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J Virol, April 1998, p. 3051-3059, Vol. 72, No. 4
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Cleavage of the Feline Calicivirus Capsid Precursor
Is Mediated by a Virus-Encoded Proteinase
Stanislav V.
Sosnovtsev,
Svetlana A.
Sosnovtseva, and
Kim Y.
Green*
Laboratory of Infectious Diseases, National
Institute of Allergy and Infectious Diseases, National Institutes of
Health, Bethesda, Maryland
Received 27 August 1997/Accepted 5 December 1997
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ABSTRACT |
Feline calicivirus (FCV), a member of the
Caliciviridae, produces its major structural protein as a
precursor polyprotein from a subgenomic-sized mRNA. In this study, we
show that the proteinase responsible for processing this precursor into
the mature capsid protein is encoded by the viral genome at the
3'-terminal portion of open reading frame 1 (ORF1). Protein expression
studies of either the entire or partial ORF1 indicate that the
proteinase is active when expressed either in in vitro translation or
in bacterial cells. Site-directed mutagenesis was used to characterize the proteinase Glu-Ala cleavage site in the capsid precursor, utilizing
an in vitro cleavage assay in which mutant precursor proteins
translated from cDNA clones were used as substrates for trans cleavage by the proteinase. In general, amino acid
substitutions in the P1 position (Glu) of the cleavage site were less
well tolerated by the proteinase than those in the P1' position (Ala).
The precursor cleavage site mutations were introduced into an
infectious cDNA clone of the FCV genome, and transfection of RNA
derived from these clones into feline kidney cells showed that
efficient cleavage of the capsid precursor by the virus-encoded
proteinase is a critical determinant in the growth of the virus.
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INTRODUCTION |
Feline calicivirus (FCV) causes an
upper respiratory tract disease in cats and is an important veterinary
pathogen (10). Virions are nonenveloped capsids of
icosahedral symmetry that carry a VPg-linked 7.7-kb single-strand
positive-sense RNA genome that is polyadenylated at the 3' end. The
genome is organized into three open reading frames (ORFs). The first
(ORF1) encodes a large polyprotein that apparently undergoes
proteolytic processing during infection to produce the mature
nonstructural proteins. The second ORF (ORF2) of the FCV genome encodes
the major structural protein that is translated as a 73-kDa precursor
protein that is rapidly cleaved to yield the mature 62-kDa capsid
protein by the removal of the first 125 amino acids (aa) from the N
terminus (6, 26). The rate of this processing is relatively
high, and the capsid precursor accumulates in infected cells only under conditions that inhibit this cleavage process, such as the addition of
protease inhibitors to the growth medium or propagation of the virus at
elevated temperature (4). It has been suggested that this
cleavage is mediated by a virus-encoded enzyme because studies of the
FCV capsid precursor in an eukaryotic expression system found no
evidence for autocatalytic or host cell-mediated cleavage
(30). The third and smallest ORF (ORF3) in FCV encodes a
predicted basic polyprotein of 106 aa. Recently, a protein
corresponding to this small ORF was detected with specific antisera in
FCV-infected cells, but the function of this protein has not yet been
determined (14).
Analysis of the proteins synthesized in feline kidney cells following
infection with FCV indicates that the mature 62-kDa capsid protein is
the predominant viral protein produced. However, additional viral
proteins of 96, 75, 39, 36, and 27 kDa have been described
(4). It has been proposed that these latter proteins correspond to cleavage products from a larger polyprotein and that they
may represent nonstructural proteins. However, the boundaries of these
cleavage products have not yet been mapped for FCV, and the role of
proteolytic processing in the replication of this virus has not been
fully defined.
The regions of homologous sequence between viruses in the
Caliciviridae and those in the Picornaviridae in
both the structural and nonstructural proteins suggest similarities in
their replication strategies (3, 17, 18, 25, 32).
Picornavirus structural and nonstructural proteins are synthesized as
part of a single large polyprotein that matures in a cascade of
proteolytic events. However, a major difference between the two
families is that the calicivirus structural capsid protein is
translated from an abundant subgenomic RNA coterminal with the 3' end
of the genome (2, 5, 7, 8, 23, 24, 26). For many members of
the Caliciviridae, the mature capsid protein is thought to
be translated directly from the subgenomic RNA. Direct sequence
analysis of the N terminus of the rabbit hemorrhagic disease virus
(RHDV) capsid protein in purified virus particles mapped it to the
precise 5' end of the subgenomic RNA (28). However, in a
subset of viruses in the Caliciviridae, represented by FCV
and San Miguel sea lion virus (SMSV), a larger capsid precursor protein
undergoes proteolytic processing (4, 9). The purpose of the
present study was to characterize the proteolytic activity involved in
FCV capsid protein maturation from this larger precursor protein and
examine the role of this cleavage event in the FCV replication
strategy.
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MATERIALS AND METHODS |
Cells and virus.
Crandell-Rees feline kidney (CRFK) cell
monolayers were grown in Eagle's minimum essential medium supplemented
with 10% heat-inactivated fetal bovine serum, amphotericin B (2.5 µg/ml), chlortetracycline (25 µg/ml), penicillin (250 U/ml), and
streptomycin (250 µg/ml). The growth, purification, and molecular
characterization of the Urbana (URB) strain of FCV have been described
elsewhere (31).
Preparation of cell lysates.
CRFK monolayers (7 × 105 cells) were mock infected or infected with FCV at a
multiplicity of infection of 10 and incubated at 37°C. At 6 h
postinfection, the cells were washed once with phosphate-buffered
saline (PBS), removed by scraping into fresh PBS, and pelleted by
centrifugation at 8,000 × g for 5 min. The pellet was
suspended in 300 µl of PBS and subjected to three cycles of
freezing-thawing. The resulting lysate was clarified by
centrifugation at 15,000 × g for 20 min and stored
at 
70°C.
For radiolabeling of virus-specific proteins, FCV-infected CRFK cells
were washed at 4 h postinfection with methionine-free growth
medium and incubated in the same medium for 30 min.
[35S]methionine (>1,000 Ci/mmol; Amersham) was added to
cells at a concentration of 150 µCi/ml, and the mixture was incubated
for 3 h. The cells were washed with PBS before lysis in 300 µl
of radioimmunoprecipitation assay (RIPA) buffer (29).
Plasmid construction.
Standard recombinant DNA methods were
used for plasmid constructions (29). The numbering of the
FCV nucleotide sequence in this study was derived from the complete
genome sequence of FCV strain URB deposited in GenBank under accession
no. L40021.
Plasmids pfI-21, pfI-20, pfI-45, pfI-9, pfI-19, pfI-28, and pfI-34 were
selected by hybridization and restriction analysis
from a cDNA library
of the FCV RNA genome cloned into the pSPORT1
vector (
31).
These clones all contained ORF2, ORF3, a poly(A)
tract, and various
lengths of the C-terminal part of ORF1 upstream
of ORF2 (Fig.
1A).
Sequence analysis mapped the 5' ends of these
clones to nucleotides
(nt) 5316, 5194, 4820, 4704, 4370, 3094,
and 2989, respectively, of the
FCV genome.
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FIG. 1.
(A) Organization of the FCV genome (URB strain) and
depiction of cDNA clones analyzed in this study. The corresponding
genomic locations of the two major positive-sense RNA species (7.6 and
2.4 kb) found in infected cells and the location of the cleavage site
(E124/A125) of the capsid precursor protein
encoded in ORF2 are indicated. Clones pfI-21, pfI-20, pfI-45, pfI-9,
pfI-19, pfI-28, and pfI-34 were selected from a cDNA library of the URB
strain that was constructed by using the pSPORT plasmid (31)
and contained nt 5316, 5194, 4820, 4704, 4370, 3094, and 2989, respectively, through a poly(A) tract from the URB genome, each under
control of the T7 promoter. The location of the first in-frame AUG
following the T7 promoter is indicated for each clone. Plasmids pTMF1,
pVPP, and pf 20 were engineered as described in Materials and
Methods. (B) Conditions under which in vitro cleavage of the FCV capsid
precursor
protein derived from plasmid pf20 were observed. Lane
1, 60-kDa protein corresponding to the mature viral capsid protein
immunoprecipitated (Immunoppt.) from an FCV-infected CRFK lysate with
gp  -FCV; lane 2, in vitro TNT translation products synthesized from
pf20 without treatment. The translation products from pf20 were
treated as follows prior to analysis by SDS-PAGE: lane 3, incubation at
37°C for 3 h; lane 4, incubation (3 h, 37°C) with a
nonradiolabeled CRFK lysate prepared from mock-infected cells; lane 5, incubation (3 h, 37°C) with a nonradiolabeled CRFK lysate prepared
from FCV-infected cells; lane 6, incubation (3 h, 37°C) with
nonradiolabeled translation products synthesized from pTMF-1. (C)
Comparison of radiolabeled translation products derived from pTMF-1
(encoding the URB ORF1) with proteins produced in FCV-infected CRFK
cells. Proteins produced in mock-infected (lane 1) or FCV-infected
(lane 2) CRFK cells were analyzed in a Western blot reacted with cat
FCV postinfection serum. The same infection serum was used to
immunoprecipitate (Immunoppt.) radiolabeled TNT products derived from
pTMF-1 (lane 3). Lane 4, immunoprecipitation analysis of radiolabeled
TNT products derived from pTMF-1 with cat preinfection serum. The
location of the mature capsid protein and its dimeric form in the
FCV-infected CRFK cell lysate is shown. Asterisks denote proteins
similar in size (indicated in kilodaltons) between ORF1 TNT products
and the FCV-infected CRFK cell lysate. (D) Comparison of products
produced by in vitro translation of cDNA clones encoding the ORF2 (with
various lengths of upstream ORF1 sequence) with the mature 60-kDa
capsid protein produced in virus-infected cells. Radiolabeled products
(in all lanes) underwent immunoprecipitation with either
preimmunization (lane 1) or postimmunization (lanes 2 to 9) gp -FCV,
as follows: lanes 1 and 2, FCV-infected CRFK lysate; lane 3, pf20;
lane 4, pfI-20; lane 5, pfI-45; lane 6, pfI-9; lane 7, pfI-19; lane 8, pfI-28; lane 9, pfI-34.
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Plasmid pf
20 was created by excision of the
NspV-
SmaI fragment from plasmid pfI-20, followed
by treatment with the Klenow
fragment of DNA polymerase I and
recircularization of the plasmid,
resulting in a clone that contained
the 3'-terminal part of the
FCV genome starting at nt 5302.
Plasmid pTMF-1 was constructed by subcloning the 5,282-bp
AspI-
NspV fragment of plasmid pQ14
(
31) into
NcoI-digested pTM-1
vector (provided by
B. Moss, National Institute of Allergy and
Infectious Diseases) after
filling in of the protruding restriction
ends of the plasmid and the
fragment. The resulting plasmid contained
the T7 RNA polymerase
promoter, the encephalomyocarditis virus
internal ribosome entry site,
and the entire ORF1 of the FCV genome
with the exception of the two
C-terminal codons.
Plasmid pVPP was constructed as follows. pTMF-1 was cleaved with
BsaI, followed by incubation with Klenow enzyme first in
the
presence of dGTP and then in the presence of dATP. The fragments
with
partially filled-in protruding ends were further treated
with
XhoI, and a 2,503-bp fragment was isolated. This fragment
was ligated into the Acc65.1 (modified by treatment with Klenow
enzyme
in the presence of dGTP and dTTP) and
XhoI sites of the
pET-29c plasmid (Novagen) downstream from the T7 promoter, and
the
selected clone was designated pVPP.
Site-directed mutagenesis of the capsid precursor cleavage
site.
An intermediate plasmid, designated pfKBS11, was prepared by
ligation of a 1,012-bp KpnI/SpeI fragment
obtained from pfI-20 into the same sites of the pLITMUS28 vector (New
England Biolabs). DNA fragments were amplified from plasmid pfKBS11 by
PCR using a sense primer corresponding to nt 5297 to 5319 of the genome and an antisense primer corresponding to nt 5678 to 5703. The antisense
primers were used to introduce mutations into either the P1 or P1'
position of the wild-type cleavage site sequence (Glu124/Ala125:5683GAAGCT5688).
The P1 position mutations were GAA to CTC for Leu, CAC for His, GAT for
Asp, AAG for Lys, and CAG for Gln. The P1' position mutations were GCT
to GTT for Val, CGT for Arg, CTT for Leu, GGT for Gly, CAT for His, and
CCT for Pro. Purified PCR-generated DNA fragments were treated with
NspV and BamHI and ligated back into the
compatible sites of pfKBS11. Clones were screened by sequence analysis,
and plasmids containing desired mutations in the cleavage site were
selected and designated pm(P1/P1'), with the amino acid sequence of P1
and P1' for each mutant designated by the single-letter code. The
FCV-specific fragments were then excised from the pfKBS11 derivatives
by digestion with NspV and SpeI and used to
replace the wild-type sequences in pfI-20. The resulting clones were
designated pf20m(P1/P1'). The same NspV-SpeI fragments were used to
introduce capsid precursor cleavage site mutations into the full-length
genomic clone pQ14, and the resulting clones were designated
pQm(P1/P1'). Mutations in the selected clones were confirmed by
sequence analysis.
In vitro coupled transcription-translation experiments.
One
microgram of plasmid DNA was used as the template in a coupled
transcription-translation reaction (TNT T7 coupled reticulocyte lysate
system; Promega). For radiolabeling of synthesized protein, [35S]methionine (>1,000 Ci/mmol) from ICN or Amersham
was used at a concentration of 1.5 mCi/ml.
Precursor cleavage assay and analysis of protease
inhibitors.
Nonradiolabeled lysates of FCV-infected CRFK cells
were incubated for 1 to 3 h at 37°C with the radiolabeled capsid
precursor protein produced by transcription and translation of pf20.
The integrity of the capsid precursor was then analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) using a
minigel system (Novex). Protease inhibitors were added to the
FCV-infected CRFK cell lysates and incubated for 15 min at 37°C prior
to mixing with radiolabeled capsid precursor protein. Inhibitors tested
were antipain dihydrochloride (50 µg/ml), aprotinin (2 µg/ml),
bestatin (40 µg/ml), chymostatin (60 µg/ml), EDTA (2 mM), E-64 (10 µg/ml), leupeptin (0.5 µg/ml), phenylmethylsulfonyl fluoride (PMSF;
170 µg/ml), PefablocSC (1 µg/ml), pepstatin (0.7 µg/ml), and
phosphoramidon (200 µg/ml), purchased from Boehringer Mannheim;
N-ethylmaleimide (1 mM), iodoacetic acid (2 mM), cystatin (100 µg/ml), N-tosyl-L-phenylalanine
chloromethyl ketone (TPCK; 100 µg/ml), and
N-p-tosyl-L-lysine chloromethyl
ketone (TLCK; 50 µg/ml), from Sigma Chemical Co.; and
ZnCl2 (1 mM), from Fluka AG.
Immunoprecipitation and Western blot analysis.
Fifty
microliters of the radiolabeled FCV-infected CRFK cell lysate was
diluted with 50 µl of RIPA buffer and incubated at 4°C for 1 h
with 5 µl of guinea pig antiserum raised against purified viral
particles (gp -FCV) or guinea pig preimmunization serum. After
incubation with serum, 50 µl of a 50% slurry of protein G beads
(Pharmacia) prewashed with RIPA buffer was added to the lysates. The
mixture was gently rotated overnight at 4°C. The beads were pelleted
by centrifugation at 12,000 × g and then washed twice
with 1 ml of RIPA buffer, twice with 1 ml of washing buffer (1 M NaCl,
0.01 M Tris-HCl [pH 7.2], 0.1% Nonidet P-40) and twice with 1 ml of
0.01 M Tris-HCl (pH 7.2). The precipitated proteins were extracted from
the beads by boiling in SDS-PAGE sample buffer with 2% mercaptoethanol
for 5 min prior to analysis by SDS-PAGE.
For the immunoprecipitation of FCV nonstructural proteins synthesized
in vitro, 15 µl of the TNT translation reaction was
diluted with 80 µl of RIPA buffer and heated for 10 min at 60°C.
The proteins were
then incubated for 1 h at room temperature with
5 µl of cat FCV
infection or preinfection sera (gifts from W.
Mengeling, U.S.
Department of Agriculture), and the immune complexes
were precipitated
with protein A beads (Sigma). Binding and washing
conditions were the
same as those described above.
Western blot analysis was performed by using standard techniques
(
29). Following electrophoretic transfer of proteins to
nitrocellulose, the membrane was incubated with cat FCV infection
serum
(1:1,000 dilution). The binding of cat antibodies was detected
with
anti-cat immunoglobulins conjugated with phosphatase (Kirkegaard
& Perry Laboratories) followed by development with alkaline phosphatase
(AP) substrate reagents (Gibco BRL). In the Western blot analysis
to
detect histidine-tagged proteins, a nickel-nitrilotriacetic
acid
(Ni-NTA)-AP conjugate (Qiagen) was used according to the
manufacturer's protocol.
Recovery of recombinant virus.
In vitro transcription of
synthetic, capped RNA from full-length genomic cDNA clones and RNA
transfection experiments were conducted as described previously
(31). Following incubation for 16 or 26 h at 37°C,
transfected CRFK cell monolayers were analyzed by immunofluorescence
with gp -FCV and -gp immunoglobulins conjugated with fluorescein
(31). In parallel experiments, monolayers were incubated for
30 min with methionine-free medium, and proteins were radiolabeled as
described above. Recovery of infectious virus was confirmed by
transferring an aliquot of culture medium from transfected cells onto
fresh CRFK monolayers.
Amino acid substitutions in the capsid protein from recovered viruses
purified by CsCl gradient centrifugation (
24) were
confirmed
by direct N-terminal sequence analysis. Viral proteins
were separated
by SDS-PAGE using tricine running buffer (Novex),
transferred to a
ProBlott membrane (Applied Biosystems), and visualized
on the membrane
by staining with 0.1% Coomassie blue R-250-40%
methanol-1% acetic
acid and destaining in 50% methanol. The band
of interest was excised
and subjected to N-terminal sequence analysis
with a model 477A protein
sequencer coupled to a model 120A PTH
Analyzer (Applied Biosystems)
according to the manufacturer's
program, NORMAL-1.
The presence of engineered mutations in the genomes of recovered
viruses was also confirmed by direct sequence analysis of
reverse
transcriptase (RT)-mediated PCR (RT)-PCR products derived
from viral
RNA. Primers used for amplification were a sense primer
corresponding
to nt 5297 to 5319 of the genome, described above,
and an antisense
primer corresponding to nt 6196 to 6216. In addition,
as a control for
the presence of DNA from the original plasmid
used to synthesize the
RNA for transfection, the PCR was performed
without an initial RT
reaction. The agarose gel-purified DNA fragments
were sequenced by
using a cycle sequencing kit from Gibco BRL
and a sense primer
corresponding to nt 5530 to 5550 of the genome.
Expression of the protease in Escherichia coli.
E.
coli BL21(DE3) cells were transformed with either plasmid pVPP or
plasmid pET-29c, and transformed cells were grown in the presence of
carbenicillin (50 µg/ml) in LB medium at 37°C. When the
A600 of the culture reached 0.8, expression was
induced by the addition of 1 mM
isopropyl-
-D-thiogalactopyranoside (IPTG). After 4 h, cells were collected by centrifugation at 4,000 × g for 15 min and the pellets were suspended in buffer containing 300 mM
NaCl and 50 mM Na2HPO4 (pH 7.8) in 1/10 of the
original culture volume. After freezing-thawing, the bacteria were
sonicated (crude lysate) and subjected to centrifugation at 12,000 × g for 20 min. The supernatant (soluble fraction) was
collected, and the pellet (insoluble fraction) was suspended in the
same buffer, sonicated, and collected again by centrifugation.
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RESULTS |
Expression of FCV capsid precursor protein in a coupled in vitro
transcription-translation system.
Clones containing ORF2 from a
cDNA library of the URB strain of FCV were selected for analysis of
capsid precursor expression in the TNT system (Fig. 1A). To optimize
protein synthesis in this system, plasmid pfI-20 was engineered to
remove ORF1 sequences upstream of the beginning of ORF2 that contained
additional AUG codons. The resulting plasmid, designated pf20,
contained the first AUG of ORF2 directly under control of the T7 RNA
polymerase promoter. Analysis of the translation products from pf20
by SDS-PAGE revealed the efficient synthesis of two major bands
corresponding to proteins with molecular sizes of 73 and 70 kDa (Fig.
1B, lane 2). The 73-kDa protein was consistent in size with the
predicted full-length product of synthesis from ORF2, while the 70-kDa
protein was consistent with the predicted product (69.2 kDa) resulting from efficient initiation at the second AUG of ORF2. In some
translation experiments of clones containing ORF2, we observed
additional minor bands corresponding to proteins of 64 and 56 kDa,
sizes consistent with those calculated for proteins produced by
internal initiation at other AUGs in the template. All proteins
described above were recognized by gp -FCV in immunoprecipitation
experiments and were not recognized by gp preimmunization serum (data
not shown). Translation of the capsid proteins in the presence of canine microsomal membranes did not lead to changes in the observed mobility of the proteins (data not shown).
Evidence for cleavage of the FCV capsid precursor by a
virus-encoded protease.
The conditions under which the capsid
precursor could be processed into the mature capsid protein were
examined. Reticulocyte lysates containing the translated capsid protein
from clone pf20 were incubated at 37°C for various lengths of time
up to 12 h, but no evidence for autocatalytic cleavage of the
precursor in the reticulocyte lysates was found (Fig. 1B, lane 3).
Similarly, no evidence for cleavage was observed following incubation
of the precursor with lysates prepared from noninfected CRFK cells (Fig. 1B, lane 4). However, incubation of the precursor with a lysate
prepared from FCV-infected CRFK cells led to the appearance of a band
(Fig. 1B, lane 5) corresponding in size to the mature radiolabeled URB
FCV capsid protein (60 kDa) immunoprecipitated from an FCV-infected
CRFK cell lysate (Fig. 1B, lane 1). Taken together, these data
suggested the presence of a proteinase in FCV-infected cells that could
cleave the capsid precursor substrate in trans.
To address whether the ORF1 of the FCV genome encoded a proteinase
responsible for the cleavage of the capsid precursor, we
cloned the URB
ORF1 into the pTM-1 plasmid (designated pTMF-1).
Analysis of the in
vitro translation products synthesized from
the pTMF-1 translation
mixture showed evidence for autocatalytic
cleavage of the encoded ORF1
polyprotein. Instead of the predicted
polyprotein with an estimated
size of 195 kDa, we observed at
least four major protein bands with
sizes ranging from approximately
30 to 80 kDa and several minor bands
including a protein of approximately
14 kDa that were
immunoprecipitated with cat FCV infection serum
(Fig.
1C, lane 3). The
proteins were not recognized by cat preinfection
serum (Fig.
1C, lane
4). These four major proteins corresponded
in size to four bands
detected in FCV-infected CRFK cells in a
Western blot reacted with the
cat FCV infection serum (Fig.
1C,
lane 2). These proteins were not
recognized by cat preinfection
serum (Fig.
1C, lane 1), although the
cat preinfection serum did
show reactivity with an apparently nonviral
62-kDa protein present
in both FCV-infected and mock-infected cell
lysates. The similarity
between these proteins produced from in vitro
translation of ORF1
and those in FCV-infected cells suggested that the
protease sequences
encoded in ORF1 were sufficient to mediate cleavage
of the ORF1
polyprotein in the absence of cellular factors and that the
majority
of proteins synthesized in vitro were identical in size to
mature
forms of viral nonstructural proteins in infected cells. The
nonradiolabeled
ORF1 translational products derived from pTMF-1 were
incubated
with radiolabeled capsid precursor protein derived from in
vitro
translation of pf
20. Analysis of the products of this
incubation
by SDS-PAGE revealed the presence of mature, cleaved capsid
protein,
consistent with
trans cleavage of the capsid
precursor by a proteinase
encoded in ORF1 (Fig.
1B, lane 6).
Polypeptides consistent in
size with the cleaved N-terminal part of the
capsid precursor
could be detected as faint bands in a high-percentage
polyacrylamide
gel (data not shown).
Mapping the FCV protease gene responsible for cleavage of the
capsid precursor.
Further localization of the region of the FCV
genome encoding the protease was facilitated by the observation that
the capsid precursor protein could be efficiently translated from
clones that contained various lengths of the viral genome upstream of the first AUG of ORF2. The 73-kDa precursor protein was detected following transcription and translation of plasmids pf20 and pfI-20
(Fig. 1D, lanes 3 and 4), which contained either 12 or 120 nt of
upstream ORF1 sequence, respectively. The 73-kDa protein was also
produced efficiently from plasmids pfI-45, pfI-9, and pfI-19,
containing the upstream 489, 605, and 939 nt, respectively, of ORF1
(Fig. 1D, lanes 5 to 7). Efficient synthesis of the capsid precursor
was observed for noncapped RNA in the TNT system as well as for capped
RNA in a noncoupled translation reaction (data not shown). We next
examined the synthesis of capsid protein from two plasmids, pfI-28 and
pfI-34, that contained upstream ORF1 sequences (a total of 2215 and
2319 nt, respectively) analogous to the 3C protease region of the
picornaviruses that had been defined by Neill (25) as
encompassing nt 3284 to 3694 (aa 1089 to 1225). In contrast to the
plasmids that did not contain 3C protease region sequences, a 60-kDa
band was observed among the products of translation of pfI-28 and
pfI-34 that was immunoprecipitated with gp -FCV (Fig. 1D, lanes 8 and 9). This 60-kDa band was consistent with the mature form of the
capsid protein immunoprecipitated from FCV-infected CRFK cells (Fig.
1D, lane 2). The efficient cotranslational cleavage of the precursor
encoded in pfI-34 was indirect evidence for the synthesis of an active
proteinase. The first predicted methionine in the upstream ORF1
sequence of pfI-34 was located at nt 3032, and initiation at this
methionine (aa 1005) would result in the translation of a protein that
included the entire 3C region defined by Neill. In contrast, initiation at the first methionine (aa 1100) of pfI-28 would result in the synthesis of a truncated 3C region product.
Subcloning of the C-terminal part of the ORF1 was carried out to
further characterize the proteins encoded in this region
of the FCV
genome. pVPP contained nt 2843 to 5303 of the URB genome
in the pET-29c
vector so that the sequence encoding the 820 amino
acid residues of the
C-terminal part of the ORF1 could be expressed
in either the TNT system
or in bacteria as a protein fused to
a His
6tag at its C
terminus. Incubation of nonradiolabeled TNT
products derived from pVPP
with the radiolabeled capsid precursor
synthesized from pf
20 led to
the efficient processing of the
precursor into the mature capsid form
(Fig.
2, lane 3), indicating
that the
proteinase encoded in pVPP was active in the in vitro
trans
cleavage assay. Cleavage of the radiolabeled capsid precursor
was
observed also after incubation with crude lysates of IPTG-induced
E. coli cells harboring pVPP (Fig.
2, lane 6) but not after
incubation
with lysates of noninduced pVPP-transformed cells (Fig.
2,
lane
5) or IPTG-induced cells harboring vector plasmid pET-29c (Fig.
2,
lane 4). Virus-specific protease activity was detected in soluble
as
well as insoluble fractions of bacterial cell lysates (data
not shown).
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FIG. 2.
Analysis of the proteolytic activity of the proteins
encoded in plasmid pVPP in the capsid precursor trans
cleavage assay. Lane 1, immunoprecipitation (Immunoppt.) of
radiolabeled FCV-infected CRFK cell lysate with gp -FCV. Lane 2, pf20 translation products, without treatment. The radiolabeled
capsid precursor protein was incubated with the following
nonradiolabeled preparations prior to analysis by SDS-PAGE: lane 3, in
vitro TNT translation products synthesized from pVPP; lane 4, E. coli crude cell lysate prepared from IPTG-induced bacteria
containing the pET-29c vector plasmid; lane 5, E. coli crude
cell lysate from noninduced bacteria carrying plasmid pVPP; lane 6, E. coli crude cell lysate from IPTG-induced bacteria
carrying plasmid pVPP.
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Analysis of radiolabeled TNT products derived from pVPP showed the
presence of several proteins with sizes ranging from approximately
14 to 95 kDa that could be immunoprecipitated with cat FCV infection
serum
(Fig.
3, lane 11). A faint 95-kDa band corresponded in size
to the
predicted full-length product of translation from pVPP,
but the major
protein observed was approximately 78 kDa. Of interest,
an
approximately 78-kDa protein was present in a FCV-infected
cell lysate
(Fig.
1C, lane 2) and in the in vitro translation
products derived from
pTMF-1 (encoding the entire ORF1) (Fig.
3, lane 13) that was recognized
by antibodies in the cat FCV infection
serum.
The proteins expressed by bacteria carrying plasmid pVPP were analyzed
by SDS-PAGE and Western blotting. Coomassie blue staining
showed two
major proteins of 78 and 18 kDa in the insoluble fraction
(Fig.
3, lane 3) that did not correspond to the
major bands of
the pET-29c soluble and insoluble fraction controls
(Fig.
3, lanes
1 and 2). A major 14-kDa protein was observed in the
soluble fraction
of bacterial cells harboring pVPP (Fig.
3, lane 4)
that comigrated
with a protein of similar size in the soluble fraction
of bacterial
cells harboring pET-29c (Fig.
3, lane 1). A Western blot
of these
fractions reacted with cat infection serum indicating that the
78-, 18-, and 14-kDa proteins were derived from FCV (Fig.
3, lanes
5 and 6). The proteins on nitrocellulose were probed also with
a
Ni-NTA-AP conjugate in order to localize the C-terminal His
tag. The
78-kDa protein was recognized efficiently, mapping it
to the 3' end of
pVPP and, therefore, the carboxy-terminal end
of the FCV ORF1 (Fig.
3,
lane 9). Cleavage of the 78-kDa protein
from a 95-kDa precursor would
result in an N-terminal cleavage
product of approximately 18 kDa. The
in vitro translation reaction
of pVPP contained both 18- and 14-kDa
proteins (Fig.
3, lane 11),
and a time course analysis showed an
accumulation of the 14-kDa
protein with a relative decrease in the
amount of 18-kDa protein
(data not shown). Thus, it appeared that the
14-kDa protein expressed
from pVPP that was observed in the TNT
reactions and in the bacteria
resulted from further proteolytic
processing of the 18-kDa N-terminal
sequence. The absence of
intermediate-sized proteins between 95
and 78 kDa suggested that this
cleavage event occurred in
trans following the release of
the 18-kDa protein from the 95-kDa precursor.
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FIG. 3.
Analysis of proteins encoded in plasmid pVPP. Bacteria
carrying either plasmid pVPP or the vector plasmid pET-29c were induced
with IPTG, and the soluble (S) or insoluble (I) bacterial products were
prepared as described in the text. The bacterial products were
subjected to SDS-PAGE and visualized with Coomassie blue stain: lane 1, pET-29c, soluble fraction; lane 2, pET-29c, insoluble fraction; lane 3, pVPP, insoluble fraction; lane 4, pVPP, soluble fraction. The same
products were analyzed in a Western blot developed with cat
postinfection serum: lane 5, pVPP, insoluble fraction; lane 6, pVPP,
soluble fraction; lane 7, pET-29C, insoluble fraction; lane 8, pET-29c,
soluble fraction. The insoluble fractions of pVPP or pET-29c were
transferred to nitrocellose and probed with Ni-NTA-AP: lane 9, pVPP;
lane 10, pET-29c. The radiolabeled TNT in vitro translation products
derived from pVPP were immunoprecipitated (Immunoppt.) with either
postinfection (lane 11) or preinfection (lane 12) cat serum. Lane 13, radiolabeled TNT products derived from pTMF-1 immunoprecipitated with
cat postinfection serum.
|
|
A panel of commercially available protease inhibitors was examined for
its effect on the proteinase and tested at either the
working
concentrations recommended by the manufacturer or at concentrations
10 times higher. The effect of the inhibitors on the ability of
the
proteinase present in FCV-infected CRFK cell lysates to cleave
the
precursor in
trans is shown in Fig.
4. A strong inhibitory
effect was
observed for the cysteine protease inhibitors ZnCl
2 and
N-ethylmaleimide at their recommended working concentrations
(Fig.
4, lanes 1 and 3) but was not observed for iodoacetic acid
(lane
5). Strong inhibition was not observed with papain-like
cysteine
protease inhibitors (cystatin and E-64; lanes 2 and 4),
a papain
protease inhibitor (antipain; lane 6), serine protease
inhibitors
(leupeptin, PMSF, chymostatin, PefablocSC, and aprotinin;
lanes 7 to
11), metalloprotease inhibitors (EDTA and phosphoramidon;
lanes 12 and
13), an amino peptidase inhibitor (bestatin; lane
14), or an aspartic
acid protease inhibitor (pepstatin; lane 15)
at their recommended
concentrations (Fig.
4). However, the protease
activity appeared to be
sensitive to TPCK, TLCK, and concentrated
quantities of iodoacetic acid
(data not shown). Cleavage of the
precursor was not observed when the
FCV-infected cell lysate was
incubated at 42°C for 15 min prior to
incubation with the precursor
(Fig.
4, lane 16).
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|
FIG. 4.
Effects of selected protease inhibitors or temperature
on the ability of the protease present in FCV-infected CRFK lysates to
cleave in trans the capsid precursor protein translated from
pf20. In lanes 1 to 15, the indicated protease inhibitors were
incubated with the FCV-infected CRFK lysate prior to incubation with
the translated precursor protein under conditions described in the
text. Lane 16, incubation of FCV-infected cell lysate at 42°C for 20 min prior to incubation with the capsid precursor; lane 17, precursor
protein incubated with nontreated FCV-infected CRFK lysate.
|
|
Mutagenesis of the FCV proteinase cleavage site in the capsid
protein precursor.
PCR was used to introduce changes into either
the P1 or P1' positions of the capsid precursor protein wild-type
cleavage site (E/A) (Fig. 5A), resulting
in mutated precursor clones (p20m L/A, H/A, D/A, K/A, Q/A, E/V, E/R,
E/L, E/G, E/H, and E/P) that were used as templates for in vitro
synthesis of capsid precursor proteins in a TNT reaction. Synthesized
precursors were incubated at 37°C with nonradiolabeled TNT mixtures
derived from pVPP as the source of proteinase. Incubation of the
proteinase with the radiolabeled TNT products from pfI-20 that
contained the wild-type precursor cleavage site showed the cleavage of
the precursor into the mature capsid protein (Fig. 5B, lane 2). No
evidence for cleavage was observed when the proteinase was incubated
with precursors that contained L, H, and K mutations in the P1 position
(Fig. 5B, lanes 3, 4, and 6); however, weak specific cleavage was
observed for precursors that possessed D and Q in the P1 position (Fig.
5B, lanes 5 and 7). Of the six amino acid substitutions introduced into
the P1' position of the cleavage site, five (V, R, L, G, and H) allowed
cleavage of the precursor (Fig. 5B, lanes 8 to 12), while one (P) did
not (Fig. 5B, lane 13). Differences in the rates of cleavage were
detectable among the five mutants that showed complete cleavage early
in the first hour of the reaction, but the final cleavage reaction
appeared similar among the mutants at the end of the incubation period
(data not shown).
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FIG. 5.
Analysis of the effects of amino acid mutations
introduced into the cleavage site of the FCV capsid precursor protein
on the efficiency of cleavage by the viral proteinase as measured in
the in vitro trans cleavage assay or by the ability of the
virus to grow in cell culture. (A) Sequence of cleavage site between
the precursor leader sequence and the mature capsid protein into which
amino acid substitutions were introduced. (B) The radiolabeled capsid
precursor proteins derived from in vitro translation of pfI-20 or
engineered plasmids containing mutant cleavage sites [clones
pf20m(P1/P1')] were incubated with nonradiolabeled translation
products derived from plasmid pVPP. The first lane contains the pfI-20
translation products without treatment. (C) Capped, synthetic RNA from
individual full-length clones that contained the mutant cleavage sites
[clones pQm(P1/P1')] were transfected into CRFK cells, and proteins
synthesized in cells were radiolabeled with
[35S]methionine. The following cell lysates were analyzed
by immunoprecipitation with gp -FCV serum: lane 1, mock-infected
CRFK cells; lane 2, CRFK cells transfected with RNA derived from pQ14;
lanes 3 to 13, CRFK cells transfected with RNA derived from plasmids
pQm(P1/P1'). (D) Effects of mutations in the P1 or P1' position of the
precursor cleavage site on the ability to recover viable virus from
engineered full-length infectious clones. In a separate experiment, an
aliquot of cell culture medium from cells transfected with RNA derived
from each of the pQm(P1/P1') clones was transferred to a fresh CRFK
monolayer. Clones that did (+) and did not () yield viable progeny
are indicated.
|
|
To analyze the effects of alterations in the capsid precursor cleavage
site on virus replication, we constructed a series
of full-length
genomic clones by engineering DNA fragments with
the corresponding
precursor mutations into the infectious FCV
clone, pQ14. The resulting
clones (pQm L/A, H/A, D/A, K/A, Q/A,
E/V, E/R, E/L, E/G, E/H, and E/P)
were used to produce synthetic
genomic RNAs for transfection
experiments. Immunoprecipitation
analysis of labeled capsid protein
from transfected cells confirmed
the expression of ORF2 for all the
capsid precursor mutants (Fig.
5C). In addition, we observed a marked
similarity between the
processing of the capsid precursor in cells and
that in the in
vitro cleavage assay (Fig.
5B and C). The apparent
accumulation
of the 73-kDa protein in cells transfected with RNA from
plasmids
encoding mutant cleavage sites that were not cleaved by the
proteinase
suggested that the first AUG of the precursor may be
preferentially
utilized in cells. The immunoprecipitation products of
the noncleaved
capsid precursor from pQm H/A expressed in cells (Fig.
6, lane
3) were compared directly with
those synthesized in the TNT system
from pfI-21 (a cDNA clone in the
library that lacked the first
AUG of ORF2) (Fig.
6, lane 1) and pf
20
(a clone that contained
the first AUG of ORF2) (Fig.
6, lane 2). The
presence of only
the 73-kDa protein in the cell lysates from pQm H/A
indicated
that the first AUG of ORF2 is utilized preferentially in
cells.
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FIG. 6.
Comparison of FCV capsid precursor polyprotein expressed
in vitro and in transfected cells. Lanes 1 and 2, radiolabeled products
of in vitro translation of pfI-21 and pf20, respectively; lanes 3, and 4, immunoprecipitation of radiolabeled precursor with gp -FCV
and gp preimmunization serum, respectively, from CRFK cells transfected
with capped genomic RNA that encoded the H/A mutant cleavage site.
|
|
Transfer of medium from transfected cells to fresh CRFK monolayers
allowed the recovery of FCV for mutants showing complete
cleavage of
the precursor in cells (pQm E/V, E/R, E/L, E/G, and
E/H) (Fig.
5D). A
time course titration for the recovered viruses
from these mutants did
not reveal significant differences in their
growth characteristics in
comparison with each other or with virus
recovered from pQ14 (data not
shown). Transfected CRFK cell monolayers
were analyzed at 16 h
posttransfection by immunofluorescence using
gp
-FCV. All wells
transfected with genomic RNAs contained intensely
stained cells at
16 h posttransfection, including those mutants
with capsid
precursor cleavage sites that were not cleaved in
the in vitro assay
and from which virus could not be recovered
(data not shown). However,
the observation of transfected cells
at 26 h posttransfection by
immunofluorescence allowed the detection
of marked differences in the
distribution of positive cells between
viable and nonviable mutants as
illustrated in Fig.
7. Figure
7A shows
the pattern of fluorescence from viable mutant pQm E/G
that was similar
in appearance to that of wild-type infectious
FCV foci in CRFK
monolayers. In contrast, Fig.
7B shows the pattern
of fluorescence from
nonviable mutant pQm Q/A in which single,
positively stained cells
remained distributed throughout the monolayer.
Capsid expression was
not observed by immunofluorescence in control
transfection experiments
in which full-length, capped transcript
RNAs derived from cDNA clones
of RNA replication-defective FCV
mutants were used, indicating that the
positive signal observed
with the capsid precursor mutants was not due
to translation of
the newly-transfected RNA (data not shown). Recovered
viruses
were amplified in CRFK cells and purified by gradient
centrifugation.
Direct sequence analysis of the capsid protein from
purified viruses
confirmed the presence of corresponding mutations at
the N terminus
for the E/L, E/V and E/G mutant viruses. However, the
identity
of the N-terminal amino acid for the E/R and E/H mutants could
not be determined by direct protein sequence analysis, and the
mutations in these viruses were confirmed by sequence analysis
of
RT-PCR products derived from the genomic RNA of the purified
viruses.
Viruses could not be recovered from cells transfected
with pQm Q/A and
pQm D/A, although mature, processed capsid protein
was observed in the
radiolabeled cell lysates. To examine whether
infectious virus was
retained in an intracellular compartment.
CRFK monolayers were
transfected with RNA from these two plasmids
in three separate
experiments. After 24 h, the transfected cells
were frozen,
thawed, and passed onto fresh cells. No evidence
for infectious virus
was found.
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FIG. 7.
Immunofluorescence of CRFK cells transfected 26 h
previously with full-length capped, synthetic RNA from pQm E/G (A) and
pQm Q/A (B).
|
|
| |
DISCUSSION |
Synthesis of the FCV capsid precursor protein is detected in cells
as early as 2 h following infection, but the protein is rapidly
cleaved into the 62-kDa mature capsid (4). In the present work, we demonstrate that the proteinase responsible for this cleavage
is encoded in the C-terminal part of ORF1 of the FCV genome. A
virus-specific protein of approximately 78 kDa was consistently observed in FCV-infected cells and in clones containing the entire or
C-terminal part of ORF1. We propose that this 78-kDa protein may be an
active proteinase complex that corresponds to the 3CD protein complex
of the picornaviruses. A similar 3CD-like complex has been observed in
translational studies of the ORF1 of the Southampton human calicivirus
(113 kDa) and RHDV (73 kDa) (20, 34). The picornavirus and
RHDV proteases participate in the cleavage of the nonstructural as well
as the structural capsid proteins from a large polyprotein (13,
19, 27). It is likely that the same FCV protease is responsible
for the cleavage of the N terminus of the 3CD protein and perhaps other
sites of the nonstructural polyprotein in addition to cleavage of the
capsid precursor. However, as for RHDV and Southampton virus, the
cleavage of the 3CD protein at the border between the protease and
polymerase sequence appears to be inefficient in vitro. Further studies
are in progress to identify the cleavage products observed in our expression studies and to determine whether they have counterparts in
infected cells.
Among sequences found in the picornavirus-like 3C region of the FCV
genome are domains containing H1110, E1131,
C1193, and H1208 that are presumably involved
in the formation of the catalytic site of the proteinase (3,
25). Picornavirus 3C cysteine proteinases are considered members
of a family of chymotrypsin-like serine proteases that contain a
cysteine instead of serine as the nucleophile in the active site
(1, 11, 12). The picornavirus 3C proteinases are sensitive
to inhibitors binding to thiol groups and are weakly inhibited by
classical inhibitors of serine proteases (16, 33). In the
present study, two classical cysteine protease inhibitors were the only
chemicals that completely inhibited the FCV protease activity. Thus,
the FCV proteinase apparently is similar to the picornavirus 3C
proteinases in regard to inhibition with different classes of protease
inhibitors. However, elucidation of the details of the FCV proteinase
interaction with inhibitors will require further work with the purified
enzyme. An interesting observation in this study was the sensitivity of
the proteinase to increased temperature, which may, in part, explain
why FCV is restricted for growth at higher temperatures. The
inactivation of the proteinase by incubation at 42°C was
irreversible, suggesting that the protease is highly sensitive to
changes in conformation.
A feature of the picornavirus 3C proteinases that distinguishes them
from cellular serine proteases is their high substrate specificity that
is largely determined by the structure of the primary cleavage site
sequence. Most wild-type cleavage sites in picornavirus polyproteins
have the sequences Q (or E)/G, A, or S (13, 19, 27).
Presumably, the structural element of the protease that determines
selection of glutamine (Q) in the P1 position is the presence of a
conserved histidine residue near the active site (1, 22).
All calicivirus 3C-like protease sequences described thus far possess
this conserved histidine residue, and there is similarity between the
primary sequences of the picornavirus and calicivirus proteinase
recognition sites, with the Southampton human calicivirus proteinase
recognizing Q/G and the RHDV proteinase recognizing E/G and T (20,
21, 34). The FCV proteinase appears closer to that of RHDV in
that the wild-type cleavage site of the capsid precursor is E/A. The FCV protease was less tolerant of changes in the P1 position, but it
could recognize Q and D in the P1 position, similar to the RHDV
protease (34). Certain mutations in the P1 (L, K, and H) and
P1' (P) positions completely inhibited the FCV precursor cleavage,
confirming that the primary sequence of the cleavage site is important.
However, it is of interest that several E/A sites exist near the
primary cleavage site that are not utilized by the proteinase, raising
the possibility that an additional factor for the preference of the
known E/A cleavage site in the precursor could be its conformational
presentation to the proteinase. In the present study, the conformation
of the N-terminal leader sequence could be ruled out as an important
aspect of cleavage because products of internal initiation from ORF2
were cleaved as efficiently as the full-length precursor. In regard to
the cleavage site itself, the stretch of amino acids that comprise the
precursor cleavage site is the most hydrophilic region of the protein
predicted by computer analysis. However, the introduction of
hydrophobic amino acids V and L into the P1' position of the cleavage
site did not significantly affect the cleavage efficiency. The cleavage
site region exhibits also a local concentration of negatively charged
amino acids, but the substitution of A with positively charged R and H
did not affect the cleavage. We were also able to observe efficient
cleavage of the precursor after the substitution of D in the P3'
position with amino acids that reduced local negative charge such as N,
S, G, and R (data not shown). It is likely that the folding of the
remainder of the capsid precursor molecule plays an important role in
providing an accessible cleavage site to the proteinase. Processing of
the precursor in the in vitro trans cleavage assay indicates
that the cleavage site is accessible after translation of the entire protein.
The mutations analyzed in the in vitro cleavage assay were introduced
into the full-length clone in order to examine their effects on the
growth and replication of the virus. The accumulation of intact
precursor molecules of a single size in cells transfected with genomic
RNA carrying mutations in the precursor cleavage site confirmed that
the E/A cleavage site at amino acid residue 125 is the unique site of
the precursor recognized by the proteinase during viral replication.
The appearance of numerous faint bands in studies of FCV grown at
higher temperatures led to the suggestion by others (4, 26)
that the capsid precursor may be processed into intermediate forms
before final maturation. However, the data in the present study
indicate that the removal of the leader sequence is a one-time event
and not a process consisting of consecutive proteolytic steps.
Furthermore, complete cleavage of the FCV capsid precursor is
apparently critical in the production of infectious virions, consistent
with previous studies by Carter (4) in which inhibition of
the capsid precursor cleavage by p-fluorophenylalanine or
elevated temperature prevented the development of FCV cytopathic effect
and release of progeny virus. We could not recover virus following the
transfection of RNA from genomic mutants carrying D/A and Q/A cleavage
sites, in which incomplete cleavage occurred that resulted in the
accumulation in cells of both noncleaved precursor and mature capsid
protein with the correct N-terminal sequence. The relationship between
these two forms of the capsid protein during virion maturation and
assembly is not yet understood, but our data suggest that only the
cleaved form of the capsid can assemble into infectious virions. The
role of the leader polypeptide is not known, but deletion of this
sequence from the FCV genome prevents the recovery of virus as well as
the detection of capsid protein synthesis in transfected cells
(unpublished data). It will be of interest to examine whether
caliciviruses that translate a mature-sized capsid protein directly
from the subgenomic RNA have a counterpart for the function of this
sequence in their genomes.
Using full-length genomic clones that possessed mutations that
abolished precursor cleavage, we observed accumulation of a 73-kDa
protein in transfected cells but found no evidence for additional
synthesis of the 70-kDa protein that was detected in our in vitro
translation experiments. This observation suggested that the first AUG
of the subgenomic RNA is the optimal site for the positioning of the
ribosome for translation of the capsid precursor protein in cells and
that the initiation of protein synthesis takes place at the first AUG
of this template. The relatively short noncoding regions at the 5' end
of the FCV genome (19 nt) and subgenomic RNA (18 nt) and lack of
consensus motifs argue against a picornavirus-like internal ribosome
entry site in the calicivirus genome but does not rule out a unique
calicivirus translation-enhancing element. It was recently demonstrated
that the removal of the VPg protein from the 5' ends of both the
genomic and subgenomic FCV RNAs with proteinase K dramatically reduced the translation efficiency of both viral RNAs in vitro (15), and it is possible that the VPg is involved in the positioning of the
ribosome at the first AUG of the ORF2 in infected cells. Studies are in
progress to examine the role of the VPg in FCV replication and to map
critical regions of the FCV genome involved in translation of the viral
proteins.
| |
ACKNOWLEDGMENTS |
We thank John Coligan and Mark Garfield, LMS, NIAID, NIH, for the
protein sequence analysis and Stephen Leppla and Valerie Gordon, NIDR,
NIH, for sharing protease inhibitors. We thank Jose Valdesuso for his
dedicated technical support. We acknowledge Jerry M. Keith, NIDR, NIH,
and Tina Schultheiss, LID, NIAID, NIH, for enthusiastic and
constructive discussions. We extend our appreciation to Albert Z. Kapikian, and Robert M. Chanock, LID, NIAID, NIH, for continuing
support and encouragement.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: 9000 Rockville
Pike, Building 7, Room 137, Bethesda, MD 20892. Phone: (301) 496-5811. Fax: (301) 496-8312. E-mail: kgreen{at}atlas.nih.gov.
| |
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0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
