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The Ecology of New Constituents of the Tick Virome and Their Relevance to Public Health

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The Ecology of New Constituents of the Tick Virome and Their Relevance to Public Health viruses Review The Ecology of New Constituents of the Tick Virome and Their Relevance to Public Health Kurt J. Vandegrift 1 and Amit Kapoor 2,3,* 1 The Center for Infectious Disease Dynamics, Department of Biology, The Pennsylvania State University, University Park, PA 16802, USA; [email protected] 2 Center for Vaccines and Immunity, Research Institute at Nationwide Children’s Hospital, Columbus, OH 43205, USA 3 Department of Pediatrics, Ohio State University, Columbus, OH 43205, USA * Correspondence: [email protected] Received: 21 March 2019; Accepted: 29 May 2019; Published: 7 June 2019 Abstract: Ticks are vectors of several pathogens that can be transmitted to humans and their geographic ranges are expanding. The exposure of ticks to new hosts in a rapidly changing environment is likely to further increase the prevalence and diversity of tick-borne diseases. Although ticks are known to transmit bacteria and viruses, most studies of tick-borne disease have focused upon Lyme disease, which is caused by infection with Borrelia burgdorferi. Until recently, ticks were considered as the vectors of a few viruses that can infect humans and animals, such as Powassan, Tick-Borne Encephalitis and Crimean–Congo hemorrhagic fever viruses. Interestingly, however, several new studies undertaken to reveal the etiology of unknown human febrile illnesses, or to describe the virome of ticks collected in different countries, have uncovered a plethora of novel viruses in ticks. Here, we compared the virome compositions of ticks from different countries and our analysis indicates that the global tick virome is dominated by RNA viruses. Comparative phylogenetic analyses of tick viruses from these different countries reveals distinct geographical clustering of the new tick viruses. Some of these new tick RNA viruses (notably severe fever with thrombocytopenia syndrome virus and Heartland virus) were found to be associated with serious human diseases. Their relevance to public health remains unknown. It is plausible that most of these newly identified tick viruses are of endogenous origin or are restricted in their transmission potential, but the efforts to identify new tick viruses should continue. Indeed, future research aimed at defining the origin, the ecology and the spillover potential of this novel viral biodiversity will be critical to understand the relevance to public health. Keywords: Emerging infectious disease; climate change; flavivirus; Jingmen; Alongshan; Ixodes; Haemaphysalis; Dermacentor; Ambylomma; Hyalomma 1. Introduction Ticks are obligate blood-feeding ectoparasites that belong to the class Arachnida, order Parsitoformes, and suborder Metastigmeta that is further divided into three families, Ixodidae (hard ticks), Argasidae (soft ticks) and Nuttalliellidae [1]. Ixodidae is the largest family and it includes four genera and over 700 species of tick which are distributed around the globe [2]. The World Health Organization attributes 17% of the global burden of disease to vector-borne pathogens and ticks are second to only the mosquitoes. The ability of ticks and associated pathogens to spread quickly and threaten public health is illustrated clearly by the recent problems with Lyme Disease in the United States. This disease, which manifests from an infection with the spirochete Borrelia burgdorferi [3] was first identified in Connecticut during the investigation of a cluster of infections in school children [4]. Thirty years later, in 2017, Viruses 2019, 11, 529; doi:10.3390/v11060529 www.mdpi.com/journal/viruses Viruses 2019, 11, 529 2 of 13 30,000 cases were reported to the Centers for Disease Control and 2018 reports indicate a tripling of overall vector-borne disease, but this increase is primarily driven by ticks [5]. Phylogenetic evidence reveals both the parasite and vector were present long before this recent expansion [6]. This suggests that the recent range expansion of the tick vector and associated disease outbreak is likely related to anthropogenic changes such as reductions in wildlife biodiversity, changing climatic conditions, agricultural intensification and forest fragmentation [7]. These factors are inextricably linked and they can increase interactions between ticks and new hosts, thereby facilitating transmission and the emergence of new pathogens in novel geographic areas [8]. These ongoing dynamics complicate the development of management strategies. Clearly, these efficiently transmitting vectors represent a genuine public health threat and investigations to describe pathogen diversity are warranted. While Lyme Disease illustrates the ability of tick-borne pathogens to rapidly expand in a dynamic environment, another important tick pathogen, Crimean Congo Hemorrhagic Fever (CCHF), shows the ability of these pathogens to persist endemically across a vast geographic area (30 countries), despite the notable virulence (10–40% mortality) [9]. First described in Crimea, and later linked to similar infections in the Congo, this disease can not only be spread by ticks, but is also transmissible through contact with infectious material or viremic animal tissue. The historic range of this pathogen closely mirrors the range of the main tick vector (Hyalomma marginatum marginatum), but recent outbreaks (in Turkey) have been linked to migratory birds dispersing both ticks and pathogens to new areas [10]. So, although CCHF is currently limited to the range of the main vector, other genera and species (including Ixodes spp.) of vectors have shown the ability to transmit the virus. Therefore, the potential exists for a pathogen such as CCHF to, like B. burgdorferi, expand in geographic distribution rapidly if conditions permit. Overall, the threat posed by ticks and their associated pathogens is great and additional research is needed to better understand issues such as the role of reservoirs, the dynamic ranges of vectors, and the community ecology of the enzootic reservoir and vector cycles. A combination of these factors is what leads to the spillover of pathogens into humans. Ticks are now well recognized as vectors of several highly pathogenic viruses. However, until a decade ago, only a few tick viruses were known and, among these, flaviviruses were the most well characterized for their geographical prevalence and disease association. Powassan virus is a tick-borne flavivirus present in North America and it is phylogenetically related to the tick-borne encephalitis virus group that was reported from ticks in Europe [11]. Although powassan transmission to humans is rare, the virus is highly pathogenic and often establishes neurotropic infections with fatal consequences [12]. Other flaviviruses of ticks include Kyasanur forest disease virus from the Indian subcontinent, Louping ill virus in Europe and Omsk hemorrhagic fever virus in Asia [13]. Other well-known viruses of ticks include CCHF, which is present in Africa, Asia and Europe, and Colorado tick fever virus, which is present in western United States. Due to a relatively low number of tick-borne virus infections in humans compared to mosquito-borne virus infections, no serious attempts were made to identify new tick viruses until the discovery of Severe Fever with Thrombocytopenia Syndrome virus (SFTSV) from ticks and humans in China in 2011 [14,15]. Soon after, a new pathogenic tick-borne Bunyavirus, named Heartland virus was identified from a patient in the United States [16]. These studies highlight the importance of virus discovery in ticks and, as a result, several investigators have now used metaviromics to identify the virome of ticks in the United States, Europe and more recently, in Australia. This metaviromics approach has led to the identification of a plethora of new tick viruses [17,18]. These new viruses are highly diverse genetically and often show very distant phylogenetic relatedness to well-characterized human and animal viruses and, therefore, it is difficult to predict the biological properties or host tropism. Additionally, although metaviromics is highly efficient in identifying all viruses in a given sample, the sequencing-based detection of a virus nucleic acid is not generally enough to confirm or refute an ongoing viral infection. The confirmation of an authentic infection requires the isolation of an infectious virus or at least the presence of viral nucleic acids inside the cells. Although our knowledge of viruses in ticks has expanded greatly due to this recent work, follow-up Viruses 2019, 11, 529 3 of 13 studies to define the origin, ecology and biological properties of these new tick viruses are critical for understanding their relevance to public health. 2. Tick Viruses That Infect Humans and Animals Most of the well-characterized tick-borne viruses were identified between 1950 and 1975. Long after the first realization that ticks were acting as the vector of pathogenic viruses such as Nairobi sheep disease virus and Louping ill virus in 1931, the first large-scale project to characterize tick viruses was undertaken by the Rockefeller Foundation [19]. In those days, virus discovery relied upon traditional virus isolation in cell culture or via the infection of laboratory mice, followed by virus neutralization assays and analysis of serological cross-reactivity. These efforts led to the identification of approximately 500 new arboviruses, most of these were from mosquitoes, ticks and sand flies. Unfortunately, in the absence of robust DNA sequencing methodologies and even polymerase chain reactions, the complete genome of
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