Quantitative Real-Time PCR Detection of Rift Valley Fever Virus and Its Application to Evaluation of Antiviral Compounds

doi:10.1128/JCM.39.12.4456-4461.2001

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Journal of Clinical Microbiology, December 2001, p. 4456-4461, Vol. 39, No. 12
0095-1137/01/$04.00+0 DOI: 10.1128/JCM.39.12.4456-4461.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Quantitative Real-Time PCR Detection of Rift Valley Fever Virus and Its Application to Evaluation of Antiviral Compounds

Stephan Garcia,¹ Jean Marc Crance,¹ Agnes Billecocq,² Andre Peinnequin,¹ Alain Jouan,¹ Michele Bouloy,² and Daniel Garin¹^,^*

Unité de Virologie, Centre de Recherches du Service de Santé des Armées (CRSSA) Emile Pardé, Grenoble,¹ and Groupe des Bunyaviridés, Institut Pasteur, Paris,² France

Received 6 August 2001/Returned for modification 12 September 2001/Accepted 27 September 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The Rift Valley fever virus (RVFV), a member of the genus Phlebovirus (family Bunyaviridae) is an enveloped negative-strandRNA virus with a tripartite genome. Until 2000, RVFV circulationwas limited to the African continent, but the recent deadly outbreakin the Arabian Peninsula dramatically illustrated the need forrapid diagnostic methods, effective treatments, and prophylaxis.A method for quantifying the small RNA segment by a real-timedetection reverse transcription (RT)-PCR using TaqMan technologyand targeting the nonstructural protein-coding region was developed,and primers and a probe were designed. After optimization of theamplification reaction and establishment of a calibration curvewith synthetic RNA transcribed in vitro from a plasmid containingthe gene of interest, real-time RT-PCR was assessed with samplesconsisting of RVFV from infected Vero cells. The method was foundto be specific for RVFV, and it was successfully applied to thedetection of the RVFV genome in animal sera infected with RVFVas well as to the assessment of the efficiency of various drugs(ribavirin, alpha interferon, 6-azauridine, and glycyrrhizin)for antiviral activity. Altogether, the results indicated a strongcorrelation between the infectious virus titer and the amountof viral genome assayed by real time RT-PCR. This novel methodcould be of great interest for the rapid diagnosis and screeningof new antiviral compounds, as it is sensitive and time savingand does not require manipulation of infectiousmaterial.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The Rift Valley fever (RVF) virus (RVFV), a member of the genus Phlebovirus, belongs to the Bunyaviridae family and possessesa negative-stranded, tripartite RNA genome composed of a large,a medium, and a small (S) segment (for reviews, see references9 and 37). Like other phleboviruses, the S segment utilizesan ambisense strategy to code for two proteins, the nucleocapsidprotein and the nonstructural protein (NS_s), which are synthesizedfrom subgenomic viral complementary and viral sense mRNA,respectively.

RVF is a mosquito-borne zoonosis predominantly provoking the death of young animals and abortion (e.g., sheep and goats) (forreviews, see references 24, 39 and 41). The disease wasfirst identified in sheep by Daubney et al. in Kenya in 1931,and it is endemic almost everywhere in subtropical Africa (6).Transmission to humans occurs primarily by contact with infectedanimal body fluids and by mosquito bites. Infection is usuallyasymptomatic or associated with a brief self-limited febrile illness.However, complications such as retinitis, encephalitis, or hemorrhagicfever occur in some patients with mortality rates of up to 10to 12% (21, 28).

The potential of RVF as a disease emerging in new areas was first documented in Egypt in 1977 (16), and since then, epidemicshave occurred in Mauritania (1987 to 1988 and 1998), Madagascar(1990 to 1991), Egypt (1993), and eastern Africa (in Kenya, Somalia,and Tanzania) (references 33 and 34 and references therein).Recently, the outbreak on the Arabian Peninsula (in Yemen andSaudi Arabia) represented the first case of RVF outside Africa(2, 4). Epizootics and epidemics are associated with periodsof heavy rainfall and the concomitant presence of large numbersof mosquitoes (18). The survival of RVFV during interepizooticsis believed to depend on transovarial transmission of the virusin floodwater Aedes mosquitoes (17).

Experimental vaccines are still in development, and no proven specific therapy is available for humans (3, 29). Thus,effective antiviral agents would be useful for treating severeinfections or reducing viremia in amplifying hosts, thereby limitingviral propagation by biting arthropods. Currently, diagnosis isbased on detection of specific antibodies or virus isolation inanimal and mosquito cells (4). Reverse transcription (RT)-PCRtechniques have been described and used to detect the RVFV genomein mosquitoes (11) and, recently, in clinical samples (35).In this work we developed a real-time RT-PCR method in order todetect and specifically quantify the virus either from cells orfrom sera and evaluated the potential of this assay for the diagnosisand screening of antiviralcompounds.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cells, virus, and mouse sera. Cells were grown at 37°C in 5% CO₂ in 199 culture medium (M199) supplemented with 10% inactivated fetal calf serum. RVFV strainsMP12, ZH501, ZH548, ArD38661, 74HB59, and clone 13 and the closelyrelated phleboviruses Toscana, Icoaraci, and Belterra were grownin Vero cells (ATCC CCL-81) by serial passage. Virus titers weredetermined either by the 50% tissue culture infective dose (TCID₅₀)method (30) or by counting the PFU under the agaroselayer.

Mice were inoculated intraperitoneally with 10⁴ PFU of RVFV strain ZH548, and blood was collected at different times postinoculationby veinal puncture at the retro-orbitalsinus.

RNA in vitro transcription. A 750-bp RNA fragment encompassing the complete NS_s open reading frame of the RVFV MP12 strain in the genomic sense orientationwas transcribed in vitro from the pGem3-NSs plasmid (19) byusing the T7 RNA polymerase (Promega) under the conditions recommendedby the supplier. The DNA template was eliminated by extensivetreatment with RNase-free DNase. Proteins were eliminated by phenol-chloroformextraction, and RNA was concentrated after isopropanol precipitation.The amount of RNA was estimated by spectrophotometry, and knownamounts were used to determine the standard curve for real-timeRNAquantification.

RNA extraction. Vero cells were infected with the MP12 virus at a rate of 0.01 PFU per cell, and virus present in the maintenance medium wascollected after 72 h when the cytopathic effect was evident. Celldebris was eliminated by low-speed centrifugation. RNA was extractedaccording to the manufacturer's instructions either from 200 µlof virus stock by using the RNA Instapur kit (Eurogentec, Seraing,Belgium), from 140 µl of mouse sera by using the Trizol method(Invitrogen Life Technologies SARL, Cergy Pontoise, France), orfrom 140 µl of human sera by using the QIAamp Viral RNA kit (Qiagen,Courtaboeuf, France). After precipitation with isopropanol, RNAwas resuspended in 50 µl of RNase-free water and stored at $-$ 80°C.

Design and synthesis of primers and fluorogenic probe. The available NS_s sequences published by Sall et al. (34) were aligned with DNAsis (version 2.6; Hitachi Software Engineering,Olivet, France), and Primer Premier software was used to designthe primers and probe (version 4.04; Premier Biosoft International,Palo Alto, Calif.).

The primers S432 (5'-ATG ATG ACA TTA GAA GG GA3') and NS3m (5'ATG CTG GGA AGT GAT GAG3'), which was modified from the NS3primer (25), hybridize at positions 432 to 450 and 712 to 729,respectively, in genomic sense RNA, generating a 298-nucleotideDNA fragment. The primers were synthesized by Invitrogen LifeTechnologies. The TaqMan probe CRSSAr (5'ATT GAC CTG TGC CTG TTGCC3')was synthesized by Oligo Genset (Paris, France). It contains afluorescent reporter dye (6-carboxyfluorescein) at the 5' endand a fluorescent quencher dye (6-carboxy-tetramethyl-rhodamine)at the 3'end.

RT. The reaction was carried out at 37°C for 60 min with 10 µl of RNA in a final volume of 30 µl with 200 IU of Moloney murineleukemia virus reverse transcriptase (Invitrogen Life Technologies)and 1 µM forward primer S432 under the conditions recommendedby the supplier. Finally, the reaction mixture was heated at 95°Cfor 10 min to denature theenzyme.

Real-time PCR. The amplification reaction mixture contained 2 µl of cDNA in a final volume of 20 µl, and the reaction was carried out withthe LightCycler fast-start DNA Master hybridization probes kit(Roche Diagnostics, Meylan, France), MgCl₂ at a 3.5 mM final concentration,the primers NS3m and S432 at 0.5 µM final concentrations, andthe fluorogenic probe CRSSAr at a 0.5 µM final concentration.PCR was carried out in the LightCycler (Roche) for 45 cycles at95°C for 15 s and 60°C for 1min.

Assay of antiviral activity of compounds in cell culture. Glycyrrhizin, ribavirin, and 6-azauridine were purchased from Sigma-Aldrich (St. Quentin-Fallavier, France). Alpha 2b interferon(IFN- $alpha$ 2b) was purchased from Schering-Plough (Herouville St-Clair,France).

Confluent layers of Vero cells in 24-well tissue culture plates were infected with 0.1 ml of diluted viral suspension (0.01TCID₅₀ per cell), and 2 ml of maintenance medium containing thetest compound at an appropriate concentration was added (4 wellsper concentration). Five concentrations of the antiviral substanceswere tested in decreasing order from the maximally tolerated dose,which was the highest dose that did not cause microscopicallydetectable cytotoxic effects. Four wells were not treated withthe drugs and served as controls. After 40 h of incubation, whena maximal infectious RVFV titer was reached in the untreated cells,intra- and extracellular RVFV were obtained by three cycles offreezing and thawing. The viral titer was determined in cell culture(TCID₅₀ per milliliter), and RNA was extracted and used to quantifythe RVFV genome by real-time RT-PCR detection (RTD-PCR).

Statistical analysis. Statistical analysis of the data was carried out using one-way analysis of variance and Spearman'stest.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Real-time RTD-PCR of RVFV. A traditional RT-PCR was already developed for the detection of RVFV in different specimens and proved to be efficient forthe diagnosis of human cases during the 1998 Mauritanian outbreak(35). A high level of sensitivity was obtained in a nested RT-PCRassay, which detected 0.5 PFU of MP12 virus and was approximately100-fold more sensitive than the simple one. In order to meetthe requirements of rapid diagnosis and to avoid the risk of contamination,we employed the novel LightCycler instrument (Roche Diagnostics),which associates ultrarapid thermal cycling with TaqMan technology.New primers and a probe were designed in the highly conservedNS_s regions previously amplified in the classical RT-PCR.

For all experiments, the threshold limit was set above the noise band, and the threshold cycle (C_T) value was determined.The conditions of the amplification for salt and primer requirementswere optimized with RVFV MP12 RNA; those yielding the lowest C_Tvalues were selected. Thus, in our standard conditions, the concentrationsof the forward and reverse primers and the probe were 500 nM,and the concentration of MgCl₂ was 3mM.

The sensitivity and specificity of the RVFV genome detection were evaluated by using serial dilutions of a known amount ofRNA transcribed in vitro from plasmid pGem-NSs. The detectionand quantification were linear over the range of concentrationsexamined, from at least 10⁶ to 100 copies per run (data not shown). To test the reproducibilityof the results, four aliquots of the same samples were independentlyamplified during the same cycles (Table 1). The intra-assay coefficientof variation (CV) calculated by using the C_T values (1) wasfound to vary between 0.2 and 1.8%, depending on the quantityof RNA. Moreover, the data reported in Table 1 indicate thatthe sensitivity limit was 50 to 100 copies.

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TABLE 1. Sensitivity and intraexperimental variability of RVFV strain MP12 synthetic RNA^a

To assay RNAs from RVFV stock, serial dilutions of samples in MP12-infected cell culture supernatants containing from 10⁶ to 10 TCID₅₀ · ml¹ were reverse transcribed and amplified. We observed a linearresponse over 10⁶ TCID₅₀ · ml¹, and the method could detect less than 10 TCID₅₀ · ml of RVFV¹ (Fig. 1). Moreover, we also tested variation with time by assayingthe same samples in three different experiments carried out witha 1-day interval. The interassay CV calculated by using the C_Tvalues was found to vary between 0.9 and 3.0%, depending on thequantity of RNA (Table 2).

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FIG. 1. Standard curve obtained with 10-fold serial dilutions of viral RVFV RNA. C_T values are plotted against different RNA amounts extracted from the infectious virus (titers running from 10⁶ to 10 TCID₅₀ · ml¹).

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TABLE 2. Interexperimental variability of RVFV RNA quantification^a

To test the specificity of the amplification, we carried out the reaction with RNAs from RVFV strains clustered in the threegroups referred to as West Africa, East-Central Africa, and Egypt(31, 32, 34). These strains were ZH501, ZH548, ArD38661,74HB59, and clone 13. We also included RNAs from closely relatedphleboviruses (Toscana, Icoaraci, and Belterra) and RNA extractedfrom uninfected AP61 or Vero cells (usually used for RVFV replication).All of the RVFV strains, except for the avirulent clone 13 strainlacking the amplified NS_s sequence (25), were detected, thusconfirming that the primers and probe hybridized in conservedregions of the RVFV genome. No amplification was observed forother phleboviruses or cellular RNAs (notshown).

Since real-time RT-PCR is utilized for accurate quantification, we compared the infectious titer of MP12 stock, and the concentrationsof genome equivalents were determined by using the calibrationcurve established with in vitro-transcribed RVFV RNA amplifiedduring the same experiment. The concentration of S genome equivalentmeasured by real-time RT-PCR is approximately 3 to 3.5 log higherthan the infectious virus titer measured in cell culture (Table3).

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TABLE 3. Real-time quantification of RVFV RNA extracted from MP12-infected Vero cell supernatant or from sera of infected mice collected at different times postinfection

Because real-time RT-PCR is of special importance for diagnosis, we evaluated the method by using sera from mice experimentallyinfected with the virulent strain ZH548 and collected at differenttimes postinoculation. Viremia was determined by plaque assay,and after RNA extraction and amplification, the concentrationsof genome equivalents were calculated (Table 3). The values obtainedwere in good correlation with the infectious titers. In addition,seven human serum samples artificially contaminated with the MP12strain were successfully amplified (data notshown).

Evaluation of antiviral activity. The screening of antiviral agents is generally tedious as it requires testing a wide range of drug concentrations followedby a large number of virus titrations. Thus, we used real-timeRT-PCR to quantify RVFV yielded in the presence of the drugs.We tested ribavirin, IFN- $alpha$ , 6-azauridine, and glycyrrhizin, whichare already commercialized and used in patients for their antiviralor antitumor activity. They were known to inhibit the in vitroreplication of another phlebovirus, sandfly fever Sicilian virus(SFSV) (5), and ribavirin was previously shown to have an inhibitoryeffect on RVFV replication in infected cells (27).

A preliminary experiment was performed to determine the maximal tolerated dose of each drug. At this concentration, thesecompounds inhibited virus production by >4.0 log (Table 4). Theeffects of decreasing concentrations were determined by two methods,titration of RVFV by TCID₅₀ and RT-PCR of genome equivalent (Fig.2). At the lowest concentrations tested, ribavirin (62.5 µg ·ml¹), IFN- $alpha$ (1 IU · ml¹), and 6-azauridine (0.3 µg · ml¹) were still active. The virus titer reductions were 1.9, 0.5,and 0.5 log, respectively, and the genome titer reductions were1.4, 0.5, and 0.6 log, respectively. Glycyrrhizin had lower antiviralactivity; viral replication was inhibited only at relatively highconcentrations.

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TABLE 4. Effects of antiviral compounds on RVFV production assessed by infectious virus assay or genome detection

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FIG. 2. Effect of antiviral compounds on the RVFV (strain MP12) yield measured by either genomic (A) or virus (B) titer. Antiviral compound concentrations, increasing from C₁ to C₅, are given in Table 4. VT is the virus control (infected nontreated cells).

IFN- $alpha$ and ribavirin caused a concentration-dependent reduction in the virus yield (by analysis of variance, P < 0.5). Thereductions in virus titer and in genome equivalent were analyzedstatistically by using the Spearman test. The two methods ledto strongly correlated results (P < 0.01). Altogether, our dataclearly indicate that this method should be recommended to detectand quantify viralreplication.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Currently, besides recognizing clinical and biological features, the diagnosis of a human RFV infection is based on the detectionof specific immunoglobulin M and immunoglobulin G antibodies orvirus isolation in mammalian or mosquito cells or in the brainsof suckling mice (7, 13, 22). Recently Sall et al. describeda single-tube RT-PCR that allows for the detection of RVFV inclinical samples (35).

The RT-PCR is often used as a method of detection for a great number of arboviruses, which facilitates phylogenetic studies(14, 36).

Here we describe, for the first time, a method of RTD-PCR which allows the identification and quantification of RVFV RNA.This new technique is a significant improvement in PCR cycling,since it is a closed system in which the formation of amplifiedproduct is measured in real time, avoiding risks of contamination.It has been used for immediate identification of a viral agentduring the early acute phase of illness and for monitoring thevirus load in treated patients infected by the hepatitis B andC viruses and by herpesvirus and cytomegalovirus (1, 12,15, 20, 40). Moreover, when compared to other quantificationmethods, RTD-PCR was often revealed to be more sensitive (1,26).

The sensitivity of the assay is dependent on several factors, such as the sample source, the nucleic acid extraction method,and the thermal cycling conditions. In our hands, RNA extractionwith phenol chloroform led to better results than adsorption elutionon the column of the QIAamp Viral RNA kit (Qiagen). Likewise,we increased the sensitivity of the RT step by adding glycogento the samples. The sensitivity of this RVFV assay was evaluatedusing synthetic and viral RNA and was shown to be less than 100RNA copies per run or less than 10 TCID₅₀ · ml¹, which is equivalent to the sensitivity of the traditional RT-PCRalready described (11, 35). It is worth noting that the genomictiter measured by real-time RT-PCR was found to be between 2 and3 log higher than the virus titer measured in cell culture. Forthe dengue virus, it was also found that each infectious PFU representsat least 100 or more genomic equivalents (10), and we founda 3 log difference with the Puumala virus (8). This differencemay be due to the presence of noninfectious viral RNA, or theRVFV S segment may be overexpressed in thecells.

The specificity of the real-time RT-PCR was successfully tested with different RVFV clusters and the closely related phlebovirusesBelterra, Toscana, and Icoaraci, and as expected, the method failedto detect the clone 13 strain. The use of a cDNA synthesis stepallows us to overcome the limitations of Tth. Theoretically, RTD-PCRis a one-step procedure employing a single enzyme, the Tth providedby the LightCycler RNA Master hybridization probe (Roche Diagnostics).This enzyme displays RT activity at a recommended temperatureof 61°C and polymerase activity at a recommended temperature of72°C. However, we found that these conditions were suboptimal.Other kits now in development will probably overcome thisproblem.

In order to screen potent antiviral drugs in cell culture, it is necessary to appreciate their ability to inhibit virus replicationat noncytotoxic concentrations and then to determine their concentration-dependentactivity. As a reference method, the titration of infectious virusis currently used to evaluate antiviral activity. It requiresa time-consuming cell culture as support for the quantificationof the virus either by evaluating PFU per milliliter or TCID₅₀milliliter (5, 38). In this study, we obtained a good correlationwhen viral genomes were quantified by RTD-PCR. The latter methodreduced the time required for an experiment from 1 week to 4 h,and it avoided manipulation of dangerous infectious material whichrequired a biosafety level 3laboratory.

Among several antiviral compounds, four were selected for their inhibitory effects on RVFV replication and for their abilitiesto be used in human therapeutics. Ribavirin, 6-azauridine, andIFN- $alpha$ were proven to be very active at low concentrations andled to a reduction of the virus titer depending on the concentration,whereas glycyrrhizin became active at the highest concentrationstested. Among these compounds, only ribavirin and IFN- $alpha$ had previouslybeen investigated for their effects on RVFV (23, 27). Intravenousribavirin has been shown to effectively treat other viral hemorrhagicfevers, including Lassa fever, hemorrhagic fever with renal syndrome,and Crimean-Congo hemorrhagic fever. Furthermore, the Saudi ArabianMinistry of Health recently evaluated the feasibility of a randomized,placebo-controlled trial using intravenous ribavirin in patientswith suspected severe RVF infection (4). 6-Azauridine and glycyrrhizinwere shown to be effective against a related phlebovirus, SFSV.It would be interesting to evaluate the efficacy of a combinationof two or three compounds as was done for SFSV (5).

In conclusion, RTD-PCR detection and quantification of RVFV would be useful as a routine diagnostic test for identifying thevirus in the early stage of the disease and for following up antiviraltherapy. The technique should be used now in large field experimentsto confirm its clinical ability. It also gives a new way to estimatethe in vitro efficiency of potential antiviral substances andto detect unusual antiviralresistance.

	ACKNOWLEDGMENTS

This work was supported by research grants from the Service de Santé des Armées and from the Délégation Générale àl'Armement (grant no. 00CO014; PEA 980-814).

We thank Corinne Rothlisberger, Danielle Gratier, Josette Guimet, Henri Blancquaert, and Pierre Vialat for technicalassistance.

	FOOTNOTES

^* Corresponding author. Mailing address: Unité de Virologie, CRSSA, 24 avenue des Maquis du Grésivaudan, BP 87-38702 La Tronchecedex, France. Phone: 33-476-63-68-44. Fax: 33-476-63-69-17. E-mail:Daniel.Garin{at}wanadoo.fr.

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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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30. Reed, L. J., and H. Muench. 1938. A simple method of estimating fifty percent end points. Am. J. Hyg. 27:493-497.

31. Sall, A. A., P. M. de A. Zanotto, H. G. Zeller, J. P. Digoutte, Y. Thiongane, and M. Bouloy. 1997. Variability of the NSs protein among Rift Valley fever virus isolates. J. Gen. Virol. 78:2853-2858[Abstract].

32. Sall, A. A., P. M. de A. Zanotto, O. K. Sene, and M. Bouloy. 1998. Molecular epidemiology and emergence of Rift Valley fever. Mem. Inst. Oswaldo Cruz 93:609-614[Medline].

33. Sall, A. A., P. M. de A. Zanotto, P. Vialat, O. K. Sene, and M. Bouloy. 1998. Origin of 1997-98 Rift Valley fever outbreak in East Africa. Lancet 352:1596-1597[CrossRef][Medline].

34. Sall, A. A., P. M. de A. Zanotto, O. K. Sene, H. G. Zeller, J. P. Digoutte, Y. Thiongane, and M. Bouloy. 1999. Genetic reassortment of Rift Valley Fever virus in nature. J. Virol. 73:8196-8200[Abstract/Free Full Text].

35. Sall, A. A., J. Thonnon, O. K. Sene, A. Fall, M. Ndiaye, B. Baudez, C. Mathiot, and M. Bouloy. 2001. Single-tube and nested reverse transcriptase-polymerase chain reaction for detection of Rift Valley fever virus in human and animal sera. J. Virol. Methods 91:85-92[CrossRef][Medline].

36. Scaramozzino, N., J.-M. Crance, A. Jouan, D. A. DeBriel, F. Stoll, and D. Garin. 2001. Comparison of Flavivirus universal primer pairs and development of a rapid, highly sensitive heminested reverse transcription-PCR assay for detection of flaviviruses targeted to a conserved region of the NS5 gene sequences. J. Clin. Microbiol. 39:1922-1927[Abstract/Free Full Text].

37. Schmaljhon, C. 1996. Bunyaviridae: the viruses and their replication, p. 1447-1471. In B. N. Fields, D. M. Knipe, and P. M. Howley (ed.), Fields virology, 3rd ed. Lippincott Raven Publishers, Philadelphia, Pa.

38. Sidwell, R. W., J. H. Huffman, B. B. Barnett, and D. Y. Pifat. 1988. In vitro and in vivo Phlebovirus inhibition by ribavirin. Antimicrob. Agents Chemother. 32:331-336[Abstract/Free Full Text].

39. Swanepoel, R., and J. A. W. Coetzer. 1994. Rift Valley fever, p. 688-717. In J. A. W. Coetzer, G. R. Thompson, and R. C. Tustin (ed.), Infectious diseases of livestock with special reference to southern Africa. Oxford University Press Southern Africa, Cape Town, South Africa.

40. Takeuchi, T., A. Katsume, T. Tanaka, A. Abe, K. Inoue, K. Tsukiyama-Kohara, R. Kawaguchi, S. Tanaka, and M. Kohara. 1999. Real-time detection system for quantification of hepatitis C virus genome. Gastroenterology 116:636-642[CrossRef][Medline].

41. Zeller, H., and M. Bouloy. 2000. Infections by viruses of the families Bunyaviridae and Filoviridae. Rev. Sci. Tech. Off. Int. Epizoot. 19:79-91.

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30.	Reed, L. J., and H. Muench. 1938. A simple method of estimating fifty percent end points. Am. J. Hyg. 27:493-497.
31.	Sall, A. A., P. M. de A. Zanotto, H. G. Zeller, J. P. Digoutte, Y. Thiongane, and M. Bouloy. 1997. Variability of the NSs protein among Rift Valley fever virus isolates. J. Gen. Virol. 78:2853-2858[Abstract].
32.	Sall, A. A., P. M. de A. Zanotto, O. K. Sene, and M. Bouloy. 1998. Molecular epidemiology and emergence of Rift Valley fever. Mem. Inst. Oswaldo Cruz 93:609-614[Medline].
33.	Sall, A. A., P. M. de A. Zanotto, P. Vialat, O. K. Sene, and M. Bouloy. 1998. Origin of 1997-98 Rift Valley fever outbreak in East Africa. Lancet 352:1596-1597[CrossRef][Medline].
34.	Sall, A. A., P. M. de A. Zanotto, O. K. Sene, H. G. Zeller, J. P. Digoutte, Y. Thiongane, and M. Bouloy. 1999. Genetic reassortment of Rift Valley Fever virus in nature. J. Virol. 73:8196-8200[Abstract/Free Full Text].
35.	Sall, A. A., J. Thonnon, O. K. Sene, A. Fall, M. Ndiaye, B. Baudez, C. Mathiot, and M. Bouloy. 2001. Single-tube and nested reverse transcriptase-polymerase chain reaction for detection of Rift Valley fever virus in human and animal sera. J. Virol. Methods 91:85-92[CrossRef][Medline].
36.	Scaramozzino, N., J.-M. Crance, A. Jouan, D. A. DeBriel, F. Stoll, and D. Garin. 2001. Comparison of Flavivirus universal primer pairs and development of a rapid, highly sensitive heminested reverse transcription-PCR assay for detection of flaviviruses targeted to a conserved region of the NS5 gene sequences. J. Clin. Microbiol. 39:1922-1927[Abstract/Free Full Text].
37.	Schmaljhon, C. 1996. Bunyaviridae: the viruses and their replication, p. 1447-1471. In B. N. Fields, D. M. Knipe, and P. M. Howley (ed.), Fields virology, 3rd ed. Lippincott Raven Publishers, Philadelphia, Pa.
38.	Sidwell, R. W., J. H. Huffman, B. B. Barnett, and D. Y. Pifat. 1988. In vitro and in vivo Phlebovirus inhibition by ribavirin. Antimicrob. Agents Chemother. 32:331-336[Abstract/Free Full Text].
39.	Swanepoel, R., and J. A. W. Coetzer. 1994. Rift Valley fever, p. 688-717. In J. A. W. Coetzer, G. R. Thompson, and R. C. Tustin (ed.), Infectious diseases of livestock with special reference to southern Africa. Oxford University Press Southern Africa, Cape Town, South Africa.
40.	Takeuchi, T., A. Katsume, T. Tanaka, A. Abe, K. Inoue, K. Tsukiyama-Kohara, R. Kawaguchi, S. Tanaka, and M. Kohara. 1999. Real-time detection system for quantification of hepatitis C virus genome. Gastroenterology 116:636-642[CrossRef][Medline].
41.	Zeller, H., and M. Bouloy. 2000. Infections by viruses of the families Bunyaviridae and Filoviridae. Rev. Sci. Tech. Off. Int. Epizoot. 19:79-91.