Abstract
AbstractSwine influenza A virus is one of the main viral pathogens responsible for respiratory disease in farmed pigs. Whilst outbreaks are often epidemic in nature, increasing reports suggest that continuous, endemic infection of herds is now common. The move towards larger herd sizes and increased intensification in the commercial pig industry may promote endemic infection, however, the impact that intensification has on swine influenza A virus infection dynamics and evolution is unclear. We carried out a longitudinal surveillance study over 18 months on two endemically infected, intensive pig farms. Frequent sampling of all production stages using individual and group sampling methods was performed, followed by virological and immunological testing and whole genome sequencing. We identified weaned pigs between 4-12 weeks old as the main reservoir of swine influenza A virus on the farms, with continuous, year-round infection. Despite the continuous nature of viral circulation, infection levels were not uniform, with increasing immunity at the herd level associated with reduced viral prevalence followed by subsequent rebound infection. A single virus subtype persisted on each farm for the entire duration of the study. Viral evolution was characterised by long periods of stasis punctuated by periods of rapid change coinciding with increasing immunity within the herd. An accumulation of mutations in the surface glycoproteins consistent with antigenic drift was observed, in addition to amino acid substitutions in the internal gene products as well as reassortment exchange of internal gene segments from newly introduced strains. These data demonstrate that long-term, continuous infection of herds with a single subtype is possible and document the evolutionary mechanisms utilised to achieve this.Author SummaryInfection with influenza A virus is widespread in pigs and contributes towards poor health and loss of productivity. Effective infection control measures are necessary to limit the impact of influenza on farms. However, modern farming practices are increasingly characterised by larger herd sizes and higher stocking densities. It is unclear how the move towards increased intensification impacts infectious diseases such as influenza. Accumulating evidence suggests that long-term infection of herds may be common. How influenza A virus can persist long-term is poorly understood. The aim of the current study was to monitor the infection status of pigs at each stage of the production process, measure the extent of the developing immune response and to characterise the evolutionary changes in the circulating influenza A viruses over time. Our findings provide insights into the dynamics of viral infection and evolution and may contribute to improved infection control strategies.
Publisher
Cold Spring Harbor Laboratory
Reference45 articles.
1. Olsen CW , Brown IH , Easterday BC , Van Reeth K. Swine Influenza. Dis. Swine 10th Ed. Ed. Zimmerman JZ Karriker LA Ramirez Schwartz KJ Stevenson GW. 10th ed., Wiley-Blackwell; 2012, p. 557–71.
2. Brockmeier SL , Halbur PG , Thacker EL. Porcine Respiratory Disease Complex. Polymicrob. Dis. Ed. Brogden KA Guthmiller JM, Washington (DC): ASM Press; 2002.
3. Antigenic structure of influenza virus haemagglutinin defined by hybridoma antibodies
4. The antigenic structure of the influenza virus A/PR/8/34 hemagglutinin (H1 subtype)
5. Amino acid sequence changes in antigenic variants of type A influenza virus N2 neuraminidase