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Previous Article | Next Article 
Journal of Virology, February 2001, p. 1790-1797, Vol. 75, No. 4
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.4.1790-1797.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Expression and Processing of Proteins Encoded by
the Saccharomyces Retrotransposon Ty5
Phillip A.
Irwin and
Daniel F.
Voytas*
Department of Zoology and Genetics, Iowa
State University, Ames, Iowa 50011-3260
Received 4 August 2000/Accepted 20 November 2000
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ABSTRACT |
Retroelements (retrotransposons and retroviruses) have two
genes in common: gag, which specifies structural
proteins that form a virus or virus-like particle, and
pol, which specifies catalytic proteins required for
replication. For many retroelements, gag and
pol are present on separate reading frames. Their
expression is highly regulated, and the ratio of Gag to Pol is critical
for retroelement replication. The Saccharomyces
retrotransposon Ty5 contains a single open reading frame, and we
characterized Gag and Pol expression by generating transpositionally
active Ty5 elements with epitope tags at the N terminus or C terminus
or within the integrase coding region. Immunoblot analysis identified two Gag species (Gag-p27 and Gag-p37), reverse transcriptase (Pol-p59), and integrase (Pol-p80), all of which are largely insoluble in the
absence of urea or ionic detergent. These proteins result from
proteolytic processing of a polyprotein, because elements with
mutations in the presumed active site of Ty5 protease express a single
tagged protein (Gag-Pol-p182). Protease mutants are also transpositionally inactive. In a time course experiment, we monitored protein expression, proteolytic processing, and transposition of a Ty5
element with identical epitope tags at its N and C termini. Both
transposition and the abundance of Gag-p27 increased over time. In
contrast, the levels of Gag-p37 and reverse transcriptase peaked after
~14 h of induction and then gradually decreased. This may be due to
differences in stability of Gag-p27 relative to Gag-p37 and reverse
transcriptase. The ratio of Ty5 Gag to Pol averaged 5:1 throughout the
time course experiment, suggesting that differential protein stability
regulates the amounts of these proteins.
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INTRODUCTION |
Ty5 is a Ty1/copia group
retrotransposon of Saccharomyces (4, 30).
Encoded between its long terminal repeats (LTRs) are homologues of
retroviral gag and pol genes. For the
retroviruses and LTR retrotransposons (collectively referred to as
retroelements), gag specifies the structural proteins that
form the viral core or the retrotransposon virus-like particle (VLP).
Packaged within the particle are retroelement mRNAs and products of
the pol gene. These include a protease (PR) that processes
the retroelement polyproteins, a reverse transcriptase (RT) and
its associated RNase H (RH) that synthesize a cDNA copy of the
retroelement from the template mRNA, and an integrase (IN) that
inserts the cDNA into a new site in the host chromosome. In addition to
gag and pol, retroviruses have an env
gene. The env gene product forms the viral envelope and
allows the particle to exit the cell as a membrane-bound virion, which
fuses with recipient cells during infection.
Assembly of the viral core or virus-like particle requires an excess of
"structural" Gag relative to "catalytic" Pol proteins (reviewed
in references 9 and 18). For many viruses,
the ratio of Gag to Pol approximates 15 to 1, and perturbing this ratio
results in a significant loss in replication efficiency. Retroelements
use a variety of expression strategies to regulate Gag and Pol
expression, including two that are closely tied to protein
synthesis
translational suppression and translational frameshifting. Translational suppression is employed by viruses such as
murine leukemia virus, for which gag and pol are
present in the same reading frame separated by a stop codon
(33). Translation of murine leukemia virus mRNA
predominantly produces Gag; however, occasionally the gag
amber termination codon is decoded by a glutamine tRNA to produce a
Gag-Pol fusion protein. Translational suppression is facilitated by
downstream sequences that form a pseudoknot, which slows
translation and enables the suppressor tRNA to better compete with
translation release factors (17, 31).
The second translational mechanism and most common strategy for
regulating gag and pol expression is 
1 and +1
frameshifting (reviewed in references 9 and
18). For retroelements that use frameshifting, the 3'
coding region of gag typically overlaps the 5' coding region
of pol in either the 1 or the +1 frame. Frameshifting is
triggered by secondary structures (stem loops or pseudoknots)
or rare codons in the mRNA that cause the ribosome to stall in
the overlap region and then to slip forward or backward one nucleotide
before continuing translation. Human immunodeficiency virus is an
example of a virus that uses 1 ribosomal frameshifting (19). Retroelements that use +1 frameshifting include the
yeast retrotransposons Ty1 and Ty3 (3, 10).
The coding regions of some retrotransposons lack stop codons and
internal frameshift sites. The ratio of Gag to Pol is nonetheless critical for these elements, and they use alternative strategies to
regulate Gag and Pol expression. For example, the copia
elements of Drosophila melanogaster produce a single
genome-length mRNA that is subject to differential splicing
(6, 34). The pol coding sequences are spliced
from the majority of transcripts, leading to an abundance of
gag mRNA and elevated levels of Gag protein. The Tf1
elements of Schizosaccharomyces pombe use a
posttranslational strategy to regulate the stoichiometry of Gag and Pol
(1, 25). A single Gag-Pol polyprotein is
synthesized, which is processed to yield equimolar amounts of mature
Tf1 proteins. As yeast cultures approach stationary phase, Pol is
preferentially degraded, resulting in a 26:1 ratio of Gag to Pol. The
degradation of Pol triggers Tf1 cDNA synthesis.
Like copia and Tf1, Ty5 encodes a single open reading frame
(ORF) and is the only Saccharomyces retrotransposon for
which gag and pol are not separated by a +1
frameshift (36). Ty5 and copia are members of
the Ty1/copia group of elements (Pseudoviridae), most of which contain a single ORF (4). In previous work,
we demonstrated that Ty5 expresses a single mRNA, suggesting that differential mRNA splicing is not used by Ty5 to regulate Gag and
Pol levels (36). In this study, we set out to characterize the Ty5 proteins and to assess possible mechanisms that regulate their expression.
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MATERIALS AND METHODS |
Strains, media, and Ty5 transposition assays.
The
Saccharomyces cerevisiae strain YPH499
(MATa ura3-52 lys2-801
ade2-101 trp1
63 his3200
leu21) was used in this study (28). The
XL1-Blue Escherichia coli strain was used for recombinant
DNA manipulations (Stratagene). Bacterial and yeast strains were grown
and transformed using standard methods (2). Synthetic
complete medium lacking uracil (SCU) was used to select yeast cells
with Ty5 plasmids, and rich medium (YPD) was used for nonselective
growth. Ty5 transcription is regulated by the GAL1-10 upstream activation sequence
(36); therefore, changing the carbon source from glucose
to galactose induces transcription. Before addition of galactose, cells
were grown for 10 to 26 h on raffinose as the carbon source. This
insured that glucose was metabolized completely before induction.
Liquid cultures also contained 2% (wt/vol) Casamino Acids.
Quantitative Ty5 transposition was carried out as previously described
(36).
Cloning and plasmids.
All plasmids were derived from pSZ152,
which contains a Ty5 element from Saccharomyces paradoxus
(36). Epitope-tagged Ty5 elements were constructed using
PCR site-directed mutagenesis (16) with primers that
encoded the epitope.
(i) The plasmid with a His-tagged RT (pIP19) was constructed using
overlapping primers DVO447
(5'-ATC-TGT-TAG-TGA-TGG-TGA-TGG-TGA-TGC-GAT-CCT-CTC-ATT-TTT-GCA-GTT-TCT-GGT-TCC-CTC-3') and DVO448
(5'-CTG-CAA-AAA-TGA-GAG-GAT-CGC-ATC-ACC-ATC-ACC-ATC- ACT-AAC-AGA-TCG-AGG-TCG-ACG-GTA-3').
These primers were designed to place the His tag
(MRGSH6; Qiagen) directly in front of the Ty5
stop codon.
(ii) The T7 epitope (MASMTGGQQMG; Novagen) was inserted at the C
terminus of RT by first amplifying Ty5 with DVO465
(5'-GCT-CTA-ACT-GCT-ATT-ATC-3'), which is upstream of a
PflMI site, and the mutagenic
primer DVO560 (5'-CCA-TCG-ATT-AAC-CCA-TTT-GCT-GTC-CAC-CAG-TCA- TGC-TAG-CCA-TTT-TTG-CAG-TTT-CTG-GTT-C-3'),
which carries the T7 tag and a ClaI restriction site. The
amplified product and pSZ152 were digested with PflMI and
ClaI and ligated. Because the his3AI marker
cassette was removed by ClaI digestion, it was then
reinserted to create pXW182.
(iii) The plasmid with an N-terminal His tag, pNK520, was constructed
using the overlapping primers DVO557
(5'-ATG-AGA-GGA-TCG-CAT-CAC-CAT-CAC-CAT-CAC-ACA-TAT-AAG-CTA-GAT-CG-3') and DVO558
(5'-GTG- ATG-GTG-ATG-GTG-ATG-CGA-TCC-TCT-CAT-AAT-GTT-GTA-AGT- TTA-TTG-G-3').
The first 10 amino acid residues of the resulting Ty5 element were
MRGSH6.
(iv) It was previously found that a portion of the C terminus of
integrase could be modified without compromising transposition (X. Gai
and D. Voytas, unpublished data). One integrase derivative (pXW29)
contained a BglII site at nucleotide position 2845. This construct was used as a template for amplification with a Ty5-specific primer and the mutagenic primer DVO543
(5'-CGG-AAT-AGA- TCT-GTG-ATG-GTG-ATG-GTG-ATG-CGA-TCC-TCT-TTG-TAT-CCT- TGT-TGG-TGG-3').
The amplification product carried the RGSH6
epitope tag as well as a BglII site. This product was
reinserted into pXW29, giving rise to pWW32. The wild-type residues
IQHS were changed to IQRGSH6RS.
(v) Protease was mutated by PCR with primer DVO246
(5'-CAT-GTG-TGA-AGT-AAT-CGC-GAT-GAT-ACA-AAT-CCA-ATC-TGA-3')
and a Ty5-specific primer. This inserted a NruI
restriction site into the presumed active site of Ty5's aspartic
protease and changed the residues DTGC to IIAI. The resulting PCR
product was used to replace the corresponding wild-type sequence of
pSZ152, thus creating pNK259. The protease mutation was moved into the
epitope-tagged constructs described above, giving rise to pIP20,
pNK526, pIP38, and pNK527 (Fig. 1).
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FIG. 1.
Epitope-tagged Ty5 elements and their respective
transposition frequencies. The genomic organization of Ty5 is shown at
the top. Boxes with filled arrowheads represent LTRs; UAS identifies
the GAL1 upstream activating sequence that drives Ty5
transcription. The Ty5 ORF is indicated by a single line above the
element. The location of regions encoding conserved amino acid sequence
domains within gag and pol are indicated.
Replication by reverse transcription is monitored by the
his3AI marker gene (8, 36). Below the map
of Ty5 are the various constructs used in this study. Construct names
are on the left, and transposition frequencies (TP) are on the right.
"None" indicates a transposition frequency of  0.04 × 10 5. pr, protease mutation. Epitope tags were placed
at various positions: T, T7 tag (MASMTGGQQMG); H, His tag
(RGSH6).
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(vi) Several plasmids were created by swapping restriction
fragments from the various constructs. A C-terminal His tag (pIP19) was
combined with either the N-terminal His tag (pNK520) or the N-terminal
His tag protease mutant (pNK526) to produce pIP37 and pIP38,
respectively. The C-terminal T7 tag (pXW182) was combined with
the N-terminal His tag (pNK520) to produce pNK522.
Protein preparation.
Yeast strains growing on plates were
used to inoculate a small volume of SCU-glucose medium, and cultures
were grown to saturation (30°C). Cells were harvested by
centrifugation (1,500 × g, 4°C, 5 min), resuspended
in SCU-raffinose medium (starting optical density at 600 nm
[OD600], 0.4 to 0.6), and then grown at 30°C for an additional 10 to 26 h. The raffinose culture was
centrifuged (1,500 × g, 4°C, 5 min), resuspended in
SCU-galactose medium (starting OD600, 0.4 to
0.6), and grown at room temperature (22 to 25°C) until the
OD600 reached 2.5 to 3.5. Harvested cells were disrupted using the glass bead method (2). The cell lysate was centrifuged (20,000 × g, 60 min), and the
supernatant was collected. The remaining pellet was extracted with
disruption buffer containing 8 M urea; a volume equivalent to that of
the supernatant was used to enable comparisons between the soluble and
insoluble fractions. A Dounce homogenizer aided in extracting proteins
from the pellet. The extract was centrifuged (20,000 × g, 15 min, 4°C) and the supernatant was collected. For the
time course study, proteins were extracted from an equivalent number of
cells (based on OD600) and harvested at various
time points after induction on galactose media. Transposition was also
measured at each time point using our standard quantitative assay
(36).
To evaluate Gag solubility, proteins were prepared as described above
from strains with pNK522. Aliquots of the cell lysate (100 µl) were
centrifuged (20,000 × g, 5 min, 4°C), and the
resulting pellet was extracted with 100 µl of Tris-buffered saline
(TBS) containing one of the following: 8 M urea; 0.1, 1.0, or 2.0%
sodium dodecyl sulfate (SDS); or 3.0 or 6.0% Triton X-100. The
extracted sample was centrifuged (20,000 × g, 5 min,
4°C) and the supernatant was collected (soluble proteins). The
remaining pellet was resuspended in 100 µl of TBS (insoluble protein
suspension). Equal volumes (20 µl) of soluble proteins and the
insoluble protein suspension were mixed with SDS-polyacrylamide gel
electrophoresis loading buffer and analyzed by immunoblotting.
To characterize the protease mutant, proteins were prepared as
described above from yeast cells carrying pIP20. After centrifugation of the cell lysate, the soluble His-tagged proteins were purified using
Qiagen's nickel-nitrilotriacetic acid agarose. A 250-µl aliquot of
the soluble protein was diluted with 750 µl of a modified Qiagen
binding buffer (100 mM
NaH2PO4, 10 mM Tris-Cl [pH
8.0], 10 mM imidazole, 5% glycerol). The diluted sample was incubated with 125 µl of nickel-nitrilotriacetic acid agarose for 1 h at room temperature. The slurry was loaded into a gravity flow column, and
1 ml of unbound sample was collected. The column was washed once with
600 µl of binding buffer containing 10 mM imidazole and once with 600 µl of binding buffer containing 20 mM imidazole and then eluted with
600 µl of binding buffer containing 250 mM imidazole. The column was
stripped with 600 µl of binding buffer containing 20 mM EDTA. The
collected fractions (60 µl) were used for immunoblot analysis.
Immunoblot analysis.
Epitope-tagged Ty5 proteins were
subjected to SDS-polyacrylamide gel electrophoresis and then
electrophoretically transferred to a nitrocellulose membrane
(NitroBind; Micron Separations Inc.) in a modified transfer buffer (25 mM Tris, 0.2 M glycine, 0.1% SDS, 10% methanol) (2). The
membrane was blocked with 3% (wt/vol) bovine serum albumin in
TBS-Tween-Triton (TBSTT) (10 mM Tris-HCl [pH 7.5], 150 mM NaCl,
0.05% Tween 20, 0.2% Triton X-100). The membrane was incubated for
1 h with either RGS-His monoclonal antibody (Qiagen) or the T7 tag
monoclonal antibody (Novagen) that had been diluted 1:1,000 in blocking
buffer. The membrane was then incubated for 1 h with a horseradish
peroxidase-conjugated sheep anti-mouse antibody that had been diluted
1:4,000 in 10% nonfat dry milk-TBSTT. Detection was accomplished using
enhanced chemiluminescent detection reagents (ECL; Amersham). Finally, the membrane was exposed to Fuji medical X-ray film. Densitometry was
performed on scanned films using the NIH Image (version 1.62) program
(developed at the U.S. National Institutes of Health and available on
the Internet at http://rsb.info.nih.gov/nih-image/).
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RESULTS |
Characterizing the Ty5 proteins.
Ty5 has a single ORF whose
product has amino acid similarity to the structural (Gag) and enzymatic
(Pol) proteins required for replication of other retrotransposons and
retroviruses. To characterize Ty5 protein expression, we modified the
coding region by the addition of epitope tags. Two short
epitope tags were chosen to minimize effects on protein function:
(i) a His tag that allows purification under native or denaturing
conditions through metal-chelate chromatography and (ii) a T7 tag
that allows for protein purification using resin-conjugated
antibodies. In both cases, monoclonal antibodies were available
for detecting tagged proteins by immunoblot analysis. We positioned
epitope tags at the very N and C termini of the Ty5 polyprotein,
and elements encoding these tags transposed at levels two- to sixfold
lower than those of the wild type (Fig. 1). Addition of both
tags reduced transposition by at most ninefold. We previously
identified a nonessential region in the presumed C terminus of IN (Gai
and Voytas, unpublished). This region was also chosen as a site for His
tag insertion (Fig. 1, pWW32), and the modified element transposed at
levels approximately threefold lower than those of the wild type.
Several of the tagged constructs were further altered to carry
mutations in a region of the Ty5 polyprotein that shows
similarity to aspartic proteases encoded by other retrotransposons and
retroviruses (the DTG motif). For Ty1 and Ty3, mutations in this motif
abolish polyprotein processing (23, 35). All Ty5
constructs with a mutation in the DTG motif were transposition
defective (Fig. 1).
Yeast cells with tagged Ty5 elements were grown in liquid galactose
media to induce transcription and transposition. Cells were harvested
in late log phase and then lysed by the glass bead method (see
Materials and Methods). Lysates were centrifuged, and proteins from the
supernatant (soluble fraction) and pellets (insoluble fraction) were
analyzed by immunoblotting using monoclonal antibodies specific for the
epitope (Fig. 2A). An insoluble
59-kDa protein was the most abundant species expressed by the element with a C-terminal His tag (pIP19). Because the C terminus of the Ty5
protein shows similarity to reverse transcriptase and RNase H, we
designated this protein RT (Pol-p59). For the element carrying an
N-terminal His tag (pNK522), two Gag species of 27 and 37 kDa were
observed (Gag-p27 and Gag-p37). These proteins were of approximately equal abundance and, like RT, were found only in the insoluble fraction. For the element with a His tag near the presumed catalytic domain of integrase (pWW32), comparable levels of an ~80-kDa protein were observed in both the soluble and insoluble fractions, suggesting that this species is Ty5 IN (Pol-p80). To characterize the protein insolubility, we extracted insoluble proteins expressed by an N-terminally tagged Ty5 element (pNK522) with several concentrations of
two detergents and 8 M urea (Fig. 2B). Up to 6% Triton X-100 was
unable to solubilize the His-tagged Gag protein. In contrast, concentrations of SDS greater than 0.2% or 8 M urea were very effective in releasing the pellet-bound proteins.
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FIG. 2.
Immunoblot analysis of His-tagged Ty5 proteins. (A) Ty5
transcription was induced in yeast cells carrying various
epitope-tagged Ty5 elements. These include His tags located at the
C terminus of RT (pIP19), at the N terminus of Gag (pNK522), or within
IN (pWW32) (Fig. 1). Cells were harvested, lysed, and centrifuged to
obtain total soluble yeast protein (S) (see Materials and Methods). The
remaining pellet (P) was extracted with a volume of 8 M urea equivalent
to that of the supernatant. The exception was pIP19 (His-tagged RT),
for which the pellet was extracted with one-fifth the supernatant
volume. Equal volumes (20 µl) of all fractions were loaded onto SDS
gels and transferred to nitrocellulose. (B) In order to further
evaluate Ty5 Gag solubility, pellets were extracted with buffer
containing one of the following: 8 M urea; 2, 1, or 0.2% SDS; or 6 or
3% Triton X-100. The extracted pellets were centrifuged and the
supernatants (S') were recovered. The remaining pellets (P') were
resuspended in a volume of SDS loading buffer equal to that of the
supernatant to enable direct comparisons with the soluble proteins.
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Ty5 is translated into a single polyprotein.
One
likely explanation for how the different Ty5 proteins are generated is
that a single polyprotein is synthesized and subsequently processed by a Ty5-encoded protease. To test this, we analyzed expression of a Ty5 protein with a His-tagged RT and a mutation in the
presumed active site of protease (pIP20). If Ty5 protease is
responsible for cleaving the polyprotein, then we should detect in the mutant an approximately 182-kDa protein corresponding to the primary translation product. Proteins were prepared from a strain
expressing the Ty5 protease mutant, and immunoblot analysis revealed a
large protein in the predicted size range as well as other
nonspecific proteins with lower molecular weights (Fig. 3). The high-molecular-weight species was
not previously observed in wild-type strains (e.g., Fig. 2A). To
confirm that the putative polyprotein was encoded by Ty5, we
subjected the protein extract to metal chelate chromatography to enrich
for His-tagged proteins. The high-molecular-weight protein specifically
bound the resin (Fig. 3, lane E) in contrast to the
lower-molecular-weight, cross-reacting proteins (Fig. 3, lanes U, W1,
and W2). This indicates that the large protein is encoded by Ty5, and
we designate it Gag-Pol-p182 based on its mobility and its molecular
weight extrapolated from the Ty5 amino acid sequence. The absence of
lower-molecular-weight His-tagged proteins in the mutant indicates that
Ty5's aspartic protease is required for cleaving the
polyprotein.
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FIG. 3.
Ty5 polyprotein identification and purification.
After 32 h of growth on galactose media, protein was prepared from
yeast cells with a Ty5 element encoding a C-terminal His tag and a
protease mutation. The protein sample was electrophoresed on an SDS
gel, blotted to nitrocellulose, and probed with the RGSH6
antibody (L1). In contrast to results in Fig. 2A, the p59 RT signal was
absent and a large protein at approximately 182 kDa was observed. To
determine if the large protein carried a His tag, the protein sample
was diluted with binding buffer (L2) and subjected to nickel chelate
chromatography. Additional lanes represent unbound flowthrough (U), 10 mM imidazole wash (W1), 20 mM imidazole wash (W2), 250 mM imidazole
eluate (E), 20 mM EDTA eluate (X), and a Gag-positive control (G).
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Proteolytic processing and transposition: a time course study.
We sought to understand the kinetics of Ty5 protein processing and the
relationship of processing to transposition. A yeast strain with
pIP37 (His-Gag, His-RT) was induced for transposition by growth on
galactose. At 2-h intervals after induction, the culture's
OD600 was measured, and samples were
harvested. Proteins were extracted from equivalent numbers of cells and
subjected to immunoblot analysis using antibodies that recognize the
His tag. Because Gag and RT contain identical epitopes, this
allowed direct comparisons of protein abundance. As observed in
previous experiments, the Ty5 proteins were insoluble (Fig.
4A); none were detected in
immunoblots performed with soluble fractions (data not
shown). Therefore, the amount of insoluble protein represents the
total Ty5 protein expressed. We also stained all gels after electrophoretic transfer to membranes to ensure that no protein remained in the gels. As a control, a study with a parallel time course
was conducted with a dually His-tagged protease mutant. In addition to
Gag-Pol-p182, a second high-molecular-weight species of comparable size
was observed. Because this protein is specific to extracts from the
protease mutant, it may represent a polyprotein breakdown
product. A protein somewhat larger than RT was apparent in proteins
prepared from both the wild type and the protease mutant (Fig. 4A and
B). This protein was observed only with C-terminal His tags (Fig. 4A).
We do not know the origin of this protein, but because it is found in
both wild-type and protease mutant extracts, we do not believe it
represents a processed form of Ty5 protein. Rather, it may
also represent a polyprotein breakdown product.
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FIG. 4.
Ty5 protein expression and transposition: a time course
analysis. (A) A yeast strain carrying a Ty5 element with His tags at
its N and C termini (pIP37) was induced for transposition by growth in
liquid galactose media. Culture samples were taken every 2 h and
analyzed for protein expression by immunoblotting. Time points are
indicated above the blot. Independent preparations of both His-tagged
RT (R) and His-tagged Gag (G) were run as protein references. (B) An
immunoblot was prepared as for panel A except that a dually tagged
element with a protease mutation was used (pIP38). (C) Densitometry
analysis of the blot in panel A. The Gag/Pol ratios were calculated by
summing the OD units for Gag-p27 and Gag-p37 and then dividing by the
OD units for Pol-p59. (D) Transposition efficiency for the time course
in panel A. Transposition frequencies are the averages for three
culture samples taken from each time point.
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Shortly after induction, Gag-p37 began to accumulate (Fig. 4A and C)
and increased in amount until h 12 to 14, after which its abundance
slowly declined. By 8 h after induction, Gag-p27 began to appear
and slowly increased throughout the remainder of the time course
experiment. The relatively late appearance of Gag-p27 suggests that the
37-kDa Gag species is initially released from the polyprotein
and then subsequently processed at its C terminus to generate the
27-kDa product. The accumulation of RT (Pol-p59) paralleled that of
Gag-p37; however, it had significantly lower abundance (Fig. 4A and C).
Despite fluctuations in protein amounts, the ratio of Gag (p27 plus
p37) to Pol (p59) was relatively constant throughout the time course
experiment, with the average being 5:1 (Fig. 4C). The only striking
change occurred when the culture reached saturation (h 32), at which
point the ratio shifted to 15:1.
The frequency of transposition was calculated at each of the time
points. The dually His-tagged Ty5 element carries a his3AI marker, which enables selection of transposition events by histidine prototrophy conferred when Ty5 cDNA enters the genome. This can occur
by integration of the cDNA, mediated by the Ty5-encoded integrase, or
through homologous recombination between the cDNA and donor Ty5 element
(22). Transposition (which in this study refers to both
integration and cDNA recombination) was observed as early as 2 h
after induction, before any Ty5 proteins were evident. Transposition
frequencies formed two plateaus (Fig. 4D): from h 2 to 14 the frequency
was less than 2 × 105; h 16 was an
inflection point, and then the frequency increased to somewhat more
than 4 × 105. The range of transposition
was 26-fold, from 0.31 × 105 at h 2 to
8.2 × 105 at h 28. There was no apparent
correlation between transposition and the kinetics of protein
processing or abundance.
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DISCUSSION |
The Ty5 proteins.
Most retroelements carry gag and
pol on separate reading frames separated by a stop codon
or frameshift, and this genetic organization is important for the
differential expression of these two genes. Retroelement mRNAs
typically direct the synthesis of Gag, which is encoded at the 5' end
of the element. Occasionally, a Gag-Pol fusion protein is synthesized
that results from translational suppression of the gag stop
codon or ribosomal frameshifting that occurs within an overlap
region between gag and pol (reviewed in
references 9 and 18). These expression
strategies produce an excess of Gag relative to Pol, which is
required for assembly of a functional virus or virus-like
particle. The single ORF present in Ty5 is
unusual among characterized retroelements and suggests that equal amounts of Gag and Pol are expressed. To
investigate Ty5 protein expression, we created a series of Ty5
elements with epitope tags at the N terminus, at the C
terminus, or near the conserved catalytic domain of integrase.
All epitope-tagged elements were transpositionally competent and
transposed at levels not more than ninefold lower than that of the wild type.
Immunoblot analysis of proteins expressed from an N-terminally tagged
Ty5 element revealed two primary protein species, which we believe
represent the major forms of Ty5 Gag (Gag-p37 and Gag-p27). Because of
the N-terminal location of the tag, the 10-kDa difference between the
two proteins must represent a C-terminal processing event. Ty5 Gag has
a zinc finger motif (36), and by extrapolating molecular
weights from the Ty5 amino acid sequence, we predict that the finger
motif resides within the presumed 10-kDa protein. Finger motifs are
characteristic of retroviral nucleocapsid proteins (NC), which bind
template mRNA, help assemble the particle shell, and have sizes (60 to 90 amino acids) similar to that of the predicted Ty5 protein
(29). Confirming the existence of the 10-kDa protein and
determining its possible role in transposition will require additional
experimentation. Other yeast retrotransposons express multiple Gag
species (Fig. 5): Ty1 encodes a 58-kDa
Gag protein that is proteolytically cleaved at its C terminus into a
54-kDa product, the major protein found in Ty1 virus-like particles
(13). The 4-kDa C terminus of Ty1 Gag that is released
during maturation may carry out an NC role, despite the fact that it
lacks a zinc finger motif (27). The phylogenetically
distant Ty3 retrotransposons produce multiple forms of Gag, which are
encoded by GAG3. Among these are a 39- or 38-kDa protein and
its two processed products, a 26-kDa capsid (the outer protein shell of
a virus particle) and a 9-kDa nucleocapsid (14). Tf1 of
Schizosaccharomyces pombe is similar to Ty5 in that it
encodes a single ORF. The Tf1 polyprotein is processed to
generate a 27-kDa Gag species (1). Like Ty1, Tf1 does not
encode a zinc finger motif characteristic of nucleocapsid proteins
(26).
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|
FIG. 5.
Summary of Ty5 proteins. (A) Estimated sizes of the
processed Ty5 proteins are based on their mobility on
SDS-polyacrylamide gel electrophoresis gels. The sizes of nucleocapsid
and protease were estimated based on the position of conserved amino
acid sequence domains and the sizes of adjacent Ty5 proteins. (B)
Comparison of protein sizes, in kilodaltons, between Ty5 and other
retrotransposons. Question marks indicate protein sizes that were
extrapolated from amino acid sequence data. Relevant references for the
other retrotransposons are found in the text.
|
|
Immunoblots prepared from cells expressing a C-terminally tagged
element identified a predominant protein species of 59 kDa that we
designate RT (Pol-p59). Based on molecular weight extrapolations from
the Ty5 amino acid sequence, Pol-p59 is large enough to encompass all
of the amino acid sequence domains that characterize RT and RH. In
comparison, Ty1 and Ty3 RT are 60 and 55 kDa, respectively (13,
14) (Fig. 5B). Immunoblots prepared from cells expressing a
centrally located His tag revealed an 80-kDa protein, which we believe
is IN (Pol-p80). The His tag resides within a poorly conserved region
downstream of the catalytic domain of IN. Our lab has previously
described a role in targeting integration for sequences further
downstream from the His tag (amino acid 1094) (11). When a
His tag is inserted at position 1094, the resulting protein is
identical in size to the IN species observed in this study (W. Xie and
D. Voytas, unpublished data). This places the protease cleavage site
downstream of residue 1094, which is consistent with the observed size
of RT. Comparatively, Ty1, Ty3, and Tf1 IN are 90, 61, and 56 kDa,
respectively (13, 15, 25). We provide evidence that Ty5
also encodes a protease (see below), but because it was not epitope
tagged, we did not detect it in our experiments. Based on the protein
species observed and the derived amino acid sequence of Ty5, we predict
that protease approximates 17 kDa. Proteases encoded by Ty1 and Ty3 are
23 and 16 kDa, respectively (13, 23).
Protease is required for Ty5 protein processing.
The single
ORF present in the Ty5 element suggests that it specifies a large
polyprotein that is processed to give rise to the various
products described above. Typically, a dimeric aspartic protease
cleaves retroelement-encoded polyproteins (20).
Evidence for a Ty5-encoded protease was first suggested by amino acid
sequence comparisons with closely related elements such as
copia, Ta1, and Ty1, all of whose products have a motif
conserved among protease active sites (D[S/T]G) (20,
36). We mutated Ty5's DTG motif in several of the
epitope-tagged elements and found that this abolished
transposition. Elements with the mutation expressed an approximately
182-kDa protein, which we purified by nickel affinity chromatography,
confirming that it carried a His tag. These results indicate that the
DTG residues are important for transposition and protein processing,
and they likely define the active site of Ty5 protease. It is unlikely
that Ty5 expresses proteins from spliced mRNAs, like the
single-ORF copia elements of D. melanogaster
(6, 34). We have previously shown that Ty5
expresses a single, genome-length mRNA (36), and
elements with a protease mutation and epitope tags at both the N
and C termini accumulate primarily the 182-kDa protein. This latter observation also suggests that frameshifting events do not occur that
introduce stop codons during translation to generate truncated protein products. Nonetheless, we do observe some bands that
cross-react with the epitope-specific antibodies, which we believe
are polyprotein breakdown products. Until these cross-reacting
proteins are better characterized, we cannot completely exclude the
possibility that Ty5 employs a nonconventional expression mechanism.
Ty5 protein insolubility.
Virus-like particles produced by Ty1
and Ty3 are soluble and can be purified on sucrose density gradients
(12, 14). Tf1 VLPs, however, are less soluble and are
readily pelleted from cell lysates by low-speed centrifugation
(1). A characteristic feature of Ty5 proteins is their
high insolubility, and denaturing agents such as ionic detergents or
urea are required to bring them into solution. Insolubility may be an
inherent feature of Ty5 proteins, or it may be due to a defect in
particle assembly. The latter is consistent with the observation that
some Ty1 gag mutants express proteins that are highly
insoluble (5). Immunolocalization studies also indicate
that mutant forms of Ty1 Gag and Ty5 proteins form aggregates within
the cytoplasm (reference 7 and unpublished data). Ty5 VLP
assembly may be hindered because Ty5 originates from a heterologous
host (S. paradoxus) or because the Ty5 element used in these
studies carries naturally occurring mutations. Two independent Ty5
gag mutations have recently been isolated which, when
combined, increase Ty5 transposition more than 10-fold (X. Gao, D. Rowley, and D. Voytas, unpublished data). These mutant elements are
being tested to determine whether they form VLPs and whether they
confer changes in protein solubility.
Ty5 protein processing and the onset of transposition.
The
ratio of Gag to Pol is critical for retroelement replication. Altering
Ty1 frameshifting, for example, changes the relative abundance of these
two proteins and has deleterious consequences for transposition
(3, 32). Our data indicate that mature Ty5 Gag and Pol
proteins are generated from processing of a single polyprotein,
suggesting that they are produced in equimolar amounts. To test this,
we measured the relative abundance of Gag and Pol (RT) using a Ty5
element with identical His tags at its N and C termini. Expression was
monitored over a time course after induction of transcription so that
protein abundance could be correlated with processing and
transposition. To ensure that all Ty5 proteins were accounted for, gels
were stained after immunoblotting to confirm that electrophoretic
transfer was complete, and immunoblots were performed with both soluble
and insoluble protein extracts from each of the time points.
Gag-p37 appeared shortly after induction (4 h). This protein peaked at
approximately h 14 and then slowly declined in abundance. In contrast,
Gag-p27 appeared 4 h after Gag-p37 and increased throughout the
time course. The expression profiles for these two proteins suggest an
order for Ty5 Gag processing events: the protease cleavage site between
Gag and PR that generates Gag-p37 is likely among the first sites
cleaved. This is also the first site cleaved in the Ty1
polyprotein (27). Once Gag-p37 is released, a
subsequent cleavage near its C terminus gives rise to Gag-p27. Other
sites within the polyprotein must be cleaved efficiently, as
high-molecular-weight processing intermediates were rarely observed.
Throughout the time course experiment, the RT profile paralleled that
of Gag-p37; however, RT was of significantly lower abundance. Despite
changes in the relative amounts of individual proteins, the ratio of
Gag (p27 plus p37) to Pol (p59) was relatively constant and averaged
5:1. This is somewhat lower than that observed for retroviruses (e.g.,
~15 to 1) (reviewed in reference 18) and other
retrotransposons (Ty1, 33:1 [21]; Tf1, 26:1
[1]). Because Ty5 proteins were measured from whole-cell
extracts, the Gag to Pol ratio could be skewed by the
accumulation of nonproductive protein aggregates. The relative
amounts of Gag and Pol may differ in VLPs and may more closely
approximate those of other retrotransposons.
How is it that levels of Ty5 Pol are significantly less than those of
Gag when both are derived from the same polyprotein? One
explanation is that Ty5 Gag and Pol are turned over at different rates,
similar to the proteins expressed by the Tf1 elements of S. pombe. For Tf1, entry into stationary phase triggers changes in
protein abundance (1). In log-phase cultures, the amounts of Tf1 Gag and Pol are equivalent. As the medium is depleted of nutrients, Pol is degraded over an approximately 6-h time period, resulting in a Gag/Pol ratio of 26:1. Tf1 cDNA levels increase when the
culture is saturated, indicating that the bulk of reverse transcription
occurs when there is a molar excess of Tf1 Gag. The abrupt shift in the
amounts of Tf1 proteins and cDNA differs from what we observed with
Ty5. Ty5 proteins gradually changed in abundance throughout the growth
of the culture, and the Ty5 Gag/Pol ratio remained relatively constant.
Transposition was detected at the earliest time point and increased
26-fold over the course of the experiment. There was no clear
correlation between Ty5 transposition and the Gag/Pol ratio.
Nevertheless, an increase in this ratio (from 5:1 to 15:1) was observed
after the culture reached saturation. Ty5 protein abundance, therefore,
may be sensitive to culture conditions, but culture conditions do not
appear to be the primary signal that triggers changes in protein
stability and transposition.
The organization of gag and pol on separate
reading frames is typical of only the small subset of
retroelements that have been characterized to date. We have already
discussed two exceptions, namely, copia of D. melanogaster and Tf1 of S. pombe. Many other examples are found in plants, where most retrotransposons carry gag and pol on a single ORF, and this includes
both Ty1/copia and Ty3/gypsy elements (reviewed
in reference 24). Among the single-ORF
retrotransposons, Tf1 and now Ty5 appear to regulate levels of Gag and
Pol by differential protein stability. Posttranslational mechanisms, therefore, may be widely used to meet the apparently universal requirement among retroelements for an excess of Gag relative
to Pol. Additional studies that test whether changes in Ty5 protein
stability affect transposition will be required to substantiate this hypothesis.
| |
ACKNOWLEDGMENTS |
We thank Ning Ke, Weiwu Xie, and Xiaowu Gai for constructing
several of the epitope-tagged Ty5 elements.
This work was supported by NIH grant GM51425 and by Hatch Act and State
of Iowa funds.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Zoology and Genetics, Iowa State University, 2208 Molecular Biology
Building, Ames, IA 50011-3260. Phone: (515) 294-1963. Fax: (515)
294-7155. E-mail: voytas{at}iastate.edu.
Journal paper J-19002 of the Iowa Agriculture and Home Economics
Experiment Station, Ames, Iowa, project no. 3383.
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Journal of Virology, February 2001, p. 1790-1797, Vol. 75, No. 4
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.4.1790-1797.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
