key: cord-0021243-zr6mvopm authors: Fang, Yuan; Hang, Tian; Xue, Jinbo; Li, Yuanyuan; Li, Lanhua; Wei, Zixin; Yang, Limin; Zhang, Yi title: Diversity, Geography, and Host Range of Emerging Mosquito-Associated Viruses — China, 2010–2020 date: 2021-08-27 journal: China CDC Wkly DOI: 10.46234/ccdcw2021.184 sha: 295d474e210977d0f7dc5dc22112029a92c31d95 doc_id: 21243 cord_uid: zr6mvopm nan The Zika virus (ZIKV) causes a traditional mosquito-borne enzootic disease and was first identified in rhesus monkeys in Uganda in 1947, subsequently spreading in Africa, Asia, and the Pacific Islands, and expanding to Brazil in May 2015 (4) . China seemed successful in keeping the Zika pandemic at bay with only a few imported cases (5) . However, ZIKV was isolated in mosquitoes from Yunnan, Guizhou, and Jiangxi from 2016 to 2018 (6) , and 1.8% of healthy individuals in Nanning, China were positive for the ZIKV antibody (7) . This suggests the existence of the natural circulation of ZIKV between mosquitoes and humans in China even before the international public health emergency. The sudden outbreak of egg drop syndrome caused by the Tembusu virus (TMUV) quickly swept the coastal provinces and neighboring regions in 2010, resulting in severe economic loss in the poultry industry (8) . To date, records of TMUV have covered 18 provinces in China, and are mainly comprised of reports from the last decade (9) . Similarly, the Getah virus, which is mainly transmitted between mosquitoes and domestic livestock, has been spreading across China since 2010 (10) , with an outbreak on a swine farm in Hunan in 2017 (11) . Moreover, despite having a relatively short history (first detected in 1997), the Liao ning virus (LNV) has been recorded in most of Northern China, including Beijing. It was initially thought that the virus was specific to China, until the virus was isolated from 4 genera of mosquitoes collected along coastal regions of Australia during 1988 to 2014, with a characteristic insect-specific phenotype (12) . By contrast, the Chinese isolates can be replicated in mammalian cell lines and cause viremia and massive hemorrhage during re-infection of mice (13) . Aside from the mosquito-borne zoonotic and potentially pathogenic viruses, the increasing discovery of insect-specific flaviviruses (ISFVs) in the last decade is also worthy of attention ( Figure 1) . ISFVs, which are specific to insects, have both horizontal and vertical transmission routes, have diverse host relationships, and have a wide geographic distribution. This group can be divided into monophyletic classical ISFVs (cISFVs) and dual-host ISFVs (dISFVs), with the latter being more closely related to mosquito-borne pathogenic flaviviruses (MBPFVs) speculated to have lost their ability to infect vertebrate cells during their evolution (14) . There are three common cISFVs hosted by medically important mosquitoes: the Culex flavivirus (CxFV), the Quang Binh virus (QBV), and the Aedes flavivirus (AeFV) (10, 15 Since vaccines for the majority of MBVs are unavailable, vector control is the major route for routine control and epidemic disposal. However, the intensive use of insecticides in agriculture and pest management has resulted in the development and increase of insecticide resistance in mosquitoes. Therefore, it is urgent to develop novel control strategies and tools. Biological control is the traditional research hotspot, as it is sustainable and environmentally friendly. Bacteria (Bacillus thuringiensis, Wolbachia) have been wildly used in the field. By contrast, the use of fungi (Metarhizium anisopliae and Beauveria bassiana) and viruses (Densovirus) as alternative mosquito control agents remains at the laboratory or semi-field stages. Further studies on ISFVs have led to the discovery of their natural, physical, and ecological characteristics, as well as their phylogenetic status, and these clues indicate the potential of ISFVs as a novel interventional tool for vector control, most likely based on the mechanism of superinfection exclusion (17) . Moreover, because of their phylogenetic similarity, it seems that dISFVs have a greater potential to inhibit the replication of MBPFVs than cISFVs. Superinfection exclusion can occur between closely related viruses; however, more distantly related viruses do not generally interfere with each other (18) . In practice, infection with cISFV and CxFV may reportedly increase the West Nile virus (WNV) infection rate, possibly through facilitation of secondary infections with similar agents by the reduction of immune recognition (18) , and because prior infection with cell-fusing agent viruses may reduce the dissessmination titer of ZIKV and dengue virus (DENV) both in vitro and in vivo. Other studies have also shown that during instances of prior infection with dISFV, the Nhumirim virus will suppress subsequent replication of mosquito-borne flaviviruses associated with human diseases, including WNV (19) , ZIKV, and DENV (20) . Nevertheless, further studies are necessary to help us arrive at a consensus regarding whether or not the presence of ISFVs can interfere with infection by MBPFVs, which could also subsequently alter the transmission capacity of certain vector populations for several vector-borne diseases. It is also important to more thoroughly analyze the maintenance cycle of ISFVs and how they escape the host immune system. Furthermore, we should pay more attention to how ISFVs are apparently unable to affect the health of birds, domestic animals, and humans. It is noteworthy that these viruses are carried by medically important mosquitoes and likely to attack vertebrate immune system when vertebrate innate immunity pathways are disabled by known pathogenic flaviviruses (21) , which represent a potential threat to both human and animal health. Emerging and preexisting MBVs are spreading globally at an unexpected rate. MBD surveillance may have been constrained by the COVID-19 pandemic, which has drawn the most attention with regards to public health, but hampers the expansion of MBVs because of restrictions in international travel. Routine mosquito surveillance and screening for mosquitoborne pathogens can be early indicators for local disease transmission and outbreaks. These practices also highlight that wide-ranging, systematic, and continuous molecular monitoring of mosquito-borne circulating viruses in vectors is urgently needed. This monitoring would provide a comprehensive understanding of virus diversity, geographic distribution, evolution, shifts in circulating genotypes, and infection rates in China and other neighboring countries and allow accurate and timely estimations of the true disease burden and prevalence of emerging/reemerging and known mosquito-borne pathogens. This is essential to support the decision-making process regarding appropriate prevention and control strategies in China, neighboring countries, and countries involved in the Belt and Road Initiatives. Moreover, a close watch on the dynamics of mosquito insecticide resistance, alternative insecticides in certain areas, and the proper use of insect growth regulators or biocontrol approaches for integrated vector control programs should also be considered to mitigate and slow the spread and impact of insecticide resistance development in disease vector populations. The biodiversity, widespread presence, and variety of mosquito host species of ISFVs in nature shed light on means of indirect protection against the dissemination of MBVs. Ultimately, there is also an urgent need to develop an MBV vaccine using strains that are prevalent in the field to reduce the increasing health risks posed by MBVs. ) CHAOV Ae. vexans Cx. pipiens Liaoning CxFV Cx. pipiens Cx. tritaeniorhynchus An. sinensis Cx. modestus Zika virus isolated from mosquitoes: a field and laboratory investigation in China Metagenomic analysis of Flaviviridae in mosquito viromes isolated from Yunnan province in China reveals genes from Dengue and Zika viruses Emergence of Zika virus in Culex tritaeniorhynchus and Anopheles sinensis mosquitoes in China Evolution of Tembusu virus in ducks, chickens, geese, sparrows, and mosquitoes in Northern China Duck egg-drop syndrome caused by BYD virus, a new tembusu-related flavivirus Identification and molecular characterization of a novel duck Tembusu virus isolate from Southwest China Complete genome sequence of avian Tembusu-related virus strain WR isolated from White Kaiya ducks in Fujian The spread of Tembusu virus in China from 2010 to 2019 Structural, antigenic, and evolutionary characterizations of the envelope protein of newly emerging duck Tembusu virus Genomic and antigenic characterization of the newly emerging Chinese duck egg-drop syndrome flavivirus: genomic comparison with Tembusu and Sitiawan viruses An infectious disease of ducks caused by a newly emerged Tembusu virus strain in mainland China Molecular analysis and serological survey of Tembusu virus infection in Zhejiang, China Studies on mosquito natural infection with Japanese encephalitis virus in border area, Yunnan Province Genome analysis of a novel Tembusu virus in Taiwan Arbovirus investigation in some regions of Shanxi province in 2007 First report of Liaoning virus from mosquitoes in Chaoyang district Investigation of mosquitoes and arboviruses in Hexi Corridor of Gansu province, China in 2011 New subtype of coltivirus isolated from mosquitoes in the northeast part of China Liaoning virus investigation in Liaoning, Xinjiang and Yunnan Provinces and molecular characterization of Liao Ning virus isolates Institute for Viral Disease Control and Provention, Chinese Center for Disease Control and Prevention Isolation and identification of Liaoning virus from Culex modestus collected in Qinghai province 0507JS60 virus isolated in Xinjiang was identified as Liaoning virus Liao ning virus in China Isolation and identification of Liaoning virus in Xinjiang uygur autonomous region, China in 2011 First isolation and characterization of Getah virus from cattle in northeastern China Monitoring mosquito-borne arbovirus in various insect regions in China Emerging of Japanese encephalitis virus and Getah virus from specimen of mosquitoes in Inner Mongolia Autonomous Region Investigation of arbovirus in some areas of Hubei Province Isolation and identification of mosquito-borne arboviruses in Yuncheng city, Shanxi province Complete sequence characterization of isolates of Getah virus (genus Alphavirus, family Togaviridae) from China Highly pathogenic swine getah virus in blue foxes Isolation and identification of the first Getah virus (GETV) strain HNJZ-S1 from clinically suspected PRRS case of pig herd in Henan province First isolation and identification of Getah virus SC1210 in Sichuan Isolation, identification and genetic evolution analysis of pig-derived gaeta virus from Sichuan From discovery to spread: the evolution and phylogeny of Getah virus An outbreak of Getah virus infection among pigs in China Isolation and characterization of Getah virus from pigs in Guangdong province of China Emergence of Getah virus infection in horse with fever in China Isolation of Getah virus from mosquitos collected on Hainan Island, china, and results of a serosurvey Isolation and characterization of a Sagiyama virus from domestic pigs Isolation and identification of arboviruses from mosquito pools in some regions of Liaoning province A new virus of flavivirus: Chaoyang virus isolated in Liaoning Province Co-circulation of Aedes flavivirus Molecular epidemiology of mosquito-borne viruses at the China-Myanmar border: discovery of a potential epidemic focus of Japanese encephalitis Isolation of the Culex flavivirus from mosquitoes in Liaoning province Distribution and phylogenetic analysis of Culex flavivirus in mosquitoes in China Isolation and identification of mosquito-borne arboviruses in Yuncheng city First detection of the Africa/Caribbean/Latin American subtype of Culex flavivirus in Asian country Identification of Culex Flavivirus by deep sequencing approach in Xinjiang