Abbreviations
BDV: Borna disease virus
RNA: Ribonucleic acid
N: Nucleoprotein
P: Phosphoprotein
M: Matrix protein
G: Glycoprotein
Introduction
According to the definition of the World Health Organization, any infectious disease common between vertebrate animals and humans is classified as a zoonosis [ 1 ]. Zoonosis currently accounts for approximately 70% of emerging diseases [ 2 ] and causes 2.7 million human deaths worldwide annually [ 3 ]. The zoonotic pathogens are highly important due to the following reasons; the pathogen itself is compatible with other human hosts and is capable of causing resistant human-to-human infection without requiring to seed from the animal reservoir [ 4 ]. Early detection of the pathogens common between humans and animals through increasing laboratory capacity is a vital step toward the control and prevention of zoonosis [ 5 , 6 ].
BDV is a highly neurotropic agent in mammalian species, such as horses, sheep, rabbits, rats, mice, guinea pigs, dogs, and cattle [ 7 , 8 ]. More than 20 various genotypes from the Borna virus were extracted from different hosts, including humans, which creates a potential danger of sharing these viruses between humans and animals [ 9 ]. Selective tropism was exhibited by BDV in the nerve cells of the limbic system, especially the cortex and hippocampus, two primitive structures that control many behavioral and cognitive functions [ 10 ]. Clinical symptoms entail unusual behavior, sensorial changes, or miss of movement performance. In advanced steps, somnolence, lethargy, stupor, ataxia, and paralysis are observed. Death usually happens four weeks after the initial clinical symptoms [ 11 ]. Numerous neuropsychiatric entities have been indicated to be related to the potential markers of BDV infection in humans [ 12 ]. Several other studies have presented human cases of BDV infection in different psychiatric disorders, namely schizophrenia, learning problems, emotional disorders, and autism [ 13 - 15 ]. Some BDV-related antigens, antibodies, and RNAs were further detected in people with neurotropic symptoms, such as Parkinson's disease, chronic fatigue syndrome, Guillain-Barre syndrome, viral encephalitis, and multiple sclerosis [ 16 ]. Bornavirus was recently detected as the root reason for fatal human encephalitis following organ transplantation procedures, which remarkably enhanced the importance of this disease in humans [ 17 ].
BDV, as a negative-stranded RNA virus, has been enveloped by helical capsid [ 18 ]. BDV genome has six open reading frames, namely N, P, M, G, X, and L [ 19 ]. Molecular biological analysis has indicated that the P40/38 nucleoprotein, p10 protein, and P24 phosphoprotein are expressed continuously in the patient's cells [ 20 ]. The P24 protein has been identified at a higher ratio of P40 in the host tissue [ 21 ]. Techniques used for detecting BDV infection were indirect immunofluorescence with infected cells, western immunoblot, nested RT-PCR, real-time PCR, and ELISA [ 12 ]. Each of these methods faced problems; for example, nested PCR and real-time PCR cannot detect previous infection and there is a possibility of contamination, resulting in false positive results [ 22 , 23 ]. The establishment of ELISA is facilitated by expressing and purifying large quantities of BDV recombinant antigens for the identification of BDV antibodies in biological samples [ 24 ]. ELISA for detecting BDV infection based on different BDV antigens has been performed in several vertebrate species, but so far this method based on P24 protein has not been investigated in rabbits [ 25 , 26 ]. This study investigated the expression of P24 recombinant protein as well as the production of polyclonal antibodies against it in order to develop an ELISA for detecting BDV infection in laboratory rabbits.
Results
Borna-P24 Expression and Purification
The pET22b-Borna-P24 construct was transformed to E. coli BL21. Expression of Borna-P24 protein was induced through IPTG for 16 hours. The product of recombinant Borna-P24 protein expression was observed in SDS-PAGE. The weight range of this protein was about 25 KDa (Figure 1A). These results were validated by western blotting through anti-His-tag antibodies (Figure 1B).
Investigation of Immunized Rabbit Serum Activity by ELISA
To evaluate the immunogenicity of the recombinant protein, Borna-P24 was injected into one rabbit in four immunizations, and then, ELISA was performed to assess the immune response. The Borna-P24 protein was coated on the well and various dilutions of immunized rabbit serum were added. According to the results of the fourth injection, the antibody titer was enhanced (Figure 2). Therefore, the recombinant Borna-P24 protein had immunogenicity to induce rabbit immune response.
Investigation of Selected Rabbit’s Serum Activity by ELISA
A total of 50 New Zealand white rabbits were selected from a herd of laboratories, and their previous borna virus infection was assessed by ELISA. After collecting a peripheral blood sample from the marginal vein, the serum was isolated. In this experiment, recombinant Borna-P24 protein was used as an antigen. The result of ELISA was negative for the P24-Borna virus antibody (Figure 3). These results were similar to the negative control and no antibodies were detected in the sera of the tested rabbits.
Discussion
BDV, as a neurotropic, enveloped, negative-stranded RNA virus is responsible for the severe infections of neuron cells [ 27 ]. Evidence indicates that BDV has a wide host range that spans several vertebrate species and humans [ 28 , 29 ]. In previous studies, the P40 and P24 antibodies of the bornavirus were detected in the blood of patients with mental disorders [ 30 ]. The P40 values were higher in the chronic stage, whereas the P24 values increased in resistant infections [ 31 ].
In this study, for monitoring previous infections, we selected the P24 protein and produced polyclonal antibodies against the P24 recombinant protein for developing ELISA. The expression and purification of P24 protein were performed in large amounts. The recombinant protein was utilized for rabbit immunization. Polyclonal antibody generation in immunized rabbits was confirmed by ELISA. In addition, ELISA was performed in the selected laboratory rabbit herd, and no antibodies were detected. The results were obtained with high reproducibility.
Previous studies have proposed different methods for diagnosing BDV infection in diseased hosts. It is well known that whatever methodology is employed must be sensitive enough to diagnose the disease. Moreover, it is important to avoid the possibility of contamination and false positive results. In the past, some studies suggested diagnostic methods based on nested PCR [ 21 , 22 ]. This method has inherent problems, such as the risk of contamination during the process and the inability to quantify the result. Other studies have suggested real-time PCR as an optimal way to diagnose BDV infection [ 23 , 32 , 33 ]. In this method, despite quantifying the results, there is still a risk of sample contamination and receiving false positive results. In addition, it should be noted that the mentioned techniques require a significant investment for the required machines. Furthermore, in all types of PCR, only an active infection is identified and no previous infection is detected. Today, ELISA is an optimal and applied method in medical diagnostic laboratories. It is low-cost and allows one to check many serum samples with minimum facilities in a few hours. In previous studies, P40 protein was used as an antigen in ELISA [ 34 , 35 ]. According to other reports, the P24 protein has a higher diagnostic value than other components [ 16 , 21 , 36 ]. Therefore, the P24 protein is the preferred antigen in ELISA.
Conclusions
The results of our study indicated that ELISA based on P24 protein has a high potential for diagnosing BDV infection. These results were obtained from a study on one immunized rabbit and 50 selected rabbits.
BDV P24 gene sequence with a length of 615 bp subcloned to the expression plasmid pET22 in frame with His-tag was purchased from Biomatik (Canada) and named pET22b-Borna-P24. This sequence is located between two restriction sites NdeI at the 5´ end and XhoI at the 3´ end. The construct was transformed into E. coli BL21 using heat-shock method and one colony was grown in 500 mL Luria-Bertani broth medium and expression of P24 protein was induced through 0.05 mM concentration of IPTG for 16 hours. Bacterial sediment was collected by centrifugation for protein purification and suspension in lysis buffer (100 mM NaH2PO4, 10 mM Tris-HCl, 8 M Urea, pH 8.0). Eventually, bacteria were lysed by sonication method. After loading the lysate on the Ni-NTA resin (Qiagen, Germany) column, washing buffer was used to prepare the resin (8 M urea, 10 mM Tris–HCl, 100 mM NaH2PO4 adjust to pH 6.0) and borna P24 protein was separated using the elution buffer (8 M urea, 10 mM Tris–HCl, 100 mM NaH2PO4 adjusted to pH 4.3). Purified protein was dialyzed against PBS, and then, lyophilized and stored in -20°C. Finally, Protein concentration was determined with BCA method.
SDS-PAGE and Western Blot
To evaluate the expression of recombinant protein, 12% SDS-PAGE was used. Protein bands in polyacrylamide gel were stained by Coomassie blue. The expressed proteins in the gel were then transmitted to the nitrocellulose membrane for western blotting. The membrane was placed in 3% casein-blocking buffer overnight at 4°C and then, washed with PBS three times. The membrane was incubated with 1/1000 anti-His tag antibody as a primary antibody and then with 1/2000 anti-rabbit HRP-conjugated as a secondary antibody. The membrane was stained with 3, 3´-diaminobenzidine solution.
Production of P24 Polyclonal Antibody
A New Zealand female rabbit was used for immunization. Fifty micrograms of Borna-P24 recombinant protein were injected subcutaneously into the rabbit. Immunization was boosted four times at two-week intervals. A recombinant protein with complete Freund’s adjuvant was used in the initial injection and incomplete adjuvant in others. Rabbits were bled from the marginal ear vein. Finally, specific polyclonal antibody titration was performed by ELISA. An amount of 1 μg/mL of recombinant Borna-P24 protein was coated in each well of the ELISA plate and was placed overnight at 4°C. Then, the plate was blocked by 3% skimmed milk and placed at room temperature for up to 1 h. PBS was used to wash the wells five times and 100 μL of serially diluted rabbit serum (1/100 to 1/3200) was added to each well and placed at room temperature for 1 h. With washing intervals, 100 μL of 1/2000 anti-rabbit HRP-conjugated was added and then, the plate was placed at room temperature for 1 h. One hundred microliter of 3, 3´, 5, 5´-tetramethylbenzidine substrate was added to all wells, and the plate was incubated at room temperature for 10 min in the dark. Finally, the reaction was stopped by adding 100 μL of stop buffer (H2SO4, 2N) into all wells. Optical density was read at the wavelength of 450 nm by a UV/Vis spectrophotometer (Epoch, BioTek, USA).
Investigation of Serum Titers Against Borna-P24 in Rabbits Herd
Fifty New Zealand rabbits were selected at the laboratory animal center of the Pasteur Institute of Iran (Karaj, Iran). After blood sampling and isolation of serum, ELISA was performed with 1/1000 serum dilution. Rabbit serum immunized with Borna-P24 was used as a positive control.
Authors' Contributions
Seyedeh Narjes Sadat performed a number of practical experiments, Writing - original draft, Writing - review & editing, and reduction of the manuscript. Sahar Khalvand, Behzad Ramezani and Hajarsadat Ghaderi performed a large number of practical experiments. Mahdi Habibi-Anbouhi and Fatemeh Kazemi-Lomedasht served as advisor. Mahdi Behdani; Writing - review & editing, served as advisors, supervision, formal analysis, reduction of the manuscript.
Acknowledgements
The authors wish to express their gratitude to all who provided support during the course of this research, especially Zahra Amirinia and Roghayeh Moghadam in KBC. This project was financially supported by KBC.
Conflict of interest
The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
Abbreviations-Cont'd
X: p10 protein
L: Large protein
PCR: Polymerase chain reaction
RT-PCR: Reverse transcription PCR
ELISA: Enzyme-linked immunosorbent assay
IPTG: Isopropyl-beta-d-thiogalactopyranoside
PBS: Phosphate-buffered saline
SDS-PAGE: Sodium dodecyl sulfate-polyacrylamide gel electrophoresis
HRP: Horseradish peroxidase
RT: Room temperature
TMB: Tetramethylbenzidine
References
- Rahman MT, Sobur MA, Islam MS, Ievy S, Hossain MJ, El Zowalaty ME, et al. Zoonotic Diseases: Etiology, Impact, and Control. Microorganisms. 2020; 8(9)DOI
- Wang LF, Crameri G. Emerging zoonotic viral diseases. Rev Sci Tech. 2014; 33:569-581. DOI
- Gebreyes WA, Dupouy-Camet J, Newport MJ, Oliveira CJ, Schlesinger LS, Saif YM, et al. The global one health paradigm: challenges and opportunities for tackling infectious diseases at the human, animal, and environment interface in low-resource settings. PLoS Negl Trop Dis. 2014; 8:e3257. DOI
- Lo Iacono G, Cunningham AA, Fichet-Calvet E, Garry RF, Grant DS, Leach M, et al. A Unified Framework for the Infection Dynamics of Zoonotic Spillover and Spread. PLoS Negl Trop Dis. 2016; 10:e0004957. DOI
- Rabaa MA, Tue NT, Phuc TM, Carrique-Mas J, Saylors K, Cotten M, et al. The Vietnam Initiative on Zoonotic Infections (VIZIONS): A Strategic Approach to Studying Emerging Zoonotic Infectious Diseases. Ecohealth. 2015; 12:726-735. DOI
- Grant C, Lo Iacono G, Dzingirai V, Bett B, Winnebah TR, Atkinson PM. Moving interdisciplinary science forward: integrating participatory modelling with mathematical modelling of zoonotic disease in Africa. Infect Dis Poverty. 2016; 5:17. DOI
- Kinnunen PM, Palva A, Vaheri A, Vapalahti O. Epidemiology and host spectrum of Borna disease virus infections. J Gen Virol. 2013; 94:247-262. DOI
- Zhang L, Wang X, Zhan Q, Wang Z, Xu M, Zhu D, et al. Evidence for natural Borna disease virus infection in healthy domestic animals in three areas of western China. Arch Virol. 2014; 159:1941-1949. DOI
- Komorizono R, Sassa Y, Horie M, Makino A, Tomonaga K. Evolutionary Selection of the Nuclear Localization Signal in the Viral Nucleoprotein Leads to Host Adaptation of the Genus Orthobornavirus. Viruses. 2020; 12(11):1291. DOI
- Bonnaud EM, Szelechowski M, Betourne A, Foret C, Thouard A, Gonzalez-Dunia D, et al. Borna disease virus phosphoprotein modulates epigenetic signaling in neurons to control viral replication. J Virol. 2015; 89:5996-6008. DOI
- Kupke A, Becker S, Wewetzer K, Ahlemeyer B, Eickmann M, Herden C. Intranasal Borna Disease Virus (BoDV-1) Infection: Insights into Initial Steps and Potential Contagiosity. Int J Mol Sci. 2019; 20(6)DOI
- Lipkin WI, Briese T, Hornig M. Borna disease virus - fact and fantasy. Virus Res. 2011; 162:162-72. DOI
- Honda T, Sofuku K, Matsunaga H, Tachibana M, Mohri I, Taniike M, et al. Detection of Antibodies against Borna Disease Virus Proteins in an Autistic Child and Her Mother. Jpn J Infect Dis. 2017; 70:225-227. DOI
- Honda T, Sofuku K, Matsunaga H, Tachibana M, Mohri I, Taniike M, et al. Prevalence of antibodies against Borna disease virus proteins in Japanese children with autism spectrum disorder. Microbiol Immunol. 2018; 62:473-6. DOI
- Williams BL, Hornig M, Yaddanapudi K, Lipkin WI. Hippocampal poly(ADP-Ribose) polymerase 1 and caspase 3 activation in neonatal bornavirus infection. J Virol. 2008; 82:1748-1758. DOI
- Zhang L, Xu MM, Zeng L, Liu S, Liu X, Wang X, et al. Evidence for Borna disease virus infection in neuropsychiatric patients in three western China provinces. Eur J Clin Microbiol Infect Dis. 2014; 33:621-627. DOI
- Korn K, Coras R, Bobinger T, Herzog SM, Lucking H, Stohr R, et al. Fatal Encephalitis Associated with Borna Disease Virus 1. N Engl J Med. 2018; 379:1375-1377. DOI
- Lutz H, Addie DD, Boucraut-Baralon C, Egberink H, Frymus T, Gruffydd-Jones T, et al. Borna disease virus infection in cats: ABCD guidelines on prevention and management. J Feline Med Surg. 2015; 17:614-616. DOI
- Briese T, Schneemann A, Lewis AJ, Park YS, Kim S, Ludwig H, et al. Genomic organization of Borna disease virus. Proc Natl Acad Sci U S A. 1994; 91:4362-4366. DOI
- McHugh JM, de Kloet SR. Bornavirus antigens in psittaciformes infected with psittaciform bornavirus and their use in diagnostic procedures. Archives of Veterinary Science and Medicine. 2020; 3:83-108.
- Li Q, Wang Z, Zhu D, Xu M, Chen X, Peng D, et al. Detection and analysis of Borna disease virus in Chinese patients with neurological disorders. Eur J Neurol. 2009; 16:399-403. DOI
- Soltani H, Mohammadzadeh S, Makvandi M, Pakseresht S, Samarbaf-Zadeh A. Detection of Borna Disease Virus (BDV) in patients with first episode of schizophrenia. Iranian Journal of Psychiatry. 2016; 11:257.
- Zhang L, Liu S, Zhang L, You H, Huang R, Sun L, et al. Real-time qPCR identifies suitable reference genes for Borna disease virus-infected rat cortical neurons. Int J Mol Sci. 2014; 15:21825-39. DOI
- Ikuta K, Ibrahim MS, Kobayashi T, Tomonaga K. Borna disease virus and infection in humans. Front Biosci. 2002; 7:d470-95.
- McHugh JM, de Kloet SR. The detection of bornavirus in birds, mammals and snakes by sandwich ELISA of bornaviral matrix protein. Archives of Veterinary Science and Medicine. 2021; 4:85-102.
- Neumann B, Angstwurm K, Linker RA, Knoll G, Eidenschink L, Rubbenstroth D, et al. Antibodies against viral nucleo-, phospho-, and X protein contribute to serological diagnosis of fatal Borna disease virus 1 infections. Cell Rep Med. 2022; 3:100499. DOI
- Liu S, Bode L, Zhang L, He P, Huang R, Sun L, et al. GC-MS-Based Metabonomic Profiling Displayed Differing Effects of Borna Disease Virus Natural Strain Hu-H1 and Laboratory Strain V Infection in Rat Cortical Neurons. Int J Mol Sci. 2015; 16:19347-68. DOI
- Hagiwara K, Tsuge Y, Asakawa M, Kabaya H, Okamoto M, Miyasho T, et al. Borna disease virus RNA detected in Japanese macaques (Macaca fuscata). Primates. 2008; 49:57-64. DOI
- He M, An TZ, Teng CB. Evolution of mammalian and avian bornaviruses. Mol Phylogenet Evol. 2014; 79:385-91. DOI
- Fukuda K, Takahashi K, Iwata Y, Mori N, Gonda K, Ogawa T, et al. Immunological and PCR analyses for Borna disease virus in psychiatric patients and blood donors in Japan. J Clin Microbiol. 2001; 39:419-29. DOI
- Geib T, Sauder C, Venturelli S, Hassler C, Staeheli P, Schwemmle M. Selective virus resistance conferred by expression of Borna disease virus nucleocapsid components. J Virol. 2003; 77:4283-90. DOI
- Barrantes X, Silva S, Macaya G, Bonilla JA. Detection of borna virus disease by real-time RT-PCR in Costa Rican equines and humans. Archives of Clinical Microbiology. 2012; 3(1)DOI
- Jin G, Xu X, Zhang L, Ma L, Huang R, Deng J, et al. Optimization of PCR buffer for Borna disease virus real-time PCR diagnostic kit. Journal of Third Military Medical University. 2011; 33:1323-27.
- Zhai A-x, Li A-m, Song W-q, Kao W-p, Qian J, Li Y-j, et al. Infection of Borna disease virus in healthy animals in northern China. Asian Pacific Journal of Tropical Medicine. 2018; 11:S30.
- de Kloet AH, Kerski A, de Kloet SR. Diagnosis of Avian bornavirus infection in psittaciformes by serum antibody detection and reverse transcription polymerase chain reaction assay using feather calami. J Vet Diagn Invest. 2011; 23:421-9. DOI
- Ma L, Deng R, Xu X, Yang H, Xie P. Preparation and identification of monoclonal antibody against phosphoprotein of Borna disease virus. Chinese Journal of Zoonoses. 2017; 33:779-783.
Send comment about this article