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Previous Article | Next Article 
Journal of Virology, July 1999, p. 5912-5917, Vol. 73, No. 7
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Recombination between Two Identical Sequences
within the Same Retroviral RNA Molecule
Jiayou
Zhang* and
Christy M.
Sapp
Department of Microbiology and Immunology and
Markey Cancer Center, University of Kentucky, Lexington, Kentucky
40536-0096
Received 10 November 1998/Accepted 12 March 1999
 |
ABSTRACT |
As a consequence of being diploid viruses, members of the
Retroviridae have a high recombination rate. To measure
recombination between two identical sequences within the same RNA
molecule per round of retroviral replication cycle, a murine leukemia
virus based vector (JZ442 + 3' Hyg) has been constructed. It
carries a drug resistance gene, hyg, and a 290-bp repeat
sequence of the 3' hyg gene inserted into the 3'
untranslated region of the green fluorescent protein gene
(gfp). Under fluorescence microscopy, Hygr
cells containing the recombinant proviruses were clear, while a green
color was observed in the drug-resistant cells carrying the parental
proviruses. The rate of recombination was determined by the ratio of
the number of clear colonies to the total number of Hygr
colonies (green and clear colonies). The rate of recombination was
found to be 62% by this method. The intermolecular recombination rate
between an infectious virus bearing two copies of the 290-bp segment
and a noninfectious chimeric RNA virus containing only a single copy of
this sequence was also measured.
| |
INTRODUCTION |
The presence of two genomic RNA
molecules in retroviral virions results in a high rate of recombination
(4). To study recombination, two different proviruses were
introduced into one retroviral helper cell line. The recombinants were
then judged by the expression of markers from both parental proviruses.
Evidence shows that intermolecular recombinations occur frequently
(8, 17). Previously, it was deduced that recombination may
occur between two sequences within the same RNA molecule
(intramolecular) as well as between sequences within two separate RNA
molecules (intermolecular) (15). If intramolecular
recombination occurs, it will result in a deletion within the progeny
provirus. However, there is no direct evidence indicating that
intramolecular recombination occurs. This is because, in the
experiments described above, retroviral particles were able to package
either two different RNA molecules or two identical RNA molecules. The
deletion can be the result of an intramolecular event or the
recombination of an upstream sequence from one RNA molecule with a
downstream sequence from the other RNA molecule. Since current
technology cannot separate viral particles containing two identical
molecules (homogeneous) from those containing two different molecules
(heterogeneous), intermolecular recombination cannot be excluded as the
source of deletion recombinants.
Previously, retroviral vectors containing two identical sequences
separated by a packaging signal within the same RNA molecule were
constructed and used to infect cells to examine deletion rates (5,
9). The investigators found that the rate of deletion in progeny
proviruses was 57 to 93% after one round of replication. This result
does not exclude the possibility that the high rate of deletion
resulted from the packaging signal being a hot spot for reverse
transcriptase template switching events (9). In addition,
because the viruses analyzed were from a pool of transfected cells
(5), it could not be determined if the deletion occurred during reverse transcription or occurred during transfection with the
proviral DNA.
To further study recombination between two identical sequences within
the same RNA molecule, murine leukemia virus (MLV)-based vector
(JZ442 + 3' Hyg) has been constructed. This vector contains a
whole hyg gene and an unselected color marker
reporter gene, the green fluorescent protein gene (gfp).
Additionally, it carries an extra 3' hyg gene segment of 290 bp inserted into the 3' untranslated region of the gfp gene.
This construct allows us to demonstrate that a high rate of deletion
does not relate to the packaging signal sequence. The intermolecular
recombination rate between an infectious virus bearing two copies of
the 290-bp segment and a chimeric RNA virus containing a single copy of
this sequence was also measured. The rate of intermolecular
recombination in the presence of two copies of identical sequences on
the infectious RNA molecule did not increase much compared with the
rate (62%) of recombination between the two identical sequences on the
same RNA molecule.
| |
MATERIALS AND METHODS |
Nomenclature.
Plasmids are designated as, for example,
pJZ442; viruses made from these plasmids are designated as, for
example, JZ442. Some infectious Moloney murine leukemia virus (MLV)
vectors contained a 290-bp sequence (3' hyg). When the
290-bp sequence was inserted at the 5' end of the neo gene,
the number of nucleotides inserted is on the left of the "N" (N
stands for neo) (for example, pL290N). When the 290-bp
sequence was inserted at the 3' end of the neo gene, the
number of nucleotides inserted is on the right of the "N" (for
example, pLN290).
Vector constructions.
All recombinant techniques were
carried out by conventional procedures (14). All vector
sequences are available upon request.
(i) Construction of pJZ442 and pJZ442 + 3' Hyg (Fig.
1A and B).
The pJZ442 construct,
from 5' to 3', was assembled as follows. The 5.4-kb
NdeI-BamHI fragment (from positions 2990 to 1630) was isolated from pLN (12) and contains the neo
gene and the two MLV long terminal repeats (LTRs). The 0.7-kb
BamHI-SalI fragment (from positions 1631 to
2387) was isolated from pEGFP-1 (Clontech, Palo Alto, Calif.). The
0.6-kb SalI-NdeI fragment (from positions 2388 to
2989) was isolated from pCITE-1 (Novagen, Madison, Wis.) and contains
the internal ribosome entry segment (IRES) sequence. In pJZ442 + 3'
Hyg, the SacII-HindIII fragment (290 bp long)
of the 3' hyg sequence was inserted at the NotI
and ClaI sites of pJZ442, which are located downstream of
the open reading frame of the gfp gene.
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FIG. 1.
Structures of retrovirus vectors used for determination
of the recombination rate between two identical sequences within the
same RNA molecule. (A) Structure of the retrovirus vector containing
the hyg gene and the gfp gene. The hyg
gene is expressed from the 5' MLV LTR, and the gfp gene is
expressed from an encephalomyocarditis virus IRES. (B) Structure of the
retrovirus containing two identical sequences. JZ442 + 3' Hyg is
similar to JZ442, except that JZ442 + 3' Hyg also contains 290 bp
of the 3' hyg gene sequence downstream of the gfp
gene. (C) Structure of the recombinant provirus. After one round of
replication, the downstream 3' hyg gene sequence will
recombine with the identical upstream hyg gene sequence and
result in the deletion of the gfp gene. Recombinants,
therefore, contain only the hyg gene. The broken lines
between JZ442, JZ442 + 3' Hyg, and the recombinant provirus
indicate the identical 3' hyg gene sequences.
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(ii) Construction of pJZ211, pLN290, pL290N, and pL290N290 (Fig.
2).
The pJZ211 and pLN290 constructs
were described previously (17, 18). The 290-bp
hyg sequence in pL290N and pL290N290 was cloned as the
SacII-HindIII fragment from pJZ211.
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FIG. 2.
Chimeric RNA vector, infectious virus vectors, and
resulting recombinants. JZ211 contains only the 5' MLV LTR, while the
infectious vectors LN, LN290, L290N, and L290N290 contain two MLV LTRs.
The recombinant proviruses containing the hyg gene form only
when recombination occurs between JZ211 and an infectious vector such
that the hyg gene is flanked by two LTRs. Recombination
between JZ211 and LN is nonhomologous (17). Most
recombinations between JZ211 and LN290, L290N, and L290N290 occurred
between the 290-bp identical sequences. The broken lines between the
chimeric RNA vector and the infectious vectors indicate the identical
290-bp 3' hyg sequences in the two vectors. The resulting
recombinants correspond to individual pairs of chimeric RNA and
infectious vectors. The lengths of the
BamHI-HindIII fragments which hybridized to a
hyg probe are shown for the recombinants. Two recombinants
resulted from recombination between JZ211 and L290N290: one, utilizing
the upstream hyg sequence, gives a 2.4-kb
BamHI-HindIII fragment, while the other,
utilizing the downstream hyg sequence, gives a 1.1-kb
BamHI-HindIII fragment. Rates of
recombination are shown on the right.
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Cells, transfection, and infection.
The processing of D17
cells (a dog osteosarcoma cell line; ATCC CRL-8468), PA317 helper cells
(ATCC CRL-9078), and PG13 helper cells (ATCC CRL-10686), DNA
transfections, virus harvesting, and virus infections were as
previously described (17).
Introduction of JZ442 + 3' Hyg (and JZ442) into helper cell
line PG13.
Plasmid DNA of pJZ442 + 3' Hyg (and pJZ442) was
transfected into an MLV amphotropic helper cell line, PA317
(10). The supernatant media containing the viruses were
collected and designated STEP 1 virus stock. The STEP 1 viruses were
used to infect an MLV xenotropic helper cell line, PG13
(11). The viruses released from infected PG13 cells were
unable to infect NIH 3T3 derivatives, including PG13 (11).
This procedure ensured that the infection of D17 cells with viruses
collected from PG13 cells represented only a single round of infection.
Infected cells were selected for hygromycin resistance
(Hygr). Visible colonies appeared about 10 days after
selection. The cells of well-separated green colonies were isolated and
designated STEP 2 cells.
Fluorescence microscopy.
A fluorescence inverted microscope
(Zeiss Axiovert 25) with a mercury arc lamp (100 W) and a fluorescence
filter set (CZ909) consisting of a 470- to 40-nm exciter, a 515-nm
emitter, and a 500-nm beam splitter was used to detect green
fluorescent protein in living cells.
| |
RESULTS |
Determination of the recombination rate within one retroviral RNA
molecule.
A bicistronic MLV-based vector (pJZ442) that carries a
drug resistance gene, hyg, and an unselected color reporter
gene, gfp (3), along with an IRES sequence
between the two genes, has been constructed (Fig. 1A). The IRES
sequence of the encephalomyocarditis virus origin allows the ribosome
to bind to the internal AUG that initiates the translation of the
second gene independently of the upstream gene (1, 2). To
measure the recombination rate between two identical sequences within
the same RNA molecule, another vector (pJZ442 + 3' Hyg) that also
contains the hyg and gfp genes but also includes
the insertion of a sequence homologous to 290 bp of the 3'
hyg gene into the 3' untranslated portion of the
gfp gene (downstream of the gfp gene or after the
stop codon of the gfp gene) has been constructed (Fig. 1B).
pJZ442 + 3' Hyg was used to transfect PG13 cells, and transfected
cells were selected for Hygr. Hygr cells were
analyzed under a fluorescence microscope. Green cells contained
parental JZ442 + 3' Hyg, and clear cells contained a gfp gene deletion (or mutation) in the transfected provirus.
Approximately 48.8% ± 10.2% of the transfected Hygr PG13
cells were clear. Therefore, transfection alone caused a high frequency
of deletion (or mutation) between the two identical sequences in the
same plasmid DNA. To avoid a high frequency of deletion during
transfection, JZ442 and JZ442 + 3' Hyg were introduced by
infection into the helper cell line PG13 described in Materials and
Methods. The viruses released from each PG13 clone, which contained
JZ442 or JZ442 + 3' Hyg provirus, were used to infect D17 cells;
the infected D17 cells were selected for Hygr. After about
12 days of selection, visible Hygr colonies appeared, and
these were designated STEP 3 cells. Because D17 cells do not contain
viral gag-pol and env gene products for retroviral replication, no progeny viruses were released from these
cells (17). Therefore, each colony of Hygr cells
represented a single viral infection.
Individual Hygr colonies were examined under a fluorescence
microscope. The clear colonies (Fig. 3A
and B) represented cells containing the proviruses with the
gfp deletion. The green colonies (Fig. 3C and D) and
represented cells containing the parental proviruses. Results from
counting green and clear colonies (Table 1) indicated that the rate of deletion
between the two identical sequences in the same RNA molecule was very
high (62% ± 9% per replication cycle). In comparison, only 1% of
the colonies infected with JZ442 were clear. This result indicates that
the rate of mutation of the gfp gene in the JZ442 vector
during a single round of retroviral replication is about the same as
previously reported (13). To determine the nature of the
recombinants, genomic DNAs from clear and green STEP 3 cells were
digested with EcoRV. EcoRV digested within the
LTRs of the vectors; the parental provirus produced a 4.2-kb fragment,
while the recombinant provirus with the deletion of the gfp
gene produced a 2.5-kb fragment (Fig. 4).
The recombinant formed a distinct 2.5-kb band, indicating that most
deletions of the gfp gene resulted from recombination between the two identical sequences.
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FIG. 3.
Microscopic analyses of D17 cells infected with viral
vector JZ442 + 3' Hyg containing the gfp gene. (A)
Visible-light microscopy of a hygromycin-resistant colony containing
recombinant JZ442 + 3' Hyg provirus. (B) Fluorescence microscopy
of a hygromycin-resistant colony (same colony as in panel A) containing
recombinant JZ442 + 3' Hyg provirus. (C) Visible-light microscopy
of a hygromycin-resistant colony containing parental JZ442 + 3'
Hyg provirus. (D) Fluorescence microscopy of a hygromycin-resistant
colony (same colony as in panel C) containing parental JZ442 + 3'
Hyg provirus.
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FIG. 4.
Southern analysis of chromosomal DNA of Hygr
cells. Cellular DNA isolated from STEP 3 cells was digested with
EcoRV and hybridized with a hyg gene probe.
Hygr cells had a deletion between the two identical
sequences in one RNA molecule of vector JZ442 + 3' Hyg. Pooled DNA
was isolated from more than 500 Hygr STEP 3 colonies. The
clear clone is an individual Hygr colony resulting from
deletion of the gfp gene between the two 3' hyg
gene segments. The green clone is an individual Hygr
colony. Molecular sizes are shown on the left.
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|
Intermolecular recombination between a noninfectious RNA and an
infectious RNA containing two identical sequences.
The retroviral
vectors and protocol used to measure rates of recombination have been
described previously (17). In order to study recombination
between chimeric and infectious MLV RNAs, a chimeric RNA, JZ211 (Fig.
2), was prepared. JZ211, derived from spleen necrosis virus (SNV),
contained a deletion in the U3 region of the 3' SNV LTR as well as an
XhoI restriction site linker in the deletion site (Fig.
5). This vector also contained a
truncated MLV vector between the two SNV LTRs, in a transcriptional
orientation opposite that of the SNV LTRs. In this truncated MLV
vector, the hyg gene was expressed from the 5' MLV LTR, and
a herpes simplex virus thymidine kinase poly(A) addition signal
replaced the completely deleted 3' MLV LTR. The infectious MLV vectors
contained a neo gene between the two MLV LTRs (17,
18) (Fig. 2 and 5). pJZ211 DNA was transfected into the SNV C3A2
helper cell line (containing the SNV gag-pol and
env genes) (16) (Fig. 5). The cells were selected
for Hygr, and resistant cells were pooled and designated
STEP 1 cells (Fig. 5, STEP 1). Virus from STEP 1 cells was used to
infect the MLV helper cell line PG13. Infected cells were selected for
Hygr, and individual clones were isolated and designated
STEP 2 cells. The structure of the proviruses formed from the SNV
U3-negative vector in the PG13 cells was monitored by Southern (DNA)
analysis. The XhoI linker in JZ211 was duplicated in the 5'
LTR during the formation of the STEP 2 provirus (Fig. 5, STEP 2)
(7). The STEP 2 clones that contained the expected
XhoI fragment, which hybridized to a hyg probe,
were used for further analysis (Fig. 5, STEP 2). To test whether any
virus capable of forming Hygr colonies was produced by STEP
2 cells, the supernatant medium (3 ml) from each STEP 2 cell clone was
used to infect D17 cells, and the infected cells were selected for
Hygr. No Hygr D17 colonies were detected. This
was because the deletion of the U3 region (promoter and enhancer) in
the SNV 5' LTR prevented transcription from the SNV vector
(6).
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FIG. 5.
Outline of an experimental approach for the
determination of the rate of recombination during a single cycle of
retroviral replication between a chimeric RNA vector, JZ211, and
infectious vectors. No plasmid backbone sequences are shown. The
directions of transcription in SNV and MLV are shown by the long thin
arrows. Transfections are indicated by test tube shapes. Infections are
indicated by virion shapes. The different backgrounds represent the
indicated cell lines. SV, late polyadenylation signal of simian virus
40;  and E, encapsidation sequences of MLV and SNV, respectively;
tk, thymidine kinase. The lines in the LTR separate the U3, R, and U5
regions.
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The infectious MLV vectors LN, LN290, L290N, and L290N290 (Fig. 2) were
transfected individually into the helper cell line PA317 (Fig. 5).
Cells exhibiting the Neor phenotype were pooled, viruses
from the PA317 cells were used to superinfect STEP 2 cells containing
JZ211, and the infected cells were selected for Neor.
Individual Neor clones were isolated and designated STEP 3 cells (Fig. 5, STEP 3). Each STEP 3 cell clone contained a single JZ211
integration and a single integration of LN, LN290, L290N, or L290N290.
Viruses from each STEP 3 clone were used to infect D17 cells, and the infected cells were selected separately for Hygr and for
Neor. The resulting cells were designated STEP 4 cells
(Fig. 5, STEP 4). With this approach, Hygr colonies form
only when recombination between JZ211 and any one of the three vectors
occurs at the shared 290-bp homologous sequences, so that the
hyg gene is flanked by two LTRs. If a nonhomologous recombination event occurs between JZ211 and LN, it results in a
Hygr colony. The rate of recombination is much lower than
the rates for vectors containing the 290-bp sequence when there are
shared homologous sequences (Fig. 2A) (17, 18). The target
cells do not contain viral gag-pol and env gene
products for retrovirus replication; therefore, no progeny virus can be
released from them (17). Consequently, these vector viruses
had undergone only one cycle of replication. LN290 and L290N contained
the same 290-bp 3' hyg sequence, except that the 290-bp
sequence of LN290 was inserted at the 3' end of neo and
served as the 3' untranslated sequence, whereas the 290-bp sequence of
L290N was inserted at the 5' end of neo and served as the 5'
untranslated sequence (Fig. 2B and C). This 290-bp sequence does not
contain an ATG motif; therefore, neo translation should not
be affected by the 5' insertion (Fig. 2A and B). The ratios of
Hygr CFU to Neor CFU produced were 8 × 10
4 ± 6 × 104 and 17 × 104 ± 5 × 104, respectively, for
LN290 and L290N. L290N290 contained two copies of sequences identical
to that in JZ211. Specifically, the 290-bp 3' hyg sequence
was inserted both upstream and downstream of the neo gene
within this vector. The rate of recombination between JZ211 and
L290N290 was 60 × 104 ± 13 × 104, and the rate of recombination between JZ211 and LN
was only 0.3 × 104 ± 0.2 × 104.
To determine whether recombination had occurred at the 5' or at the 3'
end of the hyg sequence, the DNA of pooled STEP 4 cells was
digested with BamHI and HindIII and
hybridized with a hyg probe. The proviruses resulting from
recombination between JZ211 and L290N290 utilizing upstream and
downstream hyg sequences produced different sizes of
BamHI-HindIII fragments that hybridized with a hyg probe (Fig. 2). The recombinants utilizing the
upstream hyg sequence produced a 2.4-kb
BamHI-HindIII hyg fragment, and those utilizing the downstream hyg sequence produced a
1.1-kb BamHI-HindIII hyg fragment.
The pooled recombinants from JZ211 and L290N290 yielded a 1.1-kb
fragment and a 2.4-kb fragment, indicating that both identical
sequences were used to form the recombinants between the chimeric RNA
and the infectious vector (Fig. 6).
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FIG. 6.
Southern analysis of recombinants between JZ211 and
L290N290. Chromosomal DNA of Hygr STEP 4 cells was used.
Cellular DNAs isolated from STEP 4 cells were pooled from more than 100 Hygr colonies, digested with BamHI and
HindIII, and hybridized with a hyg gene probe
(Fig. 2). LN290, L290N, and L290N290 represent Hygr cells
resulting from recombination between JZ211 and LN290, L290N, and
L290N290, respectively. Molecular sizes are shown on the left.
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| |
DISCUSSION |
Because they have two genomic RNA molecules in their virions,
retroviruses undergo recombination at a high rate. Our data indicate
that the high rate of recombination between two identical sequences
within the same RNA molecule was not dependent on the packaging signal.
The rate of intermolecular nonhomologous deletion in a single RNA
molecule (105 bp per replication cycle) is about 1,000 times higher than that of intermolecular nonhomologous recombination
(108 bp per replication cycle) (13).
Recombination between sequences within the same RNA molecule can be
intermolecular or intramolecular. Recombination between a chimeric RNA
vector and infectious vectors containing one or two copies of the
identical sequences was examined. The results indicated that the
presence of two copies of identical sequences on the infectious RNA
increased the rate of recombination very little (6 × 103) compared with a 60% increase in the rate of
recombination (6 × 101) between the same 290-bp
identical sequences in the same RNA molecule. In addition, the actual
titers of the infectious viruses, as measured by Neor, were
even higher. This result would be due to intrastrand recombination within the two identical sequences on either side of the neo
gene. From the data presented in this study, the deletion rate should be nearly 50%, which would account for the discrepancy observed. However, it is interesting to observe that most intermolecular recombination events either have involved the downstream stretch of
identical sequence or have already involved an intramolecular recombination event between the two copies of the 290-bp stretch. This
finding suggests the phenomenon of negative interference, which
indicates that intramolecular recombination increases the chance of
intermolecular recombination or vice versa. However, the individual
rate of inter- versus intramolecular recombination between two
identical sequences within the same RNA molecule remains unresolved.
| |
ACKNOWLEDGMENTS |
We thank William Bargmann, Chih-Li Hsu, Alan Kaplan, Alan
Simmons, and Ting Li for helpful comments on the manuscript.
This research was supported by Public Health Service research grant
CA70407 from the National Institutes of Health.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: 206 Combs
Research Bldg., University of Kentucky, 800 Rose St., Lexington, KY
40536-0096. Phone: (606) 257-4456. Fax: (606) 257-8940. E-mail:
jzhan1{at}pop.uky.edu.
| |
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Journal of Virology, July 1999, p. 5912-5917, Vol. 73, No. 7
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
