Detection of stable secondary structure at the 3′ terminus of dengue virus type 2 RNA

Gene, 108 (1991) 185-191 0

1991 Elsevier

GENE

Science

Publishers

B.V. All rights reserved.

185

0378-l 119/91/$03.50

06138

Detection of stable secondary structure at the 3’ terminus of dengue virus type 2 RNA (Recombinant

DNA;

flavivirus;

in vitro transcription;

polymerase

chain

reaction;

RNase A cleavage

sites;

RNase H

mapping)

P. Maruthi Mohan* and R. Padmanabhan Department

of Biochemistry

and Molecular

Biology, University of Kansas

Medical

Center, Kansas

City, KS 66103

(U.S.A.)

Received by J.R. Putnak: 6 November 1989 Revised/Accepted: 10 August/l4 August 1991 Received at publishers: 3 September 1991

SUMMARY

The 3’-terminal sequences of flavivirus genomes within approx. 100 nucleotides (nt) have been suggested to have a highly conserved secondary structure, as based on the known nt sequence data and free-energy calculations using computer programs. To test the existence of a secondary structure in solution, we devised a strategy to generate truncated RNA molecules from about 0.3-1.4 kb in length, having the same polarity and nt sequence as dengue virus type 2 (DEN-2) RNA (New Guinea-C strain). When these labeled RNA molecules were digested by RNase A, and analyzed by denaturing polyacrylamide-gel electrophoresis, three resistant fragments of 16, 20 and 23 nt in length were reproducibly obtained. To examine whether these RNase A-resistant (RNaseR) fragments emerged from a stable secondary structure formed in solution consisting of 3’ -terminal sequences, hybridization of the RNaseR fragments to four chemically synthesized oligodeoxyribonucleotides (oligos), complementary to nt l-24, 25-48, 49-72, and 73-96 from the 3’ terminus of DEN-2 RNA, followed by RNase H digestion were carried out. Oligos complementary to nt 25-48 and 49-72 from the 3’ end of DEN-2 RNA were sufficient to render all three RNaseR fragments susceptible to RNase H digestion. These data indicate that a stable secondary structure is formed in solution involving nt 18-67 from the 3’ terminus. The potential use ofthese unique transcripts to identify the viral and/or host proteins which might interact at the 3’ terminus of DEN-2 RNA during initiation of replication is discussed.

The family of flaviviridae consists of about 70 closely related enveloped viruses (Westaway et al., 1985) containing an ss RNA of approx. 11 kb as their genome with

a positive-stranded polarity (Russell et al., 1980). The 5’ end of the RNA has a type-1 cap structure, and a poly(A) track toward the 3’ end of mosquito-borne flaviviruses is absent. However, recently it has been reported that there are two types of TBE virus strains, one having a poly(A)

Correspondence to: Dr. R. Padmanabhan,

phates;

INTRODUCTION

and Molecular

Biology, University

Department

of Kansas

Medical

of Biochemistry Center,

39th and

Rainbow Blvd., Kansas City, KS 66103 (U.S.A.) Tel. (913)588-7018; Fax (913)588-4903. * Present

address:

Department

of Biochemistry,

Abbreviations:

bp, base pair(s); dengue

DEN-2,

cDNA,

Osmania

DNA complementary

virus type 2; dNTP,

ds, double

University,

deoxynucleoside

reaction;

strand(ed);

virus; kb, kilobase

litis virus; NGS-C, deoxyribonucleotide;

Hyderabad-500007 (A.P.) (India) Tel. (091)842-868951 (Ext. 245); Fax (91)842-869020.

RNA;

cephalitis

DTT,

JE, Japanese

en-

New Guinea strain C; nt, nucleotide(s); oligo, oligoORF, open reading frame; PCR, polymerase chain

PolIk, Klenow (large) fragment

resistance/resistant;

dithiothreitol;

or 1000 bp; MVE, Murray valley encepha-

RNaseR,

resistant

of6.

coli DNA polymerase

to RNase A digestion;

I; R,

ss, single

strand(ed); SSC, 0.15 M NaCI/O.OlS M Na, ‘citrate pH 7.6; 7’aq polymerase, DNA polymerase isolated from Thermus aquaficus YTl; TBE, to viral triphos-

tick-borne

encephalitis;

WN, West Nile virus; YF, yellow fever virus.

186 tract at the 3’ end (the prototype Neudoerfl strain), and the other lacking it similar to the mosquito-borne flaviviruses (Mandl et al., 1991). The first complete sequence of a flavivirus RNA reported was that of YF (Rice et al., 1985). Several interesting structural features in the RNA genome were established unequivocally& this study. (I ) There is a single long ORF coding for a large polyprotein precursor, which is then cleaved by cellular and/or viral encoded teases to form the mature structural and nonstructural

propro-

teins of the virus. (2) A model was proposed for the possible secondary structure in the 3’-terminal region of YF RNA (Rice et al., 1985; see also Grange et al., 1985). Since then, a number of flavivirus genomes have been cloned and sequenced, such as WN (Castle et al., 1985; 1986; Wengler and Castle, 1986; Wengler et al., 1985) DEN-4 (Zhao et al., 1986; Mackow et al., 1987), three distinct isolates of DEN-2 (Hahn et al., 1988; Duebel et al., 1986; 1988; Yaegashi et al., 1986; Irie et al., 1989), JE (Takegami et al., 1986; Sumiyoshi et al., 1987; McAda et al., 1987), Kunjin virus (Coia et al., 1988), and TBE (Mandl et al., 1988; 1989). These sequence data support the general structural features of the flavivirus genome mentioned above. Interestingly, the potential to form a stable secondary structure is highly conserved among the various flavivirus RNA molecules, as deduced from the primary sequence data and the computer-derived energy calculations (Tinoco et al., 1973). Two lines of experimental evidence suggested that such secondary structures could exist in solution. First, Brinton et al. (1986) found that nucleotides within the putative region of secondary structure formed at the 3’ terminus of WN were partially resistant to RNases. Second, Hahn et al. (1987) reported the isolation of rare cDNA clones of DEN-2 RNA (Sl/candidate vaccine strain of PR-159 isolate) as well as that of MVE RNA, which could have arisen by self-priming of 3’-terminal base-paired region during cDNA cloning using reverse transcriptase. The aim of the present study was to test the formation of such a stable secondary structure in solution, by devising a novel method to generate radiolabeled transcripts of high specific activity in vitro, which contained the authentic 3’terminal sequences of DEN-2 RNA (NGS-C strain). Formation of stable secondary structures in these labeled transcripts could then be analyzed by digestion with RNase A. To examine whether any of the RNaseR fragments were generated from the 3’-terminal region of the transcripts, we hybridized synthetic oligos of defined sequences complementary to the 3’-terminal region of DEN-2 RNA to the RNaseR fragments, and tested the sensitivities of the resultant RNA : DNA hybrids to RNase H. These experiments enabled us to map the RNaseR fragments within the 3’-terminal 96 nt region of DEN-2 RNA, and provided direct evidence for the formation of a stable secondary structure in solution involving this 3’-terminal region.

RESULTS

AND

DISCUSSION

(a) Generation of transcripts containing the 3’4erminal sequences of DEN-2 RNA To examine the potential of the 3’-terminal sequences to form a secondary structure in solution, we devised a strategy to generate truncated RNA molecules having the authentic 3’ terminus of DEN-2 RNA, differing only in their lengths as their 5’ end. The parent plasmid contains an insert of 1339 bp corresponding to the 3’-terminal sequence of DEN-2 RNA cloned between X&I and KpnI sites of pGEM 7Zf’ vector (Promega, Madison, WI) (Fig. 1). Several subclones were generated from this parent plasmid by sequential digestion with Escherichiu coli exonuclease III and S 1 nuclease (Henikoff, 1984). The end points of deletion in these subclones were determined by sequence analysis (Sanger et al., 1977). Two cDNA clones containing the 3’-terminal sequences of 292 bp, and 1339 bp were linearized with XbaI, followed by digestion with S 1 nuclease. They were then used as templates for in vitro transcription using SP6 RNA polymerase in the presence of labeled rNTPs to give rise to transcripts having the same polarity, as well as the 3’-terminal sequence as DEN-2 RNA, differing only in their lengths (see Fig. 2). (b) Resistance to RNase A digestion To investigate whether labeled transcripts could form a stable secondary structure in solution, digestion by RNase A was carried out under two different salt concentrations. Since ds regions of RNA are resistant and ss regions sensitive to RNase A digestion, any secondary structure formation in RNA could be visualized as RNaseR fragments by electrophoresis on polyacrylamide/urea gels followed by autoradiography. Fig. 2 shows that, when labeled transcripts of 292 and 1339 nt in length were digested by RNase A in 0.01 x SSC, or 2 x SSC, some common RNaseR fragments were obtained. The sizes of these fragments did not change when S 1 nuclease digestion to remove the four nt from the 5’ end of the XbaI-linearized plasmid was omitted, prior to in vitro transcription (not shown). The sizes of the protected fragments were estimated to be within two clusters, the first between 23 and 16 nt, the second between 1 and 10 nt long (Fig. 2, A and B), by comparison with the ladder of 5’ -labeled oligo (5 1-mer) partially digested with snake venom phoshodiesterase (not shown). The fragments indicated by arrows in the first cluster were the predominant species, and their sizes were estimated to be about 23, 20, and 16 nt in length (Fig. 2, A and B). Other RNaseR fragments produced in the digest of 1339 nt transcript were not present in the digest of 292 nt transcript in the first cluster, suggesting that these could have been produced from the region not shared by the two transcripts. Interestingly, under the conditions of RNase A

187 promoter

Tl

JkU I’

TCTAGA AGATCT

T7 promoter

XLUI I'

T AGATC Pollk

Tl promoter

I

TCTAG AGATC

Ligation cloning

t A T

and

GGTAC C PCR fragment (1.35 kb)

Fig. 1. Strategy

for generating

transcripts

containing

the same polarity

and 3’-terminal

from DEN-2 RNA which was tailed with poly(A) using E. coli poly(A) polymerase The oligos 5’-GGACAAGTTGGTACCTATGG CAACACACC amplified

clones having the parent

(representing

to the 3’-terminal

sequence

DNA after a total of 25 cycles of denaturation,

and blunt-ended sequence

complementary

XbaI sites of pGEM7Zf’ the regenerated

of DEN-2

1.35-kb cDNA

clone having

Madison,

orientation

identical

3’-terminal

treating

WI), following (up

was digested routine

for amplification

with E. coli exonuclease

by Taq polymerase.

procedures

(Maniatis

lengths

III and S 1 nuclease

prepared

previously

toward

(Henikoff,

The PCR the KpnI

et al., 1982). Several independent

to about 120 nt from X&I site corresponding

with varying

library,

by PCR (Saiki et al., 1988).

with KpnI. It was then cloned between

in this region to those reported

sequences

RNA in vitro. A cDNA

see Irie et al., 1989), and 5’-AGAACCTGTTGATT-

were used as primers

were sequenced

DEN-2

as DEN-2

1973), was used for amplification

of DEN-2 genome;

genome

and DNA synthesis

data were found to be identical

parent clone at the SacI site, and sequentially verified by DNA sequence

annealing

vector (Promega,

XbaI site in the correct

RNA). The sequence

nt 9373-9392 of DEN-2

sequences

(Sippel,

to the 3’terminal

(Irie et al., 1989). Subclones

the 5’ end were prepared

by digesting

1984). The end points of all deletions

from the were

analysis.

digestion in 0.01 x SSC, only the 23 nt fragment was produced as the RNaseR fragment (Fig. 2A, lane 5). The low salt conditions (0.0 1 x S SC) are probably not favorable for the formation of a stable secondary structure in solution. Next, the question whether these RNaseR fragments resulted specifically from the transcripts containing the 3’-terminal sequences of DEN-2 RNA was addressed. A control transcript from the region of l-550 nt at the 5’ end of DEN-2-RNA was digested with RNase A under the same conditions of high ionic strength. Fig. 2B shows that the pattern of RNaseR fragments (lane 4) was quite different from that of 3’ -terminal transcript (lane 2).

(c) Mapping the location of RNaseR fragments by annealing with synthetic oligos, followed by RNase H digestion To investigate further whether these RNaseR fragments contained sequences from the 3 ‘-terminal region of DEN-2 RNA, four oligos were synthesized complementary to the first 96 nt of DEN-2 RNA. Subsequent to RNase A digestion of the two transcripts containing the 3’-terminal sequences, the RNaseR fragments were annealed to each of the four oligos, and the annealed mixtures were digested with RNase H. Since RNase H digests only the RNA of the RNA : DNA hybrid, this experiment could reveal the speci-

188

A

123456

B

1234

ticity and location of the RNaseR fragments. The results of RNase A, followed by RNase H digestion in Fig. 3 indicate that oligos Nos. 1 and 4 did not have any effect (lanes 3 and 6 in Fig. 3, A and B). These results indicate that the RNaseR fragments do not form stable hybrids with oligos Nos. 1 and 4 to become susceptible to RNase H digestion, or do not contain sequences complementary to these oligos. However, when oligo No. 2 was annealed, 23 and 20 nt long RNaseR fragments became sensitive to RNase H (Fig. 3, A and B, lanes 4) indicating that these fragments resulted from the region of transcript corresponding to nt 17-39 from the 3’ terminus of DEN-2 RNA (see also Fig. 4). The digestion of 23-nt fragment appeared incomplete (Fig. 3, A and B, lanes 4), and there was no change in this pattern even when a mixture of all four oligos were used for annealing (Fig. 3, A and B, lanes 7). However, in another experiment in which 400 ng of oligo No. 2 was used for hybridization, this 23-nt band was completely susceptible to RNase H digestion (data not shown). When oligo No. 3 was annealed, RNaseR fragments of 20 and 16 nt in length became sensitive to RNase H digestion, suggesting that these fragments contained sequences complementary to nt 44-65 from the 3’ terminus of DEN-2

aliquots

at

- 70°C.

(Panel A) An aliquot

(5 x lo“-1 x lo5 cpm) was incubated (50 PI), containing

of the labeled

at 37°C

transcript

for 60 min in a buffer

RNase A (3 pg) as follows. Lanes 1

2

3

4

292 nt RNA

+ _

f _

+ _

0.01 x ssc

+

+ _

_

+

+

f _

+

+

_

+

1339 nt RNA

2 x ssc RNase A

5

6

_

_

_

+

+

+ _ + +

RNase A was removed by proteinase K (3 pg) digestion in 1 y0 SDS at 37°C for 15 min, followed by phenol: CHCl, extraction and ethanol precipitation Fig. 2. Analysis transcripts.

of RNaseR

fragments

Two cDNA clones having 3’-terminal

292 bp as inserts were sequentially Labeled

transcripts

templates

generated

by the method

was carried

sequences

of 1339 and

with XbaI, and S 1 nuclease.

of high specific activity

were prepared

in vitro transcription

treated

from the 3’-terminal

from the linearized of Melton

plasmid

et al. (1984). The

out in 25-~1 reaction

volume containing

40 mM Tris . HCl pH 7.5/6 mM MgCl,/2 mM spermidine/0.05 mM each of GTP, CTP, UTP/O.S mM ATP/one unit of Inhibit-ACE (5 Prime-3 Prime, Inc., West Chester, serum

albumin/l0

PCi

PA)/1 mM m7G(5’)ppp(5’)G/100 each

of

[c+~‘P]GTP,

CTP,

gg bovine UTP

(400 Ci/

mmole)/two units of SP6 RNA polymerase. The reaction mixture was incubated at 40°C for 60 min. The DNase I (1 unit) was then added and incubated

for a further

15 min at 37°C.

The reaction

mixture

was ex-

tracted with phenol: CHCI, and the unincorporated nt were removed on Biospin-101 column (BioRad). The labeled transcript was extracted once with phenol

: CHCI, and precipitated

with ethanol

and stored

as small

in the presence

of E. coli tRNA

(3 pg) added

The labeled RNA was collected

by centrifugation,

was

finally

small

Tris

0.089 M borate/2

dissolved

in

a

mM EDTA

volume buffer

as a carrier.

and the pelleted RNA of

7M

urea/O.089

pH 8.3, containing

phenol blue dye, heated at 90°C for 3 min and electrophoresed

M

bromoon a 7 M

urea/O.089 M Tris .0.089M borate/2 mM EDTA (20%) polyacrylamide gel until the bromophenol dye reached 21 cm. The sizes of the fragments were determined

from a ladder

of 5’-labeled

oligos generated

from a

partial snake venom phosphodiesterase digestion (Jay et al., 1974) of a 51-mer deoxyoligo. The gel was covered with plastic wrap and exposed directly

to Kodak

XAR-5 film at 70’ C. The sizes of the three fragments

shown by arrows are estimated to be 16, 20 and 23 nt. (Panel B) The transcript containing 292 nt of 3’-terminal sequence of DEN-2 RNA, and a transcript

(control

RNA)

from

a cDNA

clone

corresponding

to

nt I-550 from the S’terminus of DEN-2 RNA (5 x IO4 cpm each) were either incubated in buffer with no RNase A, or digested with RNase A under the same conditions

as in panel A, lanes 3 and 6.

189 lanes 5), whereas

it appeared

to be almost complete

when

oligo No. 2 was used (Fig. 3, A and B, lanes 4). These results suggested a possibility that there are two RNaseR fragments of 20 nt in length, both of which were sensitive to oligo No. 2, but only one of which was sensitive to oligo No. 3 (see section d, and Fig. 4, A and B). (d) Location of the RNase A cleavage sites in the putative model for stem-loop structure at the 3’ terminus of DEN-2 RNA The data presented in Figs. 2 and 3 support the formation of a stable secondary structure in solution. Hahn et al. (1988) proposed a model for the stem-loop structure from the primary sequence data and the computer-derived

Fig. 3. Mapping fic synthetic containing sequences

of the RNase A-resistant

oligos,

followed

fragments

by annealing

by RNase H digestion.

1339 (panel A), and 292 (panel B) nt of 3’-terminal were digested

in length are shown by arrows and B. The digests

and hybridized

with 100 ng of synthetic (oligo

oligos (24-mers)

No. 1); 2, nt 25-48

(oligo No. 3); 4, nt 73-96

(oligo

nt is 1. The hybridization

containing

25 mM Tris

HCl

was done in 10 ~1 reaction

pH 7.5/300 mM

mM MgCI, at 90°C for 3 min, followed

KC&‘2 mM

formamide

was stopped

by the addition

(80x)-bromophenol indicate

the RNase

blue dye. The samples H products

mM

at 37°C for 60 min.

of stop

buffer

containing

were heated

90” C for 3 min and loaded onto a 7 M urea/2Oft% polyacrylamid~ arrowheads

volume

DTTjl

by quick chilling in ice

for 5 min. RNase H (1 unit) was added and incubated The reaction

complementary

No. 2); 3, nt 49-72

(oligo No. 4) of DEN-Z RNA (see Fig. 4). The

3’-terminal EDTA/6

of E. coli tRNA

in the presence

Each of the digests was divided into aliquots,

to

1, nt l-24

of panels A

: CHCI,, and the labeled

with phenol

with ethanol

(OS pg) added as a carrier.

as in

of 23,20 and 16 nt

on the left and right margins

were treated

was precipitated

DEN-2

with RNase A under the same conditions

Fig. 2, panel A, lanes 3 and 6. The RNaseR fragments

RNA

speci-

The transcripts

at

gel. The

of 12 and 13 nt in length.

Lanes I

2

3

4

5

6

7

+ -

+

-

+

-

+ +

-

+

Oligo 1

-

-

+ f

+ -

Oligo 2

-

-

-

+

+ _

Oligo 3 Oligo 4

-

-

-

-

+ _

RNase

H

+

+

RNA (Fig. 3, A and B, lanes 5). It should be noted again that the digestion of 20-nt fragment appeared incomplete when oligo No. 3 was used for annealing (Fig. 3, A and B,

energy calculations (Fig. 4A). The primary sequences are identical for DEN-2 RNA of New Guinea, Jamaica strain, and Puerto Rico-l 59/S 1 (PR- 159/S 1) vaccine strain, except at nt 42, which is a G for PR-159/Sl strain (Hahn et al., 1988; Deubel et al., 1988; Irie et al., 1989). We examined the putative RNase A cleavage sites based on this model (Fig. 4A). Since oligos Nos. 2 and 3 but not oligos Nos. 1 and 4 render the RNaseR fragments susceptible to RNase H, the RNase A cleavage sites are most likely located in the ss-loop region in the proposed model shown in Fig. 4A. Since RNase A cleaves next to pyrimidines, its putative cleavage sites in the secondary structure model can be tentatively assigned as follows. For example, the cteavages occurring at sites 1 and 3, and 1 and 2 would give rise to a 23, and a 20 nt fragment, respectively, which would be susceptible to oligo No. 2 t RNase H treatments (see also Fig. 4B). It appears that the sites 1 and 3 are the most readily cleaved, as the amount of 23 nt fragment is the predominant species obtained (see Fig. 3, A and B, lanes 3). Similarly, cleavages occurring at sites 5 and 6 would give rise to a 16 nt fragment which would become susceptible to oligo No. 3 + RNase H treatment (Fig. 3, A and B, lanes 5). The generation of 20 nt fragment(s) by RNase A cieavage which become susceptible to both oligos Nos. 2 or 3 in the presence of RNase H is difficult to explain from this putative model. One possibility is that cleavages at sites 4 and 8 in the secondary structure model shown in Fig. 4A would also result in a 20 nt fragment susceptible to oligo No. 3. A second possibility is that two 20 nt fr~ments could be generated from alternate secondary structures formed at the 3’-terminal region of DEN-2 transcript in solution. It is possible that the stem-loop structure proposed by Hahn et al. (1988) could be stabilized by interaction with proteins in vivo, but in the absence of stabilizing protein, the RNA could assume alternate stable structures in solution. It is noteworthy that smaller fragments of approx. 12-13 nt in length were also generated after RNase H digestion (as shown by arrowheads in Fig. 3, A and B, lanes 4). The origin of these bands could not be mapped at present.

190

B A A U-A G-C G-C A-U A-U U-A 24- G - C G U U-A

III GGC I ACA 48

3'..UGUCGUGGUAAGGUIIIIAAGA oligo 3’......

23 nt

I

I 30 50 I

3’. oligo

6

60 I 16

CGGACCUUACUACGAC

Fig. 4. A model for the putative proposed

secondary

minal sequences ary structure numbered Guinea, strain,

20 nt

GACC I II

A I A

CUGG

GA

G -96

sites in the previously

to form a stable second-

et al., 1988). The 3’ terminus

strain,

are identical

and Puerto

of DEN-2

for DEN-2

Rico-159/Sl

RNA is

RNA

of New

(PR-159/Sl)

vaccine

except at nt 42, which is a G for PR-159/S 1 strain (Hahn

putative AG

of DEN-2 RNA has a potential

Jamaica

et al., 1988; Irie et al., 1989). The arrows

sites of cleavage

fragments. - A

RNase A-sensitive

for DEN-2 RNA at 3’ end. (A) The 3’-ter-

as nt 1. Sequences

1988; Deubel

C-G

structure

(Hahn

nt

I I I I I I I I I I I I I I CTGGAATGATGCTGAGGAGACAGC

.

#3

CACG&XXUUACUACGACUC

G - C\ A-U 8 A C U U C-G A-U A C C - G -72 A-U G-C G-C U U U-A

I

UGUCGUGG20

U-A G-CI'

C A

TTTCB I I I I I I I I I I I I I I I

a

G-C C-G

3'-U

#2

20 nt

RNaseR

fragments

underlined. fragment,

of possible

hybrids

that

with synthetic

Base pairing

substrates

would

between

for RNase H digestion.

be formed

oligos

in the annealing

of

Nos. 2 and 3 are shown

as

the oligo No. 2 and 23-nt

and oligo No. 3 and 16-nt RNaseR

respectively)

the

by RNase A that would give rise to the RNaseR

(B) Structures

The RNA: DNA

et al.,

indicate

are shown by short vertical

fragment

RNaseR

(15 and 14 bp,

lines.

G

u u

5’

(e) Conclusions Our results support the existence of base-paired region and a general stem-loop structure proposed by Hahn et al. (1988) between nt 18-62 from the 3’ terminus of DEN-2 RNA. The region between nt 1-17, or 63-96 did not give any significant resistance to RNase A under our test conditions. This highly conserved secondary structure has been proposed to be important for replication of viral RNA (Hahn et al., 1987; Brinton et al., 1986; Takegami et al., 1986). Therefore, it will be interesting to test whether such a secondary structure is stabilized by binding of proteins in vivo. Our method to generate labeled transcripts having the same polarity and the 3’-terminal sequences of DEN-2 RNA might be useful for such studies.

(DAMD17-86-G-6038) to Dr. Fred Sampson, and by Biomedical Research Support Grant/Shared Instrumentation Facility. The views, opinions, and/or findings in this report are those of the authors only and should not be construed as an official Department of the Army position, policy, or decision unless so designated by other documentation.

REFERENCES Brinton,

M.A., Fernandez,

flavivirus Virology

genomic

A.V. and Dispoto, RNA

form

J.H.: The 3’-nucleotides

a conserved

ciated proteins

structure

for these proteins.

of the West Nile flavivirus

tural proteins.

G. and Wengler, G.: Seand the membrane-asso-

Vl and NV2 of the flavivirus

the genome sequence

Castle, E., Leidner, U., Novak, T., Wengler,

We thank Drs. James P. Calvet and Christian Zwieb for many helpful suggestions. We thank Kevin Graham and Melissa Larson for expert technical assistance. This work was supported by a Contract from the U.S. Army Medical Research and Development Command (DAMD 17-85-C5273) to R.P., by a grant from the Department of Defense

of

structure.

153 (1986) 113-121.

Castle, E., Novak, T., Leidner, U., Wengler, quence analysis of the viral core protein ACKNOWLEDGEMENTS

secondary

Virology

West Nile virus and of

Virology 145 (1985) 227-236. G. and Wengler,

G.: Primary

genome coding for all non-struc-

149 (1986) 10-26.

Coia, G., Parker, M.D., Speight, G., Byrne, M.E. and Westaway, E.G.: Nucleotide and complete amino acid sequence of Kunjin virus: detinitive gene order and characteristics Gen. Virol. 69 (1988) l-21. Deubel, V., Kinney, R.M. and Trent,

of the virus-specified D.W.: Nucleotide

proteins. sequence

J. and

191 deduced

amino

acid sequence

type 2 virus, Jamaica Duebel,

V., Kinney,

deduced

amino acid sequence

type 2 virus,

Virology

R.M. and Trent,

Jamaica

length genome. Grange,

of the structural

genotype.

D.W.: Nucleotide

of the nonstructural

genotype:

Virology

of dengue

sequence

proteins

comparative

analysis

and

of dengue of the full-

C.S., Hahn,

and Strauss,

M.: Stable secondary

structures

at

(17D vaccine strain).

of yellow fever virus

elements

RNAs and potential

L., Strauss,

in the 3’untranslated

cyclization

sequences.

E.G. region

J. Mol. Biol.

Y.S., Caller,

and Strauss, parison

R., Hunkapillar,

E.G.: Nucleotide

of the encoded

Virology Henikoff,

T., Dalrymple, sequence

proteins

J.M., Strauss,

J.H.

of dengue 2 RNA and com-

with those

of other

flaviviruses.

S.: Unidirectional

breakpoints

P.M., Sasaguri,

Sequence

analysis strain).

Jay, E., Bambara, analysis:

digestion

for DNA sequencing.

Guinea-C

with

III

creates

R. and Padmanabhan,

dengue

R., Padmanabhan,

a general,

virus

R.:

type 2 genome

(New

R. and Wu, R.: DNA

simple, and rapid fragments

White,

Y., Zhao,

A., Guiler,

method

by mapping.

B., Zhang,

M., Chanock,

sequence

of dengue

structural

proteins.

Mandl,

sequence

for sequencing Nucleic

large

Acids Res. 1

C.W., Heinz, of tick-borne analysis

of genes coding

for non-

159 (1987) 217-228.

encephalitis with

L., Buckler-

R. and Lai, C.-j.: The nucleotide

F.X. and Kunz,

protein

Y.-M., Markoff,

type 4 virus: analysis Virology

parative

C.: Sequence

virus (Western

other

flaviviruses.

subtype)

Virology

and com166 (1988)

C.W., Heinz,

F.X., Stockl,

encephalitis

sis of nonstructural (1989) 291-301.

proteins

serotype)

with other

rus: significant

differences

T., Fritsch,

Laboratory Harbor,

sequence

and comparative

flaviviruses.

C.W., Kunz, C. and Heinz, F.X.: Presence

Maniatis,

E.M., Eddy,

S.R., Shin,

between

analy-

Virology

173

Sambrook,

Cold Spring

of poly(A) in a flavivi-

the 3’ noncoding

encephalitis

E.F. and

Manual.

Harbor

regions

virus strains.

of the

J. Viral. 65

J.: Molecular

Cloning.

Laboratory,

A

Cold Spring

NY, 1982, pp. 21 l-246.

P.C., Mason,

T.L. and Fournier, encephalitis

S.J., Sheets,

and

evolution.

W.E. and Dalrymple,

of flaviviruses.

ruses. Academic

Science

J.M.: Chemical

In: Schlesinger,

Press, New York,

M.J.: Partial

virus genome.

C.S., Dalrymple,

nucleotide

Virology

sequence

J.M., Mason, of the Japanese

158 (1987) 348-360.

229 (1985) and antigenic

R.W. (Ed.), The Togavi-

1980, pp. 503-530.

D.H., Stoffel, S., Scharf,

plification

of DNA with a thermostable

S.J., Higuchi,

R., Horn,

enzymatic

DNA polymerase.

am-

Science

239 (1988) 487-491. Sanger,

F., Nicklen,

S. and Coulson,

inhibitors.

Proc.

A.R.: DNA sequencing Natl.

Acad.

Sci.

with chain-

USA

74 (1977)

5463-5467. A.E.: Purification

phate: ribonucleic J. Biochem.

and characterization

of adenosine

triphos-

from Escherichia coli. Eur.

acid adenyl transferase

37 (1973) 31-40.

H., Mori, C., Fuke, I., Morita,

Kikuchi,

Y., Nagamatu,

sequence

of Japanese

K., Kuhara,

H. and Igarashi, encephalitis

S., Kondou,

A.: Complete

virus genome

J.,

nucleotide

RNA. Virology

161

(1987) 497-510. T., Washizu,

3’-end

of Japanese

M. and Yasui, K.: Nucleotide encephalitis

virus genomic

sequence

at the

RNA. Virology

152

(1986) 483-486. Tinoco Jr., I., Borer, P.N., Dengler, D.M. and Gralla,

Wengler,

acids. Nature

G., Castle,

quence

analysis

B., Levine, M.D., Uhlenbeck,

J.: Estimation

E., Leidner,

U., Nowak,

Wengler, G. and Castle, E.: Analysis bly are characteristic RNA of flaviviruses.

protein

Padmanabhan, type 2 genome. Zhao,

B., Mackow,

in

G.: SeWest

147 (1985) 264-274. properties sequence

which possi-

of the genome

J. Gen Virol. 67 (1986) 1183-l 188. M.A., Gaidamovich,

A., Kaariainen,

T., Vakharia,

T. and Wengler,

of structural

S.Y., Horzinek,

L., Lvov, D.K., Porterfield,

P.K. and Trent, D.W.: Flaviviridae. Yaegashi,

O.C.,

structure

V3 of the flavivirus

for the 3’-terminal

E.G., Brinton,

Igarashi,

of secondary

New Biol. 246 (1973) 40-41.

of the membrane

Intervirology

V.N., Page, K., Sasaguri,

R.: Partial sequence analysis Gene 46 (1986) 257-267. E., Buckler-White,

Lai, C.-j. and Makino,

P.W., Schmaljohn,

R.L. and

of yellow fever virus: implications

sequence

gene expression

Saiki, R.K., Geltand,

Westaway,

genomic RNAs of tick-borne (199 1) 4070-4077.

McAda,

E. and Kunz, C.: Genome

(Western

a bacterio-

Acids Res. 12 (1984) 7035-7056.

Nile virus and of its gene. Virology

of tick-borne

Mandl,

structure

ribonucleic

of the structural

active RNA

containing

726-733.

Crothers,

197-205. Mandl,

for flavivirus

Takegami,

E., Makino,

Lenches,

Nucleic

J.H.: Nucleotide

Sumiyoshi,

(1974) 331-353. Mackow,

probes from plasmids

SP6 promoter.

Rice, C.M.,

Sippel,

Gene 28 (1984) 351-359.

Y., Putnak,

of cloned

exonuclease

Gene 75 (1989) 197-211.

oligodeoxynucleotide

phage

terminating

162 (1988) 167-180.

Irie, K., Mohan,

and RNA hybridization

T., Zinn, K. and

of biologically

G.T., Mullis, K.B. and Erlich, H.A.: Primer-directed

198 (1987) 262-267. Hahn,

M.R., Maniatis,

M.R.: Efficient in vitro synthesis

Russell, P.K., Brandt,

Y.S., Rice, CM., Lee, E., Dalgarno,

J.H.: Conserved

of flavivirus

D.A., Kreig, P.A., Rebaghati,

Strauss,

FEBS Lett. 188 (1985) 159-163. Hahn,

Melton,

Green,

165 (1988) 234-244.

T., Bouloy, M. and Gerard,

the 3’-end of the genome

proteins

155 (1986) 365-377.

Y.: Cloning

24 (1985) 183-192. Y., Feighny,

R. and

of cloned dengue virus

A., Markoff, full-length

DNA sequences: analysis of genes coding Virology 155 (1986) 77-88.

M.C.,

J.S., Russell,

L., Chanock, dengue

for structural

R.M.,

type 4 viral proteins.