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Journal of Virology, October 1998, p. 8408-8412, Vol. 72, No. 10
Department of Virology,
Received 13 March 1998/Accepted 8 July 1998
The complete nucleotide sequence of a novel enteric virus, Aichi
virus, associated with nonbacterial acute gastroenteritis in humans was
determined. The Aichi virus genome proved to be a single-stranded
positive-sense RNA molecule with 8,251 bases excluding a poly(A) tail;
it contains a large open reading frame with 7,302 nucleotides that
encodes a potential polyprotein precursor of 2,433 amino acids. The
genome contains a 5' nontranslated region (NTR) with 712 bases and
a 3' NTR with 240 bases followed by a poly(A) tail. The structure of
the genome, VPg-5' NTR-leader protein-structural proteins-nonstructural proteins-3' NTR-poly(A), was found to be typical of a picornavirus. The VP0-VP3 and VP3-VP1 cleavage sites were
determined to be Q-H and Q-T, respectively, by N-terminal amino acid
sequence analyses using purified virion proteins. Possible cleavage
sites, Q-G, Q-A, and Q-S, which cleave P2 and P3 polyproteins were
found to be similar to those of picornaviruses. A dendrogram based on
3Dpol proteins indicated that Aichi virus is genetically
distinct from the known six genera of picornaviruses including entero-,
rhino-, cardio-, aphtho-, and hepatovirus and echovirus 22. Considering this together with other properties of the virus (T. Yamashita, S. Kobayashi, K. Sakae, S. Nakata, S. Chiba, Y. Ishihara, and S. Isomura,
J. Infect. Dis. 164:954-957, 1991), we propose that Aichi virus
be regarded as a new genus of the family Picornaviridae.
In fecal specimens of patients with
nonbacterial acute gastroenteritis, morphologically distinct
round-structured viruses (approximately 20 to 40 nm in diameter) have
been detected by electron microscopy (9, 10). Of these
viruses, Norwalk or Norwalk-like viruses (18-22, 38) and
astroviruses (17, 24, 39) have been recognized as major
etiologic agents of human gastroenteritis (4), and recent
genetic analyses have revealed that they can be classified into the
families Caliciviridae and Astroviridae,
respectively (8, 23).
In 1989, we isolated a novel cytopathic small round virus,
designated Aichi virus, from a stool specimen of a patient
with oyster-associated nonbacterial gastroenteritis. The virus
caused apparent cytopathic effects of BS-C-1 cells (40). By
using an enzyme-linked immunosorbent assay, 13 of 47 (28%) stool
specimens collected from five different oyster-associated
gastroenteritis outbreaks were shown to be positive for the Aichi virus
antigen. Seroconversion, detected by an increase of the neutralizing
antibody titer up to four times or more, was observed in 20 of 43 (47%) paired sera from these outbreaks (41). Furthermore,
Aichi virus was isolated from Pakistani children with gastroenteritis
as well as from Japanese travelers who developed gastroenteritis after having traveled in Southeast Asian countries (42). Although direct evidence for the pathogenesis of the virus has not been obtained
yet, these findings strongly suggested that Aichi virus is one of the
causative agents of human gastroenteritis.
A morphological study on purified Aichi virus virions indicated that
the surface structure is characteristic of a small round-structured virus (40). However, the ability to grow in cultured cells, along with other biological properties, i.e., resistance to treatment with chloroform and stability under a low pH (pH 3.5), suggested that
Aichi virus was a member of the enteroviruses. However, none of the
enterovirus antisera neutralized Aichi virus, and, conversely, the
antiserum to Aichi virus did not react with any other enterovirus or
other enteric viruses such as Norwalk-like viruses and astroviruses (40, 41). Neither a nucleotide nor amino acid sequence has been reported yet. Therefore, definitive classification of this virus
remains unclear.
In this study, we performed molecular cloning and complete
nucleotide sequence analysis as well as genetic analysis of
Aichi virus genome RNA to define the phylogenetic
relationship between Aichi virus and other RNA viruses. Our results
indicated that Aichi virus is a distinct member of the known
picornaviruses.
A standard Aichi virus strain, A846/88, was isolated in BS-C-1 cells,
as described previously (40), plaque purified, and then
grown in Vero cells. The virion was purified by CsCl and sucrose
density gradient centrifugation, as described elsewhere (40), and RNA was extracted by proteinase K treatment
followed by phenol-chloroform extraction and ethanol precipitation
(36). One microgram of the RNA was converted into cDNA with
a mixture of random and oligo(dT)15 primers (Promega Corp.,
Madison, Wis.) by using a reverse transcriptase from Moloney
murine leukemia virus (Gibco BRL, Gaithersburg, Md.), which was
subsequently cloned into pBR322 (Gibco BRL) by a dC-dG-tailing
method, as previously described (35). Screening was carried
out by dot blot hybridization with the virion RNA as a template and
biotinylated inserts as probes. Clones containing the 5' end of the
genome were obtained with the 5' RACE System for Rapid Amplification of
cDNA Ends (Gibco BRL). The following nucleotide sequences were
obtained from GenBank: bovine enterovirus (BEV), D00214;
coxsackievirus A16 (CA16), U05876; coxsackievirus B3 (CB3), M16572;
enterovirus 70 (EV70), D00820; poliovirus type 1 (PV1), J02281; human
rhinovirus 2 (HRV2), X02316; human rhinovirus 14 (HRV14), X01087; human rhinovirus 89 (HRV89), M16248; encephalomyocarditis virus (EMCV), M81861; Theiler murine encephalomyelitis virus (TMEV), M20301; foot-and-mouth disease virus type A12 (FMDV-A), M10975; foot-and-mouth disease virus type OK1 (FMDV-O), X00871; foot-and-mouth disease virus
type SAT3 (FMDV-S), M28719; hepatitis A virus (HAV), M14707; echovirus
22 (E22), L02971; swine vesicular disease virus (SVDV), X54521; and
simian hepatitis A virus (SHAV), D00924.
Previous studies have shown that the Aichi virus virion contains a
single-stranded RNA molecule as the genome (40). The length
was roughly estimated to be 8.2 kb by agarose gel electrophoresis under
a denatured condition (data not shown). Twelve overlapping cDNA clones
spanning the entire genome were obtained, and their nucleotide
sequences were determined. The RNA genome of Aichi virus consists of
8,251 nucleotides (nt), excluding a poly(A) tract. A large open reading
frame with 7,302 nt that encodes a potential polyprotein precursor of
2,433 amino acids (aa) was found; it is preceded by 712 nt and followed
by 240 nt and a poly(A) tail. The genome organization was analogous to
that of other picornaviruses, and the deduced amino acid sequence of
the C-terminal one-third of the polyprotein had a high degree of
sequence conservation with picornaviruses. These observations made it
possible to suggest that the first 712 nt are a 5' nontranslated region
(NTR). The length is similar to that of other picornaviruses and must
encode cis-acting elements and an internal ribosome entry
site (IRES) (25). The base composition was found to be
19.5% adenine, 21.1% guanine, 37.8% cytosine, and 21.6% uracil.
This high G+C content ( Aichi virus virions contain three, not four, capsid proteins, of 42, 30, and 22 kDa. No protein band corresponding to VP4 (usually 7 to 8 kDa) was observed in sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE), even when only 1 µg of purified virions
was loaded onto the gel and visualized by silver staining. Because it
has been reported that preparations of highly purified picornavirus
particles invariably contain small amounts of VP0, intact Aichi virus
particles were separated from the empty particles by sedimentation in
sucrose, and the capsid proteins were separated by SDS-PAGE. The
proteins composing these two particles were found to be similar (Fig.
2). This clearly illustrated that the
Aichi virus virion has no VP4, as previously shown for E22
(15).
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Complete Nucleotide Sequence and Genetic Organization of Aichi
Virus, a Distinct Member of the Picornaviridae
Associated with Acute Gastroenteritis in Humans
ABSTRACT
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59%) was relatively similar to that of
aphthoviruses (in FMDV-O, G+C is 53%) rather than of enteroviruses (in
PV1, G+C is 45%), rhinoviruses (in HRV14, G+C is 41%), hepatoviruses
(in HAV, G+C is 38%), cardioviruses (in EMCV, G+C is 49%), or E22
(G+C is 39%). In the Aichi virus 5' NTR, neither a poly(C) tract, as
found in aphtho- and cardioviruses, nor a relatively long
pyrimidine-rich sequence (approximately 40 bases), structurally
analogous to the poly(C) tract found in hepatoviruses, was observed.
Although the precise secondary structure of the 5' NTR could not be
defined, the location of the pyrimidine tract (nt 695 to 701) and the
initiator methionine (nt 713) suggested that the IRES of Aichi virus
belongs to type II, similar to aphtho-, cardio- and hepatoviruses (Fig. 1). RNA folding analysis of the extreme
5' end of the RNA with the MFOLD program in CGC (version 9.0, December
1996; Genetics Computer Group, Madison, Wis.) suggested the presence of
a hairpin structure followed by pseudonots, such as found in aphtho-,
cardio-, and hepatoviruses (data not shown). The picornavirus 3' NTRs
differ in length, ranging from 40 nt in HRV to 126 nt in EMCV
(32), and the 3' NTR of the Aichi virus genome was longer
than that of EMCV, the longest in the picornavirus family, by more than 100 nt. Whether the 3' NTR of Aichi virus consists of three
double-stranded hairpin stems, as seen in EMCV, two stems, as seen in
PV1 and FMDV, or a single stem, similar to HRV and HAV, could not be
determined (2, 27).
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FIG. 1.
Comparison of conserved sequence elements in the IRES of
picornaviruses. A short stretch including the
Yn-Xm-ATG motif and the
initiator methionine, according to Jang et al. (16), is
shown. Yn, pyrimidine-rich tract;
Xm, nonconserved sequence; ATG, initiator
methionine.
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FIG. 2.
Electron micrograph (A) and SDS-PAGE analysis (B) of
Aichi virus full particle (F) and empty particle (E). The intact
virions and the empty particles were purified by banding at
100,000 × g for 22 h in CsCl with an initial
density of 1.36g/ml followed by 5 to 30% (wt/vol) sucrose density
gradient centrifugation at 100,000 × g for 100 min
(40). The proteins were analyzed by SDS-12% PAGE, and the
bands were visualized by silver staining. For N-terminal sequence
analysis, the protein band was transferred to a polyvinylidene
difluoride membrane (Millipore Corporation, Bedford, Mass.) and
analyzed by an Applied Biosystems model 476A automated protein
sequencer.
To further characterize each capsid protein and identify some of the
cleavage sites, 30- and 22-kDa proteins from the intact particles were
separated by SDS-PAGE and transferred to a polyvinylidene difluoride
membrane, and then the N-terminal sequence was determined. The analysis
provided the results TLTEDLDAPQDTGNI and HWKTRAVPGAG for the 30- and
22-kDa proteins, respectively. These sequences were found at aa 765 to
779 and 542 to 552 in the predicted polyprotein sequence. These
residues unambiguously localized the N-terminal end of VP1 and VP3 in
Aichi virus P1 protein (Table 1). The
largest, 42 kDa, provided no signal in the analysis, indicating that
the N-terminal amino acid was blocked. This was not surprising, because the N-terminal end of picornavirus VP4 is myristylated, and it has been
shown that a characteristic consensus myristylation sequence (GXXX[T/S], where X is a nonconserved amino acid) is conserved in all
picornaviruses. This motif was easily found at aa 171 to 175 of the
Aichi virus polyprotein. Therefore, glycine at aa 171 was probably
myristylated like other VP4 proteins of picornaviruses (32).
Because the molecular mass calculated for aa 171 to 541 (39 kDa) was
close to the molecular mass obtained in SDS-PAGE and no VP4 was found
on the gel, we concluded that the 42-kDa protein is VP0 and that no
VP4-VP2 cleavage occurred. The Aichi virus 42-kDa protein strongly
reacted with convalescent-phase serum from patients (40);
therefore, it probably constitutes the surface of the virions. We
concluded that the VP0-VP3 and VP3-VP1 cleavage sites are Q-H and Q-T,
respectively. These observations further indicated that a leader (L)
protein consisting of 170 aa is present upstream of VP0. The length of
the L protein is a little shorter than that of FMDV (217 aa) and more
than two times longer than that of EMCV (67 aa). However, neither the
catalytic dyad (Cys and His) conserved in a papain-like thiol protease
and found in the FMDV L protein (12, 26) nor a putative
zinc-binding motif, Cys-His-Cys-Cys, found in EMCV or TMEV
(6) could be identified. The function of the Aichi virus L
protein is unknown at the moment. Although there was no consensus amino
acid sequence around the VP1-2A junctions among the picornaviruses, the
P1-P2 cleavage site of Aichi virus was tentatively determined to be Y-V, located at aa 1042 and 1043, based on the molecular mass of VP1
and the known P1-P2 cleavage site of HRV2 (31).
|
Possible cleavage sites of nonstructural proteins were determined from
amino acid alignment with known picornaviruses. Cleavage sites 2A-2B,
2B-2C, 2C-3A, 3A-3B (VPg), 3B-3Cpro, and
3Cpro-3Dpol are similar to those well conserved
among picornaviruses, and they were tentatively assigned as Q-G, Q-G,
Q-G, Q-A, Q-G, and Q-S, respectively. The 2A protein of picornavirus is
known to have a cis-acting proteolytic activity and has been
classified into two types. In entero- and rhinoviruses, 2A functions
autocatalytically to cleave the P1 polyprotein at its own N terminus
and mediates the cleavage of the p220 component of the
cap-binding complex eIF-4
, leading to the shutoff of host
cellular protein synthesis. Like 3C protease, a catalytic triad
conserved in trypsin-like protease has been identified (3,
43). In aphtho- and cardioviruses, on the other hand, 2A mediates
the cleavage at its own C terminus and the autocleavage motif, NPEG, is
conserved in a C-terminal 2A protein (11, 30). In Aichi
virus 2A protein, neither the critical GXCG motif of trypsin-like
protease nor the NPEG motif could be found. Further study is necessary
to elucidate the function and capability of Aichi virus 2A in virus
replication. Amino acid sequences of the 2C, 3Cpro, and
3Dpol regions were well aligned with other picornaviruses
(data not shown). Although the function of 2C protein was not
completely elucidated, a highly conserved motif (GxxGXGKT [X,
uncharged, x, nonconserved]) in the nucleotide binding domain of the
putative picornavirus helicase was found in Aichi virus 2C protein. 3B (VPg) of Aichi virus (27 aa) was longer than that of other
picornaviruses by 3 to 7 aa. A tyrosine residue was conserved at the
third amino acid, as observed in other VPg proteins of picornaviruses.
We found only one copy of the VPg sequence; therefore, Aichi virus was
determined to be different from aphthoviruses, which have three copies
of the VPg sequence in tandem. The 3Cpro that participates
in most of the cleavages of picornavirus polyprotein contains a
catalytic triad formed by histidine, aspartate/glutamate, and cysteine.
These amino acids are conserved in all picornaviruses, and they were
seen in Aichi virus 3Cpro at positions 42, 84, and 143, respectively. A motif, GXCGG, conserved at the C terminus of
enterovirus and rhinovirus 3Cpro was considered to form a
part of the active site, and this motif was present but altered
to GXCGS in Aichi virus (X, nonconserved amino acid). An
identical change was observed in cardioviruses. A histidine residue
that probably participates in the substrate binding pocket in the
trypsin-like protease was found at aa 161 in Aichi virus
3Cpro (3, 5). Highly conserved motifs (KDELR,
YGDD, and FLKR) in picornavirus 3Dpol were found at aa 160, 328, and 377, respectively, in Aichi virus 3Dpol.
The genome structure of Aichi virus, VPg-5' NTR-leader protein-structural proteins-nonstructural proteins-3' NTR-poly(A) tail, is typical of a picornavirus (Fig. 3). The overall structure of the Aichi virus genome most closely resembled an aphthovirus, except for VPg. The genome organization was apparently different from that of caliciviruses, including small round-structured viruses, or that of astroviruses. These two viruses contain three open reading frames, and 3Dpol is located more than 2,000 nt upstream of the poly(A) tail due to the presence of a capsid protein gene (17, 19, 39).
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The nucleotide sequence homologies of the 5' and 3' NTRs and the amino acid sequence homologies between Aichi virus and representative viruses from other picornaviruses are shown in Table 1. The 5' NTR of Aichi virus exhibits a similar and relatively high degree of sequence homology with other viruses. The homology of Aichi virus proteins with corresponding polypeptides of other picornaviruses varied between 15 and 36%, except for a short leader of HAV and E22. This value is of the same order as that seen when HAV or E22 is compared with other picornaviruses (7, 15). The dendrogram based on 3Dpol proteins is depicted in Fig. 4, indicating that Aichi virus should be separated from the known six genera of picornaviruses including entero-, rhino-, cardio-, aphtho-, and hepatoviruses and E22 (15, 28, 32, 33).
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Acute epidemic gastroenteritis outbreaks after consumption of raw oysters are reported every winter in Japan (1, 13, 14, 34, 37), and most of them are suspected to be caused by Norwalk-like viruses. However, it has become obvious that some of them have been caused by Aichi virus (41). The primary structure of Aichi virus elucidated in this study will be unambiguously useful for developing sensitive and specific detection of Aichi virus sequences by PCR. By such a detection system, the significance of Aichi virus as a causative agent in acute nonbacterial gastroenteritis will be clarified.
Nucleotide sequence accession number. The complete nucleotide sequence of Aichi virus has been submitted to the DDBJ, EMBL, and GenBank databases under accession no. AB010145.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Virology, Aichi Prefectural Institute of Public Health, 7-6, Nagare, Tsujimachi, Kita-ku, Nagoya, Aichi 462-8576, Japan. Phone: 81-52-911-3111. Fax: 81-52-913-3641. E-mail: tyamashita{at}hi-ho.ne.jp.
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Journal of Virology, October 1998, p. 8408-8412, Vol. 72, No. 10
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