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Journal of Virology, May 1999, p. 4316-4326, Vol. 73, No. 5
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Genetic and Fitness Changes Accompanying Adaptation
of an Arbovirus to Vertebrate and Invertebrate Cells
Scott C.
Weaver,1,2,*
Aaron C.
Brault,1
Wenli
Kang,1 and
John J.
Holland2
Center for Tropical Diseases and Department of Pathology,
University of Texas Medical Branch, Galveston, Texas
77555,1 and Department of Biology,
University of California
San Diego, La Jolla, California
920932
Received 22 October 1998/Accepted 16 February 1999
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ABSTRACT |
The alternating host cycle and persistent vector infection may
constrain the evolution of arboviruses. To test this hypothesis, eastern equine encephalitis virus was passaged in BHK or mosquito cells, as well as in alternating (both) host cell passages. High and
low multiplicities were used to examine the effect of defective interfering particles. Clonal BHK and persistent mosquito cell infections were also evaluated. Fitness was measured with one-step growth curves and competition assays, and mutations were evaluated by
nucleotide sequencing and RNA fingerprinting. All passages and assays
were done at 32°C to eliminate temperature as a selection factor.
Viruses passaged in either cell type alone exhibited fitness declines
in the bypassed cells, while high-multiplicity and clonal passages
caused fitness declines in both types of cells. Bypassed cell fitness
losses were mosquito and vertebrate specific and were not restricted to
individual cell lines. Fitness increases occurred in the cell line used
for single-host-adaptation passages and in both cells for alternately
passaged viruses. Surprisingly, single-host-cell passage increased
fitness in that cell type no more than alternating passages. However,
single-host-cell adaptation resulted in more mutations than alternating
cell passages. Mosquito cell adaptation invariably resulted in
replacement of the stop codon in nsP3 with arginine or cysteine. In one
case, BHK cell adaptation resulted in a 238-nucleotide deletion in the
3' untranslated region. Many nonsynonymous substitutions were shared
among more than one BHK or mosquito cell passage series, suggesting
positive Darwinian selection. Our results suggest that alternating host transmission cycles constrain the evolutionary rates of arboviruses but
not their fitness for either host alone.
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INTRODUCTION |
Arthropod-borne viruses
(arboviruses) are transmitted among vertebrate hosts by insect and tick
vectors. Although some can persist by vertical transmission from female
arthropods to their offspring, most must replicate alternately in
vertebrates and vectors in horizontal transmission cycles. Eastern
equine encephalitis virus (EEEV) and several other mosquito-borne
alphaviruses appear to undergo lower rates of evolution than many other
animal RNA viruses that replicate only in vertebrate hosts, such as
human immunodeficiency virus, hepatitis C virus, and poliovirus
(37, 38). The factors responsible for alphavirus genetic
stability have not been addressed definitively. One hypothesis is that
alphavirus evolution is constrained by innate properties of their
genome replication, while others involve strong purifying selection
imposed by the alternating host transmission cycle or other factors
related to their transmission that minimize genetic drift and founder effects (38). None of these hypotheses have been tested experimentally.
Despite high mutation frequencies, the sequences of many RNA viruses
remain stable in nature and under certain laboratory conditions, such
as serial, low-multiplicity passages in vitro (28). However,
other conditions promote genetic disequilibrium and rapid experimental
evolution (29). One such factor is the presence of defective
interfering (DI) particles, which are preferentially amplified during
serial, high-multiplicity passages and interfere with standard virus
replication. Selective pressure for resistance to interference leads to
rapid genome evolution of vesicular stomatitis virus (VSV)
(28). The presence of DI particles also contributes to rapid
evolution of VSV in persistently infected cells (16). Another factor known to promote rapid phenotypic changes in RNA viruses
is the founder effect or genetic bottleneck. When subjected to clonal
(plaque-to-plaque) passages, bacteriophage 
6 (3), VSV
(9), and foot-and-mouth-disease virus (13)
undergo fitness losses due to Muller's ratchet (25).
Deleterious mutations presumably accumulate in the genomes of these
viruses because forward mutation rates exceed those of back mutations.
Clonal passages can also prevent a more-fit variant present in the
original population from being selected during passage and reduce the
probability of regenerating mutation-free genomes through genetic
recombination or reassortment (2).
Multiplicities of infection and DI virus may be important factors in
the regulation of alphavirus evolution (38). Multiplicities in mosquito vectors may be limited by infectious virus titers in
vertebrate blood and by the small volume (generally only a few
microliters) of blood ingested. During progression of virus from the
mosquito midgut to the salivary glands, basal laminae appear to
interfere with alphavirus movement and may limit multiplicities of
infection in other tissues (33, 40). Titers of alphaviruses in mosquito saliva also decrease after about 1 week of infection (1, 40), limiting inocula and multiplicities of infection in
vertebrate hosts and increasing opportunities for founder effects. Because the life cycle of alphaviruses includes persistent infection of
mosquito vectors, the potential for rapid evolution under the influence
of DI virus has also been suggested (38).
To investigate the influences of alternating host replication,
infection multiplicity, founder effects, and DI particles on genetic
and fitness changes of an arbovirus, we used a cell culture model
system to study the evolution of EEEV. Alternating host cell
replication generally resulted in lower rates of genetic change but
similar fitness increases compared single-host-cell passages. Undiluted
passages, favoring the accumulation of DI particles, resulted in severe
fitness declines and moderate genetic change, as did persistent
infection of mosquito cells. Clonal passages resulted in little genetic
change but reductions in fitness in both cell types.
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MATERIALS AND METHODS |
Cell cultures.
Monolayer cultures of BHK21 cells were grown
at 37°C in Eagle's minimal essential medium (MEM) containing 5%
heat-inactivated calf serum. Aedes albopictus C6/36 mosquito
cells were grown at 32°C in MEM supplemented with nonessential amino
acids and 10% heat-inactivated calf serum.
EEEV infections.
An unpassaged strain of EEEV, 2061-88, isolated in 1988 from field-collected Culiseta melanura
mosquitoes in Pocomoke Swamp, Maryland, was used for experimental
infections. The original triturated mosquito pool was diluted and
inoculated into a bottle of BHK cells to yield a single plaque, and the
harvested clonal pool was amplified once in BHK cells to generate the
stock used for all subsequent infections.
The plaque harvest described above was used to initiate serial
infections of cell cultures and persistent infections. All passage
series were carried out 100 times, with the exception of the clonal
(plaque-to-plaque) series, which was carried out 40 times, and
persistent infections of mosquito cells, which were maintained for 200 days. All virus passages were carried out at 32°C to eliminate
temperature as a selection factor. Virus (diluted in MEM or undiluted)
was adsorbed to cells at room temperature for 30 min, followed by
addition of MEM containing 5% serum and incubation at 32°C. Plaque
assays were carried out at 32°C with BHK or Vero cells and 0.4%
agarose in MEM for overlays. Randomly isolated plaques (no more than
three in a 25-cm2 bottle) were harvested by using a Pasteur
pipette to obtain clonal pools of EEEV. Persistent infections of C6/36
mosquito cells were initiated by infection at a multiplicity of 0.1. Following 7 days of incubation at 32°C, cells were detached by
vigorous shaking and diluted 1:20 with fresh medium. Thereafter, cells
were split 1:20 at 10-day intervals.
One-step growth curves.
To examine changes in replication
kinetics after different passages, one-step growth curves were done in
triplicate. Virus inocula were diluted to yield a multiplicity of
infection of 0.01. MEM was aspirated from 25-cm2 bottles
containing cell monolayers, and 0.25 ml of virus was added at 5°C.
Following adsorption for 1 h with frequent rocking, cells were
washed three times with phosphate-buffered saline, and MEM was added at
32°C. Supernatant samples were taken at selected intervals and plaque
assayed on Vero cells to determine replication kinetics.
Competition fitness assays.
Competition fitness assays were
a modification of those described previously (14). Each
passaged virus was competed against the same standard, the alternating
host cell, diluted-passage-series virus (see Table 1) that had
undergone a mutation in an XhoI restriction site within the
nsP4 gene. Mixtures of viruses were prepared in defined ratios and
passaged in triplicate series with dilutions (10
4 for BHK
cells and 102 for C6/36) to maintain multiplicities of
ca. 0.01. Following incubation for 24 h (BHK) or 48 h
(C6/36), RNA was extracted from cell culture media and the nsP3-nsP4
fragment was amplified by reverse transcription (RT)-PCR as described
below. Approximately 500 ng of amplicons was purified by eluting DNA
from 1% agarose gels and digested with XhoI (5 units) for
2 h at 37°C. The ratios of viruses were estimated by quantifying
the DNA in uncut (542 bp) versus cut (398 and 144 bp) bands with
densitometry of ethidium bromide-stained gels and the 2-D Scan program
(Scanalytics, Inc., Billerica, Mass.).
T1 oligonucleotide fingerprinting.
Plaque clones
and passaged EEEV populations were amplified by infection of BHK
monolayers at 32°C with multiplicities of infection of 0.01 to 0.1. Viral RNA was intrinsically labeled by adding 0.1 to 0.2 mCi of
32P, as inorganic phosphate, per ml to cell culture bottles
during virus amplification. Cell culture supernatants were harvested after 24 h, and viral RNA was purified as described previously (39). Ribonuclease T1 digestion of genomic RNA
and two-dimensional electrophoresis of oligonucleotides were performed
as described by Holland et al. (16). All RNA fingerprints
were compared to those obtained for the starting plaque clone of strain
2061-88. Missing oligonucleotides, as well as newly appearing
oligonucleotides, were recorded and assembled in a master map.
RT-PCR amplification and sequencing.
Viral RNA was extracted
from 0.25 ml of cell culture supernatants by adding 0.75 ml of Trizol
LS (BRL, Bethesda, Md.) and processed according to the manufacturer's
protocol. Yeast tRNA (0.2 µg) was added to enhance RNA precipitation.
cDNA was synthesized at 42°C with Superscript reverse transcriptase
(BRL) by using a primer of sequence 5'-T19V-3', and PCR was
conducted with the following three primer pairs:
5'-CGTGGACTTAATCACGTTTGACAG-3' (sense) and
5'-CAGAGAGGTATGAGCCTAT-3' (antisense), designed to amplify genome positions 5428 to 5969, covering the C terminus of nsP3 and the
N-terminus of nsP4 (sequence positions according to reference 36); 5'-GGAGTAAAGGCACCGTACTTTTG-3'
(sense) and 5'-AATGGAACGTCTCAGGTCCTC-3' (antisense),
designed to amplify genome positions 7196 to 7735, covering the C
terminus of the nsP4 gene, the promoter region and untranslated region
(UTR) of the 26S mRNA 5' region, and the N terminus of the capsid gene;
and 5'-TTACCTGCAAAGGRGATTG-3' (sense) and
5'-GAAATATTAAAAACAAAATA-3' (antisense), designed to amplify genome positions 11118 to 11678, covering the C terminus of the E1 gene
and the 3' UTR. PCRs were done according to a previously described
protocol (4), with 30 amplification cycles as follows: heat
denaturation at 95°C for 30 s, primer annealing at 49°C for 30 s, and extension at 72°C for 1 min. PCR amplicons were
extracted from 1% agarose gels and sequenced directly with the PCR
primers and the Applied Biosystems (Foster City, Calif.) Prism
automated DNA sequencing kit and sequencer, according to the
manufacturer's protocol.
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RESULTS |
One-step growth curves to determine passage dilutions.
To
determine dilutions and passage times necessary to obtain serial EEEV
passages of predictable multiplicity, one-step growth curves were
determined for the parental strain 2061-88. BHK infectious titers
reached about 1010 PFU/ml within 24 h of infection,
when cytopathic effects (CPE) were 3+ to 4+, whereas titers in C6/36
cells neared their maximum of about 109 after 48 h of
incubation (data not shown). Infected C6/36 cells also showed a slight
clustering and elongation at that time. Diluted passages 20 and 50 showed similar kinetics. Therefore, to insure adequate inoculum titers
during serial passages and multiplicities of about 0.01, BHK infections
were incubated for 24 h and C6/36 infections were incubated for
48 h at 32°C for each passage.
Serial passages and DI particle generation.
EEEV was subjected
to 13 different passage series in BHK and/or C6/36 cells, including
both diluted and undiluted, as well as clonal (plaque-to-plaque)
passages in BHK cells and persistent infection of C6/36 cells (Table
1). All passage series were carried out
100 times with the exception of clonal (plaque-to-plaque) series, which
were carried out 40 times, and persistent infections of mosquito cells,
which were maintained for 200 days. To evaluate the infectious titers
of these passages and confirm the presence of DI particles in the
undiluted passages, culture media from the first 13 undiluted and
diluted passage series were evaluated by plaque assay. Diluted passages
maintained relatively stable, high titers (ca. 109 to
1010 PFU/ml) in both BHK and C6/36 mosquito cells. PFU
titers were nearly identical on both BHK and Vero cell monolayers (data
not shown). Titers of undiluted passages dropped by about 100- to 10,000-fold by passage 4 (C6/36) or 7 (BHK), followed by fluctuations during subsequent passages. These results were consistent with generation and amplification of DI particles in the undiluted passage
series, leading to fluctuations in titer (cycling) as DI particles
suppressed wild-type virus replication, followed by drops in DI
replication due to inadequate amounts of helper virus (26).
To confirm the presence of interfering activity in the undiluted
passage series, 107 PFU of undiluted BHK and C6/36 passages
7 were mixed with standard helper virus (original clonal pool with one
diluted BHK passage) at a multiplicity of 10 and used to infect BHK and
C6/36 cells in triplicate. Infectious virus titers were measured at
times listed below for one-step growth curves. Replication in either BHK or C3/36 cells was suppressed at least 3-fold (P < 0.01 [Student's t test]) at early time points and at
least 30-fold (P < 0.001 [Student's t
test]) at late time points by both BHK and C6/36 undiluted-passage
viruses, relative to diluted passage 7 or first-passage controls,
indicating the presence of interfering activity. BHK cell-generated DI
particles interfered more with helper virus replication in BHK cells
than in C6/36 cells, and C6/36 cell-generated particles interfered more
in C6/36 cells.
One-step growth curves to evaluate fitness changes after serial
passages.
Initial fitness testing of all passage series comprised
one-step growth curves in both BHK and C6/36 cells at 32°C.
Infectious titers after 5 and 20 h of replication in BHK cells, or
20 and 44 h in C6/36 cells, are presented in Fig.
1. Diluted passages (100) in BHK cells
resulted in little or no change in BHK replication measured at 5 or
20 h. However, the passaged virus exhibited 3- to 300-fold
declines in C6/36 cell replication after 20 and 44 h compared to
the parent. Likewise, diluted passage in C6/36 cells resulted in little
or no change in C6/36 cell replication after 20 or 44 h but in 5- to more than 1,000-fold declines in BHK cell replication after 5 to
20 h. When viruses were passaged undiluted to enhance DI particle
accumulation, replication kinetics declined in both cell types, with
10- to 1,000-fold decreases at both early and late time points, except
for the BHK passage series tested in BHK cells at the 20-h incubation
time. Alternating passage with dilutions resulted in both increases and
declines in replication kinetics, depending on the cell type and time
point in one-step growth curves. Undiluted, alternating passage
resulted in reductions of 10- to 100-fold in replication in both cell
types, except for BHK cells at the 20-h incubation time.
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FIG. 1.
Titers of EEEV in cell culture supernatant after
one-step infection of BHK or C6/36 cells. The passage histories of
viruses are shown below the graphs (all series underwent 100 passages
with the exception of the clonal [plaque-to-plaque] series, which
were carried out 40 times, and persistent infections of mosquito cells,
which were maintained for 200 days). *, <1.3 log10
PFU/ml (below the detection limit of the plaque assay). Error bars show
standard deviations of mean titers.
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Clonal (40 plaque-to-plaque) passage in BHK cells resulted in 10-fold
reductions in early replication in BHK cells and 3-
to 1,000-fold
reductions in early C6/36 replication, with smaller
reductions or
increases at later sampling points. Reductions were
generally greater
in C6/36 cell replication than in BHK cell replication,
probably
reflecting some selection for BHK cell replication during
plaque
formation. Persistent infection of C6/36 cells resulted
in large
reductions in fitness for acute infection of both BHK
and C6/36 cells,
with 4- to over 1,000-fold reductions in virus
titers at both early and
late time points of one-step growth curves.
Reductions were generally
greater in BHK than in C6/36 cells,
again consistent with some
selection for maintenance of fitness
in mosquito
cells.
To determine whether fitness decreases in bypassed cells were specific
to the individual vertebrate and mosquito cell lines
used for
adaptation, we also measured one-step growth curves for
the diluted
passage series, as well as one persistent C6/36 cell
infection series,
in Vero monkey kidney and
Anopheles albimanus mosquito
cells. The results are presented in Fig.
2. As with BHK
and C6/36 cell
replication, the BHK-adapted virus replicated more
poorly than the
parent in the
Anopheles albimanus mosquito cells,
and the
C6/36-adapted virus also exhibited a fitness decline in
Vero cells.
Fitness levels of BHK-adapted virus, as well as the
alternating passage
virus, were similar to the parent in Vero
cells, and the C6/36-adapted
and alternating viruses also had
similar replication kinetics to the
parent in
Anopheles albimanus cells. These results indicate
that the fitness declines in the
bypassed cell lines were probably
vertebrate and mosquito specific
and not restricted to a single host
cell line. The persistent
C6/36-adapted virus also exhibited declines
in replication in
both cell types during acute infection, with the
exception of
the 20-h time point in Vero cells, when infectious titers
were
similar to those produced by the parent (Fig.
2).
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FIG. 2.
Titers of EEEV in cell culture supernatant after
one-step infection of Vero or Anopheles albimanus cells.
*, <1.3 log10 PFU/ml (below the detection limit of the
plaque assay). Error bars show standard deviations of mean titers.
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Competition passages to evaluate fitness changes after serial
passages.
Competition relative fitness assays representing a
modification of those used previously to study VSV evolution
(14) were developed to overcome several limitations of
one-step growth curves: (i) limited accuracy due to the dependence of
virus replication on inoculum titers and the inherent imprecision of
plaque assays, (ii) the possibility that plaque assays underestimate
C6/36 cell-adapted viruses that may lose the ability to form visible
plaques in vertebrate cells, and (iii) inconsistent results we
sometimes observed comparing relative virus production at early versus
late time points (Fig. 1). The loss of an XhoI restriction
site within the nsP3-nsP4 amplicon sequence of the alternate-host-cell,
diluted-passage series was used as a genetic marker; this
alternate-passaged virus was used as a fitness standard and mixed with
either the parent, BHK diluted (104), or C6/36 diluted
(102) series, as well as the clonal passage viruses
(series A to D), and competed in BHK or C6/36 cells in triplicate
series with dilutions (104 or 102 for BHK
and C6/36, respectively) to minimize the influence of DI particles.
Proportions of viruses following each passage were monitored by RT-PCR
amplification of the nsP3-nsP4 genome region from the culture
supernatant, followed by XhoI digestion of the purified
amplicon and agarose gel electrophoresis to determine ratios of the two
genotypes. All viruses used in competition assays were also passaged
alone four times to ensure stability of the marker (XhoI
site present or absent). An example of this assay is presented in Fig.
3. The alternating passaged virus showed a consistent competition fitness advantage over the parent in both
cells, as did each single-cell passaged virus in the adapted cell line
(Fig. 4). Surprisingly, the
single-host-cell-adapted viruses showed little or no advantage over the
alternating-cell-passage virus when competed in either BHK or C6/36
cells. Clonally passaged viruses exhibited varying degrees of fitness
declines, which tended to be more severe in the C6/36 cell environment.
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FIG. 3.
Agarose gel electrophoresis showing results from an EEEV
competition fitness assay. Parent and alternately passaged (100 times)
viruses were mixed in a ratio of approximately 13:1 and passaged
serially in triplicate in C6/36 cells with 100-fold dilution to reduce
the multiplicity of infection. RNA was extracted from 250 µl of the
original virus mixture as well as from the passages, and the nsP3-nsP4
genome region was amplified by RT-PCR. The resulting 542-bp amplicon
was eluted from a 1% agarose gel and digested with XhoI to
produce DNA fragments of 398 and 144 bp for the parental genotype only.
A, 100-bp ladder; B, parent virus used in competitions; C, alternately
passaged virus used in competitions; D, mixture of parent and
alternately passaged viruses used to initiate competitions; E to G,
triplicate first-competition passages; H to J, triplicate
second-competition passages; K, parent virus after four passages alone;
L, alternately passaged virus after four passages alone; M, 100-bp
ladder.
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FIG. 4.
Relative fitness plots for EEEV competition assays in
BHK and C6/36 cells. Parent, BHK 104-diluted, C6/36
102-diluted (all 100 times), and clonally passaged (40 times, A to D) viruses were competed with the alternate diluted-passage
virus that had lost the XhoI site in nsP4. Ratios of the
competing viruses were estimated following XhoI digestion of
RT-PCR amplicons, as shown in Fig. 3, by using densitometry and were
plotted for up to four competition passages. Fitness vectors were
plotted by regression. The alternating-passage virus served as the
standard and thus has a fitness slope of 0 (horizontal line). The
digested DNA bands corresponding to the clonally passaged viruses were
not detected after the first C6/36 cell competition passage, so C6/36
ratios and vectors for the clonally passaged viruses represent the
maximum possible values.
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Genetic analyses.
All 13 passage series were analyzed by
RT-PCR amplification and sequencing of three genome regions totaling
ca. 1,500 nucleotides and by T1 RNA fingerprinting, which
samples all EEEV genes (34). The results of the
fingerprinting analysis are presented in Table 1 and Fig.
5. For BHK cell passages, the
106 dilution series showed the most change, with 12 oligonucleotide differences versus the parent fingerprint. With a
previous estimate of 13% sampling of the EEEV genome in the large,
unique, T1-resistant oligonucleotides evaluated in
fingerprints (34), this change corresponded to about 0.9%
sequence divergence from the starting clone. The undiluted BHK series
was more stable, with only five oligonucleotide differences, or about
0.4% sequence change, while the 104 dilution series
showed seven oligonucleotide changes, or about 0.5% divergence.
Several of the oligonucleotides in the 104 and undiluted
series were lower in molar amount than nearby (similar-length) oligonucleotides (Table 1), indicating that they were not present in
all genomes of the virus population and suggesting the development of
quasispecies populations. The C6/36 cell passages showed seven oligonucleotide changes versus the parent, while the alternating passaged viruses showed only one or two oligonucleotide
changes. One clonally passaged virus had six oligonucleotide changes,
while the persistent infections showed only one and no changes,
respectively.
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FIG. 5.
T1 oligonucleotide fingerprint of the clonal
pool of parent EEEV used to initiate adaptation passages. Map below
shows oligonucleotides analyzed for comparison of the parent virus to
viruses generated after various passage histories (Table 1).
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Sequence analyses included three regions of the EEEV genome, each
encompassing ca. 500 nucleotides excluding primer sequences:
genome
positions 5428 to 5969, including the C terminus of nsP3,
the N
terminus of the nsP4 gene, and the termination codon; genome
positions
7196 to 7735, including the C terminus of the nsP4 gene,
the promoter
region and UTR of the 26S RNA 5' region, and the
N terminus of the
capsid gene; and genome positions 11118 to 11678,
including the C
terminus of the E1 gene and the 3' UTR. Consensus
sequences of PCR
amplicons revealed nucleotide changes in all
passage series except for
two of the four clonal passages (Fig.
6;
Table
2). The nsP3-nsP4
region showed the most change, with
a total of 21 nucleotide changes,
19 of which were nonsynonymous.
The nsP4-capsid region had 12 changes,
6 of which were nonsynonymous,
and the E1 3' UTR showed 17 changes, 2 of which were nonsynonymous
changes in the E1 gene. Eleven of the 3'
UTR changes represented
mixed nucleotide populations, especially in the
undiluted BHK
passage series (Fig.
6).
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FIG. 6.
Aligned nucleotide sequences for the three EEEV genome
regions generated by RT-PCR. Deduced amino acid sequences of the parent
strain are shown above second codon positions. Deletions are indicated
by dashes, and dots indicate the same nucleotide as the parent virus.
Ambiguous nucleotide symbols indicate mixed populations
represented by multiple peaks in the electropherograms of both strand
sequences. The XhoI site at positions 5825 to 5830, used as
a genetic marker for competition fitness assays, is underlined.
Numbers above nucleotides adjacent to righthand margins represent
genomic EEEV numbering as previously published (36).
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Overall, 27 of the 50 total nucleotide substitutions observed in the
three genome regions were nonsynonymous. The BHK passages
and C6/36
persistent infections resulted in the largest numbers
of nucleotide
substitutions, with 0.2 to 0.7% sequence change,
while the clonal
passages showed smaller amounts of change, 0
to 4 nucleotides (Table
2). The alternating cell passages also
showed small amounts of change
(one substitution each) compared
with the single-host-cell, diluted
passages (two to seven
substitutions).
Analysis of individual nucleotide changes revealed that many were
common to a particular host cell passage type. For example,
both
persistent infections of C6/36 cells resulted in four common,
nonsynonymous substitutions in the nsP4 gene region, suggesting
common,
positive Darwinian selection for polymerase amino acid
changes. It is
possible that these mutations were present in the
original parent
population generated by a single BHK passage from
the plaque clone
pool. However, this seems unlikely, because these
mutations did not
appear in any of the BHK cell passage series.
All four passage series
exclusively involving C6/36 cells resulted
in a change in the stop
codon near the end of the nsP3 gene (Fig.
5); the serial diluted and
undiluted C6/36 passages resulted in
arginine (CGA) and cysteine (TGC)
codons, while both persistent
infection series also underwent the
arginine substitution. Analysis
of sequence electropherogram peaks for
C6/36 cell passages 5 and
10 revealed a gradual increase in the
proportion of the populations
with sense codons, with the stop codons
undetectable by passage
10. In contrast, all passage series involving
BHK cells, either
exclusively BHK or alternating C6/36-BHK, retained
the stop codon
with no evidence of mixed populations in these
nucleotides.
Surprisingly, the untranslated genome regions we sequenced,
the 26S junction region and 3' UTR, contained the fewest consensus
nucleotide sequence substitutions for most passage series. However,
one
of the diluted BHK cell passages (10
4) underwent a
238-nucleotide deletion in the 3' UTR, beginning
23 nucleotides
downstream of the structural polyprotein stop codon.
This deletion
region includes all but one of the repeated sequence
elements believed
to interact with cellular proteins and to possibly
regulate translation
of the alphavirus genome (
32).
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DISCUSSION |
Evolutionary implications of an alternating host transmission
cycle.
In some respects, our results support the longstanding
assumption that alphaviruses and other arboviruses must adopt a
compromise fitness level for replication in both vertebrate and
invertebrate cells. When EEEV was freed of the alternating host cell
transmission cycle, dramatic fitness losses were observed in the
bypassed cell environment. Another prediction of this hypothesis is
that elimination of one host from an adaptation transmission cycle will
result in the acquisition of higher fitness for the retained host than will occur in an alternating adaptation cycle. However, this was not
observed in either BHK or C6/36 cell adaptation (Fig. 4). The ability
of the alternating-host-cell-passaged viruses to acquire fitness gains
comparable to those observed during single-host-cell adaptation
indicates that two different kinds of genetic solutions to fitness
gains occurred, both host-specific and more generalized adaptations.
This remarkable ability of an RNA virus to adapt efficiently to two
different host cell environments is probably reflected in the fact that
nearly all arboviruses have RNA genomes.
The hypothesis that alternating host replication limits rates of
arbovirus evolution is supported by our results. Using both
RNA
fingerprinting and limited genome sequencing, viruses subjected
to
alternating vertebrate-mosquito host cell passage exhibited
consistently smaller amounts of genetic change than did viruses
passaged in large populations in either cell type alone. However,
the
reasons for the relative genetic stasis in the alternating
host cell
adaptation may be more complex than greater purifying
selective
constraints, since similar fitness gains occurred in
alternating and
single host cell
adaptation.
Serial passage of EEEV in cell culture also demonstrated that this
virus is capable of undergoing rapid sequence and fitness
evolution
under appropriate conditions. For example, the estimated
0.7 to 0.9%
nucleotide sequence change that accompanied 100 passages
in cell
culture represents the equivalent of 44 to 56 years of
natural EEEV
evolution in North America (
35). This provides
further
indirect evidence that the relatively low rates of alphavirus
evolution
in nature are not due to innate properties of their
genome replication,
such as high fidelity or proofreading by viral
polymerases.
Two of the genetic changes accompanying single-host-cell replication
are of particular interest. The replacement of the stop
codon near the
3' end of the nsP3 gene by arginine or cysteine
codons occurred in all
four C6/36 cell passage series, suggesting
a selective advantage for
the nsP1-nsP4 polyprotein open reading
frame in mosquito cell
replication. This may reflect more-efficient
replication in mosquito
cells when greater amounts of the nsP4
polymerase are present and a
preference for lower polymerase levels
(generated only by read-through)
in vertebrate cell replication.
In alphaviruses, the nonstructural
polyprotein precursor is cleaved
by a virus-encoded protease that is
part of nsP2 to produce four
final products
nsP1, nsP2, nsP3 and
nsP4
as well as partially
digested polyproteins. In 8 of 10 alphaviruses (including the
82V2137 strain of EEEV previously sequenced
[
36]), there is
an opal termination codon (UGA)
between nsP3 and nsP4 that is
read through with moderate efficiency (5 to 20%), whereas in two
other alphaviruses, including o'nyong-nyong
virus (ONNV), this
codon has been replaced by a sense codon for
arginine (CGA) (
32).
Although the first sequences of ONNV
obtained indicated that it
possesses a sense (arginine) codon rather
than a termination codon
(
22), Lanciotti et al.
(
20) recently reported that consensus
sequences of more
recent ONNV isolates of lower passage history
have both stop and sense
codons at this position and exist in
nature as quasispecies. All of the
recent isolates with stop codons
also have a C residue
immediately downstream, which enhances readthrough
in
Sindbis virus (
23). When four recent ONNV isolates with the
opal termination codon were passaged in Vero cells (
20), all
were observed to acquire the arginine codon found in the original
1959 Gulu strain (
22). These results suggest that the termination
codon in ONNV is subject to different selective pressures than
that of
EEEV. Both results also suggest that previous passage
in
vertebrate or invertebrate cells may have influenced the
sequences
reported for some
alphaviruses.
The effects of the opal termination codon versus sense
codons on replication of Sindbis virus in both vertebrate and
mosquito
cells was studied experimentally by Li and Rice
(
24). Sense
amino acids (serine, tryptophan, or arginine) or
the other two
translation termination codons (amber or ochre) were
introduced
into an infectious cDNA clone, and rescued viruses were
analyzed
for replication in chicken cells. The sense codon mutants
overproduced
nsP34 but not nsP4, indicating that the level of nsP4 is
not regulated
solely by read-through of the opal codon. NsP4 is rapidly
degraded
via an N end rule pathway (
5), and Sindbis virus
mutants that
replace the termination codon with a sense codon do not
accumulate
excessive nsP4, presumably due to protein degradation
(
24).
Temperature-sensitive Sindbis virus mutants that
exhibit decreased
levels of nsP34 and nsP4 production grow poorly in
mosquito cells
but normally in chicken cells at nonpermissive
temperature (
21),
also suggesting that greater amounts of
nsP4 are required for
replication in mosquito cells. Li and Rice
(
24) also determined
that the serine mutant of the Sindbis
opal termination codon was
gradually replaced by the opal virus during
mixed infection of
chick embryo fibroblasts. Taken together, these
results suggest
that the termination codon confers a fitness advantage
for replication
of some but not all alphaviruses in vertebrate
cells.
The large deletion in the EEEV 3' UTR following 100 diluted BHK cell
passages also suggests that this genome region may function
differently
during replication in vertebrate than invertebrate
cells. The
alphavirus genomic RNA and 26S mRNA 3' UTR include
several repeated
sequence elements believed to interact with cellular
proteins
(
32). The previous finding that an engineered 3' deletion
of
Sindbis virus repeated elements has a much greater effect on
replication in C6/36 cells than in chicken cells (
19) is
consistent
with our finding that the EEEV 3' UTR can undergo extensive
deletions
accompanied by efficient replication in hamster cells. Both
findings
suggest that parts of the 3' UTR may be more important for
alphavirus
replication in mosquitoes than in
vertebrates.
Effects of clonal passages.
Viruses undergoing
clonal, plaque-to-plaque passages in BHK cells exhibited
declines in replication in both BHK and C6/36 cells. The effect was
most pronounced when replication was measured early (after 5 and
20 h, respectively) and when competition assays were used to
measure relative fitness. Surprisingly, 20-h BHK cell yields of
clonally passaged viruses were actually higher than those of the parent
in one-step growth curves. A possible explanation for the apparent
recovery of replication later in infection is that the reduced
replication during early stages allowed the BHK cells to remain
productive longer for virus replication. This hypothesis is supported
by the observation that the clonally passaged viruses showed less CPE
than the parent after 20 h of replication, and complete (no normal
cells observed attached to the plastic) CPE occurred ca. 8 h later
in the clonal passage group (data not shown). This difference in CPE of
BHK cells was also noted in the C6/36-adapted viruses and the undiluted
series adapted to both cell types. Another possible explanation for the apparent recovery of clonally passaged viruses later in BHK cell infection is that these viruses underwent reversion of deleterious mutations or compensatory mutations to regain fitness during hours 5 to
20 of replication. The small numbers of mutations detected in these
clonally passaged viruses are consistent with this possibility and with
previous studies of foot-and-mouth-disease virus, which showed that
small numbers of mutations mediate fitness declines following clonal
passage (13). To fully assess these hypotheses, an
infectious cDNA clone of EEEV is needed to produce genetically defined
viruses that can be used to test the effects of individual mutations or combinations.
Effects of DI particles on EEEV evolution.
Our results
indicate that the presence of DI particles, which accompany high
multiplicity or persistent infection of cell cultures, can have a
profound effect on EEEV fitness for acute replication in both
vertebrate and mosquito cells. Whether DI particles exert a significant
influence on arbovirus evolution in nature remains to be determined. DI
particles have never been detected in infected mosquitoes, though
extensive investigations have not been reported. Vertebrate host
infections by alphaviruses generally are cleared after a few days,
probably precluding the generation of large DI populations. Although
mosquitoes become persistently infected with alphaviruses and can
survive for several months, rates of EEEV saliva infection decline 1 to
3 weeks after an infectious blood meal (33, 40), and
mosquitoes generally suffer high mortality rates in nature. These
limitations on the time that infected mosquitoes can transmit suggest
that DI particles may generally appear too late to influence the
evolution of the virus population that is transmitted to the vertebrate host.
The greater amount of genetic change observed during serial, dilute
passages of EEEV, relative to undiluted passages, was
surprising
considering previous findings with VSV. Spindler et
al. (
28)
reported that high multiplicities of VSV infection
favor rapid and
random evolution. However, Sanchez-Palomino et
al. (
27)
reported that dilute passages of human immunodeficiency
virus type 1, with multiplicities of infection of 0.001, promote
rapid genetic change
in vitro. One possible explanation for the
greater rate of EEEV change
in the dilute passage series is that
lower multiplicities resulted in
more cycles of genome replication
than in undiluted passages.
Greater genome replication could augment
evolution by either (i)
increasing the possibility of adaptive
change by generating more
mutations, some of which might enhance
fitness, or (ii) increasing the
number of mutants available for
stochastic change (genetic drift). A
second possibility is that
the reduction in EEEV population sizes,
associated with dilution
between passages, enhanced genetic drift.
However, titers of virus
in diluted passages indicated that, on
average, inocula of the
10
6 passage series contained
about 5 × 10
4 PFU of EEEV. If mutation frequencies
are on the order of 10
4 (
7,
8,
15,
29), most
passages should have included
a consensus genome in the inoculum.
Although our results suggest
that adaptive change, or natural
selection, was responsible for
much of the evolution we observed in
vitro, genetic drift may
also have played a
role.
Another possible explanation for this apparent discrepancy between our
results and those of Spindler et al. (
28) is the
nature of
the viruses and the recent host passage history of the
viruses used to
initiate serial passages. Whereas Spindler et
al. (
28) used
a VSV strain which had been passaged many times
in BHK cell culture and
was presumably "preadapted" to the BHK
cells used, our experiments
and those of Sanchez-Palomino et al.
(
27) used viruses of
low passage history which may have undergone
more adaptation during
serial passages. The common nucleotide
and oligonucleotide changes in
our EEEV passage series suggest
positive selection; dilute passages may
have optimized selection
by reducing the influence of DI particles in
generating complex
quasispecies populations that can suppress
mutants of superior
fitness (
6). Sanchez-Palomino
et al. (
27) also speculated
that their HIV
mutants, which appeared only after dilute passage,
may have been
previously suppressed by DI genomes in complex quasispecies.
Finally,
DI particles of VSV may be better able to suppress high-fitness
viruses
and promote random change through selection for resistance
to
interference than DI particles of EEEV. Experiments such as
those
conducted by de la Torre and Holland (
6), examining the
ability of high-fitness EEEV to replicate in complex quasispecies
populations, are needed to test this hypothesis. The possibility
that
transfers in vertebrate hosts at mammalian or avian core
body
temperatures might select additional genetic changes also
should be
addressed.
Host cell dependence of interference has been described previously for
DI particles of other alphaviruses. Several authors
have reported that
DI particles of Semliki Forest and Sindbis
viruses generated in
vertebrate cells do not interfere with viral
RNA synthesis in
A. albopictus mosquito cells (
11,
17,
31).
Igarashi and
Stollar (
17) were unable to generate DI particles
with
serial undiluted passages in
A. albopictus cells, although
later work using longer incubation times for each serial passage
resulted in DI particle generation (
30). King et al.
(
18)
also reported the generation of Sindbis virus DI
particles in
mosquito cells; these particles did not interfere with
Sindbis
virus replication in chicken cells, and others generated in
chicken
cells did not interfere in mosquito cells. Persistently
infected
mosquito cells have been shown to produce Sindbis virus DI
particles
that can be replicated in both vertebrate and mosquito cells
(
10,
12).
Our results also indicated some host cell dependence of interference;
DI particles produced in C6/36 mosquito cells interfered
more with EEEV
replication in mosquito cells than in BHK cells,
whereas DI particles
produced in BHK cells interfered more with
replication in BHK
cells. However, in contrast to several studies
with Sindbis and Semliki
Forest viruses (
11,
17,
31), DI
particles of EEEV produced
in vertebrate cells do appear to interfere
with virus replication in
mosquito cells, and vice versa. Further
studies are needed to determine
whether this reflects fundamental
differences in the replication of
EEEV versus Sindbis and Semliki
Forest viruses and their corresponding
DI
particles.
| |
ACKNOWLEDGMENTS |
We thank Liz Anne Bowman, Estelle Bussey, Amy Hagenbaugh, and
William Sweeney for excellent technical assistance and Thomas Scott for
providing the EEEV strain. Esteban Domingo provided helpful suggestions
for improvement of the manuscript.
This research was supported by National Institutes of Health grants
AI26787, AI14627, and AI39508.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Pathology, University of Texas Medical Branch, Galveston, TX
77555-0609. Phone: (409) 747-0758. Fax: (409) 747-2415. E-mail:
sweaver{at}utmb.edu.
| |
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Abstract
Introduction
