviral development has accelerated since the late , building on earlier foundations. The live-attenuated , licensed in 1963, continues to undergo efficacy evaluations; a 2016 confirmed two-dose regimens achieve 95% protection against in diverse populations, driving global eradication efforts. In the 2020s, platforms have been adapted for negative-strand RNA viruses, with Moderna's mRNA-1010 entering phase 3 trials in 2022, demonstrating robust antibody responses comparable to licensed vaccines. For , CureVac's mRNA (CV7202) in phase 1 trials (2018-2020) elicited strong immune responses, with up to 100% at higher doses. Current research as of 2025 emphasizes , gene editing, and predictive modeling to combat these viruses. has refined rescue systems, allowing de novo synthesis of entire viral genomes for studying paramyxovirus assembly. CRISPR-Cas9 editing has been applied to negative-strand RNA viruses, with 2024 studies using it to disrupt the A polymerase complex in cultures, reducing replication by over 90% and highlighting antiviral potential. Metagenomic surveys have uncovered novel bunya-like viruses, such as the 2023 discovery of Beilong parainfluenza virus 5-like agents in bats, expanding the family and underscoring environmental surveillance needs. preparedness for filoviruses has intensified, with the (CEPI) funding stockpiles and pan-ebolavirus vaccines in phase 2 trials by 2025. As of 2025, CEPI has advanced Nipah mRNA vaccines to phase 3 trials. Additionally, AI tools like have predicted structures of RNA-dependent RNA s (RdRps) from viruses such as , revealing conserved motifs for inhibitor design with atomic accuracy validated in 2024 cryo-EM studies.

References

  1. [1]
    Developments in Negative-Strand RNA Virus Reverse Genetics - PMC
    Mar 11, 2024 · Negative-stranded RNA viruses share common characteristics, such as being enveloped viruses, having linear and cyclic morphology, and ...Missing: definition | Show results with:definition
  2. [2]
    Structure and Classification of Viruses - Medical Microbiology - NCBI
    The viral RNA may be single-stranded (ss) or double-stranded (ds), and the genome may occupy a single RNA segment or be distributed on two or more separate ...
  3. [3]
    Introduction to RNA Viruses - PMC - PubMed Central
    The definition of an RNA virus. • The subgroups within the RNA virus group (positive strand, negative strand, ambisense, and double strand) and the differences ...
  4. [4]
    The Baltimore Classification of Viruses 50 Years Later
    Fifty years ago, David Baltimore published a brief conceptual paper delineating the classification of viruses by the routes of genome expression.
  5. [5]
    Virus taxonomy and the role of the International Committee on ... - NIH
    The ICTV upholds the distinction between a virus or replicating genetic element as a physical entity and the taxon category to which it is assigned. This is ...
  6. [6]
    Structural insights into RNA polymerases of negative-sense ... - Nature
    Jan 25, 2021 · In this Review, we compare recent high-resolution X-ray and cryoelectron microscopy structures of RNA polymerases of negative-sense RNA viruses.Missing: general | Show results with:general
  7. [7]
    Negative and ambisense RNA virus ribonucleocapsids - ASM Journals
    Sep 26, 2023 · The genomes of negative sense RNA viruses consist of single-stranded RNA that can be segmented or non-segmented.
  8. [8]
    Negative-sense RNA viruses: An underexplored platform for ...
    Oct 1, 2021 · This perspective primarily focuses on the negative-sense RNA viruses from the order Mononegavirales, which obtain their lipid envelope from the host plasma ...Missing: classification | Show results with:classification<|separator|>
  9. [9]
    https://www.annualreviews.org/doi/full/10.1146/annurev-virology-111821-102603
  10. [10]
    Structures & Mechanisms of Nonsegmented RNA Virus Polymerases
    Sep 29, 2023 · The nonsegmented, negative-strand RNA viruses (nsNSVs), also known as the order Mononegavirales, have a genome consisting of a single strand ...
  11. [11]
    Nucleocapsid Structure of Negative Strand RNA Virus - MDPI
    All viruses assemble a nucleocapsid. The capsid consists of viral proteins and encloses the nucleotide genome of the virus.Nucleocapsid Structure Of... · 2. The Capsid Protein Fold · 4. Viral Rna Synthesis<|control11|><|separator|>
  12. [12]
    The Nucleocapsid of Paramyxoviruses: Structure and Function of an ...
    Dec 9, 2021 · This ribonucleoprotein complex, termed a nucleocapsid, is the template of the viral polymerase complex made of the large protein (L) and its co-factor, the ...
  13. [13]
    Family: Rhabdoviridae - ICTV
    The family Rhabdoviridae includes four subfamilies, 56 genera and 434 species for viruses with negative-sense, single-stranded RNA genomes of approximately 10– ...Genus: Lyssavirus · Genus: Vesiculovirus · Genus: Almendravirus · Rhabdoviridae
  14. [14]
    Rhabdoviridae - ViralZone
    VIRION. Enveloped, bullet shaped. 180 nm long and 75 nm wide. Certain plant rhabdoviruses are bacilliform in shape and almost twice the length.
  15. [15]
    Family: Bornaviridae - ICTV
    Virions are enveloped, appear to carry small spikes (7 nm) and are believed to bud from host-cell membranes (Zimmermann et al., 1994, Kohno et al., 1999).
  16. [16]
    https://ictv.global/report/chapter/bornaviridae/bornaviridae
  17. [17]
    https://doi.org/10.3389/fmicb.2019.01490
  18. [18]
    https://doi.org/10.1038/s41579-020-00501-8
  19. [19]
    https://doi.org/10.1016/j.molcel.2006.11.013
  20. [20]
    https://doi.org/10.1006/viro.2001.1150
  21. [21]
    https://doi.org/10.1038/nature14009
  22. [22]
    https://doi.org/10.1016/0092-8674(81)90143-4
  23. [23]
    https://doi.org/10.1073/pnas.73.4.1504
  24. [24]
    https://doi.org/10.1128/JVI.00990-12
  25. [25]
    https://doi.org/10.1016/j.virol.2015.03.018
  26. [26]
    Current ICTV Taxonomy Release
    This taxonomy browser provides access to the current virus taxonomy. This page will be updated whenever a new taxonomy release has been approved by the ICTV.Visual Taxonomy Browser · Using the Taxonomy Browser · Taxon Details · GenomeMissing: Negarnaviricota | Show results with:Negarnaviricota
  27. [27]
    Changes to virus taxonomy and the ICTV Statutes ratified by the ...
    Nov 3, 2024 · This article reports changes to virus taxonomy and taxon nomenclature that were approved and ratified by the International Committee on Taxonomy of Viruses ( ...
  28. [28]
    Promotion of order Bunyavirales to class Bunyaviricetes to ...
    Sep 20, 2024 · In 2017, the International Committee on Taxonomy of Viruses (ICTV) promoted the family to order Bunyavirales and subsequently greatly expanded its composition.
  29. [29]
    ICTV Virus Taxonomy Profile: Fimoviridae 2024 - PMC - NIH
    Members of the family Fimoviridae are plant viruses with a multipartite negative-sense enveloped RNA genome (−ssRNA), composed of 4–10 segments comprising 12.3 ...
  30. [30]
    Family: Mymonaviridae - ICTV
    At least one virus, Sclerotinia sclerotiorum negative-stranded RNA virus 1, induces hypovirulence in its fungal host.Missing: term | Show results with:term
  31. [31]
    The Plant Negative-Sense RNA Virosphere: Virus Discovery ...
    Sep 15, 2020 · In this review, we consider the application of HTS approaches to uncover novel plant viruses with a focus on the negative-sense, single-stranded RNA virosphere.
  32. [32]
    Viruses Subcommittee, 2025 - PMC - NIH
    Summary of taxonomy changes ratified by the International Committee on Taxonomy of Viruses (ICTV) from the Animal dsRNA and ssRNA(−) Viruses Subcommittee, 2025.
  33. [33]
    RNA Dependent RNA Polymerases: Insights from Structure ...
    Feb 10, 2018 · RdRp is the most conserved gene in RNA viruses that is ideally suited to understand their evolutionary patterns [100,101]. The molecular ...
  34. [34]
    How does the polymerase of non-segmented negative strand RNA ...
    Jul 30, 2024 · This review examines the biochemical, molecular biology, and structural biology data regarding the first steps of transcription and RNA replication
  35. [35]
    A Glimpse on the Evolution of RNA Viruses - NIH
    The original Baltimore classification placed viruses into one of six classes—class I (double-stranded DNA genome, (+/−) dsDNA), class II (single-stranded DNA ...
  36. [36]
    [PDF] A five-fold expansion of the global RNA virome reveals multiple new ...
    Feb 17, 2022 · By contrast, the phyla Duplornaviricota (double-stranded RNA viruses) and. Negarnaviricota (negative-strand RNA viruses) remained largely stable ...
  37. [37]
    Structure Unveils Relationships between RNA Virus Polymerases
    We used an automated structural comparison method, homologous structure finder, for comprehensive comparisons of viral RNA-dependent RNA polymerases (RdRps).
  38. [38]
    Homologous Recombination in Negative Sense RNA Viruses - PMC
    In this review, we focus on homologous recombination that involves two similar or closely related RNA molecules with extensive sequence homology.
  39. [39]
    Reassortment in segmented RNA viruses: mechanisms and outcomes
    The observation that no family members have 13 or more segments may be a reflection of the packaging process and the icosahedral capsid architecture.
  40. [40]
    Parallel evolution between genomic segments of seasonal human ...
    Aug 27, 2021 · Each of the last three influenza pandemics was attributable to a reassortant strain composed of a novel combination of the eight viral RNA (vRNA) ...
  41. [41]
    The diversity, evolution and origins of vertebrate RNA viruses - PMC
    Aug 13, 2018 · That some RNA viruses seemingly only infect vertebrates suggest that they are 'vertebrate-specific' viruses, while another 'vector-borne' class ...
  42. [42]
    Negative-strand RNA viruses: the plant-infecting counterparts
    While a large number of negative-strand (-)RNA viruses infect animals and humans, a relative small number have plants as their primary host.
  43. [43]
    Re-assessing the diversity of negative strand RNA viruses in insects
    Dec 12, 2019 · Here, we systematically probed the diversity of negative strand RNA viruses in the largest and most representative collection of insect transcriptomes.<|control11|><|separator|>
  44. [44]
    Cryptic and abundant marine viruses at the evolutionary origins of ...
    Apr 7, 2022 · Because the gene encoding RdRp is ancient, thought to be among the first genes of the peptide-RNA world (10–12), it serves as a deep ...
  45. [45]
    Origins and Evolution of the Global RNA Virome | mBio
    Summary of each segment:
  46. [46]
    Origins and Evolution of the Global RNA Virome - PubMed Central
    For instance, the members of the ICTV-approved order Bunyavirales are called bunyaviruses, whereas those of the family Tombusviridae are called tombusviruses.
  47. [47]
    Endogenous non-retroviral RNA virus elements in mammalian genomes - Nature
    ### Summary of Bornavirus-Like Elements in Mammalian Genomes
  48. [48]
    The ancient Virus World and evolution of cells | Biology Direct
    Sep 19, 2006 · The RdRps of dsRNA viruses and negative-strand RNA viruses are likely to be highly diverged derivatives of the same polymerase domain, an old ...Missing: endogenization | Show results with:endogenization
  49. [49]
    Complexities of Viral Mutation Rates | Journal of Virology
    Jun 29, 2018 · RNA viruses, however, have higher mutation rates that range between 10−6 and 10−4 s/n/c (Fig. 1). Despite variable per-site rates, species with ...
  50. [50]
    Quasispecies Nature of RNA Viruses: Lessons from the Past - NIH
    Jan 30, 2023 · The mutability of RNA viruses is around a million-fold higher than standard mutation rates operating in cellular DNA and is an established facet ...
  51. [51]
    Quasispecies theory and emerging viruses: challenges and ... - Nature
    Nov 14, 2024 · Viral populations are characterized by high mutation rates due to the limited template-copying fidelity of RNA-dependent RNA polymerases (RdRp) ...
  52. [52]
    Origins and evolutionary genomics of the 2009 swine-origin H1N1 ...
    Jun 11, 2009 · A phylogenetic analysis of swine-origin H1N1 influenza A virus provides evidence that the virus is a reassortment possessing genes from ...
  53. [53]
    Genetics of the Influenza Virus | Learn Science at Scitable - Nature
    For example, when a cell is infected with influenza viruses from different species, reassortment can result in progeny viruses that contain genes from strains ...
  54. [54]
    Identifying genetic markers of adaptation for surveillance of viral host ...
    Oct 12, 2010 · Host-jump mechanisms. There are different ecological and evolutionary processes involved in viral host jumps (Fig. 1). If the primary factor ...
  55. [55]
    Emergence and adaptive evolution of Nipah virus - PMC
    Here, we combined phylogenetic with selection analysis and structural biology to understand the role of different NiV lineages in interspecies transmission and ...
  56. [56]
    The evolution of seasonal influenza viruses - Nature
    Oct 30, 2017 · ... virus variants, whereas adaptive immunity selects for immune escape mutants ... mutations in these positions must cause antigenic change ...<|separator|>
  57. [57]
    Antigenic drift expands influenza viral escape pathways ... - PubMed
    Mar 11, 2025 · We identified escape mutations from clonal antibody lineages that targeted the receptor binding site and lateral patch. By adjusting the antigen ...
  58. [58]
    How Flu Viruses Can Change: "Drift" and "Shift" - CDC
    Sep 17, 2024 · One way flu viruses change is called "antigenic drift." Drift consists of small changes (or mutations) in the genes of influenza viruses ...
  59. [59]
    Unprecedented genomic diversity of RNA viruses in arthropods ...
    Jan 29, 2015 · We discovered 112 novel viruses that appear to be ancestral to much of the documented genetic diversity of negative-sense RNA viruses.Missing: nomenclature | Show results with:nomenclature
  60. [60]
    Doubling of the known set of RNA viruses by metagenomic analysis ...
    Jul 20, 2020 · Branch 4 consists of diverse dsRNA viruses, including the large families Reoviridae and Totiviridae, and the only known family of prokaryotic ...
  61. [61]
    Meta-transcriptomics and the evolutionary biology of RNA viruses
    Oct 27, 2017 · Meta-transcriptomics (bulk RNA-Seq) is a powerful new way to characterise viromes. Meta-transcriptomic data are changing our understanding of virus evolution.
  62. [62]
    History of 1918 Flu Pandemic - CDC Archive
    The number of deaths was estimated to be at least 50 million worldwide with about 675,000 occurring in the United States. Mortality was high in people younger ...
  63. [63]
    Minus-Strand RNA Viruses - PMC - PubMed Central
    Seven families of viruses contain minus-strand RNA [(−)RNA], also called negative-strand RNA, as their genome. These are listed in Table 4.1.
  64. [64]
    Ebola outbreak 2014-2016 - West Africa
    More than 28 600 people had been infected and 11 325 people had died. Disease outbreak news - start of the outbreak · Emergency List. Ebola ...
  65. [65]
    Overview of Viruses - Infectious Diseases - Merck Manuals
    Negative-sense RNA viruses possess a single-stranded negative-sense genome ... Ebola virus infection, respiratory syncytial virus [RSV], rabies virus).
  66. [66]
    9.9A: Negative-Strand RNA Viruses of Animals - Biology LibreTexts
    Nov 23, 2024 · The RNA found in a negative-sense virus is not infectious by itself, as it needs to be transcribed into positive-sense RNA. The complementary ...
  67. [67]
    Rescue of tomato spotted wilt virus entirely from complementary ...
    Jan 14, 2020 · Tomato spotted wilt virus (TSWV) is one of the most important plant NSVs, infecting more than 1,000 plant species, and poses major threats to ...
  68. [68]
    Nipah and Hendra Viruses: Deadly Zoonotic Paramyxoviruses ... - NIH
    Nov 25, 2022 · The natural reservoirs of NiV and HeV are bats (flying foxes) in which the virus infection is asymptomatic. The intermediate hosts for NiV and ...
  69. [69]
    Influenza Virus Entry - PMC - PubMed Central
    The receptor molecule for influenza virus is a terminal α-sialic acid that is linked to saccharides anchored on the host cell surface by various mechanisms.
  70. [70]
    Rabies virus receptors - PubMed
    ... (nAChR), the neuronal cell adhesion molecule (NCAM), and the p75 neurotrophin receptor (p75NTR) bind rabies virus and/or facilitate rabies virus entry into cells
  71. [71]
    Antagonism of Innate Immunity by Paramyxovirus Accessory Proteins
    Available evidence indicates that paramyxoviruses employ specific strategies to antagonize the IFN response of their specific hosts, which is one of the major ...
  72. [72]
    Interplay between Innate Immunity and Negative-Strand RNA Viruses
    Ebolavirus is internalized into host cells via macropinocytosis in a viral glycoprotein-dependent manner. ... stranded RNA render Ebola virus avirulent in guinea ...
  73. [73]
    Cell-Cell Fusion Induced by Measles Virus Amplifies the Type I ... - NIH
    Wild-type measles virus induces large syncytium formation in primary human small airway epithelial cells by a SLAM(CD150)-independent mechanism. Virus Res.
  74. [74]
    Molecular mechanisms of Ebola virus pathogenesis: focus on cell ...
    May 29, 2015 · The EBOV first attacks macrophages and dendritic immune cells. The innate immune reaction is characterized by a cytokine storm, with secretion ...
  75. [75]
    Respiratory Syncytial Virus Infection of Human Airway Epithelial ...
    Our studies show that RSV preferentially targets the ciliated cells of the airway epithelium and that infection (and subsequent virus release) occurs ...
  76. [76]
    Everything you always wanted to know about Rabies Virus (but were ...
    The cellular tropism of RABV, for example, is thought to be determined by the virus' ability to bind to at least two cell surface targets specific to neurons, ...1). Rabies Virus Taxonomy... · 5). Rabv Axonal Transport · 8). Rabv Immune Evasion
  77. [77]
    Intracellular Events and Cell Fate in Filovirus Infection - MDPI
    Filoviruses have a broad cell tropism in susceptible host species. Among the ... Moreover, GP expression in explanted blood vessels resulted in endothelial cell ...
  78. [78]
    Varied Persistent Life Cycles of Borna Disease Virus in a Human ...
    Viral persistence or latency is a mechanism adapted by the virus for the maintenance of the viral genome in infected cells. In dividing cells, there must be ...
  79. [79]
    Rabies vaccines: Journey from classical to modern era - ScienceDirect
    It was established that the rabies virus contains RNA in 1963 (Whitley et al., 1997). While the rabies virus had been successfully transmitted to ...
  80. [80]
    PRESIDENT'S ADDRESS: VIROLOGY THROUGH THE LENS OF ...
    Important advances in animal and human virology came from the development of embryonic chicken egg cultures for virus propagation by Woodruff and Goodpasture ( ...
  81. [81]
    The History of Tumor Virology - PMC - PubMed Central
    Peyton Rous founded this scientific field in 1911 by discovering an avian virus that induced tumors in chickens.
  82. [82]
    ELECTRON MICROSCOPE STUDIES OF RABIES VIRUS IN ... - NIH
    The cells of brains of 2- and 3-day old mice infected with street rabies virus were examined in the electron microscope.
  83. [83]
    Influenza Virus Evolution, Host Adaptation and Pandemic Formation
    Influenza viruses (family Orthomyxoviridae) are enveloped negative-strand RNA viruses with segmented genomes containing seven to eight gene segments. The ...
  84. [84]
    Taxonomy of the order Mononegavirales: update 2019 - PMC - NIH
    The virus order Mononegavirales was established in 1991 to accommodate related viruses with nonsegmented, linear, single-stranded, negative-sense RNA genomes ...