Abstract
Lassa virus (LASV) is the causative agent of Lassa fever, an often-fatal hemorrhagic disease that is endemic in West Africa. Seven genetically distinct LASV lineages have been identified. As part of CEPI’s (Coalition for Epidemic Preparedness Innovations) Lassa vaccine development program, we assessed the potential of the human immune system to mount cross-reactive and cross-protective humoral immune responses to antigens from the most prevalent LASV lineages, which are lineages II and III in Nigeria and lineage IV in Sierra Leone. IgG and IgM present in the blood of Lassa fever survivors from Nigeria or Sierra Leone exhibited substantial cross-reactivity for binding to LASV nucleoprotein and two engineered (linked and prefusion) versions of the glycoproteins (GP) of lineages II–IV. There was less cross-reactivity for the Zinc protein. Serum or plasma from Nigerian Lassa fever survivors neutralized LASV pseudoviruses expressing lineage II GP better than they neutralized lineage III or IV GP expressing pseudoviruses. Sierra Leonean survivors did not exhibit a lineage bias. Neutralization titres determined using LASV pseudovirus assays showed significant correlation with titres determined by plaque reduction with infectious LASV. These studies provide guidance for comparison of humoral immunity to LASV of distinct lineages following natural infection or immunization.
Similar content being viewed by others
Introduction
Lassa virus (LASV) is the causative agent of Lassa fever, an often fatal viral hemorrhagic fever (VHF). Cases are reported year round in Nigeria, Sierra Leone, Liberia, Guinea and other West African countries, with peak incidence in the dry season. Case-fatality rates (CFRs) among hospitalized Lassa fever patients vary from approximately 25% in Nigeria1,2 to greater than 60% in Sierra Leone3. Subclinical infections appear to be common4,5. A variety of factors, including differential virulence of LASV strains and variations in human genetic susceptibility, immune responses or patient care, may account for the range of CFRs. The main reservoir of LASV is Mastomys natalensis, the natal multimammate rat (or mouse), an abundant peridomestic rodent6,7,8. Additional rodent reservoirs or intermediate hosts have been discovered8,9. While human-to-human transmission can occur, especially in hospital settings, most infections occur by exposure to rodent excreta or during preparation of rodents for food. Accurate estimates for the number of Lassa fever cases and deaths are not possible because of the limited availability of epidemiological data. Supportive care including management of fluid and electrolyte balance can improve survival10,11. The only available treatment is the off-label use of the nucleoside drug ribavirin12. There is currently no approved Lassa fever vaccine. Lassa fever has been recognized by the World Health Organization (WHO) as an important threat to global health that is in urgent need of countermeasure development13. The Coalition for Epidemic Preparedness Innovations (CEPI) has prioritized the accelerated development of a Lassa fever vaccine14,15. CEPI has also initiated an epidemiological study in five West African countries as part of their strategy to facilitate vaccine development efforts16.
LASV is a single-stranded RNA virus in the family Arenaviridae (Order: Bunyavirales)17. Its genome consists of two ambisense segments encoding four proteins: Z (zinc, matrix), L (polymerase), NP (nucleoprotein), and GPC (glycoprotein complex)18. GPC is post-translationally cleaved into glycoprotein 1 (GP1), glycoprotein 2 (GP2), and a stable signal peptide (SSP) that trimerize on the virion surface19. There are currently seven proposed genetically distinct LASV lineages (lineages I–VII) distributed throughout West Africa20. Phylogenetic analyses of the highly divergent LASV genomes suggest that the virus has been circulating in Nigeria for over a thousand years, followed by a more recent spread across West Africa21. LASV lineages and sublineages (clades) cluster geographically suggesting that once established in a region the virus remains stably separated in the rodent reservoirs22,23,24. The initial isolate of LASV representing lineage I has been detected in northern Nigeria25, but has rarely been observed in recent samplings20,23,26. lineages II and III are the most common lineages in Nigeria and are found in the southern and central regions, respectively27,28. Recently, lineages and phylogenetic clusters in Nigeria have been geographically mapped at a higher resolution20. Within lineage II five sublineages were distinguishable. Seven sublineages were distinguishable in lineage III. Lineage IV LASV, including the prototypical Josiah strain commonly used in laboratory studies, is present in Sierra Leone, Liberia and Guinea21,29. LASV lineage V is found in Mali and Ivory Coast30,31. LASV isolates from the Hylomyscus pamfi rodent trapped in Nigeria8 and from a nosocomial outbreak in Togo32 have been proposed to represent new lineage VI and lineage VII, respectively.
Development of Lassa fever countermeasures is potentially challenged by the high genetic diversity of LASV14,33. The genetic variability of LASV could produce differences in the antigenicity of LASV proteins34,35,36. It is unclear whether a vaccine produced with antigens of LASV from a particular lineage will induce a human immune response that is protective against LASV of other lineages. Most Lassa vaccines in development have employed antigens of the Josiah strain (LIV) of LASV37,38. As a component of CEPI’s efforts to facilitate and accelerate Lassa vaccine development, serum or plasma from Lassa fever survivors living in different geographical areas and thus representing different lineages has been collected through a contractual arrangement between CEPI and the Viral Hemorrhagic Fever Consortium (VHFC). Vaccine developers are being supplied with panels consisting of samples with high, medium and low titres from survivors of infection with different LASV lineages. These samples in addition to Lassa negative control samples are being used to establish and fine-tune immunoassays for vaccine development.
A suite of Lassa fever diagnostic immunoassays has been developed based on LASV recombinant proteins, including antigen- IgG- and IgM-capture ELISA and rapid diagnostic tests (RDTs)39,40,41,42,43. The antibody-capture ELISA has demonstrated the capability to detect IgM seropositivity and subsequent class-switching to IgG seropositivity in Lassa fever cases41 and has proven useful in surveillance and vaccine studies30,44,45,46,47. These prior assays were configured with recombinant antigens based on the lineage IV LASV Josiah strain39. To quantify seroreactivity to genetically diverse LASV strains recombinant NP, GP and Z proteins representing additional prominent West African lineages, Nigerian lineages II and III, have been cloned and molecularly characterized. Representative strains from lineage II (LASV237-Nigeria-2010H) and lineage III (LASV-Nig08-A18-Nigeria-2008H) were chosen for molecular cloning and expression based on their approximate median divergence from the corresponding lineage root27. Here, we assess the ability of antibodies from Nigerian Lassa fever survivors exposed to LASV lineages II and III and Sierra Leonean Lassa fever survivors exposed to LASV lineage IV to cross-react with recombinant NP, GP and Z proteins representing LASV of these divergent lineages and to cross-neutralize pseudoviruses expressing LASV GPC of these divergent lineages.
Results
IgG and IgM capture ELISA based on recombinant antigens representing LASV of divergent lineages
Recombinant NP N- and C-terminal domains and Z proteins from lineages II–IV were expressed in codon-optimized E. coli strains and purified. The proteins were then visualized on SDS-PAGE and immunoblotting for identity and purity for use as coating antigens for ELISA (Fig. 1A,B, Fig. S1A,B). The NP N- and C-terminal domains from the three lineages are homogenous monomers (Fig. 1A). Minor levels of contaminants and breakdown products are present in the purified NP preparations. In contrast, Z proteins exhibit multimerization; lineage II Z protein forms higher order multimers than Z proteins of lineages III and IV (Fig. 1B).
Two forms of the LASV glycoprotein are utilized in the current studies. Linked LASV GP tethers the GP1 and GP2 subunits together via a flexible linker and is designed to present both pre- and post-fusion epitopes (Fig. 1C, Fig. S1C–F, Fig. S2A). Linked GP has been successfully used for the identification and characterization of anti-LASV GP antibodies from human survivors of Lassa virus infection48. Prefusion, stabilized GP is a disulphide linked LASV GP used in the determination of the only pre-fusion structures available for any arenavirus glycoprotein trimer49,50. Pre-fusion GP (Pf-GP) contains only the prefusion form (Fig. 1D, Fig. S1C–F, Fig. S2B) and is best suited for detection of serum/plasma IgG and IgM against the complex, neutralizing, domain-spanning epitopes that are a desired product of vaccination efforts. Linked GP and Pf-GP are expressed in Drosophila S2 cells and purified via streptactin-affinity chromatography. Following strepII tag removal with enterokinase, the GPs are further purified by size-exclusion chromatography (SEC). Both linked GP and Pf-GP show appropriate reactions with human monoclonal antibodies (huMAbs) that react with divergent epitopes (Fig. S2C,D)48.
A mixture of NP or Pf-GP GP from LASV lineages II, III, and IV immobilized in the ELISA microwell plates was used for the direct absorption of LASV-specific IgM or IgG antibodies from serum or plasma of Lassa fever survivors. Pan-Lassa NP or Pf-GP IgG- and IgM-capture ELISAs exhibited significant differences in reactivity by serum from Sierra Leone Lassa fever survivors compared to serum from United States controls (healthy blood donors) (Fig. 1E). IgG seroreactivity to NP and Pf-GP was higher than IgM seroreactivity in the Sierra Leonean sample cohort. Additional studies on validation of the Pan-Lassa antibody and antigen capture assays is presented elsewhere51.
Nigerian and Sierra Leone Lassa fever survivors reactivity to LASV recombinant antigens
During Jan. 14th–29th, 2019 laboratory staff of Redeemer’s University (RUN), Ede State VHF Laboratory in Nigeria and the Kenema Government Hospital (KGH) VHF Laboratory in Sierra Leone, with training and assistance from Zalgen Labs personnel, conducted studies on seroreactivity to LASV recombinant proteins. Nigerian laboratory personnel from Irrua Specialist Teaching Hospital (ISTH) in Edo State, Federal Medical Center (FMC) in Owo, Ondo State, FMC Abakaliki in Ebonyi State and Ibadan U. were trained to use the ReLASV immunoassays. Lassa fever survivor, contacts, and suspected Lassa fever samples were obtained from ISTH, FMC Owo, and FMC Abakaliki for the study. At KGH post-acute, convalescent and Lassa fever survivor samples were selected from a biorepository of samples obtained from other on-going studies.
Samples were screened using the ReLASV Pan-Lassa NP IgG/IgM ELISA Kit and the prototype ReLASV Pan-Lassa Prefusion GP IgG/IgM ELISA Kit. In Nigeria 140 plasma or serum samples were screened at a 1:100 sample dilution using mixed NP or mixed Prefusion GP ELISAs for IgG/IgM reactivity (Fig. 2). In Sierra Leone 80 plasma and serum samples were selected and screened at a 1:100 sample dilution for IgG and/or IgM reactivity. A range of reactivities to LASV NP and GP was observed in the prescreening of samples from both Sierra Leonean and Nigerian subjects. With the exception of IgM in Sierra Leoneans the correlations between NP and GP reactivity were significant. While many samples had both strong IgG and/or IgM reactivity to both NP and GP other samples had low reactivity to one protein or the other. Linear correlations between NP and GP reactivity in both Sierra Leonean and Nigerian subjects for IgG and IgM had slopes that diverged from 1 (0.10x to 0.44x) indicating lower overall reactivity to GP.
Binding to antigens encoded by LASV of lineages II, III, and IV
We next assessed a subset of plasma or serum samples from Nigerian (n = 40) and Sierra Leonean (n = 61) with a range of immune responses (from high to low or negative) using ELISAs coated with single antigens, NP, linked GP, Pf-GP, or Z representing LASV of lineages II–IV. Results of the binding studies using a 1:100 sample dilution are presented as scatterplots of the absorbance with linear correlations (Fig. 3). Overall substantial cross-reactivity for IgG binding exists between both NP and linked GP or Pf-GP of LASV of lineages II–IV (Fig. 3A–F). The slopes for all cross-reactivity comparisons were near 1 (range from 0.80x to 1.15x) with the exception of lineage II Pf-GP versus lineage IIwI Pf-GP (slope = 0.49x, Fig. 3E). Binding of plasma or serum IgG to NP and both forms of GP across lineages gave significant R2 values (> 0.80, P < 0.001) indicating that there were few samples that bound strongly to protein of one lineage, but weakly to the protein from another lineage.
In contrast to the results with NP and GP we found that there was less IgG cross-reactivity between Z proteins of lineages II–IV (Fig. 3G,H). Slopes of 0.82x and 0.57x were observed for comparison of binding of lineage II Z versus lineage III Z for Nigerian and Sierra Leonean samples, respectively. However, for the comparison of lineage IV Z versus lineage II Z the slopes were 0.27x and 0.39x indicating a bias for binding of the lineage II protein. Similar results were obtained with the Z reactivity of Sierra Leonean plasma samples. The differences in the Z protein multimerization may contribute to these differences. Lineage II Z tended to form higher order multimers that may display epitopes more effectively (Fig. 1B). Z is a small protein with a limited number of epitopes that appear to be poorly cross-reactive. Similar correlations for IgG cross-reactivity to NP, linked GP, Pf-GP, or Z representing LASV of lineages II–IV were obtained using endpoint titres rather than quantifying absorbance at a 1:100 dilution (Fig. S3). Typical examples of the reactivities in serial dilution is shown for two Nigerian subjects and one Sierra Leonean subject (Fig. 4). Endpoint titres to LASV NP were typically higher than those to either linked GP, Pf-GP or Z. IgM cross-reactivity among lineages II-IV followed a similar pattern to that observed with IgG (Fig. 5). Class switching from IgM to IgG reactivity is delayed in Lassa fever survivors, which is reflected in the high levels of IgM detected41.
Cross-neutralization studies with LASV pseudoviruses expressing GPC of LASV lineages II–IV
Pseudoviruses expressing the GPC of LASV from lineages II, III or IV were employed to assess the ability of antibodies from Lassa fever survivors to cross-neutralize different lineages of LASV (Fig. 6). The average reciprocal 50% neutralization titres were higher in Nigerians than in Sierra Leoneans (Fig. 6A–C). Neutralization by Nigerian samples was biased towards LASVpv lineage II. Reciprocal 50% neutralization titres against LASVpv lineage II were higher than titres against LASVpv expressing lineage III or IV in 23/30 (77%) Nigerian subjects (Fig. 6A). This does not appear to be due to LASVpv lineage II being easier to neutralize by human antibodies. 6/32 Sierra Leonean subjects (13%, p < 0.0001 Fisher’s exact test) had reciprocal 50% neutralization titres against LASVpv lineage II that were higher than the titres for LASVpv lineage III or IV (Fig. 6B). Samples from Sierra Leoneans did not exhibit a strong bias to neutralization of LASVpv lineage IV, their cognate lineage. Only 7/32 samples from Sierra Leonean subjects had reciprocal 50% neutralization titres against LASVpv lineage IV that were higher than those against LASVpv lineage II or III. Eleven of 32 Sierra Leonean samples neutralized LASVpv lineage II or III as well or better than LASVpv LIV. In contrast, only 2/30 samples from Nigerian subjects neutralized LASVpv lineage III or IV as well as they neutralized LASVpv lineage II (p < 0.01).
Neutralization curves for LASV expressing GPC of LII–IV had similar slopes even when there were differences in the reciprocal 50% neutralization titres for the distinct lineages (Fig. 6C–E). Some samples failed to neutralize 100% of any lineage at any dilution tested (Fig. 6C). The failure to neutralize 100% of viruses even at high antibody levels has been noted in prior monoclonal antibody studies50. Certain dilutions of serum or plasma resulted in increased infectivity of the pseudovirus (asterisks in Fig. 6D,E). The possible presence of enhancing antibodies in serum from Lassa fever survivors has previously been reported52.
Cross-neutralization in neutralizing responses by Nigerian and Sierra Leonean plasma or serum samples was examined using linear correlations (Fig. 7). This analysis confirmed the bias for neutralization of LASVpv lineage II by Nigerian samples (Fig. 7A,C,E). In contrast, bias for neutralization of LASVpv of lineage IV was not demonstrated by Sierra Leonean samples (Fig. 7B,D,F).
Comparison of recombinant binding assays to pseudovirus neutralization assays and plaque reduction assays using BSL-4 LASV
A subset of samples (n = 20) was further evaluated in additional neutralization assays and these results were compared to the results of ELISA binding assays (Fig. 8). For this subanalysis plaque reduction neutralization tests (PRNT) at Biosafety Level-4 (BSL-4) were compared to 50% binding titres using pseudoviruses expressing GPC or binding to recombinant Pf-GP. Infectious LASV of lineage II and lineage IV showed a significant correlation (R2 = 0.73, P < 0.001) when compared in PRNT (Fig. 8A). A comparison of neutralization titres using LASVpv expressing either the GPC of LASV lineage II or IV on an HIV-1 core also showed a significant correlation (R2 = 0.30, P = 0.012). LASVpv neutralization assays were more sensitive than the PRNT, however, there were significant correlations between these neutralization assays. PRNT using LASV of LII showed a significant correlation (R2 = 0.40, P = 0.003) to neutralization titres using LASVpv expressing lineage II GPC (Fig. 8C). Similarly, PRNT using LASV lineage IV showed a significant correlation (R2 = 0.53, P < 0.001) to neutralization titres using LASV expressing lineage IV GPC. Although less sensitive, LASVpv using a vesicular stomatitis virus core showed significant correlations with neutralization of LASVpv using a HIV core (R2 = 0.40, P = 0.001) and with PRNT (R2 = 0.37, P = 0.004) (Fig. S4). PRNT titres were also lower than the binding titres to LASV Pf-GP. Significant correlations between PRNT titres and binding titres to LASV Pf-GP of lineage II (Fig. 8E) or lineages IV (Fig. 8F) were not observed. Likewise, significant correlations between pv neutralization titres and binding titres to LASV Pf-GP of lineage II (Fig. 8G) or lineages IV (Fig. 8H) were not observed. These results are expected since the majority of antibodies to LASV GP are non-neutralizing48.
Discussion
LASV infection induces IgG or IgM that cross-reacts with NP or GP of multiple lineages
As an initial step to evaluate the cross-reactivity potential of Lassa vaccine antigen(s) to cover different lineages, we assessed the ability of the human immune system to mount cross-reactive humoral immune responses during natural infections. Humoral responses to LASV proteins by Nigerian and Sierra Leonean Lassa fever survivors are heterogeneous. Lassa survivors may show IgG and/or IgM reactivity to NP and GP or reactivity to only NP or GP. NP, linked-GP, and Pf-GP antigens representing LASV lineages II- IV were shown to be reactive to LASV-specific antibodies produced by both Nigerian and Sierra Leonean survivors. These results suggest that infection with LASV induces IgG or IgM that is able to effectively cross-react with NP or GP of multiple lineages. Reactivity to Z was variable and there was minimal cross-reactivity between Z of lineages II-IV.
These results differ from a previous study that reported that anti-LASV antibodies preferentially react with the antigens of virus strains present in the local areas34. Different techniques were used in this prior study including an indirect immunofluorescence assay (IFA) employing cells infected with different LASV strains and a reverse ELISA that utilized lysates from cells infected with different LASV strains. It is possible that differences in the sensitivities of these assays compared to the recombinant antigen ELISAs account for the more extensive cross-reactivity observed in the current study.
Heterogeneous induction of LASV cross-neutralizing antibodies by Lassa fever survivors
We also assessed the ability of natural LASV infection to induce cross-neutralizing antibodies. As in previous studies48, we observed that not all Lassa fever survivors produce LASV neutralizing antibodies. Neutralizing antibody titres when present are lower than binding titres, which is expected since most antibodies to the LASV GP do not neutralize48. Infection with LASV lineage II in Nigerians induces strong neutralizing titres to LASVpv lineage II, but neutralization titres to LASVpv lineages III and IV were lower. In contrast, infection with LASV lineage IV in Sierra Leoneans generally induces cross-reactive neutralizing immune responses to LASVpv of lineage II and III . These results suggest that GP of LASV lineage IV may be more effective than GP of LASV lineage II at presenting epitopes that induce broadly neutralizing antibodies.
Guidance for procedures to quantify humoral aspects of vaccine-induced immunity to LASV of distinct lineages
Recombinant LASV NP of lineages II–IV produced in E. coli appear to be appropriate to assess IgG and IgM responses. NP is not expressed on the surface of the LASV virion or infected cells. Therefore, it is unlikely that anti-NP humoral immune responses are involved in protection from LASV infection. However, anti-NP antibodies can serve as a marker for exposure to infectious LASV either prior to or during Lassa vaccine trials conducted in West Africa. NP could be involved in protective cellular immune response to LASV53,54,55. Most of the LASV vaccines in the CEPI portfolio, with the exception of the measles vectored vaccine do not express LASV NP14,38. Recombinant Pan-Lassa linked and Pf-GP IgG/IgM ELISA kits are capable of accurate detection of LASV GP-specific IgG and IgM antibody titres. The Pan-Lassa IgG/IgM ELISA has demonstrated sensitivity to Lassa fever in both Sierra Leone and Nigeria. This study confirms that the Pf-GP construct is a superior reagent for detecting serological responses to LASV GP, which are of prime importance for future vaccine studies.
A LASV pseudovirus platform was more sensitive for quantifying neutralization than PRNT, which is based on replication competent LASV in BSL-4. These findings agree with previous studies that compared several virus neutralization platforms in the evaluation of monoclonal antibodies against LASV48. Envelope glycoprotein levels, mechanisms of viral entry, transport, fusion, uncoating, pre-nuclear localization of replicative viral nucleic acids, tropism, and specificity versus passive incorporation of heterologous glycoproteins into particles may all contribute in some degree and affect the sensitivity of each neutralization assay platform. Given the imperfect correlation caution, should be employed when extrapolating the results from pseudovirus platforms to replication competent LASV. While a sensitive pv assay is useful for preclinical vaccine development, comparison of the results to BSL-4 assays would be prudent for vaccine trials.
Challenges in developing Lassa fever correlates of protection
Correlates of Protection (CoP) for Lassa fever and for Lassa fever vaccines have yet to be defined. These CoP might also be different. Cellular immunity appears to be the primary effective arm of the adaptive immune response against LASV during natural infection56. High-titred anti-LASV IgG and virus can be simultaneously present in the blood of human Lassa fever patients3. Only a subset of Lassa fever survivors produce LASV neutralizing antibodies, and production of neutralizing antibodies is delayed months into convalescence48,57. In contrast to the situation during natural infection, passive serum transfer therapy from survivors protects against disease and death in animal models58,59. However, the ability of serum to neutralize LASV of particular strains determined the effectiveness of passive antibody transfer in treating LASV-infected nonhuman primates59. Furthermore, neutralizing huMAbs have shown high efficacy in passive immunotherapy of LASV-infected guinea pigs and NHPs60,61,62. In NHP models of lethal Lassa fever infection, treatment with cocktails of selected neutralizing huMAbs completely protected animals even when the first treatment was delayed until eight days post infection, a time when severe disease and dysregulation were clinically evident61. Moreover, this huMAb cocktail protected NHPs in late stage Lassa fever, highlighting the relevance of humoral immunity in protecting against lethal Lassa fever60,61. Even though neutralizing antibodies are not involved in clearing LASV during natural human infection, they could be important for an induced protective immune response. These studies educate future approaches toward evaluation of the quantity and quality of the humoral response generated by vaccination with LASV specific antigens, namely the viral glycoprotein. The conformation and presentation of the viral glycoprotein is critical to the level of protection63. Previous studies demonstrated that multiple doses of inactivated LASV failed to protect NHP from lethal challenge, despite induction of a substantial antibody response64. It remains to be determined if protective neutralizing antibodies could be elicited by vaccination, perhaps with engineered forms of LASV GP63.
Induction of cross-protective immune responses by Lassa vaccines
A limited number of LASV vaccine studies have evaluated whether a cross-protective immune response is induced. Safronetz and coworkers65 demonstrated that recombinant VSV expressing GP of LASV LIV (Josiah) protects guinea pigs from infection and disease following challenge with LASV isolates originating from Liberia (lineage IV), Mali (lineage V) and Nigeria (lineage I). A recent study in nonhuman primates found that immunization with VSV expressing GPC of LIV (Josiah) as part of a quadrivalent vaccine against Ebola, Sudan, Marburg and Lassa viruses induces a protective immune response against LASV of lineage II46. Both cellular immune response and neutralizing antibodies against LASV were induced by the quadrivalent vaccine. Most neutralizing human monoclonal antibodies derived from Sierra Leonean Lassa fever survivors were effective at neutralizing pv expressing LASV GP of divergent lineages (I–IV)48. Coupled with the current observation that natural infection with lineage IV viruses (but not lineage II LASV) induces a broad cross-reactive and cross-neutralizing response suggests that it may be possible to induce an immune response with a LASV Josiah (lineage IV) GP-based vaccine that will be cross-protective for infections with LASV of other lineages. Further study on the differences in the induced immune responses to LASV in Nigerians and Sierra Leoneans is warranted and has important implications for vaccine development.
Limitations to the current study
Representative strains from each of the three most prevalent lineages (II–IV) were selected, but a variety of sublineages (clades) exist within each lineages20,23. Due to the high heterogeneity among LASV lineages, continuous monitoring of its mutational spectrum and evolutionary change will be critical for maintaining effective vaccines. The large number of assays employed in this study required the use of a limited number of samples with sufficient volume to comprehensively evaluate binding and neutralizing activities.
Implications of Lassa diversity for vaccine development
The genetic diversity of LASV presents potentially a major challenge to development of Lassa fever vaccines14. A Lassa vaccine or vaccines should provide protective immunity against LASV from the multiple lineages present across West Africa. A variety of Lassa vaccines are under development14,15,38. The different vaccine constructs and delivery platforms will present LASV antigens in different ways than natural infection. This study of cross-reactivity and cross-neutralization is based on natural infection to evaluate the cross-protective potentials of Lassa proteins as vaccine candidates. More relevant for vaccine evaluation is of course studies of sera after vaccination and their cross-neutralizing/functional capacity that can be evaluated and compared among different vaccine candidates. Such studies should be done in a similar fashion to the present study, but with sera from vaccinees. Human trials of Lassa fever vaccines based on a protein (or proteins) of a single lineage, such as LASV Josiah (lineage IV), should quantify cross-reactive and cross-neutralizing immune responses to LASV proteins of other lineages and then, of even larger importance, how well the vaccinee sera neutralizes wild-type viruses from different lineages.
Methods
Recombinant protein representing LASV lineages II–IV
LASV NPs are produced in E. coli using strains engineered for stability and overexpression of genes containing rare codons39. Recombinant LASV NPs are initially purified via affinity chromatography, and polished by ion exchange (IEX) chromatography and size exclusion chromatography (SEC), as appropriate. The proteins are then visualized on SDS-PAGE for purity and subjected to Western blot for identity and purity. Recombinant linked and Pf-GP are produced from stable Drosophila S2 cell lines, under serum-free conditions49. Resulting proteins are purified via streptactin affinity columns and are > 95% pure following this single step purification. Z proteins are HIS-tagged and purified on Ni–NTA columns.
IgM and IgG ELISA
The ReLASV Pan-Lassa NP-specific IgM and IgG ELISA utilize microwell plates coated with a mixture of recombinant nucleoprotein NP from lineages II, III, and IV and performed according to the manufacturer’s recommendations66. ELISAs utilizing recombinant LASV antigen (NP, linked GP, Pf-GP and Z from LII–IV were performed similarly. LASV antigens (either singular or combined lineages) were coated at 200 to 500 ng/well in 96-well microtiter plates (Nunc A/S, Denmark) using Carb-Bicarb buffer, pH 9.6. After antigens were immobilized, the coated microwell plates were stabilized using proprietary blocking solution, dried and packaged with desiccant.
For the ELISA, lyophilized human monoclonal calibrator and negative control plasma were reconstituted with 0.25 mL laboratory-grade water. Calibrator was diluted 1:101 (0.01 mL/1.0 mL followed by four threefold serial dilutions to create a calibration curve for antibody concentration estimation. For Z protein ELISA screening a well characterized LF convalescent sample with sufficient anti-Z antibody titer was used as assay Reference and similarly diluted to create Reference curve dilutions. LF patient samples were diluted 1:101 in provided Sample Diluent prior to assay. Calibrator (or Reference) dilutions, diluted Negative Control and patient samples were transferred (0.1 mL/well) in duplicate wells. Microwell plates were incubated at ambient temperature (18–30 °C) for 30 min. Microwell plates were washed four times with PBS-Tween wash buffer. Anti-Hu IgG or IgM-horseradish peroxidase conjugate reagent (Jackson ImmunoResearch, West Grove, PA, USA) was added to microwell plate (0.1 mL/well) followed by a 30 min incubation at ambient temperature. After repeating the PBS-Tween wash, 3,3′,5,5′-Tetramethylbenzidine (TMB) Substrate (Moss Biotech Inc., Hanover, Maryland, USA) was added to each well (0.1 mL/well). The TMB substrate was incubated for 10 min followed by addition (0.1 mL/well) of Stopping Solution (0.36 N Sulfuric Acid). Developed ELISA plates were read at 450 nm (with 650 nm reference). IgG or IgM estimated concentration was calculated from Calibrator/Reference Curve plot using 4-paramenter logistic fit. Negative cut-off was determined as the 95th percentile distribution of the study population.
Pseudovirus assay
LASV pseudoviruses (LASVpv) were generated by co-transfection of HEK293T cells with LASV GPC plasmids and pSG3Denv encoding the envelope-deficient core of HIV-1 as previously described48. The pseudoviruses express LASV GPC of different lineages on a particle containing the core proteins of HIV and are capable of a single round of replication. LASV pseudoviruses (LASVpv) capable of a single round of replication were produced by co-transfection of HEK293T cells with LASV GPC plasmids (lineages II–IV) and pSG3Denv, encoding the envelope-deficient core of HIV-1. These LASVpv were assayed in TZMbl cells, a HeLa cell derivative that contains integrated luciferase and β-galactosidase genes under regulatory control of an HIV-1 long terminal repeat, which is activated by HIV-1 Tat after virion entry67. The neutralizing activities of Sierra Leonean and Nigerian plasma samples were determined by incubating mixtures of LASVpv stocks at predetermined optimal dilutions with serial dilutions of each plasma sample. Luciferase activity in the cultures was measured at 48 or 72 h after inoculation using a commercially available kit (Promega BriteGlo). Luminescence was measured with a Wallac 1,420 Multilabel Counter (PerkinElmer, Waltham, MA). Studies were also undertaken with LASVpv expressing the core proteins of vesicular stomatitis virus.
Plaque reduction neutralization test
To assess neutralizing activity of plasma or serum samples, a standard PRNT with infectious LASV was performed under BSL-4 conditions48,61,62,68. 100 plaque-forming units of LASV were incubated for 60 min with serial twofold dilutions of each sample in Earle’s Minimal Essential Medium, 1% Pen/Strep and glutamax containing 10% guinea pig complement (Rockland, Limerick, PA). After incubation these reaction mixtures were assayed for residual infectivity (plaque-forming units). The mixture was used to inoculate Vero 76 cells for 60 min. The inoculum was removed and cells were overlaid with agar-containing medium and incubated for 4–6 days at 37 °C. Cells were stained with neutral red for 24 h and plaques were counted. End-point titres were determined through standard 4-parameter logistic regression analysis and represented as the dilution of antibody that neutralized 50% of the plaques. For these assays we used a low-passage LASV Josiah virus stock (lineage IV), which was kindly provided by Tom Ksiazek (University of Texas Medical Branch-Galveston, TX), and originated from CDC Lassa-Josiah CDC number 057562. This strain was originally isolated from a human clinical specimen that was passed once in Vero cells and twice in Vero E6 cells. The study material was the second passage of a lineage II LASV isolate (0043/LV/14) originated from human serum collected from a 30-year-old male patient in Edo State, Nigeria who died in January of 201446.
Data analysis and statistical methods
Laboratory data, including absorbance values were expressed as mean ± standard error of the mean.Data were analyzed in their individual forms and were not transformed.Two-sample t testswere used to compare absorbance measures between Lassa fever case and control groups.Ordinary linear regression models were used to compare continuous measures between lineage groups and optical density values between ELISA approaches.Pearson’s correlation coefficients or coefficients of determination were used to quantify the magnitude of linear association where linear regression approaches were used.Data was analyzed using Microsoft Excel (version 16.39, Microsoft, Redmond, WA), JMP software (version 13.0.0, SAS Institute, Inc., Cary, NC) and Prism (version 6.07, GraphPad Software, Inc., San Diego, CA). Figures were compiled using Adobe Illustrator (version 15.1.0, San Jose, CA). Analyses were two-tailed with a significance threshold set at p < 0.05.
Ethics approvals
All methods were carried out in accordance with relevant guidelines and regulations, including the Declaration of Helsinki. All subjects enrolled in this study and/or their legal guardians provided written informed consent. Human subjects testing, incuding the use of excess clinical samples (deidentified, surplus diagnostic samples) under a waiver of consent, was approved by the Tulane University Institutional Review Board (191330), the Nigerian National Health Research Ethics Committee and Irrua Specialist Teaching Hospital (ISTH/HREC/20170915/22) and the Sierra Leone Ethics and Scientific Research Committee (070716). Plasma or serum samples were obtained from Nigeria Lassa fever survivors, contacts, and suspected Lassa fever cases presenting to ISTH, FMC Owo, and FMC Abakaliki between November 2017 and January 2019. In Sierra Leone plasma or serum samples from post-acute, convalescent and Lassa fever survivors were selected from a biorepository of samples collected between October 2012 and January 2014 and between January 2016 and November 2018. Only Nigerian or Sierra Leonean medical personnel staff were involved in the administration of health care to suspected Lassa fever patients. All medical decisions, including whether or not to administer ribavirin to patients, were at the sole discretion of the attending physicians.
References
Akpede, G. O. et al. Caseload and case fatality of Lassa fever in Nigeria, 2001–2018: A specialist center’s experience and its implications. Front. Public Health 7, 170. https://doi.org/10.3389/fpubh.2019.00170 (2019).
Ilori, E. A. et al. Epidemiologic and clinical features of Lassa fever outbreak in Nigeria, January 1–May 6, 2018. Emerg. Infect. Dis. 25, 1066–1074. https://doi.org/10.3201/eid2506.181035 (2019).
Shaffer, J. G. et al. Lassa fever in post-conflict Sierra Leone. PLoS Negl. Trop. Dis. 8, e2748. https://doi.org/10.1371/journal.pntd.0002748 (2014).
McCormick, J. B. Epidemiology and control of Lassa fever. Curr. Top Microbiol. Immunol. 134, 69–78 (1987).
Arnold, R. B. & Gary, G. W. A neutralization test survey for Lassa fever activity in Lassa, Nigeria. Trans. R. Soc. Trop. Med. Hyg. 71, 152–154 (1977).
Monath, T. P., Newhouse, V. F., Kemp, G. E., Setzer, H. W. & Cacciapuoti, A. Lassa virus isolation from Mastomys natalensis rodents during an epidemic in Sierra Leone. Science 185, 263–265 (1974).
Lecompte, E. et al. Mastomys natalensis and Lassa fever, West Africa. Emerg. Infect. Dis. 12, 1971–1974 (2006).
Olayemi, A. et al. New hosts of the Lassa virus. Sci. Rep. 6, 25280. https://doi.org/10.1038/srep25280 (2016).
Yadouleton, A. et al. Lassa virus in pygmy mice, Benin, West Africa, 2016–2017. Emerg. Infect. Dis. https://doi.org/10.3201/eid2510.180523 (2019).
Okokhere, P. et al. Clinical and laboratory predictors of Lassa fever outcome in a dedicated treatment facility in Nigeria: A retrospective, observational cohort study. Lancet. Infect. Dis 18, 684–695. https://doi.org/10.1016/s1473-3099(18)30121-x (2018).
Duvignaud, A. et al. Lassa fever clinical course and setting a standard of care for future randomized trials: A protocol for a cohort study of Lassa-infected patients in Nigeria (LASCOPE). Travel. Med. Infect. Dis. https://doi.org/10.1016/j.tmaid.2020.101557 (2020).
Eberhardt, K. A. et al. Ribavirin for the treatment of Lassa fever: A systematic review and meta-analysis. Int. J. Infect. Dis. https://doi.org/10.1016/j.ijid.2019.07.015 (2019).
Mehand, M. S., Al-Shorbaji, F., Millett, P. & Murgue, B. The WHO R&D Blueprint: 2018 review of emerging infectious diseases requiring urgent research and development efforts. Antiviral Res. 159, 63–67. https://doi.org/10.1016/j.antiviral.2018.09.009 (2018).
Bernasconi, V. et al. Developing vaccines against epidemic-prone emerging infectious diseases. Bundesgesundheitsblatt, Gesundheitsforschung, Gesundheitsschutz 63, 65–73. https://doi.org/10.1007/s00103-019-03061-2 (2020).
Gouglas, D., Christodoulou, M., Plotkin, S. A. & Hatchett, R. CEPI: Driving progress towards epidemic preparedness and response. Epidemiol. Rev. https://doi.org/10.1093/epirev/mxz012 (2019).
Coalition for Epidemic Preparedness Innovations. Preparing for Lassa vaccine trials with targeted epidemiology studies. https://cepi.net/get_involved/cfps/ (2019).
Abudurexiti, A. et al. Taxonomy of the order Bunyavirales: Update 2019. Arch. Virol. 164, 1949–1965. https://doi.org/10.1007/s00705-019-04253-6 (2019).
Oldstone, M. B. Arenaviruses. II. The molecular pathogenesis of arenavirus infections. Introduction. Curr. Top Microbiol. Immunol. 263, 5–12 (2002).
Oldstone, M. B. Arenaviruses. I. The epidemiology molecular and cell biology of arenaviruses Introduction. Curr. Top Microbiol. Immunol. 262, 5–12 (2002).
Ehichioya, D. U. et al. Phylogeography of Lassa virus in Nigeria. J. Virol. https://doi.org/10.1128/jvi.00929-19 (2019).
Andersen, K. G. et al. Clinical sequencing uncovers origins and evolution of Lassa virus. Cell 162, 738–750. https://doi.org/10.1016/j.cell.2015.07.020 (2015).
Bowen, M. D. et al. Genetic diversity among Lassa virus strains. J.. Virol. 74, 6992–7004 (2000).
Siddle, K. J. et al. Genomic analysis of Lassa virus during an increase in cases in Nigeria in 2018. N. Engl. J. Med. 379, 1745–1753. https://doi.org/10.1056/NEJMoa1804498 (2018).
Kafetzopoulou, L. E. et al. Metagenomic sequencing at the epicenter of the Nigeria 2018 Lassa fever outbreak. Science 363, 74–77. https://doi.org/10.1126/science.aau9343 (2019).
Buckley, S. M. & Casals, J. Lassa fever, a new virus disease of man from West Africa. 3. Isolation and characterization of the virus. Am. J. Trop. Med. Hyg. 19, 680–691 (1970).
Olayemi, A. et al. Arenavirus diversity and phylogeography of Mastomys natalensis rodents, Nigeria. Emerg. Infect. Dis. 22, 694–697. https://doi.org/10.3201/eid2204.150155 (2016).
Ehichioya, D. U. et al. Current molecular epidemiology of Lassa virus in Nigeria. J. Clin. Microbiol. 49, 1157–1161. https://doi.org/10.1128/jcm.01891-10 (2011).
Oloniniyi, O. K. et al. Genetic characterization of Lassa virus strains isolated from 2012 to 2016 in southeastern Nigeria. PLoS Negl. Trop. Dis. 12, e0006971. https://doi.org/10.1371/journal.pntd.0006971 (2018).
Wiley, M. R. et al. Lassa virus circulating in Liberia: A retrospective genomic characterisation. Lancet. Infect. Dis https://doi.org/10.1016/s1473-3099(19)30486-4 (2019).
Safronetz, D. et al. Geographic distribution and genetic characterization of Lassa virus in sub-Saharan Mali. PLoS Negl. Trop. Dis. 7, e2582. https://doi.org/10.1371/journal.pntd.0002582 (2013).
Manning, J. T., Forrester, N. & Paessler, S. Lassa virus isolates from Mali and the Ivory Coast represent an emerging fifth lineage. Front. Microbiol. 6, 1037. https://doi.org/10.3389/fmicb.2015.01037 (2015).
Whitmer, S. L. M. et al. New lineage of Lassa virus, Togo, 2016. Emerg. Infect. Dis. 24, 599–602. https://doi.org/10.3201/eid2403.171905 (2018).
Emperador, D. M., Yimer, S. A., Mazzola, L. T., Norheim, G. & Kelly-Cirino, C. Diagnostic applications for Lassa fever in limited-resource settings. BMJ Glob. Health 4, e001119. https://doi.org/10.1136/bmjgh-2018-001119 (2019).
Emmerich, P., Gunther, S. & Schmitz, H. Strain-specific antibody response to Lassa virus in the local population of west Africa. J. Clin. Virol. 42, 40–44. https://doi.org/10.1016/j.jcv.2007.11.019 (2008).
Botten, J. et al. HLA-A2-restricted protection against lethal lymphocytic choriomeningitis. J. Virol. 81, 2307–2317. https://doi.org/10.1128/jvi.02063-06 (2007).
Lukashevich, I. S., Paessler, S. & de la Torre, J. C. Lassa virus diversity and feasibility for universal prophylactic vaccine. F1000Research https://doi.org/10.12688/f1000research.16989.1 (2019).
Warner, B. M., Safronetz, D. & Stein, D. R. Current research for a vaccine against Lassa hemorrhagic fever virus. Drug Des. Dev. Ther. 12, 2519–2527. https://doi.org/10.2147/dddt.S147276 (2018).
Salami, K., Gouglas, D., Schmaljohn, C., Saville, M. & Tornieporth, N. A review of Lassa fever vaccine candidates. Curr. Opin. Virol. 37, 105–111. https://doi.org/10.1016/j.coviro.2019.07.006 (2019).
Branco, L. M. et al. Bacterial-based systems for expression and purification of recombinant Lassa virus proteins of immunological relevance. Virol. J. 5, 74. https://doi.org/10.1186/1743-422x-5-74 (2008).
Grove, J. N. et al. Capacity building permitting comprehensive monitoring of a severe case of Lassa hemorrhagic fever in Sierra Leone with a positive outcome: case report. Virol. J. 8, 314. https://doi.org/10.1186/1743-422x-8-314 (2011).
Branco, L. M. et al. Emerging trends in Lassa fever: Redefining the role of immunoglobulin M and inflammation in diagnosing acute infection. Virol. J. 8, 478. https://doi.org/10.1186/1743-422x-8-478 (2011).
Boisen, M. L. et al. Field validation of the ReEBOV antigen rapid test for point-of-care diagnosis of ebola virus infection. J. Infect. Dis. https://doi.org/10.1093/infdis/jiw261 (2016).
Branco, L. M. et al. Lassa hemorrhagic fever in a late term pregnancy from northern Sierra Leone with a positive maternal outcome: case report. Virol. J. 8, 404. https://doi.org/10.1186/1743-422x-8-404 (2011).
Safronetz, D. et al. Detection of Lassa virus Mali. Emerg. Infect. Dis. 16, 1123–1126. https://doi.org/10.3201/eid1607.100146 (2010).
Ogunro, B. N. et al. Detection of antibody and antigen for Lassa virus nucleoprotein in monkeys from southern Nigeria. J. Epidemiol. Glob. Health 9, 125–127. https://doi.org/10.2991/jegh.k.190421.001 (2019).
Cross, R. W. et al. Quadrivalent VesiculoVax vaccine protects nonhuman primates from viral-induced hemorrhagic fever and death. J. Clin. Invest. 130, 539–551. https://doi.org/10.1172/jci131958 (2020).
Cashman, K. A. et al. A DNA vaccine delivered by dermal electroporation fully protects cynomolgus macaques against Lassa fever. Hum. Vacc. Immunother. 13, 2902–2911. https://doi.org/10.1080/21645515.2017.1356500 (2017).
Robinson, J. E. et al. Most neutralizing human monoclonal antibodies target novel epitopes requiring both Lassa virus glycoprotein subunits. Nat. Commun. 7, 11544. https://doi.org/10.1038/ncomms11544 (2016).
Hastie, K. M. et al. Structural basis for antibody-mediated neutralization of Lassa virus. Science 356, 923–928. https://doi.org/10.1126/science.aam7260 (2017).
Hastie, K. M. et al. Convergent structures illuminate features for germline antibody binding and pan-Lassa virus neutralization. Cell 178, 1004-1015.e1014. https://doi.org/10.1016/j.cell.2019.07.020 (2019).
Boisen, M. L. et al. Field evaluation of a Pan-Lassa rapid diagnostic test during the 2018 Nigerian Lassa fever outbreak. Sci. Rep. 10, 8724. https://doi.org/10.1038/s41598-020-65736-0 (2020).
Lewis, R. M., Cosgriff, T. M., Griffin, B. Y., Rhoderick, J. & Jahrling, P. B. Immune serum increases arenavirus replication in monocytes. J. Gen. Virol. 69(Pt 7), 1735–1739 (1988).
Clegg, J. C. & Lloyd, G. Vaccinia recombinant expressing Lassa-virus internal nucleocapsid protein protects guineapigs against Lassa fever. Lancet 2, 186–188 (1987).
Sakabe, S. et al. Identification of common CD8+ T cell epitopes from Lassa fever survivors in Nigeria and Sierra Leone. J. Virol. https://doi.org/10.1128/jvi.00153-20 (2020).
Sullivan, B. M. et al. High crossreactivity of human T cell responses between Lassa virus lineages. PLoS Pathog. 16, e1008352. https://doi.org/10.1371/journal.ppat.1008352 (2020).
Prescott, J. B. et al. Immunobiology of Ebola and Lassa virus infections. Nat. Rev. Immunol. 17, 195–207. https://doi.org/10.1038/nri.2016.138 (2017).
McCormick, J. B. & Fisher-Hoch, S. P. Lassa fever. Curr. Top. Microbiol. Immunol. 262, 75–109 (2002).
Jahrling, P. B., Peters, C. J. & Stephen, E. L. Enhanced treatment of Lassa fever by immune plasma combined with ribavirin in cynomolgus monkeys. J. Infect. Dis. 149, 420–427 (1984).
Jahrling, P. B. & Peters, C. J. Passive antibody therapy of Lassa fever in cynomolgus monkeys: Importance of neutralizing antibody and Lassa virus strain. Infect. Immun. 44, 528–533 (1984).
Cross, R. W. et al. Antibody therapy for Lassa fever. Curr. Opin. Virol. 37, 97–104. https://doi.org/10.1016/j.coviro.2019.07.003 (2019).
Mire, C. E. et al. Human-monoclonal-antibody therapy protects nonhuman primates against advanced Lassa fever. Nat. Med. 23, 1146–1149. https://doi.org/10.1038/nm.4396 (2017).
Cross, R. W. et al. Treatment of Lassa virus infection in outbred guinea pigs with first-in-class human monoclonal antibodies. Antiviral Res. 133, 218–222. https://doi.org/10.1016/j.antiviral.2016.08.012 (2016).
Hastie, K. M. & Saphire, E. O. Lassa virus glycoprotein: Stopping a moving target. Curr. Opin. Virol. https://doi.org/10.1016/j.coviro.2018.05.002 (2018).
McCormick, J. B., Mitchell, S. W., Kiley, M. P., Ruo, S. & Fisher-Hoch, S. P. Inactivated Lassa virus elicits a non protective immune response in rhesus monkeys. J. Med. Virol. 37, 1–7 (1992).
Safronetz, D. et al. A recombinant vesicular stomatitis virus-based Lassa fever vaccine protects guinea pigs and macaques against challenge with geographically and genetically distinct Lassa viruses. PLoS Negl. Trop. Dis. 9, e0003736. https://doi.org/10.1371/journal.pntd.0003736 (2015).
Zalgen Labs. ReLASV® Pan-Lassa NP IgG/IgM ELISA Kit. https://www.zalgen.com/wp-content/uploads/2019/05/PI-10004.pdf.
Wei, X. et al. Antibody neutralization and escape by HIV-1. Nature 422, 307–312. https://doi.org/10.1038/nature01470 (2003).
Jahrling, P. B., Smith, S., Hesse, R. A. & Rhoderick, J. B. Pathogenesis of Lassa virus infection in guinea pigs. Infect. Immun. 37, 771–778 (1982).
Acknowledgements
This work was supported by Grant INTU1901 from CEPI under the Development, Characterization and Establishment of Biological Standards program. Drs. Trygve Danielsen, Valentina Bernasconi and Gunnstein Norheim provided invaluable guidance for study design and constructive criticism of the manuscript. We thank the members of the VHFC, including the Broad Institute, Harvard University, La Jolla Institute of Immunology, the Scripps Research Institute, Tulane University, the University of Texas Medical Branch, Zalgen Labs, the ISTH Lassa Fever Program, and KGH, and the program staff of CEPI for their support. We are also grateful to the patients who presented to clinical sites in Nigeria and Sierra Leone, as well as their families, without whose cooperation this study would not have been possible. Douglass T Simpson, Simbirie C. Jalloh, Allyson M. Haislip, Christopher M. Bishop and Tynette D. Hills provided program management and logistical support.
Author information
Authors and Affiliations
Contributions
Conceived and designed the experiments: J.H., R.F.G., L.M.B., M.L.B., M.L.H., E.O.S., K.H. Performed the experiments: M.L.H., M.L.B., R.W.C., A.P.K., A.R.H., B.J.B., V.B., M.M., J.D.S., A.G., I.O., F.B., J.O.A., B.E., P.E., C.U., T.O., M.N.O., J.E., R.A., M.A., S.S.G., M.A.E., O.O., L.M.B., R.F.G. Analyzed the data: M.L.B., R.F.G., L.M.B., J.G.S., J.H. Developed reagents/materials/analysis tools: L.M.B., M.L.B., M.L.H., E.O.S., K.H., D.S.K.N., D.J.B., A.P.K., A.R.H., B.J.B., M.M.R., I.A., S.K., R.L. Subject enrollment, phlebotomists, patient care, and ethical approvals: D.S.G., C.T.H., J.S.S., E.E.E., G.O.A., D.O.A., S.A.O., P.O.O. Study coordinators: A.G., P.E., I.O., E.E.E., J.S.S., D.S.G., O.F., C.T.H. Contributed to writing of the manuscript: R.F.G., L.M.B., J.H., M.L.H., E.O.S., K.H., T.W.G., C.T.H., D.S.G. All authors reviewed and approved the manuscript.
Corresponding authors
Ethics declarations
Competing interests
Tulane University and its various academic and industry partners have filed US and foreign patent applications for countermeasures to emerging viruses. Technical information may also be kept as trade secrets. If commercial products are developed, including Lassa diagnostics, MLH, MLB, DSKN, DJB, RWC, APK, KMH, MMR, IA, SK, RL, JGS, JSS, TWG, EOS, CTH, DSG, RFG and LMB may receive royalties or profits. This does not alter our adherence to all policies of the NIH and Scientific Reports on sharing data and materials. The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Heinrich, M.L., Boisen, M.L., Nelson, D.K.S. et al. Antibodies from Sierra Leonean and Nigerian Lassa fever survivors cross-react with recombinant proteins representing Lassa viruses of divergent lineages. Sci Rep 10, 16030 (2020). https://doi.org/10.1038/s41598-020-72539-w
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-020-72539-w
This article is cited by
-
Lassa fever — the road ahead
Nature Reviews Microbiology (2023)
-
A Lassa virus mRNA vaccine confers protection but does not require neutralizing antibody in a guinea pig model of infection
Nature Communications (2023)
-
Humoral and cellular immune responses to Lassa fever virus in Lassa fever survivors and their exposed contacts in Southern Nigeria
Scientific Reports (2022)
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.