Replication of Rocio virus in primary cultures of mouse neural cells

Souto, Adriano da Paixão; Casseb, Samir Mansour Moraes; Melo, Karla Fabiane Lopes de; Martins Filho, Arnaldo Jorge; Franco, Edna Cristina Santos

doi:10.31744/einstein_journal/2023AO0160

ABSTRACT

Objective

This study verified the replication efficiency of the Rocio virus in a primary culture of mouse neural cells.

Methods

Mixed primary cultures (neurons/glia) obtained from the brains of newborn isogenic BALB/c mice were inoculated with Rocio virus on the 7 ^th day of culture, and the development of cytopathogenic effects was monitored. The infection was confirmed via immunocytochemistry (anti-ROCV), while viral replication was quantified in infected primary cultures. The titration method used depended on the infection period.

Results

Rocio virus efficiently infected primary cultured neural cells, with the highest viral titer causing cytopathic changes was observed at 2 days post infection. The virus-infected primary culture survived for up to 7 days post infection, and viral load quantitation showed viral replication kinetics compatible with the cell death kinetics of cultures.

Conclusion

The findings of this study suggest that mouse neural cell primary cultures support Rocio virus replication and could be used as an alternative system for studying Flavivirus infection in the central nervous system.

Rocio virus; Flavivirus; Flavivirus infection; Primary cell culture; Central nervous system infections; Antigens, viral; Disease models, animal; Mice

INTRODUCTION

The Rocio virus (ROCV) is an arbovirus that causes encephalitis . It belongs to the family Flaviviridae and the genus Flavivirus. It was first isolated in 1975 in the southeastern region of Brazil from an outbreak of encephalitis in humans, affecting at least 23 countries in Ribeira Valley, São Paulo State. This outbreak began in 1973 and was curbed in 1980. The reason for this outbreak is still unclear. Approximately 1,021 encephalitis cases with a fatality rate of 10% were reported during the infection period. The ROCV disease is characterized by an acute onset of high fever, headache, prostration, myalgia, and vomiting. Neurological symptoms manifest as changes in consciousness, motor and reflex changes, balance disorders, mobility issues, and seizures. ( ¹1. Setoh YX , Amarilla AA , Peng NY , Slonchak A , Periasamy P , Figueiredo LT , et al . Full genome sequence of Rocio virus reveal substantial variations from the prototype Rocio virus SPH 34675 sequence . Arch Virol . 2018 ; 163 ( 1 ): 255 - 8 . )

The members of the genus Flavivirus are responsible for the significant morbidity and mortality associated with their infections. There are 36 Flaviviruses known to cause disorders in humans, and it is estimated that at least one of these viruses infects approximately two-thirds of the world’s population. Flaviviruses include the dengue virus, which infects approximately 50 million people each year; the West Nile virus (WNV), which has become endemic in the Northern Hemisphere since 1999 and continues to cause significant public health problems; the Yellow fever virus, which is endemic in African and South American countries; and the Japanese encephalitis virus (JEV), which is endemic in Asian countries and has a 30% to 40% mortality. ( ²2. Henriques DF , Quaresma JA , Fuzii HT , Nunes MR , Silva EV , Carvalho VL , et al . Persistence of experimental Rocio virus infection in the golden hamster (Mesocricetus auratus) . Mem Inst Oswaldo Cruz . 2012 ; 107 ( 5 ): 630 - 6 . )

Considering the strong potential encephalitogenic nature of the ROCV, it is important to study the pathogenesis of this agent in systems that affect the central nervous system (CNS). However, the few studies conducted on ROCV so far have predominantly used in vivo experimental models, with no reports on the use of primary cultures of CNS cells as in vitro models for ROCV infection. This study was conducted to verify whether ROCV can replicate efficiently in primary cultures of mouse CNS cells. Our data demonstrate the cytopathogenic effect and death of primary CNS cultured cells due to ROCV replication. Additionally, the ROCV has active replication kinetics in this system five days post-infection. These findings open the possibility of developing an experimental infection protocol of mice primary neural cells of mice by ROCV, contributing greatly to future studies involving the replication of ROCV and other encephalitogenic Flavivirus and virus-neural cell interactions in vertebrates. ( ¹1. Setoh YX , Amarilla AA , Peng NY , Slonchak A , Periasamy P , Figueiredo LT , et al . Full genome sequence of Rocio virus reveal substantial variations from the prototype Rocio virus SPH 34675 sequence . Arch Virol . 2018 ; 163 ( 1 ): 255 - 8 . )

OBJECTIVE

To verify the efficient replication of the Rocio virus in primary cultures of mouse neural cells.

METHODS

Viral stock

We used the Rocio virus strain (BeH34675, GenBank: MF461639) from a collection of viral isolates from the Section of Arbovirology and Hemorrhagic Fevers, Instituto Evandro Chagas (SAARB/IEC). For this study, a viral stock of ROCV strains was generated through VERO cell culture. Dulbecco’s Modified Eagle Medium (DMEM) (Gibco, USA) was used for the propagation and maintenance of cells. Cells were maintained at approximately 28°C, with weekly passages of confluent monolayers in 25cm ² plastic bottles with 10mL growth medium. ( ²2. Henriques DF , Quaresma JA , Fuzii HT , Nunes MR , Silva EV , Carvalho VL , et al . Persistence of experimental Rocio virus infection in the golden hamster (Mesocricetus auratus) . Mem Inst Oswaldo Cruz . 2012 ; 107 ( 5 ): 630 - 6 . )

The inoculated culture was observed daily under an inverted microscope to detect the cytopathogenic effect. When approximately 70% of the cells were infected, we used anti-ROCV polyclonal antibodies from SAARB/IEC and performed indirect immunofluorescence. The infected culture was maintained at -70°C. After 24 hours, the culture was defrosted and aliquoted into 1mL microtubes, which were stored at -70°C.

The viral titer, which indicates the number of infectious viral particles present in 1 mL of the viral stock, was determined by analyzing the culture plates and expressed as plaque-forming units per milliliter of culture medium (PFU/mL). The viral titer was calculated by applying the formula: PFU/mL = n x FC x 10d, where n is the average of the number of lysis plaques formed in the two wells inoculated with the highest dilution that generated isolated plaques; FCc is the correction factor, the number by which the value of the inoculum used must be multiplied to obtain 1mL (in this case, it was 10); and 10d is the inverse of the dilution in which the value of n was found. ( ³3. Baer A , Kehn-Hall K . Viral concentration determination through plaque assays: using traditional and novel overlay systems . J Vis Exp . 2014 ;( 93 ): e52065 . )

Primary culture of neural cells

Male or female neonate isogenic mice of the BALB/c strain up to 2 days old from the IEC vivarium (n=50) were used. The animals used in the experiments were sacrificed via decapitation in compliance with the CONCEA Euthanasia Practice Guidelines. ( ⁴4. Ministro de Estado da Ciência, Tecnologia, Inovações e Comunicações (MCTIC) . Normativas do CONCEA: para Produção, Manutenção ou Utilização de Animais em Ensino ou Pesquisa Científica . 3 rd ed. Brasília (DF) : MCTIC ; 2016 . ) Decapitation was performed outside the laminar flow cabinet in a Petri dish containing 70% ethanol. The animals’ heads were placed in a cabin for brain removal, which was performed on a Petri dish containing an ice-cold sterile dissection medium (Phosphate buffered saline). The brains were crushed with scissors and incubated for 5-10 minutes at 37°C in a solution of 0.05% calcium- and magnesium-free trypsin-EDTA so that the tissue could undergo enzymatic digestion. Later, the material was transferred to a 15mL falcon tube containing DMEM with 10% fetal bovine serum (FBS) and mechanically crushed with a Pasteur pipette. The cell suspension was left to rest for 2 minutes so that excess brain material could be decanted and the supernatant be collected. The cell density of the supernatant was measured using a Neubauer chamber with 50µL of Trypan blue, 40µL of saline, and 10µL of the cell suspension.

To obtain mixed cultures (neurons/glia), the cells in the supernatant were grown at a density of 5×10 ⁵ cells/well in 24-well culture plates (15.4mm in diameter and 1.91cm ² per growth area) whose wells were covered with poly-L-lysine. Each well also contained 1.5mL of neurobasal culture medium supplemented with 10% FBS, 25µM glutamate, 100IU/mL penicillin, 0.1mg/mL streptomycin, 1mM GlutaMAX ^TM (Gibco), and 0.25mM L-glutamine. The plates were kept in an incubator at 37 °C in a humidified atmosphere with 5% carbon dioxide (CO ² ). After 24 hours, this medium was changed, and the spent medium was changed every three days thereafter. ( ⁵5. Gao HM , Hong J-S , Zhang W , Liu B . Distinct role for microglia in rotenone-induced degeneration of dopaminergic neurons . J Neurosci . 2002 ; 22 ( 3 ): 782 - 90 . )

Inoculation of ROCV in primary cultures of neural cells

The volume of the viral suspension of ROCV from the viral stock used as the inoculum had a multiplicity of infection index (MOI) of 2. This MOI was selected based on the previous work of Henriques et al. ( ²2. Henriques DF , Quaresma JA , Fuzii HT , Nunes MR , Silva EV , Carvalho VL , et al . Persistence of experimental Rocio virus infection in the golden hamster (Mesocricetus auratus) . Mem Inst Oswaldo Cruz . 2012 ; 107 ( 5 ): 630 - 6 . ) The culture medium was completely removed, and the inoculum containing approximately 1×10 ⁶ infectious virions was inoculated. The treated wells, as negative controls, were inoculated using sterile neurobasal culture medium only, and the cells were subjected to the same conditions as those inoculated with ROCV. The cultures were maintained at 37 °C in an incubator with 5% CO ₂ in a humidified atmosphere and observed for cytopathic changes daily using an inverted microscope.

Phenotypic characterization of the primary neural cell cultures and detection of ROCV viral antigen via immunocytochemistry

Immunocytochemical tests were carried out using an immunoassay kit (DAKO, EUA) according to the manufacturer’s protocol. For phenotypic characterization of primary cultures of neural cells, neurons were labeled with antibodies against the NeuN protein (anti-NeuN) (DAKO, EUA), astrocytes were labeled with antibodies against glial fibrillary acidic protein (anti-GFAP) (Thermo Scientific, EUA), and microglia were labeled with antibodies against adapter-ionized (AIP) calcium-binding molecule 1 (anti-IBA 1) (DAKO). The immunohistochemical pattern of cultures was obtained by calculating the percentage of labeled cells (NeuN, GFAP, and IBA 1) in relation to the total number of cells stained, as previously reported by Kádár et al. ( ⁶6. Kádár A , Wittmann G , Liposits Z , Fekete C . Improved method for combination of immunocytochemistry and Nissl staining . J Neurosci Methods . 2009 ; 184 ( 1 ): 115 - 8 . )

The cells were analyzed using an inverted microscope. Control wells not treated with the primary antibodies were included in the test.

RESULTS

Viral stock characterization

The culture of VERO cells inoculated with the viral suspension prepared from the brains of sick animals showed cytopathogenic effects from 2 days post infection; approximately 70% of the cells showed cytopathogenic effects at 4 days post infection. The immunofluorescence test performed on samples from this culture showed strong reactivity (+++) for the ROCV antigen ( Figure 1A ) compared with the negative control ( Figure 1B ). The viral stock had a titer of 4.7×10 ⁶ PFU/mL.

Figure 1
(A) Indirect immunofluorescence of VERO cells infected with Rocio virus at 4 days post infection as labeled using polyclonal anti-ROCV antibodies; (B) Indirect immunofluorescence of uninfected (control) VERO cells. Magnification: 200×

Phenotypic characterization of primary neural cell cultures

Identification of the cell phenotype present in primary neural cell cultures via immunocytochemistry experiments was performed to detect neurons (anti-NeuN), astrocytes (anti-GFAP), and microglia (anti-IBA 1). The results revealed a heterogeneous cell composition of these three cells ( Figure 2 ). These experiments were repeated four times to ensure data reliability and reproducibility. Counterstaining using the Nissl method revealed that primary cultures consisted of 39% neurons, 28% astrocytes, and 23% microglia.

Figure 2
Immunocytochemistry of the primary mouse neural cell cultures. (A) Staining with anti-NeuN antibodies; (B) Staining with anti-GFAP antibodies; (C) Labeling with anti-Iba-1 antibodies; (D) Control cells incubated without primary antibodies. Magnification: 200×

The Nissl method uses cresyl violet staining for free-floating sections, which are then mounted and air-dried. A cresyl violet acetate solution was used to stain the cytoplasm of neurons in paraformaldehyde- or formalin-fixed tissues, and the neutrophils was stained with purple-blue granules.

Kinetics of death of primary neural cell cultures infected with the ROCV

Primary cultures of neural cells were inoculated with ROCV on the 7 ^th day of culture when the monolayer of neural cells was established and appeared sufficiently dense. After inoculation, the negative control remained healthy for up to six days as no morphological changes were observed during this period ( Figure 3A ); four replicates were conducted to assure data dependability. From the 7 ^th days post infection, the culture began to die, with cells disintegrate and progressively dying at the 10 ^th days post infection. Compared to the negative control cells, the cells inoculated with ROCV began to show cytopathogenic effects from the 2 ^nd days post infection ( Figure 3B ), with few cells exhibiting morphological changes, such as granules and cell aggregation, and a slight regression of the cell monolayer, which remained until 5 ^th days post infection. From the 6 ^th days post infection ( Figure 3C ).

Figure 3
Primary culture of mouse neural cells infected with the Rocio virus. (A) A monolayer of uninfected neural cells at 5 days post infection cultured with sterile neurobasal culture medium; (B) Rocio virus-infected neural cells at 2 days post infection; (C) Rocio virus-infected neural cells at 7 days post infection. Magnification: 200×

ROCV antigens were detected in the primary neural cell cultures via immunocytochemistry. At 5 days post infection, the cells revealed strong reactivity (+++) ( Figure 4A ) compared to the negative control, which was inoculated with sterile neurobasal culture medium only ( Figure 4B ). Four replicates of these experiments were conducted to ensure data dependability.

Figure 4
(A) Immunocytochemistry of primary mouse neural cell cultures infected with Rocio virus at the 5 th days post infection and incubated with polyclonal anti-ROCV antibodies; (B) Immunocytochemistry of uninfected primary mouse neural cell cultures and incubated with polyclonal anti-ROCV antibodies. Magnification: 200×

ROCV replication in primary neural cell cultures

Quantifying viral replication during the infectious period was performed via virus titration using samples of the spent primary culture medium following infection with ROCV at 5 days post infection. The virus titers observed at 1, 2, 3, 4, and 5 days post infection were 1×10 ⁷ , 1×10 ⁸ , 1×10 ⁷ , 1×10 ⁶ , and 7×10 ⁵ PFU/mL, respectively.

DISCUSSION

Primary cultures of neural cells are paramount to studying CNS Flavivirus infections, as they allow us to explore the intrinsic behavior of CNS cells without the interference of blood components. Several protocols for obtaining primary cultures of CNS cells have been published, encompassing various compositions of neurons and glial cells and their mode of action. ( ⁵5. Gao HM , Hong J-S , Zhang W , Liu B . Distinct role for microglia in rotenone-induced degeneration of dopaminergic neurons . J Neurosci . 2002 ; 22 ( 3 ): 782 - 90 . , ⁷7. Ju L , Zeng H , Chen Y , Wu Y , Wang B , Xu Q . Dual polarization of microglia isolated from mixed glial cell cultures . J Neurosci Res . 2015 ; 93 ( 9 ): 1345 - 52 . , ⁸8. Zhang W , Wang T , Pei Z , Miller DS , Wu X , Block ML , et al . Aggregated alpha-synuclein activates microglia: a process leading to disease progression in Parkinson’s disease . FASEB J . 2005 ; 19 ( 6 ): 533 - 42 . )

In this study, we have optimized the primary cultures of neural cells to create a representative system of the CNS, i.e., containing neurons and glia. The cell monolayers were sufficiently dense and established from the 7 ^th day of cultivation. Immunocytochemistry and counterstaining using the Nissl method revealed a heterogeneous cell composition, with the three CNS cell types present: neurons, astrocytes, and microglia ( Figure 2 ). These results corroborate the results obtained by Gao et al., ( ⁵5. Gao HM , Hong J-S , Zhang W , Liu B . Distinct role for microglia in rotenone-induced degeneration of dopaminergic neurons . J Neurosci . 2002 ; 22 ( 3 ): 782 - 90 . ) Ju et al., ( ⁷7. Ju L , Zeng H , Chen Y , Wu Y , Wang B , Xu Q . Dual polarization of microglia isolated from mixed glial cell cultures . J Neurosci Res . 2015 ; 93 ( 9 ): 1345 - 52 . ) and Zhang et al., ( ⁸8. Zhang W , Wang T , Pei Z , Miller DS , Wu X , Block ML , et al . Aggregated alpha-synuclein activates microglia: a process leading to disease progression in Parkinson’s disease . FASEB J . 2005 ; 19 ( 6 ): 533 - 42 . ) validating the paradigm of this study as an in vitro experimental model for the study of CNS infections.

Based on the cell death profile, i.e viral antigen detection by immunocytochemistry, viral titer in infected cells; enable determination of efficient replication of ROCV in neural cells. To create favorable conditions for both viral replication and the growth of primary neural cell cultures, the cells were inoculated with ROCV on the 7 ^th day of astrocytes, causing dense monolayer growth of neural cells.

Considering the neurotropism of ROCV, a broad permissiveness in the primary cultures was expected in this study after ROCV infection. This causes rapid cell destruction leading to complete death of the culture up to a maximum of 4 ^th days post infection, as shown by Diniz et al. ( ⁹9. Diniz JA , Da Rosa AP , Guzman H , Xu F , Xiao SY , Popov VL , et al . West Nile virus infection of primary mouse neuronal and neuroglial cells: the role of astrocytes in chronic infection . Am J Trop Med Hyg . 2006 ; 75 ( 4 ): 691 - 6 . ) in a model of neuronal infection using WNV. Interestingly, the cultures inoculated with ROCV showed cytopathogenic effects and subtle cell death, observed only from the 2 ^nd days post infection ( Figure 3B ), which remained constant until the 5 ^th days post infection. From 6 days post infection, cell death increased, and the number of cells in the cell monolayer until the complete death of the culture on the 7 ^th days post infection ( Figure 3C ).

This profile of primary neural cell culture death is similar to the findings of primary glial cell culture death after infection with JEV as obtained by Chen et al. ( ¹⁰10. Chen CJ , Chen JH , Chen SY , Liao SL , Raung SL . Upregulation of RANTES gene expression in neuroglia by Japanese encephalitis virus infection . J Virol . 2004 ; 78 ( 22 ): 12107 - 19 . ) In addition, Kumar et al. reported that the encephalitogenic Flavivirus generated similar profiles of cell death in cultured human neuroblastoma cells. ( ¹¹11. Kumar M , Verma S , Nerurkar VR . Pro-inflammatory cytokines derived from West Nile virus (WNV)-infected SK-N-SH cells mediate neuroinflammatory markers and neuronal death . J Neuroinflammation . 2010 ; 7 : 73 . ) The negative control cultures remained healthy for up to six days, then began to show signs of cell death and gradual disintegration of the cell monolayer from 7 ^th days post infection along with complete death of the culture on the 10 ^th days post infection. The death of the negative control cultures resulted from nutrient depletion in the growth medium. Since the control cells were not introduced to fresh media, the same conditions as ROCV-infected cultures were maintained.

Aspects inherent to the particular physiology of CNS cells should also be considered in the kinetics of primary culture death. It has been proposed that viral infections can induce the death of infected cells via necrosis or apoptosis due to inflammatory responses. ( ¹²12. Julkunen I , Melén K , Nyqvist M , Pirhonen J , Sareneva T , Matikainen S . Inflammatory responses in influenza A virus infection . Vaccine . 2000 ; 19 ( Suppl 1 ): S32 - 7 .

13. Rempel JD , Murray SJ , Meisner J , Buchmeier MJ . Differential regulation of innate and adaptive immune responses in viral encephalitis . Virology . 2004 ; 318 ( 1 ): 381 - 92 . - ¹⁴14. Holanda GM , Casseb SM , Quaresma JA , Vasconcelos PF , Cruz AC . Yellow fever virus modulates cytokine mRNA expression and induces activation of caspase 3/7 in the human hepatocarcinoma cell line HepG2 . Arch Virol . 2019 ; 164 ( 4 ): 1187 - 92 . ) Apoptosis of cells infected by Flavivirus can occur either directly as a result of viral spread or indirectly via mobile sensors that initiate cell death. Thus, apoptotic death serves as a mechanism of the innate immune response. ( ¹⁴14. Holanda GM , Casseb SM , Quaresma JA , Vasconcelos PF , Cruz AC . Yellow fever virus modulates cytokine mRNA expression and induces activation of caspase 3/7 in the human hepatocarcinoma cell line HepG2 . Arch Virol . 2019 ; 164 ( 4 ): 1187 - 92 . , ¹⁵15. Sherman KE , Rouster SD , Kong LX , Aliota MT , Blackard JT , Dean GE . Zika virus replication and cytopathic effects in liver cells . PLoS One . 2019 ; 14 ( 3 ): e0214016 . ) However, in CNS infections, neural cells regulate their immune responses to preserve the integrity of nerve tissue as they try to eliminate the virus since severe neuronal damage can cause functional damage in the host. ( ¹⁶16. Massa PT , Whitney LW , Wu C , Ropka SL , Jarosinski KW . A mechanism for selective induction of 2’-5’ oligoadenylate synthetase, anti-viral state, but not MHC class I genes by interferon-beta in neurons . J Neurovirol . 1999 ; 5 ( 2 ): 161 - 71 .

17. Gomes GF , Peixoto RD , Maciel BG , Santos KF , Bayma LR , Feitoza Neto PA , et al . Differential Microglial Morphological Response, TNFα, and Viral Load in Sedentary-like and Active Murine Models After Systemic Non-neurotropic Dengue Virus Infection . J Histochem Cytochem . 2019 ; 67 ( 6 ): 419 - 39 . - ¹⁸18. Hussmann KL , Samuel MA , Kim KS , Diamond MS , Fredericksen BL . Differential replication of pathogenic and nonpathogenic strains of West Nile virus within astrocytes . J Virol . 2013 ; 87 ( 5 ): 2814 - 22 . )

Thus, neurons and many glial cells are highly resistant to the induction of apoptosis, which is mediated by viral replication or cytotoxic cells. This is likely because of the expression of apoptotic inhibitors, such as Bcl-2, Bcl-xL, and Mcl-1, which can be activated as nerve tissue protection mechanisms. ( ¹⁹19. van Marle G , Antony J , Ostermann H , Dunham C , Hunt T , Halliday W , et al . West Nile virus-induced neuroinflammation: glial infection and capsid protein-mediated neurovirulence . J Virol . 2007 ; 81 ( 20 ): 10933 - 49 . , ²⁰20. Okamoto T , Suzuki T , Kusakabe S , Tokunaga M , Hirano J , Miyata Y , et al . Regulation of Apoptosis during Flavivirus Infection . Viruses . 2017 ; 9 ( 9 ): 243 . Review . ) Additionally, neurons regulate the expression of interferons, which are responsible for the antiviral response activation in adjacent cells. ( ¹⁶16. Massa PT , Whitney LW , Wu C , Ropka SL , Jarosinski KW . A mechanism for selective induction of 2’-5’ oligoadenylate synthetase, anti-viral state, but not MHC class I genes by interferon-beta in neurons . J Neurovirol . 1999 ; 5 ( 2 ): 161 - 71 . ) It has also been proposed that astrocytes contribute to the survival of CNS mixed primary cultures because they are more resistant to viral infection and regulate the spread of WNV in the CNS, possibly causing persistent infection. ( ⁹9. Diniz JA , Da Rosa AP , Guzman H , Xu F , Xiao SY , Popov VL , et al . West Nile virus infection of primary mouse neuronal and neuroglial cells: the role of astrocytes in chronic infection . Am J Trop Med Hyg . 2006 ; 75 ( 4 ): 691 - 6 . , ¹⁷17. Gomes GF , Peixoto RD , Maciel BG , Santos KF , Bayma LR , Feitoza Neto PA , et al . Differential Microglial Morphological Response, TNFα, and Viral Load in Sedentary-like and Active Murine Models After Systemic Non-neurotropic Dengue Virus Infection . J Histochem Cytochem . 2019 ; 67 ( 6 ): 419 - 39 . , ¹⁸18. Hussmann KL , Samuel MA , Kim KS , Diamond MS , Fredericksen BL . Differential replication of pathogenic and nonpathogenic strains of West Nile virus within astrocytes . J Virol . 2013 ; 87 ( 5 ): 2814 - 22 . )

To quantitatively determine viral replication in primary ROCV-infected cell cultures depending on the infectious period, viral load was quantified using the viral titration method at intervals of 24 hours during the first five days of the infectious period. We chose this period by considering the profile of observed cell death in primary cultures inoculated with ROCV. Interestingly, the ROCV replication kinetics results we obtained were similar to the WNV replication kinetics in neural cell cultures obtained by Kumar et al. ( ¹¹11. Kumar M , Verma S , Nerurkar VR . Pro-inflammatory cytokines derived from West Nile virus (WNV)-infected SK-N-SH cells mediate neuroinflammatory markers and neuronal death . J Neuroinflammation . 2010 ; 7 : 73 . ) and van Marle et al. ( ¹⁹19. van Marle G , Antony J , Ostermann H , Dunham C , Hunt T , Halliday W , et al . West Nile virus-induced neuroinflammation: glial infection and capsid protein-mediated neurovirulence . J Virol . 2007 ; 81 ( 20 ): 10933 - 49 . )

CONCLUSION

In conclusion, the current study reports that primary cultures of neural cells from newborn mice enable Rocio virus infection. The infection causes a mild cytopathogenic effect on the cells at 2 days post infection. The highest viral titer was observed at 5 days post infection, and culture death gradually began at 7 days post infection. Our results demonstrate the advantage of culturing primary neural cells and infecting them with the Rocio virus as an alternative central nervous system infection system to replace the in vivo model, which is practical, faster, and affordable. Moreover, this system provides an elaborate analysis of the infectious process at the cellular level and contributes to the immunologic and pathophysiological exploration of Rocio virus infection and encephalitogenic Flaviviruses.

ACKNOWLEDGEMENTS

Thanks to the Instituto Evandro Chagas / Ministry of Health and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) /Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for the financial support during the execution of this work.

REFERENCES

¹
Setoh YX , Amarilla AA , Peng NY , Slonchak A , Periasamy P , Figueiredo LT , et al . Full genome sequence of Rocio virus reveal substantial variations from the prototype Rocio virus SPH 34675 sequence . Arch Virol . 2018 ; 163 ( 1 ): 255 - 8 .
²
Henriques DF , Quaresma JA , Fuzii HT , Nunes MR , Silva EV , Carvalho VL , et al . Persistence of experimental Rocio virus infection in the golden hamster (Mesocricetus auratus) . Mem Inst Oswaldo Cruz . 2012 ; 107 ( 5 ): 630 - 6 .
³
Baer A , Kehn-Hall K . Viral concentration determination through plaque assays: using traditional and novel overlay systems . J Vis Exp . 2014 ;( 93 ): e52065 .
⁴
Ministro de Estado da Ciência, Tecnologia, Inovações e Comunicações (MCTIC) . Normativas do CONCEA: para Produção, Manutenção ou Utilização de Animais em Ensino ou Pesquisa Científica . 3 rd ed. Brasília (DF) : MCTIC ; 2016 .
⁵
Gao HM , Hong J-S , Zhang W , Liu B . Distinct role for microglia in rotenone-induced degeneration of dopaminergic neurons . J Neurosci . 2002 ; 22 ( 3 ): 782 - 90 .
⁶
Kádár A , Wittmann G , Liposits Z , Fekete C . Improved method for combination of immunocytochemistry and Nissl staining . J Neurosci Methods . 2009 ; 184 ( 1 ): 115 - 8 .
⁷
Ju L , Zeng H , Chen Y , Wu Y , Wang B , Xu Q . Dual polarization of microglia isolated from mixed glial cell cultures . J Neurosci Res . 2015 ; 93 ( 9 ): 1345 - 52 .
⁸
Zhang W , Wang T , Pei Z , Miller DS , Wu X , Block ML , et al . Aggregated alpha-synuclein activates microglia: a process leading to disease progression in Parkinson’s disease . FASEB J . 2005 ; 19 ( 6 ): 533 - 42 .
⁹
Diniz JA , Da Rosa AP , Guzman H , Xu F , Xiao SY , Popov VL , et al . West Nile virus infection of primary mouse neuronal and neuroglial cells: the role of astrocytes in chronic infection . Am J Trop Med Hyg . 2006 ; 75 ( 4 ): 691 - 6 .
¹⁰
Chen CJ , Chen JH , Chen SY , Liao SL , Raung SL . Upregulation of RANTES gene expression in neuroglia by Japanese encephalitis virus infection . J Virol . 2004 ; 78 ( 22 ): 12107 - 19 .
¹¹
Kumar M , Verma S , Nerurkar VR . Pro-inflammatory cytokines derived from West Nile virus (WNV)-infected SK-N-SH cells mediate neuroinflammatory markers and neuronal death . J Neuroinflammation . 2010 ; 7 : 73 .
¹²
Julkunen I , Melén K , Nyqvist M , Pirhonen J , Sareneva T , Matikainen S . Inflammatory responses in influenza A virus infection . Vaccine . 2000 ; 19 ( Suppl 1 ): S32 - 7 .
¹³
Rempel JD , Murray SJ , Meisner J , Buchmeier MJ . Differential regulation of innate and adaptive immune responses in viral encephalitis . Virology . 2004 ; 318 ( 1 ): 381 - 92 .
¹⁴
Holanda GM , Casseb SM , Quaresma JA , Vasconcelos PF , Cruz AC . Yellow fever virus modulates cytokine mRNA expression and induces activation of caspase 3/7 in the human hepatocarcinoma cell line HepG2 . Arch Virol . 2019 ; 164 ( 4 ): 1187 - 92 .
¹⁵
Sherman KE , Rouster SD , Kong LX , Aliota MT , Blackard JT , Dean GE . Zika virus replication and cytopathic effects in liver cells . PLoS One . 2019 ; 14 ( 3 ): e0214016 .
¹⁶
Massa PT , Whitney LW , Wu C , Ropka SL , Jarosinski KW . A mechanism for selective induction of 2’-5’ oligoadenylate synthetase, anti-viral state, but not MHC class I genes by interferon-beta in neurons . J Neurovirol . 1999 ; 5 ( 2 ): 161 - 71 .
¹⁷
Gomes GF , Peixoto RD , Maciel BG , Santos KF , Bayma LR , Feitoza Neto PA , et al . Differential Microglial Morphological Response, TNFα, and Viral Load in Sedentary-like and Active Murine Models After Systemic Non-neurotropic Dengue Virus Infection . J Histochem Cytochem . 2019 ; 67 ( 6 ): 419 - 39 .
¹⁸
Hussmann KL , Samuel MA , Kim KS , Diamond MS , Fredericksen BL . Differential replication of pathogenic and nonpathogenic strains of West Nile virus within astrocytes . J Virol . 2013 ; 87 ( 5 ): 2814 - 22 .
¹⁹
van Marle G , Antony J , Ostermann H , Dunham C , Hunt T , Halliday W , et al . West Nile virus-induced neuroinflammation: glial infection and capsid protein-mediated neurovirulence . J Virol . 2007 ; 81 ( 20 ): 10933 - 49 .
²⁰
Okamoto T , Suzuki T , Kusakabe S , Tokunaga M , Hirano J , Miyata Y , et al . Regulation of Apoptosis during Flavivirus Infection . Viruses . 2017 ; 9 ( 9 ): 243 . Review .

This article is part of the Master’s dissertation submitted by Adriano da Paixão Souto to the Graduate Program in Biotechnology at the Universidade Federal do Pará as a partial requirement for obtaining the degree of Master in Biotechnology, in 2015.
In Brief

According to Souto et al., a primary culture infected with ROCV can survive up to seven days post-infection; during this time, the viral replication rate is comparable to that of the cell death rate. Thus, this method demonstrates an alternative system for studying central nervous system infection.
Highlights

A novel in vitro experimental model was described for Rocio Flavivirus replication in a primary mouse neural cell culture.

ROCV efficiently infects primary neural cell cultures, causing cytopathic changes and cell death from the 2nd and 7th days post infection, respectively.

A higher viral titer was observed on the 2nd days post infection.

The viral replication kinetics was compatible with the cell death kinetics of ROCV-infected cultures.

Publication Dates

Publication in this collection
29 May 2023
Date of issue
2023

History

Received
03 May 2022
Accepted
16 Oct 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
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