Serological Surveillance of Wild Waterfowl in Northern Australia for Avian Influenza Virus Shows Variations in Prevalence and a Cyclical Periodicity of Infection.

The virological surveillance of 3582 wild waterfowl in northern Australia from 2004 to 2009 for avian influenza virus (AIV) found an apparent prevalence (AP) of 1% (31 of 2989 cloacal swabs; 95% CI: 0.71%-1.47%) using a Taqman Type A real-time reverse transcription polymerase chain reaction test and no viral isolations from 593 swabs tested by the embryonating chicken egg culture method. From serological testing using a nucleoprotein competitive enzyme-linked immunosorbent assay for AIV antibody, 1131 of 3645 sera had ≥ 40% inhibition, indicating an apparent seroprevalence of 31% (95% CI: 29.5%-32.6%). This value suggests that the low AP from virological testing does not reflect the dynamics of AIV infection in these populations. Spatiotemporal and species variations in seroprevalence were found at wetland sampling sites, with consistently higher values at Kununurra in Western Australia (AP  =  39%, 95% CI: 36.9%-41.4%) compared to other locations. At Kununurra, seroprevalence values had a two-year cyclical periodicity and suggest this location is a hotspot of AIV activity. From hemagglutination inhibition (HI) testing using multiple subtype antigens, the highest AP of HI reactions were to H6 and H5 subtypes. The phenomenon of cyclic periodicity in NP seroprevalence at Kununurra is hypothesized as being related to the prevalent H6 subtype that may have either become predominant or cycled back into a mostly AIV naïve flock. The inclusion of serological testing provided insight into the dynamics of AIV infection in wild birds such as species risk profiles and spatiotemporal patterns, important epidemiological information for a risk-based approach to surveillance.

Surveillance of Charadriiformes in northern Australia shows species variations in exposure to avian influenza virus and suggests negligible virus prevalence.

The virologic surveillance of 4248 Charadriiformes since 1992 primarily from coastal northwest Australia did not detect any evidence of avian influenza virus (AIV) excretion (test prevalence = 0%; 95% confidence interval [CI]: 0%-0.09%). Past exposure to AIV was evident from serologic testing using nucleoprotein (NP) competitive-ELISA (c-ELISA) with an overall seroprevalence of 8.8% (95% CI: 8%-9.7%). The c-ELISA seroprevalence of family Scolopacidae and genus Numenius was significantly higher when compared with other families and genera, respectively. Exposure risk profiles, based on c-ELISA seroprevalence, were compiled for 40 species with the following species having significantly higher values when compared with the combined value of all other species: eastern curlew (Numenius madagascariensis), whimbrel (Numenius phaeopus), ruddy turnstone (Arenaria interpres), grey plover (Pluvialis squatarola), little curlew (Numenius minutus), red knot (Calidris canutus), sharp-tailed sandpiper (Calidris acuminata), and red-necked stint (Calidris ruficollis). From hemagglutination inhibition (HI) testing, the more prevalent HI reactions were against H2, H5, H6, and H9 subtypes, with no reactions against subtypes H11, H14, H15, and H16. Serologic testing using c-ELISA provided species risk profiles for optimizing a surveillance strategy for AIV in diverse populations of wild birds. The paucity of knowledge about the role of waders in the ecology of AIV and the overall very low to negligible virus prevalence reported globally, and in this study, suggests that waders are spillover hosts in shared ecosystems with a lesser role than previously considered.

Evaluation of avian influenza serologic and virologic diagnostic methods in wild Anseriformes and Charadriiformes.

Evaluation of avian influenza virus (AIV) diagnostic methods, including a nucleoprotein (NP) competitive enzyme-linked immunosorbent assay (c-ELISA), hemagglutination inhibition (HI) test, type A real-time reverse transcription polymerase chain reaction (RRT-PCR), and embryonating chicken egg (ECE) virus isolation (VI), suggested validity of these tests in wild birds comparable to that reported in poultry. This was determined by analyzing the results from experimental inoculation of three species of wild birds with a low-pathogenicity AIV and from field surveillance data. The NP c-ELISA in a high-AIV prevalence setting had 100% diagnostic sensitivity (Se; 95% confidence interval [CI]: 81.5%-100%) and 91% diagnostic specificity (Sp; 95% CI: 70.8%-98.9%) in negative controls compared with the RRT-PCR. In low-AIV prevalence flocks using a > 60% inhibition positivity threshold, relative to the HI test, c-ELISA performed with 90.5% Se (95% CI: 86.2%-93.8%) and 41.2% Sp (95% CI: 38.1%-44.5%). Assessment of HI suggests a titer > or = 8 is a positive test result in wild-bird sera, and using this titer had 83.3% Se (95% CI: 58.6%-96.4%) in experimentally infected birds. The RRT-PCR diagnostic performance compared with VI in cloacal swabs varied over 2-6 days postinoculation, having high Se (83.3%-100%) and Sp (94.1%-100%) with substantial agreement (kappa = 0.8). The cycle thresholds (C(t)) for the RRT-PCR of C(t) < 37 for positivity and C(t) = 37-40 as indeterminate were found to be valid for the species included in this study. In view of the interpretative diagnostic difficulties in heterogeneous populations of wild birds, this evaluation in three species of wild birds and in surveillance data should provide greater confidence in the application of these methods routinely used in poultry.

Variation in the responses of wild species of duck, gull, and wader to inoculation with a wild-bird-origin H6N2 low pathogenicity avian influenza virus.

There is poor understanding of host responses to avian influenza virus (AIV) infection in wild birds, with most experimental studies using captive-bred birds and highly pathogenic AIVs that have an early endpoint. The objective of this study was to experimentally assess antibody responses and patterns of viral excretion in wild birds challenged with a low pathogenicity AIV. Ruddy turnstones (Arenaria interpres), silver gulls (Chroicocephalus novaehollandiae), and wandering whistling ducks (Dendrocygna arcuata) were challenged with a H6N2 virus, and blood, cloacal, and oropharyngeal (OP) swabs were analyzed from each bird over 28 days, with serology conducted on the ducks for a further 7 mo. Nineteen of 22 birds showed evidence of infection, with respiratory infection prevalent in the turnstones and gulls as mostly low titer viral excretion to 4 days postinoculation (DPI) with gastrointestinal replication detected in only one turnstone. In AIV naive ducks, there was gastrointestinal tropism with moderately high titer viral excretion via the cloaca to 6 DPI and low-grade OP viral excretion to 4 DPI. The hemagglutination inhibition antibody response was poor in the ducks, declining from 19 to 56 DPI, with higher titer responses in the gulls and turnstones. All infected birds responded with elevated nucleoprotein antibodies (in competitive enzyme-linked immunosorbent assay) by 7-10 DPI, and in the ducks these waned slowly after 42 DPI and were long-lived to at least 8 mo. The interspecies variability in response was consistent with a subtype that had adapted well in ducks, while the response of the turnstones may have been influenced by preexisting immunity to AIV. These findings provide insight into AIV infection dynamics in wild birds and highlight the need for further research.

Serological and clinical surveillance studies to validate reported foot-and-mouth disease free status in Tsirang district of Bhutan.

Serological and clinical studies were conducted between March 2009 and August 2010 to validate the foot-and-mouth disease free status of Tsirang district of Bhutan as determined by the country's passive surveillance system. Randomised (first survey) and targeted (third survey) samplings, with subsequent follow-up samplings (second and fourth), were conducted on FMD-susceptible animals to detect the disease at a design prevalence of 25% and 20% at the individual animal-level and village-level, respectively. Sera from cattle, goats, pigs, and sheep were tested for the presence of non-structural protein (NSP) antibodies using two commercial (PrioCHECK(®) FMDV NS and CHEKIT(®)-FMD-3ABC-bo-ov) and one in-house NSP kit (c-ELISA, AAHL, Australia). The overall seropositivity (all species) at the animal-level was 3% (95% CI: 1.7, 4.8) and 3.5% (95% CI: 2.1, 5.4), for the randomised and targeted surveys, respectively. Except for one goat from the first survey, none of the small ruminants and pigs had NSP antibodies. The seropositives from the first and targeted surveys were distributed among 13 and 16 of 20 villages sampled, respectively. All repeat testing from the initial seropositive animals and their herd mates, for both the first and third surveys, were negative in the NSP tests 6-8 months later. Using the hypergeometric exact probability formula for two-stage analyses, the results enabled rejection of the null hypothesis and supported conclusion that the population was free from disease at the minimum expected prevalence of 20% at the 95.53% and 99.46% confidence levels, for the randomised and targeted surveys, respectively. Clinical surveillance also showed absence of disease or clinical signs suggestive of FMD. The few seropositives were likely to be false positives due to factors such as imperfect specificities of the tests and possible NSP-residues in the vaccines. The study has paved the way for initiation of zoning approaches for the progressive control of FMD in Bhutan.

The seroprevalence of foot-and-mouth disease in the sedentary livestock herds in four districts of Bhutan.

Cross sectional serological surveys were conducted between March and December 2009 to determine the distribution of foot-and-mouth disease and also to validate the current passive surveillance system in Bhutan. A total of 1909 sera collected from cattle, goats, sheep, and pigs, from 485 herds in 106 villages, were tested using a foot-and-mouth disease non-structural protein 3ABC ELISA. The true prevalence at the animal-level for all species was 15% (95% CI: 13.5, 16.7) using the sensitivity (97.2%) and specificity (99.5%) for cattle. The true prevalence for cattle, goats, sheep and pigs were 17.6 (95% CI: 15.6, 19.5), 11.9% (95% CI: 5.6, 18.3), 11.9% (95% CI: 1.3, 25.1), and 1.9% (95% CI: 0.0, 3.8), respectively. The sub-districts that shared border with India had significantly (p=0.03) higher seroprevalence than the interior sub-districts. Villages located in the sub-tropical zone had significantly (p<0.0001) higher seroprevalence than those located at high altitude zones. Herds with known outbreaks of FMD were 3.6 times more likely (p<0.001) to be seropositive than those with no history of outbreaks of FMD. The study showed the usefulness of population-based serological surveys in detecting circulation of active infection in populations which were, until now, considered to be free of disease based on a passive surveillance system. The study also highlighted the benefits of conducting serological and questionnaire surveys, simultaneously, to ascertain the infection status of herds and animals. Some of the findings from this study could be considered for strengthening of the current FMD control program in Bhutan.

Evaluation of a Subunit H5 Vaccine and an Inactivated H5N2 Avian Influenza Marker Vaccine in Ducks Challenged with Vietnamese H5N1 Highly Pathogenic Avian Influenza Virus.

The protective efficacy of a subunit avian influenza virus H5 vaccine based on recombinant baculovirus expressed H5 haemagglutinin antigen and an inactivated H5N2 avian influenza vaccine combined with a marker antigen (tetanus toxoid) was compared with commercially available inactivated H5N2 avian influenza vaccine in young ducks. Antibody responses, morbidity, mortality, and virus shedding were evaluated after challenge with a Vietnamese clade 1 H5N1 HPAI virus [A/VN/1203/04 (H5N1)] that was known to cause a high mortality rate in ducks. All three vaccines, administered with water-in-oil adjuvant, provided significant protection and dramatically reduced the duration and titer of virus shedding in the vaccinated challenged ducks compared with unvaccinated controls. The H5 subunit vaccine was shown to provide equivalent protection to the other two vaccines despite the H5 antibody responses in subunit vaccinated ducks being significantly lower prior to challenge. Ducks vaccinated with the H5N2 marker vaccine consistently produced antitetanus toxoid antibody. The two novel vaccines have attributes that would enhance H5N1 avian influenza surveillance and control by vaccination in small scale and village poultry systems.

Analysis of H5N1 avian influenza infections from wild bird surveillance in Hong Kong from January 2006 to October 2007.

Intensive surveillance of dead wild birds for H5N1 avian influenza infection is conducted in Hong Kong. Between January 2006 and October 2007 pooled cloacal and tracheal swabs from 17692 dead wild birds (from 16 different orders including 82 genera) were tested and 33 H5N1 highly pathogenic avian influenza viruses were isolated. No H5N1 infection has occurred in poultry farms since January 2003, or in live poultry markets in Hong Kong since November 2003 until a recent detection of H5N1 virus by surveillance of live poultry markets in June 2008. The gross and histopathology in the various H5N1-infected avian species is described, along with the performance of the virus isolation and polymerase chain reaction (PCR) tests used. This evaluation also included determination of virus titres and detection limits for the H5 haemagglutinin gene (H5)and matrix gene real-time reverse-transcription PCR tests in cloacal and tracheal swabs from 12 wild birds. The viruses isolated belonged to Clades 2.3.2 and 2.3.4, and within Clade 2.3.4 some clustering was evident based on H5 haemagglutinin gene haemagglutinating sequencing. There were no differences in the pathology findings between these subgroupings and the various diagnostic tests gave similar results for these viruses, except for a loss in sensitivity of the H5 real-time reverse-transcription PCR for several viruses in one cluster from birds submitted in February 2007. The use of multiple test methods was important in maintaining the diagnostic sensitivity for detecting avian influenza viruses with high genetic variability.

Characterization of avian influenza viruses A (H5N1) from wild birds, Hong Kong, 2004-2008.

From January 2004 through June 2008, surveillance of dead wild birds in Hong Kong, People's Republic of China, periodically detected highly pathogenic avian influenza (HPAI) viruses (H5N1) in individual birds from different species. During this period, no viruses of subtype H5N1 were detected in poultry on farms and in markets in Hong Kong despite intensive surveillance. Thus, these findings in wild birds demonstrate the potential for wild birds to disseminate HPAI viruses (H5N1) to areas otherwise free from the viruses. Genetic and antigenic characterization of 47 HPAI (H5N1) viruses isolated from dead wild birds in Hong Kong showed that these isolates belonged to 2 antigenically distinct virus groups: clades 2.3.4 and 2.3.2. Although research has shown that clade 2.3.4 viruses are established in poultry in Asia, the emergence of clade 2.3.2 viruses in nonpasserine birds from Hong Kong, Japan, and Russia raises the possibility that this virus lineage may have become established in wild birds.

Evaluation of a positive marker of avian influenza vaccination in ducks for use in H5N1 surveillance.

Control measures for H5N1 avian influenza involve increased biosecurity, monitoring, surveillance and vaccination. Subclinical infection in farmed ducks is important for virus persistence. In major duck rearing countries, homologous H5N1 vaccines are being used in ducks, so sero-surveillance using H5- or N1-specific antibody testing cannot identify infected flocks. An alternative is to include a positive marker for vaccination. Testing for an antibody response to the marker would confirm approved vaccine use. Concurrent testing for H5 antibody responses would determine levels adequate for protection or indicate recent infection, with an anamnestic H5 antibody response requiring further virological investigation. In this study, we have evaluated the use of a TT marker in ducks given avian influenza vaccination. Wild or domestic ducks were tested for antibodies against TT and all 463 ducks were negative. High levels of TT-specific antibodies, produced in twice-TT vaccinated Muscovy ducks, persisted out to 19 weeks. There was no interference by inclusion of TT in an inactivated H6N2 vaccine for H6- or TT-seroconversion. Thus TT is a highly suitable exogenous marker for avian influenza vaccination in ducks and allows sero-surveillance in countries using H5N1 vaccination.

Use of tetanus toxoid as a differentiating infected from vaccinated animals (DIVA) strategy for sero-surveillance of avian influenza virus vaccination in poultry.

Strategies for differentiating infected from vaccinated animals (DIVA) require improvement for increased surveillance of avian influenza (AI), where vaccination is employed to control disease. We propose a novel DIVA approach for chickens using tetanus toxoid (TT) as an exogenous marker independent of serotype and relatedness of circulating and vaccine strains. Of 1779 chickens tested from Australia, Hong Kong and China, 100% were seronegative for TT-specific antibodies without vaccination. Tetanus toxoid adjuvanted to mineral oil was immunogenic in chickens. Co-delivery of both TT and inactivated LPAI (H6N2) vaccines in chickens elicited strong TT and influenza-specific antibody responses, which persisted to 53 weeks post-vaccination. Furthermore, immunization with a combined vaccine composed of TT and AI induced high levels of antibodies to both antigens. We conclude that TT is a highly suitable exogenous marker for AI vaccination in chickens allowing simple and effective monitoring of AI vaccination status.

Risk for infection with highly pathogenic influenza A virus (H5N1) in chickens, Hong Kong, 2002.

We used epidemiologic evaluation, molecular epidemiology, and a case-control study to identify possible risk factors for the spread of highly pathogenic avian influenza A virus (subtype H5N1) in chicken farms during the first quarter of 2002 in Hong Kong. Farm profiles, including stock sources, farm management, and biosecurity measures, were collected from 16 case and 46 control chicken farms by using a pretested questionnaire and personal interviews. The risk for influenza A (H5N1) infection was assessed by using adjusted odds ratios based on multivariate logistic regression analysis. Retail marketing of live poultry was implicated as the main source of exposure to infection on chicken farms in Hong Kong during this period. Infection control measures should be reviewed and upgraded as necessary to reduce the spread of influenza A (H5N1) related to live poultry markets, which are commonplace across Asia.

Performance evaluation of five detection tests for avian influenza antigen with various avian samples.

In this paper, we report on the evaluation of five influenza antigen detection tests by avian influenza H5N 1 virus-positive swab samples to estimate their diagnostic sensitivity. The tests included two chromatographic immunoassays, an H5 avian influenza-specific antigen detection enzyme-linked immunosorbent assay (ELISA), an influenza A antigen detection ELISA, and an H5 rapid immunoblot assay. The results showed that the overall sensitivities of these tests ranged from 36.3% to 51.4% (95% confidence interval ranging from 31.0% to 57.0%), which were comparable to Directigen Flu A antigen detection tests but substantially lower than genome detection methods. Diagnostic sensitivity performance is a function of the concentration of antigens in samples and the analytical sensitivity of the individual test. The test sensitivities were significantly higher for sick and dead birds by cloacal, tracheal, or tissue swabs than for fecal swabs from apparently healthy birds, and these tests would not be suitable for surveillance testing of clinically healthy birds. Furthermore, the sensitivity for testing tracheal and cloacal swabs from waterfowl and wild birds was not as good as for chickens. This was most likely to be associated with variation in virus titers between specimens from different bird species. However, the tests showed good sensitivities for testing brain swabs from clinically affected waterfowl species. The results indicate that these antigen detection tests could be used for preliminary investigations of H5N 1 outbreaks as a low-cost, simple flock test in sick and dead birds for the rapid detection of H5N1 infection. However, the relatively low sensitivity of the tests as individual bird tests means that they should be used on optimal clinical specimens from diseased birds, testing birds on a flock basis, or testing samples as close to the onset of disease as possible before viral titers diminish. They should be followed up by confirmatory tests, such as reverse transcription polymerase chain reaction or viral culture, wherever possible but could assist in facilitating rapid investigations and control interventions.

Investigation of outbreaks of highly pathogenic H5N1 avian influenza in waterfowl and wild birds in Hong Kong in late 2002.

Outbreaks of highly pathogenic H5N1 avian influenza have occurred in Hong Kong in chickens and other gallinaceous poultry in 1997, 2001, twice in 2002 and 2003. High mortality rates were seen in gallinaceous birds but not in domestic or wild waterfowl or other wild birds until late 2002 when highly pathogenic H5N1 avian influenza occurred in waterfowl (geese, ducks and swans), captive Greater Flamingo (Phoenicopterus ruber) and other wild birds (Little Egret Egretta garzetta) at two waterfowl parks and from two dead wild Grey Heron (Ardea cinerea) and a Black-headed Gull (Larus ridibundus) in Hong Kong. H5N1 avian influenza virus was also isolated from a dead feral pigeon (Columba livia) and a dead tree sparrow (Passer montanus) during the second outbreak. The first waterfowl outbreak was controlled by immediate strict quarantine and depopulation 1 week before the second outbreak commenced. Control measures implemented for the second outbreak included strict isolation, culling, increased sanitation and vaccination. Outbreaks in gallinaceous birds occurred in some live poultry markets concurrently with the second waterfowl outbreak, and infection on a chicken farm was detected 1 week after the second waterfowl park outbreak was detected, on the same day the second grey heron case was detected. Subsequent virus surveillance showed the outbreaks had been contained.

Vaccination of chickens against H5N1 avian influenza in the face of an outbreak interrupts virus transmission.

Vaccination of chickens with a commercially available killed H5N2 vaccine was being evaluated as an additional tool to enhanced biosecurity measures and intensive surveillance for control of highly pathogenic avian influenza subtype H5N1 disease in Hong Kong in 2002. In December 2002 to January 2003, there were outbreaks of H5N1 disease in waterfowl in two recreational parks, wild water birds, several poultry markets and five chicken farms. In addition to quarantine, depopulation of the affected sheds and increased biosecurity, vaccination of the unaffected sheds and surrounding unvaccinated farms was undertaken on three farms. In at least two farms, infection spread to the recently vaccinated sheds with low rates of H5N1 mortality in sheds when the chickens were between 9 and 18 days post-vaccination. However, after 18 days post-vaccination no more deaths from H5N1 avian influenza occurred and intensive monitoring by virus culture on these farms showed no evidence of asymptomatic shedding of the virus. This provides evidence that H5 vaccine can interrupt virus transmission in a field setting.

Characterisation of an extracellular serine protease gene (nasp gene) from Dermatophilus congolensis.

A partial amino acid sequence of a serine protease from Dermatophilus congolensis allowed the design of oligonucleotide primers that were complemented with additional ones from previously published partial sequences of the gene encoding the enzyme. The polymerase chain reaction (PCR), using combinations of specific and degenerate oligonucleotide primers, allowed the amplification of a 1738-bp internal fragment of the gene, which was finally characterised by inverse PCR as the first full-length sequenced serine protease gene (nasp) from Dermatophilus congolensis. The deduced amino acid sequence of this enzyme, probably involved in the pathogenesis of dermatophilosis, links it to the subtilisin family of proteases.

Characterization of H5N1 influenza viruses that continue to circulate in geese in southeastern China.

The H5N1 influenza virus, which killed humans and poultry in 1997, was a reassortant that possibly arose in one type of domestic poultry present in the live-poultry markets of Hong Kong. Given that all the precursors of H5N1/97 are still circulating in poultry in southern China, the reassortment event that generated H5N1 could be repeated. Because A/goose/Guangdong/1/96-like (H5N1; Go/Gd) viruses are the proposed donors of the hemagglutinin gene of the H5N1 virus, we investigated the continued circulation, host range, and transmissibility of Go/Gd-like viruses in poultry. The Go/Gd-like viruses caused weight loss and death in some mice inoculated with high virus doses. Transmission of Go/Gd-like H5N1 viruses to geese by contact with infected geese resulted in infection of all birds but limited signs of overt disease. In contrast, oral inoculation with high doses of Go/Gd-like viruses resulted in the deaths of up to 50% of infected geese. Transmission from infected geese to chickens occurred only by fecal contact, whereas transmission to quail occurred by either aerosol or fecal spread. This difference is probably explained by the higher susceptibility of quail to Go/Gd-like virus. The high degree of susceptibility of quail to Go/Gd (H5N1)-like viruses and the continued circulation of H6N1 and H9N2 viruses in quail support the hypothesis that quail were the host of origin of the H5N1/97 virus. The ease of transmission of Go/Gd (H5N1)-like viruses to land-based birds, especially quail, supports the wisdom of separating aquatic and land-based poultry in the markets in Hong Kong and the need for continued surveillance in the field and live-bird markets in which different types of poultry are in contact with one another.