key: cord-0000216-87yq2317 authors: Amonsin, Alongkorn; Choatrakol, Chuensakon; Lapkuntod, Jiradej; Tantilertcharoen, Rachod; Thanawongnuwech, Roongroje; Suradhat, Sanipa; Suwannakarn, Kamol; Theamboonlers, Apiradee; Poovorawan, Yong title: Influenza Virus (H5N1) in Live Bird Markets and Food Markets, Thailand date: 2008-11-03 journal: Emerg Infect Dis DOI: 10.3201/eid1411.080683 sha: 0bef65699098fb63e5091c44004b59bcdb52858f doc_id: 216 cord_uid: 87yq2317 A surveillance program for influenza A viruses (H5N1) was conducted in live bird and food markets in central Thailand during July 2006–August 2007. Twelve subtype H5N1 viruses were isolated. The subtype H5N1 viruses circulating in the markets were genetically related to those that circulated in Thailand during 2004–2005. Infl uenza virus (H5N1) was identifi ed in 12 of 930 samples tested. In November 2006, a total of 5 samples with infl uenza virus (H5N1) were isolated from 1 healthy chicken and 4 visceral organs obtained from 1 live bird market (chicken) and 3 different food markets (moor hen, water cock, and quail). In December 2006, a total of 5 samples with infl uenza virus (H5N1) were isolated from 5 visceral organs (quail, water cock) from 1 food market. In January 2007, a total of 2 samples with infl uenza virus (H5N1) were isolated from 2 healthy ducks obtained from 1 live bird market. In the study, 7 isolates were sequenced for whole genome analysis, and the remaining 5 To analyze the isolates, nucleotide sequences were compared with those of infl uenza subtype H5N1 viruses in Thailand, People's Republic of China, Vietnam, Indonesia, Lao, Myanmar, and Cambodia. The sequences were aligned by using the DNASTAR program (3) to elucidate and compare the genetic changes. Phylogenetic analysis was conducted by applying the PAUP program (4) with the neighbor-joining algorithm and using branch swapping and bootstrap analysis with 1,000 replicates. In the course of the 14-month surveillance program, we isolated infl uenza virus (H5N1) from 12 samples from live birds and from bird meats obtained from the markets. Bird meats were the source of 9 virus-containing samples (5 quail, 2 moor hens, and 2 water cocks), which indicates a risk for infl uenza virus (H5N1) contamination in bird meats, especially quail. In addition, 3 highly pathogenic avian infl uenza viruses were isolated from healthy live poultry (1 chicken and 2 ducks). However, the samples that contained infl uenza virus subtype H5N1 were detected only during the 3-month winter season (November-January). A possible explanation for virus contamination in live bird and food markets may be animal movement from outbreak areas to the markets as well as an attempt to sell infected (dead or dying) birds, especially quail, as bird meat. In addition, most animals or meats in the markets came from backyard farms, where they were in unavoidably close contact with wild birds. Phylogenetic analysis of the virus HA and NA genes indicated that all 12 subtype H5N1 isolates were part of the Vietnam and Thailand lineage (clade 1). The viruses were closely related to those investigated in Thailand (2004) (2005) as well as to other subtype H5N1 isolates in clade 1. In contrast, they differed from infl uenza subtype H5N1 viruses of the south China and Indonesia lineages (clade 2) (Figure 2) . In this study, we did not discern any Thailand isolates closely related to the south China lineage, as previously established in Lao and Cambodia (5) . Phylogenetic analysis of 6 remaining genes showed them to be also closely related to the Vietnam and Thailand isolates. Analysis of the deduced amino acid sequences of the HA and NA proteins indicated that the viruses had characteristics of highly pathogenic avian infl uenza. The HA cleavage site consists of multiple basic amino acids RE-RRRKKR (in 1 isolate, CU-329, REKRRKKR). All infl uenza subtype viruses harbor Glu-222 and Gly-224 at the receptor binding site, indicating preferential binding to the avian receptor SA-α-2, 3-Gal. In addition, the virus sequences contain 7 glycosylation sites as previously identifi ed in most isolates from Thailand (6) . A glycosylation site adjacent to receptor binding sites may help increase virus infectivity in host cells (7) . In some isolates, polymorphisms of amino acids related to antigenic properties of the viruses at position V86A, L138Q, and K140N were observed. All 12 subtype H5N1 viruses had a 20-aa deletion in the NA protein, typical for the NA stalk region of recent subtype H5N1 isolates (2003) (2004) (2005) (2006) (2007) (8, 9) . None of the subtype H5N1 isolates had any amino acids indicating oseltamivir resistance at the crucial positions 119 (E), 275 Emerging Infectious Diseases • www.cdc.gov/eid • Vol. 14, No. 11, November 2008 (H), 293 (R), and 295 (N) of the NA protein. In summary, the 12 viruses isolated from this study were similar to the viruses from other sources in Thailand, which indicates that the viruses are endemic to Thailand, are circulating in the country, and can be found in any exposed species. The route of infl uenza virus (H5N1) introduction into the markets remains to be established. We suspect that this contamination might have occurred as a consequence of animal movement from outbreak areas or from viruscontaminated cages, trucks, and equipment. Unfortunately, the original sources of animals in the markets could not be identifi ed because birds from different sources were housed in 1 or several cages. Fortunately, no human infection was found during 2007-2008 in those provinces where the viruses were isolated. It has been known that live bird and wet markets play a major role in facilitating emergence or reemergence of infl uenza and some other respiratory diseases (10) (11) (12) . Moni-toring of live bird and food markets as an early warning system should be implemented in Asian countries where such markets are still commonplace, and routine surveillance of these markets should be conducted year-round. In addition, raw bird meats should be handled with caution, and consumption of raw bird meats should be avoided. Increased public awareness about the risks for infl uenza virus (H5N1) in association with live bird and food markets will help prevent and control subtype H5N1 infection in humans. Figure 2 . Phylogenetic analysis of the hemagglutinin (A) and neuraminidase genes (B) of infl uenza virus (H5N1) isolates. Phylogenetic trees were generated by using the PAUP computer program (4) and applying the neighbor-joining algorithm with branch swapping and bootstrap analysis with 1,000 replicates. The trees were rooted to A/goose/China/Guangdong/1/96 (H5N1). World Organisation for Animal Health. Manual of standards for diagnostic tests and vaccines Single-step multiplex reverse transcription-polymerase chain reaction (RT-PCR) for infl uenza A virus subtype H5N1 detection DNASTAR's Lasergene sequence analysis software Phylogenetic analysis using parsimony (*and other methods), version 4. Sunderland (MA): Sinauer Associates H5N1 infl uenza viruses in Lao People's Democratic Republic Genetic characterization of infl uenza A viruses (H5N1) isolated from 3rd wave of Thailand AI outbreaks The surface glycoproteins of H5 infl uenza viruses isolated from humans, chickens, and wild aquatic birds have distinguishable properties Large-scale sequence analysis of avian infl uenza isolates The genome sequence analysis of H5N1 avian infl uenza A virus isolated from the outbreak among poultry populations in Thailand The infl uenza virus gene pool in a poultry market in south central China Food markets with live birds as source of avian infl uenza Wet markets-a continuing source of severe acute respiratory syndrome and infl uenza? We thank Petra Hirsch for reviewing the manuscript.