- Email: [email protected]
The fowl adenovirus type 1 (CELO) virus-associated RNA-encoding gene: a new ribozyme-expression vector
Gene. 161 (1995) 1X9-193 10 1995 Elsevier Science B.V. All rights reserved.
GENE
189
0378-I 119, Y5SO9.50
08969
The fowl adenovirus type 1 (CELO) virus-associated RNA-encoding gene: a new ribozyme-expression vector (Catalytic
RNA; secreted alkaline
A.N. Zakharchuk,
phosphatase;
K.K. Doronin,
Received by H. van Ormondt:
24 October
hammerhead
V.A. Karpov,
1994; Accepted:
Rz)
V.A. Krougliak”
I6 February
and B.S. Naroditsky
1995; Received at publishers:
7 April 1995
SUMMARY
A new system virus-associated secreted between
for hammerhead RNA (CELO
ribozyme VA RNA)
(Rz) expression
was examined
was used as a vector
for the incorporation
type 1 (CELO)
of Rz to target
the mRNA
of
alkaline phosphatase (SEAP) both in vitro and in vivo. The Rz gene was integrated into the CELO VA RNA the internal promoter boxes A and B; apparently this did not interfere with its transcription. Rz integrated
into CELO
VA RNA
RNA sequences
and, lacking
did not inhibit
293 cells by co-transfection We conclude
the viral sequences,
the integrated
with plasmids
that CELO
exhibited
the same activity
VA RNA may be used for effective expression
of catalytic
RNAs that cleave target
RNAs in a sequence-specific manner (Cech. 1987) they have been proven to be a potentially powerful instrument in the control of gene expression and in gene therapy (Rossi and Sarver, 1990; Altman, 1993). The so-called Correspondence
hammerhead
to: Dr.
ribozymes
B.S. Naroditsky,
Timiryazevskaya
(Rz), which are
Institute
Street 42, Moscow
Tel. (7-095) 977-0829;
of Agricultural 127550, Russian
Fax (7-095) 977-0947;
e-mail: [email protected] address:
Department
Main Street, West Hamilton.
of Btology, Ontario
McMaster
University,
L8S 4K1, Canada.
1280
Tel. (t-416)
525-9140. Abbreviations:
Ad. adenovirus;
bp, base pair(s);
1; CELO VA RNA, VA RNA from CELO;
ribozyme(s);
Rz, gene encoding
CELO.
fowl Ad type
CELO VARNA, gene encod-
ing CELO VA RNA: MCS, multiple cloning minimum essential medium; m.u., map unit(s); Rz: SEAP,
site; MEM, Eagle’s nt, nucleotide(s); Rz.
human
secreted
placental
alkaline phosphatase; SEAP, gene encoding SEAP: VA RNA, virusassociated RNA; VA1 RNA. VA1 RNA from human Ad2: VAI RNA, gene encoding VA1 RNA.
SSDI 037X-111’)(95100251-0
VA
Rz activity in vitro. In vivo experiments were carried out with human Rz and SEAP. Inhibition of enzyme activity was 50% in 48 h.
(Forster
Federation.
CELO
of hammerhead
Rz.
found in some plant viroids and plant viral satellite
Since the discovery
Biotechnology.
in vitro. Consequently,
containing
INTRODUCTION
*Present
in which fowl adenovirus
and Symons,
1987), have a common
structure and cleave the substrate N is any nucleotide, U is uridine
RNA
secondary
at an NUH site, where and H may be A, C or
U (Ruffner et al.. 1990). Effective gene suppression by Rz in vivo requires a substantial molar excess of the Rz over the target RNA (Cotten
and Birnstiel,
1989; Cameron
which can be achieved by increasing stability of Rz. A promising solution merase
III-driven
expression
and Jennings,
1989)
the amount or the is the use of poly-
advanced
by Cotten
and
Birnstiel (1989). Genes under control of an RNA polymerase III promoter are efficiently transcribed in various tissues (Geiduschek and Tocchini-Valentini, 1988). They usually have a rigid secondary structure that ensures transcript stability. The genes for tRNA (Cotten and Birnstiel, 1989; Yuyama et al., 1992; Ohkawa et al., 1993) and human Ad2 virus-associated RNA (VA1 RNA) (Ventura et al., 1993) have already been used to express hammerhead Rz. In this work, we examined an Rz-producing system based on CELO VA RNA. Like VA1 RNA. the CELO VA
190
RNA is transcribed by RNA polymerase III; however, it differs dramatically from I/AZ RNA in both length and sequence. It can be abundantly expressed in a broad range of tissues from different hosts (Larsson et al., 1986). It has a high-free-energy stem-loop structure (Fig. 1B) which makes it very stable.
EXPERIMENTAL
A. PCVA
pCVArib3
or pCMrib2
AND DISCUSSION
(a) Cloning of Rz into CELO VA RNA
CELO I/ARNA is located at about 90 mu. of the viral genome (Larsson et al., 1986). A MaeI-CfvI genomic fragment including CELO I/ARNA was cloned into pGEM-3zf(-) to generate pCVA (Fig. 1A). Using the method of Haseloff and Gerlach (1988) we have constructed a Rz specifically targeted against the SEAP reporter gene (Zakharchuk et al., 1994). The Rz was inserted into pGEM-3zf(-) downstream from the SP6 promoter, and also into the unique BspMII site of pCVA downstream from the same promoter to generate pR3 and pCVAR3 (Fig. 1A). The unique BspMII site is located between the A and B promoter boxes of CELO WI RNA. In the present work we inserted the Rz between the internal promoter boxes of CELO T/ARNA. Ventura et al. (1993) cloned the Rz downstream from the promoter boxes of T/AZ.The unique BspMII site between the promoter boxes substantially facilitated the cloning into CELO VA RNA. The putative secondary structure of the CELO VA RNA with integrated Rz is shown in Fig. 1B. In the secondary structure of CELO VA RNA with integrated Rz, predicted by the computer program DNASIS, the antisense arms of Rz are in a loop and thus can bind to the target. The fragment of the target gene was also cloned into pGEM-3zf(-) downstream from the SP6 promoter to give pSB (Fig. 1A.).
cleavage
A-U Et
Fig. 1. Plasmid (A) Open
activity in vitro
To evaluate the influence of flanking sequences on the catalytic activity of the Rz, the Rz,CELO I/ARNA with integrated Rz and a fragment of the target gene were transcribed in vitro. Both catalytic RNA transcripts cleaved the target RNA in vitro in the expected manner (Fig. 2): two specific products of predicted size (170 and 70 nt) were observed. The products accumulated while the amount of substrate decreased with time. The cleavage activity of Rz was assayed at two constant temperatures and with the temperature between 80 and 56°C. Cyclic changes of the reaction temperature
and secondary sequences;
structure
sequences;
Promoter
sequence
cated.
boxes and terminator
All enzymes
Lithuania)
and
operations plasmids
together
plasmid
the pGEM-3zf(-) with BamHI
vector.
synthesized treatment,
pCVArib3,
cannot ment
plasmid
Germany).
et al. (1989). All
of the
and A&-linearized contained
was recloned
The
WI, USA) genome
was
site of the
anti-SEAP
chemistry;
were annealed
Rz after
were kinase
to generate
BspMII
into BspMII-linearized
pCVA,
pGEM-3zf-),
yielding
pR3.
the Rz whose antisense
arms
bind with the SEAP RNA sequence. of SEAP
Madison,
of the CELO
into the MCS BarnHI
ends and inserted pCVArib2
(Vilnius,
(Mannheim,
phosphoramidite strands
are indi-
Fermentas
by Sambrook
(Promega,
Pentacontanucleotides
complementary
sequence;
boxes, Rz sequence.
of CELO VA RNA
(MaeI-CfrI) linkers
by automated
and AuaI-compatible Similarly,
out as described
A 190-bp fragment
black
were from
Boehringer-Mannheim
contain
backbone. cloned
used for cloning
were carried
of CELO VA RNA.
dark gray boxes, SEAP
light gray boxes, pGEM-3zf(-)
yielding
(b) Influence of the flanking sequences on the Rz catalytic
constructs
boxes, CELO
The HindIII-BanaH
from pBcl2/RSV/SEAP
frag-
(Berger
et al.,
1988) into pGEM-3zf(-) at the same sites, to give plasmid pSB. All of the constructs were sequenced. (B) Left: secondary structure of CELO VA RNA (Larsson et al., 1986); the insertion site of Rz is indicated. Right:
possible
integrated
secondary
structure
for CELO
VA RNA
with
the
Rz.
enhanced the Rz efficiency in agreement with the data of Dropulic et al. (1993). The enzymatic in vitro activity of the Rz alone was similar to that of Rz incorporated into CELO VA RNA (Fig. 3). Consequently, the extra sequences around Rz
191
A. 4tt3-
65
4
3
2
1
242-
,Pl
llO-
-P2
67-
nt
7
6
5
4
3
2
56<--->80
56
37
B.
(“C)
Temperature
1 Fig. 3. Comparison
of the Rz enzymatic
temperatures.
boxes. activity
Gray
RNA; open boxes, activity constant
temperatures
equihbrdte
80-
of heating
by cooling two
of cleavage
for
VA
was conducted
at
to the maximum
I min. Allowing
temperatures,
each
the available
target cleaved during the reaction.
-P2
by counting
the radioactivity
took
4 min.
the percentage
of
This was accomplished
of gel slices corresponding
Each value is the mean of five independent
temperature
for the time to
round
was based on determining
-R
cleavage of SEAP RNA substrate hy the Rz. (A) substrate (S) by the Rr (R) integrated into CELO VA RNA
reaction
into CELO
(37’C or 56°C) or cycled between 56°C and 80-C
between
Quantitation
at various
of Rz alone. The cleavage
for 1 h. Each cycle consisted for 1 mm. followed
activities
of Rz integraled
to the bands.
experiments.
Confidence
bars (95%) are shown.
Fig. 2. In vitro Cleavage
of
produces products Pl and P2. The reaction was conducted at 56’C. Incubation times: 15 min (lane 3). 30 min (lane 4). 60 min (lane 5); the Rz in these lanes was unlabeled. substrate
without
Lanes: 1. [r-3’P]
R7: 6, molecular
strate (S) by the Rz (R) without PI and PI?. The reaction
size marker.
Rz; 2. [r-32P]-labeled (B) Cleavage
the viral sequences
was conducted
produces
at 56’C. Incubation
min (lane 2), 20 min (lane 3 I, 40 min (lane 4), 50 min (lane 6): molecular Rz without
reaction.
size marker
of subproducts times: 10
(lane 5), 60 min
(lane 7). Lane 1, labeled substrate
and
Methods: Plasmids pCVArib3 and pR3 were linear-
ized in the MCS with XhuI or EwRI;
pSB was linearired
with EcoRI.
The corresponding transcript lengths were 270, 90 and 240 nt, respectively. All linearized DNAs were transcribed in vitro with the Riboprobe II System cleavage
(Promega)
and [a-32P]UTP
was conducted
10 mM MgCI.
(PEI,
in the presence
The RNAs
were initially
Obninsk,
Russia).
of 10 mM TrisHCl heat-denatured
at 95°C for
1 min. and than quickly cooled on ice. The substrdte’ribozyme was 1:l. The reaction loading
buffer
was terminated
(95”/0
formamide/‘lO
by adding mM
The
pH 7.5’ ratio
an equal volume of gel
Na,EDTA.‘O.O?%
xylenc
cyanolei0.02”C bromophenol blue). Samples were then heat-denatured at X0 C for 2 min prior to running on 8 M urea-lo% polyacrylamidc
However,
Ventura
vitro catalytic
et al. (1993) have shown
activity
of Rz encoded
rated into the 3’ region of I/AZ downstream moter
boxes is inhibited
by flanking
that the in
by sequences
integ-
from the pro-
sequences
of VAI.
The secondary structure of CELO VA RNA may be more convenient for hammerhead Rz than that of VAI. The choice of insertion
site between
the promoter
boxes may
also have played an important role. The relatively low catalytic activity of the Rz at 37°C may be explained by the appreciable length (22 nt) of the flanking antisense arms which bind tightly to the substrate and hinder the release of the Rz from the substrate complex, thereby attenuating its turnover number. However, the Rz with longer arms may be more efficient within cells (Crisell et al.. 1993).
gels. The gels were autoradiographed.
were inert with regard to the enzymatic activity of the Rz in vitro. These data are in agreement with those of Cotten and Birnstiel (1989) and Yuyama et al. (1992).
(c) Transcription of CELO VA RNA with integrated Rz in 293 cell line We attempted to evaluate the activity of the CELO VA RN.4 promoter after insertion of the Rz.To this end, total RNA from a pCVArib3-transfected 293 cell line
192
(Graham et al., 1977) was subjected to primer extension analysis, with a labeled oligodeoxyribonucleotide from one of the Rz DNA strands. Fig. 4A demonstrates that lOO-nt extension product corresponding to the 5’region of the CELO VA RNA is transcribed in the cells. Total RNA from pCVArib3- or pCVA-transfected cells was examined by slot-blot hybridization (Fig. 4B). The transcription of VA RNA with the Rz insert was not less than its native counterpart. The results obtained suggest that the 50-nt insert between the promoter boxes A and B does not affect the transcription of CELO VA RNA. Expression of a Rz active against SEAP RNA should attenuate the amount of the protein product and thus decrease the enzymatic activity. This was tested
TABLE
I
Expression
B.
118lOO-
a.
82-
b. c. d.
48Fig. 4. CELL isolated
VA RNA transcription
from cells transfected
from cells transfected 3, molecular-size
SEAP activityb
(mu/ml) pCVArib2
0.52 i_ 0.05
pCVArib3
0.26 & 0.07
a The 293 cells (10’ in a 30-mm dish) were co-transfected pBcl2/RSV/SEAP plasmid
The primer extension
Lane 4, RNA isolated control). product
an arrow. (B) Total RNA (20 pg) of cells transfected pCVArib3
(d) was applied to the Bio-Dot
USA), transferred
to Hybond
1 and
is indicated
by
with pCVA (c) or
SF (Bio-Rad,
N (Amersham,
Lanes
Richmond,
Lincoln
CA,
Place, UK) filter,
and probed with a-3zP-labeled pCVA DNA. The specific activity of the probe was lo9 dpm/ug. (a) In vitro transcribed CELO VA RNA with integrated
Rz, positive
control;
b, RNA of untransfected
cells, negative
control. Methods: Human 293 cells (Graham et al., 1977) were grown in MEM medium with 5% fetal calf serum and transfected with plasmid DNA using the Caphosphate
precipitation
der Eb, 1973). For RNA isolation,
protocol
(Graham
and Van
10 ug of pCVA or pCVArib3
was
used to transfect a 60-mm dish containing lo6 cells. Total RNA of the transfected cells was isolated with the TRI REAGENT (MRC, Cincinnati, OH, USA). Primer-extension analysis of the isolated RNA was performed
plasmid
by the Ca.phosphate
which
sampled
served
precipitation
method
with 1 ug of or pCVArib3
(Graham
pCVArib2
contains
Rz with random
as a negative
control.
The culture
der Eb, 1973). Plasmid arms
and 3 ug of either pCVArib2
and Van sequence
medium
was
at 48 h after transfection.
b The level of SEAP activity
was determined
et al. (1988). It is given in milliunits One mU is defined
as the amount
of p-nitrophenylphosphate experiments.
(mu)
by Berger medium.
of SEAP that hydrolyses
1.0 pmol
per min. Each Standard
as described per ml of culture value
deviations
is the mean
of five
are shown.
by co-transfecting 293 cells with pCVArib3 and pBC12/RSV/SEAP (Berger et al., 1988) carrying the SEAP coding sequence under control of Rous sarcoma virus long terminal repeat. As a negative control, 293 cells were cotransfected with pBC12/RSV/SEAP and pCVArib2 where the same Rz has random sequence arms precluding correct interaction with the substrate. The DNA molar ratio of SEAP-producing and Rz-expressing plasmids was 1:lO. The SEAP activity in the culture medium of cells co-transfected with pCVArib3 decreased by half at 48-h post transfection (Table I). The mechanism of target inactivation includes antisense inhibition and enzymatic cleavage. We did not evaluate the contribution of catalytic and antisense effects separately because it was outside of our scope. These questions will be addressed in future studies.
in cell line 293. (A) Lane 2, RNA
with pCVArib3.
with pCVA (the negative
marker.
of Rz in 293 cells
Plasmid”
independent
A.
of SEAP in the presence
with the AMV Reverse Transcriptase
Primer
(d) Conclusions CELO VA RNA was explored as a new vector for expressing the hammerhead Rz. (I) The scheme of Cotten and Birnstiel (1989) can be used for inserting Rz into CELO VA RNA. The surrounding viral sequences are inert to the in vitro Rz activity. (2) The 50-nt insert between the promoter boxes does not affect the transcription of CELO VA RNA in cell culture. The Rz is efficiently transcribed as a part of the CELO VA RNA in human 293 cells and shows bio-activity. (3) CELO VA RNA is an alternative for transfer and effective expression of hammerhead Rz.
Extension
System (Promega). The primer complementary to the Rz sequence (50 nt) was labeled with [y-a’P]dATP (PEI) and T4 polynucleotide kinase; the specific activity was 5 x lo5 dpm/pmol. RNA (6 pg) was annealed with excess primer for 30 min at 70°C. The primer extension was con-
ACKNOWLEDGEMENTS
ducted at 42°C for 30 min. Labeled on a 8 M urea-lo% polyacrylamide
We thank Dr. B.R. Cullen (Howard Hughes Medical Institute, Durham, NC, USA), who kindly supplied plas-
extension gel.
products
were separated
193 mid pBcl2/RSVjSEAP, and Dr. S.V. Zelivyansky for helpful discussions. This work was supported the Russian Foundation for Basic Research grant 930420767 and ISF grant M HGOOO.
of a human
cell line transformed
type 5. J. Gen. Virology Graham,
F.L. and Van der Eb. A.J.: A new technique
infectivity
of human
456-m467. Haseloff, J. and Gerlach,
adenovirus
adenoviruses:
gene location. Altman.
S.: RNA enzyme-directed
gene therapy.
Proc. Nat]. Acad. Sci.
Berger. J.. Hauber. placental
_I.,Hauber.
alkaline
Cameron,
ribozymes
Science 236 (1987) Cotten,
new quantitative
cells. Gene 66
by engi-
cells. Proc. Nat]. Acad. Sci. USA 86 RNA and RNA enzymes.
mediated
that show poor activity
destruction
of RNA
B.. Lin. N.H. and Jeang,
of HIV-l
in vitro. Nucleic
K.-T.: A method
Acids Res. 21 ( 1993 13273-2274. Forster, A.C. and Symons. R.H.: Self-cleavage and a structural
polymerase
thermal
replication Acids Res.
to increase
III. Annu. Rev. Biochem.
the
cycling. Nucleic
Trends
D.E., Stormo,
( 1988) 585-591. and
in length. sequence,
and
( 1986) 600--609. Y., Nishikawa.
in ribozyme
human
S. and Taira,
reaction:
multiple
K.:
kinetic behavior
ribozymes
immunodeficiency
Biotechnol.
virus.
with potenProc.
as antiviral
Natl. thera-
8 ( 1990) l79- 183.
G.D. and Uhlenbeck,
mcnts of the hammerhead Sambrook.
J.. Fritsch, Manual,
Cold Spring Ventura,
0.C.:
RNA self-cleavage
Sequence
reaction.
of plus and minus RNAs sites. Cell 49
require-
Biochemistry
G.P.: Transcrlption
by RNA
57 (1988) 873 ~914.
F.L.. Smiley, J.. Russel, W C. and Nairn,
R.: Characterization
of
Maniatis.
T.:
Molecular
Cloning.
Laboratory
A
Press,
NY, 1989. T.. Perricaudet.
HIV-specific
ribozyme
M. and Saragosti,
activity
by
S.:
self-cleavage.
Acids Res. 21 (1993) 3249-3255.
Nucleic
Yuyama.
N.. Ohkawa. Taira.
trimming 1271
Harbor,
E.F.,
2nd ed. Cold Spring Harbor
M.. Wang, P., Ragot.
S. and
model for the active
(19871 211~ 220. Geiduschek. E.P. and Tocchini-Valentini. Graham.
334
Acad. Sci. USA 90 (1993) 11302-11306. Rossi. J.J. and Sarver, N.: RNA enzymes (ribozymes)
Activation
cleavage efficiency of ribozymes:
of a virusoid
Nature
differences
N., Takebe.
against
peutic agents.
52 (1973)
G.: VA RNAs from avian
and of simply connected
Laboratory
21 (1993) 5251-5255. cumulative
dramatic
of independence
tial activity
for the assay of
Virology
29 (1990) 10695-10702.
M.: Ribozyme
in 11iuo.EMBO J. 8 ( 1989) 3861 3866. Crisell, P.. Thompson, S. and James, W.: Inhibition
Dropulic.
activities.
J. Virol. 58
J.. Yuyama,
of trimmed
Ruffner. of self-cleaving
1532- 1539.
M. and Birnstiel,
by ribozymes
indica-
( 1988) l-10.
P.A.: Specific gene suppression
in monkey
(1989)9139%9143. Cech. T.R.: The chemistry
R. and Cullen. B.R.: Secreted
a powerful
in eukaryotic
F.H. and Jennings,
neered
R, Geiger,
phosphatase:
tor of gene expression
Ohkawa,
Importance
LISA 90 (1993) 10898~10900.
5 DNA.
S.. Bellett. A. and Akusjarvi,
human
REFERENCES
adenovirus
W.: Simple RNA enzymes with new and highly
specific endoribonuclease Larsson,
by DNA from human
36 (1977) 59.-72.
J., Inokuchi.
Y.. Shirai. M. Sato, A.. Nlshikawa,
K.: Construction
plasmid.
Biochem.
of a tRNA-embedded-ribozyme Biophys.
Res. Commun.
186 (1992)
1279.
Zakhnrchuk. A.N., Doronin, K.K., Karpo\. V.A.. Krougliak, V.A and Naroditsky. B.S.: Studies of an ctnri-secreted alkaline phosphatase mRNA
ribozyme
Virusol.
6 (1994) X-12
in r,itro and
in ~ICO. Mol.
Genet.
Mikrobiol.
GENE
189
0378-I 119, Y5SO9.50
08969
The fowl adenovirus type 1 (CELO) virus-associated RNA-encoding gene: a new ribozyme-expression vector (Catalytic
RNA; secreted alkaline
A.N. Zakharchuk,
phosphatase;
K.K. Doronin,
Received by H. van Ormondt:
24 October
hammerhead
V.A. Karpov,
1994; Accepted:
Rz)
V.A. Krougliak”
I6 February
and B.S. Naroditsky
1995; Received at publishers:
7 April 1995
SUMMARY
A new system virus-associated secreted between
for hammerhead RNA (CELO
ribozyme VA RNA)
(Rz) expression
was examined
was used as a vector
for the incorporation
type 1 (CELO)
of Rz to target
the mRNA
of
alkaline phosphatase (SEAP) both in vitro and in vivo. The Rz gene was integrated into the CELO VA RNA the internal promoter boxes A and B; apparently this did not interfere with its transcription. Rz integrated
into CELO
VA RNA
RNA sequences
and, lacking
did not inhibit
293 cells by co-transfection We conclude
the viral sequences,
the integrated
with plasmids
that CELO
exhibited
the same activity
VA RNA may be used for effective expression
of catalytic
RNAs that cleave target
RNAs in a sequence-specific manner (Cech. 1987) they have been proven to be a potentially powerful instrument in the control of gene expression and in gene therapy (Rossi and Sarver, 1990; Altman, 1993). The so-called Correspondence
hammerhead
to: Dr.
ribozymes
B.S. Naroditsky,
Timiryazevskaya
(Rz), which are
Institute
Street 42, Moscow
Tel. (7-095) 977-0829;
of Agricultural 127550, Russian
Fax (7-095) 977-0947;
e-mail: [email protected] address:
Department
Main Street, West Hamilton.
of Btology, Ontario
McMaster
University,
L8S 4K1, Canada.
1280
Tel. (t-416)
525-9140. Abbreviations:
Ad. adenovirus;
bp, base pair(s);
1; CELO VA RNA, VA RNA from CELO;
ribozyme(s);
Rz, gene encoding
CELO.
fowl Ad type
CELO VARNA, gene encod-
ing CELO VA RNA: MCS, multiple cloning minimum essential medium; m.u., map unit(s); Rz: SEAP,
site; MEM, Eagle’s nt, nucleotide(s); Rz.
human
secreted
placental
alkaline phosphatase; SEAP, gene encoding SEAP: VA RNA, virusassociated RNA; VA1 RNA. VA1 RNA from human Ad2: VAI RNA, gene encoding VA1 RNA.
SSDI 037X-111’)(95100251-0
VA
Rz activity in vitro. In vivo experiments were carried out with human Rz and SEAP. Inhibition of enzyme activity was 50% in 48 h.
(Forster
Federation.
CELO
of hammerhead
Rz.
found in some plant viroids and plant viral satellite
Since the discovery
Biotechnology.
in vitro. Consequently,
containing
INTRODUCTION
*Present
in which fowl adenovirus
and Symons,
1987), have a common
structure and cleave the substrate N is any nucleotide, U is uridine
RNA
secondary
at an NUH site, where and H may be A, C or
U (Ruffner et al.. 1990). Effective gene suppression by Rz in vivo requires a substantial molar excess of the Rz over the target RNA (Cotten
and Birnstiel,
1989; Cameron
which can be achieved by increasing stability of Rz. A promising solution merase
III-driven
expression
and Jennings,
1989)
the amount or the is the use of poly-
advanced
by Cotten
and
Birnstiel (1989). Genes under control of an RNA polymerase III promoter are efficiently transcribed in various tissues (Geiduschek and Tocchini-Valentini, 1988). They usually have a rigid secondary structure that ensures transcript stability. The genes for tRNA (Cotten and Birnstiel, 1989; Yuyama et al., 1992; Ohkawa et al., 1993) and human Ad2 virus-associated RNA (VA1 RNA) (Ventura et al., 1993) have already been used to express hammerhead Rz. In this work, we examined an Rz-producing system based on CELO VA RNA. Like VA1 RNA. the CELO VA
190
RNA is transcribed by RNA polymerase III; however, it differs dramatically from I/AZ RNA in both length and sequence. It can be abundantly expressed in a broad range of tissues from different hosts (Larsson et al., 1986). It has a high-free-energy stem-loop structure (Fig. 1B) which makes it very stable.
EXPERIMENTAL
A. PCVA
pCVArib3
or pCMrib2
AND DISCUSSION
(a) Cloning of Rz into CELO VA RNA
CELO I/ARNA is located at about 90 mu. of the viral genome (Larsson et al., 1986). A MaeI-CfvI genomic fragment including CELO I/ARNA was cloned into pGEM-3zf(-) to generate pCVA (Fig. 1A). Using the method of Haseloff and Gerlach (1988) we have constructed a Rz specifically targeted against the SEAP reporter gene (Zakharchuk et al., 1994). The Rz was inserted into pGEM-3zf(-) downstream from the SP6 promoter, and also into the unique BspMII site of pCVA downstream from the same promoter to generate pR3 and pCVAR3 (Fig. 1A). The unique BspMII site is located between the A and B promoter boxes of CELO WI RNA. In the present work we inserted the Rz between the internal promoter boxes of CELO T/ARNA. Ventura et al. (1993) cloned the Rz downstream from the promoter boxes of T/AZ.The unique BspMII site between the promoter boxes substantially facilitated the cloning into CELO VA RNA. The putative secondary structure of the CELO VA RNA with integrated Rz is shown in Fig. 1B. In the secondary structure of CELO VA RNA with integrated Rz, predicted by the computer program DNASIS, the antisense arms of Rz are in a loop and thus can bind to the target. The fragment of the target gene was also cloned into pGEM-3zf(-) downstream from the SP6 promoter to give pSB (Fig. 1A.).
cleavage
A-U Et
Fig. 1. Plasmid (A) Open
activity in vitro
To evaluate the influence of flanking sequences on the catalytic activity of the Rz, the Rz,CELO I/ARNA with integrated Rz and a fragment of the target gene were transcribed in vitro. Both catalytic RNA transcripts cleaved the target RNA in vitro in the expected manner (Fig. 2): two specific products of predicted size (170 and 70 nt) were observed. The products accumulated while the amount of substrate decreased with time. The cleavage activity of Rz was assayed at two constant temperatures and with the temperature between 80 and 56°C. Cyclic changes of the reaction temperature
and secondary sequences;
structure
sequences;
Promoter
sequence
cated.
boxes and terminator
All enzymes
Lithuania)
and
operations plasmids
together
plasmid
the pGEM-3zf(-) with BamHI
vector.
synthesized treatment,
pCVArib3,
cannot ment
plasmid
Germany).
et al. (1989). All
of the
and A&-linearized contained
was recloned
The
WI, USA) genome
was
site of the
anti-SEAP
chemistry;
were annealed
Rz after
were kinase
to generate
BspMII
into BspMII-linearized
pCVA,
pGEM-3zf-),
yielding
pR3.
the Rz whose antisense
arms
bind with the SEAP RNA sequence. of SEAP
Madison,
of the CELO
into the MCS BarnHI
ends and inserted pCVArib2
(Vilnius,
(Mannheim,
phosphoramidite strands
are indi-
Fermentas
by Sambrook
(Promega,
Pentacontanucleotides
complementary
sequence;
boxes, Rz sequence.
of CELO VA RNA
(MaeI-CfrI) linkers
by automated
and AuaI-compatible Similarly,
out as described
A 190-bp fragment
black
were from
Boehringer-Mannheim
contain
backbone. cloned
used for cloning
were carried
of CELO VA RNA.
dark gray boxes, SEAP
light gray boxes, pGEM-3zf(-)
yielding
(b) Influence of the flanking sequences on the Rz catalytic
constructs
boxes, CELO
The HindIII-BanaH
from pBcl2/RSV/SEAP
frag-
(Berger
et al.,
1988) into pGEM-3zf(-) at the same sites, to give plasmid pSB. All of the constructs were sequenced. (B) Left: secondary structure of CELO VA RNA (Larsson et al., 1986); the insertion site of Rz is indicated. Right:
possible
integrated
secondary
structure
for CELO
VA RNA
with
the
Rz.
enhanced the Rz efficiency in agreement with the data of Dropulic et al. (1993). The enzymatic in vitro activity of the Rz alone was similar to that of Rz incorporated into CELO VA RNA (Fig. 3). Consequently, the extra sequences around Rz
191
A. 4tt3-
65
4
3
2
1
242-
,Pl
llO-
-P2
67-
nt
7
6
5
4
3
2
56<--->80
56
37
B.
(“C)
Temperature
1 Fig. 3. Comparison
of the Rz enzymatic
temperatures.
boxes. activity
Gray
RNA; open boxes, activity constant
temperatures
equihbrdte
80-
of heating
by cooling two
of cleavage
for
VA
was conducted
at
to the maximum
I min. Allowing
temperatures,
each
the available
target cleaved during the reaction.
-P2
by counting
the radioactivity
took
4 min.
the percentage
of
This was accomplished
of gel slices corresponding
Each value is the mean of five independent
temperature
for the time to
round
was based on determining
-R
cleavage of SEAP RNA substrate hy the Rz. (A) substrate (S) by the Rr (R) integrated into CELO VA RNA
reaction
into CELO
(37’C or 56°C) or cycled between 56°C and 80-C
between
Quantitation
at various
of Rz alone. The cleavage
for 1 h. Each cycle consisted for 1 mm. followed
activities
of Rz integraled
to the bands.
experiments.
Confidence
bars (95%) are shown.
Fig. 2. In vitro Cleavage
of
produces products Pl and P2. The reaction was conducted at 56’C. Incubation times: 15 min (lane 3). 30 min (lane 4). 60 min (lane 5); the Rz in these lanes was unlabeled. substrate
without
Lanes: 1. [r-3’P]
R7: 6, molecular
strate (S) by the Rz (R) without PI and PI?. The reaction
size marker.
Rz; 2. [r-32P]-labeled (B) Cleavage
the viral sequences
was conducted
produces
at 56’C. Incubation
min (lane 2), 20 min (lane 3 I, 40 min (lane 4), 50 min (lane 6): molecular Rz without
reaction.
size marker
of subproducts times: 10
(lane 5), 60 min
(lane 7). Lane 1, labeled substrate
and
Methods: Plasmids pCVArib3 and pR3 were linear-
ized in the MCS with XhuI or EwRI;
pSB was linearired
with EcoRI.
The corresponding transcript lengths were 270, 90 and 240 nt, respectively. All linearized DNAs were transcribed in vitro with the Riboprobe II System cleavage
(Promega)
and [a-32P]UTP
was conducted
10 mM MgCI.
(PEI,
in the presence
The RNAs
were initially
Obninsk,
Russia).
of 10 mM TrisHCl heat-denatured
at 95°C for
1 min. and than quickly cooled on ice. The substrdte’ribozyme was 1:l. The reaction loading
buffer
was terminated
(95”/0
formamide/‘lO
by adding mM
The
pH 7.5’ ratio
an equal volume of gel
Na,EDTA.‘O.O?%
xylenc
cyanolei0.02”C bromophenol blue). Samples were then heat-denatured at X0 C for 2 min prior to running on 8 M urea-lo% polyacrylamidc
However,
Ventura
vitro catalytic
et al. (1993) have shown
activity
of Rz encoded
rated into the 3’ region of I/AZ downstream moter
boxes is inhibited
by flanking
that the in
by sequences
integ-
from the pro-
sequences
of VAI.
The secondary structure of CELO VA RNA may be more convenient for hammerhead Rz than that of VAI. The choice of insertion
site between
the promoter
boxes may
also have played an important role. The relatively low catalytic activity of the Rz at 37°C may be explained by the appreciable length (22 nt) of the flanking antisense arms which bind tightly to the substrate and hinder the release of the Rz from the substrate complex, thereby attenuating its turnover number. However, the Rz with longer arms may be more efficient within cells (Crisell et al.. 1993).
gels. The gels were autoradiographed.
were inert with regard to the enzymatic activity of the Rz in vitro. These data are in agreement with those of Cotten and Birnstiel (1989) and Yuyama et al. (1992).
(c) Transcription of CELO VA RNA with integrated Rz in 293 cell line We attempted to evaluate the activity of the CELO VA RN.4 promoter after insertion of the Rz.To this end, total RNA from a pCVArib3-transfected 293 cell line
192
(Graham et al., 1977) was subjected to primer extension analysis, with a labeled oligodeoxyribonucleotide from one of the Rz DNA strands. Fig. 4A demonstrates that lOO-nt extension product corresponding to the 5’region of the CELO VA RNA is transcribed in the cells. Total RNA from pCVArib3- or pCVA-transfected cells was examined by slot-blot hybridization (Fig. 4B). The transcription of VA RNA with the Rz insert was not less than its native counterpart. The results obtained suggest that the 50-nt insert between the promoter boxes A and B does not affect the transcription of CELO VA RNA. Expression of a Rz active against SEAP RNA should attenuate the amount of the protein product and thus decrease the enzymatic activity. This was tested
TABLE
I
Expression
B.
118lOO-
a.
82-
b. c. d.
48Fig. 4. CELL isolated
VA RNA transcription
from cells transfected
from cells transfected 3, molecular-size
SEAP activityb
(mu/ml) pCVArib2
0.52 i_ 0.05
pCVArib3
0.26 & 0.07
a The 293 cells (10’ in a 30-mm dish) were co-transfected pBcl2/RSV/SEAP plasmid
The primer extension
Lane 4, RNA isolated control). product
an arrow. (B) Total RNA (20 pg) of cells transfected pCVArib3
(d) was applied to the Bio-Dot
USA), transferred
to Hybond
1 and
is indicated
by
with pCVA (c) or
SF (Bio-Rad,
N (Amersham,
Lanes
Richmond,
Lincoln
CA,
Place, UK) filter,
and probed with a-3zP-labeled pCVA DNA. The specific activity of the probe was lo9 dpm/ug. (a) In vitro transcribed CELO VA RNA with integrated
Rz, positive
control;
b, RNA of untransfected
cells, negative
control. Methods: Human 293 cells (Graham et al., 1977) were grown in MEM medium with 5% fetal calf serum and transfected with plasmid DNA using the Caphosphate
precipitation
der Eb, 1973). For RNA isolation,
protocol
(Graham
and Van
10 ug of pCVA or pCVArib3
was
used to transfect a 60-mm dish containing lo6 cells. Total RNA of the transfected cells was isolated with the TRI REAGENT (MRC, Cincinnati, OH, USA). Primer-extension analysis of the isolated RNA was performed
plasmid
by the Ca.phosphate
which
sampled
served
precipitation
method
with 1 ug of or pCVArib3
(Graham
pCVArib2
contains
Rz with random
as a negative
control.
The culture
der Eb, 1973). Plasmid arms
and 3 ug of either pCVArib2
and Van sequence
medium
was
at 48 h after transfection.
b The level of SEAP activity
was determined
et al. (1988). It is given in milliunits One mU is defined
as the amount
of p-nitrophenylphosphate experiments.
(mu)
by Berger medium.
of SEAP that hydrolyses
1.0 pmol
per min. Each Standard
as described per ml of culture value
deviations
is the mean
of five
are shown.
by co-transfecting 293 cells with pCVArib3 and pBC12/RSV/SEAP (Berger et al., 1988) carrying the SEAP coding sequence under control of Rous sarcoma virus long terminal repeat. As a negative control, 293 cells were cotransfected with pBC12/RSV/SEAP and pCVArib2 where the same Rz has random sequence arms precluding correct interaction with the substrate. The DNA molar ratio of SEAP-producing and Rz-expressing plasmids was 1:lO. The SEAP activity in the culture medium of cells co-transfected with pCVArib3 decreased by half at 48-h post transfection (Table I). The mechanism of target inactivation includes antisense inhibition and enzymatic cleavage. We did not evaluate the contribution of catalytic and antisense effects separately because it was outside of our scope. These questions will be addressed in future studies.
in cell line 293. (A) Lane 2, RNA
with pCVArib3.
with pCVA (the negative
marker.
of Rz in 293 cells
Plasmid”
independent
A.
of SEAP in the presence
with the AMV Reverse Transcriptase
Primer
(d) Conclusions CELO VA RNA was explored as a new vector for expressing the hammerhead Rz. (I) The scheme of Cotten and Birnstiel (1989) can be used for inserting Rz into CELO VA RNA. The surrounding viral sequences are inert to the in vitro Rz activity. (2) The 50-nt insert between the promoter boxes does not affect the transcription of CELO VA RNA in cell culture. The Rz is efficiently transcribed as a part of the CELO VA RNA in human 293 cells and shows bio-activity. (3) CELO VA RNA is an alternative for transfer and effective expression of hammerhead Rz.
Extension
System (Promega). The primer complementary to the Rz sequence (50 nt) was labeled with [y-a’P]dATP (PEI) and T4 polynucleotide kinase; the specific activity was 5 x lo5 dpm/pmol. RNA (6 pg) was annealed with excess primer for 30 min at 70°C. The primer extension was con-
ACKNOWLEDGEMENTS
ducted at 42°C for 30 min. Labeled on a 8 M urea-lo% polyacrylamide
We thank Dr. B.R. Cullen (Howard Hughes Medical Institute, Durham, NC, USA), who kindly supplied plas-
extension gel.
products
were separated
193 mid pBcl2/RSVjSEAP, and Dr. S.V. Zelivyansky for helpful discussions. This work was supported the Russian Foundation for Basic Research grant 930420767 and ISF grant M HGOOO.
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