Previous Article | Next Article 
Journal of Virology, November 2000, p. 9980-9986, Vol. 74, No. 21
Department of Virology, Faculty of Medicine,
Tottori University, Yonago 683-8503, Japan
Received 1 May 2000/Accepted 3 August 2000
A permuted whole-genome construct of a TT virus (TTV), named VT416,
had 3,852 nucleotides (nt) 98.2% similar to the prototype TA278
genome. To allow the transcription of TTV from the internal promoter,
pBK*VT416(1.3G), carrying 1.3 units of VT416, was constructed. The
poly(A)+ RNAs expressed in COS1 cells 48 h
posttransfection contained three TTV mRNA species 3.0, 1.2, and 1.0 kb
in length, which were recovered in the 13 DNA clones from a A novel DNA virus, named TT virus
(TTV), was found in a patient with posttransfusion hepatitis of unknown
etiology (14) by representational difference analysis
(7). Subsequently, Okamoto et al. (18) reported
that TTV is an unenveloped virus with a buoyant density of 1.31 to 1.32 g/cm3 in CsCl and a single-stranded linear DNA genome 3,739 nucleotides (nt) in length. Recently, Mushahwar et al. (12)
and Miyata et al. (10) independently found an additional 113 nt to circularize and complete the 3,852-nt-long genome and proposed
TTV as the first human virus similar to members of the family
Circoviridae (10). TTV has an extremely wide
range of sequence divergence, by which at least 16 genotypes are
classified (16).
Among vertebrate viruses in Circoviridae, chicken anemia
virus (CAV) in the genus Gyrovirus (21) has a
negative-strand DNA (15) as is the case for TTV
(12). Although the genome of CAV is 2.3 kb long and thus
much shorter than the genome of TTV (3.9 kb), CAV resembles TTV in
genome structure (10, 15, 17). By contrast, porcine
circovirus (PCV) and beak feather disease virus in the genus
Circovirus have an ambisense genome (13). A
capsid protein is encoded by the antigenomic strand for CAV (8,
13). RNA transcripts of three vertebrate viruses in
Circoviridae have been analyzed in detail. A single
nonspliced 2.0-kb mRNA is recognized in CAV (20), although
other spliced mRNAs may encode three open reading frames (ORFs)
(15). Of the three transcripts of PCV, one for the Rep
protein is spliced and in the genomic orientation, and the other two
are in the antigenomic orientation (8). There have been no
reports on mRNAs of TTV, which is proposed to encode two putative ORFs,
named ORF1 and ORF2 (5, 17, 24), primarily due to the lack
of an appropriate culture system to support viral replication.
To analyze the transcription profile of TTV, we designed a construct
containing a linearized TTV genome which could multiply in transfected
COS1 cells with help of simian virus 40 (SV40) T antigen. The obtained
results suggest that at least three mRNAs of TTV would be transcribed
from a common promoter and that splicing of these mRNAs may create two
novel coding regions.
Preparation of a plasmid containing the entire TTV genome.
Nucleic acids extracted from the serum (kindly supplied by M. Mayumi,
Jichi Medical School, Tochigi, Japan) from which the prototype TTV
(TA278) was cloned (17) were used as the template for
amplifying the two overlapping parts of genomic DNA in a TTV of
genotype 1 (VT416) by a modification of the PCR protocol described previously (10). Briefly, we amplified part A (nt 971 to
2877) by a double PCR using a primer pair (5'-CGC GGA TCC
A946TG ACT ACA GAC AAA TTT ACT TTA A970-3' and
5'-AAG GAA AAA AGC GGC CGC T2901TA TGG TGC TAT
TTG AAA TAA GGA2878-3') and part B (nt 2093 to 3852 linked
to nt 1 to 997) by PCR with an outer primer pair
(5'-GGG1274 GTA CCC CCA AAC AGA TCT TTG TGA CAT GGT GCT TCT
AAC TG1315-3' and 5'-G1281GG GTA CCA TTT ATC
AGT GAA CAT TTT TGG TGC CCC TAC TCT TA1238-3') and a nested
inner primer pair (5'-CGC GGA TCC2067 ATG AAT
GCC AGG CTA CTA ATA AGA A2092-3' and 5'-AAG GAA AAA
AGC GGC CGC TTA A1020GA TGC TGT CCA
GTA GTT CAT AA998-3' (flanking restriction sequences added
for cloning are in boldface; the italicized A in the last
primer sequence was introduced to create a stop codon for truncating
the product of ORF1 when ligated to an expression vector). Each PCR
product was digested with BamHI-NotI and
subcloned into the corresponding site in expression vector pGEX4T3
(Amersham Pharmacia Biotech, Little Chalfont, United Kingdom). To
minimize mutations during PCR, we selected for each of the two parts
one clone that produced a glutathione S-transferase-ORF1 fusion protein with the predicted size (data not shown). Using the
unique EcoRI site at nt 971 and PstI site at nt
2761 in parts A and B, respectively, a permuted complete genome of TTV
(VT416) was subcloned into the PstI site in pTZ18U
(Worthington Biochemical, Lakewood, N.J.), to create a plasmid named pTZVT416.
Transfection and RNA extraction.
COS1 cells constitutionally
expressing SV40 T antigen were cultured in Dulbecco's minimum
essential medium supplemented with 10% (vol/vol) fetal bovine serum
(Filtron Pty., Brooklyn, Victoria, Australia). Plasmid DNA in an amount
of 24 µg was transfected into 2 × 106 COS1 cells by
the calcium phosphate method (3). Total cellular RNAs in
COS1 cells 48 h posttransfection were extracted with guanidinium thiocyanate and phenol chloroform (4), and
poly(A)+ mRNAs were selected by Oligotex-dT30 (TaKaRa
Biomedicals, Kyoto, Japan).
TTV-specific probes.
Three probes were transcribed in vitro:
148/Bam (full genome length), 627/Eco (nt 1522 to 972) in the antisense
orientation, and 148/Not (full genome length) in the sense orientation.
They were labeled with digoxigenin by a DIG RNA labeling kit (Roche Diagnostics, Mannheim, Germany) and used in Northern blotting. An
additional 1.8-kb DNA probe, EP1.8 (nt 972 to 2759), was labeled with
[ Northern blotting.
Poly(A)+ mRNAs (1 µg) were
denatured with 50% (vol/vol) formamide and electrophoresed on a 1%
SeaKem ME agarose (FMC BioProducts, Rockland, Maine). They were
transferred onto a nylon membrane (Hybond N+; Amersham
Pharmacia Biotech) and fixed by UV irradiation (22). The
filter was prehybridized at 68°C for 1 h in 5× SSPE (1× SSPE contained 180 mM NaCl, 10 mM sodium phosphate [pH 7.7], and 1 mM
EDTA)-50% formamide-5× Denhardt's solution (1)-0.5%
(wt/vol) sodium dodecyl sulfate (SDS)-20 µg of denatured sermon
sperm DNA per ml, hybridized at 68°C for 16 h in the
prehybridization solution, washed once in 2× SSC (1× SSC is 0.15 M
NaCl plus 0.015 M sodium citrate)-0.1% SDS at 25°C for 15 min, and
then washed once in 0.2× SSC-0.1% SDS at 68°C for 30 min.
Thereafter, the filter was incubated with antidigoxigenin antibody
labeled with alkaline phosphatase, and mRNAs on it were visualized with
a DIG luminescent detection kit (Roche).
cDNA cloning.
On poly(A)+ mRNAs from COS1 cells
transfected with TTV DNA clones, cDNAs were reverse transcribed by
Moloney murine leukemia virus reverse transcriptase (Stratagene, La
Jolla, Calif.) using a primer, 5'-(GAGA)5 ACT AGT CTC
GAG T17-3', carrying a XhoI restriction
site (in boldface) and a poly(dT) stretch. The antisense strand was
synthesized with a mixture of dATP, dGTP, dTTP, and 5'-methyl-dCTP that
protected the products from digestion with restriction endonucleases in
a later step. The sense strand was synthesized with DNA polymerase I
and RNase H. Obtained cDNAs were ligated to an EcoRI adapter
and digested with EcoRI and XhoI. cDNA fragments
greater than 500 nt in size were fractionated by a Sephacryl S-500
column, ligated into the EcoRI and XhoI sites in
a Nucleotide sequencing.
DNA was sequenced by the
dideoxy-sequencing method (23) using a Cy5 AutoCycle
sequencing kit (Amersham Pharmacia Biotech). Some regions were
subcloned into M13mp18, as required, and sequenced by the
single-stranded M13 DNA method with use of a SequiTherm EXCEL II
Long-Read DNA sequencing kit-ALF (Epicentre, Madison, Wis.).
Computer analyses.
Database (DDBJ) searches and sequence
analyses were performed by using FASTA (19) and Genetyx
(version 9.0). The alignment of DNAs was carried out with Sequencher
(version 3.0).
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Three Spliced mRNAs of TT Virus Transcribed from a
Plasmid Containing the Entire Genome in COS1 Cells
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
phage
cDNA library. These mRNAs in the antigenomic orientation possessed in
common the 3' terminus downstream of a poly(A) signal
(A3073ATAAA) and the 5' terminus downstream of a cap site
(C98ACTTC). A common splicing to join nt 185 with nt 277 was detected in all mRNAs. The coding region of the largest open
reading frame (ORF) was maintained in 3.0-kb mRNA, because this
splicing was located upstream of its initiation codon
(A589TG). The second splicing was detected in 1.2-kb mRNA
to join nt 711 with nt 2374 and in 1.0-kb mRNA to bind nt 711 to nt
2567. They linked a proposed ORF2 to another ORF for creating new ORFs over nt 2374 to 2872 in frame 2 and nt 2567 to 3074 in frame 3. The
donor and acceptor sites of all three splicings matched the consensus
sequence and were conserved in most of the 16 TTVs of distinct
genotypes retrieved from the database. The observed transcription profile is unique to TTV among known members in the family
Circoviridae.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-32P]dCTP (Amersham Pharmacia Biotech) by a random
priming DNA labeling kit (version 2; TaKaRa) and used for plaque hybridization.
phage vector (Zap Express; Stratagene), and packaged with Gigapack II Gold packaging extracts (Stratagene). Escherichia coli XL1-Blue MRF (Stratagene) was infected with phages, and the plaques obtained were lifted onto a nitrocellulose membrane (Protran BA85; Schleicher & Schuell, Dassel, Germany) and hybridized with the
TTV EP1.8 probe. The candidate phages were clone purified three times.
Recovered cDNA fragments were subcloned into pBK-CMV by in vivo
excision through superinfection with the ExAssist helper phage (Stratagene).
Nucleotide sequence accession numbers. The nucleotide sequence data in this report have been deposited in the DDBJ/EMBL/GenBank nucleotide sequence databases under accession no. AB041007 for the whole TTV genome (VT416) and AB041821, AB041822, and AB041823 for cDNA clones 302 (representative of 3.0-kb mRNA), 1031 (1.2-kb mRNA), and 19 (1.0-kb mRNA), respectively.
| |
RESULTS |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
Construction of plasmids.
pTZVT416 (Fig.
1A) contained the permuted whole genome
of a TTV DNA (VT416) with 3,852 nt and 98.2% sequence similarity to TA278 (accession no. AB017610). The major ORFs and motifs in TA278,
including a 113-base-long GC-rich region, five ATF (CREB) binding
sites, and one TATA box (10), were conserved in VT416. However, VT416 had only one poly(A) signal at A3073ATAAA,
and A1722ATAAA in TA278 was replaced with
A1722AAACA.
|
Expression of TTV mRNAs in COS1 cells.
The
poly(A)+ RNAs obtained from COS1 cells 48 h
posttransfection were tested by Northern blotting. As shown in Fig.
2A (upper panel, lane 1.3G), the cells
transfected with pBK*VT416(1.3G) revealed three distinct RNA bands at
3.0, 1.2, and 1.0 kb which were hybridized with the full-genome-length
probe in the genomic orientation (148/Bam). No visible bands were
observed for mock- or pBK*-transfected cells (lanes Mock and pBK*). The
quality and amount of poly(A)+ RNA applied in each lane
were confirmed in a parallel run probed for a constitutional mRNA
expressed in COS1 cells (glyceraldehyde-3-phosphate dehydrogenase)
(Fig. 2, middle panel). In contrast, only the 3.0-kb band was visible
by hybridization with the 627/Eco probe representing a partial genome
(nt 1522 to 972) (Fig. 2B, lane 1.3G), suggesting a splicing in both
1.2- and 1.0-kb mRNAs over the corresponding region. The cells
transfected with pBK*VT416(1.5G), for expression of mRNAs in the
genomic orientation, did not produce any positive signals by
hybridization with the full-genome-length probe in the antigenomic
orientation (148/Not) (Fig. 2C, lane 1.5G).
|
cDNA clones of TTV mRNAs.
A phage cDNA library was
obtained on a preparation of poly(A)+ RNAs from COS1 cells
transfected with pBK*VT416(1.3G). From 3 × 105
plaques screened by the TTV DNA probe (EP1.8 [nt 972 to 2761]), 15 clones which carried TTV sequences were recovered. The sizes of TTV
inserts were 1.0 kb in three clones (clones 19, 75, and 1211), 1.2 kb
in four clones (clones 25, 1031, 1152, and 1321), 3.0 kb in six clones
(clones 302, 1131, 1181, 1231, 1351, and 1391), and 1.8 (clone 1161)
and 2.1 (clone 1381) kb in one clone each (Fig.
3). Both 3' and 5' termini of each insert
were sequenced. The 3' terminus of every insert had poly(A) starting at
7 or 10 nt downstream of the poly(A) signal (A3073ATAAA),
suggesting that all mRNAs used this poly(A) signal (Fig. 4). In each of the 13 clones of 1.0, 1.2, or 3.0 kb, the 5'-terminus was at a position from 123 to 135 nt
downstream of the TATA box (A85TATAA). Hence, they would
use a common promoter and C98ACTTC that was the only cap
site between the promoter and the 5' terminus in each of these clones.
|
X174 DNA with
HaeIII.
|
The 3.0-kb mRNA.
Clone 302 representing 3.0-kb mRNA covered
the entire ORF1 (nt 589 to 2898) in the TTV genome (10, 12,
17). It had a single splicing to join nt 185 with nt 277. The
splicing did not affect ORF1, however, because of its location upstream
of the first A589TG and the presence of multiple stop
codons between the splicing and A589TG in frame 1 (Fig.
5).
|
The 1.2-kb mRNA. Clone 1031 representing 1.2-kb mRNA had two splicings to join nt 185 with nt 277 and nt 711 with nt 2374 (Fig. 5). The first splicing was identical to that in 3.0-kb mRNA; the second, at nt 711, was located 2 nt upstream of the termination codon (T713AA) of ORF2 that is predicted in frame 2 (10, 17). Due to this splicing, however, the predicted coding region of ORF2 was linked to a new ORF (ORF4 [nt 2374 to 2872]) in the same frame. The other two clones carrying 1.2-kb mRNA (clones 1152 and 1321) had the same two splicings. Clone 25 carrying 1.2-kb mRNA had an additional splicing to join nt 2875 with nt 2894.
The 1.0-kb mRNA. The complete sequence of clone 75, one of the three 1.0-kb mRNA clones, had two splicings to join nt 185 with nt 277 and nt 711 with nt 2567 (Fig. 5). As in 1.2-kb mRNA, the first splicing was identical to that in 3.0-kb mRNA. The second splicing donor was located at the same position as that in 1.2-kb mRNA, but the coding region abutted another ORF (ORF5 [nt 2567 to 3074]) in frame 3 and terminated in T3075AA that overlapped with the poly(A) signal starting at nt 3073 (Fig. 5). The second splicing in the other two 1.0-kb mRNAs (clones 1211 and 19) spanned nt 711 to 2564 and was 3 nt shorter than those in clone 75.
Consensus sequence of splicing.
We searched the database for
the three splicings in mRNAs from 16 TTVs of five distinct genotypes,
using the GT-AG splicing rule (2) and the intron consensus
rule (11) (indicated at the top of Fig.
6).
|
| |
DISCUSSION |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
Three classes of mRNAs driven from the internal promoter in the TTV genome were recovered from COS1 cells transiently transfected with the plasmid carrying 1.3 genome lengths of a TTV of genotype 1 (VT416). Their sizes were 3.0, 1.2, and 1.0 kb, and the 3' termini of all were 7 or 10 nt downstream of the only poly(A) signal in VT416 (T3073ATAAA). Identification of the exact 5' terminus of each mRNA was not feasible with the experimental protocol used in this present study. However, the 5' termini of all 13 cDNA clones reverse transcribed from TTV mRNAs were located at a position from nt 123 to 135 immediately downstream of the putative promoter, TATA box (A85TATAA), and cap site (C98ACTCC). The results suggest strongly that the three TTV mRNAs would use the same internal promoter, the TATA box and cap site in VT416.
mRNAs in the genomic orientation were not detected in COS1 cells transfected with pBKVT*416(1.5G) carrying a TTV genome in the antisense orientation. This had to be evaluated in view of the report of one genomic and two antigenomic mRNAs in PCV (8), along with several transcription promoter motifs identified in a region (nt 521 to 13) in the genomic orientation of VT416. Although VT416 had a poly(A) signal (A271ATAAA) in the antisense orientation, the signal was not conserved in most 16 TTVs from the database. Furthermore, no TATA boxes were found downstream of this putative promoter sequence in any TTVs examined. The results suggest that TTV would not transcribe mRNAs in the genomic orientation. In this respect, TTV is distinct from PCV, which has an ambisense genome (8, 9, 13). TTV is also different from CAV in that it transcribes three species of mRNAs (20).
The first splicing, joining nt 185 with nt 277, was shared by the three mRNAs. The consensus sequence for the splicing is preserved in all 16 examined TTVs of genotype 1, 2, 3, 11, or 13, although there were minor differences in the length of splicing. Based on the obtained results, the first splicing would be ubiquitous in TTVs of all genotypes.
Only 3.0-kb mRNA possessed ORF1 (nt 589 to 2898), which has been assigned to a putative capsid protein of TTV; it had the first splicing alone. By contrast, 1.2- and 1.0-kb mRNAs had a second splicing, in addition to the first splicing in 3.0-kb mRNA, which joined nt 711 with nt 2374 and nt 711 with nt 2567. The stop codon (T713AA) predicted on ORF2 in frame 2 (nt 95 to 712) (14, 17, 24) cannot be used due to the second splicings in 1.2- and 1.0-kb mRNAs (Fig. 5, upper panel). The coding region of the 1.2-kb mRNA adjoined ORF4 (nt 2374 to 2872) in the frame 2, and that of the 1.0-kb mRNA adjoined ORF5 (nt 2553 to 3074) in frame 3 (Fig. 5, lower panel). As a result, two novel coding regions which may encode distinct TTV proteins were generated. The results of this study could not determine, however, which of the two second acceptor sites at nt 2567 and 2564 is actually operating.
The 16 TTVs of various genotypes retrieved from the database had similar ORFs in frames 2 and 3 corresponding to ORF4 and ORF5, respectively, in VT416. Furthermore, the donor and acceptor sites for the second splicings in 1.2- and 1.0-kb mRNAs of VT416 were conserved in all 16 TTVs examined. The obtained data suggest that these second splicings also would be common to TTVs of all genotypes.
Since the initiation codon proposed for ORF2 (14, 17, 24) is
no longer valid, we searched for it in TTVs of various genotypes (Fig.
5). The first A107TG in frame 2 after the cap site in VT416
should be out of frame, because the first splicing spanned 91 nt. No
ATGs are found between the cap site and the first splicing donor site
in frame 3. Moreover, the A263TG in frame 2 that was
proposed for the initiation codon (14, 17, 24) is lost by
the first splicing. Hence, three ATGs at nt 353, 431, and 596, located
between the first splicing acceptor site and the end of ORF2, would be
candidates (Fig. 5). Their positions in reference to the
A589TG of ORF1 were at 
236, 158 and +7, respectively,
in all TTVs examined (Fig. 7). They were
evaluated on the basis of Kozak's rule, which prefers A
3
or G3 and G+4 with reference to ATG
(6). Although A3 and G+4 in
A589TG of ORF1 satisfy the rule (Fig. 7), those in the
three candidate ATGs for ORF2 do so only partially. The first
A236TG is conserved in 16 of the 17 TTVs (VT416
included); the exception is TUS01, although its position was shifted in
the three TTVs of genotype 2 (JA1, US35, and US32) and the one of
genotype 13 (SANBAN). The second A158TG is conserved in
12 of the 17 TTVs used for comparison, the five exceptions being CHN2
of genotype 1, JA2B and JA10 of genotype 3, TUS01 of genotype 11, and
SANBAN of genotype 13. The third A+7TG is conserved in 14 of the 17 TTVs, the exceptions being US35 (genotype 2), TUS01 (genotype
11), and SANBAN (genotype 13). However, ATGs of US35 and TUS01 may be
reconstituted if C588 and C600, respectively,
were deleted. In that event, 16 of the 17 TTVs of various genotypes
would have A+7TG at the expected position. These
speculations, however, do not specify which of the first and third ATGs
serves as the authentic initiation codon for ORF2 in 1.2- and 1.0-kb
mRNAs.
|
Because of the second splicing, 1.2- and 1.0-kb mRNAs would code for two proteins corresponding to the regions ORF2-ORF4 and ORF2-ORF5. The presence of ORF4 and ORF5 in all TTVs in the database lends support to this view. Should the ATG at nt 353 be used, the joint polypeptides predicted in VT416 would have 286 and 290 amino acids (aa) coded for by 1.2- and 1.0-kb mRNAs, respectively. The predicted protein encoded by the 1.2-kb mRNA has a serine-rich region (aa 213 to 264). Proteins with amino acid sequences similar to the two joint proteins of TTV were searched for by FASTA. Those resembling the ORF2-ORF4 protein carried transcription factors and mammalian RNA-binding motifs with serine-rich residues. Likewise, those similar to the ORF2-ORF5 protein possessed transcription factors. Hence, both novel TTV proteins, encoded by ORF2-ORF4 and ORF2-ORF5, respectively, may be speculated to serve as regulators in the transcription of TTV DNA. The expression of these two novel proteins encoded by joint ORFs, as well as the product of putative ORF1, would have to be demonstrated by immunoassays with antibodies specific to each of them.
There is the possibility that both 1.2- and 1.0-kb mRNAs use the same A589TG in frame 1 bearing ORF1. Should this be the case, 1.2-kb mRNA would code for a 216-aa protein having the same head and tail as the product of ORF1 but lacking the middle 554 aa out of the encoded 770 aa. Likewise, 1.0-kb mRNA would code for a 144-aa protein joining ORF1 with ORF2. However, a translation start in frame 2 would be preferred, since those from frame 1 would not support the maintenance of ORF5 shared by most TTVs from the database, despite continuous evolutionary pressure in the past.
In conclusion, three distinct species of mRNA were transcribed by TTV in COS1 cells. Their profiles are distinct from those of the members of Circoviridae, such as a single nonspliced transcript for CAV (20) and two antigenomic and one genomic mRNA for PCV (8, 13). The two putative proteins encoded by novel joint ORFs, borne by 1.2- and 1.0-kb mRNAs, warrant analysis for roles in the replication of TTV.
| |
ACKNOWLEDGMENTS |
|---|
We thank D. Nameki, R. Okamoto, and A. Yamada, undergraduate students of the faculty, for technical assistance.
| |
FOOTNOTES |
|---|
* Corresponding author. Mailing address: Department of Virology, Faculty of Medicine, Tottori University, 86 Nishi, Yonago 683-8503, Japan. Phone: 81-859-34-8021. Fax: 81-859-34-8133. E-mail: hino{at}grape.med.tottori-u.ac.jp.
Present address: Animal Research Center, University of Occupational
and Environmental Health, Yahata-nishi-ku, Kitakyushu 807-8555, Japan.
| |
REFERENCES |
|---|
|
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
|---|
| 1. | Alwine, J. C., D. J. Kemp, B. A. Parker, J. Reiser, J. Renart, G. R. Stark, and G. M. Wahl. 1979. Detection of specific RNAs or specific fragments of DNA by fractionation in gels and transfer to diazobenzyloxymethyl paper. Methods Enzymol. 68:220-242[Medline]. |
| 2. |
Breathnach, R.,
C. Benoist,
K. O'Hare,
F. Gannon, and P. Chambon.
1978.
Ovalbumin gene: evidence for a leader sequence in mRNA and DNA sequences at the exon-intron boundaries.
Proc. Natl. Acad. Sci. USA
75:4853-4857 |
| 3. |
Chen, C., and H. Okayama.
1987.
High-efficiency transformation of mammalian cells by plasmid DNA.
Mol. Cell. Biol.
7:2745-2752 |
| 4. | Chomczynski, P., and N. Sacchi. 1987. Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction. Anal. Biochem. 162:156-159[Medline]. |
| 5. | Hijikata, M., K. Takahashi, and S. Mishiro. 1999. Complete circular DNA genome of a TT virus variant (isolate name SANBAN) and 44 partial ORF2 sequences implicating a great degree of diversity beyond genotypes. Virology 260:17-22[CrossRef][Medline]. |
| 6. | Kozak, M. 1984. Point mutations close to the AUG initiator codon affect the efficiency of translation of rat preproinsulin in vivo. Nature 308:241-246[CrossRef][Medline]. |
| 7. | Lisitsyn, N., N. Lisitsyn, and M. Wigler. 1993. Cloning the differences between two complex genomes. Science 259:946-951[Abstract]. |
| 8. | Mankertz, J., H. J. Buhk, G. Blaess, and A. Mankertz. 1998. Transcription analysis of porcine circovirus (PCV). Virus Genes 16:267-276[CrossRef][Medline]. |
| 9. | Meehan, B. M., J. L. Creelan, M. S. McNulty, and D. Todd. 1997. Sequence of porcine circovirus DNA: affinities with plant circoviruses. J. Gen. Virol. 78:221-227[Abstract]. |
| 10. |
Miyata, H.,
H. Tsunoda,
A. Kazi,
A. Yamada,
M. A. Khan,
J. Murakami,
T. Kamahora,
K. Shiraki, and S. Hino.
1999.
Identification of a novel GC-rich 113-nucleotide region to complete the circular, single-stranded DNA genome of TT virus, the first human circovirus.
J. Virol.
73:3582-3586 |
| 11. |
Mount, S. M.
1982.
A catalogue of splice junction sequences.
Nucleic Acids Res.
10:459-472 |
| 12. |
Mushahwar, I. K.,
J. C. Erker,
A. S. Muerhoff,
T. P. Leary,
J. N. Simons,
L. G. Birkenmeyer,
M. L. Chalmers,
T. J. Pilot Matias, and S. M. Dexai.
1999.
Molecular and biophysical characterization of TT virus: evidence for a new virus family infecting humans.
Proc. Natl. Acad. Sci. USA
96:3177-3182 |
| 13. | Niagro, F. D., A. N. Forsthoefel, R. P. Lawther, L. Kamalanathan, B. W. Ritchie, K. S. Latimer, and P. D. Lukert. 1998. Beak and feather disease virus and porcine circovirus genomes: intermediates between the geminiviruses and plant circoviruses. Arch. Virol. 143:1723-1744[CrossRef][Medline]. |
| 14. | Nishizawa, T., H. Okamoto, K. Konishi, H. Yoshizawa, Y. Miyakawa, and M. Mayumi. 1997. A novel DNA virus (TTV) associated with elevated transaminase levels in posttransfusion hepatitis of unknown etiology. Biochem. Biophys. Res. Commun. 241:92-97[CrossRef][Medline]. |
| 15. |
Noteborn, M. H.,
G. F. de Boer,
D. J. van Roozelaar,
C. Karreman,
O. Kranenburg,
J. G. Vos,
S. H. Jeurissen,
R. C. Hoeben,
A. Zantema,
G. Koch,
H. van Ormondt, and A. J. van der Eb.
1991.
Characterization of cloned chicken anemia virus DNA that contains all elements for the infectious replication cycle.
J. Virol.
65:3131-3139 |
| 16. |
Okamoto, H.,
M. Fukuda,
A. Tawara,
T. Nishizawa,
Y. Itoh,
I. Hayasaka,
F. Tsuda,
T. Tanaka,
Y. Miyakawa, and M. Mayumi.
2000.
Species-specific TT viruses and cross-species infection in nonhuman primates.
J. Virol.
74:1132-1139 |
| 17. | Okamoto, H., T. Nishizawa, N. Kato, M. Ukita, H. Ikeda, H. Iizuka, Y. Miyakawa, and M. Mayumi. 1998. Molecular cloning and characterization of a novel DNA virus (TTV) associated with posttransfusion hepatitis of unknown etiology. Hepatol. Res. 10:1-16. |
| 18. | Okamoto, H., T. Nishizawa, M. Ukita, M. Takahashi, M. Fukuda, H. Iizuka, Y. Miyakawa, and M. Mayumi. 1999. The entire nucleotide sequence of a TT virus isolate from the United States (TUS01): comparison with reported isolates and phylogenetic analysis. Virology 259:437-448[CrossRef][Medline]. |
| 19. |
Pearson, W. R., and D. J. Lipman.
1988.
Improved tools for biological sequence comparison.
Proc. Natl. Acad. Sci. USA
85:2444-2448 |
| 20. |
Phenix, K. V.,
B. M. Meehan,
D. Todd, and M. S. McNulty.
1994.
Transcriptional analysis and genome expression of chicken anaemia virus.
J. Gen. Virol.
75:905-909 |
| 21. | Pringle, C. R. 1999. Virus taxonomy at the XIth International Congress of Virology, Sydney, Australia, 1999. Arch. Virol. 144:2065-2070[CrossRef][Medline]. |
| 22. | Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y. |
| 23. |
Sanger, F.,
S. Nicklen, and A. R. Coulson.
1977.
DNA sequencing with chain-terminating inhibitors.
Proc. Natl. Acad. Sci. USA
74:5463-5467 |
| 24. | Takahashi, K., Y. Ohta, and S. Mishiro. 1998. Partial ~2.4kb sequences of TT virus (TTV) genome from eight Japanese isolates: diagnostic and phylogenetic implications. Hepatol. Res. 12:111-120[CrossRef]. |
Journal of Virology, November 2000, p. 9980-9986, Vol. 74, No. 21
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Ng, T. F. F., Suedmeyer, W. K., Wheeler, E., Gulland, F., Breitbart, M.
(2009). Novel anellovirus discovered from a mortality event of captive California sea lions. J. Gen. Virol.
90: 1256-1261
[Abstract] [Full Text] -
Ng, T. F. F., Manire, C., Borrowman, K., Langer, T., Ehrhart, L., Breitbart, M.
(2009). Discovery of a Novel Single-Stranded DNA Virus from a Sea Turtle Fibropapilloma by Using Viral Metagenomics. J. Virol.
83: 2500-2509
[Abstract] [Full Text] -
Ninomiya, M., Takahashi, M., Hoshino, Y., Ichiyama, K., Simmonds, P., Okamoto, H.
(2009). Analysis of the entire genomes of torque teno midi virus variants in chimpanzees: infrequent cross-species infection between humans and chimpanzees. J. Gen. Virol.
90: 347-358
[Abstract] [Full Text] -
Zheng, H., Ye, L., Fang, X., Li, B., Wang, Y., Xiang, X., Kong, L., Wang, W., Zeng, Y., Ye, L., Wu, Z., She, Y., Zhou, X.
(2007). Torque Teno Virus (SANBAN Isolate) ORF2 Protein Suppresses NF-{kappa}B Pathways via Interaction with I{kappa}B Kinases. J. Virol.
81: 11917-11924
[Abstract] [Full Text] -
Leppik, L., Gunst, K., Lehtinen, M., Dillner, J., Streker, K., de Villiers, E.-M.
(2007). In Vivo and In Vitro Intragenomic Rearrangement of TT Viruses. J. Virol.
81: 9346-9356
[Abstract] [Full Text] -
Ninomiya, M., Nishizawa, T., Takahashi, M., Lorenzo, F. R., Shimosegawa, T., Okamoto, H.
(2007). Identification and genomic characterization of a novel human torque teno virus of 3.2 kb. J. Gen. Virol.
88: 1939-1944
[Abstract] [Full Text] -
Kamada, K., Kuroishi, A., Kamahora, T., Kabat, P., Yamaguchi, S., Hino, S.
(2006). Spliced mRNAs detected during the life cycle of Chicken anemia virus.. J. Gen. Virol.
87: 2227-2233
[Abstract] [Full Text] -
Qiu, J., Kakkola, L., Cheng, F., Ye, C., Soderlund-Venermo, M., Hedman, K., Pintel, D. J.
(2005). Human Circovirus TT Virus Genotype 6 Expresses Six Proteins following Transfection of a Full-Length Clone. J. Virol.
79: 6505-6510
[Abstract] [Full Text] -
Suzuki, T., Suzuki, R., Li, J., Hijikata, M., Matsuda, M., Li, T.-C., Matsuura, Y., Mishiro, S., Miyamura, T.
(2004). Identification of Basal Promoter and Enhancer Elements in an Untranslated Region of the TT Virus Genome. J. Virol.
78: 10820-10824
[Abstract] [Full Text] -
Jelcic, I., Hotz-Wagenblatt, A., Hunziker, A., zur Hausen, H., de Villiers, E.-M.
(2004). Isolation of Multiple TT Virus Genotypes from Spleen Biopsy Tissue from a Hodgkin's Disease Patient: Genome Reorganization and Diversity in the Hypervariable Region. J. Virol.
78: 7498-7507
[Abstract] [Full Text] -
Kooistra, K., Zhang, Y.-H., Henriquez, N. V., Weiss, B., Mumberg, D., Noteborn, M. H. M.
(2004). TT virus-derived apoptosis-inducing protein induces apoptosis preferentially in hepatocellular carcinoma-derived cells. J. Gen. Virol.
85: 1445-1450
[Abstract] [Full Text] -
Okamoto, H., Takahashi, M., Nishizawa, T., Tawara, A., Fukai, K., Muramatsu, U., Naito, Y., Yoshikawa, A.
(2002). Genomic characterization of TT viruses (TTVs) in pigs, cats and dogs and their relatedness with species-specific TTVs in primates and tupaias. J. Gen. Virol.
83: 1291-1297
[Abstract] [Full Text] -
(2002). TT virus infection: a novel virus-host relationship. J Med Microbiol
51: 455-458
[Full Text] -
Kakkola, L., Hedman, K., Vanrobaeys, H., Hedman, L., Soderlund-Venermo, M.
(2002). Cloning and sequencing of TT virus genotype 6 and expression of antigenic open reading frame 2 proteins. J. Gen. Virol.
83: 979-990
[Abstract] [Full Text] -
Yokoyama, H., Yasuda, J., Okamoto, H., Iwakura, Y.
(2002). Pathological changes of renal epithelial cells in mice transgenic for the TT virus ORF1 gene. J. Gen. Virol.
83: 141-150
[Abstract] [Full Text] -
Okamoto, H., Nishizawa, T., Takahashi, M., Tawara, A., Peng, Y., Kishimoto, J., Wang, Y.
(2001). Genomic and evolutionary characterization of TT virus (TTV) in tupaias and comparison with species-specific TTVs in humans and non-human primates. J. Gen. Virol.
82: 2041-2050
[Abstract] [Full Text]
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Copyright © 2009 by the American Society for Microbiology. For an alternate route to Journals.ASM.org, visit: http://intl-journals.asm.org | More Info»