Next Article in Journal
Molecular Insights into Host and Vector Manipulation by Plant Viruses
Previous Article in Journal
MiR-202-5p Inhibits RIG-I-Dependent Innate Immune Responses to RGNNV Infection by Targeting TRIM25 to Mediate RIG-I Ubiquitination
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Antibodies for Venezuelan Equine Encephalitis Virus Protect Embryoid Bodies from Chikungunya Virus

Department of Biology, Baylor University, Waco, TX 76798, USA
*
Author to whom correspondence should be addressed.
Submission received: 5 February 2020 / Revised: 25 February 2020 / Accepted: 26 February 2020 / Published: 27 February 2020
(This article belongs to the Section Animal Viruses)

Abstract

:
Chikungunya virus (CHIKV) is an alphavirus that causes febrile illness punctuated by severe polyarthralgia. After the emergence of CHIKV in the Western Hemisphere, multiple reports of congenital infections were published that documented neurological complications, cardiac defects, respiratory distress, and miscarriage. The Western Hemisphere is endemic to several alphaviruses, and whether antigenic cross-reactivity can impact the course of infection has not been explored. Recent advances in biomedical engineering have produced cell co-culture models that replicate the cellular interface at the maternal fetal axis. We employed a trans-well assay to determine if cross-reactive antibodies affected the movement and replication of CHIKV across placental cells and into an embryoid body. The data showed that antibodies to Venezuelan equine encephalitis virus significantly reduced CHIKV viral load in embryoid bodies. The data highlighted the fact that viral pathogenesis can be cell-specific and that exploiting antigenic cross-reactivity could be an avenue for reducing the impact of congenital CHIKV infections.

1. Introduction

Chikungunya virus (CHIKV) is an alphavirus vectored by Aedes mosquitos and is an enveloped + positive sense single stranded RNA ssRNA virus with a 12 kb genome. In humans, CHIKV can cause a febrile illness punctuated by severe polyarthralgia. Historically, CHIKV infection was thought to be self-limited, but increasing reports are showing that rheumatic and neurological sequelae can linger for years following infection [1,2,3]. When CHIKV emerged in the Western Hemisphere, neuroinvasive disease and congenital infections were reported at rates much higher than the Eastern Hemisphere [4]. CHIKV congenital infections were first reported during the 2005 outbreak on Reunion Island [5,6,7]. After the emergence of CHIKV in the Western Hemisphere, multiple reports of congenital infections were published that documented neurological complications, cardiac defects, respiratory distress, and miscarriage [5,8,9]. Although reports of congenital infection were published in many CHIKV-endemic locations, the vast majority originated from South and Central America [4].
South and Central America, along with the Caribbean, are endemic to several New World alphaviruses including Madariaga virus (MADV), Mayaro virus (MAYV), Eastern equine encephalitis (EEEV), Venezuelan equine encephalitis (VEEV), and Western equine encephalitis (WEEV). Human exposure prevalence for these viruses can be as high as 80% in some regions [10,11]. VEEV and CHIKV have been found to circulate in the same Central and South American regions [12,13,14,15]. For example, VEEV has been thought to be endemic in southern Mexico for decades, with seroprevalence rates between 18–75%, whereas the seroprevalence of CHIKV in southern Mexico has been determined by some studies to be as high as 85% [13,14]. Additionally, recent studies have indicated that antigenic cross-reactivity, antibody-mediated enhancement, and antibody cross-neutralization of alphaviruses can have a significant impact on the course of infection [16,17,18,19].
The study of congenital infections with these viruses is problematic, as most animal models do not reflect human disease. Although research has shown that non-human primates and sheep can serve as models, these systems can be expensive, labor intensive, and contain small sample sizes [20,21]. As a result, aside from Zika virus, there is limited research on other congenital arboviral infections outside of case reports and epidemiological studies. Recent advances in biomedical engineering have produced co-culture models using human stem cells or primary cells that replicate the cellular interface at the blood–brain barrier and the maternal fetal axis in order to evaluate the movement and effects of exogenous substances [22,23]. In order to determine if alphaviral antibody cross-reactivity could impact CHIKV congenital infections, we employed a trans-well assay to determine if cross-reactive antibodies impacted the pathogenesis or replication of CHIKV across placental cells and into an embryoid body.
Several in vitro models are used to measure translocation of products across the placenta, such as microfluidics, spheroids, organoids, and trans-well models [24,25,26]. Although scientists aim for model complexity in order to better replicate the placenta, the trans-well assay excels because it lends well to standardization and is easy to manipulate and reproduce [23,26]. For this study, we employed the trans-well approach due to its success in measuring the movement of nanoparticles across the placenta [27,28,29,30]. We followed Aengenheister et al. (2018) [27] by including an embryoid body (EB) in our co-culture model. EBs consist of self-organized stem cells that mimic the three dimensional structure of early peri-implantation development and possess the differentiation potential of early embryonic development [31]. We reasoned that this model would allow us to determine if virus and/or virus/antibody complexes could cross the placenta barrier and if they could impact an embryo.
We followed other research and used maternal syncytiotrophoblast and fetal umbilical vein cells (BeWo and HUVEC) cells for our placenta model [25,27,28] (Figure 1). BeWo cells are derived from human placenta and were used to represent syncytiotrophoblasts that form the placenta [32]. These cells form a continuous layer around the placenta, are in direct contact with the maternal blood supply, and function in nutrient exchange with the fetus [33]. These cells also form a barrier through which CHIKV must cross in order to invade the fetal environment. HUVEC cells are derived from the fetal umbilical vein and were cultured with a variety of factors to promote microvascular phenotypes (ATCC). Microvascular placental endothelial cells are involved with placental expansion during the first trimester and vascularization throughout pregnancy [33]. These cells are located adjacent to maternal syncytiotrophoblasts and maternal blood in the intervillous space in the placenta [33,34]. BeWo and HUVEC cells were plated on a permeable membrane that was coated with collagen to provide a basement membrane for cell attachment and for the development of microvillous structures as well as desmosome and tight junctions (Figure 1). Here, we describe the impact of VEEV antibodies on CHIKV infection using this in vitro congenital model.

2. Materials and Methods

2.1. Cell Culture and Virus Propagation

Primary human umbilical vein endothelial cells; normal, human, pooled (HUVEC) (ATCC PCS-100-013) were cultured in EndoGRO-MV-VEGF media (MilliporeSigma, Burlington, MA, USA) containing 5% fetal bovine serum (FBS). Additionally, human placental cells BeWo (ATCC CCL-98) were cultured in Ham’s F-12K (Kaighn’s) medium containing 10% FBS, penicillin/streptomycin, 1X non-essential amino acids, 1X Glutamax, and 1 mM HEPES. Lastly, Cercopithecus aethiops kidney cell line Vero E6 (ATCC CRL-1586) were grown in Dulbecco’s modified Eagle’s medium (DMEM) with 10% FBS, supplemented with penicillin/streptomycin, 1X non-essential amino acids, 1X Glutamax, and 1 mM HEPES. All cell lines were incubated at 37 °C/5% CO2. CHIKV (181/25) was obtained from BEI Resources (NR-50345) and expanded once in Vero cells. Polyclonal anti-Venezuelan equine encephalitis virus, TC-83 (subtype IA/B) glycoprotein (antiserum, goat), NR-9404, was obtained through BEI Resources (BEIresources.org) NIAID, NIH.

2.2. Embryoid Body Formation

Human-induced pluripotent stem cells (ATCC ACS-1019) were cultured in mTeSR1 media (StemCell Technologies, Vancouver, Canada) on plates coated with vitronectin XF (Stemcell Technologies). ACS-1019 cells were seeded in an AggreWell 400 24-well plate at a density of 2.4 × 105 cells per well, following the manufacturer’s directions, in order to initiate EB formation (StemCell Technologies). ACS-1019 were cultured in the AggreWell microwells with AggreWell EB formation media for 72 h at 37 °C/5% CO2. After this, the resulting EBs were harvested and divided equally between replicates of each treatment.

2.3. Monolayer Infection and Imaging

Monolayers of BeWo and HUVEC cells were infected with 100 infectious units per well. After 48 h, samples were fixed with 4% paraformaldehyde and blocked with 5% lamb serum. Cells were stained with anti-CHIKV monoclonal antibody 3E7b and anti-MAP2 antibody (Novus Biologicals, Littleton, CO, USA). Slides were mounted with ProLong Gold Antifade Reagent with DAPI (Cell Signaling Technology, Danvers, MA, USA catalog #8961S) and images were obtained using an Olympus Fluoview 3000 confocal microscope. Images were processed using the Olympus Fluoview FV10-ASW 4.1 software package.

2.4. Trans-Well Co-Culture

Corning 12 mm Trans-well-COL collagen-coated 3.0 µm pore PTFE membrane insert (Corning, NY, USA catalog #3494) were seeded with HUVEC cells on the basolateral side of the insert at a concentration of 1.0 × 105 cells per 200 µL, and BeWo cells were seeded on the apical side of the insert at a density of 1.5 × 105 cells in 500 µL. The HUVEC monolayer on the basolateral side was achieved using methods described by Aengenheister et al. (2018) [27]. Briefly, inserts were inverted into 6-well plates, with 1 mL of phosphate buffered saline (PBS) in one well to ensure sufficient humidity. Rubber spacers (approximately 1.5 mm thick) were placed on the corner of the 6-well plate to lift up the lid slightly and prevent direct contact of the lid with the inverted insert. After the basolateral side was seeded with HUVECs and the lid was replaced, there was slight adhesion between the lid and the media. HUVEC-seeded inserts were then incubated at 37 °C/5% CO2 for 2 h, and afterwards the inserts were placed back into the 12 well plate containing fresh HUVEC media. Co-cultures were incubated for 72 h with the media being changed every 48 h until a 100% confluent layer was observed.

2.5. Trans-Well Neutralization Assay

Prior to infection, the media in each basolateral well was replaced with 1/2 HUVEC media 1/2 EB formation media. EBs were added to the bottom of well (Figure 1). Neutralization assays using VEEV serum were performed using a 1:200 dilution of serum in PBS. A total of 10,000 infectious units of virus in PBS were incubated with serum for 1 h at 37 °C, after which BeWo cells, apical side of the trans-well inserts, were inoculated with the mixture. Assay controls included treatments of mock infection and virus only. Culture supernatant (BeWo and HUVEC) and EB samples were taken at 24, 48, and 72 h. EBs were separated from culture supernatant by centrifugation at 400× g for 4 min. The supernatant was aspirated. EBs were rinsed in 1 mL PBS and centrifuged again at 400× g for 4 min. The supernatant was removed, and the EBs were resuspended in PBS and homogenized by vigorous trituration. Results are expressed as an average between two independent trials with three replicates for each treatment. Pairwise comparisons were performed between relative treatments using Student’s t-test with a Tukey post-hoc test.

2.6. Viral Quantification

Plaque assays were performed using culture supernatant from the HUVEC and BeWo monolayers, as well as using the pooled supernatant samples from each treatment at each time point taken during the course of the trans-well experiment following a method described previously [35]. EBs were separated as described above. Briefly, serial dilutions of culture supernatant or EBs in PBS were inoculated onto confluent Vero E6 cells and covered with 0.25% methylcellulose overlay. After 3 days, the overlay was removed, and cells were stained with Coomassie blue. Viral RNA was extracted using a kit in accordance to the manufacturer’s instructions (Zymo quick viral RNA kit). Quantitative real-time PCR, performed on all supernatant samples taken from all treatments at each time point using Verso One-Step RT-qPCR Kit, SYBR Green, ROX (Thermo Fisher), and primers designed by Patel et al. (2019), which are specific for the CHIKV E1 gene [36]. A non-template control was used to normalize the RT-qPCR results. Pairwise comparisons between treatments were performed using raw Ct values with Student’s t-test with a Tukey post-hoc test. Relative fold change was calculated via the ∆∆Ct method using the non-infected reference cell line as a baseline.

3. Results

3.1. Chikungunya Infected Maternal and Fetal Placental Cells

Both BeWo and HUVEC cell lines were infected with CHIKV and visualized using anti-CHIKV monoclonal antibody 3E7b (EMD Millipore). The images show that both BeWo and HUVEC cells were permissive to CHIKV infection with significantly more fluorescence detected in CHIKV-infected cells than in their non-infected controls (Figure 2). BeWo monolayers exhibited no noticeable cytopathic effects (CPE) At 72 h post infection (p.i.), HUVEC cells showed increased CPE consisting of cell rounding and sloughing, whereas BeWo cells showed no CPE.

3.2. Trans-Well Neutralization Assay

CHIKV was detected via viral plaque assay and RT-PCR 24 h p.i. and continuing through 72 h p.i. in BeWo and HUVEC cells. Pairwise comparisons of timepoints of CHIKV-infected BeWo cells indicated a significant rise in viral titers at 72 h compared with 24 h p.i. (p = 0.0387). The presence of VEEV antibodies resulted in a significant reduction in viral plaques at 72 h post-inoculation in BeWo cells when compared to CHIKV-infected BeWo cells without VEEV antibodies (p = 0.0162) (Figure 3A). When evaluated by RT-PCR, significant increases in viral genome copy were observed over all time points for BeWo cells for both CHIKV only (p = 0.021–0.037) and CHIKV + VEEV antibody (p = 0.009–0.021) treatments (Figure 3B). Pairwise comparisons between CHIKV only and CHIKV + VEEV antibodies at each time point also indicted no significant changes in Ct value when VEEV antibodies were present in BeWo cells (Figure 3B).
HIKV was detected in HUVEC cells with significant increase in viral titer at 48 h compared to 24 h (p = 0.0372), followed by a significant reduction in viral titer at 72 h compared to 48 h (p = 0.0219) (Figure 3C). The presence of VEEV antibodies did not result in a significant reduction in viral plaques at any time point in HUVEC cells when compared to CHIKV-infected HUVEC cells without VEEV antibodies. When evaluated by RT-PCR, significant increases in viral genome copy were observed at all time points for HUVEC cells for both CHIKV only (p = 0.021–0.037) and CHIKV + VEEV antibody (p = 0.009–0.021) treatments (Figure 3D). Pairwise comparisons between CHIKV only and CHIKV + VEEV antibodies at each time point indicted that no significant changes in Ct value were found when VEEV antibodies were present in HUVEC cells (Figure 3D). Because cell culture supernatant was used, the discrepancies between the quantities of infectious virus and nucleic acid were likely a reflection on the proportion of defective virions that exited from the host cell.
For EBs, CHIKV was detected by viral plaque assay at 24, 48, and 72 h p.i. (Figure 4). CHIKV was also detected in EBs when VEEV antibody was present at 24, 48, and 72 h p.i. (Figure 4). When VEEV antibodies were present, significantly fewer viral plaques were measured at 72 h p.i. when compared to the virus-only treatment at the same time point (p = 0.027) (Figure 4A). Conversely, when evaluated by RT-PCR at 72 h p.i., viral genome copies were detected at a 5-fold greater quantity for CHIKV alone and a 29.95-fold greater quantity for CHIKV + VEEV antibodies. These were significantly more than at the previous time points (p = 0.002). Additionally, at 48 h p.i., the presence of VEEV antibodies resulted in a significant decrease in CHIKV genomic material as detected by RT-RCR (p = 0.0103). Furthermore, at 72 h p.i., CHIKV was detected at significantly higher levels by RT-PCR when VEEV antibodies were present as opposed to CHIKV alone at 72 h (p = 0.0267) (Figure 4B). The discrepancies between the quantities of infectious virus and genome copy we observed could have been a reflection of viral assembly on the proportion of infectious virions that exited from the host cell.

4. Discussion

The data showed that CHIKV can replicate in maternal and fetal placental cells as well as in EBs. Previous work has shown that the ability for CHIKV to infect and replicate in specific cells types is host-specific as has been shown for multiple flaviviruses [37,38,39]. Thus, it is necessary to identify which cells participate in viral pathogenesis. Reports on CHIKV replication efficiency in mammals and cell lines have shown a range of detection depending on the host [40,41]. The data here show that in BeWo and HUVEC cells, CHIKV replication peaked at 48 h p.i., whereas in EBs, CHIKV replication was greatest at 72 h p.i. Whether this 72 h peak reflected an infection delay caused by the movement of CHIKV through two cell monolayers and a basement membrane requires further investigation.
CHIKV has been detected in the placenta and amniotic fluid of infected mothers, which supports this platform as an in vitro mechanism for studying the kinetics of congenital CHIKV infections [5,6,42,43]. The virus was quantified via titration in Vero cells and by RT-PCR. Titration quantifies infectious units whereas RT-PCR measures genome copies. In this study, there was little correlation between infectious units and genome copies. Further, it was found that significantly more genome copies were produced in EBs when VEEV antibodies were present. This might suggest potential antibody-mediated enhancement. Although this is commonly associated with flaviviruses, antibody-mediated enhancement has also been documented for two alphaviruses, Ross River virus (RRV), and recently, CHIKV (by RT-PCR) [16,44]. These studies measured the enhancement of sub-neutralizing RRV or CHIKV antibodies against subsequent infections with the same virus. However, outside these two studies, antibody-mediated cross enhancement has not been explored in depth for other alphaviruses. Regardless, viral plaque assays in this study showed that infection of EBs was significantly reduced when VEEV antibodies were present, suggesting that these antibodies could be interfering with viral assembly, maturation, or exit. Recent work has shown that neutralizing antibodies interact with viral glycoproteins present on the cell surface, which inhibits the budding of CHIKV at the plasma membrane [45,46,47]. Furthermore, CHIKV monoclonal antibodies have been shown to interact with viral envelope proteins of other alphaviruses to inhibit both at viral fusion and exit [47].
The data show that CHIKV actively replicates in both cell lines by 48 h p.i. Whether infection of the basolateral side of the membrane was due to cell–cell contact or virus escape into the basolateral media is not known. Although the detection of CHIKV in cells located on either side of the maternal fetal axis in this study supports case reports of CHIKV congenital infections and isolation of CHIKV from placentas, the susceptibility observed in this study may not reflect the cellular tropism of CHIKV in actual placentas [5,6,42,48].
A major limitation of this study was the omission of Hofbauer cells from the model. These cells function as the antigen presenting macrophages in the placental villous stroma and function in host defense [33]. Although the role of Hofbauer cells has not been described for CHIKV, several reports document their role for other congenital viral infections [49,50,51,52,53,54]. Because Hofbauer cells are antigen-presenting, they could play a role in viral enhancement, as has been reported for Zika virus [50].
Cross-protective antibodies are commonly targeted for their use in vaccines and therapeutics, and antigenic cross-reactivity has been described for CHIKV [47]. This study found that VEEV antibody-mediated neutralization of CHIKV occurred in BeWo cells and EBs. The polyclonal serum used in this study was pooled from several goats obtained beginning 2 weeks post final inoculation and continuing for at least 4 weeks. The development of neutralizing antibodies begins about 2 weeks p.i. and continues to rise over the next 3–6 months. Thus, the serum used here may not have represented the full repertoire of VEEV neutralizing or enhancing antibodies. Furthermore, the serum used in this study was from goats vaccinated with TC-83 VEEV vaccine due to its availability from BEI Resources and its defined nature. However, the response of CHIKV to VEEV antibodies may not represent the full potential of CHIKV cross-reactivity in the New World.
Although alphaviruses possess a high degree of genetic diversity, phylogenetic studies have shown distinct groupings of Old and New World alphaviruses [55]. The VEEV complex itself contains a high degree of genetic and antigenic variation, and human seroprevalence rates have been reported to range from 14% to 33% [55,56,57,58]. Other New World alphaviruses such as Western Equine Encephalitis and Eastern Equine Encephalitis groups have less genetic diversity than VEEV and are distributed over larger geographic areas than viruses in the VEEV complex [55]. Further, MAYV and MADV are emerging as new threats to human health. MAYV belongs to the Semliki Forest Virus complex, which also contains CHIKV and could possess more antigenic cross-reactivity than VEEV [55]. Clearly this area warrants further investigation.

5. Conclusions

Early immune VEEV antibodies significantly reduce CHIKV in BeWo and EBs 72 h p.i. There may be other cross-neutralizing antibodies from other alphaviruses that also impact congenital CHIKV infections. More information on CHIKV congenital infections is needed, as is work that evaluates other alphaviruses and Hofbauer cells.

Author Contributions

Conceptualization, K.L.B., E.M.S.; methodology, K.L.B., E.M.S.; formal analysis, K.L.B., E.M.S.; investigation, K.L.B., E.M.S., T.J.J.; writing, K.L.B., E.M.S.; reviewing and editing, K.L.B., E.M.S., T.J.J. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported through start-up funding from Baylor University to Barr.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

References

  1. Feldstein, L.R.; Rowhani-Rahbar, A.; Staples, J.E.; Weaver, M.R.; Halloran, M.E.; Ellis, E.M. Persistent Arthralgia Associated with Chikungunya Virus Outbreak, US Virgin Islands, December 2014-February 2016. Emerg Infect. Dis. 2017, 23, 673–676. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Cerny, T.; Schwarz, M.; Schwarz, U.; Lemant, J.; Gérardin, P.; Keller, E. The Range of Neurological Complications in Chikungunya Fever. Neurocrit Care 2017, 27, 447–457. [Google Scholar] [CrossRef] [PubMed]
  3. van Aalst, M.; Nelen, C.M.; Goorhuis, A.; Stijnis, C.; Grobusch, M.P. Long-term sequelae of chikungunya virus disease: A Syst. review. Travel Med. Infect. Dis. 2017, 15, 8–22. [Google Scholar] [CrossRef] [PubMed]
  4. Barr, K.L.; Vaidhyanathan, V. Chikungunya in Infants and Children: Is Pathogenesis Increasing? Viruses 2019, 11, 294. [Google Scholar] [CrossRef] [Green Version]
  5. Lenglet, Y.; Barau, G.; Robillard, P.Y.; Randrianaivo, H.; Michault, A.; Bouveret, A.; Gérardin, P.; Boumahni, B.; Touret, Y.; Kauffmann, E.; et al. Chikungunya infection in pregnancy: Evidence for intrauterine infection in pregnant women and vertical transmission in the parturient. Survey of the Reunion Island outbreak. J. De Gynecol. Obstet. Et Biol. De La Reprod. 2006, 35, 578–583. [Google Scholar] [CrossRef]
  6. Touret, Y.; Randrianaivo, H.; Michault, A.; Schuffenecker, I.; Kauffmann, E.; Lenglet, Y.; Barau, G.; Fourmaintraux, A. Early maternal-fetal transmission of the Chikungunya virus. Presse Med. 2006, 35, 1656–1658. [Google Scholar] [CrossRef]
  7. Robillard, P.Y.; Boumahni, B.; Gérardin, P.; Michault, A.; Fourmaintraux, A.; Schuffenecker, I.; Carbonnier, M.; Djémili, S.; Choker, G.; Roge-Wolter, M.; et al. Vertical maternal fetal transmission of the chikungunya virus: Ten cases among 84 pregnant women. Presse Med. 2006, 35, 785–788. [Google Scholar] [CrossRef]
  8. Villamil-Gomez, W.; Alba-Silvera, L.; Menco-Ramos, A.; Gonzalez-Vergara, A.; Molinares-Palacios, T.; Barrios-Corrales, M.; Rodriguez-Morales, A.J. Congenital Chikungunya Virus Infection in Sincelejo, Colombia: A Case Series. J. Trop. Pediatrics 2015, 61, 386–392. [Google Scholar] [CrossRef] [Green Version]
  9. Cardona-Correa, S.E.; Castano-Jaramillo, L.M.; Quevedo-Velez, A. Vertical transmission of chikungunya virus infection. Case Report. Rev. Chil. De Pediatr. 2017, 88, 285–288. [Google Scholar] [CrossRef] [Green Version]
  10. Vittor, A.Y.; Armien, B.; Gonzalez, P.; Carrera, J.P.; Dominguez, C.; Valderrama, A.; Glass, G.E.; Beltran, D.; Cisneros, J.; Wang, E.; et al. Epidemiology of Emergent Madariaga Encephalitis in a Region with Endemic Venezuelan Equine Encephalitis: Initial Host Studies and Human Cross-Sectional Study in Darien, Panama. PLoS Negl. Trop. Dis. 2016, 10, e0004554. [Google Scholar] [CrossRef]
  11. Cardozo, F.; Konigheim, B.; Albrieu-Llinás, G.; Rivarola, M.E.; Aguilar, J.; Rojas, A.; Quaglia, A.I.; Paez, M.; Guillén, Y.; Diaz, A.; et al. Alphaviruses: Serological Evidence of Human Infection in Paraguay (2012–2013). Vector-Borne Zoonotic Dis. 2018, 18, 266–272. [Google Scholar] [CrossRef] [PubMed]
  12. Aguilar, P.V.; Estrada-Franco, J.G.; Navarro-Lopez, R.; Ferro, C.; Haddow, A.D.; Weaver, S.C. Endemic Venezuelan equine encephalitis in the Americas: Hidden under the dengue umbrella. Future Virol. 2011, 6, 721–740. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  13. Galán-Huerta, K.A.; Martínez-Landeros, E.; Delgado-Gallegos, J.L.; Caballero-Sosa, S.; Malo-García, I.R.; Fernández-Salas, I.; Ramos-Jiménez, J.; Rivas-Estilla, A.M. Molecular and Clinical Characterization of Chikungunya Virus Infections in Southeast Mexico. Viruses 2018, 10, 248. [Google Scholar] [CrossRef] [Green Version]
  14. Estrada-Franco, J.G.; Navarro-Lopez, R.; Freier, J.E.; Cordova, D.; Clements, T.; Moncayo, A.; Kang, W.; Gomez-Hernandez, C.; Rodriguez-Dominguez, G.; Ludwig, G.V.; et al. Venezuelan equine encephalitis virus, southern Mexico. Emerg. Infect. Dis. 2004, 10, 2113–2121. [Google Scholar] [CrossRef]
  15. Charlier, C.; Beaudoin, M.-C.; Couderc, T.; Lortholary, O.; Lecuit, M. Arboviruses and pregnancy: Maternal, fetal, and neonatal effects. Lancet Child. Adolesc. Health 2017, 1, 134–146. [Google Scholar] [CrossRef]
  16. Lum, F.M.; Couderc, T.; Chia, B.S.; Ong, R.Y.; Her, Z.; Chow, A.; Leo, Y.S.; Kam, Y.W.; Renia, L.; Lecuit, M.; et al. Antibody-mediated enhancement aggravates chikungunya virus infection and disease severity. Sci. Rep. 2018, 8, 1860. [Google Scholar] [CrossRef] [PubMed]
  17. Kam, Y.W.; Pok, K.Y.; Eng, K.E.; Tan, L.K.; Kaur, S.; Lee, W.W.L.; Leo, Y.S.; Ng, L.C.; Ng, L.F.P. Sero-Prevalence and Cross-Reactivity of Chikungunya Virus Specific Anti-E2EP3 Antibodies in Arbovirus-Infected Patients. PLoS Negl. Trop. Dis. 2015, 9, e3445. [Google Scholar] [CrossRef] [Green Version]
  18. Partidos, C.D.; Paykel, J.; Weger, J.; Borland, E.M.; Powers, A.M.; Seymour, R.; Weaver, S.C.; Stinchcomb, D.T.; Osorio, J.E. Cross-protective immunity against o’nyong-nyong virus afforded by a novel recombinant chikungunya vaccine. Vaccine 2012, 30, 4638–4643. [Google Scholar] [CrossRef] [Green Version]
  19. Rico, A.B.; Phillips, A.T.; Schountz, T.; Jarvis, D.L.; Tjalkens, R.B.; Powers, A.M.; Olson, K.E. Venezuelan and western equine encephalitis virus E1 liposome antigen nucleic acid complexes protect mice from lethal challenge with multiple alphaviruses. Virology 2016, 499, 30–39. [Google Scholar] [CrossRef]
  20. Steinbach, R.J.; Haese, N.N.; Smith, J.L.; Colgin, L.M.A.; MacAllister, R.P.; Greene, J.M.; Parkins, C.J.; Kempton, J.B.; Porsov, E.; Wang, X.; et al. A neonatal nonhuman primate model of gestational Zika virus infection with evidence of microencephaly, seizures and cardiomyopathy. PLoS ONE 2020, 15, e0227676. [Google Scholar] [CrossRef] [Green Version]
  21. Schwarz, E.R.; Pozor, M.A.; Pu, R.; Barr, K.L.; Beachboard, S.E.; MacLachlan, N.J.; Prakoso, D.; Long, M.T. Experimental Infection of Pregnant Female Sheep with Zika Virus During Early Gestation. Viruses 2019, 11, 795. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  22. Setia, H.; Muotri, A.R. Brain organoids as a model system for human neurodevelopment and disease. Semin. Cell Dev. Biol. 2019, 95, 93–97. [Google Scholar] [CrossRef] [PubMed]
  23. Campagnolo, L.; Lacconi, V.; Massimiani, M.; Magrini, A.; Pietroiusti, A. In vitro experimental models to study the efficiency of the placental barrier for environmental toxicants: Tumor cell lines versus trophoblast primary cells. Biomed. Prev. 2018, 1. [Google Scholar] [CrossRef]
  24. Blundell, C.; Tess, E.R.; Schanzer, A.S.; Coutifaris, C.; Su, E.J.; Parry, S.; Huh, D. A microphysiological model of the human placental barrier. Lab. A Chip 2016, 16, 3065–3073. [Google Scholar] [CrossRef] [PubMed]
  25. Muoth, C.; Aengenheister, L.; Kucki, M.; Wick, P.; Buerki-Thurnherr, T. Nanoparticle transport across the placental barrier: Pushing the field forward! Nanomed. (Lond. Engl. ) 2016, 11, 941–957. [Google Scholar] [CrossRef] [PubMed]
  26. Cartwright, L.; Poulsen, M.S.; Nielsen, H.M.; Pojana, G.; Knudsen, L.E.; Saunders, M.; Rytting, E. In vitro placental model optimization for nanoparticle transport studies. Int. J. Nanomed. 2012, 7, 497–510. [Google Scholar] [CrossRef] [Green Version]
  27. Aengenheister, L.; Keevend, K.; Muoth, C.; Schonenberger, R.; Diener, L.; Wick, P.; Buerki-Thurnherr, T. An advanced human in vitro co-culture model for translocation studies across the placental barrier. Sci. Rep. 2018, 8, 5388. [Google Scholar] [CrossRef] [Green Version]
  28. Aengenheister, L.; Dietrich, D.; Sadeghpour, A.; Manser, P.; Diener, L.; Wichser, A.; Karst, U.; Wick, P.; Buerki-Thurnherr, T. Gold nanoparticle distribution in advanced in vitro and ex vivo human placental barrier models. J. Nanobiotechnology 2018, 16, 79. [Google Scholar] [CrossRef]
  29. D’Errico, J.N.; Doherty, C.; Fournier, S.B.; Renkel, N.; Kallontzi, S.; Goedken, M.; Fabris, L.; Buckley, B.; Stapleton, P.A. Identification and quantification of gold engineered nanomaterials and impaired fluid transfer across the rat placenta via ex vivo perfusion. Biomed. Pharmacother. Biomed. Pharmacother. 2019, 117, 109148. [Google Scholar] [CrossRef]
  30. Turco, M.Y.; Gardner, L.; Kay, R.G.; Hamilton, R.S.; Prater, M.; Hollinshead, M.S.; McWhinnie, A.; Esposito, L.; Fernando, R.; Skelton, H.; et al. Trophoblast organoids as a model for maternal-fetal interactions during human placentation. Nature 2018, 564, 263–267. [Google Scholar] [CrossRef] [Green Version]
  31. Brickman, J.M.; Serup, P. Properties of embryoid bodies. Wires Dev. Biol. 2017, 6, e259. [Google Scholar] [CrossRef] [PubMed]
  32. Heaton, S.J.; Eady, J.J.; Parker, M.L.; Gotts, K.L.; Dainty, J.R.; Fairweather-Tait, S.J.; McArdle, H.J.; Srai, K.S.; Elliott, R.M. The use of BeWo cells as an in vitro model for placental iron transport. Am. J. Physiol Cell Physiol 2008, 295, C1445–C1453. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  33. Wang, Y. Cell Types of the Placenta. In Vascular Biology of the Placenta, 4th ed.; Wang, Y., Zhao, S., Eds.; Morgan & Claypool Life Sciences: San Rafael, CA, USA, 2010. [Google Scholar]
  34. Benirschke, K.; Driscoll, S.G. Anatomy and pathology of the umbilical cord. In Pathology of the human placenta, 5th ed.; Benirschke, K., Burton, G.J., Baergen, R.N., Eds.; Springer: Berlin/Heidelberg, Germany, 2006; p. 71. [Google Scholar]
  35. Barr, K.L.; Khan, E.; Farooqi, J.Q.; Imtiaz, K.; Prakoso, D.; Malik, F.; Lednicky, J.A.; Long, M.T. Evidence of Chikungunya Virus Disease in Pakistan Since 2015 With Patients Demonstrating Involvement of the Central Nervous System. Front. Public Health 2018, 6, 186. [Google Scholar] [CrossRef] [PubMed]
  36. B., S.R.; Patel, A.K.; Kabra, S.K.; Lodha, R.; Ratageri, V.H.; Ray, P. Virus load and clinical features during the acute phase of Chikungunya infection in children. PLoS ONE 2019, 14, e0211036. [Google Scholar] [CrossRef]
  37. Barr, K.L.; Anderson, B.D.; Prakoso, D.; Long, M.T. Working with Zika and Usutu Viruses In Vitro. PLoS Negl. Trop. Dis. 2016, 10, e0004931. [Google Scholar] [CrossRef] [Green Version]
  38. Barr, K.L.; Anderson, B.D.; Heil, G.L.; Friary, J.A.; Gray, G.C.; Focks, D.A. Dengue serotypes 1–4 exhibit unique host specificity in vitro. Virus Adapt. Treat. 2012, 2012, 8. [Google Scholar] [CrossRef] [Green Version]
  39. Wikan, N.; Sakoonwatanyoo, P.; Ubol, S.; Yoksan, S.; Smith, D.R. Chikungunya virus infection of cell lines: Analysis of the East, Central and South African lineage. PLoS ONE 2012, 7, e31102. [Google Scholar] [CrossRef] [Green Version]
  40. Guerrero, N.A.S.; Bello, F.J. Comparative assessment of the replication efficiency of dengue, yellow fever, and chikungunya arboviruses in some insect and mammalian cell lines. Rev. Soc. Bras. Med. Trop 2019, 52, e20180511. [Google Scholar] [CrossRef]
  41. Sasayama, M.; Benjathummarak, S.; Kawashita, N.; Rukmanee, P.; Sangmukdanun, S.; Masrinoul, P.; Pitaksajjakul, P.; Puiprom, O.; Wuthisen, P.; Kurosu, T.; et al. Chikungunya virus was isolated in Thailand, 2010. Virus Genes 2014, 49, 485–489. [Google Scholar] [CrossRef] [Green Version]
  42. Watanaveeradej, V.; Endy, T.P.; Simasathien, S.; Kerdpanich, A.; Polprasert, N.; Aree, C.; Vaughn, D.W.; Nisalak, A. The study transplacental chikungunya virus antibody kinetics, Thailand. Emerg. Infect. Dis. 2006, 12, 1770–1772. [Google Scholar] [CrossRef]
  43. Prata-Barbosa, A.; Cleto-Yamane, T.L.; Robaina, J.R.; Guastavino, A.B.; de Magalhaes-Barbosa, M.C.; Brindeiro, R.M.; Medronho, R.A.; da Cunha, A. Co-infection with Zika and Chikungunya viruses associated with fetal death-A case report. Int. J. Infect. Dis. 2018, 72, 25–27. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  44. Linn, M.L.; Aaskov, J.G.; Suhrbier, A. Antibody-dependent enhancement and persistence in macrophages of an arbovirus associated with arthritis. J. Gen. Virol. 1996, 77, 407–411. [Google Scholar] [CrossRef] [PubMed]
  45. Jin, J.; Galaz-Montoya, J.G.; Sherman, M.B.; Sun, S.Y.; Goldsmith, C.S.; O’Toole, E.T.; Ackerman, L.; Carlson, L.-A.; Weaver, S.C.; Chiu, W.; et al. Neutralizing Antibodies Inhibit Chikungunya Virus Budding at the Plasma Membrane. Cell Host Microbe 2018, 24, 417–428.e415. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  46. Jin, J.; Liss, N.M.; Chen, D.-H.; Liao, M.; Fox, J.M.; Shimak, R.M.; Fong, R.H.; Chafets, D.; Bakkour, S.; Keating, S.; et al. Neutralizing Monoclonal Antibodies Block Chikungunya Virus Entry and Release by Targeting an Epitope Critical to Viral Pathogenesis. Cell Rep. 2015, 13, 2553–2564. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  47. Fox, J.M.; Long, F.; Edeling, M.A.; Lin, H.; van Duijl-Richter, M.K.S.; Fong, R.H.; Kahle, K.M.; Smit, J.M.; Jin, J.; Simmons, G.; et al. Broadly Neutralizing Alphavirus Antibodies Bind an Epitope on E2 and Inhibit Entry and Egress. Cell 2015, 163, 1095–1107. [Google Scholar] [CrossRef] [Green Version]
  48. Chen, C.I.; Clark, D.C.; Pesavento, P.; Lerche, N.W.; Luciw, P.A.; Reisen, W.K.; Brault, A.C. Comparative pathogenesis of epidemic and enzootic Chikungunya viruses in a pregnant Rhesus macaque model. Am. J. Trop. Med. Hyg. 2010, 83, 1249–1258. [Google Scholar] [CrossRef] [Green Version]
  49. Zulu, M.Z.; Martinez, F.O.; Gordon, S.; Gray, C.M. The Elusive Role of Placental Macrophages: The Hofbauer Cell. J. Innate Immun. 2019, 11, 447–456. [Google Scholar] [CrossRef]
  50. Zimmerman, M.G.; Quicke, K.M.; O’Neal, J.T.; Arora, N.; Machiah, D.; Priyamvada, L.; Kauffman, R.C.; Register, E.; Adekunle, O.; Swieboda, D.; et al. Cross-Reactive Dengue Virus Antibodies Augment Zika Virus Infection of Human Placental Macrophages. Cell Host Microbe 2018, 24, 731–742.e736. [Google Scholar] [CrossRef] [Green Version]
  51. Reyes, L.; Golos, T.G. Hofbauer Cells: Their Role in Healthy and Complicated Pregnancy. Front. Immunol. 2018, 9, 2628. [Google Scholar] [CrossRef] [Green Version]
  52. Rosenberg, A.Z.; Yu, W.; Hill, D.A.; Reyes, C.A.; Schwartz, D.A. Placental Pathology of Zika Virus: Viral Infection of the Placenta Induces Villous Stromal Macrophage (Hofbauer Cell) Proliferation and Hyperplasia. Arch. Pathol. Lab. Med. 2017, 141, 43–48. [Google Scholar] [CrossRef] [Green Version]
  53. Schwartz, D.A. Viral infection, proliferation, and hyperplasia of Hofbauer cells and absence of inflammation characterize the placental pathology of fetuses with congenital Zika virus infection. Arch. Gynecol. Obs. 2017, 295, 1361–1368. [Google Scholar] [CrossRef] [PubMed]
  54. Simoni, M.K.; Jurado, K.A.; Abrahams, V.M.; Fikrig, E.; Guller, S. Zika virus infection of Hofbauer cells. Am. J. Reprod Immunol. 2017, 77. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  55. Weaver, S.C.; Winegar, R.; Manger, I.D.; Forrester, N.L. Alphaviruses: Population genetics and determinants of emergence. Antivir. Res. 2012, 94, 242–257. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. Carrera, J.P.; Bagamian, K.H.; Travassos da Rosa, A.P.; Wang, E.; Beltran, D.; Gundaker, N.D.; Armien, B.; Arroyo, G.; Sosa, N.; Pascale, J.M.; et al. Human and Equine Infection with Alphaviruses and Flaviviruses in Panama during 2010: A Cross-Sectional Study of Household Contacts during an Encephalitis Outbreak. Am. J. Trop. Med. Hyg. 2018, 98, 1798–1804. [Google Scholar] [CrossRef] [Green Version]
  57. Pisano, M.B.; Oria, G.; Beskow, G.; Aguilar, J.; Konigheim, B.; Cacace, M.L.; Aguirre, L.; Stein, M.; Contigiani, M.S. Venezuelan equine encephalitis viruses (VEEV) in Argentina: Serological evidence of human infection. PLoS Negl. Trop. Dis. 2013, 7, e2551. [Google Scholar] [CrossRef] [Green Version]
  58. Adams, A.P.; Navarro-Lopez, R.; Ramirez-Aguilar, F.J.; Lopez-Gonzalez, I.; Leal, G.; Flores-Mayorga, J.M.; Travassos da Rosa, A.P.A.; Saxton-Shaw, K.D.; Singh, A.J.; Borland, E.M.; et al. Venezuelan equine encephalitis virus activity in the Gulf Coast region of Mexico, 2003-2010. PLoS Negl. Trop. Dis. 2012, 6, e1875. [Google Scholar] [CrossRef] [Green Version]
Figure 1. Experimental model of the trans-well co-culture assay modified from Campagnolo et al. (2018) [23]. Co-cultures of BeWo, HUVEC, and embryoid body (EB) were apically infected with either Chikungunya virus (CHIKV) or CHIKV + VEEV (Venezuelan equine encephalitis) antibody.
Figure 1. Experimental model of the trans-well co-culture assay modified from Campagnolo et al. (2018) [23]. Co-cultures of BeWo, HUVEC, and embryoid body (EB) were apically infected with either Chikungunya virus (CHIKV) or CHIKV + VEEV (Venezuelan equine encephalitis) antibody.
Viruses 12 00262 g001
Figure 2. CHIKV infection in BeWo and HUVEC cells. (A) BeWo cells were infected with CHIKV and stained at 48 h p.i. (B) HUVEC cells were infected with CHIKV and stained at 72 h p.i. (blue = DAPI, pink = CHIK3E7b).
Figure 2. CHIKV infection in BeWo and HUVEC cells. (A) BeWo cells were infected with CHIKV and stained at 48 h p.i. (B) HUVEC cells were infected with CHIKV and stained at 72 h p.i. (blue = DAPI, pink = CHIK3E7b).
Viruses 12 00262 g002aViruses 12 00262 g002b
Figure 3. Viral titration as well as RT-PCR of BeWo and HUVEC cell lines. Viral titrations via plaque assay were performed for BeWo and HUVEC cells infected with CHIKV and CHIKV + VEEV antibodies. (A) Viral titrations showed that significantly less CHIKV was detected in BeWo cells at 72 h when VEEV antibodies were present (p = 0.0162, n = 6). (B) Significant increases in viral genome copy were observed at all time points for BeWo cells for both CHIKV only (p = 0.021–0.037) and CHIKV + VEEV antibody (p = 0.009–0.021) treatments. However, there was no significant difference in Ct value at each time point for pairwise comparison for CHIKV only compared to CHIKV + VEEV antibodies. (C) Viral titrations displayed that there was no significant difference in CHIKV at any time point, with or without the presence of VEEV antibodies in HUVEC cells. There was significant increase in viral titers of CHIKV between 24 and 48 h (p = 0.0372, n = 6), but a significant decrease in viral titers between 48 and 72 h (p = 0.029, n = 6). (D) HUVEC cells exhibited significant increases in viral genome copies over all time points for CHIKV only (p = 0.021–0.037, n = 6) and CHIKV + VEEV antibodies (p = 0.009–0.021, n = 6). * denotes statistical significance between treatments.
Figure 3. Viral titration as well as RT-PCR of BeWo and HUVEC cell lines. Viral titrations via plaque assay were performed for BeWo and HUVEC cells infected with CHIKV and CHIKV + VEEV antibodies. (A) Viral titrations showed that significantly less CHIKV was detected in BeWo cells at 72 h when VEEV antibodies were present (p = 0.0162, n = 6). (B) Significant increases in viral genome copy were observed at all time points for BeWo cells for both CHIKV only (p = 0.021–0.037) and CHIKV + VEEV antibody (p = 0.009–0.021) treatments. However, there was no significant difference in Ct value at each time point for pairwise comparison for CHIKV only compared to CHIKV + VEEV antibodies. (C) Viral titrations displayed that there was no significant difference in CHIKV at any time point, with or without the presence of VEEV antibodies in HUVEC cells. There was significant increase in viral titers of CHIKV between 24 and 48 h (p = 0.0372, n = 6), but a significant decrease in viral titers between 48 and 72 h (p = 0.029, n = 6). (D) HUVEC cells exhibited significant increases in viral genome copies over all time points for CHIKV only (p = 0.021–0.037, n = 6) and CHIKV + VEEV antibodies (p = 0.009–0.021, n = 6). * denotes statistical significance between treatments.
Viruses 12 00262 g003
Figure 4. Detection of CHIKV in EBs. (A) Viral titration of EBs was performed via plaque assay. Significantly less CHIKV was detected at 72 h p.i. when VEEV antibodies were present (p = 0.027, n = 6). (B) RT-PCR detected significantly more genome copies at 72 h p.i. when VEEV antibodies were present (p = 0.0267, n = 6), and significantly less at 48 h when VEEV antibodies were present (p = 0.0103, n = 6). * denotes statistical significance between treatments.
Figure 4. Detection of CHIKV in EBs. (A) Viral titration of EBs was performed via plaque assay. Significantly less CHIKV was detected at 72 h p.i. when VEEV antibodies were present (p = 0.027, n = 6). (B) RT-PCR detected significantly more genome copies at 72 h p.i. when VEEV antibodies were present (p = 0.0267, n = 6), and significantly less at 48 h when VEEV antibodies were present (p = 0.0103, n = 6). * denotes statistical significance between treatments.
Viruses 12 00262 g004

Share and Cite

MDPI and ACS Style

Schultz, E.M.; Jones, T.J.; Barr, K.L. Antibodies for Venezuelan Equine Encephalitis Virus Protect Embryoid Bodies from Chikungunya Virus. Viruses 2020, 12, 262. https://0-doi-org.brum.beds.ac.uk/10.3390/v12030262

AMA Style

Schultz EM, Jones TJ, Barr KL. Antibodies for Venezuelan Equine Encephalitis Virus Protect Embryoid Bodies from Chikungunya Virus. Viruses. 2020; 12(3):262. https://0-doi-org.brum.beds.ac.uk/10.3390/v12030262

Chicago/Turabian Style

Schultz, Emily M., TyAnthony J. Jones, and Kelli L. Barr. 2020. "Antibodies for Venezuelan Equine Encephalitis Virus Protect Embryoid Bodies from Chikungunya Virus" Viruses 12, no. 3: 262. https://0-doi-org.brum.beds.ac.uk/10.3390/v12030262

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop