Evaluation and comparison of hemagglutination inhibition and indirect immunofluorescence tests for the detection of antibodies against duck Tembusu virus.

Currently, duck Tembusu virus (DTMUV), an emerging avian pathogenic flavivirus, is widely spread and becomes endemic in duck populations in Asia, causing significant economic losses in the duck producing industry. To early detection and control of DTMUV, the well-validated diagnostic tests for efficient detection of DTMUV infection in ducks are needed. In this study, we validated and compared hemagglutination inhibition (HI) and indirect immunofluorescence (IFA) tests for identifying antibodies against DTMUV in duck serum samples. Our results demonstrated that HI and IFA tests can both be used to detect antibodies against DTMUV in duck serum samples with high sensitivity (100%), specificity (>87%) and overall agreement with the gold standard serum neutralization (SN) test (>90%). Additionally, DTMUV-specific antibody titres determined by HI and IFA tests correlated well with the neutralizing antibody titres obtained by SN test. No cross-reactivity against common duck viruses and other flaviviruses was observed in both tests. It is interesting to note that HI test had higher diagnostic specificity and exhibited a stronger positive correlation with SN test than IFA test. Evaluating the performance of HI and IFA tests with experimental and field serum samples revealed that both tests showed comparable performance with SN test in terms of antibody kinetic and detection rate. Collectively, these findings support the use of both tests, particularly HI test, as the alternative to SN test for measuring the antibody responses against DTMUV in ducks. These tests could be the suitable choices for DTMUV diagnosis, epidemiological study and vaccine efficacy evaluation.

Patterns of duck Tembusu virus infection in ducks, Thailand: a serological study.

Duck Tembusu virus (DTMUV), a mosquito-borne flavivirus, has been identified as a causative agent of an emerging viral disease in ducks, causing significant economic losses to the duck-producing industry. In Thailand, DTMUV has been detected sporadically in ducks since the first report in 2013. However, information on the patterns of DTMUV infection in ducks in Thailand is limited. In this study, a serological survey of DTMUV on ducks raised in farming and free-grazing systems was conducted during 2015-2016. Blood samples of farm ducks (n = 160) and free-grazing ducks (n = 240) were collected in the summer, rainy, and winter seasons during 2015-2016 and tested for DTMUV infection. Our results showed that DTMUV infection in ducks in Thailand occurred all year-round; however, the patterns of DTMUV infection varied between 2 duck-raising systems. Significant seasonal pattern was found in free-grazing ducks, whereas no seasonality was observed in farm ducks. Notably, DTMUV infection in ducks in Thailand was highest in the winter season. In conclusion, our data indicate distinct patterns of DTMUV infection between farm and free-grazing ducks, and the year-round circulation of DTMUV in ducks in Thailand, with peaks in the winter season. This information will help reduce the risk of DTMUV transmission through prevention and control strategies focusing on the peak period. Routine surveillance of DTMUV in ducks is essential for early detection of DTMUV allowing the implementation of control measures in a timely manner.

Evaluation of host systems for efficient isolation and propagation of duck Tembusu virus.

Several phylogenetic clusters of duck Tembusu virus (DTMUV) that caused outbreaks in ducks in Asia have been identified since its emergence in 2010, highlighting the need for an efficient host system that can support isolation of all circulating phylogenetic clusters of DTMUV. In this study, various host systems, including different avian embryonated eggs (duck and chicken) and cell cultures (primary duck embryo fibroblast (DEF), primary chicken embryo fibroblast (CEF), baby hamster kidney (BHK-21), African green monkey kidney (Vero) and Aedes albopictus clone C6/36 (C6/36) cells), were evaluated and compared for their ability to support DTMUV isolation and propagation. Our results showed that all host systems were susceptible to DTMUV infection; however, BHK-21 and primary DEF cells supported more efficient replication of DTMUV compared to the other host systems. BHK-21 cells had the highest DTMUV isolation rate when tested with experimental and field clinical samples. All circulating phylogenetic clusters of DTMUV, including clusters 1, 2 and 3, were successfully isolated from duck clinical samples using BHK-21 cells. In conclusion, our findings supported the use of BHK-21 cells as a host system for primary isolation of all circulating phylogenetic clusters of DTMUV from duck clinical samples. This study highlights the importance of selecting the most appropriate host system for efficient isolation and propagation of DTMUV from duck clinical samples.RESEARCH HIGHLIGHTS DTMUV replicated more efficiently in BHK-21 and primary DEF cells than in other host systems tested.BHK-21 cells had the highest DTMUV isolation rate.All DTMUV phylogenetic clusters were successfully isolated from the samples using BHK-21 cells.BHK-21 cells were the most efficient host system for DTMUV isolation.

Development and Validation of a Universal One-Step RT-PCR Assay for Broad Detection of Duck Tembusu Virus.

Duck Tembusu virus (DTMUV), a mosquito-borne flavivirus, has been identified as a causative agent of an emerging disease in ducks. Since its first report in 2010, several clusters of DTMUV have increasingly been identified and caused outbreaks in many Asian countries. This highlights the need for improved and novel broad detection assays in order to detect all circulating clusters of DTMUV. In this study, a universal one-step reverse-transcription PCR (RT-PCR) assay targeting a highly conserved region of the NS5 gene was developed and validated for broad detection of all DTMUV clusters. The newly developed universal RT-PCR assay could specifically detect all clusters of DTMUV without cross-reactions with common duck viruses and other related flaviviruses. The assay was able to detect DTMUV as low as a 0.001 50% embryo lethal dose/milliliter. The performance of the assay was evaluated by using experimental and field clinical samples. The assay could successfully detect DTMUV in all experimentally DTMUV-infected samples and gave a higher DTMUV detection rate (36%) than the previously reported envelope-specific RT-PCR assay (30%) in field clinical samples. All the positive samples were confirmed DTMUV-positive by DNA sequencing. In conclusion, the newly developed universal RT-PCR assay exhibited high accuracy, specificity, and sensitivity in broad DTMUV detection, thus providing an improved screening assay for routine detection and epidemiologic surveillance of DTMUV.

Pathogenesis of Thai duck Tembusu virus in Cherry Valley ducks: The effect of age on susceptibility to infection.

Several duck Tembusu virus (DTMUV) clusters have been identified since its first emergence in 2010. However, the pathogenesis evaluation of DTMUV has been restricted to cluster 2.2 Chinese DTMUVs. In this study, the pathogenesis of a cluster 2.1 Thai DTMUV was investigated in three ages of Cherry Valley ducks (1-, 4- and 27-week-old). In each age, 35 ducks were inoculated with a cluster 2.1 Thai DTMUV and evaluated for clinical signs, virus distribution and shedding, pathology and serological response. Our results demonstrated that all duck ages were susceptible to Thai DTMUV; however, Thai DTMUV induced greater disease severity in younger ducks (1- and 4-week-old) when compared to older ducks (27-week-old) reflected by higher morbidity and mortality rates, and higher degree of pathological severity. Corresponding to these results, longer-term viremia, higher levels of viral loads in tissues and lower neutralizing antibody titers were also observed in younger ducks compared to those in older ducks. However, it should be noted that a significant drop in egg production was found in older ducks, which also indicates the susceptibility to Thai DTMUV in older ducks. Interestingly, prolonged shedding period with high viral loads was observed in older ducks even without showing clinical signs, suggesting the potential role of the older ducks as the carriers of Thai DTMUV. This finding highlights the importance of monitoring DTMUV and preventing the transmission of DTMUV in adult ducks. Overall, this study provides insights into the pathogenesis and infection dynamics of a cluster 2.1 Thai DTMUV in ducks.

Genetic characterization of duck Tembusu virus in Thailand, 2015-2017: Identification of a novel cluster.

Duck Tembusu virus (DTMUV) infected cases have increasingly been observed in several duck farms in Thailand since its first report in 2013. However, information on the genetic characteristic of DTMUVs recently circulating in ducks in Thailand is limited. In this study, we investigated the geographic distribution and genetic characteristic of DTMUVs recently circulating in ducks in Thailand during 2015-2017. Of the 288 clinical samples obtained from 89 ducks farms located in duck raising areas of Thailand, 65 samples (22.57%) of 34 duck farms (38.20%) were DTMUV positive. Our results demonstrated that DTMUV was extensively distributed in duck raising areas of Thailand. Phylogenetic analysis of the E and NS5 genes revealed that DTMUVs circulating in Thailand were divided into three distinct clusters, including cluster 1, subcluster 2.1 and a novel cluster 3. Among these three clusters, subcluster 2.1 was a predominant cluster of DTMUV circulating in duck populations in Thailand during 2015-2017. It is interesting to note that a novel cluster of DTMUV (cluster 3), which was genetically different from any of the previously reported DTMUV clusters, was first identified in this study. In conclusion, our data demonstrated the circulation of different clusters of DTMUV and the presence of a novel DTMUV cluster in ducks in Thailand. This study highlights the high genetic diversity of DTMUVs in Thailand and the necessity of the routine surveillance of DTMUV for early detection, prevention and control of newly emerging DTMUVs.

Serological evidence of duck Tembusu virus infection in free-grazing ducks, Thailand.

Duck Tembusu virus (DTMUV) has been reported in ducks raised in farming system since its emergence in 2010. No information is available on DTMUV infection in free-grazing ducks, which are commonly raised and widespread in several Asian countries. To determine the presence of DTMUV infection in free-grazing ducks in Thailand, retrospective serum samples collected from 1,000 free-grazing ducks during 2008-2015 were tested for DTMUV infection. Our result showed that 91 (9.10%) were positive for DTMUV neutralizing antibodies and DTMUV seropositive ducks have been detected in Thailand since 2008. To further investigate the seroprevalence and geographic distribution of DTMUV infection in free-grazing ducks in Thailand, a cross-sectional serological survey of DTMUV was conducted in 2016. Of 1,200 free-grazing ducks in the 60 flocks from 20 provinces located in the major free-grazing duck raising areas of Thailand, 365 (30.42%) were positive for DTMUV neutralizing antibodies and 56 flocks (93.33%) had at least one DTMUV seropositive duck. Additionally, DTMUV seropositive ducks were observed in all provinces tested. In conclusion, our data demonstrated the presence of DTMUV infection in free-grazing ducks since 2008 and widespread DTMUV infection in free-grazing ducks in Thailand with a relatively high seroprevalence. These findings suggest the potential role of free-grazing ducks in the dissemination of DTMUV and highlight the necessity of systemic DTMUV surveillance in free-grazing ducks in addition to farm ducks for early detection, prevention, and control of this emerging disease.

In vitro characterization of the novel H3N1 reassortant influenza viruses from quail.

Quail is considered as an intermediate host for generation of the novel reassortant influenza A viruses (IAVs). In this study, we evaluated the replication ability of the three novel H3N1 reassortant viruses recovered from pandemic H1N1 2009 (pH1N1) and duck H3N2 (dkH3N2) co-infected quail generated from our previous study in embryonated chicken eggs, mammalian (MDCK) and human lung derived (A549) cells. Our study demonstrated that all of the reassortant viruses replicated efficiently in avian and mammalian cells, albeit with slightly lower titers than the parental viruses. Of note, all of the reassortant viruses showed enhanced replication in human lung derived A549 cells compared to their parental viruses. Interestingly, among the reassortant viruses tested, a reassortant virus (P(NA,NS)-DK) containing NA and NS genes derived from pH1N1 and the other genes from dkH3N2 exhibited the highest replication ability in all in vitro models, indicating a high level of gene compatibility of this reassortant virus. Our results highlight the potential role of quail as intermediate hosts for the generation of the viable reassortant viruses with ability to replicate efficiently in avian, mammalian, and particularly human lung derived cells. These findings emphasize the need for the continuous IAV surveillance in quail to prevent the risk of the emergence of the novel viable reassortant viruses.

Tembusu-Related Flavivirus in Ducks, Thailand.

Since 2013, outbreaks of disease caused by duck Tembusu virus (DTMUV) have been observed in layer and broiler duck farms in Thailand. The virus is closely related to Chinese DTMUVs and belongs to the Ntaya group of mosquitoborne flaviviruses. These findings represent the emergence of DTMUV in ducks in Thailand.

Hepatitis E virus genotype 3f sequences from pigs in Thailand, 2011-2012.

Phylogenetic analysis of partial ORF1 and ORF2 genes of Hepatitis E virus (HEV) strains from pigs in Thailand during 2011-2012 was performed. The result indicated that the current Thai strains belonged to the genotype 3 subgroup 3f, which were similar to the previous HEVs circulating in humans in Thailand.

Comparative study of pandemic (H1N1) 2009, swine H1N1, and avian H3N2 influenza viral infections in quails.

Quail has been proposed to be an intermediate host of influenza A viruses. However, information on the susceptibility and pathogenicity of pandemic H1N1 2009 (pH1N1) and swine influenza viruses in quails is limited. In this study, the pathogenicity, virus shedding, and transmission characteristics of pH1N1, swine H1N1 (swH1N1), and avian H3N2 (dkH3N2) influenza viruses in quails was examined. Three groups of 15 quails were inoculated with each virus and evaluated for clinical signs, virus shedding and transmission, pathological changes, and serological responses. None of the 75 inoculated (n = 45), contact exposed (n = 15), or negative control (n = 15) quails developed any clinical signs. In contrast to the low virus shedding titers observed from the swH1N1-inoculated quails, birds inoculated with dkH3N2 and pH1N1 shed relatively high titers of virus predominantly from the respiratory tract until 5 and 7 DPI, respectively, that were rarely transmitted to the contact quails. Gross and histopathological lesions were observed in the respiratory and intestinal tracts of quail inoculated with either pH1N1 or dkH3N2, indicating that these viruses were more pathogenic than swH1N1. Sero-conversions were detected 7 DPI in two out of five pH1N1-inoculated quails, three out of five quails inoculated with swH1N1, and four out of five swH1N1-infected contact birds. Taken together, this study demonstrated that quails were more susceptible to infection with pH1N1 and dkH3N2 than swH1N1.

Quail as a potential mixing vessel for the generation of new reassortant influenza A viruses.

Quail has been proposed as one of the intermediate hosts supporting the generation of newly reassortant influenza A viruses (IAVs) with the potential to infect humans. To evaluate the role of quail as an intermediate host of IAVs, co-infections of quail with swine-origin pandemic H1N1 2009 (pH1N1) and low pathogenic avian influenza (LPAI) duck H3N2 (dkH3N2) viruses (n=10) or endemic Thai swine H1N1 (swH1N1) and dkH3N2 viruses (n=10) were conducted. Three additional groups of five quail were each inoculated with pH1N1, swH1N1 and dkH3N2 as control groups to verify that each virus can infect quail. Our result showed that co-infected quail shed higher viral titers from the respiratory tract than single virus infected quail. This study confirmed that reassortant viruses could be readily generated in the respiratory tract of quail from both the pH1N1/dkH3N2 co-infected group (100% of quail generating reassortant viruses) and the swH1N1/dkH3N2 (33% of quail generating reassortant viruses) co-infected group without discernible clinical signs. The reassortment efficacy between the two combination of viruses was different in that the frequency of reassortant viruses was significantly higher in pH1N1/dkH3N2 co-infected quail (21.4%) compared to swH1N1/dkH3N2 co-infected quail (0.8%), indicating that gene combinations in pH1N1 have a higher potential to reassort with dkH3N2 compared to swH1N1. In summary, our result confirmed that quail could be an intermediate host of IAVs for generating new reassortant viruses. Our finding highlights the importance of monitoring IAVs especially pH1N1 in quail.

Single-step multiplex reverse transcription polymerase chain reaction assay for detection and differentiation of the 2009 H1N1 Influenza A virus pandemic in Thai swine populations.

A recently emerged H1N1 Influenza A virus (pandemic H1N1 (pH1N1)) with a Swine influenza virus (SIV) genetic background spread globally from human-to-human causing the first influenza virus pandemic of the 21st century. In a short period, reverse zoonotic cases in pigs followed by a widespread of the virus in the pig population were documented. The implementation of effective control strategies, rapid diagnosis, and differentiation of such virus from endemically circulating SIV in the various swine populations of the world is needed. To address the problem, a multiplex reverse transcription polymerase chain reaction assay utilizing a combination of the PB1, H1, and N1 primers that can rapidly and simultaneously subtype and screen for the presence of pH1N1 virus infection in Thai pigs was developed. The assay had 100% specificity and did not amplify genetic material from other subtypes of SIV, seasonal H1N1 human influenza (huH1N1) virus, highly pathogenic influenza H5N1 virus, and other important swine respiratory viral pathogens. The assay was able to both detect and subtype pH1N1 virus as low as 0.1-50% tissue culture infective doses/ml (TCID(50)/ml). The assay was used to screen 175 clinical samples obtained from SIV suspected cases, of which 6 samples were pH1N1 positive and were confirmed through virus isolation and whole genome sequencing. The results of the study suggested that the assay would be useful for the rapid diagnosis of pH1N1 in suspected Thai swineherds, where genetics of the endemically circulating SIV differ from the strains circulating in North American and European herds.

Serological evidence of pig-to-human influenza virus transmission on Thai swine farms.

We investigated influenza interspecies transmission in two commercial swine farms in Thailand. Sera from swine-exposed workers (n=78), age-matched non-swine-exposed healthy people (n=60) and swine populations in both farms (n=85) were studied. Hemagglutination-inhibition (HI) assay was performed on Thai swine H1 viruses (swH1N1 and swH1N2) isolated from both farms. Thai human H1N1 (huH1N1) and pandemic H1N1 2009 (pH1N1) were also used as test antigens. The hemagglutinin (HA) 1 genes of swH1N1 and swH1N2 viruses were sequenced and shown to be genetically distinct from the Thai huH1N1 and pH1N1 viruses. Evidence of pig-to-human influenza virus transmission was found in farm workers with increased odds of elevated antibody titers to both swH1N1 (OR 42.63, 95% CI, 14.65-124) and swH1N2 (OR 58, 95% CI, 13.12-256.3) viruses. No evidence of human-to-pig influenza virus transmission was detected in this study.

Distribution of mosquito (Diptera: Culicidae) species and Wolbachia (Rickettsiales: Rickettsiaceae) infections during the bird immigration season in Pathumthani province, central Thailand.

Mosquito distribution in the immigration bird-nested area, Pathumthani province, was investigated from August to December in 2006. Mosquitoes were collected by using CO2-baited Centers for Disease Control light traps in which dry ice was used as a source of CO2 to attract mosquitoes. Six traps were operated from 4 p.m. until 7 a.m. on each study day. Four genera, which were Anopheles, Armigeres, Culex, and Mansonia with 14 species of mosquitoes were collected. Culex gelidus (13.94-59.41%) and Culex tritaeniorhynchus (32.87-70.30%) were most collected species in this area for every month. Other two species with moderate distribution in this area were Anopheles barbirostris (0.76-3.30%) and Mansonia uniformis (1.55-11.36%). Polymerase Chain Reactions were performed for testing Wolbachia infection in Cx. gelidus and Cx. tritaeniorhynchus only. Fifty-four percent (15/28 pools) of Cx. gelidus and none (0/20 pools) of Cx. tritaeniorhynchus were positive for Wolbachia infection. Wolbachia infection in other mosquito species collected in this and other areas need to be investigated to understand species and geographic variation of Wolbachia infection in mosquitoes in nature.

The single-step multiplex reverse transcription- polymerase chain reaction assay for detecting H5 and H7 avian influenza A viruses.

Avian influenza (AI) A virus subtypes H5 and H7 cause severe disease in domestic poultry, including chickens and turkeys. Moreover, H5 and H7 AI A viruses can cross the species barrier from poultry to humans. In the present study, we have developed a single-step multiplex reverse transcription-polymerase chain reaction assay (RT-PCR) for detecting H5 and H7 AI A viruses. This assay was applied to the poultry isolates with the aim of establishing a surveillance method to monitor possible transmission to humans. Two subtype-specific primer sets capable of producing PCR products of 157 and 326 base pairs corresponding to AI A virus H5 and H7 subtypes, respectively, were utilized in a one-step and one-tube reaction. The single-step multiplex RT-PCR assay developed in this study was found to be specific for detecting H5 and H7 AI A viruses. No specific amplification bands were detected with total nucleic acids extracted from other influenza hemagglutinin subtypes and other viral pathogens. The sensitivity of this assay was about 10(3) RNA copies/microl. In conclusion, this novel single-step multiplex RT-PCR is a simple assay with high potential for rapid, specific and cost effective laboratory diagnosis of H5 and H7 AI A virus isolates from clinical specimens of poultry.

The genome sequence analysis of H5N1 avian influenza A virus isolated from the outbreak among poultry populations in Thailand.

In this report, the genome of the Thai avian influenza virus A (H5N1); A/Chicken/Nakorn-Pathom/Thailand/CU-K2/04, isolated from the Thai avian influenza A (AI) epidemic during the early of 2004 was sequenced. Phylogenetic analyses were performed in comparison to AI viruses from Hong Kong 1997 outbreaks and other AI (H5N1) isolates reported during 2001-2004. Molecular characterization of the Thai AI (H5N1) HA gene revealed a common characteristic of a highly pathogenic AI (HPAI), a 20-codon deletion in the neuraminidase gene, a 5-codon deletion in the NS gene and polymorphisms of the M2 and PB2 genes. Moreover, the HA and NA genes of the Thai AI displayed high similarity to those of the AI viruses isolated from human cases during the same epidemic. Finally, our results demonstrated that the Thai AI emerged as a member of 2000's AI lineage with most of the genetic sequences closely related to the Influenza A/Duck/China/E319.2/03 (H5N1).

Orangutan herpesvirus.

A male orangutan suffered from ulcers at the buccal mucosa. We obtained swab fluid from the base of both vesicles and ulcers and collected blood for further separation into serum, plasma and peripheral blood mononuclear cells (PBMC) for detection of antibody to herpesvirus by serology and herpesvirus DNA by polymerase chain reaction (PCR) using consensus degenerate primers. Serology was positive for human EBV IgG but negative for Epstein-Barr virus (EBV) immunoglobulin (IgM), as well as for both human cytomegalovirus and herpes simplex virus IgG and IgM. Upon PCR, we obtained a 232-bp product of virus DNA from PBMC, but not from lesions, serum or plasma. We confirmed the positive result by direct sequencing and compared the nucleotide sequence with other nucleotide sequences applying the BLAST program from GenBank. The sequence was similar to lymphocryptovirus of macaque (93%), marmoset (93%), gorilla (90%) and human EBV (90%). We aligned this sequence with other sequences in GenBank and performed phylogenetic analysis, showing that it probably belongs to the gammaherpesvirus group.

Avian influenza H5N1 in tigers and leopards.

Influenza virus is not known to affect wild felids. We demonstrate that avian influenza A (H5N1) virus caused severe pneumonia in tigers and leopards that fed on infected poultry carcasses. This finding extends the host range of influenza virus and has implications for influenza virus epidemiology and wildlife conservation.