Detection of influenza viral gene in European starlings and experimental infection

Most recent composition of the ornithofauna of the Middle Irtysh region, Russia

Aim. The work was to compile a list of bird species and their status in the forest-steppe and steppe of the Middle Irtysh region at the present time and to analyse their potential ability in terms of the transmission of influenza viruses that pose a danger to humans and farm animals.

Materials and Methods. The study of avifauna and their status in the forest-steppe and steppe of the Middle Irtysh region has been conducted by us from 1973 to the present. The analysis of literary sources has been carried out since the time of P.S. Pallas's travels in the region in 1871. In addition, information on the wetlands of the Irtysh region which is freely available on the Internet was used.

Results. At the beginning of the 20th century, about 200 species of birds were recorded in the vicinity of Omsk, 125 of them being breeding species. At present about 150 species of birds have been recorded in Omsk and its environs. Of the 290 bird species of the Middle Irtysh region, 48 species (16.6%) belong among the natural hosts of influenza A viruses. Of these, at least 40 species are migratory and 25 species nest there. In addition to the prinicipal influenza virus host species, the list of birds of the Middle Irtysh region includes several species of scavengers and predators, as well as synanthropic bird species. These species may share habitat or food resources with the main host species of influenza viruses. Influenza A viruses can be transmitted between species either by direct or indirect contact through mechanical propagation or contamination of nutritional resources.

Conclusion. As the 3 largest bird migratory flyways run through the Middle Irtysh region where there is a significant number of wetlands, the prerequisites are created for a mass simultaneous accumulation of different populations and species of migratory birds carrying viruses and, accordingly, a high probability of exchanging viral genomes with each other and their further spread to new regions.

Strength in numbers: Avian influenza A virus transmission to poultry from a flocking passerine

The effects of flock size of European starlings (Sturnus vulgaris) was experimentally manipulated to assess the potential of influenza A virus (IAV; H4N6) transmission from a flocking passerine to bobwhite quail (Colinus virginianus) through shared food and water resources to mimic starling intrusions into free-range and backyard poultry operations. Of the three starling flock sizes tested (n = 30, n = 20 and n = 10), all successfully transmitted the virus to all or most of the quail in each animal room (6/6, 6/6 and 5/6) by the end of the experimental period, as determined by seroconversion and/or viral RNA shedding. Although starlings have been shown to be inconsistent shedders of IAVs and when they do replicate and subsequently shed virus they typically do so at low to moderate levels, this study has provided evidence that relatively small flocks (i.e., 10 or possibly a smaller number) of this species can collectively transmit the virus to a highly susceptible gallinaceous bird species. Future work should assess if starlings can transmit IAVs to additional poultry species commonly found in backyard or free-range settings.

Avian influenza A virus susceptibility, infection, transmission, and antibody kinetics in European starlings

Avian influenza A viruses (IAVs) pose risks to public, agricultural, and wildlife health. Bridge hosts are spillover hosts that share habitat with both maintenance hosts (e.g., mallards) and target hosts (e.g., poultry). We conducted a comprehensive assessment of European starlings (Sturnus vulgaris), a common visitor to both urban and agricultural environments, to assess whether this species might act as a potential maintenance or bridge host for IAVs. First, we experimentally inoculated starlings with a wild bird IAV to investigate susceptibility and replication kinetics. Next, we evaluated whether IAV might spill over to starlings from sharing resources with a widespread IAV reservoir host. We accomplished this using a specially designed transmission cage to simulate natural environmental transmission by exposing starlings to water shared with IAV-infected mallards (Anas platyrhynchos). We then conducted a contact study to assess intraspecies transmission between starlings. In the initial experimental infection study, all inoculated starlings shed viral RNA and seroconverted. All starlings in the transmission study became infected and shed RNA at similar levels. All but one of these birds seroconverted, but detectable antibodies were relatively transient, falling to negative levels in a majority of birds by 59 days post contact. None of the contact starlings in the intraspecies transmission experiment became infected. In summary, we demonstrated that starlings may have the potential to act as IAV bridge hosts if they share water with IAV-infected waterfowl. However, starlings are unlikely to act as maintenance hosts due to limited, if any, intraspecies transmission. In addition, starlings have a relatively brief antibody response which should be considered when interpreting serology from field samples. Further study is needed to evaluate the potential for transmission from starlings to poultry, a possibility enhanced by starling's behavioral trait of forming very large flocks which can descend on poultry facilities when natural resources are scarce.

European Starlings (Sturnus vulgaris) as Vectors and Reservoirs of Pathogens Affecting Humans and Domestic Livestock

European starlings are an abundant, widespread avian species frequently found in close association with human development and agriculture. The ability of starlings to carry and disperse pathogens of humans and domesticated livestock has received considerable attention, including studies of enteric bacteria, viruses, and some fungi. To investigate the importance of European starlings as disease vectors, I reviewed and assessed the available literature, comprising several hundred published papers. Although a wide variety of potential pathogens have been reported in starlings, the strongest evidence suggests that they may be responsible for harboring and dispersing some species of enteric bacteria, with Escherichia coli and Campylobacter jejuni of perhaps greatest interest, and primarily in the context of dairies, concentrated animal feeding operations, and other intensive livestock agriculture.

A Review of Avian Influenza A Virus Associations in Synanthropic Birds

Avian influenza A viruses (IAV) have received significant attention due to the threat they pose to human, livestock, and wildlife health. In this review, we focus on what is known about IAV dynamics in less common avian species that may play a role in trafficking IAVs to poultry operations. Specifically, we focus on synanthropic bird species. Synanthropic species, otherwise known as peridomestic, are species that are ecologically associated with humans and anthropogenically modified landscapes, such as agricultural and urban areas. Aquatic birds such as waterfowl and shorebirds are the species most commonly associated with avian IAVs, and are generally considered the reservoir or maintenance hosts in the natural ecology of these viruses. Waterfowl and shorebirds are occasionally associated with poultry facilities, but are uncommon or absent in many areas, especially large commercial operations. In these cases, spillover hosts that share resources with both maintenance hosts and target hosts such as poultry may play an important role in introducing wild bird viruses onto farms. Consequently, our focus here is on what is known about IAV dynamics in synanthropic hosts that are commonly found on both farms and in nearby habitats, such as fields, lakes, wetlands, or riparian areas occupied by waterfowl or shorebirds.

Surveillance for highly pathogenic H5 avian influenza virus in synanthropic wildlife associated with poultry farms during an acute outbreak

In November 2014, a Eurasian strain H5N8 highly pathogenic avian influenza virus was detected in poultry in Canada. Introduced viruses were soon detected in the United States and within six months had spread to 21 states with more than 48 million poultry affected. In an effort to study potential mechanisms of spread of the Eurasian H5 virus, the United States Department of Agriculture coordinated several epidemiologic investigations at poultry farms. As part of those efforts, we sampled synanthropic birds and mammals at five infected and five uninfected poultry farms in northwest Iowa for exposure to avian influenza viruses. Across all farms, we collected 2,627 samples from 648 individual birds and mammals. House mice were the most common mammal species captured while house sparrows, European starlings, rock pigeons, swallows, and American robins were the most commonly captured birds. A single European starling was positive for Eurasian H5 viral RNA and seropositive for antibodies reactive to the Eurasian H5 virus. Two American robins were also seropositive. No mammal species showed evidence of infection. These results indicate synanthropic species merit further scrutiny to better understand potential biosecurity risks. We propose a set of management practices aimed at reducing wildlife incursions.

Are passerine birds reservoirs for influenza A viruses?

Abstract Although peridomestic passerine species have been involved in influenza A virus (IAV) outbreaks in poultry, there is little evidence to indicate they serve as reservoirs for these viruses under natural conditions. Recent molecular-based detections of IAV in terrestrial wild birds have challenged this paradigm, and it has been suggested that additional research is warranted to better define the role of these birds as IAV hosts. To address this need, we reviewed the published literature reporting results from IAV surveillance of passerines. We also conducted prospective virologic and serologic surveillance of North American passerines for IAVs. The literature review included 60 publications from 1975-2013 that reported results from 829 species of passerines and other terrestrial birds. In our prospective study during 2010 and 2011, 3,868 serum samples and 900 swab samples were collected and tested from 102 terrestrial wild bird species from Georgia, New Jersey, Delaware, and Minnesota, USA. Antibodies to the nucleoprotein of IAV were detected with a commercial blocking enzyme-linked immunosorbent assay in 4/3,868 serum samples (0.1%); all positive samples were from Minnesota. No virus was detected in 900 swab samples by virus isolation in embryonated chicken eggs or matrix real-time reverse transcriptase PCR. Our results are consistent with historic literature; although passerines and terrestrial wild birds may have a limited role in the epidemiology of IAV when associated with infected domestic poultry or other aberrant hosts, there is no evidence supporting their involvement as natural reservoirs for IAV.