Nepal Journal of Biotechnology. D e c . 2 0 1 8 Vol. 6, No. 1: 69-73 ISSN 2091-1130 (Print)/ISSN 2467-9319 (online) REVIEW ARTICLE ©NJB, Biotechnology Society of Nepal 69 Nepjol.info/index.php/njb Nipah Virus (NiV) Infection: Is Nepal Prepared for the Possible Outbreak? Dhiraj Shrestha1, 2*, Balkrishna Bhattachan3 1Department of Microbiology, Tri-Chandra Multiple College, Kathmandu, Nepal 2Department of Microbiology, Shi-Gan International College of Science and Technology, Kathmandu, Nepal 3Siddhi Memorial Hospital, Bhaktapur, Nepal Abstract After 20 years of the first Nipah Virus (NiV) outbreak in the world, it re-emerged as the outbreak in India. WHO has recognized NiV as a potent epidemic threat to human health. Both animal-to-human and human-to-human transmission of zoonotic NiV has been documented. Fruit bat of Pteropodidae family is the natural reservoir of the virus. Thus, the territorial habitat of these bats is the high risk zone of NiV outbreak. The symptoms are very nonspecific and the pathogenicity of NiV is yet to be fully understood. Diagnosis of NiV infection still relies on molecular techniques. Till date, no drugs or vaccines against NiV has been approved. Some research have presented arrays of the possible treatment and prevention option, but without sure shot implications. So, appropriate precautions are the only currently available prevention option. Nepal is yet to experience a NiV outbreak but that does not undermine the risk posed to the general population. High risk countries including Nepal should be well prepared to tackle the possible outbreak in future. Keywords: Nipah virus, NiV, outbreak, Nepal *Corresponding Author Email: hiraj.diamond@gmail.com Introduction Outbreaks in glance In the past few years, the outbreak of Ebola virus was on high rise throughout the world. In counter response against the virus, vaccine was developed and was being tested in high risk zones of Democratic Republic of the Congo on 19 May, 2018 [1]. Coincidentally on the same day, this was overshadowed by the news of the outbreak of the Nipah virus (NiV) in India. Initially three deaths were reported due to NiV infection. Since then 15 people have been tested positive for NiV, of which 13 are already dead. Other 16 suspected cases identified through contact tracing are under observation and at least 753 additional people are quarantined [2]. NiV is featured in the WHO list of blueprint priority diseases 2018 with potent epidemic threat demanding urgent research and development (R&D) action [3]. The first recorded outbreak of NiV occurred in 1998 in Malaysia following in Singapore in 1999. The outbreak involved severe respiratory illness in pigs and encephalitis in humans. Later outbreak involving human infections was reported from Bangladesh and India in 2001 [4,5]. Till date, more than 600 cases of NiV human infections has been documented. The outbreaks in Indian subcontinent have been recurrent [6]. Higher mortality of around 70% has been observed in Bangladesh and India, compared to mortality in Malaysia and Singapore outbreak [5]. This is probably due to higher engagement of the respiratory tract in the Bangladesh and India outbreaks, differences in pathogenicity of the viral strains and lack of advanced healthcare facilities [5]. Nipah Virus (NiV) NiV is a member of the family Paramyxoviridae, genus Henipavirus [4,7]. The name Nipah virus originated from Sungai Nipah, a Malaysian village reporting the onset of an outbreak in 1998 [7]. NiV is a zoonotic virus. Both animal-to- human transmission (from infected bats/pigs) and human-to-human transmission have been documented. During Malaysian and Singaporean outbreaks transmission occurred from infected pigs, an intermediate host. However during Bangladeshi and Indian outbreak, transmission occurred through consumption of fruits/sap contaminated with infectious bat secretions and also through Nepal Journal of Biotechnology. D e c . 2 0 1 8 Vol. 6, No. 1: 69-73 Shrestha and Bhattachan et al. ©NJB, Biotechnology Society of Nepal 70 Nepjol.info/index.php/njb human-to-human transmission. During this outbreak, no any intermediate host was reported owing to the lack of pig farms in the region [4,7]. Figure 1. Adapted from “Nipah Virus Distribution Map,” by Centers for Disease Control and Prevention (CDC) 2018, available at: https://www.cdc.gov /vhf/nipah/outbreaks/distribution-map.html. Copyright 2018 by the CDC. Adapted with permission. Natural host The natural hosts of NiV are fruit bats belonging to the Pteropodidae family, Pteropus spp. in particular [4,8]. Geographical distribution of NiV and Pteropus overlaps, ranging from Madagascar to Australia; covering South Asia, South-East Asia and Oceania region (Figure 1). Besides, African fruit bats of Pteropodidae family were also tested positive for NiV antibodies indicating further geographical distribution of NiV to African territory. NiV has also been tested positive in other animals including pigs, horses, goats, sheep, cats and dogs but only during the outbreaks [4]. Distribution map of these bats published by WHO includes Nepal however exact distribution and population of these bats are still to be studied and reported from Nepal. Pathogenesis NiV contains a negative-strand RNA. The non- segmented RNA contain six genes which encodes structural proteins of virus namely, fusion protein (F), glycoprotein (G), polymerase (L), matrix protein (M), nucleocapsid (N) and phosphoprotein (P). The P gene encodes additional three accessory proteins namely, C, V and W proteins [9,10]. V protein was the key determinants for pathogenesis in hamster and ferret infection model [11-13]. V proteins target multiple host proteins and thus suppress the host antiviral response. In addition, V proteins interact and suppress different signaling pathways. V protein suppress the dephosphorylation of melanoma differentiation-associated protein 5 (MDA5) thus inhibiting the activation of the interferon (IFN) β promoter [14-16]. V proteins also suppress the retinoic acid-inducible gene-I (RIG-I) dependent induction of IFN [17]. V proteins also block signaling through Toll-like receptors 7/9 (TLRs 7/9) and suppress IFN induction [18,19]. V proteins interact with IFN-responsive signaling pathway preventing activation and nuclear accumulation [20,21]. Similarly, C proteins regulate early host proinflammatory response thereby contributing virulence [22]. C protein was responsible for respiratory diseases in a ferret infection model [11,12]. The exact molecular mechanism of the pathogenicity of NiV is still to be revealed. Signs and symptoms The incubation time of NiV ranges between 4-14 days, and upto 45 days in some cases. Infections in human ranges from asymptomatic infection to acute respiratory infection, and fatal encephalitis in severe cases. Initial symptoms include headaches, influenza-like fever, myalgia (muscle pain), sore throat and vomiting. These symptoms are followed by acute encephalitis. Finally in severe cases, encephalitis and seizures occurs, leading to coma within 24-48 hrs. Fatality varies from 40% to 75%. Surviving cases are reported to demonstrate long-term sequel including persistent convulsions, personality change, seizure disorder, relapse and delayed onset encephalitis [4,7]. Diagnosis Initial signs and symptoms of NiV infection are nonspecific, thus accurate diagnosis is challenging especially during an outbreaks. IgM Elisa for NiV, Real-time polymerase chain reaction (RT-PCR) and viral isolation are the tests employed for diagnosis [4]. These tests demands higher technical expertise and resources challenging the effectiveness of immediate counter measures during an outbreak. Treatment Currently, no drugs or vaccines are approved for NiV infection. Supportive care with intensive care is the only recommended treatment [4,7]. https://www.cdc.gov/ Nepal Journal of Biotechnology. D e c . 2 0 1 8 Vol. 6, No. 1: 69-73 Shrestha and Bhattachan et al. ©NJB, Biotechnology Society of Nepal 71 Nepjol.info/index.php/njb Favipiravir (T-705) has been demonstrated to inhibit NiV replication and transcription in Syrian hamster model, with twice daily oral administration for 14 days [23]. Ribavirin, which has broad spectrum anti-DNA and anti-RNA virus activity and can transverse the blood-brain barrier, was also reported to reduce mortality in an open-label trial [24]. Prevention Vaccines have not been developed against NiV. However, routine and thorough disinfection of pig farms can prevent the infection. Also, avoiding the consumption of the bat eaten fruits or saliva/urine contaminated fruits/sap can prevent the infection. Thus, public awareness of the associated risk factors is the only measure to reduce risk of NiV infection. During outbreaks, suspected animal premises should be quarantined and infected animals should be culled. Also, healthcare workers caring suspected or confirmed NiV infected patients should adhere to standard infection control precautions [4]. Personal protection, such as masks, goggles, gloves, gowns, and boots, is advocated for field and farm workers of NiV risk zones. Personal protection should be accompanied by hand-washing and disinfection of equipments for better prevention [5]. Future prospects Respiratory route administration of lipopeptides prevented NiV infection in both hamsters and non-human primates. Also, retention of peptides in respiratory tract avoided systemic delivery of NiV thus increasing safety and enhancing interventions [25]. Vaccines using a vesicular stomatitis virus vector have demonstrated protection against NiV in hamsters, ferrets and African green monkeys [26]. Recently in Australia, subunit vaccines using Hendra G protein have demonstrated protection against NiV in horses by producing cross-protective antibodies. This vaccine has potential for NiV protection in humans as well [7]. We could be on verge of testing vaccine against NiV soon. Nepalese prospects Till date no outbreak of NiV or NiV confirmed mortality has been documented within the territory of Nepal. No research has been done on surveilling antibodies against NiV in Nepalese human and/or bat population. However, Nepal harbors well distribution of Pteropus bat. Pig farms are widespread throughout the country. Nepal also has significant pork eating ethnic communities. This clearly outlines the possibility of surveilling NiV in bats and/or pigs of Nepal. Furthermore, Nepal and India share open border without medical surveillance and population mobility is higher in the border region. This further adds possible risk of viral transmission in Nepal. Thus, Nepal is at high risk of potential NiV outbreak. Conclusion Twenty years ago, NiV unveiled itself to the world causing significant morbidity and mortality. Initially NiV shattered the pig- farming industry in Malaysia, and is continually causing outbreaks in Indian subcontinent. The natural reservoir Pteropus bat is widespread, thus outbreaks can occur in any risk zones. The recent outbreak in India has again increased the concern of NiV as potential threat to human health. Governments and universities should fund research to develop vaccine or drug against NiV to neutralize the potential threat. All high risk countries including Nepal, should be well prepared to tackle the possible future catastrophe. Conflict of Interest The authors declare no any conflict of interest. Funding None Authors Contribution Both authors DS and BB contributed to the work. References 1 World Health Organization (WHO): Ebola virus disease-Democratic Republic of the Congo: Update on Ring vaccination. 2018, available at: http://www.who.int/csr/don/21-may-2018- ebola-drc/en/ [accessed 23/05/2018]. 2 World Health Organization (WHO): Nipah virus - India. 2018, available at: http://www.who.int/csr/don/31-may-2018- nipah-virus-india/en/ [accessed15/06/2018]. 3 World Health Organization (WHO): R&D Blueprint. List of Blueprint priority diseases. 2018, available at: Nepal Journal of Biotechnology. 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