Characterization of the Genome Sequences of Enterovirus C109 from Two Respiratory Disease Cases in Florida, 2016.

The genomic sequences of two enterovirus C109 isolates (EV-C109 USA/FL/2016-21003 and EV-C109 USA/FL/2016-21002) were obtained during two separate case investigations of respiratory disease in two children. This marks the first description of EV-C109 genomes in the United States.

Diversity of picornaviruses in rural Bolivia.

The family Picornaviridae is a large and diverse group of viruses that infect humans and animals. Picornaviruses are among the most common infections of humans and cause a wide spectrum of acute human disease. This study began as an investigation of acute flaccid paralysis (AFP) in a small area of eastern Bolivia, where surveillance had identified a persistently high AFP rate in children. Stools were collected and diagnostic studies ruled out poliovirus. We tested stool specimens from 51 AFP cases and 34 healthy household or community contacts collected during 2002-2003 using real-time and semi-nested reverse transcription polymerase chain reaction assays for enterovirus, parechovirus, cardiovirus, kobuvirus, salivirus and cosavirus. Anecdotal reports suggested a temporal association with neurological disease in domestic pigs, so six porcine stools were also collected and tested with the same set of assays, with the addition of an assay for porcine teschovirus. A total of 126 picornaviruses were detected in 73 of 85 human individuals, consisting of 53 different picornavirus types encompassing five genera (all except Kobuvirus). All six porcine stools contained porcine and/or human picornaviruses. No single virus, or combination of viruses, specifically correlated with AFP; however, the study revealed a surprising complexity of enteric picornaviruses in a single community.

Naturally acquired picornavirus infections in primates at the Dhaka zoo.

The conditions in densely populated Bangladesh favor picornavirus transmission, resulting in a high rate of infection in the human population. Data suggest that nonhuman primates (NHP) may play a role in the maintenance and transmission of diverse picornaviruses in Bangladesh. At the Dhaka Zoo, multiple NHP species are caged in close proximity. Their proximity to other species and to humans, both zoo workers and visitors, provides the potential for cross-species transmission. To investigate possible interspecies and intraspecies transmission of picornaviruses among NHP, we collected fecal specimens from nine NHP taxa at the Dhaka Zoo at three time points, August 2007, January 2008, and June 2008. Specimens were screened using real-time PCR for the genera Enterovirus, Parechovirus, and Sapelovirus, and positive samples were typed by VP1 sequencing. Fifty-two picornaviruses comprising 10 distinct serotypes were detected in 83 fecal samples. Four of these serotypes, simian virus 19 (SV19), baboon enterovirus (BaEV), enterovirus 112 (EV112), and EV115, have been solely associated with infection in NHP. EV112, EV115, and SV19 accounted for 88% of all picornaviruses detected. Over 80% of samples from cages housing rhesus macaques, olive baboons, or hamadryas baboons were positive for a picornavirus, while no picornaviruses were detected in samples from capped langurs or vervet monkeys. In contrast to our findings among synanthropic NHP in Bangladesh where 100% of the picornaviruses detected were of human serotypes, in the zoo population, only 15% of picornaviruses detected in NHP were of human origin. Specific serotypes tended to persist over time, suggesting either persistent infection of individuals or cycles of reinfection.

Characterizing the picornavirus landscape among synanthropic nonhuman primates in Bangladesh, 2007 to 2008.

The term synanthropic describes organisms that thrive in human-altered habitats. Where synanthropic nonhuman primates (NHP) share an ecological niche with humans, cross-species transmission of infectious agents can occur. In Bangladesh, synanthropic NHP are found in villages, densely populated cities, religious sites, and protected forest areas. NHP are also kept as performing monkeys and pets. To investigate possible transmission of enteric picornaviruses between humans and NHP, we collected fecal specimens from five NHP taxa at16 locations in Bangladesh during five field sessions, from January 2007 to June 2008. Specimens were screened using real-time PCR assays for the genera Enterovirus, Parechovirus, and Sapelovirus; PCR-positive samples were typed by VP1 sequencing. To compare picornavirus diversity between humans and NHP, the same assays were applied to 211 human stool specimens collected in Bangladesh in 2007 to 2008 for acute flaccid paralysis surveillance. Picornaviruses were detected in 78 of 677 (11.5%) NHP fecal samples. Twenty distinct human enterovirus (EV) serotypes, two bovine EV types, six human parechovirus serotypes, and one virus related to Ljungan virus were identified. Twenty-five additional enteroviruses and eight parechoviruses could not be typed. Comparison of the picornavirus serotypes detected in NHP specimens with those detected in human specimens revealed considerable overlap. Strikingly, no known simian enteroviruses were detected among these NHP populations. In conclusion, enteroviruses and parechoviruses may be transmitted between humans and synanthropic NHP in Bangladesh, but the directionality of transmission is unknown. These findings may have important implications for the health of both human and NHP populations.

Parechovirus typing in clinical specimens by nested or semi-nested PCR coupled with sequencing.

BACKGROUND: The Parechovirus genus (Picornaviridae) contains two known species, Human parechovirus (HPeV) and Ljungan virus (LV). HPeVs cause a wide spectrum of disease, including meningitis, gastroenteritis, encephalitis, respiratory illness, and neonatal sepsis-like disease. LVs are associated with diabetes and myocarditis in bank voles and have been proposed to cause disease in humans. The ability to rapidly and accurately type parechoviruses is critical to understanding their role in human disease. OBJECTIVES: For parechovirus molecular typing, we sought to develop reverse transcription, nested polymerase chain reaction (RT-PCR) assays to amplify the sequence encoding the VP1 capsid protein from all known members of the Parechovirus genus. STUDY DESIGN: The assays consist of a two-step RT-PCR with primers flanking VP1 (PCR1), followed by semi-nested PCR2A and PCR2B reactions that produce overlapping amplicons, encompassing the complete VP1 gene, as well as a nested PCR2C that amplifies a shorter internal VP1 amplicon. RESULTS: All primer sets are 100% sensitive and 100% specific for the 77 parechovirus culture isolates tested. The semi-nested and nested PCR primer sets are 94% sensitive and 100% specific for detection of parechovirus in original specimens. Viral genotype can be deduced from analysis of amplicon sequences. Parechoviruses of the same type share>or=77% complete VP1 nucleotide sequence identity or >or=87% amino acid identity, while those of different types share

Resolving ambiguities in genetic typing of human enterovirus species C clinical isolates and identification of enterovirus 96, 99 and 102.

Molecular methods, based on sequencing the region encoding the VP1 major capsid protein, have recently become the gold standard for enterovirus typing. In the most commonly used scheme, sequences more than 75% identical (>85% amino acid identity) in complete or partial VP1 sequence are considered to represent the same type. However, as sequence data have accumulated, it has become clear that the '75%/85% rule' may not be universally applicable. To address this issue, we have determined nucleotide sequences for the complete P1 capsid region of a collection of 53 isolates from the species Human enterovirus C (HEV-C), comparing them with each other and with those of 20 reference strains. Pairwise identities, similarity plots and phylogenetic reconstructions identified three potential new enterovirus types, EV96, EV99 and EV102. When pairwise sequence comparisons were considered in aggregate, there was overlap in percentage identity between comparisons of homotypic strains and heterotypic strains. In particular, the differences between coxsackievirus (CV) A13 and CVA17, CVA24 and EV99, and CVA20 and EV102 were difficult to discern, largely because of intratypic sequence diversity. Closer inspection revealed the minimum intratypic values and maximum intratypic values varied by type, suggesting that the rules were at least consistent within a type. By plotting VP1 amino acid identity vs nucleotide identity for each sequence pair and considering each type separately, members of each type were fully resolved from those of other types. This study suggests that a more stringent value of 88% VP1 amino acid identity is more appropriate for routine typing and that other criteria may need to be applied, on a case by case basis, where lower values are seen.

The complete genome sequences for three simian enteroviruses isolated from captive primates.

In a recent study, we used RT-PCR and partial genome sequencing to detect simian enteroviruses SV6, SV19 and SV46, as well as two new enterovirus types (EV92 and EV103) in fecal specimens from rhesus macaques (Macaca mulatta), pigtail macaques (M. nemestrina), and sooty mangabeys (Cercocebus atys) with diarrheal disease at a US primate center. The complete genome sequences of representative SV46, EV92, and EV103 strains, presented here, show that SV46 and EV92 are typical of the simian enteroviruses classified within the species Human enterovirus A, while EV103 appears to belong to an unclassified species that also contains SV6 and N125/N203.

Identification of enteroviruses in naturally infected captive primates.

In a recent study, we investigated cases of diarrheal disease among monkeys at a U.S. primate center. In that study, enteroviruses were detected in a high proportion of the fecal specimens tested. To determine whether the enterovirus detections represented the circulation of one or more simian enteroviruses within the colony or the transmission of human enteroviruses from animal handlers, we determined in the present study the serotype identity of each virus by reverse transcription-PCR and sequencing of a portion of the VP1 gene, a region whose sequence corresponds to antigenic type. Enteroviruses were identified in 37 of 56 specimens (66%), 30 of 40 rhesus macaques, 5 of 11 pigtail macaques, 2 of 4 sooty mangabeys, and 0 of 1 chimpanzee. No previously known human viruses were detected. Three previously known simian enterovirus serotypes--SV6, SV19, and SV46--were among the viruses identified, but more than half of the identified viruses were previously unknown; these have been assigned as new types: EV92 and EV103.

Detection of all known parechoviruses by real-time PCR.

The Parechovirus genus of the Picornaviridae family contains two species, Human parechovirus (HPeV) and Ljungan virus (LV). The HPeVs (including the former echoviruses 22 and 23, now HPeV type 1 (HPeV1) and HPeV2, respectively) cause a wide spectrum of disease, including aseptic meningitis, gastroenteritis, encephalitis, acute respiratory illness, and neonatal sepsis-like disease. The LVs were isolated from bank voles in Sweden during a search for an infectious agent linked to fatal myocarditis cases in humans. Because of the decline in use of cell culture and neutralization to investigate enterovirus-like disease, very few laboratories currently have the capability to test for parechoviruses. We have developed a real-time reverse transcription-PCR (RT-PCR) assay for detection of all known members of the genus Parechovirus. The assay targets the conserved regions in the 5' nontranslated region (5'NTR) of the parechovirus genome and can detect both HPeVs and LVs, unlike other published parechovirus 5' NTR assays, which only detect known HPeVs or only LVs. HPeV and LV can be differentiated by sequencing the 5'NTR real-time RT-PCR amplicon, when needed. The assay is approximately 100 times more sensitive than cell culture and may be used to test original clinical specimens. The availability of a broad-specificity PCR method should facilitate the detection of new human parechoviruses, as well as new parechoviruses in other mammalian species, and provide an opportunity to investigate the role of these viruses in human and animal disease.

Complete genome sequences for nine simian enteroviruses.

Analysis of the VP1 capsid-coding sequences of the simian picornaviruses has suggested that baboon enterovirus (BaEV), SV19, SV43 and SV46 belong to the species Human enterovirus A (HEV-A) and SA5 belongs to HEV-B, whereas SV4/A2 plaque virus (two isolates of a single serotype), SV6 and N125/N203 (two isolates of a single serotype) appear to represent new species in the genus. We have further characterized by complete genomic sequencing the genetic relationships among the simian enteroviruses serotypes (BaEV, N125/N203, SA5, SV4/A2 plaque virus, SV6, SV19, SV43 and SV46) and to other enteroviruses. Phylogenetic and pairwise sequence relationships for the P1 region paralleled those of VP1 alone, and confirmed that SV4/A-2 plaque virus, SV6 and N125/N203 represent unique genetic clusters that probably correspond to three new species. However, sequence relationships in the P2 and P3 regions were quite different. In 2C, SV19, SV43 and SV46 remain clustered with the human viruses of HEV-A, but BaEV, SV6 and N125/N203 cluster together; in 3CD, SA5 (HEV-B) also joined this cluster. The 3'-non-translated region (NTR) sequences are highly conserved within each of the four human enterovirus species, but the 3'-NTRs of the simian enteroviruses are distinct from those of all human enteroviruses and generally distinct from one another. These results suggest that host species may have a significant influence on the evolution of enterovirus non-capsid sequences.

Molecular identification of 13 new enterovirus types, EV79-88, EV97, and EV100-101, members of the species Human Enterovirus B.

Molecular methods have enabled the rapid identification of new enterovirus (EV) serotypes that are untypeable using existing neutralizing antisera. As a result, sequencing of the VP1 capsid gene has been developed as a surrogate for antigenic typing to distinguish enterovirus types. In this study, 17 enterovirus isolates from four countries were identified as members of 13 new types within the species Human Enterovirus B (HEV-B) by complete genome sequencing. Members of each of these new types are at least 75% identical to one another (91% amino acid identity) in VP1, but members of different types differ from one another and from other enteroviruses by at least 27% in nucleotide sequence (26% amino acid sequence difference). The complete P1 (capsid) sequences of the new types are at least 17% different from those of all other enterovirus serotypes (14.5% amino acid sequence difference), but they are highly conserved within a type (<8% amino acid sequence difference). For both VP1 and P1, the 17 isolates are monophyletic by type with respect to all other EV serotypes. The P2 and P3 sequences are closely related to those of other HEV-B viruses (>93% amino acid identity), confirming that the 17 new strains belong to HEV-B. We propose that these 17 isolates be classified as members of 13 new human enterovirus types, enteroviruses 79-88, 97, and 100-101.

Species-specific RT-PCR amplification of human enteroviruses: a tool for rapid species identification of uncharacterized enteroviruses.

The 65 serotypes of human enteroviruses are classified into four species, Human enterovirus (HEV) A to D, based largely on phylogenetic relationships in multiple genome regions. The 3'-non-translated region of enteroviruses is highly conserved within a species but highly divergent between species. From this information, species-specific RT-PCR primers were developed that can be used to rapidly screen collections of enterovirus isolates to identify species of interest. The four primer pairs were 100 % specific when tested against enterovirus prototype strains and panels of isolates of known serotype (a total of 193 isolates). For evaluation in a typical application, the species-specific primers were used to screen 186 previously uncharacterized non-polio enterovirus isolates. The HEV-B primers amplified 68.3 % of isolates, while the HEV-A and HEV-C primers accounted for 9.7 and 11.3 % of isolates, respectively; no isolates were amplified with the HEV-D primers. Twelve isolates (6.5 %) were amplified by more than one primer set and eight isolates (4.3 %) were not amplified by any of the four primer pairs. Serotypes were identified by partial sequencing of the VP1 capsid gene, and in every case sequencing confirmed that the species-specific PCR result was correct; the isolates that were amplified by more than one species-specific primer pair were mixtures of two (11 isolates) or three (one isolate) species of viruses. The eight isolates that were not amplified by the species-specific primers comprised four new serotypes (EV76, EV89, EV90 and EV91) that appear to be unique members of HEV-A based on VP1, 3D and 3'-non-translated region sequences.

Enteroviruses 76, 89, 90 and 91 represent a novel group within the species Human enterovirus A.

Molecular methods have enabled the rapid identification of new enterovirus (EV) serotypes that would have been untypable using existing neutralizing antisera. Nineteen strains of four new EV types termed EV76 (11 isolates), EV89 (two isolates), EV90 (four isolates) and EV91 (two isolates), isolated from clinical specimens from patients in France (one isolate) and Bangladesh (18 isolates), are described. Nucleotide sequences encoding the VP1 capsid protein (882-888 nt) are less than 65 % identical to the homologous sequences of the recognized human EV serotypes, but within each group the sequences are more than 78 % identical. The deduced amino acid sequences of the complete capsid (P1) region are more than 94 % identical within type but less than 76 % identical to those of the recognized serotypes. For both VP1 and P1, the 19 isolates are monophyletic by type with respect to all other EV serotypes. Using the proposed molecular typing scheme, these data support their identification as four new types within the species Human enterovirus A (HEV-A). In almost all cases, the VP1 sequences were more similar to those of some simian EVs than to the human EVs. Partial 3D sequences of all 19 isolates also clustered within HEV-A; they were monophyletic as a group, but not by type, suggesting that recombination has occurred among viruses of these four types. Partial 3D sequences were more closely related to those of simian EVs than to human viruses in HEV-A. These results suggest that the four new types may represent a new subgroup within HEV-A, in addition to the existing human and simian subgroups.

Molecular identification and characterization of two proposed new enterovirus serotypes, EV74 and EV75.

Sequencing of the gene that encodes the capsid protein VP1 has been used as a surrogate for antigenic typing in order to distinguish enterovirus serotypes; three new serotypes were identified recently by this method. In this study, 14 enterovirus isolates from six countries were characterized as members of two new types within the species Human enterovirus B, based on sequencing of the complete capsid-encoding (P1) region. Isolates within each of these two types differed significantly from one another and from all other known enterovirus serotypes on the basis of sequences that encode either VP1 alone or the entire P1 region. Members of each type were > or =77.2 % identical to one another (89.5 % amino acid identity) in VP1, but members of the two different types differed from one another and from other enteroviruses by > or =31 % in nucleotide sequence (25 % amino acid sequence difference), indicating that the two groups represent separate new candidate enterovirus types. The complete P1 sequences differed from those of all other enterovirus serotypes by > or =31 % (26 % amino acid sequence difference), but were highly conserved within a serotype (<8 % amino acid sequence difference). Phylogenetic analyses demonstrated that isolates of the same serotype were monophyletic in both VP1 and the capsid as a whole, as shown previously for other enterovirus serotypes. This paper proposes that these 14 isolates should be classified as members of two new human enterovirus types, enteroviruses 74 and 75 (EV74 and EV75).

Enterovirus 68 is associated with respiratory illness and shares biological features with both the enteroviruses and the rhinoviruses.

Enterovirus (EV) 68 was originally isolated in California in 1962 from four children with respiratory illness. Since that time, reports of EV68 isolation have been very uncommon. Between 1989 and 2003, 12 additional EV68 clinical isolates were identified and characterized, all of which were obtained from respiratory specimens of patients with respiratory tract illnesses. No EV68 isolates from enteric specimens have been identified from these same laboratories. These recent isolates, as well as the original California strains and human rhinovirus (HRV) 87 (recently shown to be an isolate of EV68 and distinct from the other human rhinoviruses), were compared by partial nucleotide sequencing in three genomic regions (partial sequencing of the 5'-non-translated region and 3D polymerase gene, and complete sequencing of the VP1 capsid gene). The EV68 isolates, including HRV87, were monophyletic in all three regions of the genome. EV68 isolates and HRV87 grew poorly at 37 degrees C relative to growth at 33 degrees C and their titres were reduced by incubation at pH 3.0, whereas the control enterovirus, echovirus 11, grew equally well at 33 and 37 degrees C and its titre was not affected by treatment at pH 3.0. Acid lability and a lower optimum growth temperature are characteristic features of the human rhinoviruses. It is concluded that EV68 is primarily an agent of respiratory disease and that it shares important biological and molecular properties with both the enteroviruses and the rhinoviruses.

Complete genome sequences of all members of the species Human enterovirus A.

The species Human enterovirus A (HEV-A) in the family Picornaviridae consists of coxsackieviruses (CV) A2-A8, A10, A12, A14 and A16 and enterovirus 71. Complete genome sequences for the prototype strains of the 10 serotypes whose sequences were not represented in public databases have been determined and analysed in conjunction with previously available complete sequences in GenBank. Members of HEV-A are monophyletic relative to all other human enterovirus species in all regions of the genome except in the 5' non-translated region (NTR), where they are known to cluster with members of HEV-B. The HEV-A prototype strains were about 66 to 86 % identical to one another in deduced capsid amino acid sequence. Antigenic cross-reactivity has been reported between CVA3-Olson and CVA8-Donovan, between CVA5-Swartz and CVA12-Texas-12 and between CVA16-G-10 and EV71-BrCr. Similarity plots, individual sequence comparisons and phylogenetic analyses demonstrate a high degree of capsid sequence similarity within each of these three pairs of prototype strains, providing a molecular basis for the observed antigenic relationships. In several cases, phylogenies constructed from the structural (P1) and non-structural regions of the genome (P2 and P3) are incongruent. The incongruent phylogenies and the similarity plot analyses imply that recombination has played a role in the evolution of the HEV-A prototype strains. CVA6-Gdula clearly contains sequences that are also present in CVA10-Kowalik and CVA12-Texas-12, suggesting that these three strains have a shared evolutionary history despite their lack of similarity in the capsid region.

Evidence for frequent recombination within species human enterovirus B based on complete genomic sequences of all thirty-seven serotypes.

The species Human enterovirus B (HEV-B) in the family Picornaviridae consists of coxsackievirus A9; coxsackieviruses B1 to B6; echoviruses 1 to 7, 9, 11 to 21, 24 to 27, and 29 to 33; and enteroviruses 69 and 73. We have determined complete genome sequences for the remaining 22 HEV-B serotypes whose sequences were not represented in public databases and analyzed these in conjunction with previously available complete sequences in GenBank. Members of HEV-B were monophyletic relative to all other human enterovirus species in all regions of the genome except in the 5'-nontranslated region (NTR), where they are known to cluster with members of HEV-A. Within HEV-B, phylogenies constructed from the structural (P1) and nonstructural regions of the genome (P2 and P3) are incongruent, suggesting that recombination had occurred. Similarity plots and bootscanning analysis across the complete genome identified multiple sites at which the phylogeny of a given strain's sequence shifted, indicating potential recombination points. These points are distributed in the 5'-NTR and throughout P2 and P3, but no sites with >80% bootstrap support were identified within the capsid. Individual sequence comparisons and phylogenetic analyses suggest that members of HEV-B have recombined with one another on multiple occasions, resulting in a complex mosaic of sequences derived from multiple parental viruses in the nonstructural regions of the genome. We conclude that RNA recombination is a common mechanism for enterovirus evolution and that recombination within the nonstructural regions of the genome (P2 and P3) has been observed only among members of the same species.

Genomic evidence that simian virus 2 and six other simian picornaviruses represent a new genus in Picornaviridae.

Analysis of the VP1 capsid protein coding region of simian virus (SV) 2, SV16, SV18, SV42, SV44, SV45, and SV49 demonstrates that they are clearly distinct from members of the Enterovirus genus and from members of other existing picornavirus genera. To further characterize this group of viruses and to clarify their classification within the Picornaviridae, we have determined the complete genomic sequence of SV2 (8126 nucleotides). The genome was typical of members of Picornaviridae, encoding a single open reading frame. The putative polyprotein contained typical picornavirus protease cleavage sites, yielding mature proteins homologous to each of the known picornavirus proteins. SV2 contained an amino-terminal extension of the reading frame, which was analogous to the leader protein of members of the Aphthovirus, Cardiovirus, Erbovirus, Kobuvirus, and Teschovirus genera, but there was no significant amino acid homology with any of these known leader proteins. The 2A protein also aligned poorly with the 2A proteins of other picornaviruses. The deduced amino acid sequences of the SV2 structural and nonstructural proteins were related to but phylogenetically distinct from those of enteroviruses and human rhinoviruses. The major distinguishing features of SV2 were the presence of a type 2 internal ribosome entry site in the 5'-NTR, a putative leader protein encoded upstream of the structural proteins, and an unusually large 2A protein. On the basis of the molecular analysis, we propose that SV2, SV16, SV18, SV42, SV44, SV45, SV49, and porcine enterovirus 8 be classified as members of a new genus in Picornaviridae and that SV2 (strain 2383) be designated as the type strain.

Complete genomic sequencing shows that polioviruses and members of human enterovirus species C are closely related in the noncapsid coding region.

The 65 human enterovirus serotypes are currently classified into five species: Poliovirus (3 serotypes), Human enterovirus A (HEV-A) (12 serotypes), HEV-B (37 serotypes), HEV-C (11 serotypes), and HEV-D (2 serotypes). Coxsackie A virus (CAV) serotypes 1, 11, 13, 15, 17, 18, 19, 20, 21, 22, and 24 constitute HEV-C. We have determined the complete genome sequences for the remaining nine HEV-C serotypes and compared them with the complete sequences of CAV21, CAV24, and the polioviruses. The viruses were most diverse in the capsid region (4 to 36% amino acid difference). A high degree of capsid sequence conservation (96% amino acid identity) suggests that CAV15 and CAV18 should be classified as strains of CAV11 and CAV13, respectively. In the 3CD region, CAV1, CAV19, and CAV22 differed from one another by only 1.2 to 1.4% and CAV11, CAV13, CAV17, CAV20, CAV21, CAV24, and the polioviruses differed from one another by only 1.2 to 3.6%. The two groups, however, differed from one another by 14.6 to 16.2%. The polioviruses as a group were monophyletic only in the capsid region. Only one group of serotypes (CAV1, CAV19, and CAV22) was consistently monophyletic in multiple genome regions. Incongruities among phylogenetic trees based on different genome regions strongly suggest that recombination has occurred between the polioviruses, CAV11, CAV13, CAV17, and CAV20. The close relationship among the polioviruses and CAV11, CAV13, CAV17, CAV20, CAV21, and CAV24 and the uniqueness of CAV1, CAV19, and CAV22 suggest that revisions should be made to the classification of these viruses.

Characterization of a novel coronavirus associated with severe acute respiratory syndrome.

In March 2003, a novel coronavirus (SARS-CoV) was discovered in association with cases of severe acute respiratory syndrome (SARS). The sequence of the complete genome of SARS-CoV was determined, and the initial characterization of the viral genome is presented in this report. The genome of SARS-CoV is 29,727 nucleotides in length and has 11 open reading frames, and its genome organization is similar to that of other coronaviruses. Phylogenetic analyses and sequence comparisons showed that SARS-CoV is not closely related to any of the previously characterized coronaviruses.