Effective Vaccine for Lassa Fever

doi:10.1128/JVI.74.15.6777-6783.2000

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Journal of Virology, August 2000, p. 6777-6783, Vol. 74, No. 15
0022-538X/00/$04.00+0

Effective Vaccine for Lassa Fever

S. P. Fisher-Hoch,¹^,^* L. Hutwagner,²^, B. Brown,³^, and J. B. McCormick¹^,^§

Special Pathogens Branch, Division of Viral¹ and Rickettsial Diseases, Biostatistics Branch, Division of Bacterial Diseases², and Animal Resources Branch, Centers for Disease Control and Prevention, Atlanta, Georgia³

Received 7 February 2000/Accepted 3 May 2000

	ABSTRACT

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Lassa fever has been estimated to cause 5,000 deaths annually in West Africa. Recently, war in the zone where Lassa feveris hyperendemic has severely impeded control and treatment. Vaccinationis the most viable control measure. There is no correlation betweenantibody levels and outcome in human patients, and inactivatedvaccines produce high titers of antibodies to all viral proteinsbut do not prevent virus replication and death in nonhuman primates.Accordingly, we vaccinated 44 macaques with vaccinia virus-expressedLassa virus structural proteins separately and in combination,with the object of inducing a predominantly TH1-type immune response.Following Lassa virus challenge, all unvaccinated animals died(0% survival). Nine of 10 animals vaccinated with all proteinssurvived (90% survival). Although no animals that received full-lengthglycoprotein alone had a high titer of antibody, 17 of 19 survivedchallenge (88%). In contrast, all animals vaccinated with nucleoproteindeveloped high titers of antibody but 12 of 15 died (20% survival).All animals vaccinated with single glycoproteins, G1 or G2, died,but all those that received both single glycoproteins (G1 plusG2) at separate sites survived, showing that both glycoproteinsare independently important in protection. Neither group had demonstrableantibody levels prior to challenge. We demonstrate that in primates,immune responses to epitopes on both glycoproteins are requiredto protect against lethal challenge with Lassa virus without havinguntoward side effects and that this protection is likely to beprimarily cell mediated. We show that an effective, safe vaccineagainst Lassa virus can and should be made and that its evaluationfor human populations is a matter of humanitarianpriority.

	INTRODUCTION

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Lassa virus is endemic in rural West Africa. The prevalence of antibody to Lassa virus ranges from 5% in Guinea and 15 to20% in Sierra Leone and Liberia to over 20% in Nigeria (7,30). Lassa fever has been estimated to cause from 100,000 to300,000 infections a year and several thousand deaths (30).The fatality rate for hospitalized patients is about 17%, butin certain groups of patients, such as pregnant women in theirthird trimester, more than 30% may die, and fetal or neonatalloss is about 88% (34). Deafness is a common complication ofLassa fever, affecting as many as 15% of patients and renderingan estimated 1 to 2% of the population hearing impaired in areaswith high rates of infection (11). Treatment with intravenousribavirin has been shown to be effective; however, it is not widelyavailable in the areas where the disease is endemic and must beadministered in the first week of illness for optimal efficacy(28). Recently, social and economic conditions have deterioratedin areas of high endemicity of eastern Sierra Leone and Liberia,and incidence and mortality have increased (R. Allan, R. Ladbury,K. Skinner, and S. Mardel, Abstr. Int. Conf. Emerg. Infect. Dis.,abstr. 16, p. 21,1998).

Lassa virus, an arenavirus, exhibits persistent, asymptomatic infection, with profuse urinary virus excretion in Mastomysnatalensis, the ubiquitous and highly commensal rodent host (23,31). Human infection is due to contact with rodents or infectedpatients. Widespread prevention of such contact is presently impractical,so provision of a vaccine for community and hospital use is animperative public health need (19, 23, 30). We previouslyreported that a vaccinia virus expressing the Lassa virus glycoproteinprotected four nonhuman primates against lethal challenge withLassa virus (16). We now present data using standardized vaccinationand challenge protocols which compare levels of protection affordedby vaccines expressing the full range of Lassa virus proteinsfor two different species of nonhumanprimates.

	MATERIALS AND METHODS

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Nonhuman primates. We studied 44 nonhuman primates: 28 Macaca mulatta (rhesus) and 16 Macaca fascicularis (cynomolgus) monkeys under protocolsapproved by the Centers for Disease Control and Prevention AnimalCare and Use Committee. All procedures requiring animal handlingwere performed with the monkeys being under light ketamine anesthesia.Immediately before Lassa virus challenge, animals were moved frombiosafety level 2 to biosafety level 4 facilities, where theywere housed in Bioclean laminar-flow animal containment hoods(BiochemGARD, Sanford, Maine), and daily inspections were madeto record changes in appetite, water consumption, behavior, andgeneral condition. Some animals were sacrificed in extremis forhumanitarian reasons (minimal responses to stimuli, hypothermia,and hypotension). Antibody to simian retrovirus (SRV) was measuredin animals which were from a colony in thefacility.

Lassa vaccine candidates. The viruses used to immunize were NYBH strains of vaccinia virus either expressing Lassa genes, not expressing these genesas a negative control, or expressing Mopeia virus genes (MOP)as a positive control (41; M. P. Kiley, J. V. Lange, and K.M. Johnson, Letter, Lancet ii:738, 1979). Lassa virus isan arenavirus and has an ambisense S segment coding for structuralproteins and an L segment coding for the viral polymerase (2).We therefore used vaccinia viruses expressing the following S-segmentLassa structural proteins: (i) the full-length glycoprotein (V-LSG),(ii) the nucleoprotein (V-LSN), (iii) the full-length glycoproteinand nucleoprotein in the same construct (V-LSG/N), and finally(iv) single glycoproteins (V-LSG1 [containing residues 1 to 296]and V-LSG2 [with a deletion of residues 67 to 234]) (1, 31,33). Sequences used were derived from the Josiah strain of Lassavirus, isolated from a patient in Sierra Leone. Among 10 negativecontrol animals, 3 received NYBH and 7 wereunvaccinated.

We vaccinated 34 animals (Table 1). Two received V-LSG1, and two received V-LSG2. Eleven received V-LSN. Nine received eitherthe full-length glycoprotein expressed singly (seven were vaccinatedwith V-LSG) or the separate glycoproteins expressed in combination(two were vaccinated with V-LSG1 plus V-LSG2). A further eightanimals were vaccinated with constructs expressing all the proteinproducts of the small segment of the Lassa virus genome; six werevaccinated simultaneously with V-LSG and V-LSN, and two were vaccinatedwith a single construct, V-LSG/N. Two animals received 10⁴ PFU of Mopeia virus subcutaneously.

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TABLE 1. Virus titers of the challenge virus at various days after challenge in vaccinated and unvaccinated monkeys challenged with lethal doses of Lassa virus

Immunization and challenge procedures. All animals received a single vaccination consisting of 0.2 ml of vaccine given intradermally and simultaneously at four separatesites (each forearm and the lateral aspect of each thigh) at adilution which delivered to each animal a total dose of 10⁹ PFU. When two vaccines were used, each vaccine was administeredin one arm and one leg on the ipsilateral side. Typical vacciniavirus lesions were measured and recorded regularly. All animalswere challenged subcutaneously with 10³ to 10⁴ PFU of the Josiah strain of Lassa virus in 0.5 ml of phosphate-bufferedsaline within 36 to 700 days (Table 1).

Laboratory procedures. Lassa virus titers following challenge were measured in serum samples and tissue specimens by plaque assay on Vero E6 cells.Cocultivation was performed by mixing a trypsinized suspensionof Vero E6 cells with an equal number of cells from a suspensionof ground liver, spleen, or kidney. Anti-Lassa virus antibodieswere measured by immunofluorescent antibody (IFA) techniques andby radioimmunoprecipitation (RIP) using [S]methionine and glucosamineradiolabels as previously described (16, 40). The intensitiesof the RIP bands were graded by the same observer using a scaleof 1 to 4, with 1 being a faint band and 4 being a strong band.Reverse transcriptase PCR (RT-PCR) detection was applied to guanidine-extractedsera and tissues from infected monkeys to detect Lassa virus RNAduring both the acute and the convalescent stages of infectionas described previously (36). Primers were derived from a regionof the small RNA segment of Lassa virus coding for the glycoprotein(36). Hemoglobin, hematocrit, platelet, leukocyte, and erythrocytecounts were performed using a Hycell 555 cell counter (BoehringerMannheim, Houston, Tex.) or a Coulter Electronics Inc. (Hialeah,Fla.) model T660 counter. Some white cell and differential countswere performed manually. Clinical chemistries were performed usinga Lambda 3 UV-visual-spectrum spectrophotometer (Perkin-ElmerCorporation, Norwalk, Conn.).

Autopsy and biopsy. A unilateral nephrectomy with splenectomy and liver biopsies was performed on three animals to obtain serial biopsy material.Survivors were electively sacrificed when they were well and aviremicbetween days 21 and 966. Animals which died or which were sacrificedin extremis during acute Lassa virus infection were autopsied,and their livers, spleens, and kidneys were taken for virus isolationand RT-PCR. Effusions, when present, were sampled for virus titration.Cerebrospinal fluid (CSF) was taken after careful surgical exposureof the cisterna magna to avoid bloodcontamination.

Data analysis. Data were collated using Paradox 3.0 data management systems and analyzed using EpiInfo 5.01a and SAS/PC software. Valuesare from an unconditional logistic regression analysis that controlledfor monkey species, unless otherwisestated.

	RESULTS

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Survival following challenge. Twenty of 44 animals survived Lassa virus challenge (Table 1). Among the survivors were 8 of 9 V-LSG-vaccinated animals and9 of 10 monkeys which received the full S-segment products (Mopeiavirus, V-LSG/N, or V-LSG plus V-LSN). This protection againstdeath was significant when compared with the death rate of controls(P < 0.0005). The deaths were of the two animals with the longestvaccine-to-challenge intervals (488 and 700 days; range, 36 to700 days; mean, 319 days). Survival diminished as the vaccine-to-challengeinterval increased (P < 0.05; range, 36 to 700 days). A trendtowards increasing duration of viremia (days) was also observedwith increased intervals between vaccination andchallenge.

The 24 animals that died or were sacrificed in extremis included all 10 negative (unprotected) controls and all 4 vaccinatedwith single glycoproteins (V-LSG1 or V-LSG2). In addition 8 ofthe 11 V-LSN-vaccinated animals died, which shows that this vaccinewas not significantly protective (P > 0.10). The V-LSN animalsappeared to have a shorter and more acute process than unprotectedanimals. The median day of death for V-LSN animals was day 11.5(range, 9 to 13), compared with day 13 (range, 10 to 19) for controlanimals (P < 0.10). The highest individual terminal viremias wereseen in V-LSN-vaccinated animals (highest viremia, 10⁹ versus 10^6.7 PFU/ml for unprotected animals at death). This phenomenon ofmore severe disease and early death was, however, related to thechallenge dose. Back titration of the challenge inoculum usedin the final experiment showed that the titer had dropped from10⁴ to 10³ PFU/ml. The three V-LSN-vaccinated animals in that experimentthat received the lower challenge titer survived. These threeanimals were rhesus monkeys. In contrast, all four V-LSG1- andV-LSG2-vaccinated animals received the lower challenge dose butdiedregardless.

Viremia and viral load in tissues and exudates. Viremias following challenge are shown in Table 1. All but two animals experienced viremia, but in general, limitation ofviremia correlated with outcome and thus protection. The highesttiters were seen in the animals that had received the V-LSN recombinantvaccine, but this difference was not statistically significantwhen these animals were compared with the unvaccinated animals.On the other hand, the groups of animals which received the entireglycoprotein (V-LSG) or all the S-segment proteins (V-LSG/N orV-LSG plus V-LSN) showed significantly diminished mean virus titerscompared with those of unvaccinated animals (P < 0.001 and 0.001,respectively; Student t test). The one V-LSG-vaccinated animalthat died reached maximum viremia on day 8, and the last day onwhich virus was detected in serum was day 11. At autopsy on day21 this animal had evidence of pericarditis and cardiac failure.Virus could not be recovered from postmortem blood samples, butthere were virus-laden transudates. Virus was also recovered inlow titers from liver, kidney, and CSF. This animal was coincidentallySRV antibody positive; however, overall analysis of SRV positivityamong the animals showed no association with outcome followingchallenge.

Straw-colored pericardial fluid was obtained at autopsy from all animals that received V-LSN, the one that died after V-LSGvaccination, and five of the unvaccinated animals. Pleural fluidwas available from one V-LSN vacinee, the one that died from V-LSN-V-LSGvaccination, and four unvaccinated animals. Titers in these fluidswere almost uniformly higher than in serum (range, 10³ to 10^8.3 PFU/ml). Titers in CSF were lower than in serum (range, <10⁰ to 10^4.6 PFU/ml).

Persistence of Lassa virus. The latest day on which virus could be recovered from serum was day 14, and that from tissues was day 21. Evidence for persistenceelsewhere in tissues or fluids in survivors could not be foundby cocultivation of tissues taken up to 112 days following challenge(Table 2). However, autopsy and biopsy material examined by RT-PCRrevealed that viral RNA could be detected at least 112 days afterchallenge.

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TABLE 2. Detection of Lassa virus RNA by RT-PCR in tissues taken from monkeys surviving challenge

Antibody experiments. Survival or death did not correlate with the titer of IFA to whole Lassa virus antigens prior to challenge. Following vaccinationand prior to challenge, low-titer IFA could be detected in V-LSN-V-LSG-and V-LSN-vaccinated animals, with titers ranging from 4 to 256.There was a decline in antibody titer with time, but challengeresulted in a rapid boost in titers. We performed RIP analysesto determine the pattern of responses against all viral proteinsin order to search for a correlation with protection. RIP responsesto the glycoprotein were seen only in animals receiving the wholeS segment or the glycoprotein. There were barely detectable amountsof glycoprotein antibody by RIP assay after a single vaccination,but this increased briskly on challenge in protected animals (Fig.1). IFA titers and strong nucleoprotein responses seen by RIPwithout responses to the glycoprotein were seen in those animalsvaccinated with the corresponding vaccine. Repeated efforts failedto demonstrate the presence of plaque reduction neutralizationin sera from vaccinated animals before challenge or in the seraof surviving animals after recovery from challenge.

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FIG. 1. RIP readings and IFA titers in sera from several monkeys in each group following vaccination and challenge. The densities of the RIP bands against each nucleoprotein were scored from 0 to 5 subjectively by a single observer on the same occasion. The x axis denotes events and time following vaccination and challenge in days. Open bars denote antibody titer, and the other bars represent immune responses detected by RIP assay as follows:

, glycoprotein;

, glycoprotein 1;

, glycoprotein 2; and

, nucleoprotein.

Evidence of disturbances in clinical chemistry and hematology. Following challenge, mean hemoglobin and hematocrit counts, cell volume, and red cell counts did not vary significantly withviremia. Platelet counts were moderately depressed in viremiccompared with those in nonviremic animals, but this did not correlatewith virus titer in serum or with the vaccine received. Changesin differential white cell counts (reduced lymphocyte and raisedneutrophil counts) and minimal disturbances in hepatic enzymesdid correlate with protection and thus outcome (data not shown).Consistent with a possible cytotoxic T lymphocyte dominant protectiveresponse was the observation of a prompt lymphocytic responseto the virus challenge by day 4 in animals that had been protectedwith recombinants expressing all the S-segment proteins. Thisfinding contrasts with the usual lymphopenia seen in primatesfatally infected with Lassa virus (18). Furthermore, animalsthat died had significantly higher peak neutrophil counts thanthose that survived. Serum aspartate transaminase levels werehighest in animals that had received the V-LSN vaccine and inthe unprotected animals, which correlates with outcome. Animalsprotected by V-LSG or the full S segment showed little or no disturbanceof liver function, even in the face of viremia. Overall, the V-LSN-vaccinatedanimals had marked lymphopenia and higher mean aspartate aminotransferasevalues than unvaccinated animals. The V-LSN-vaccinated animalswere observed to be sicker and died earlier than unvaccinatedanimals.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Single administration of a vaccine expressing the full-length Lassa virus glycoprotein affords protection against Lassa feverin primates, with or without expression of the nucleoprotein.Vaccines expressing single glycoprotein genes, or the nucleoproteinalone, do not protect. This is the first convincing evidence thata protective immune response in nonhuman primates requires expressionof the full-length Lassa virus glycoprotein. There was no differencein protection attributable to different macaque species, so itis reasonable to anticipate that similar protection can be achievedinhumans.

Vaccination using the nucleoprotein may protect primates against a lower challenge dose of Lassa virus (10³ PFU). On the other hand, we did not observe superior protectionin animals given V-LSN and V-LSG together in terms of reductionsin maximum virus titers or duration of viremia. V-LSN-vaccinatedanimals receiving the full Lassa challenge dose (10⁴ PFU) suffered 100% mortality, earlier deaths (by 2 days), andthe highest viremias (up to 10⁹ PFU/ml). The three V-LSN survivors that received a lower challengedose were rhesus monkeys. We do not know if difference in speciesmay have influenced outcome. Against this is the observation thatamong the V-LSN fatalities, half were rhesus and half were cynomolgousmonkeys, but numbers are too small to draw conclusions. We canconclude from the data currently available only that V-LSN isnot required forprotection.

The lack of relationship between high levels of preexisting high-titer antibody to the Lassa nucleoprotein and protectionis consistent with findings for patients in Sierra Leone, forwhom there was no correlation between titer of immunoglobulinG antibody on hospital admission and subsequent outcome (22).In this study we showed that the presence of high titers of anti-nucleoproteinantibody measured prior to challenge bears no relation to outcome.The nucleoprotein is produced in excess of other proteins duringarenavirus replication, and this may explain the dominance ofanti-nucleoprotein antibodies in test systems. While we observedlittle in the way of antibody to glycoprotein after vaccinationwith glycoprotein antigen, we did observe a brisk response afterchallenge (Fig. 1). However, we were not able to demonstrate neutralizingantibody activity in any postchallenge serum by the techniquethat uses a fixed amount of serum and various dilutions of virus(20). Unlike with Junin virus infection, Lassa fever in humansdoes not respond to treatment with high-titer human immune plasma,so the role of antibodies detected by IFA assay in virus clearanceor in protection from initial infection is at least secondary(16, 25, 29). There are some experimental data indicatingthat protection is conferred by giving immune serum before challengeto monkeys, but neutralizing antibodies to Lassa virus are notoriouslydifficult to demonstrate (16, 20, 21). Attempts at treatmentof monkeys after infection have been uniformly unsuccessful. Fatalchoriomeningitis caused by intracranial inoculation of the closelyrelated arenavirus lymphocytic choriomeningitis virus (LCMV) canbe prevented (but not treated) in mice using a neutralizing monoclonalantibody to the LCMV G1 protein (3, 5, 6).

Clearly the response to glycoprotein protects the animals from induction of fatal processes leading to disease and death.Route and infectious dose are important determinants of outcome,and the inoculum in this study was chosen to model the high-doseparenteral challenge for which we require protection (19). Theimmune response is the key to understanding control of pathogenesisin this disease. Severe illness seems to be a manifestation ofdisordered host responses rather than lytic viral destructionof cells and organs (4, 10, 17, 18). It seems reasonablefrom the experiments presented here to assume that the T-cellresponse is critical in controlling virus replication and preventingthe cascade of fatal events that lead to death. Apoptosis of Tcells has now been reported to correlate with fatal outcome inEbola hemorrhagic fever. In Ebola virus, orderly T-cell responseswith limited apoptosis correlate with survival and outcome isapparently determined very early in disease (4). Lymphopeniaand impaired lymphocyte proliferation responses are characteristicof severe Lassa fever. It may be that apoptosis is likewise acentral feature of the failure to control virus replication andhence fataloutcome.

Our data strongly implicate the primary role of cytotoxic T lymphocytes in protection from Lassa fever. The protection ofour animals by Lassa virus glycoprotein expressed in vacciniavirus in the face of a low antibody response and the lack of protectionby antibody alone led us to the conclusion that antibody alonedoes not provide protection (29). The immune response to theLassa virus glycoprotein limits but does not eliminate virus replicationafter challenge. What we do know from our study is that epitopeson both glycoproteins are needed and that these are apparentlyable to induce protective immunity in concert but not independently.It is known that the proper folding of LCMV glycoprotein is criticalfor induction of the humoral response and that baculovirus- andvaccinia virus-expressed glycoproteins, such as we used in theseexperiments, are not posttranslationally processed or transportedcorrectly to the membrane (12, 38, 39). Thus, the minimalmeasurable antibody response to glycoprotein after vaccinationmay be related to improperly folded glycoprotein. Despite thestrong evidence implicating cell-mediated immunity, we still thinkwe have to keep an open mind about some contribution to protectiveprocesses byantibodies.

Lassa virus has long been known to persist in humans, but secondary cases due to contact with recovered patients have neverbeen reported (15, 28). We could not demonstrate persistentviremia but did detect persistence of Lassa virus RNA in tissues,particularly the spleen, at least 112 days after challenge. However,we could not recover virus from these tissues even using cocultivationtechniques. Thus, it seems very unlikely that persistence at thislevel can have any public health importance. Indeed low-levelpersistence of viral RNA following natural infection may be importantin protection against reinfection. By current estimates about100,000 new Lassa virus infections are acquired naturally eachyear, and there is no evidence that such people, once recovered,infect others in their communities or in medical carefacilities.

Not unexpectedly, we determined that vaccine-to-challenge intervals and challenge dose also influenced outcome. The two V-LSG-and V-LSG-V-LSN-vaccinated animals that died each had the longestvaccine-to-challenge intervals in their group (700 and 488 days,respectively). The single V-LSG death was atypical, in that theanimal died late (day 19) with complications (pericarditis), seenoccasionally in humans with Lassa fever (9, 28). V-LSN-vaccinatedanimals that received a 10-fold-lower challenge dose survived,even though this lower dose killed all the single-glycoprotein-vaccinatedanimals. Partial protection of guinea pigs vaccinated with theLassa virus nucleoprotein constructs has also been observed (1,8, 32). It is difficult and potentially misleading to comparedata from disparate species, particularly from the rodent host,in which arenaviruses establish silent persistent infection, andfrom the accidental host, the primate, in which the host responseis acute, severe, and often fatal. The "protection" seen in thethree surviving monkeys vaccinated with nucleoprotein may, onthe other hand, be purely a function of challenge. Persistentlyinfected mastomys urine (about 10² to 10³ Lassa virus particles/ml) is the most likely source of primaryinfections in humans (23, 30). In practice, however, virustiters in human blood may be as high as 10⁷ to 10⁹, so a vaccine for hospital staff must protect against high-dosechallenge by parenteral routes such as needlesticks and accidentalinfusion (19, 22, 23).

Cross-protection against other West African strains of Lassa virus remains to be addressed. The protection afforded by theMopeia virus from southern Africa certainly supports the ideathat broad protection is achievable and desirable, particularlysince some Nigerian strains may induce more severe and fatal illnessesthan strains from further west (19, 23, 35). Monoclonalantibody mapping and molecular studies of the glycoproteins ofAfrican arenaviruses show a conserved B-cell epitope on G2 inall of the known African arenaviruses, including Mopeia and mostSouth American arenaviruses (33). However, both G1 and G2 recognitionis necessary based on the results of our experiments. We concludedfrom continuous observations over 14 years in Sierra Leone thata single natural infection provides long-term protective immunityagainst disease (27).

We are concerned that genetically engineered vaccines will protect only in the short term. With respect to the populationthat most needs this vaccine, a single shot of live attenuatedcandidate vaccine conferring life-long immunity is much preferred.Mopeia virus is a good illustration of an effective live attenuatedvaccine, with the advantage that a single administration mightinduce life-long protection. Mopeia virus is unlikely ever tobe acceptable, since it is presently classified as a BSL3 pathogen,even though data from Mozambique and southern Africa suggest thatthis virus is not pathogenic for humans (41). There are majorsequence differences in the S segments of Lassa and Mopeia viruses,but no sites associated with virulence have been genetically mapped.Mopeia virus possesses not one but two hairpin loops connectingthe ambisense S gene, but the G1 and G2 proteins have 74 and 80%amino acid sequence homology, respectively (37). Pathogenicityin LCMV has been mapped to the L gene, and the most divergentregions are found in the RdRp and Z proteins (14). RdRp analysesgroup Lassa virus and LCMV together as a separate arenavirus lineage(13, 24). Sequence data are not available for the Mopeia virusL gene, but geographically it is likely to also fall within thisOld World arenavirus lineage. Despite this evidence, Mopeia virusis never going to achieve the safety standards required, and othersolutions must besought.

Among the hemorrhagic fever-causing viruses, Lassa fever and hantaviruses afflict the greatest number of victims. Lassa fevercould easily threaten communities in West Africa outside of itsalready broad area of endemicity. In the first three months of2000, three fatal cases have been reported among travelers returningto Europe, and in April 2000 epidemics are again being seen inNigeria, the most populous country in Africa. Since 1990, severesocial disruption from conflicts and terror campaigns in SierraLeone and Liberia have resulted in displacement of up to 2,000,000people $---$ half the population of the area $---$ with a substantial increasein the already large number of Lassa fever cases and deaths (Allanet al., Int. Conf. Emerg. Infect. Dis., abstr. 134). An effectivevaccine for the closely related hemorrhagic fever virus Juninvirus has been made and has virtually eliminated disease causedby this virus in Argentina (26). We have shown that an effectivevaccine for Lassa fever can be made. This vaccine needs to expressthe full-length glycoprotein, and the nucleoprotein is not required.We now need to pursue production and evaluation of a vaccine forhuman use as a matter of humanitarian concern andpriority.

	ACKNOWLEDGMENTS

We thank Anne Conaty, Lynette Brammer, Sam Trappier, Bertha Farrar, Gilda Perez-Oronoz, and Eddie Jackson for their contributionto the care of the animals and extensive technical assistance.We also acknowledge the contributions of D. Auperin and H. Morrisonand thank them for providing us with the constructs used in ourexperiments. We are most grateful to Lindsay Whitton and MarkGirard for their helpful review of themanuscript.

	FOOTNOTES

^* Corresponding author. Present address: Fondation Marcel Mérieux, 17 rue Bourgelat, 69002 Lyon, France. Phone: 33-4-72-40-79-58.Fax: 33-4-72-40-79-50. E-mail: jxsmccormk{at}aol.com.

Present address: EPO/CDC, Atlanta, GA30333.

Present address: Division of Animal Welfare, OPRR, NIH, Rockville, MD 20892-7507.

^§ Present address: Aventis Pasteur, 69260 Marcy l'Etoile,France.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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15. Fisher-Hoch, S. P. 1993. Stringent precautions are not advisable when caring for patients with viral haemorrhagic fevers. Rev. Med. Virol. 3:7-13.

16. Fisher-Hoch, S. P., J. B. McCormick, D. D. Auperin, B. G. Brown, M. Castor, G. Perez, S. Ruo, A. Conaty, L. Brammer, and S. Bauer. 1989. Protection of rhesus monkeys from fatal Lassa fever by vaccination with a recombinant vaccinia virus containing the Lassa virus glycoprotein gene. Proc. Natl. Acad. Sci. USA 86:317-321[Abstract/Free Full Text].

17. Fisher-Hoch, S. P., J. B. McCormick, D. Sasso, and R. B. Craven. 1988. Hematologic dysfunction in Lassa fever. J. Med. Virol. 26:127-135[Medline].

18. Fisher-Hoch, S. P., S. W. Mitchell, D. R. Sasso, J. V. Lange, R. Ramsey, and J. B. McCormick. 1987. Physiological and immunologic disturbances associated with shock in a primate model of Lassa fever. J. Infect. Dis. 155:465-474[Medline].

19. Fisher-Hoch, S. P., O. Tomori, A. Nasidi, G. I. Perez Oronoz, Y. Fakile, L. Hutwagner, and J. B. McCormick. 1995. Review of cases of nosocomial Lassa fever in Nigeria: the high price of poor medical practice. Br. Med. J. 311:857-859[Abstract/Free Full Text].

20. Jahrling, P. B., and C. J. Peters. 1984. Passive antibody therapy of Lassa fever in cynomolgus monkeys: importance of neutralizing antibody and Lassa virus strain. Infect. Immun. 44:528-533[Abstract/Free Full Text].

21. Jahrling, P. B., C. J. Peters, and E. L. Stephen. 1984. Enhanced treatment of Lassa fever by immune plasma combined with ribavirin in cynomolgus monkeys. J. Infect. Dis. 149:420-427[Medline].

22. Johnson, K. M., J. B. McCormick, P. A. Webb, E. S. Smith, L. H. Elliott, and I. J. King. 1987. Clinical virology of Lassa fever in hospitalized patients. J. Infect. Dis. 155:456-464[Medline].

23. Keenlyside, R. A., J. B. McCormick, P. A. Webb, E. Smith, L. Elliott, and K. M. Johnson. 1983. Case-control study of Mastomys natalensis and humans in Lassa virus-infected households in Sierra Leone. Am. J. Trop. Med. Hyg. 32:829-837.

24. Lukashevich, I. S., M. Djavani, K. Shapiro, A. Sanchez, E. Ravkov, S. T. Nichol, and M. S. Salvato. 1997. The Lassa fever virus L gene: nucleotide sequence, comparison, and precipitation of a predicted 250 kDa protein with monospecific antiserum. J. Gen. Virol. 78:547-551[Abstract].

25. Maiztegui, J., M. Feuillade, and A. Briggiler. 1986. Progressive extension of the endemic area and changing incidence of Argentine hemorrhagic fever. Med. Microbiol. Immunol. 175:149-152[CrossRef][Medline].

26. Maiztegui, J. I., K. T. McKee, Jr., J. G. Barrera Oro, L. H. Harrison, P. H. Gibbs, M. R. Feuillade, D. A. Enria, A. M. Briggiler, S. C. Levis, A. M. Ambrosio, N. A. Halsey, and C. J. Peters. 1998. Protective efficacy of a live attenuated vaccine against Argentine hemorrhagic fever. AHF Study Group. J. Infect. Dis. 177:277-283[Medline].

27. McCormick, J. B. 1990. Arenaviruses, p. 1245-1267. In B. N. Fields, and D. M. Knipe (ed.), Fields virology. Raven Press, New York, N.Y.

28. McCormick, J. B., I. J. King, P. A. Webb, K. M. Johnson, R. O'Sullivan, E. S. Smith, S. Trippel, and T. C. Tong. 1987. A case-control study of the clinical diagnosis and course of Lassa fever. J. Infect. Dis. 155:445-455[Medline].

29. McCormick, J. B., I. J. King, P. A. Webb, C. L. Scribner, R. B. Craven, K. M. Johnson, L. H. Elliott, and R. Belmont Williams. 1986. Lassa fever. Effective therapy with ribavirin. N. Engl. J. Med. 314:20-26[Abstract].

30. McCormick, J. B., P. A. Webb, J. W. Krebs, K. M. Johnson, and E. S. Smith. 1987. A prospective study of the epidemiology and ecology of Lassa fever. J. Infect. Dis. 155:437-444[Medline].

31. Monath, T. P., V. F. Newhouse, G. E. Kemp, H. W. Setzer, and A. Cacciapuoti. 1974. Lassa virus isolation from Mastomys natalensis rodents during an epidemic in Sierra Leone. Science 185:263-265[Abstract/Free Full Text].

32. Morrison, H. G., S. P. Bauer, J. V. Lange, J. J. Esposito, J. B. McCormick, and D. D. Auperin. 1989. Protection of guinea pigs from Lassa fever by vaccinia virus recombinants expressing the nucleoprotein or the envelope glycoproteins of Lassa virus. Virology 171:179-188[CrossRef][Medline].

33. Morrison, H. G., C. S. Goldsmith, H. L. Regnery, and D. D. Auperin. 1991. Simultaneous expression of the Lassa virus N and GPC genes from a single recombinant vaccinia virus. Virus Res. 18:231-241[CrossRef][Medline].

34. Price, M. E., S. P. Fisher-Hoch, R. B. Craven, and J. B. McCormick. 1988. A prospective study of maternal and fetal outcome in acute Lassa fever infection during pregnancy. Br. Med. J. 297:584-587.

35. Ruo, S. L., S. W. Mitchell, M. P. Kiley, L. F. Roumillat, S. P. Fisher-Hoch, and J. B. McCormick. 1991. Antigenic relatedness between arenaviruses defined at the epitope level by monoclonal antibodies. J. Gen. Virol. 72:549-555[Abstract/Free Full Text].

36. Trappier, S. G., A. L. Conaty, B. B. Farrar, D. D. Auperin, J. B. McCormick, and S. P. Fisher-Hoch. 1993. Evaluation of the polymerase chain reaction for diagnosis of Lassa virus infection. Am. J. Trop. Med. Hyg. 49:214-221.

37. Wilson, S. M., and J. C. Clegg. 1991. Sequence analysis of the S RNA of the African arenavirus Mopeia: an unusual secondary structure feature in the intergenic region. Virology 180:543-552[CrossRef][Medline].

38. Wright, K. E., M. S. Salvato, and M. J. Buchmeier. 1989. Neutralizing epitopes of lymphocytic choriomeningitis virus are conformational and require both glycosylation and disulfide bonds for expression. Virology 171:417-426[CrossRef][Medline].

39. Wright, K. E., R. C. Spiro, J. W. Burns, and M. J. Buchmeier. 1990. Post-translational processing of the glycoproteins of lymphocytic choriomeningitis virus. Virology 177:175-183[CrossRef][Medline].

40. Wulff, H., and J. V. Lange. 1975. Indirect immunofluorescence for the diagnosis of Lassa fever infection. Bull. W. H. O. 52:429-436[Medline].

41. Wulff, H., B. M. McIntosh, D. B. Hamner, and K. M. Johnson. 1977. Isolation of an arenavirus closely related to Lassa virus from Mastomys natalensis in south-east Africa. Bull. W. H. O. 55:441-444[Medline].

Journal of Virology, August 2000, p. 6777-6783, Vol. 74, No. 15
0022-538X/00/$04.00+0

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1.	Auperin, D. D., J. J. Esposito, J. V. Lange, S. P. Bauer, J. Knight, D. R. Sasso, and J. B. McCormick. 1988. Construction of a recombinant vaccinia virus expressing the Lassa virus glycoprotein gene and protection of guinea pigs from a lethal Lassa virus infection. Virus Res. 9:233-248[CrossRef][Medline].
2.	Auperin, D. D., D. R. Sasso, and J. B. McCormick. 1986. Nucleotide sequence of the glycoprotein gene and intergenic region of the Lassa virus S genome RNA. Virology 154:155-167[CrossRef][Medline].
3.	Bachmann, M. F., and R. M. Zinkernagel. 1997. Neutralizing antiviral B cell responses. Annu. Rev. Immunol. 15:235-270[CrossRef][Medline].
4.	Baize, S., E. M. Leroy, M. C. Georges-Courbot, M. Capron, J. Lansoud-Soukate, P. Debre, S. P. Fisher-Hoch, J. B. McCormick, and A. J. Georges. 1999. Defective humoral responses and extensive intravascular apoptosis are associated with fatal outcome in Ebola virus-infected patients. Nat. Med. 5:423-426[CrossRef][Medline].
5.	Baldridge, J. R., and M. J. Buchmeier. 1992. Mechanisms of antibody-mediated protection against lymphocytic choriomeningitis virus infection: mother-to-baby transfer of humoral protection. J. Virol. 66:4252-4257[Abstract/Free Full Text].
6.	Baldridge, J. R., T. S. McGraw, A. Paoletti, and M. J. Buchmeier. 1997. Antibody prevents the establishment of persistent arenavirus infection in synergy with endogenous T cells. J. Virol. 71:755-758[Abstract].
7.	Bloch, A. 1978. A serological survey of Lassa fever in Liberia. Bull. W. H. O. 56:811-813[Medline].
8.	Clegg, J. C., and G. Lloyd. 1987. Vaccinia recombinant expressing Lassa-virus internal nucleocapsid protein protects guineapigs against Lassa fever. Lancet ii:186-188[CrossRef].
9.	Cummins, D., D. Bennett, S. P. Fisher-Hoch, B. Farrar, and J. B. McCormick. 1989. Electrocardiographic abnormalities in patients with Lassa fever. J. Trop. Med. Hyg. 92:350-355[Medline].
10.	Cummins, D., S. P. Fisher-Hoch, K. J. Walshe, I. J. Mackie, J. B. McCormick, D. Bennett, G. Perez, B. Farrar, and S. J. Machin. 1989. A plasma inhibitor of platelet aggregation in patients with Lassa fever. Br. J. Haematol. 72:543-548[Medline].
11.	Cummins, D., J. B. McCormick, D. Bennett, J. A. Samba, B. Farrar, S. J. Machin, and S. P. Fisher-Hoch. 1990. Acute sensorineural deafness in Lassa fever. JAMA 264:2093-2096[Abstract/Free Full Text].
12.	Di Simone, C., and M. J. Buchmeier. 1995. Protection of mice from lethal LCMV infection by a reconstituted glycoprotein vaccine, p. 33-37. In Vaccines. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
13.	Djavani, M., I. S. Lukashevich, and M. S. Salvato. 1998. Sequence comparison of the large genomic RNA segments of two strains of lymphocytic choriomeningitis virus differing in pathogenic potential for guinea pigs. Virus Genes 17:151-155[CrossRef][Medline].
14.	Djavani, M., I. S. Lukashevich, A. Sanchez, S. T. Nichol, and M. S. Salvato. 1997. Completion of the Lassa fever virus sequence and identification of a RING finger open reading frame at the L RNA 5' end. Virology 235:414-418[CrossRef][Medline].
15.	Fisher-Hoch, S. P. 1993. Stringent precautions are not advisable when caring for patients with viral haemorrhagic fevers. Rev. Med. Virol. 3:7-13.
16.	Fisher-Hoch, S. P., J. B. McCormick, D. D. Auperin, B. G. Brown, M. Castor, G. Perez, S. Ruo, A. Conaty, L. Brammer, and S. Bauer. 1989. Protection of rhesus monkeys from fatal Lassa fever by vaccination with a recombinant vaccinia virus containing the Lassa virus glycoprotein gene. Proc. Natl. Acad. Sci. USA 86:317-321[Abstract/Free Full Text].
17.	Fisher-Hoch, S. P., J. B. McCormick, D. Sasso, and R. B. Craven. 1988. Hematologic dysfunction in Lassa fever. J. Med. Virol. 26:127-135[Medline].
18.	Fisher-Hoch, S. P., S. W. Mitchell, D. R. Sasso, J. V. Lange, R. Ramsey, and J. B. McCormick. 1987. Physiological and immunologic disturbances associated with shock in a primate model of Lassa fever. J. Infect. Dis. 155:465-474[Medline].
19.	Fisher-Hoch, S. P., O. Tomori, A. Nasidi, G. I. Perez Oronoz, Y. Fakile, L. Hutwagner, and J. B. McCormick. 1995. Review of cases of nosocomial Lassa fever in Nigeria: the high price of poor medical practice. Br. Med. J. 311:857-859[Abstract/Free Full Text].
20.	Jahrling, P. B., and C. J. Peters. 1984. Passive antibody therapy of Lassa fever in cynomolgus monkeys: importance of neutralizing antibody and Lassa virus strain. Infect. Immun. 44:528-533[Abstract/Free Full Text].
21.	Jahrling, P. B., C. J. Peters, and E. L. Stephen. 1984. Enhanced treatment of Lassa fever by immune plasma combined with ribavirin in cynomolgus monkeys. J. Infect. Dis. 149:420-427[Medline].
22.	Johnson, K. M., J. B. McCormick, P. A. Webb, E. S. Smith, L. H. Elliott, and I. J. King. 1987. Clinical virology of Lassa fever in hospitalized patients. J. Infect. Dis. 155:456-464[Medline].
23.	Keenlyside, R. A., J. B. McCormick, P. A. Webb, E. Smith, L. Elliott, and K. M. Johnson. 1983. Case-control study of Mastomys natalensis and humans in Lassa virus-infected households in Sierra Leone. Am. J. Trop. Med. Hyg. 32:829-837.
24.	Lukashevich, I. S., M. Djavani, K. Shapiro, A. Sanchez, E. Ravkov, S. T. Nichol, and M. S. Salvato. 1997. The Lassa fever virus L gene: nucleotide sequence, comparison, and precipitation of a predicted 250 kDa protein with monospecific antiserum. J. Gen. Virol. 78:547-551[Abstract].
25.	Maiztegui, J., M. Feuillade, and A. Briggiler. 1986. Progressive extension of the endemic area and changing incidence of Argentine hemorrhagic fever. Med. Microbiol. Immunol. 175:149-152[CrossRef][Medline].
26.	Maiztegui, J. I., K. T. McKee, Jr., J. G. Barrera Oro, L. H. Harrison, P. H. Gibbs, M. R. Feuillade, D. A. Enria, A. M. Briggiler, S. C. Levis, A. M. Ambrosio, N. A. Halsey, and C. J. Peters. 1998. Protective efficacy of a live attenuated vaccine against Argentine hemorrhagic fever. AHF Study Group. J. Infect. Dis. 177:277-283[Medline].
27.	McCormick, J. B. 1990. Arenaviruses, p. 1245-1267. In B. N. Fields, and D. M. Knipe (ed.), Fields virology. Raven Press, New York, N.Y.
28.	McCormick, J. B., I. J. King, P. A. Webb, K. M. Johnson, R. O'Sullivan, E. S. Smith, S. Trippel, and T. C. Tong. 1987. A case-control study of the clinical diagnosis and course of Lassa fever. J. Infect. Dis. 155:445-455[Medline].
29.	McCormick, J. B., I. J. King, P. A. Webb, C. L. Scribner, R. B. Craven, K. M. Johnson, L. H. Elliott, and R. Belmont Williams. 1986. Lassa fever. Effective therapy with ribavirin. N. Engl. J. Med. 314:20-26[Abstract].
30.	McCormick, J. B., P. A. Webb, J. W. Krebs, K. M. Johnson, and E. S. Smith. 1987. A prospective study of the epidemiology and ecology of Lassa fever. J. Infect. Dis. 155:437-444[Medline].
31.	Monath, T. P., V. F. Newhouse, G. E. Kemp, H. W. Setzer, and A. Cacciapuoti. 1974. Lassa virus isolation from Mastomys natalensis rodents during an epidemic in Sierra Leone. Science 185:263-265[Abstract/Free Full Text].
32.	Morrison, H. G., S. P. Bauer, J. V. Lange, J. J. Esposito, J. B. McCormick, and D. D. Auperin. 1989. Protection of guinea pigs from Lassa fever by vaccinia virus recombinants expressing the nucleoprotein or the envelope glycoproteins of Lassa virus. Virology 171:179-188[CrossRef][Medline].
33.	Morrison, H. G., C. S. Goldsmith, H. L. Regnery, and D. D. Auperin. 1991. Simultaneous expression of the Lassa virus N and GPC genes from a single recombinant vaccinia virus. Virus Res. 18:231-241[CrossRef][Medline].
34.	Price, M. E., S. P. Fisher-Hoch, R. B. Craven, and J. B. McCormick. 1988. A prospective study of maternal and fetal outcome in acute Lassa fever infection during pregnancy. Br. Med. J. 297:584-587.
35.	Ruo, S. L., S. W. Mitchell, M. P. Kiley, L. F. Roumillat, S. P. Fisher-Hoch, and J. B. McCormick. 1991. Antigenic relatedness between arenaviruses defined at the epitope level by monoclonal antibodies. J. Gen. Virol. 72:549-555[Abstract/Free Full Text].
36.	Trappier, S. G., A. L. Conaty, B. B. Farrar, D. D. Auperin, J. B. McCormick, and S. P. Fisher-Hoch. 1993. Evaluation of the polymerase chain reaction for diagnosis of Lassa virus infection. Am. J. Trop. Med. Hyg. 49:214-221.
37.	Wilson, S. M., and J. C. Clegg. 1991. Sequence analysis of the S RNA of the African arenavirus Mopeia: an unusual secondary structure feature in the intergenic region. Virology 180:543-552[CrossRef][Medline].
38.	Wright, K. E., M. S. Salvato, and M. J. Buchmeier. 1989. Neutralizing epitopes of lymphocytic choriomeningitis virus are conformational and require both glycosylation and disulfide bonds for expression. Virology 171:417-426[CrossRef][Medline].
39.	Wright, K. E., R. C. Spiro, J. W. Burns, and M. J. Buchmeier. 1990. Post-translational processing of the glycoproteins of lymphocytic choriomeningitis virus. Virology 177:175-183[CrossRef][Medline].
40.	Wulff, H., and J. V. Lange. 1975. Indirect immunofluorescence for the diagnosis of Lassa fever infection. Bull. W. H. O. 52:429-436[Medline].
41.	Wulff, H., B. M. McIntosh, D. B. Hamner, and K. M. Johnson. 1977. Isolation of an arenavirus closely related to Lassa virus from Mastomys natalensis in south-east Africa. Bull. W. H. O. 55:441-444[Medline].