Feline fecal virome reveals novel and prevalent enteric viruses

Ng, Terry Fei Fan; Mesquita, João R.; Nascimento, María Säo José; Kondov, Nikola O.; Wong, Walt; Reuter, Gábor; Knowles, Nick J.; Vega, Everardo; Esona, Mathew D.; Deng, Xutao; Vinjé, Jan; Delwart, Eric

doi:10.1016/j.vetmic.2014.04.005

Cited by 95 publications

(148 citation statements)

References 33 publications

(47 reference statements)

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“…BLAST searches identified 47–102 nt-long elements with 64–74% identity to the FHMPV 5’UTR in the 5’UTRs of porcine sapelovirus 1, bat picornavirus 2 (BPV-2), Feline sakobuvirus A (SakV-A1) and Ia io picornavirus 1 (IiPV-1). These 5’UTRs contain Type IV IRES structures (Hellen and de Breyne, 2007; Lau et al, 2011, 2012; Ng et al, 2014), and the sequence homology with them maps to domain IIIe and flanking regions. A shorter (11–14nt-long) segment of the FHMPV 5’UTR matched precisely to domain IIIe in the Type IV IRESs of avian encephalomyelitis virus (AEV), duck hepatitis A virus 1 (DHAV-1) and Pigeon picornavirus B (PiPV-B) (Hellen and de Breyne, 2007; Kofstad and Jonassen, 2011) and to segments of the 5’UTRs of California sea lion sapelovirus 1 (Csl SapV-1), Ferret parechovirus (FPV) and Pasivirus 1 (PaV-A1).…”

Section: Resultsmentioning

confidence: 99%

“…The sole Type III IRES occurs in Hepatitis A virus (genus Hepatovirus )(Brown et al, 1994); Type V IRESs were recently identified in members of the genera Kobuvirus, Salivirus , and Oscivirus (Yu et al, 2011; Sweeney et al, 2012). Type IV IRESs were discovered in Hepatitis C virus (HCV) and Classical swine fever virus (CSFV), members of the genera Hepacivirus and Pestivirus of Flaviviridae , but have subsequently also been identified in several picornavirus genera, including Aquamavirus, Avihepatovirus, Kobuvirus, Megrivirus, Sapelovirus, Senecavirus, Teschovirus , and Tremovirus (Pisarev et al, 2004; Chard et al, 2006a; Hellen and de Breyne, 2007; Kapoor et al, 2008; Reuter et al, 2009; Honkavuori et al, 2011), in the proposed genera Aalivirus (Wang et al, 2014), Anativirus (duck picornavirus TW90A; Hellen and de Breyne, 2007; Tseng and Tsai, 2007), Colbovirus (pigeon picornavirus A (PiPV-A) and PiPV-B; Kofstad and Jonassen, 2011), Kunsagivirus (Boros et al, 2013), Phacovirus (quail picornavirus 1 (QPV-1); Pankovics et al, 2012) and Sakobuvirus (Ng et al, 2014), and in other species, including Bat picornavirus 1 (BPV-1), BPV-2 (Lau et al, 2011) and feline picornavirus 1 (FePV-1)(Lau et al, 2012), that have been provisionally assigned to the genus Sapelovirus .…”

Section: Introductionmentioning

confidence: 99%

“…The picornavirus type IV IRESs identified to date all contain the PK-IIId-IIIe core, including an apical GGG motif in domain IIId and a GA[U/C]A tetraloop in domain IIIe, but apical elements of domain III may be truncated or even absent. Domain II contains an internal loop near its base that enables it to switch between bent and extended conformations, and a ‘loop E’ motif (Lukavsky et al, 2003; Hellen and de Breyne, 2007; Boerneke et al, 2014; Ng et al, 2014; Wang et al, 2014). Very few picornavirus type IV IRESs contain an equivalent of domain IV (Hellen and de Breyne, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Widespread distribution and structural diversity of Type IV IRESs in members of Picornaviridae

2015

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Picornavirus genomes contain internal ribosomal entry sites (IRESs) that promote end-independent translation initiation. Five structural classes of picornavirus IRES have been identified, but numerous IRESs remain unclassified. Here, previously unrecognized Type IV IRESs were identified in members of three proposed picornavirus genera (Limnipivirus, Pasivirus, Rafivirus) and four recognized genera (Kobuvirus, Megrivirus, Sapelovirus, Parechovirus). These IRESs are ∼230–420 nucleotides long, reflecting heterogeneity outside a common structural core. Closer analysis yielded insights into evolutionary processes that have shaped contemporary IRESs. The presence of related IRESs in diverse genera supports the hypothesis that they are heritable genetic elements that spread by horizontal gene transfer. Recombination likely also accounts for the exchange of some peripheral subdomains, suggesting that IRES evolution involves incremental addition of elements to a pre-existing core. Nucleotide conservation is concentrated in ribosome-binding sites, and at the junction of helical domains, likely to ensure orientation of subdomains in an active conformation.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Widespread distribution and structural diversity of Type IV IRESs in members of Picornaviridae

2015

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“…Among these, RVH strains have been identified in humans in parts of Asia and in pigs in Asia and the Americas; however, no genetic relationship among human and porcine strains were reported [136][137][138]. RVI is a putative novel rotavirus species, which has been detected in cats and dogs in Europe and in a feral sea lion in the USA [139][140][141]. Because cats and dogs are thought to be the sources of human infections with RVA, closer monitoring for the zoonotic potential of RVI will be needed.…”

Section: Evidence and Mechanisms Of Rotavirus Zoonosismentioning

confidence: 99%

Zoonotic transmission of rotavirus: surveillance and control

Dóró

Farkas

Martella

et al. 2015

Expert Review of Anti-infective Therapy

110

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Group A rotavirus (Rotavirus A, RVA) is the main cause of acute dehydrating diarrhea in humans and numerous animal species. RVA shows vast diversity and a variety of human strains share genetic and antigenic features with animal origin RVA strains. This finding suggests that interspecies transmission is an important mechanism of rotavirus evolution and contributes to the diversity of human RVA strains. RVA is responsible for half a million deaths and several million hospitalizations worldwide. Globally, two rotavirus vaccines are available for routine use in infants. These vaccines show a great efficacy profile and induce protective immunity against various rotavirus strains. However, little is known about the long-term evolution and epidemiology of RVA strains under selective pressure related to vaccine use. Continuous strain surveillance in the post-vaccine licensure era is needed to help better understand mechanisms that may affect vaccine effectiveness.

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“…The advent of highthroughput sequencing technology has enabled comprehensive approaches for the simultaneous detection of many viral genomes and the identification of unknown viral genomes without viral isolation (Firth & Lipkin, 2013). Using high-throughput sequencing, viral metagenomics approaches have elucidated whole enteric viromes, resulting in the discovery of unknown viruses in a variety of mammals, including non-human primates, bats, pigs, rodents, cats, sea lions, martens, badgers, foxes, ferrets and pigeons (Baker et al, 2013;Bodewes et al, 2013;Dacheux et al, 2014;Donaldson et al, 2010;Ge et al, 2012;Handley et al, 2012;Li et al, 2010bLi et al, , 2011bNg et al, 2014;Phan et al, 2011Phan et al, , 2013aShan et al, 2011;Smits et al, 2013a;van den Brand et al, 2012;Wu et al, 2012). Further molecular characterization has revealed high nucleotide sequence diversity and unique genome organization of novel viruses (Boros et al, , 2013Li et al, 2010a;Phan et al, 2013b;Sauvage et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Metagenomic analysis of the shrew enteric virome reveals novel viruses related to human stool-associated viruses

Sasaki

Orba

Ueno

et al. 2015

Journal of General Virology

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Shrews are small insectivorous mammals that are distributed worldwide. Similar to rodents, shrews live on the ground and are commonly found near human residences. In this study, we investigated the enteric virome of wild shrews in the genus Crocidura using a sequence-independent viral metagenomics approach. A large portion of the shrew enteric virome was composed of insect viruses, whilst novel viruses including cyclovirus, picornavirus and picorna-like virus were also identified. Several cycloviruses, including variants of human cycloviruses detected in cerebrospinal fluid and stools, were detected in wild shrews at a high prevalence rate. The identified picornavirus was distantly related to human parechovirus, inferring the presence of a new genus in this family. The identified picorna-like viruses were characterized as different species of calhevirus 1, which was discovered previously in human stools. Complete or nearly complete genome sequences of these novel viruses were determined in this study and then were subjected to further genetic characterization. Our study provides an initial view of the diversity and distinctiveness of the shrew enteric virome and highlights unique novel viruses related to human stool-associated viruses.

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Feline fecal virome reveals novel and prevalent enteric viruses

Cited by 95 publications

References 33 publications

Widespread distribution and structural diversity of Type IV IRESs in members of Picornaviridae

Widespread distribution and structural diversity of Type IV IRESs in members of Picornaviridae

Zoonotic transmission of rotavirus: surveillance and control

Metagenomic analysis of the shrew enteric virome reveals novel viruses related to human stool-associated viruses

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